KR20240118362A - A laundry treating apparatus and a control method of the same - Google Patents

Abstract

The present invention maintains the operation of the compressor when the drying cycle is performed until the drying cycle is completed or drying of the clothes is completed, and the temperature inside the inner case is raised to a set temperature or higher while the compressor is operating. It relates to a clothing treatment device that operates together with the first heater or the second heater.

Description

{A laundry treating apparatus and a control method of the same}

The present invention relates to a clothing treatment device and a control method thereof. More specifically, it relates to a clothing treatment device and its control method that can supply steam and hot air to clothing to perform a refresh process such as sterilizing, removing wrinkles, deodorizing, and drying clothing.

In general, among clothes processing devices, a dryer equipped with a rotating drum and a clothes care machine equipped with an inner case that holds clothes in a floating state can perform a drying process to remove moisture from clothes.

Wrinkles and wrinkles in clothing can be removed only when all three factors - moisture content, temperature, and physical force - are met. However, the dryer and clothes care machine are set to make it difficult to secure a section that satisfies all three factors in the drying cycle.

As a result, the dryer and clothes care machine can dry clothes while supplying hot air, but may not be able to easily remove creases or wrinkles present in the clothes.

Figure 1 shows the principle by which wrinkles in clothing are removed.

Referring to Figure 1(a), the fibers constituting clothing L may be woven in the order of 1, 2, 3, 4, and 5. That is, fiber 1, fiber 2, fiber 3, fiber 4, and fiber 5 can be connected by physical bond (I).

However, when these fibers rub against or come into contact with each other depending on their internal chemical structures, chemical bonds (II) such as covalent bonds, hydrogen bonds, and intermolecular bonds may occur between each fiber. For example, the fiber 1 and the fiber 3 are not connected by a physical bond (I) but can be connected by a chemical bond (II), and the fiber 3 and fiber 5 are not connected by a physical bond (I) but can be connected by a chemical bond. It can be connected to (II).

Therefore, at least some of these chemical bonds (II) are concentrated in the clothing (L), and the arrangement or arrangement changes between the fibers where the chemical bonds (II) occur, ultimately causing wrinkles or wrinkles.

Since the wrinkles and creases are created by chemical bonding (II), they cannot be removed using simple physical force alone. The wrinkles and creases can be removed only by dissolving the chemical bond (II).

Referring to Figure 1(b), in order to remove the wrinkles and creases, moisture that can break the chemical bond (II) is first needed. If water is added between the chemical bonds (II) between the fibers, the chemical bonds (II) may be weakened or dissolved.

The amount of moisture that can remove creases and wrinkles can be determined by the moisture content of the clothing, and it is generally known that a moisture content of between 5 and 45 percent is required. Therefore, a moisture content rate of 5 to 45 percent can be defined as a moisture removal rate.

If more moisture than the removal moisture rate is saturated in the clothing, the water actually binds the fibers additionally, so there is no effect of removing wrinkles and wrinkles. If less moisture than the removal moisture rate is present in the clothing, chemical bonding between the fibers (II ) cannot be removed, so there is no effect in removing wrinkles and wrinkles.

Referring to Figure 1(c), in order to remove the wrinkles and creases, heat or energy required to dissolve the chemical bond (II) is required. The chemical bond (II) between the fibers may be weakened when heat is supplied. Heat or energy for removing wrinkles and wrinkles can be achieved when the temperature at which the fiber is contacted is above the set temperature. The set temperature corresponds to a temperature higher than room temperature, and may be set to 36 degrees, for example.

If water is added between the fibers and a high temperature environment above the set temperature is reached, the chemical bond (II) may become very weak.

Referring to Figure 1(d), in order to remove the wrinkles and creases, a physical force that can change the arrangement of the fibers is required. The physical force may include a tensile force that can arrange the fibers in the order in which they are connected by physical bond (I). The physical force that can generate the tensile force can be defined as the removal physical force.

Referring to Figure 1(e), when a chemical bond (II) occurs in the fibers constituting the clothing (L) and wrinkles and wrinkles are formed in the clothing, the conditions of removal moisture rate, set temperature, and removal physical force are all If satisfied, the chemical bonds (II) are removed, and each fiber can be arranged according to the order in which it is connected by physical bonds (I). As a result, wrinkles and wrinkles can be eliminated.

As a result, it can be seen that the removal moisture rate, set temperature, and removal physical force correspond to the removal conditions for wrinkles and wrinkles.

Figure 2 shows a situation in which clothes are dried in a dryer.

The dryer can accommodate clothes in a drum (D) and perform a drying process to remove moisture from the clothes by supplying hot air.

Referring to Figure 2(a), at the beginning of the drying process, the moisture rate of the clothes (L) generally corresponds to a moisture rate higher than the removal moisture rate, and sufficient heat (H) is not applied to the inside of the drum (D). You can.

Even if the drum D rotates, proper tensile force cannot be applied to the clothes because the clothes with high moisture content are clumped together.

As a result, the removal conditions are not achieved at the beginning of the drying process, and wrinkles in the clothing cannot be removed.

Referring to Figure 2(b), in the middle of the drying cycle, the moisture content of the clothing L may reach the removal moisture rate. However, since a large amount of moisture contained in the clothing (L) is vaporized, most of the heat (H) supplied to the inside of the drum (D) can be removed as heat of vaporization.

Therefore, the temperature inside the drum D does not reach the set temperature or higher. Therefore, even in the middle of the drying cycle, the removal conditions are not fully achieved, so wrinkles in the clothing cannot be removed.

Referring to Figure 2(c), at the end of the drying cycle, most of the moisture contained in the clothing (L) evaporates, and the amount of heat absorbed as heat of vaporization may rapidly decrease.

Accordingly, the temperature inside the drum D can rapidly rise above the set temperature to satisfy the removal temperature.

In addition, since the clothes are in a dry state, the clothes may be separated from each other and fall from the rotating drum (D). Therefore, the removal force condition can also be achieved.

However, since most of the clothing L has been dried, the moisture content of the clothing is lower than the removed moisture rate.

Therefore, since the removal condition is not achieved even at the end of the drying cycle, the wrinkles in the clothing cannot be removed.

As a result, it is difficult to form a section that satisfies all removal conditions during the entire drying process in the dryer.

Therefore, there was a fundamental problem in that wrinkles in clothes could not be removed during the drying process with a conventional clothes treatment device.

As a result, there was a limitation in requiring the user to take action such as ironing the clothes separately to remove wrinkles or adding ice, etc. into the drum to satisfy the moisture removal rate condition at the end of the drying cycle.

Recently, clothing treatment devices that can spray steam at the end of the drying cycle to satisfy the removal conditions at the end of the drying cycle have also appeared.

However, although conventional clothing treatment devices can remove wrinkles, there is a problem that additional moisture must be supplied to the dried clothes at the end of the drying cycle and the clothes must be dried again, which not only delays the drying cycle but also inevitably results in wasted energy.

Furthermore, the conventional clothing treatment device had a control limitation in that the operation of the compressor had to be stopped in order to block power consumption exceeding the allowable power amount in the process of driving the heater to supply steam. Therefore, after the drying cycle is completed, the steam must be supplied and the compressor must be driven again for drying, or the compressor must be stopped during the drying cycle and then operated again after supplying steam, which not only delays the drying cycle but also drastically reduces drying efficiency. There was.

Conventional clothing treatment devices had a problem in that they could not automatically remove creases and wrinkles from clothing during the drying process to remove moisture from clothing.

The present invention aims to solve the problem of providing a clothing treatment device that can remove creases and wrinkles from clothing during the drying process.

The present invention aims to solve the problem of providing a clothing treatment device that can maintain the operation of the compressor without interruption even when steam is supplied to remove creases and wrinkles from clothing.

The present invention aims to solve the problem of providing a clothing treatment device that can secure a section that satisfies the removal conditions during the drying process for removing moisture from clothing.

The present invention aims to solve the problem of providing a clothing treatment device that can remove creases and wrinkles from clothing while maintaining energy efficiency in the drying process and preventing drying delays.

In order to solve the above-described problem, the present invention includes a cabinet, an inner case provided inside the cabinet to accommodate clothing, a heat supply unit that supplies hot air to the inside of the inner case, and a steam supply unit that supplies steam. A machine room, a control unit provided in the machine room to control the heat supply unit and the steam supply unit to perform a drying process to dry the clothes, and a control unit provided in the inner case or the machine room to detect the temperature of the air inside the inner case. A clothing processing device including a temperature sensor is provided.

The heat supply unit includes a circulation duct for circulating the air discharged from the inner case, a heat exchanger installed in the circulation duct to dehumidify and reheat the air, and compressing and supplying a refrigerant provided to the heat exchanger to exchange heat with the air. Includes compressor.

The steam supply unit includes a steam case that stores water that generates the steam, and a steam heater that is accommodated in the steam case and heats the water.

When the drying cycle is performed, the control unit operates the steam heater until the inner temperature of the inner case reaches a set temperature or higher to remove wrinkles from the clothing, and even when the steam heater operation is terminated, the compressor When driven, the steam heater can be driven above the guaranteed temperature to ensure that the inner temperature of the inner case reaches the set temperature again.

The set temperature may be set to 37 degrees or higher, and the guaranteed temperature may be set higher than the set temperature.

The control unit may be set to block re-driving of the steam heater after operating the steam heater until the inner temperature of the inner case reaches the guaranteed temperature or higher.

The clothing handling apparatus of the present invention further includes a moving hanger that holds the clothing inside the inner case and drives the clothing to shake.

The control unit may drive the moving hanger at least when the inner case temperature exceeds the set temperature for the second or third time.

The above control unit may stop driving the moving hanger or drive it at a first frequency before the temperature inside the inner case exceeds the set temperature for the second time or reaches it for the third time, and drive the moving hanger at a second frequency that is faster than the first frequency after the temperature inside the inner case exceeds the set temperature for the second time or reaches it for the third time.

The control unit may drive the moving hanger at a third frequency that is slower than the second frequency before the rate of increase in temperature inside the inner case becomes greater than the reference value or reaches the guaranteed temperature again.

The control unit may drive the moving hanger at the second frequency for a set time, and then drive the moving hanger at a third frequency that is slower than the second frequency.

The third frequency may be set to be greater than the first frequency.

The control unit may arrange the section in which the steam heater operates and the section in which the moving hanger operates at the second frequency to be spaced apart from each other.

The control unit may drive the compressor after the steam heater is completed.

The control unit may maintain operation of the compressor until drying of the clothes is completed.

The control unit may drive the compressor before the steam heater is driven and may stop driving the compressor while the steam heater is driving.

The steam heater may be provided as a single heater accommodated inside the steam case.

The steam heater includes a first heater that generates the steam, and a second heater that is spaced apart from the first heater and heats the water to generate the steam, and the control unit when the drying cycle is performed. , the first heater and the second heater can be operated simultaneously until the inner temperature of the inner case reaches the guaranteed temperature or higher.

The present invention has the effect of removing creases and wrinkles from clothing during the drying process.

The present invention has the effect of maintaining the operation of the compressor without interruption even when steam is supplied to remove creases and wrinkles from clothing.

The present invention has the effect of securing a section that satisfies removal conditions during a drying process for removing moisture from clothing.

The present invention has the effect of removing creases and wrinkles in clothing while maintaining energy efficiency in the drying cycle and preventing drying delays.

Figure 1 shows conditions for removing wrinkles and wrinkles.
Figure 2 shows whether the removal conditions of a conventional dryer are achieved.
Figure 3 shows the appearance of the laundry treatment device of the present invention.
Figure 4 shows the machine room structure of the laundry treatment device of the present invention.
Figure 5 shows the circulation duct structure of the laundry treatment device of the present invention.
Figure 6 shows the structure of the heat supply unit of the laundry treatment apparatus of the present invention.
Figure 7 shows the blowing fan structure of the laundry treatment device of the present invention.
Figure 8 shows the inlet duct structure of the laundry treatment device of the present invention.
Figure 9 shows the structure of the steam supply unit of the laundry treatment device of the present invention.
Figure 10 shows the steam heater structure of the laundry treatment device of the present invention.
Figure 11 shows the inside of the steam case of the laundry treatment device of the present invention.
Figure 12 shows the internal structure of the steam supply unit of the laundry treatment device of the present invention.
Figure 13 shows the flow path structure of the laundry treatment device of the present invention.
Figure 14 is a schematic diagram of the flow path structure of the laundry treatment device of the present invention.
Figure 15 shows the movement directions of steam and water in the laundry treatment device of the present invention.
Figure 16 shows the moving hanger structure of the laundry treatment device of the present invention.
Figure 17 shows how the moving hanger of the laundry treatment device of the present invention operates.
Figure 18 shows the configurations of the moving hanger of the laundry treatment device of the present invention.
Figure 19 shows the moving hanger structure of the laundry treatment device of the present invention.
Figure 20 shows the operating structure of the moving hanger of the laundry treatment device of the present invention.
Figure 21 shows a process in which the clothing treatment apparatus of the present invention performs a clothing treatment course.
Figure 22 shows an embodiment of performing a drying course of the laundry treatment apparatus of the present invention.
Figure 23 shows the progress of the drying process in Figure 22.
Figure 24 shows another embodiment of a drying course performed in the laundry treatment apparatus of the present invention.
Figure 25 shows the state of the clothing treatment device when the control method of Figure 24 is performed.
Figure 26 shows another embodiment of a drying course performed in the laundry treatment apparatus of the present invention.

Figure 3 shows the appearance of the laundry treatment device 1 of the present invention.

Referring to Figure 3(a), the laundry treatment apparatus of the present invention may include a cabinet 100 forming an exterior, and a door 400 rotatably coupled to the cabinet 100.

The door 400 includes a main body 410 that forms the front of the cabinet 100, and an installation body extending from one side of the main body 410 on which a display displaying information about the laundry treatment device can be installed. It may include (420).

The installation body 420 may be provided to form a step 430 from the main body 410 toward the rear of the cabinet 100.

Meanwhile, at least a portion of the installation body 420 may be arranged to overlap in the front-to-back direction at the rear of the main body 410. Accordingly, the step 430 can function as a handle.

The installation body 420 may be made of a different material or color than the main body 410. Additionally, the installation body 420 may be made of a translucent material that allows light emitted from the display to pass through.

Referring to Figure 3(b), an inner case 200 having a receiving space 220 for storing clothing may be provided inside the cabinet 100. The inner case 200 may be provided with an opening 210 at the front through which clothing enters and exits, and the opening 210 may be shielded by the door 400.

The inner case 200 may be made of a plastic resin series, and may be made of a reinforced plastic resin series that is not deformed by air at a temperature higher than room temperature air, heated air (hereinafter referred to as hot air), steam, or moisture. .

The inner case 200 may be provided with a height longer than the width. As a result, the clothing can be accommodated in the receiving space 220 without being folded or wrinkled.

The clothing processing device 1 of the present invention may include a moving hanger 1000 capable of holding clothing in the receiving space 220 of the inner case 200.

The moving hanger 100 may be provided as a simple mounting portion mounted on the upper part of the inner case 200 to fix the clothing while floating inside the receiving space 220.

Alternatively, the moving hanger 1000 may be installed on the upper surface of the inner case 200 to shake the clothing.

The moving hanger 1000 may be provided to reciprocate or rotate reciprocally on the upper part of the inner case 200. As a result, clothing mounted on the moving hanger 100 can be shaken in the receiving space 220 to remove foreign substances, and can be effectively exposed to supplied steam or hot air.

The detailed structure and function of the above moving hanger (1000) will be described later.

A pressing portion 520 capable of pressing clothing may be provided on the inner surface of the door 400.

The pressing unit 520 may include a support unit 522 that is fixed to the inner surface of the door 400 and supports one side of the clothing, and a pressing unit 521 that presses the clothing supported on the support unit 522. there is.

The pressing portion 521 may be moved toward the support portion 522 or may be provided to move away from the support portion 522 . For example, the pressing part 521 may be rotatably provided on the support part 522 or the inner surface of the door 400.

Accordingly, the pressing portion 521 and the supporting portion 522 may press both sides of the clothing to remove wrinkles from the clothing and create intended creases.

The laundry treatment apparatus of the present invention supplies one or more of hot air or steam to the receiving space 220, or a machine room ( 300) can be provided.

The machine room 300 may be equipped with a built-in control unit that can control the laundry treatment device. Of course, the control unit may be installed inside the door 400.

The control unit may be provided as a PCB that controls one or more of the electrical components of the laundry treatment device of the present invention and performs an arbitrary course for processing the clothing.

The machine room 300 may be arranged separately or partitioned from the inner case 200, and may be provided to communicate with the inner case 200.

The machine room 300 may be placed below the inner case 200. Accordingly, when hot air and steam with a small specific gravity are supplied to the inner case 200, the hot air and steam can be naturally supplied to the clothing.

The machine room 300 may include a heat supply unit 340 capable of supplying hot air to the inside of the inner case 200. The heat supply unit 340 may be provided as a heat pump system or as a heater that directly heats air with electric energy.

When the heat supply unit 340 is provided as a heat pump system, it may be provided to dehumidify and heat the air discharged from the inner case 200 and supply it to the inner case 200. The detailed structure is described later.

The machine room 300 may include a steam supply unit 800 capable of supplying steam to the inner case 200. The steam supply unit 800 may be provided to directly supply steam to the inside of the inner case 200. The detailed structure is described later.

To this end, the inner case 200 may be provided with a plurality of through holes 230 that penetrate one surface and communicate with the machine room 300.

Air in the receiving space 220 may be supplied to the machine room 300 through the through hole 230, and at least one of hot air or steam generated in the machine room 300 may be supplied to the receiving space 200. can be supplied.

The through hole 230 includes an inlet hole 231 provided to penetrate the lower surface of the inner case 200 and introduce air inside the inner case 200 into the machine room 300, and the inlet hole ( 231) and may include an discharge hole 232 that penetrates the lower surface of the inner case 200 and discharges hot air generated in the machine room 300 into the inner case 200.

The discharge hole 232 may be located closer to the back of the lower surface of the inner case 200 than the front or door 400.

Additionally, the discharge hole 232 may be disposed between the lower surface or the rear surface of the inner case 200 at an angle to the ground. The discharge hole 232 is provided to face the moving hanger 1000, so that the hot air can be supplied toward the clothes.

The inlet hole 231 may be located closer to the front or door 400 than the rear of the lower surface of the inner case 200.

The inlet hole 231 is arranged to be furthest from the outlet hole 232 to prevent the air discharged from the outlet hole 232 from being absorbed directly into the inlet hole 231 without reaching the clothing. there is.

The through hole 230 may further include a steam hole 233 that penetrates the lower part of the inner case 200 and guides the steam generated by the steam supply unit 800 into the inner case 200. .

The steam hole 233 may be located closer to the discharge hole 232 than the inlet hole 231. For example, the steam hole 233 may be placed on one side of the discharge hole 232.

Meanwhile, the machine room 300 may further include a water tank 30 capable of supplying water to the steam supply unit 800, and a drain tank 40 in which condensed water condensed in the heat supply unit 340 is collected. there is.

The water tank 30 and the water tank 40 may be provided to be detachable from the front of the machine room 300. Accordingly, the laundry treatment device 1 of the present invention can be freely installed without being restricted from a water supply source or a drainage source.

Meanwhile, the machine room 300 may further include a drawer 50 that is withdrawn and retracted from the front and has a separate accommodation space. For example, the drawer 50 may store a steam generator or an iron.

Figure 4 shows the machine room structure of the laundry treatment apparatus of the present invention.

Figure 4(a) is a view of the machine room 300 from the front, and Figure 4(b) is a view of the machine room 300 from the rear.

Inside the machine room 300, components may be placed to supply hot air to the clothing processing space, circulate air inside the clothing processing space, supply steam to the clothing processing space, or clean the air outside the cabinet.

The machine room 300 may include a base portion 310 that supports various devices or arranges a space for installation. The base portion 310 can provide an area where various devices can be installed.

The base portion 310 may be provided with a circulation duct 320 through which air introduced from outside the inner case 200 or the cabinet 100 moves.

The circulation duct 320 may be provided in a case shape with an open top, and some of the heat supply units 340 may be installed therein.

When the heat supply unit 340 is provided as a heat pump system, it may include heat exchangers 341 and 343, which will be described later, inside the circulation duct 320, and a compressor 342 that supplies high-temperature and high-pressure refrigerant to the heat exchanger. .

The heat exchangers 341 and 343 are accommodated inside the circulation duct 320 and can cool and dehumidify the air flowing through the circulation duct 320, or heat the air to generate hot air.

When the circulation duct 320 is provided to suck air from the outside of the cabinet 100, an outside air duct 370 may be installed in front of the circulation duct 320 to suck in outside air.

The circulation duct 320 may be provided to communicate with the outside air duct 370 and may be provided to selectively suck in outside air.

The water supply tank and the drain tank may be detachably coupled to the front of the circulation duct 320. The water tank 30 and the water tank 40 may be placed and seated on the upper part of the outdoor air duct 370.

The circulation duct 320 may be provided coupled to the base portion 310, or may be provided integrally with the base portion 310. For example, the base portion 310 and the circulation duct 320 may be manufactured by injection molding.

The machine room 300 may include a base cover 360 provided to communicate with the circulation duct 320 and the inlet hole 231.

The base cover 360 may be coupled to the upper part of the circulation duct 320 and may be provided to guide air sucked in from the inlet hole 231 into the circulation duct 320.

The base cover 360 can block the air inside the circulation duct 320 from being discharged to the outside by shielding the upper surface of the circulation duct 320. The lower part of the base cover 360 and the upper surface of the circulation duct 320 may form one side of the flow path of the circulation duct 320.

The base cover 360 may include an inlet 362 connecting the inlet hole 231 and the circulation duct 320. The inlet 362 is provided in a duct shape and can serve as an intake duct that delivers air inside the inner case 200 to the circulation duct 320.

The machine room 300 may be installed with a steam supply unit 800 that is connected to the water tank 30, receives water, generates steam, and supplies it to the inner case 200. The steam supply unit 800 may be placed and seated on the upper part of the base cover 360.

The steam supply unit 800 may be disposed outside the circulation duct 320. As a result, the steam supply unit 800 can be prevented from impeding the movement of air flowing through the circulation duct 320 or heating the air.

Additionally, the steam supply unit 800 may be arranged to be spaced apart from the inlet 362. For example, the steam supply unit 800 may be placed rearward of the inlet unit 362.

The machine room 300 may include a fan installation unit 350 provided to communicate with the circulation duct 320 and the inner case 200. The fan installation unit 350 accommodates a blowing fan 353 that provides power to move the air inside the circulation duct 320 in one direction, and is coupled to the circulation duct 320 to accommodate the blowing fan 353. It may include a fan housing 351 that extends or extends.

The fan installation unit 350 may be provided with a discharge duct 352 that communicates with the circulation duct 320 and the discharge hole 232.

The discharge duct 352 may be provided in the fan housing 351 with a cross-sectional area corresponding to the discharge hole 232 and extending toward the discharge hole 232.

As a result, the air inside the inner case 200 flows in through the base cover 360, passes through the circulation duct 320, and then flows back into the inner case 200 through the fan installation part 350. can be supplied.

Meanwhile, the base portion 310 may be provided with a compressor installation portion 313 where the compressor 342 that supplies refrigerant to the heat exchangers 341 and 343 is installed. The compressor installation unit 313 may be disposed outside the circulation duct 320.

Additionally, the base unit 310 may be equipped with the control unit 700 that controls the laundry treatment apparatus of the present invention.

The base unit 310 may be provided with a control unit installation unit 312 that forms a space into which the control unit 700 can be inserted at the bottom of the circulation duct 320.

The control unit 700 may be provided to control all electronically controlled electrical components, such as the compressor 342, the steam supply unit 800, and the blowing fan 353.

Since the control unit 700 is inserted and supported in the base unit 310, the vibration generated from the moving hanger 1000 or the clothing is blocked or attenuated from being transmitted to the control unit 700. ) can be transmitted.

In addition, the control unit 700 is installed in the base unit 310 and has a close separation distance from all electrical components installed in the machine room 300, thereby preventing noise or control errors from occurring.

In the laundry treatment apparatus of the present invention, the steam supply unit 800 is disposed at the upper part of the circulation duct 320, and the control unit 700 is disposed at the lower part of the circulation duct 320. Therefore, the circulation duct 320 may be provided in the shape of a straight duct between the steam supply unit 800 and the control unit 700. As a result, flow resistance of air passing through the circulation duct 320 can be minimized.

Since the circulation duct 320, the outside air duct 370, the steam supply unit 800, the control unit 700, and the heat supply unit 340 can all be installed in the base unit 310, the base unit 310 Can be provided as one module. As a result, the base unit 310 can be pulled in and out of the machine room 300 forward or backward, allowing most electrical equipment to be easily installed, maintained, and repaired.

Figure 5 shows the machine room base structure of the laundry treatment device of the present invention.

Figure 5(a) is a perspective view of the base portion 310 viewed from the front, and Figures 5(b) and 5(c) are perspective views of the base portion 310 viewed from the rear.

The base portion 310 may be installed on a base plate that forms the lower surface of the laundry treatment device. The base portion 310 may itself form the lower surface of the laundry treatment device.

The base portion 310 may include a base bottom portion 311 that forms a support surface. The base bottom portion 311 may form the lower surface of the laundry treatment device. Additionally, the base bottom portion 311 may be installed on the upper surface of the bottom surface of the cabinet 100, which forms the lower surface of the laundry treatment apparatus.

The base portion 310 may be integrally equipped with the circulation duct 320, which forms at least a portion of the flow path through which air moves. The circulation duct 320 may be formed to extend upward from the base bottom portion 311.

The circulation duct 320 provides a duct body 321 extending from the base bottom 311 to form a flow path and a space where an evaporator 341 or a condenser 343 is installed inside the duct body 321. It may include a heat exchanger installation part 3212 and an air discharge part 323 provided at the rear of the duct body 321 through which air of the duct body 321 is discharged.

The air discharge unit 323 may be provided in the shape of a pipe extending rearward from the duct body 321. The diameter of the air outlet 323 may be smaller than the width of the duct body 321.

The air discharge unit 323 may be connected to the fan housing 350. The air discharged from the air discharge unit 323 may be guided into the inner case 200 through the fan housing 350.

The circulation duct 320 may include an external air intake portion 322 formed through the front surface of the duct body 321.

The outside air intake unit 322 may be provided to communicate with the outside air duct 370. The outdoor air duct 370 may be seated and supported in front of the outdoor air intake unit 322.

The circulation duct 320 may be provided with a damper that opens and closes the outside air intake unit 322. By opening and closing the damper, it is possible to allow or block outside air from flowing into the circulation duct 320.

The base portion 310 may include a compressor installation portion 312 that provides a space where the compressor 342 is installed. The compressor installation portion 312 may be formed on one side of the base bottom portion 311 and may be formed integrally with the base bottom portion 311.

The compressor installation portion 312 may be formed with a protrusion capable of supporting the compressor 342. The compressor installation unit 312 may be disposed biased toward the rear of the base unit 310. The compressor installation part 312 may be arranged so that at least a portion of the compressor installation part 312 overlaps the air discharge part 323 in the width direction.

The compressor installation unit 312 may be equipped with a buffer member to reduce vibration transmitted from the compressor 342. The buffer member may be fixed to the protrusion.

The base unit 310 may include a control unit installation unit 313 where the control unit 700 is installed. The control unit installation part 313 may be formed between the base bottom part 311 and the circulation duct 320. The control unit installation portion 313 may be formed between the base bottom portion 311 and the bottom surface of the circulation duct 320. The control unit installation unit 313 may be provided in the shape of an open duct at either the front or the rear at the lower part of the circulation duct 320.

Figure 6 shows the circulation duct structure of the laundry treatment device of the present invention.

The circulation duct 320 may extend from the base bottom to the top to form a flow path through which air flows. The circulation duct 320 may include a heat exchanger installation portion 3212 that provides a space where the evaporator 341 and the condenser 342 are installed. The heat exchanger installation part 3212 may be provided inside the duct body 321.

The duct body 321 may be provided with an open upper surface. The condenser 343 and the evaporator 341 can be installed through the opening of the duct body 321.

The opening of the duct body 321 may be shielded by the base cover 360, and the base cover 360 and the duct body 321 may form a flow path of the circulation passage 320.

The front surface of the duct body 321 may be arranged to be spaced rearward from the front end of the base bottom portion 311.

As a result, the base bottom portion 311 can secure a support surface 3111 on which one or more of the water tank 30, the water tank 40, and the outdoor air duct 370 are installed and supported.

Meanwhile, the heat supply unit 340 includes an evaporator 341 installed inside the circulation duct 320 and provided as a heat exchanger to cool and dehumidify the air flowing into the circulation duct 320, and the evaporator 341. A condenser 343 provided as a heat exchanger that heats the passing air to form hot air, and a compressor 342 arranged outside the circulation duct 320 and supplying a refrigerant that exchanges heat with the air to the condenser 343. , It may include an expansion valve 344 that expands and cools the refrigerant that has passed through the condenser 343.

Meanwhile, as the duct body 321 is integrally molded with the base portion 310, the height of the heat exchanger installation portion 3212 can be increased, and the height of the condenser 343 and the evaporator 341 can also be increased. can be increased. As a result, the width of the condenser 343 and the evaporator 341 in the front and rear directions can be reduced, and the number of refrigerant pipes passing through the condenser and evaporator can be reduced. Accordingly, there is an effect of reducing the flow loss of air passing through the condenser and evaporator.

Meanwhile, the sum of the lengths of the evaporator 341 and the condenser 343 may be smaller than the length of the heat exchanger installation portion 3212. Accordingly, the front-to-back length of the heat exchanger installation portion 3212 may be equal to or less than half the length of the duct body 321.

Therefore, since the heat exchanger installation part 3212 can be sufficiently spaced apart from the outside air intake part 322, sufficient space is provided inside the circulation duct 320 through which the outside air and the air inside the inner case 200 can be introduced. It can be secured.

Meanwhile, the interior of the duct body 321 may include an installation partition 3211 that separates the heat exchanger installation part 3212 from the outside of the heat exchange installation part 3212. The installation partition 3211 may be provided to protrude from the side of the duct body 321 and support the front of the evaporator 341.

Additionally, the duct body 321 may be expanded in width based on the installation partition 3211 and extend rearward.

As a result, the width of the heat exchanger installation portion 3212 may be greater than half the width of the base portion 310. Additionally, the width of the circulation duct 320 may be greater than half the width of the base portion 310.

The width of the condenser 343 and the width of the evaporator 341 may also be greater than half the total width of the base portion 310. As described above, if the width of the condenser 343 and the evaporator 341 is secured, there is an effect of securing sufficient heat exchange capacity.

Additionally, the fan housing 350 may be arranged to overlap the condenser 343 or the evaporator 341 in the front-to-back direction. Accordingly, the air that has passed through the evaporator 341 and the condenser 343 can be introduced into the fan housing 350 without bending the flow path. In other words, the air flowing into the circulation duct 320 has the effect of minimizing flow loss because the flow path is not bent in the process of moving to the fan housing. The laundry treatment device of the present invention includes a temperature sensor (S1) that detects the temperature inside the inner case 200 or the temperature of the air flowing into the circulation duct 320 from the inside of the inner case 200, and a heat supply unit that circulates the heat supply. It may further include a refrigerant sensor (S2) that detects the temperature of the refrigerant.

The temperature sensor (S1) may be installed on the inner wall of the net duct (320), and the refrigerant sensor (S2) may be provided on the discharge side of the compressor (342).

Figure 7 shows the structure of the air discharge unit 323 of the laundry treatment device of the present invention.

The base portion 310 may include an air discharge portion 323 that discharges treated air toward the fan housing.

The air discharge unit 323 may be provided to communicate with the inside of the circulation duct 320 or between the duct body 321 and the fan housing 350. The air discharge unit 323 may be provided in the shape of a bell mouth. Equipped with a bell mouth shape, it can reduce air flow loss and improve air circulation efficiency.

The air discharge pipe 3232 of the air discharge unit 323 is provided in the shape of a pipe, and during the mold removal process based on the parting line 3233, the mold disposed in front of the parting line 3233 is pulled forward, The mold placed behind the parting line 3233 can be pulled out rearward.

The fan installation unit 350 may be supported by being coupled to the air discharge pipe 3232. The fan housing 351 may have a coupling hole coupled to the outer peripheral surface of the air discharge pipe 3232, and the blowing fan 353 can be placed in the coupling hole.

The fan housing 351 may include a discharge duct 352 extending from the outer peripheral surface or the outside of the blowing fan 353 to the discharge hole 232.

The fan housing 351 and the discharge duct 352 may accommodate the blowing fan 353 therein and form a flow path through which air can move.

The motor that rotates the blowing fan 353 may be coupled to and supported on the outside of the fan housing 351.

Figure 8 shows the structure of the base cover of the laundry treatment device of the present invention.

The base cover 360 may be coupled to the upper surface of the circulation duct 320 to prevent the inside of the circulation duct 320 from being exposed.

The base cover 360 is coupled to the upper surface of the circulation duct 320 and includes an inlet body 361 that communicates the inner case 200 and the circulation duct 320, and an inlet body 361 extending from the inlet body 361. It may include a shielding body 363 that shields the circulation duct 320.

The inlet body 361 may be provided in a duct shape to communicate with the inlet hole 231 of the inner case and the inside of the circulation duct 320. The inflow body 361 may be provided to protrude further upward than the shielding body 363.

The inlet body 361 may be placed ahead of the evaporator 341 so as not to face the evaporator 341 and the condenser 343, and may be placed ahead of the partition wall 3211.

The inlet body 361 may serve as an inlet duct that moves air in the inner case 200 to the circulation duct 320.

The inflow body 361 may be provided with an inlet portion 362 through which the air of the inner case 200 can pass.

Specifically, the base cover 360 has a first rib 362a extending along the width direction of the inlet body 361, and is spaced rearward from the first rib 362a to form a portion of the inlet body 361. It may include a second rib 362b extending along the width direction.

The first rib 362a and the second rib 362b may be provided side by side. The first rib 362a and the second rib 362b may be provided in a plate shape extending in the vertical direction, and their height may be provided to correspond to the height of the inlet body 361.

The front edge of the inlet body 361 and the first rib 362a may form a first inlet 3621, and the first rib 362a and the second rib 362b may form the second inlet. 3622 can be formed, and the second rib 362b and the rear edge of the inlet body 361 can form a third inlet 3623.

The first inlet 3621 and the third inlet 3622 may have the same area, and the second inlet 36222 may be the area of the first inlet 3621 and the third inlet 3622. It can be provided smaller.

The base cover 360 includes a damper part 364 provided to open and close the inlet part 362, and a drive part 365 that is coupled to the damper part 364 and controls the opening and closing of the damper part 364. It can be included.

The damper unit 364 may include a first damper unit 3641 provided to open and close the first inlet 3621, and a second damper unit 3642 provided to open and close the third inlet 3623. You can.

The first damper unit 3641 is provided in a plate shape with an area corresponding to the first inlet 3621, and is rotatable on both sides of the inlet body 361 within the first inlet 3621. can be combined

The second damper unit 3642 is provided in a plate shape with an area corresponding to the third inlet 3622, and is rotatable on both sides of the inlet body 361 within the third inlet 3622. can be combined

The second inlet 3622 may be provided with a blocking filter 366 that allows air to pass through but filters foreign substances such as fine dust and lint.

The blocking filter 366 may be inserted into the second inlet 3622 to partition the first inlet 3621 and the third inlet 3623. The blocking filter 366 may be arranged to extend from the second inlet 3622 to contact the bottom surface of the circulation duct 320.

The blocking filter 366 may be provided as a filter capable of filtering even the moisture. For example, the blocking filter 366 may be provided as a HEPA filter or the like.

Meanwhile, when the blocking filter 366 is inserted into the second inlet 3622, a shielding member that shields the second inlet 3622 may be further coupled.

The driving unit 365 includes a motor that provides power to selectively rotate the first damper unit 364 and the second damper unit 365, and a motor that engages the motor to rotate the first damper unit 364. ) and a plurality of gear members capable of selectively rotating the second damper unit 365.

Due to the driving unit 365, the first inlet 3611 and the third inlet 3623 can be selectively opened.

Due to the above driving unit (365), air contained inside the inner case (200) may be introduced into the circulation duct (320) along the first inlet (3621) or may be introduced into the circulation duct (320) along the third inlet (3623).

Of course, the driving unit 365 can control the first damper 3641 and the second damper 3642 to open both the first inlet 3611 and the third inlet 3623, and the The first damper 3641 and the second damper 3642 can be controlled to shield both the first inlet 3611 and the third inlet 3623.

The driving unit 365 may be provided in any structure as long as it can rotate the first damper 3641 and the second damper 3642. For example, it may be provided as a combination of a motor, a main gear rotating by the motor, and a driven gear coupled to the first damper and the second damper and rotating by rotation of the main gear.

The base cover 360 may include a shielding body 363 that extends from the inflow body 361 and can shield the evaporator 341 and the condenser 343. The shielding body 363 may be provided in a plate shape.

The base cover 360 can be detachably coupled to the upper surface of the circulation duct 320 through an inlet hook 3612 extending from the lower surface of the inlet body 361.

The circulation duct 320 may be provided with a coupling portion that is detachably coupled to the inlet hook 3612.

Figure 9 shows the installation structure of the steam supply unit.

The steam supply unit 800 may be supported by being seated on the base cover 360.

The steam supply unit 800 may include a steam generator 810 that is seated on the base cover 360 and stores water for generating the steam.

The steam supply unit 800 may further include an installation bracket 870 capable of fixing the steam generator 810 to the base cover 360.

The installation bracket 870 can be coupled to the base cover 360 to fix the steam generator 810.

The installation bracket 870 may include a lower panel 871 supporting the lower surface of the steam generator 810 and a side panel 872 supporting both sides of the steam generator 810 on the lower panel 871. You can.

The installation bracket 870 may further include one or more fixing clips 873 that extend from the side panel 872 to prevent the steam generator 810 from being separated.

The fixing clip 873 may be detachably provided on the top or side of the steam generator 810.

The compressor 342 may be disposed lower than the steam supply unit 800.

The installation bracket 870 may be provided to block heat generated from the compressor or heat generated from the refrigerant compressed in the compressor from being transmitted to the steam supply unit 800.

The installation bracket 870 can also block the fire from spreading to the steam supply unit 800 when a fire occurs in the compressor 342.

Meanwhile, the base cover 360 may include a fastening part 3631 provided on the shielding body 363 and detachably coupled to the steam supply unit 800. The fastening part 3631 may be provided in a structure that is detachably coupled to a protrusion protruding from the lower part of the steam generator 810.

Accordingly, even if a large amount of water is contained within the steam generator 810, the steam generator 810 can be stably seated on the base cover 360.

In addition, since the steam generator 810 is disposed above the circulation duct 320 and the distance to the inner case 200 is shorter, the steam generated by the steam generator 810 is directed to the inner case 200. Condensation before reaching the target can be minimized.

Figure 10 shows the detailed structure of the steam supply unit.

Referring to Figure 10(a), the steam supply unit 800 includes a steam generator 810 capable of receiving and storing water to generate steam, and is accommodated in the steam generator 810 to heat the water to generate steam. It may include a steam heater 840 that generates steam.

The steam generator 810 may be provided in a case shape that forms a space for accommodating the steam heater 840.

For example, the steam generator 810 may be provided in the form of a case with an open top, and may be provided to accommodate the steam heater 840.

The steam supply unit 800 is coupled to the steam generator 810 to prevent the steam heater 840 from being exposed to the outside, and may further include a case cover 820 to prevent the water from leaking. .

The case cover 820 includes a water level sensor 850 that detects the water level of the steam generator 810, and a temperature inside the steam generator 810 or whether steam is generated inside the steam generator 810. A steam sensor 860 that detects may be installed.

Referring to FIG. 10(b), the steam generator 810 may include a case body 811 that stores the water and provides a space to accommodate the steam heater 840.

The case body 811 has an open top so that various parts can be easily installed inside the case body 811.

The case body 811 may include a heater insertion hole 8111 through which one side can be inserted or extracted.

The case body 811 may be provided with a recovery pipe 814 inside which receives water to generate steam.

The recovery pipe 814 may be provided to discharge water contained within the case body 811 to the outside.

The recovery pipe 814 can be kept closed by the shielding stopper 8141 so that it is opened only when residual water inside the steam generator 810 is removed, and the shielding stopper 8141 is prevented from being separated arbitrarily. It may include a shielding clip 8142 that maintains the shielding stopper 8141 coupled to the recovery pipe 814.

Accordingly, when repairing the steam generator 800 or preventing freezing or bursting of the steam generator 800, water inside the steam generator 800 can be discharged through the recovery pipe 814.

Of course, the recovery pipe 814 may be provided to receive water from the water tank 30. Details will be described later.

Meanwhile, a heater fixing part 830 capable of supporting or fixing the steam heater 840 may be installed inside the case body 811. The heater fixing part 830 may include a fixing clip 831 for fixing the steam heater 840, and a clip fastening member 833 for fixing the support clip 831 to the case body 811. there is.

The fixing clip 831 may be provided to accommodate or surround at least a portion of the steam heater 840.

Meanwhile, the steam supply unit 800 may be provided with a water supply pipe 815 through which water is supplied. The water supply pipe 815 may be provided to communicate with the water tank 30 to receive water.

The water supply pipe 815 may be provided on the case cover 820 or may be placed on top of the steam generator 810. As a result, water can be prevented from flowing back through the water supply pipe 815.

The steam supply unit 800 may be provided with a steam pipe 813 that discharges steam generated by driving the steam heater 840 to the outside. The steam pipe 813 is also provided on the upper part of the case cover 820 to prevent water from arbitrarily being discharged into the steam pipe 813.

The steam pipe 813 may communicate with the steam hole 233 of the inner case 200.

The case cover 820 may be provided with a water level sensor hole 854 where the water level sensor can be installed.

The water level sensor 850 includes one or more contact protrusions 852 that are inserted into the water level sensor hole 854 and are immersed in water to detect the water level, and the contact protrusions 852 float within the steam generator 810. It may include a sensor body 851 coupled to the water level sensor hole 854 or supported on the case cover 820 to maintain the sensor body 851 in a fixed state.

The sensor body 851 may be coupled to the case cover 820 through a sensor fastening member 853.

Meanwhile, the case cover 820 may be provided with an insertion hole 864 into which the steam sensor 860 can be installed. The steam sensor 860 is inserted into the insertion hole 864 and includes a detection device 861 that detects whether steam is generated inside the steam generator 810, and a detection device 861 connected to the case cover ( It may include a support 863 that is fixed to the support 820 and a coupling member 862 that couples the support 863 to the case cover 820.

The detection device 861 is provided as a humidity sensor or a temperature sensor and can detect whether steam is generated inside the steam generator 810.

Meanwhile, the case cover 820 may be provided with a cover hook 821 that extends forward and can be coupled to the base cover 860.

In addition, a fixing protrusion 822 that can fix the lower part of the inner case 200 or a separate steam discharge part 900 may be provided at the rear of the case cover 820.

The steam heater 840 is inserted into the heater insertion hole 8111 and accommodated in the steam generator 810, and may be provided to heat water by receiving power.

The steam heater 840 may be provided as a sheath heater, etc., and may be controlled by the control unit 700 so that driving and stopping can be repeated.

The steam heater 840 may include a first heater 841 that receives first power to heat water, and a second heater 842 that heats water by receiving a power smaller than the first power.

As a result, the second heater 842 may be equipped to heat a smaller amount of water and generate more steam than the first heater 841.

The first heater 841 and the second heater 842 may be provided to divide and consume the maximum amount of heater power allowed for the steam heater 840 in the laundry treatment device. That is, if the first heater 841 is equipped to consume a portion of the maximum heater power amount, the second heater 842 may be equipped to consume the remainder of the maximum heater power amount.

For example, when the general maximum heater power allowable for the steam heater 840 is 1500w, the first heater 841 is provided to consume 880w, and the second heater 842 is provided to consume 600w. It may be provided to do so. In this way, 20w can be distributed less considering errors, etc.

Of course, the steam heater 840 may include three or more heaters. For example, it includes the first heater 841, the second heater 842, and the third heater 843, and the first heater 841, the second heater 842, and the third heater 843. The heater 843 may be provided to consume the maximum heater power by dividing it.

Hereinafter, the steam heater 340 will be described based on the fact that it is equipped with the first heater 841 and the second heater 842.

The first heater 841 and the second heater 842 may be formed as a U-shaped metal tube.

The steam heater 840 may include a heater sealer 843 capable of fixing the first heater 841 and the second heater 842 and sealing the heater through hole 8111. It may include a terminal portion 844 that supplies current to the first heater 841 and the second heater 842.

The terminal portion 844 may include a first terminal 844a that supplies current to the first heater 841 and a second terminal 844b that supplies current to the second heater 842.

The first heater 841 and the second heater 842 may be arranged at the same height. Accordingly, the first heater 841 and the second heater 842 may be provided to generate steam by heating water at the same level.

Accordingly, the control unit 700 can adjust the amount of steam generated and the amount of power consumed by using both or selectively the first heater 841 and the second heater 842.

Figure 11 shows the inside of the steam generator.

The steam generator 810 stores water therein and may be provided with a heating space 817 that accommodates a steam heater 840.

Additionally, the steam generator 810 can receive water to generate steam through a water supply hose 8151 connected to the water supply pipe 815.

Meanwhile, steam generated by driving the steam heater 840 in the steam generator 810 may be discharged to the outside of the steam supply unit 800 along the steam hose 8131 through the steam discharge pipe 813.

The steam hose 8131 may communicate with the steam hole 233 of the inner case 200.

Meanwhile, the steam generator 810 may be provided with a separation partition 812 that can separate the heating space 817 and the water level sensor 850. That is, the separation partition 812 may be provided to separate the steam heater 840 and the water level sensor 850, and may be disposed to be biased toward one side of the case body 811.

The water level sensor 850 may be disposed between the separation partition wall 812 and the inner surface of the case body 811.

As a result, it is possible to prevent water vibration generated when the water boils from being transmitted to the water level sensor 850, and to prevent heat generated from the steam heater 840 from being directly transmitted to the water level sensor 850. can do.

Figure 12 shows a steam supply unit where the steam heater is installed.

Referring to FIG. 12(a), the steam sensor 860 may be disposed above the steam heater 840 and may be provided to sense the temperature inside the steam generator 810. Accordingly, the steam sensor 860 can detect that steam is generated when the water reaches 100 degrees or a high temperature.

The steam heater 840 is supported by the support clip 832 to prevent the steam heater 840 from contacting the bottom surface of the steam generator 810, etc.

In addition, the upper part is surrounded by the fixing clip 831 to prevent the water level at which the steam heater 840 is placed from changing.

Referring to FIG. 12(b), the heater sealer 844 of the steam heater 840 has a first support hole 8441 through which the first heater 841 is supported and the second heater 842 penetrates. A second support hole 8442 supported by this may be provided.

The first support hole 8441 has a first length L1 spaced apart from the bottom surface of the steam generator 810, and the second support hole 8442 has a length spaced apart from the bottom surface of the steam generator 810. 2Lengths (L2) may be equal to each other.

Even though the diameters of the first support hole 8441 and the second support hole 8442 are different, the installation height may be the same.

Accordingly, the first heater 841 and the second heater 842 can generate steam by heating water at the same level.

Figure 13 shows in detail the steam supply structure of the laundry treatment device of the present invention.

Steam generated inside the steam generator 810 can be directly supplied into the inner case 200 through the steam pipe 813.

However, if steam is directly supplied into the inner case 200 through the steam pipe 813, there is a risk that water contained in the steam generator 810 will also be supplied into the inner case 200.

In addition, there is a risk that water heated in the steam generator 810 heats the bottom surface of the inner case 200, causing thermal damage to the inner case 200.

To prevent this, the steam supply unit 800 of the present invention may further include a steam nozzle 900 that receives steam generated from the steam generator 810 and supplies it to the inner case 200.

The steam nozzle 900 may be arranged to be spaced apart from the steam generator 810, and may be provided to receive only the steam formed in the steam generator 810 and not to receive water contained in the steam generator 810. there is.

For example, the steam nozzle 900 may be placed above the steam generator 810 and connected to the steam pipe 813. Accordingly, the steam generated in the steam generator 810 rises due to the density difference and is supplied to the steam nozzle 900 along the steam pipe 813, and the water contained in the steam generator 810 is moved by gravity. It may not flow into the steam pipe 813 or the steam nozzle 900.

The steam nozzle 900 may be disposed between the bottom surface of the inner case 200 and the steam generator 810, and may be provided to communicate with the steam hole 233.

Meanwhile, the steam supply unit 800 of the present invention is provided to generate steam by receiving water from the water tank 30.

To this end, the clothing treatment device of the present invention may further include a water pump (880) that supplies water contained in the water tank (30) to the steam supply unit (800).

The steam supply unit 800 may further include a supply pipe 890 capable of guiding the water contained in the water tank 30 to the water pump 880.

In addition, the laundry treatment apparatus of the present invention may further include a water supply pipe 815 that guides the water discharged from the water pump 880 to the steam supply unit 800. The water supply pipe 815 may be provided in the form of a rubber-like water supply hose 8151.

As a result, the water pump 880 can be provided to receive water from the supply pipe 890 connected to the water tank 30. Additionally, the water pump 880 may be equipped to discharge water to supply water to the steam supply unit 800 through the water supply pipe 881.

The steam supply unit 800 can be viewed as including a water pump 880 that provides power to supply water contained in the water tank 30 to the steam generator 810.

The supply pipe 890 may be provided as a hose connecting the water tank 30 and the water pump 880, and the water supply pipe 881 may be provided as a hose coupled to the water pump 880. .

Meanwhile, the water supply pipe 815 may be provided to directly connect the water pump 880 and the steam generator 810. As a result, the water supplied from the water pump 880 can be directly supplied to the steam generator 810 and heated by the steam heater 840 to generate steam. The steam may be supplied to the steam nozzle 900 through the steam pipe 813 and delivered to the inner case 200.

However, as shown in FIG. 15, the water supply pipe 815 may be provided to directly connect the water pump 880 and the steam nozzle 900.

In other words, the laundry treatment apparatus of the present invention may be equipped to supply water contained in the water tank 30 to the steam nozzle 900 rather than the steam generator 810. Water supplied from the water pump 880 may be directly supplied to the steam nozzle 900.

The water pump 880 may not be directly connected to the steam generator 810. It can be seen that the water pump 880 communicates with the steam generator 810 and the steam nozzle 900.

The steam nozzle 900 can receive water contained in the water tank 30 through the water pump 880. The water supplied to the steam nozzle 900 may be delivered to the steam generator 810.

Since the steam nozzle 900 is disposed above the steam generator 810, water supplied to the steam nozzle 900 can be automatically supplied to the steam generator 810.

As a result, the steam nozzle 900 may be provided to receive water contained in the water tank 30 through the water pump 880 and deliver it to the steam generator 810.

The steam supply unit 900 may further include a recovery pipe 815 connecting the steam nozzle 900 and the steam generator 810. The recovery pipe 815 can supply water temporarily contained by being supplied to the steam nozzle 900 to the steam generator 810.

Accordingly, the steam pipe 813 through which steam flows into the steam nozzle 900 and the return pipe 815 through which water is discharged from the steam nozzle 900 can be provided as separate flow paths.

Accordingly, water supplied from the steam nozzle 900 can be prevented from interfering with the movement of steam supplied from the steam generator 810.

Meanwhile, the recovery pipe 815 may be provided in a U-shape. That is, a portion of the area between the two ends of the recovery pipe 815 may be placed lower in height. As a result, a certain amount of water, like a water trap, may remain in the recovery pipe 815, thereby preventing re-inflow of steam or water supplied from the steam generator 810 through the recovery pipe 815. there is.

The steam pipe 813 may include a steam hose 8131 connecting the steam nozzle 900 and the steam generator 810. The steam hose 8131 may be made of rubber.

The recovery pipe 815 may be provided separately from the steam pipe 813 and may be arranged to be spaced apart from the steam pipe 813. It may include a recovery hose 8151 connecting the steam nozzle 900 and the steam generator 810. The recovery hose 8151 may be made of rubber.

The steam generator 810 can receive and receive water supplied to the steam nozzle 900. Since the steam generator 810 is not directly connected to the water pump 880, there is no possibility that water flowing into the steam generator 810 will flow back to the water pump 880.

In addition, the steam nozzle 900 is disposed above the steam generator 810, and because the steam nozzle 900 is connected to the steam generator 810 and the recovery pipe 815, the steam Water supplied to the nozzle 900 may be automatically supplied to the steam generator 810 by gravity. As a result, the water supplied from the water pump 880 to the steam nozzle 900 is unlikely to flow back to the water pump 880.

As a result, the check valve between the water pump 800 and the steam nozzle 900 or the steam generator 810 can be omitted. Therefore, the water supply pipe 881 may be provided as a single water supply hose. The flow path for supplying water to the steam supply unit 900 can be simplified, and the possibility of water leaking from the flow path can be correspondingly reduced.

Additionally, a large amount of water can be supplied to the steam nozzle 900 through the water pump 800 at considerable pressure. As a result, foreign substances or growing bacteria accumulated in the steam nozzle 900 can be washed away with the water supplied to the steam nozzle 900 and washed down into the steam generator 810. Accordingly, the steam nozzle 900 can always be maintained in a clean state, and the flow of supplied steam can be prevented from being disturbed.

Meanwhile, when the steam supplied from the steam nozzle 900 is condensed, the condensed water may reflow into the steam generator 810 through the recovery pipe 815. That is, the condensed water generated from the steam nozzle 900 can be recovered to the steam generator 810 in the same direction of movement of the water supplied from the water pump 800, and can be recycled as water for generating the steam. Therefore, the laundry treatment apparatus of the present invention can prevent the water level in the water tank 30 from rapidly decreasing and also prevent waste of water.

Figure 14 is a schematic diagram of the flow path structure of the steam supply unit of the present invention.

Water supplied from the water supply pump 880 may be supplied to the steam nozzle 900 along the water supply pipe 881.

The steam nozzle 900 can supply supplied water to the steam generator 810.

The steam generator 810 can receive water through the recovery pipe 815.

When water is heated by the steam heater 840 in the steam generator 810 to generate steam, the steam may be supplied to the steam nozzle 900 along the steam pipe 813.

At this time, the recovery pipe 815 and the steam pipe 813 may be separated from each other and placed in the steam generator 810.

The steam condensed in the steam nozzle 9000 may be re-introduced into the steam generator 810 through the recovery pipe 815.

The steam generator 810 may omit hoses connected to the outside other than the recovery pipe 815 and the steam pipe 813 connected to the steam nozzle 900. That is, since the water pump 880 may not be directly connected to the steam generator 810, the hose connecting the water pump 800 and the steam generator 810 can be omitted.

Accordingly, the laundry treatment device of the present invention only needs to have a water supply pipe 881, a return pipe 815, and a steam pipe 813 as flow passages related to steam, so the passage structure can be simplified.

Additionally, the steam nozzle 900 may be placed above the steam generator 810. Accordingly, all of the water supplied to the steam nozzle 900 can be guided to the steam generator 810 without a separate check valve.

Therefore, when the water supplied from the feed pump 880 is supplied to the steam nozzle 900, all of the water supplied to the steam nozzle 900 is guided to the steam generator 810, so the steam nozzle 900 ), the possibility of water flowing back from the water pump 880 is blocked.

Therefore, the check valve between the water pump 880 and the steam nozzle 900 can be omitted.

Additionally, since the check valve does not need to be installed in the water supply pipe 880, the water supply pipe 880 does not need to be provided in plural pieces and can be provided as a single hose. As a result, not only is the flow path structure more simplified, but installation and repair of the flow path are also simplified, and the possibility of water leaks can be further reduced.

Figure 15 shows the flow path structure of the steam nozzle.

The steam nozzle 900 may receive steam from the steam case 810 or may include a supply container 910 capable of receiving water from the water pump 880.

The supply container 910 may be provided in a case shape with an internal space capable of receiving and receiving water or steam.

The water supply pipe 881 may be connected to the supply container 910 at a higher level than the bottom surface of the supply container 910. For example, the water supply pipe 881 may be coupled to the side of the supply container 910. As a result, the water supplied to the supply container 910 can be prevented from flowing back into the water supply pipe 881.

The water supply pipe 881 may be connected to the supply container 910 at a higher place than the recovery pipe 815. For example, the recovery pipe 815 may be disposed with one end coupled to the bottom surface of the supply container 910 and the other end coupled to the steam generator 810. Accordingly, the water supplied to the water supply pipe 881 can automatically flow into the recovery pipe 815.

Additionally, the recovery pipe 815 may be provided in a U-shape to accommodate a certain amount of water therein.

Meanwhile, the recovery pipe 815 may be placed adjacent to the water supply pipe 881. Accordingly, the water supplied to the water supply pipe 811 can quickly flow into the steam case 810 without remaining in the supply container 810.

Meanwhile, one end of the steam pipe 813 may be coupled to the lower part of the supply container 910, and the other end may be coupled to the top of the steam generator 810 or the steam cover 820. Accordingly, the steam generated from the steam generator 810 can be automatically supplied to the supply container 910 due to the density difference.

The steam pipe 813 may be connected to a higher position in the supply container 910 than the recovery pipe 815. Additionally, the steam pipe 813 may be disposed farther from the water supply pipe 881 than the return pipe 815.

As a result, more water supplied to the supply container 910 can be supplied to the recovery pipe 815 without flowing back into the steam pipe 813.

The steam pipe 813 may be coupled to the bottom of the supply container 910.

The bottom surface of the supply container 910 may have a lower portion where the recovery pipe 815 is connected and a higher portion where the steam pipe 813 is connected. For this purpose, a step may be formed on the bottom of the supply container 910 or it may be provided at an angle.

The steam nozzle 900 may further include a container cover 920 coupled to the upper part of the supply container 910. The container cover 920 may include a steam injection hole 923 provided through the upper portion. The steam injection hole 923 may be provided to communicate with the interior of the inner case 200.

The supply container 910 may be provided in the form of a box with an open top, and the container cover 920 may be provided to shield the top of the supply container 910.

Steam supplied through the steam pipe 813 may be discharged through the steam injection hole 923 and supplied into the inner case 200.

The steam pipe 813 may be disposed between the steam injection hole 932 and the inner surface of the supply container 910. The steam injection hole 932 may be disposed between the water supply pipe 881 and the steam pipe 813, and may be disposed between the return pipe 815 and the steam pipe 813. As a result, the condensed steam that cannot be discharged through the steam injection hole 932 can be discharged into the recovery pipe 815 without remaining inside the supply container 910.

The steam injection hole 932 may be located at the center of the container cover 920 based on the width direction.

The container cover 920 may be coupled to the supply container 910 by hook coupling or the like. Accordingly, a separate fastening member that couples the container cover 920 and the supply container 910 can be omitted.

Meanwhile, since the supply container 910 is provided with an open top, it may be advantageous to install various shapes or structures therein, and the container cover 920 may be advantageous for installing various structures at the bottom.

Based on the steam injection hole 932, the water supply pipe 881 and the recovery pipe 815 are disposed on one side of the supply container 910, and the steam pipe 813 is located on the other side of the supply container 910. is placed in

That is, the water supply pipe 881 and the recovery pipe 815 are disposed adjacent to each other, and the steam pipe 813 may be disposed farther from the water supply pipe 881 than the recovery pipe 815.

Accordingly, water moving to the water supply pipe 881 can be supplied to the supply container 910 along the I direction. The water supplied to the supply container 910 can be immediately discharged along the II direction to the recovery pipe 815 and supplied to the steam generator 810. Steam supplied from the steam pipe 813 may be supplied to the supply container 910 along the III direction and discharged through the steam injection hole 932, and the condensed water may be discharged into the recovery pipe 815 along the II direction. It can be discharged and re-supplied to the steam generator 810.

Hereinafter, an embodiment of the moving hanger 1000 will be described in detail.

The moving hanger 1000 may be provided to move linearly back and forth inside the inner case 200. As a result, the clothing can move back and forth in a straight line inside the inner case 200 and shake.

The moving hanger 1000 may be provided to periodically shake clothing at various frequencies.

For example, the moving hanger 1000 may be provided in a structure similar to Korean Patent Publication No. 10-1285890.

Additionally, the moving hanger 1000 may be provided to shake the clothing while reciprocating and rotating the clothing inside the inner case.

That is, in the clothing handling apparatus of the present invention, the moving hanger 1000 may be provided in any structure as long as the clothing can be shaken in the inner case.

Hereinafter, a structure in which the moving hanger 1000 reciprocates and rotates the clothing will be described.

Figure 16 shows the upper structure of the inner case of the laundry treatment device of the present invention.

The moving hanger 1000 of the laundry treatment device of the present invention may include a power transmission unit 1400 disposed on the upper part of the inner case 200 and provided to shake the hanger 1900.

A hanger 1700 on which the hanger 1900 can be seated or mounted may be provided below the power transmission unit 1400.

Accordingly, when the power transmission unit 1400 moves, the hanger 1700 moves, and the hanger 1900 mounted on the hanger 1700 shakes, resulting in the effect of shaking off the clothes.

The power transmission unit 1400 may be provided in plural numbers, and the hanging parts 1700 coupled to the power transmission unit 1400 may also be provided in plural numbers. As a result, a large amount of clothing corresponding to the power transmission unit 1400 can be refreshed by being placed inside the inner case 200.

The moving hanger 1000 may further include a driving unit 1200 that provides power to move the power transmission unit 1400.

The driving unit 1200 may be provided to be exposed inside the inner case 200 as long as it can transmit power to the power transmission unit 1400. However, since the drive unit 1200 is provided to operate by receiving electric energy, it is desirable to block exposure to steam or hot air.

Accordingly, the driving unit 1200 may be disposed between the upper surface of the inner case 200 and the cabinet 100 and may be prevented from being exposed to the receiving space 220.

The power transmission unit 1400 may receive power from the driving unit 1200 through the inner case 200 and transmit it to the hanging unit 1700.

The power transmission unit 1400 may penetrate the upper surface of the inner case 200 and extend into the receiving space 220. The lower end of the power transmission unit 1400 may be exposed to the receiving space 220, and the upper end of the power transmission unit 1400 may be exposed above the inner case 200.

The power transmission unit 1400 may be provided in a rod shape, tube shape, or plate shape, etc., where the length is longer than the thickness.

Meanwhile, the upper surface of the inner case 200 can support the loads of the power transmission unit 1400 and the driving unit 1200. Clothing is mounted and moved on the power transmission unit 1400, and the load of the driving unit 1200 is relatively heavy. Therefore, in order to stably install the moving hanger 1000 on the upper surface of the inner case 200, the laundry treatment device 1 of the present invention may further include a support portion 1800.

The support part 1800 is disposed on the upper part of the inner case 200 and may be coupled to and supported by the cabinet 100. The support portion 1800 may be made of a metal material that is durable and difficult to deform.

The power transmission unit 1400 and the driving unit 1200 may be seated on the support unit 1800 and placed on the upper part of the inner case 200. The power transmission unit 1400 may extend into the receiving space 220 through the support unit 1800.

Meanwhile, the driving unit 1200 includes a motor that rotates a rotation shaft. The driving unit 1200 may be provided to move the power transmission unit 1400 with power to rotate the rotation shaft.

However, it may be difficult to shake the power transmission unit 1400 with sufficient displacement just by rotating the rotation shaft in place.

Therefore, the moving hanger 1000 may further include a displacement generator 1300 that is coupled to the rotation shaft rotated by the motor and generates sufficient displacement (amount of change in position) to enable the power transmission unit 1400 to move. You can.

The displacement generating unit 1300 may be connected or coupled to the driving unit 1200.

For example, the displacement generating unit (1300) may be provided to transmit the power of the driving unit (1200) to the power transmission unit (1400).

The displacement generator 1300 may include an eccentric shaft that rotates along a trajectory larger than the diameter of the rotation shaft. The eccentric shaft may be directly coupled to the rotation shaft of the drive unit 1200, or may be eccentrically coupled or extended to the power shaft 1240 rotated by the rotation shaft.

The displacement generating unit 1300 may be provided in any configuration as long as it can generate a displacement that causes the power transmission unit 1400 to move back and forth over a certain range. The detailed structure is described later.

When the driving unit 1200 operates, the power generated from the rotation shaft generates the displacement of the displacement generating unit 1300, and the power transmission unit 1400 can move according to the displacement of the displacement generating unit 1300. .

The displacement generating unit 1300 can directly move the power transmission unit 1400, but can also move the power transmission unit 1400 through an additional configuration.

The moving hanger 1000 of the present invention may be provided to reciprocate the power transmission unit 1400.

Additionally, the moving hanger 1000 of the present invention may be provided to rotate the power transmission unit 1400. Specifically, the moving hanger 1000 may be provided to reciprocate and rotate the power transmission unit 1400 in a certain angular range rather than reciprocating in a straight line.

The power transmission unit 1400 may be provided to rotate clockwise or counterclockwise in a fixed position, and clothing mounted on the power transmission unit 1400 may also rotate clockwise or counterclockwise. The power transmission unit 1400 is provided to rotate by the moving hanger 1000, but its position may vary to the left or right and may not move.

Even if clothing rotates inside the inner case 200 due to the power transmission unit 1400, movement of the center of gravity within the inner case 200 may be restricted. Therefore, even when the moving hanger 1000 operates, vibration occurring inside the inner case 200 can be drastically reduced, and noise generation can be minimized.

To this end, the moving hanger 1000 includes a reciprocating rotation unit 1500 that converts the continuous rotational energy generated by the driving unit 1200 or the displacement generating unit 1300 into a reciprocating rotation movement of the power transmission unit 1400. may further include.

The reciprocating rotation unit 1500 may be provided to connect the displacement generating unit 1300 and the power transmission unit 1400 to each other. The reciprocating rotating unit 1500 may be provided to connect the displacement generating unit 1300 and the power transmission unit 1400 to each other at an upper level than the inner case 200. The reciprocating and rotating unit 1500 is prevented from being exposed to the receiving space 220, thereby preventing the clothing from being damaged by the reciprocating and rotating unit 1500.

Meanwhile, the moving hanger 1000 may be provided to reciprocate and rotate only one of the plurality of power transmission units 1400.

However, if only one power transmission unit 1400 rotates, clothing mounted on the rotating power transmission unit may collide with clothing mounted on the other power transmission unit 1400 and be damaged. Additionally, there is a risk that the impact may be transmitted to the moving hanger 1000 and the moving hanger 1000 may be damaged.

Therefore, it is preferable that the moving hanger 1000 is provided to rotate all of the plurality of power transmission units 1400.

The moving hanger 1000 can rotate the plurality of power transmission units 1400 as one unit. The moving hanger 1400 may be provided to rotate a plurality of power transmission units 1400 at the same time at the same angle. As a result, the laundry treatment apparatus of the present invention can prevent the power transmission units 1400 from colliding with each other.

It may be advantageous for the power generated by the driving unit 1200 to be directly transmitted to the plurality of power transmission units 1400 to rotate all the power transmission units 1400.

However, if the driving unit 1200 is provided to directly transmit power to each power transmission unit 1400, the structure connecting the driving unit 1200 and all power transmission units 1400 may become complicated.

In addition, if the driving unit 1200 is provided in plurality, or if the driving unit 1200 is provided with a plurality of components connecting all power transmission units 1400, excessive damage to the inner case 200 or the support unit 1800 may occur. Loads may be added. Additionally, the inconvenience of having to control a plurality of driving units 1200 may also result.

In addition, when the displacement generating unit 1300 and the reciprocating rotation unit 1500 are connected to transmit power transmitted from one driving unit 1200 to all power transmitting units 1400, the displacement generating unit 1300 and The arrangement and structure of the reciprocating rotary unit 1500 may become complicated, resulting in reduced reliability.

Therefore, the moving hanger 1000 may be equipped so that one driving unit 1200 generates power to rotate the plurality of power transmission units 1400.

In addition, the moving hanger 1000 preferentially transmits the power generated by the driving unit 1200 to some of the power transmission units 1400 or some of the reciprocating rotation units 1500, and to the remaining power transmission units 1400 or the remaining power transmission units 1400. The reciprocating rotary unit 1500 may be provided to secondarily receive the power.

For example, the reciprocating rotation unit 1500 may be provided to receive power transmitted from the driving unit 1200 or the displacement generating unit 1300 and transmit it to a portion of the power transmission unit 1400. That is, the moving hanger 1000 is equipped to centrally transmit the power generated by the driving unit 1200 to one reciprocating rotating unit 1500, so that the power transmission structure can be designed simply and power loss can be minimized. You can.

The moving hanger 1000 of the present invention is equipped to transmit the power transmitted from the driving unit 1200 to one reciprocating rotating unit 1500 to rotate a specific power transmission unit 1400 connected to the reciprocating rotating unit 1500. It can be.

In addition, the moving hanger 1000 may further include a connection part 1600 provided to transmit power transmitted to a specific power transmission unit 1400 to another power transmission unit 1400.

For example, the connection unit 1600 may be provided to connect a plurality of power transmission units 1400 to each other. Accordingly, when one power transmission unit 1400 rotates, the connection unit 1600 can rotate all of the plurality of power transmission units 1400.

Figure 17 shows how the moving hanger of the present invention operates.

Referring to Figure 17(a), the power transmission unit 1400 can rotate to the right by the reciprocating rotation unit 1500 when the driving unit 1200 operates. At this time, all power transmission units 1400 connected to the connection unit 1600 can also rotate to the right.

Referring to Figure 17(b), the power transmission unit 1400 can rotate to the left by the reciprocating rotation unit 1500 when the driving unit 1200 operates further. At this time, the power transmission units 1400 connected to the connection unit 1600 may also rotate to the left.

As this process is repeated, the power transmission unit 1400 can rotate left and right.

At this time, the power transmission unit 1400 may be provided to rotate left and right while being fixed in a fixed position. The power transmission unit 1400 may be fixed to the support unit 1800 so that there is no change in position back and forth and left and right when rotating.

The power transmission unit 1400 may be fixed so that its position does not move in the vertical, forward, and horizontal directions.

However, the power transmission unit 1400 may be provided to rotate left and right using the vertical or height direction in which the power transmission unit extends as a rotation axis. As a result, when the driving unit 1200 is driven, the hanging unit 1700 rotates left and right around the power transmission unit 1400 as an axis, and there may be no positional movement.

Referring to Figure 17(c), the hanger 1900 may include a ring portion 1910 mounted on the hanger 1700 and a seating portion 1900 coupled to the ring portion 1910. . The surface of the seating portion 1950 may be provided with a surface portion 950 that prevents clothing from slipping.

The seating portion 1950 may be provided symmetrically left and right with the ring portion 1910 as the center. The clothes hanger 1900 may be mounted on the hanger 1700 so that the seating portion 1950 is arranged in the front-to-back direction.

When the power transmission unit 1400 rotates to the left, the hanger unit 1900 rotates to the left on the left side of the seating unit 1950 with respect to the ring unit 1910, and the right side of the seating unit 1950 rotates to the left. You can turn to the right. At this time, the angle (I) at which the left side of the seat 1950 rotates is equal to the angle (theta) at which the right side of the seat 1950 rotates, and the distance that the left side of the seat 1950 moves is The distance that the right side of the seating portion 1950 moves may be the same.

As a result, the weight and force moving to the left with respect to the hanger unit 1900 are the same as the weight and force moving to the right, so they may cancel each other out.

Likewise, even if the power transmission unit 1400 rotates to the right, as a result, the weight and force moving to the left with respect to the hanger unit 1900 will be the same and cancel each other out.

As a result, even if the power transmission unit 1400 rotates, the forces applied to the hanger unit 1900 can cancel each other out, and as a result, the vibration force, exciting force, or inertial force generated in the hanger unit 1900 itself is minimized. It can be. As a result, the inertial force generated from the plurality of power transmission units 1400 can be minimized, thereby minimizing vibration or noise generated throughout the moving hanger 1000, and preventing vibration or noise from occurring throughout the clothing processing device 1. There can be a sharp decline.

As a result, even if the driving unit 1200 rotates at maximum output, vibration occurring in the moving hanger 1000 or the entire laundry treatment device 1 may not occur significantly.

Instead, each of the surfaces of the clothes mounted on the hanger 1900 is shaken by rotating left and right, so a large hair removal force can be secured.

As described above, the power transmission unit 1400 may be provided to penetrate the inner case 200 and may be provided to receive the power and rotate back and forth clockwise and counterclockwise. As a result, the power transmission unit 1400 can reciprocate left and right at the top of the inner case 200 with its position fixed. The power transmission unit 1400 is fixed so that its position does not change up, down, left and right. In addition, not only the upper part of the power transmission unit 1400 but also the lower part is fixed so that the position does not change up, down, left, and right.

That is, the power transmission unit 1400 may be provided to reciprocate at a certain angle in less than one rotation while the rotation center is fixed.

As a result, no matter how fast the power transmission unit 1400 rotates, the position of the hanger unit 1900 is fixed and one end rotates or moves to one side and the other end moves to the other side, so the power transmitted to the power transmission unit 1400 Force and vibration can cancel each other out.

Accordingly, vibration and noise generated by the power transmission unit 1400, the hanger 1700, and the clothes hanger 1900 inside the inner case 200 can be minimized.

As a result, the laundry treatment device of the present invention can rotate the drive unit 1200 at a higher rpm to reciprocate the power transmission unit 1400 at a faster frequency. As a result, the clothing treatment device of the present invention can shake the clothing more strongly.

In addition, the moving hanger 1000 of the present invention has a power transmission unit 1400 that rotates clockwise or counterclockwise in place. Therefore, as described above, no matter how fast the hanger unit 900 rotates, vibration or inertial force generated from the hanger unit 1900 and clothing may cancel each other out when transmitted to the power transmission unit 1400.

As a result, the moving hanger 1000 of the present invention may not be damaged even if the driving unit 1200 is raised above a certain RPM, and vibration or noise exceeding the limit value may not be generated in the laundry treatment device. may be blocked.

Therefore, the laundry processing device of the present invention can drive the driving unit 1200 faster than a clothing processing device using a conventional moving hanger, and drive the power transmission unit 1400 at a faster frequency to shake the clothes more strongly. there is.

As a result, the clothing treatment device of the present invention can more reliably remove foreign substances from clothing through the moving hanger 1000 and remove wrinkles from clothing more effectively. Additionally, the clothing treatment device of the present invention can stimulate the clothing more quickly and expose it to more of the supplied steam.

In addition, the laundry treatment device of the present invention can freely adjust the RPM of the drive unit 1200, and adjust the drive frequency or drive cycle of the power transmission unit 1400 to suit the course.

Figure 18 shows an embodiment of the moving hanger 1000 of the present invention.

The moving hanger 1000 of the present invention transmits the power of the driving unit 1200 to only one of the plurality of power transmission units 1400, and transmits the power transmitted to the specific power transmission unit 1400 through the connection unit 1600. It may be provided to transmit to the remaining power transmission unit 1400.

The displacement generating unit 1300 or the reciprocating rotation unit 1500 may be provided to intensively transmit the power generated by one driving unit 1200 to one power transmission unit 1400. The connection unit 1600 can transmit power transmitted to a specific power transmission unit 1400 to all power transmission units 1400.

The connection part 1600 may be provided as a rigid body so that its length does not vary, and may be provided to connect all power transmission units 1400.

Accordingly, all power transmission units 1400 can rotate simultaneously in the same direction and at the same angle when the connection unit 1600 moves. As a result, the moving hanger 1000 of the present invention can reciprocate and rotate a plurality of power transmission units 1400 at the same angle at the same time or at the same time with one driving unit 1200.

The moving hanger 1000 is fixed to the upper part of the inner case 200 and is coupled to a driving unit 1200 that provides power to move the power transmission unit, and a plurality of power transmission units 1400 to provide the driving unit 1200. It may include a plurality of reciprocating rotating parts 1500 that receive the power and rotate so that the rotation direction changes repeatedly, and a connecting part 1600 provided to connect the plurality of reciprocating rotating parts to each other.

The connection part 1600 may include a link bar that connects the plurality of reciprocating rotating parts 1500 and rotates the plurality of reciprocating rotating parts 1500 as one unit.

The connection portion 1600 may be provided in single pieces.

The connection part 1600 may be provided to connect all of the power transmission parts 1400.

However, if the connection part 1600 is provided to connect the reciprocating transmission parts 1500, the connection part 1600 can be installed higher than the support part 1800, preventing it from being exposed inside the inner case 200. It can be prevented.

The connection part 1600 is coupled to either the front or rear of the reciprocating rotating part 1500, and at least one of the displacement generating part 1300 and the driving part 1200 is connected to the front or rear of the reciprocating rotating part 1500. It can be placed in one of the others. Accordingly, the connection part 1600 can be prevented from interfering with the driving part 1200.

The connection part 1600 may be provided to reciprocate in the width direction of the inner case 200 and rotate the plurality of reciprocating rotating parts 1500.

The driving unit 1200 includes a motor 1210 that rotates the rotation shaft 1210, a power shaft 1240 that rotates together when the rotation shaft 1210 rotates, and the power shaft 1240 and the rotation shaft 1210. ) may be connected to a transmission unit 1230 that transmits the rotational force of the rotation shaft 1210 to the power shaft 1240.

The motor 1210 may be fixed to the upper part of the inner case 200 and may be provided to rotate the rotation shaft 1220. However, the rotation shaft 1220 is provided to rotate at a speed that is too fast than the appropriate cycle for reciprocating the power transmission unit 1400 in the motor 1210. Considering this, if the RPM of the rotation shaft is lowered, there is a risk that the output of the motor 1210 may not be transmitted to the power transmission unit 1400.

To solve this problem, the transmission unit 1230 may be provided to transmit the output of the rotation shaft 1220 to the power transmission unit 1400 as is, while lowering the RPM of the rotation shaft 1220.

The transmission unit 1230 is connected to the rotation shaft 1220 to rotate, and has a larger diameter than the rotation shaft 1220 so that it can rotate. Accordingly, the transmission unit 1230 may be provided to transmit the torque of the rotation shaft 1220 while rotating slower than the RPM of the rotation shaft 1220.

The power shaft 1240 may be provided to rotate by the transmission unit 1230, is provided separately from the rotation shaft 1230, and is configured to directly transmit power to the power transmission unit 1400.

The reciprocating rotation unit 1500 may be coupled to the power transmission unit 1400 and be rotatable together with the power transmission unit 1400.

The reciprocating rotation unit 1500 may include a reciprocating lever 1510 that is coupled to the upper part of the power transmission unit 1400 and rotates the power transmission unit 1400.

The reciprocating lever 1510 may have a rib or bar shape whose rotation center is coupled to the support shaft 1410.

The reciprocating lever 1510 may be coupled to the upper end of each of the plurality of power transmission units 1400, and some of the reciprocating levers 1510 are connected to the transmission unit 1230 to provide power to the motor 1210. It can be prepared to be delivered.

The reciprocating lever 1510 may be provided to reciprocate at a certain angle when the transmission unit 1230 is rotated by the motor 1210. The power transmission unit 1400 may be coupled to the rotation center of the reciprocating lever 510 and rotated together with the reciprocating lever 1510.

A plurality of reciprocating levers 1510 may be connected and arranged by a connection portion 1600.

The connection portion 1600 may be provided to connect one end of a plurality of reciprocating levers 1510.

Accordingly, when any one of the plurality of reciprocating levers 1510 rotates, the connection part 1600 moves so that the plurality of reciprocating levers 1510 can rotate simultaneously and at the same time.

The power transmission unit 1400 and the reciprocating lever 1510 may be supported on the support unit 1800. Additionally, the motor 1210 and the transmission unit 1230 may also be supported on the support unit 1800.

Figure 19 shows the moving hanger 1000 of the present invention separated from the inner case 200.

The power transmission unit 1400 may be provided extending from the top to the bottom of the inner case, and the hook 1700 may be coupled to the lower part of the power transmission unit 1400.

The reciprocating rotation unit 1500 can be coupled to each power transmission unit 1400, and can be easily connected to the driving unit 1200 by being coupled to the upper part of the power transmission unit 1400.

The power transmission unit 1400 and the reciprocating rotation unit 1500 are provided in plural pieces and are arranged at a certain distance apart along the width direction of the inner case.

The connecting portion 1600 is provided to connect the plurality of power transmission portions 1400 or the plurality of reciprocating rotating portions 1500 to each other. Accordingly, the connection unit 1600 may be provided to rotate all of the plurality of power transmission units 1400 or the plurality of reciprocating rotation units 1500 simultaneously.

The power transmission unit 1400 may include a support shaft 1410 that penetrates the upper part of the inner case 200 and is coupled to the reciprocating lever 1510.

The support shaft 1410 may penetrate the support part 1800 and be exposed to the upper part of the support part 1800 or the upper part of the inner case 200.

The power transmission unit 1400 may include an auxiliary support unit 1420 coupled to the support shaft 1410 and exposed to the receiving space. The auxiliary support part 1420 is provided in the shape of a bar and can be fixed by combining a hook part 1700 at the bottom.

The auxiliary support part 1420 may be fixed to the support shaft 1410 and rotate together with the support shaft 1410. Accordingly, when the support shaft 1410 rotates by the reciprocating lever 1510, the auxiliary support portion 1420 coupled to the support shaft 1410 also rotates, so that the hanger 1700 can also rotate left and right. .

The reciprocating lever 1510 includes a main lever 1511 that receives power directly from the driving unit 1200 and reciprocates, and an auxiliary lever 1512 that receives power from the main lever 1511 through a connection part 1600. It can be included.

The main lever 1511 may be provided as a single unit to directly receive power from the driving unit 1200.

In the driving unit 1200, the motor 1210 may include a vertical motor 1211 coupled to the support unit 1800 and a vertical rotation shaft 1221 rotated by the vertical motor 1211.

The transmission unit 1230 is coupled to the vertical rotation shaft 1221 and rotates with the vertical rotation shaft 1221, and a power pulley 1231 is coupled to the power shaft 1240 to rotate the power shaft 1240. It may include a transmission pulley 1232 and a belt 1233 connecting a portion of the outer peripheral surface of the power pulley 1231 and the transmission pulley 1232.

The transmission unit 1230 may further include a pulley support part 1224 that rotatably supports the power shaft 1240 and the transmission pulley 1232. The pulley support part 1224 is provided to support the transmission pulley 1232 to be arranged in parallel with the power pulley 1231, and can be provided by being seated on the support part 1800.

The power shaft 1240 may be provided to transmit power transmitted from the rotation shaft 1220 to one of both ends of the main lever 1511.

The displacement generator 1300 may be coupled to the power shaft 1240 to receive power. Additionally, the displacement generator 1300 is connected to the main lever 1511 and can reciprocate and rotate the main lever 1511 about the support shaft 410.

For example, the displacement generator 1300 may include an eccentric shaft that is eccentrically coupled to the power shaft 1240 and rotates at a constant radius with respect to the rotation center of the power shaft 1240.

The displacement generator 1300 may be connected to the end of the main lever 1511. The displacement generator 1300 may rotate the end of the main lever 1511 around the support shaft 410 while rotating by the power shaft 1240.

The connection part 1600 is a link bar connecting one end of the main lever 1511 that is not connected to the power shaft 1240 or the displacement generator 1300 and one end of the auxiliary lever 1512 ( 1610, bar).

The auxiliary lever 1512 is rotatably coupled to the remaining support shaft 1410 that is not coupled to the main lever 1511, and extends in one direction from the portion coupled to the support shaft 1410 to form the link bar 1610. ) can be provided to be connected to.

The link bar 1610 may be provided in the form of a straight frame connecting one end of the main lever 1511 and one end of the auxiliary levers 1512. At this time, one end of the main lever 1511 and one end of the auxiliary lever 1512 may be arranged parallel to each other based on the link bar 1610 or the width direction.

The link bar 1610 may be provided in a single piece to rotate the main lever 1511 and the auxiliary lever 1512 simultaneously and simultaneously about their respective support axes 1410.

The inner case 200 may be provided with a through hole 230 in which a portion of the support portion 1800 is seated to expose the power transmission portion 1400 to the receiving space 220.

The through hole 230 may be provided on the upper surface 22 of the inner case, and the through hole 230 may be provided along the direction in which the power transmission unit 1400 is disposed.

For example, the power transmission units 1400 may be arranged to be spaced apart from each other along the width direction of the inner case, and the through holes 230 may be arranged along the width direction of the inner case.

The laundry treatment device 1 of the present invention may further include a support frame 120 disposed outside the inner case to support the cabinet 100.

The support frame 120 may be made of a metal material that is disposed at positions corresponding to the corners of the cabinet 100 or the corners of the inner case 200 and maintains the appearance of the clothing treatment device. Both ends of the support portion 1800 are supported by being seated on the support frame 120, thereby preventing unnecessary shock or load from being transmitted to the upper surface 220 of the inner case.

Figure 20 shows the operating method of the moving hanger 1000 of the present invention.

Referring to Figure 20(a), the main lever 1511 may include a main body 15111 coupled to the support shaft 1410 and the connecting bar 1610.

The main body 15111 may include a main center hole 15115 that is coupled to the support shaft 1410 and can rotate the support shaft 1410, and extends from the main center hole 15115 to both sides. It can be provided.

The main body 15111 may be provided with a main receiving hole 15112 that receives power from the driving unit 1200 at one end, and a main transmission hole 15113 on the other end into which the connecting bar 1610 is seated and coupled. It can be included.

The main body 15111 may further include a step portion 15114 extending from the center hole to the main receiving hole 15112 and forming a step. One end of the main body 15111 or the main delivery hole 15113 may be placed lower than the main center hole 15115 due to the step portion 15114.

As a result, the length in which the power shaft 1240 or the eccentric shaft 1310 disposed on the upper part of the main central hole 15115 extends from the transmission unit 1230 can be secured.

Meanwhile, the auxiliary lever 1512 has an auxiliary center hole 15125 coupled to the support shaft 1410, and an auxiliary delivery hole extending to one side from the auxiliary center hole 15125 and coupled to the link bar 1610. It may include an auxiliary body (15121) having (15123).

The auxiliary body 15121 may be provided with a shorter length than the main body 15111.

The distance from the main central hole 15115 to the main delivery hole 15113 may be set to be the same as the distance from the auxiliary central hole 15125 to the auxiliary delivery hole 15123.

The link bar 1610 is seated on the upper part of the auxiliary delivery hole 15123 and the main delivery hole 15113 and can connect the auxiliary lever 1512 and the main lever 1511 to each other.

Referring to Figure 20(b), the driving unit 1200 may be provided so that the power shaft 1240 is inserted into the main receiving hole 15112. As a result, the main receiving hole 15112 can be rotated left and right by directly rotating the power shaft 1240.

In other words, sufficient displacement may not be generated to rotate the main receiving hole 15112 left and right with respect to the main center hole 15115 just by rotating the power shaft 1240.

To this end, the displacement generator 1300 may be coupled to the power shaft 1240 to generate a displacement larger than the rotation radius of the power shaft 1240.

The displacement generator 1300 may be provided to convert the in-place rotational motion of the power shaft 1240 into a displacement motion that moves back and forth over a certain range. The displacement motion is transmitted to the reciprocating rotation unit 1500 so that the power transmission unit 1400 can reciprocate.

As described above, the displacement generator 1300 may include the eccentric shaft 1310 that extends from the power shaft 1240 and rotates along a predetermined radius.

The eccentric shaft 1310 has a smaller diameter than the power shaft 1240, and may be coupled to or extended from the power shaft 1240 at a certain distance from the rotation center of the power shaft 1240.

Accordingly, when the power shaft 1240 rotates, the eccentric shaft 1310 can rotate in a circle whose radius is the distance from the power shaft 1240.

The diameter of the eccentric shaft 1310 may be set smaller than the diameter or width of the main receiving hole 15112.

The eccentric shaft 1310 can be inserted and supported in the main receiving hole 15112.

However, the constant radius around which the eccentric shaft 1310 rotates may be set larger than the width or diameter of the main receiving hole 15112. As a result, when the eccentric shaft 1310 rotates, the main receiving hole 15112 is pushed by the eccentric shaft 1310 and can move left and right based on the main center hole 15115.

As a result, when the eccentric shaft 1310 rotates in a specific direction (x), the main receiving hole 15112 of the main body 1511 also rotates along a specific direction (y), and as a result, the center of the main body The hole 15115 also rotates in the same direction as the main receiving hole 15112, and the main delivery hole 15113 can rotate in a direction (z) opposite to the constant direction.

When the eccentric shaft 1310 rotates, the support shaft 1410 reciprocates together with the main center hole 15115 so that the power transmission unit 1400 can reciprocate, and the main transmission hole 15113 also rotates. By reciprocating and moving the link bar 1610, the auxiliary lever 1521 can also reciprocate around the auxiliary center hole 15125 and the support shaft 1410. The power transmission unit 1400 coupled to the auxiliary lever 1521 may also be rotated reciprocally.

The power transmission unit 1400 may be provided with a thread along the circumference of the upper part of the support shaft 1410.

The main transmission hole 15113 and the auxiliary center hole 15125 can be directly coupled and fixed to the support shaft 1410 using threads, etc.

However, in the power transmission unit 1400, the support shaft 1410 passes through the main transmission hole 15113 and the auxiliary center hole 15125, and then connects the support shaft 1410 to the main transmission hole ( 15113) and a transmission coupling portion 1415 coupled to the thread of the support shaft 1410 to be fixed to the auxiliary center hole 15125.

Therefore, the support shaft 1410 and the reciprocating lever 1510 are coupled to each other due to the transmission coupling portion 1415, so that the support shaft 1410 and the reciprocating lever 1510 can rotate simultaneously.

Below, an embodiment in which the control unit 700 of the laundry treatment apparatus of the present invention performs an arbitrary course will be described based on the above configuration.

Figure 21 shows a process in which the clothing treatment apparatus of the present invention performs a clothing treatment course.

In the laundry treatment apparatus of the present invention, the allowable power amount can be set as the maximum amount of power that can be used. The control unit 700 of the laundry treatment apparatus of the present invention can be set to block power supply when it detects that more than the allowable amount of power is being consumed.

The allowable amount of power may be less than the amount of power consumed when the first heater 841, the second heater 842, and the compressor 342 are operated simultaneously. As a result, the laundry treatment apparatus of the present invention is set so that the entire steam heater 840 and the compressor 342 cannot be operated simultaneously.

As a result, the laundry treatment device of the present invention cannot operate the first heater 841 and the second heater 842 simultaneously while the compressor 342 is running, and the first heater 841 and the second heater 842 cannot be operated simultaneously. At the same time, it is set so that the compressor 342 cannot be driven during operation.

Therefore, the laundry treatment apparatus of the present invention can be set so that it is impossible to supply the maximum amount of steam that can be supplied while hot air is supplied inside the inner case.

However, the allowable amount of power may be greater than the amount of power consumed when the first heater 841 and the second heater 842 are operated simultaneously. Additionally, the allowable amount of power may be greater than the amount of power consumed when the first heater 841 and the compressor 342 are operated simultaneously. Additionally, the allowable amount of power may be greater than the amount of power consumed when the second heater 842 and the compressor 342 are operated simultaneously.

As a result, the first heater 841 and the second heater 842 can be driven simultaneously, the first heater 841 and the compressor 342 can be driven simultaneously, and the second heater and The compressors 342 can be driven simultaneously.

Therefore, in the laundry treatment apparatus of the present invention, when the compressor 342 is not driven, the first heater 841 and the second heater 842 are driven simultaneously, thereby supplying the maximum amount of steam that can be supplied inside the inner case.

In addition, in the laundry treatment apparatus of the present invention, one of the first heater 841 and the second heater 842 and the compressor 342 are operated simultaneously to supply the steam into the inner case 200. Hot air can be supplied into the inner case 200, and steam can be supplied into the inner case 200 while supplying hot air.

The laundry treatment apparatus of the present invention initially operates the first heater 841 and the second heater 842 simultaneously to rapidly heat water inside the steam generator 810 to generate steam first. Thereafter, when steam is generated, the laundry treatment apparatus of the present invention operates only one of the first heater 841 and the second heater 842 to maintain the temperature of the water at the boiling point, etc. to continue generating steam. .

However, in this case, after steam is generated, the amount of steam sprayed may be reduced compared to when the first heater 841 and the second heater 842 are driven simultaneously.

The laundry treatment apparatus of the present invention can control the steam supply amount by operating only one of the first heater 841 and the second heater 842. Therefore, a sufficient refresh process can be performed by supplying only a small amount of steam to materials that are vulnerable to moisture and temperature, such as silk or cashmere.

When supplying steam into the inner case, the laundry treatment device of the present invention can use only one of the first heater 841 and the second heater 842, thereby reducing the power consumption required for steam supply.

In addition, the laundry treatment apparatus of the present invention can quickly increase the temperature inside the inner case by operating the compressor 342 together when supplying steam. As a result, the clothing treatment device of the present invention can quickly complete the drying process to remove moisture from wet clothes and the refresh process to sterilize, deodorize, and remove wrinkles from clothes.

Figure 21(a) shows an embodiment of the present laundry treatment device control method.

The laundry treatment apparatus of the present invention includes a steam preparation step (A1) in which water is heated by driving a steam heater when the refresh course or standard course for performing the refresh process is performed, and the water is heated during the steam preparation step (A1). When steam is generated, a steam injection step (A2) of supplying the steam to the clothing can be performed.

In general, the purpose of the refresh process is to supply moisture to clothes in a dry state, so a large amount of steam is sprayed on the clothes.

Therefore, the laundry treatment apparatus of the present invention can simultaneously operate the first heater 841 and the second heater 842 in both the steam preparation step (A1) and the steam injection step (A2).

In the steam preparation step (A1) and the steam injection step (A2), considering the allowable amount of power, the compressor 342 may not be driven.

The clothing treatment apparatus of the present invention performs a waiting step (A3) that provides time for the clothing to be moistened with supplied steam.

When the waiting step (A3) is performed for a certain period of time, the clothing treatment apparatus of the present invention performs a cooling step (A4) in which only the blowing fan is operated by further lowering the surface temperature of the clothes before driving the compressor. The cooling step (A4) can prevent thermal damage to clothing.

When the internal temperature of the inner case 200 decreases and the moisture content of the clothes is sufficient, the clothes treatment device of the present invention performs a drying step (A5) in which one or more of the compressor 342 and the blowing fan 351 is driven. Perform.

Through the drying step (A5), a refreshing process such as deodorizing and removing wrinkles from clothes can be performed while drying the moisture contained in the clothes. The drying step (A5) has the longest duration compared to all previously performed steps.

Meanwhile, since the compressor does not operate in the steam injection step (A2), hot air cannot be supplied. Therefore, until reaching the drying step (A5), the internal temperature of the inner case 200 and the temperature of the refrigerant flowing through the heat supply unit 400 are relatively low temperatures.

Therefore, in the above-described control method, the drying step (A5) must last relatively long to ensure refresh performance, including any one of complete drying, sterilization, deodorization, and wrinkle removal of clothes.

Figure 21(b) shows another embodiment of the laundry treatment device control method of the present invention.

However, as described above, the laundry treatment device of the present invention has a plurality of heaters, so it can operate some of the heaters and the compressor at the same time.

For example, since the steam heater 840 includes a first heater 841 and a second heater 842, either one of the first heater 841 and the second heater 842 and the compressor can be driven simultaneously. there is. Using this, the refresh process can be performed in a different way.

Therefore, the clothing treatment device of the present invention can rapidly increase the temperature inside the inner case 200 before the drying step by operating the heater and the compressor simultaneously before the drying step, thereby completely drying, sterilizing, deodorizing, and removing wrinkles from the clothes. The necessary temperature and time can be secured more quickly.

As a result, the duration of the drying step can be reduced compared to before. Additionally, the duration of the drying step can be set to be the longest in the refresh cycle. By reducing the duration of the drying step, the duration of the entire refresh process can be greatly reduced. Additionally, energy efficiency can be greatly increased by reducing the compressor operation time.

The clothing treatment device of the present invention can perform a steam preparation step (b1) in which all of the steam heaters 840 are operated to supply steam to the clothing when any course for refreshing or managing the clothing is performed. .

In the steam preparation step (b1), the refresh process time can be reduced as the steam is generated faster, so the control unit 700 can drive all heaters of the steam heater 840.

In other words, in the steam preparation step (B1), the control unit 700 can heat water using the maximum power of the steam heater 840.

If the steam heater 840 is composed of the first heater 841 and the second heater 842, the first heater 841 and the second heater 842 can be driven simultaneously to heat water. You can.

When steam is detected inside the steam case 810 through the detection device 860 in the steam preparation step (B1), the laundry treatment device of the present invention performs a preheating step ( B2) can be performed.

That is, after steam is generated in the steam case 810, even if only one of the first heater 841 and the second heater 842 is driven, the steam is continuously generated and the inner case 200 ) can be supplied.

In the preheating step (B2), the control unit 700 may drive only one of the first heater 841 and the second heater 842 to supply the heater 842 to the inner case 200.

Accordingly, the clothing treatment apparatus of the present invention can increase the moisture content of the clothing by increasing the temperature inside the inner case 200 using the steam from the preheating stage B2. In addition, since only a portion of the steam heater 840 is used in the preheating step (B2), extra power can be secured.

In the preheating step (B2), the laundry treatment apparatus of the present invention can drive one or more of the compressor 342 and the blowing fan 351. As a result, hot air can also be supplied into the inner case 200.

As a result, in at least some sections in the preheating step (B2), the compressor 342, the blowing fan 351, and a portion of the steam heater 840 may overlap and operate together.

In the preheating step (B2), either the first heater 841 or the second heater 842 and the compressor 342 may be driven simultaneously. Steam and hot air may be supplied simultaneously inside the inner case 200.

When either the first heater 841 or the second heater 842 and the compressor 342 are driven simultaneously, the temperature inside the inner case 200 can be increased from the beginning of the refresh process, and the evaporator Higher temperature air may be introduced into (341). As a result, the heat exchange performance of the evaporator 341 is enhanced and the condenser 343 can be heated to a higher temperature. Accordingly, hot air of a higher temperature is supplied to the inside of the inner case 200, so that the inside of the inner case 200 can reach the optimal or minimum temperature required for the refresh process more quickly. Therefore, the execution time of the subsequent refresh process can be greatly shortened.

Additionally, the overall coefficient of performance (cop) of the heat supply unit 340 may also be increased.

In the preheating step (B2), at least one of a section in which one of the first heater 841 and the second heater 842 and the compressor 342 are driven simultaneously, and a section in which only the compressor 342 is driven may include.

For example, in the preheating step (B2), there may not only be a section in which the steam heater 840 and the compressor 342 are simultaneously driven, but there may also be a section in which only the compressor 342 is driven.

However, it is preferable that the section in which only the compressor 342 is driven is placed after the section in which the steam heater 840 and the compressor 342 are driven.

This is because it is more advantageous to drive the heat supply unit 340 if air with high heat capacity is supplied to the evaporator 341 before driving the compressor 342. That is, when the steam is supplied to the inner case 200 through the steam heater 840, not only does the temperature inside the inner case 200 rise, but the absolute humidity also increases, creating air with a high heat capacity in the evaporator 341. may be contacted.

Specifically, the preheating step (B2) includes a first section for driving one of the first heater 841 and the second heater 842 and the compressor 342, and the first heater 841 and the compressor 342. It may include a second section in which the operation of the second heater 842 is stopped and only the compressor 342 is operated.

Hot air and steam can be supplied to the inner case 200 through the first section to increase the temperature inside the inner case 200 and the amount of heat of the air flowing into the circulation duct 320.

Through the second section, hot air is supplied to the inside of the inner case 200 in earnest to satisfy the minimum temperature condition for refreshing clothes such as deodorization, wrinkle removal, and sterilization.

In the preheating section B2, the first heater 841 may be driven. As a result, a larger amount of steam is supplied into the inner case 200 than when driving the first heater 841, thereby reducing the temperature inside the inner case 200 and the air flowing into the circulation duct 320. calories can be further increased.

Alternatively, the second heater 841 may be driven in the preheating section B2.

Accordingly, the preheating section B2 can gradually increase the temperature inside the inner case 200 and maintain the increased temperature more stably for a longer period of time. As a result, the time required for sterilization, etc. can be secured.

Additionally, it can prevent clothing from being deformed due to high humidity.

On the other hand, the laundry treatment apparatus of the present invention uses the steam heater ( 840) may be set to stop operation.

In addition, the laundry treatment apparatus of the present invention can be set so that either the first heater 841 or the second heater 842 is repeatedly driven and stopped (ON/OFF) in the preheating section (B2). there is. That is, when the temperature of the refrigerant approaches or exceeds the limit temperature, the control unit 700 can stop the operation of the steam heater 840, and when the temperature of the refrigerant reaches a safe temperature lower than the limit temperature. Re-driving the steam heater 840 can be repeated. In addition, when the internal temperature of the inner case approaches or exceeds the target temperature, the control unit 700 may stop operating the steam heater 840, and the internal temperature may reach a cooling temperature lower than the target temperature. When it reaches this point, operating the steam heater 840 again can be repeated.

Meanwhile, even if the steam heater 840 is driven intermittently, the preheating section B2 aims to quickly increase the internal temperature of the inner case 200, so the first heater 841 and the second heater ( The time for which 842 is driven may be set longer than the time for which the first heater 841 and the second heater 842 are stopped.

The preheating section (B2) may be performed for a predetermined period of time, and may be terminated when the internal temperature of the inner case or the temperature of the refrigerant maintains a predetermined temperature for more than a predetermined period of time.

When the preheating section (B2) is completed, the laundry treatment device of the present invention can perform the steam injection step (B3) of supplying steam to the inside of the inner case 200 in earnest. In the steam injection step (B3), the first heater 841 and the second heater 842 are operated simultaneously to supply a large amount of steam to the inner case 200.

Since the steam spraying step (B3) is performed while the clothing placed in the inner case 200 is heated to a certain level in the preheating step (B2), the moisture content of the entire clothing can be greatly increased.

The steam injection step (B3) may be performed shorter than the steam injection step (A2) without previously performing the preheating step (B2). This is because a certain level of steam has already been supplied in the preheating step (B2), so the amount of steam to be additionally supplied is set to be small.

The steam spraying step (B3) may be terminated when the guaranteed time for sufficiently moistening the clothing has elapsed.

When the steam injection step (B3) is completed, a drying step (B6) of drying the clothes with hot air can be performed. However, when the steam injection step (B3) is completed, a waiting step (B4) may be additionally performed in which the steam sprayed into the inner case 200 waits for a certain period of time to ensure time to penetrate the entire clothing. there is.

The standby stage (B4) may correspond to a state in which the steam heater 840 and the compressor 342 are not driven.

Through the waiting step (B4), it is possible to prevent the steam sprayed inside the inner case from evaporating immediately before being moistened by the clothing, and while the surface temperature of the clothing has risen due to the steam, the surface temperature of the clothing is lowered by additional hot air supply. It can prevent damage from rising rapidly.

The drying step (B6) is a step in which full-fledged hot air is supplied to the inner case 200 by driving the compressor 342. Therefore, if hot air is supplied immediately while the temperature inside the inner case 200 does not fall below the safe temperature, the temperature inside the inner case 200 may rise above the limit temperature and damage the clothing.

Therefore, the cooling step (B5) of driving the blowing fan 352 can be performed before performing the drying step (B6). In the cooling step (B5), the control unit 700 may drive the blowing fan 352, but block the compressor 342 and the steam heater 340 from operating.

In the cooling step (B5), the air inside the inner case 200 may be cooled by circulating along the circulation duct 200.

When the temperature inside the inner case 200 falls below the safe temperature or the cooling step (B5) is performed for the required time, the cooling step (B5) can be ended.

The clothing treatment apparatus of the present invention can perform a drying step (B6) of supplying hot air to the clothing. The drying step (B6) may be performed until the moisture content of the clothes falls below a certain level.

The control unit 700 may recognize that the moisture content is reduced below a certain level by detecting the temperature inside the inner case 200 or the temperature of the refrigerant.

For example, if the moisture content of clothes is high, even if the drying step (B6) is performed, the temperature flowing back into the circulation duct 320 due to the heat of vaporization may not rise, or may not rise sharply even if it rises. .

However, when most of the clothing is dried and the moisture content is below a certain level, the heat of vaporization is small, so the temperature flowing into the circulation duct 320 may rise rapidly, and ultimately may correspond to the temperature of hot air.

This allows the temperature of the refrigerant to move in a similar pattern to the temperature flowing into the circulation duct 320.

When the control unit 700 detects that the moisture content of the clothes is lowered, sufficient drying of the clothes is achieved, and the minimum time required for refreshing has elapsed, the control unit 700 can end the drying step (B6). there is.

Alternatively, the control unit 700 may end the drying step (B6) when the time the clothes are exposed to the minimum drying temperature condition or more reaches the minimum time.

As a result, the laundry treatment apparatus of the present invention further arranges the preheating step (B2) before the drying step (B6), thereby increasing the total time for the temperature inside the inner case 200 to reach the minimum condition temperature or higher, The duration of the drying step (B6) can be greatly reduced.

Meanwhile, in the laundry treatment apparatus of the present invention, after the compressor 342 is driven and stopped in the preheating section (B2), the driving of the compressor 342 is continuously maintained until the drying step (B6) is performed. You can.

Figure 22 shows an embodiment of performing a drying course of the laundry treatment apparatus of the present invention.

When the drying course is performed, a drying cycle may be performed in the order of the first stage or heating stage, the second stage or constant rate stage, the third stage or reduced rate stage, and the fourth stage or cooling stage.

Wet clothing or clothing with a moisture content higher than the removal moisture rate may be placed inside the inner case 200.

Referring to Figure 22(a), when the first step is performed, one or more of the compressor 342 and the blowing fan 352 may be driven. Accordingly, as the refrigerant is heated, the air inside the inner case 200 can also be heated, and as the temperature of the air gradually increases due to the Sungpong fan 352, the inner case 200 and the circulation duct 320 ) can be cycled. During this process, moisture in the clothing may begin to evaporate.

Referring to Figure 22(b), when the first step continues for a certain period of time, high temperature air (hot air) capable of vaporizing moisture in the clothing is supplied to the inner case 200. In this process, more and more moisture contained in the clothing evaporates, allowing more heat of vaporization to be absorbed from the hot air. As a result, despite hot air being supplied inside the inner case 200, the temperature increase rate inside the inner case 200 falls below the reference value, or a constant rate stage in which the temperature inside the inner case 200 is maintained. can be performed.

For example, the above reference value may be set at a rate of increase of 1 degree per minute, but this is only an example, and it may be set at any rate of temperature increase over time as long as the first stage and the second stage can be distinguished.

The control unit 700 may drive the moving hanger 1000 in the second step. The hanger unit 1900 mounted on the moving hanger 1000 may move back and forth or vibrate. Thereby, the removal physical force condition can be achieved in the constant rate step.

In the second step, the moisture content of the clothing gradually decreases from 100 percent, so that the moisture removal rate can be reached. However, in the second step, the moisture contained in the clothing evaporates and continuously absorbs heat of vaporization from the air inside the inner case 200, so the temperature inside the inner case 200 is lower than the set temperature.

Referring to Figure 22(c), if the second step is performed for more than a certain period of time, the moisture content of the clothing becomes lower than the removal moisture rate. From this point on, the amount of moisture evaporating from the clothing rapidly decreases, so the heat of vaporization absorbed from the air inside the inner case 200 also decreases. As a result, a third step in which the temperature increase rate inside the inner case 200 increases above the reference value can be performed.

When the third step begins, the temperature inside the inner case 200 reaches the set temperature or higher. Specifically, in the third step, the temperature inside the inner case 200 may reach a drying temperature higher than the set temperature.

For example, the drying temperature may be set to 50 degrees or higher.

In addition, when the third step is performed, the clothes are almost completely dried, so the moisture content of the clothes drops to less than 5%, which is much lower than the removal moisture rate.

If the third step is performed for more than a certain period of time, the control unit 700 can complete the drying process. The control unit 700 stops driving the compressor 342 and operates the fourth blower fan 352 until the temperature inside the inner case 200 falls below a safe temperature lower than the set temperature. You can follow the steps.

The safe temperature may correspond to room temperature. For example, the safe temperature may be set to 25 degrees.

Referring to Figure 22(d), the control unit 700 may additionally perform a removal step to remove creases and wrinkles from clothing.

Steam can be supplied into the inner case 200 by driving the steam heater 840. Accordingly, the moisture content of the clothing inside the inner case 200 may increase back to the removed moisture content.

Additionally, the control unit 700 may drive the moving hanger 1000 to apply a removal physical force to the clothing.

As a result, in the removal step, the control unit 700 can simultaneously operate the steam heater 840 and the moving hanger 1000 to remove creases and wrinkles from the clothing.

Since the removal step is additionally performed after the fourth step, the internal temperature of the inner case 200 may be higher than the set temperature. Therefore, in the removal step, the control unit 700 can stop driving the compressor.

When the removal step is performed, a cooling step may be performed to lower the internal temperature of the inner case 200 to a safe temperature lower than the set temperature. In the cooling step, the blowing fan 352 can be driven, and the steam heater 840 and the compressor 342 can be blocked from driving.

Meanwhile, the compressor 342 may be restarted to dry the moisture supplied from the steam heater 840 in either the removal step or the cooling step.

As a result, the clothing treatment apparatus of the present invention can completely dry the clothing up to the fourth step and then additionally perform the removal step to remove creases and wrinkles from the clothing.

Figure 23 shows the progress of the drying process in Figure 22.

Referring to Figures 23(a) and 23(b), when the drying course is performed, the compressor 342 can start driving, and the driving of the compressor 342 is stopped until the drying course is completed. It can be maintained without failing.

Additionally, when the compressor 342 is driven, the blowing fan 352 may also be driven simultaneously.

As a result, hot air can be continuously supplied to the inner case 200 while the drying course is performed.

When the compressor 342 starts operating, the first step may be performed in which the temperature inside the inner case 200 gradually increases until the temperature of the refrigerant increases.

Afterwards, when the heating of the refrigerant is completed, hot air is supplied to the inside of the inner case 200 to vaporize the moisture contained in the clothing, so that the temperature rise rate inside the inner case 200 is lowered than the reference value. A second step is performed. You can.

The second step may not reach the set temperature due to the heat of vaporization of the clothing.

Thereafter, when the moisture content of the clothing reaches less than 5 percent, a fourth step may be performed in which the temperature inside the inner case 200 passes the set temperature and continues to rise to the drying temperature or higher.

Since the compressor 342 is always operated, the steam heater 342 is blocked, thereby reducing the power consumption of the entire laundry treatment device. Additionally, in the drying course, steam may not be supplied to the clothes because the moisture content of the clothes is high.

The moving hanger 1000 can be driven to shake the clothing. As a result, not only can the moisture contained in the clothing be shaken off, but the entire clothing can be evenly exposed to hot air.

Alternatively, as in the first step, in a section where the moisture content of the clothing is higher than the removal moisture rate, the weight of the clothing is heavy, so the operation of the moving hanger 1000 may be blocked.

As a result, if the wrinkle removal step is not performed, there may be no section that satisfies all removal conditions until the fourth step in the embodiment of the present invention shown in FIGS. 22 and 23. Therefore, in this embodiment of the drying course control method, clothes can be dried quickly, but creases and wrinkles in the clothes may not be removed.

Figure 24 shows another example of a drying course performed in the laundry treatment apparatus of the present invention.

The laundry treatment apparatus of the present invention can supply steam inside the inner case in the initial section when performing a drying cycle through a drying course.

When the moisture content of clothes is high, even if steam is supplied to the clothes, the moisture content of the clothes is not significantly increased or is almost maintained, so more energy is not required to remove moisture by the steam. Additionally, since the steam does not lose heat through heat of vaporization, etc., the temperature inside the inner case 200 can rapidly increase.

As a result, the laundry treatment apparatus of the present invention can achieve the removal condition by supplying steam at the beginning of the drying course to increase the inner temperature of the inner case above the set temperature. Accordingly, wrinkles and creases in the clothing can be automatically removed.

Referring to Figure 24(a), when the drying course is performed, the laundry treatment apparatus of the present invention operates the compressor 342 and the blowing fan 352 to supply heated air to the inner case 200. You can follow the steps.

In the first step, the control unit 700 may drive the steam heater 840.

Specifically, the control unit 700 may generate steam by driving either the first heater 841 or the second heater 842 while the compressor 342 is operating.

That is, the control unit 700 may drive the compressor 342 first and then drive either the first heater 841 or the second heater 842 simultaneously with the compressor 342.

In addition, the control unit 700 may first heat the water contained in the steam case 381 by simultaneously driving the first heater 841 and the second heater 842, and then drive the compressor 342. there is. Afterwards, steam can be supplied by driving either the first heater 841 or the second heater 842.

That is, the control unit 700 may drive the first heater 841 and the second heater 842 first and then drive the compressor 342 later.

However, even in this case, since either the first heater 841 or the second heater 842 is stopped before the compressor 342 starts to drive, the heater 842 is stopped while the compressor 342 is running. Only one of the first heater 841 and the second heater 842 can be driven.

Accordingly, it can be seen that either the first heater (841) or the second heater (842) is driven while the compressor (342) is driving first.

The control unit 700 simultaneously operates any one of the first heater 841 and the second heater 842 and the compressor 342 in at least a portion of the first stage to Hot air and steam can be supplied simultaneously. As a result, the internal temperature of the inner case 200 can rise above the set temperature from the first stage.

The control unit 700 may simultaneously drive either the first heater 841 or the second heater 842 and the compressor 342 from the start of the first stage. After a certain period of time, either the first heater 841 or the second heater 842 and the compressor 842 can be operated simultaneously.

As a result, the first heater 841 and the second heater 842 are simultaneously driven at the beginning of the first stage and the compressor 342 is blocked to ensure time for boiling the water first, or the first heater (842) is operated at the beginning of the first stage. Even if the 841) and the second heater 842 are not operated at the same time, steam can be prevented from being supplied from the initial stage when the moisture content of the clothes is too high.

In the first step, due to the operation of the steam heater 840, the internal temperature of the inner case 200 may rise to a limit temperature higher than the set temperature.

The limit temperature may be set to a temperature that ensures that the internal temperature of the inner case 200 does not decrease below the set temperature even if steam is not supplied and moisture contained in the clothing evaporates.

For example, it may correspond to 45 degrees Celsius.

Referring to Figure 24(b), when the first step is passed and the second step is entered, the moisture content of the clothing can reach the removal moisture rate.

In addition, since steam supply and hot air supply are performed simultaneously in the first stage, the clothing may reach the moisture removal rate during the first stage.

As a result, clothing may be in a state of moisture removal rate in a specific section throughout the first and second stages.

Even in the second stage, steam may be supplied into the inner case 200 in the initial section. As a result, the internal temperature of the inner case 200 can be prevented from falling below the set temperature due to heat of vaporization.

Additionally, the control unit 700 can drive the moving hanger 1000 in the second step. Therefore, a removal force can be applied to the clothing.

Of course, the control unit 700 may drive the moving hanger 1000 from the first step.

As a result, all wrinkle removal conditions can be satisfied in the second step.

Referring to Figure 24(c), when the second step is performed and the moisture content of the clothing falls below the removal moisture rate, the third step can be performed.

However, since all wrinkles were removed in the second step, the third step can be performed in a state where there are no creases or wrinkles in the clothing.

In the third stage, since the moisture content of the clothing is low, the temperature inside the inner case 200 may rise above the drying temperature.

In the third step, the operation of the first heater 841 and the second heater 842 may be completely blocked. As a result, unnecessary steps to increase the thickness of dried clothing can be omitted, and the temperature inside the inner case 200 can be prevented from becoming too high.

Referring to FIG. 24(d), when the temperature inside the inner case 200 rises above the drying temperature that can ensure drying of clothes, or when the drying time elapses above the drying temperature, the control unit 700 Step 4 described in can be performed as is.

As a result, the laundry treatment apparatus of the present invention can omit the additional wrinkle removal step after the clothes are dried by performing the first to fourth steps.

The laundry treatment apparatus of the present invention can be considered to include a wrinkle removal step in the drying cycle or to automatically perform the wrinkle removal step.

Additionally, the clothing processing device of the present invention can automatically remove creases and wrinkles from clothing while performing a drying course.

In other words, the clothing treatment device of the present invention can omit the process of supplying additional steam and drying the clothes again after the moisture content of the clothes falls below 5%. In addition, in the laundry treatment apparatus of the present invention, stopping and restarting the compressor can be omitted in order to drive both the first heater 841 and the second heater 842 until the end of the drying course. In addition, the clothing treatment device of the present invention can omit the inefficient process of increasing the moisture content of clothes again in the section below the removal moisture rate.

In addition, the clothing treatment device of the present invention can automatically remove creases and wrinkles from clothing during the drying cycle, and can prevent drying delays or reductions in drying efficiency in order to remove creases and wrinkles from clothing.

Accordingly, the clothing treatment device of the present invention allows the user to omit taking additional measures to remove creases and wrinkles from clothing.

Figure 25 shows the control state of the clothing treatment device when the control method of Figure 24 is performed.

The laundry treatment apparatus of the present invention may operate either the first heater 841 or the second heater 842 simultaneously with the compressor 342 while the compressor 342 is being driven in the first step. Accordingly, the temperature inside the inner case 200 can rise faster and higher. As a result, the temperature inside the inner case 200 may rise above the set temperature from the first stage even if the moisture content of the clothing is too high and the removal moisture rate has not yet been reached.

On the other hand, in the laundry treatment device of the present invention, the internal temperature of the inner case 200 rises above the set temperature and reaches the limit temperature due to the simultaneous operation of the steam heater 840 and the compressor 342, so that the first step The effect of setting the execution time longer is derived.

In addition, since the first step is completed at a high temperature, the effect of shortening at least one of the second step and the third step can be obtained.

For example, the first stage is typically completed at the first time t1 when the compressor 342 starts to drive and the driving rpm reaches the maximum rpm. However, in the laundry treatment apparatus of the present invention, the temperature increase rate inside the inner case 200 from the first time (t1) to the third time (t3) is above the reference value, so the first step is performed until the third time (t3). It can be seen that it is being carried out.

In addition, in the laundry treatment apparatus of the present invention, the temperature increase rate inside the inner case 200 begins to become less than the reference value after the third time (t3).

Accordingly, in the laundry treatment apparatus of the present invention, the second step may start from the third time (t3).

In addition, since the temperature increase rate rises again above the reference value from the 7th hour (t7), the third stage can be considered to start from the 7th hour, and from the 8th hour, the temperature inside the inner case 200 exceeds the drying temperature. Therefore, the third step can be considered to be performed from the 7th time (t7) to the 8th time (t8).

The fourth step may be performed from the 8th hour until the 9th hour when the operation of the compressor 342 ends.

In the embodiment of the drying course in which steam is not originally supplied to the inside of the inner case 200, the rate reduction step is performed even after the 9th hour, but in the embodiment of the drying course in which steam and hot air are initially supplied simultaneously, the inside of the inner case 200 Since the temperature is maintained higher than the set temperature, the drying course can be ended at the 8th hour. That is, the embodiment of FIG. 24 can significantly shorten the drying course execution time compared to the embodiment of FIG. 22.

Referring to FIGS. 25(a) and 25(b), the control unit 700 operates the compressor 342 from the initial time t0 when the compressor starts operating until the ninth time t9 when the drying course ends. ) can be maintained.

The control unit 700 can drive the compressor 342 from the initial time (t0) and maintain it until the ninth time (t9) when the drying cycle ends.

The control unit 700 can simultaneously drive the compressor 342 and the blowing fan 352 from the first to the third stage, and in the fourth stage, the blowing fan 352 is driven while the compressor 342 is operated. ) may not run.

Referring to Figure 25(c), the control unit 700 may first drive the steam heater 840 before driving the compressor 342.

The control unit 700 can quickly heat the water contained in the steam case 810 by driving the entire steam heater 840 at maximum power faster than the initial time t0. For example, before driving the compressor 342, the control unit 700 can simultaneously operate the first heater 841 and the second heater 842 to generate steam as quickly as possible.

When steam is generated by simultaneously driving the first heater 841 and the second heater 842, the control unit 700 can drive only one of the first heater 841 and the second heater 842. there is.

The control unit 700 may start driving the compressor 342 when either the first heater 841 or the second heater 842 is driven.

Alternatively, the control unit 700 may drive either the first heater 841 or the second heater 842 after the compressor 342 is driven.

Alternatively, the control unit 700 heats the water to a certain level by operating the first heater 841 and the second heater 842 at the same time before the initial time t0. When it reaches , either the first heater 841 or the second heater 842 can be driven to further heat the water and the compressor 342 can be driven.

Alternatively, the control unit 700 first drives the compressor 342 at the initial time (t0) and then operates either the first heater 841 or the second heater 842 after the initial time (t0). It can be operated to heat water. Therefore, while the compressor 342 is operating, some of the steam heaters 840 are driven to heat the water, and when the first time (t1) is reached, steam is generated and the inner case ( 200) Steam may be supplied internally.

In any case, once the compressor 342 starts to operate, the operation of the compressor 342 is not blocked until the third stage is completed, and hot air is first supplied inside the inner case 200 and steam is supplied later. You can.

As a result, the control unit 700 can supply steam into the inner case 200 by operating the steam heater 840 from the first step.

The control unit 700 can maintain the operation of the steam heater 840 until the temperature inside the inner case 200 rises above the set temperature. In other words, the operation of the first heater 841 or the second heater 842 can be maintained.

Additionally, the control unit 700 can maintain the operation of the steam heater 840 even after the temperature inside the inner case 200 rises above the set temperature. For example, the control unit 700 operates the heater among the first heater 842 and the second heater 842 until the internal temperature of the inner case 200 rises to a limit temperature higher than the set temperature. can be maintained.

This means that even if the internal temperature of the inner case 200 is above the set temperature, when the steam heater 840 is stopped, moisture evaporates from the clothing inside the inner case 200 and absorbs heat of vaporization, causing the internal temperature of the inner case 200 to decrease. This is because the temperature may fall below the set temperature again.

Therefore, even if the internal temperature of the inner case 200 rises above the set temperature, the control unit 700 operates the first heater 841 until the internal temperature increase rate of the inner case 200 enters the second stage below the reference value. ) Alternatively, the operation of the second heater 842 can be maintained.

As a result, the clothing processing apparatus of the present invention can maintain the internal temperature of the inner case 200 above the set temperature in at least some sections of the first and second steps, thereby satisfying the condition of removing creases and wrinkles from clothing. .

The control unit 700 may stop driving the first heater 841 or the second heater 842 when the second stage enters or the temperature inside the inner case 200 reaches the limit temperature. That is, the control unit 700 may stop supplying steam to the inner case 200 when the second stage enters or the temperature inside the inner case 200 reaches the limit temperature. As a result, the moisture content of clothing can be prevented from being unnecessarily increased or decreased.

Of course, the control unit 700 can continuously supply steam by maintaining the operation of the first heater 841 or the second heater 842 until at least a portion of the second stage. As a result, it is possible to completely prevent the internal temperature of the inner case 200 from falling below the set temperature.

The moisture content of the clothing begins to decrease from the first step because the clothing begins to dry from the first step.

Even if the moisture rate is 100% because the clothing placed in the initial inner case 200 is completely wet, from the second time (t2), which is before the third time entering the second stage, the moisture rate of the clothing is equal to the removal moisture rate. You can enter. In other words, from the first stage, the moisture content of clothing can drop to 45 percent.

In addition, from the second time (t2) to the sixth hour (t6) corresponding to the second stage, or the fifth hour (t5), which is earlier than the sixth hour, the moisture content of the clothing may be 45% to 5% and is removed. The moisture content condition can be satisfied as is.

In addition, the moisture removal rate may be deviated before the 6th hour, which is before the 7th hour when the third step is performed.

In summary, in the clothes treatment apparatus of the present invention, the internal temperature of the inner case 200 is higher than the set temperature between the second and sixth hours corresponding to the first and second stages, and the clothes are placed in a state of removal moisture content. .

Therefore, in the laundry treatment apparatus of the present invention, in a partial section of the first stage and a partial section of the second stage between the second time and the sixth time, the control unit 700 drives the moving hanger 1000 to remove the clothes until the physical force is removed. It can be delivered to .

As a result, all removal conditions are satisfied in a partial section of the first stage and a partial section of the second stage between the second time and the sixth hour, so the section can be set as the wrinkle removal section (A).

In other words, the wrinkle removal section (A) can be defined as a section where the temperature at which the clothing is placed is above the set temperature and the moisture content of the clothing corresponds to the removal moisture rate, and all removal conditions are satisfied when only the removal physical force is applied.

The laundry treatment apparatus of the present invention can drive the moving hanger (1000) at least in the wrinkle removal section (A).

The control unit 700 may intermittently drive the steam heater 840 operating in the wrinkle removal section (A). That is, the control unit 700 can drive the first heater 841 or the second heater 842 by repeatedly turning it on and off. As a result, excessive steam can be prevented from being supplied, the temperature inside the inner case 200 can be prevented from rapidly rising, and the reliability of the compressor can be maintained.

From another perspective, the control unit 700 may intermittently drive the steam heater 840 when the internal temperature of the inner case 200 corresponds to a limit temperature higher than the set temperature. The limit temperature may correspond to a temperature at which the temperature of the refrigerant input into the compressor 342 or the refrigerant discharged from the compressor 342 can be set to a limit temperature that threatens the reliability of the compressor 342.

Accordingly, the control unit 700 can intermittently drive the first heater 841 or the second heater 842 in a temperature section above the limit temperature.

In the wrinkle removal section (A), the control unit 700 can supply steam to the inside of the inner case 200, but the third time is earlier than the sixth time (t6) when the wrinkle removal section (A) ends. The operation of the steam heater 840 can be stopped at (t3). As a result, it is possible to prevent the internal humidity of the inner case 200 from unnecessarily increasing or energy from being wasted in the wrinkle removal section A.

The wrinkle removal section (A) may be set between the 2nd time and the 6th time, but it can be set longer than that as long as it includes the minimum time for removing wrinkles between the 2nd time and the 6th time. It is okay to set it short.

That is, the control unit 700 may shake the moving hanger 1000 or drive the steam heater 840 to maintain the temperature above the set temperature during the set time within the wrinkle removal section A. That is, steam is supplied inside the inner case 200 until the set time, and after the set time has elapsed, the operation of the steam heater 840 can be blocked even before the sixth time.

For example, the set time may correspond to 15 minutes.

Referring to Figure 25(d), the control unit 700 may drive the moving hanger 1000 for at least a set time during the wrinkle removal section A.

If the moving hanger 1000 has not been driven before the wrinkle removal section A, the control unit 700 can drive the moving hanger 1000 in the wrinkle removal section A for at least a set time.

Therefore, if the moving hanger 1000 is driven while the steam heater 840 is driving, and the set time has not elapsed even after driving of the steam heater is terminated, the moving hanger is operated for a certain period of time until the set time has elapsed. (1000) can maintain the driving speed.

That is, even if the steam heater 840 is not operated for the set time, the internal temperature of the inner case 200 can be maintained above the set temperature. However, the moving hanger 1000 must be driven for a set time to achieve the removal force condition. For example, the steam heater 840 may be shut off at the third time t3, but the moving hanger 1000 may be further driven at least until the sixth time t6.

If the above-described control method is analyzed from the perspective of driving the moving hanger 1000 and the steam heater 840, it can be interpreted as follows.

The moving hanger 1000 may be driven so that it overlaps at least part of the section in which the steam heater 740 is driven.

The control unit 700 may drive the moving hanger 1000 in a section where the temperature inside the inner case 200 is at least the set temperature or higher.

Additionally, the control unit 700 can drive the moving hanger 1000 while the first heater 841 or the second heater 842 is operating.

In addition, if the control unit 700 drives the moving hanger at a first frequency (1 rpm) before the wrinkle removal section (A), the moving hanger operates at a second frequency (2 rpm) faster than the first frequency in the wrinkle removal section (A). ) can be driven.

If the moving hanger 1000 starts to drive before the steam heater 840 drives, the control unit 700 drives the moving hanger 1000 faster in the section in which the steam heater 840 drives. You can.

If the moving hanger 1000 is not driven before the steam heater 840 is driven, the control unit 700 operates the moving hanger 1000 in at least some of the sections in which the steam heater 840 is driven. can do.

Accordingly, by applying a physical force greater than the removal physical force to the clothing in the wrinkle removal section A, the removal conditions can be further satisfied and wrinkles and wrinkles in the clothing can be reliably removed.

The control unit 700 may stop driving the moving hanger 1000 after the wrinkle removal section (A) or drive the moving hanger 1000 at a third frequency (3 rpm) that is slower than the second frequency. . As a result, it is possible to prevent overload of the moving hanger 1000 and save energy during the drying process.

The first frequency may be set lower than the third frequency. As a result, the moving hanger 1000 can be prevented from consuming excessive energy to shake heavy clothing with high moisture content, and vibration occurring in the entire clothing processing device can be minimized.

If the control unit 700 drives the moving hanger 1000 while the steam heater 840 is operating, the control unit 700 does not drive the moving hanger 1000 after the steam heater 840 is driven. The moving hanger (1000) can be driven slowly.

The control unit 700 may control the section in which the steam supply unit 800 is driven and the section in which the moving hanger 1000 is driven at the second frequency to at least partially overlap.

The control unit 700 may drive the moving hanger 1000 at the second frequency after the steam supply unit 800 is driven.

As a result, the laundry processing apparatus of the present invention drives the moving hanger 1000 or drives it at the fastest speed in at least some sections of the first and second stages, and does not drive the moving hanger 1000 or drives it at the slowest speed before that. You can.

If the above process is described focusing on the driving of the moving hanger 1000, it can be analyzed as follows.

The control unit 700 may drive the moving hanger 1000 at a first frequency or maintain a stopped state in a section where the temperature inside the inner case is below the set temperature. Additionally, the control unit 700 may drive the moving hanger 1000 at a second frequency faster than the first frequency in a section where the temperature inside the inner case is higher than the set temperature.

When the control unit 700 drives the moving hanger 1000 at the second frequency for a reference time, it can then drive it at a third frequency lower than the second frequency.

When the temperature rise rate inside the inner case becomes higher than the reference value or when the temperature inside the inner case reaches a drying temperature higher than the set temperature, the control unit 700 operates the moving hanger 1000 at a slower speed than the second frequency. It can be driven at 3 frequencies.

The control unit 700 may set the driving frequency of the moving hanger 1000 differently depending on the internal temperature of the inner case 200.

Specifically, the control unit 700 drives the moving hanger 1000 at a first frequency until the inner temperature of the inner case reaches the set temperature, and after the inner temperature of the inner case reaches the set temperature, It can be driven at a second frequency that is faster than the first frequency.

The above control unit (700) can drive the moving hanger (1000) at a third frequency lower than the second frequency in a section after the temperature inside the inner case reaches a drying temperature higher than the set temperature.

The control unit 700 may drive the moving hanger 1000 at the second frequency for a set time and then drive it at a third frequency lower than the second frequency.

The second frequency (2rpm) may be set to the fastest frequency at which the moving hanger operates while performing the course.

The third step can be performed when the moisture content of the clothing is lower than the removal moisture content. The third stage corresponds to a section where the temperature increase rate inside the inner case 200 becomes greater than the reference value again. The wrinkle removal section (A) may be ended before the third step. Accordingly, the steam heater 840 may be terminated before the third step, and the steam heater 840 may be blocked from operating during the third step and thereafter.

When the internal temperature of the inner case 200 reaches the drying temperature or higher, the control unit 700 may stop driving the compressor 342 and maintain at least part of the driving of the blowing fan 352.

Meanwhile, the laundry treatment apparatus of the present invention can drive the second heater 842 when the steam heater 840 is driven simultaneously with the compressor 342 in the drying course including the wrinkle removal section A. As a result, less steam is supplied to the inside of the inner case 200, thereby preventing the possibility of the moisture content of clothing increasing, and it is possible to focus on raising only the temperature inside the inner case 200 above the set temperature.

The power amount of the second heater 842 may be set such that the amount of steam generated by the second heater 842 corresponds to a range of 50 to 150% of the amount of dehumidification that the evaporator can dehumidify.

Additionally, the amount of water used and energy consumption can be minimized when raising the temperature inside the inner case 200 above the set temperature.

Meanwhile, the steam heater 840 stops operating at least during the second stage, and the second stage corresponds to a section where the temperature rise rate is below the reference value or the temperature change range inside the inner case 200 is below a specific range, so the inner case 200 It can be seen that operation of the first or second heater is stopped in a section where the internal temperature change range is below a certain range.

The specific range may correspond to 5 degrees.

In addition, the laundry treatment device of the present invention blocks the steam supply after the third step in the above control method, so it can be considered that the steam heater is blocked after the drying temperature is reached.

Figure 26 shows another embodiment of a drying course performed in the laundry treatment apparatus of the present invention.

The laundry treatment apparatus of the present invention may not operate the steam heater 840 and the compressor 342 simultaneously in the wrinkle removal section (A).

That is, the laundry treatment device of the present invention can always drive the steam heater 840 at maximum power, and the steam heater 840 can also be designed as a single heater rather than a first heater and a second heater.

Hereinafter, in order to avoid duplication of description with the above-described embodiment, the description will focus on other content.

When the drying course is performed, the laundry treatment apparatus of the present invention can perform a preparation step to increase the temperature of the refrigerant circulating in the heat supply unit 340 by driving the compressor 342.

The preparation step may correspond to increasing the driving RPM of the compressor 342 to the maximum RPM to increase the temperature of the refrigerant to a target temperature at which a drying cycle can be performed.

The preparation step may be performed up to a time (ta).

Once the preparation step is performed, the laundry treatment apparatus of the present invention can perform the first step of driving the steam heater 840.

The first step may correspond to driving a single heater at maximum output if the steam heater 840 is provided as a single heater, and may correspond to driving all heaters if the steam heater 840 is provided as a plurality of heaters.

When the steam heater 840 is driven at maximum output, it cannot be driven simultaneously with the compressor 342. However, the steam heater 840 is driven at maximum output so that the temperature inside the inner case 200 can more quickly rise above the set temperature.

The control unit 700 can increase the internal temperature of the inner case 200 to a guaranteed temperature that is higher than the set temperature.

The guaranteed temperature is a temperature that can ensure that the internal temperature of the inner case 200 can be maintained above the set temperature for a set time when the steam heater 840 is stopped and the compressor 342 is started again. It may apply.

The first step can be performed up to b time (tb).

In the first step, the control unit 700 may always maintain the operation of the steam heater 840, but may also intermittently and repeatedly operate the steam heater 840.

When the first step is completed, the control unit 700 can block the operation of the steam heater 840 and drive the compressor 342 and the blowing fan 352.

When the blower fan 352 is driven and air flows into the inner case 200, the moisture contained in the clothing is evaporated, so the heat of vaporization is absorbed, and the temperature inside the inner case 200 decreases at time c (tc). It may be lower than the set temperature.

However, due to the previously performed preheating step and the operation of the compressor 342, hot air is supplied, and the temperature inside the inner case 200 stops falling and rises. Therefore, from time c, the internal temperature of the inner case 200 may again become higher than the set temperature.

From time b (tb) to time c (tb), the temperature rise rate is always below the reference value until d time (tb), when the temperature rise rate is above the reference value. Therefore, the period from time b (tb) to time d (tb) can be defined as the second stage.

The wrinkle removal section (A) can be satisfied when the internal temperature of the inner case 200 reaches the set temperature during the second step.

The wrinkle removal section (A) is a section where the temperature at which the clothing is placed is above the set temperature and the moisture content of the clothing corresponds to the removal moisture rate. It corresponds to a section that satisfies all removal conditions when only the removal physical force is applied.

The control unit 700 may enter the wrinkle removal section (A) when the internal temperature of the inner case 200 begins to reach at least the second set temperature.

The wrinkle removal section (A) is satisfied in the second step. That is, in the second step, the moisture content of the clothing satisfies the removal moisture rate, and the internal temperature of the inner case corresponds to the set temperature or higher.

Accordingly, the control unit 700 can drive the moving hanger 1000 at least in the wrinkle removal section (A) during the drying course. As a result, a removal force can be added to the clothing.

As a result, since all removal conditions are achieved in the wrinkle removal section A, wrinkles and wrinkles in clothing can be removed.

The wrinkle removal section (A) may be completed before d time (tb), which is the third stage entry section when the temperature increase rate inside the inner case 200 becomes greater than the reference value.

The third step may be performed until f time (tf) when the temperature inside the inner case 200 reaches the drying temperature or higher.

From the second stage to the third stage, the compressor 342 may be maintained, and the steam heater 840 may be blocked.

Referring to Figure 28(d), the control unit 700 can drive the moving hanger 1000 in the wrinkle removal section (A). If the moving hanger 1000 has not been driven before the wrinkle removal section A, the control unit 700 can drive the moving hanger 1000 in the wrinkle removal section A for at least a set time.

The control unit 700 may be set to drive the compressor 342 and the moving hanger 1000 with at least some overlap, but not to drive the compressor 342 and the steam heater 840 with overlap.

Additionally, the moving hanger 1000 can be driven simultaneously while the steam heater 840 is driven. The moving hanger 1000 can be driven before or after the steam heater 840 is driven.

In addition, if the control unit 700 drives the moving hanger at a first frequency (1 rpm) before the wrinkle removal section (A), the moving hanger is driven at a second frequency (2 rpm) faster than the first frequency in the wrinkle removal step (A). ) can be driven.

Accordingly, by applying a physical force greater than the removal physical force to the clothing in the wrinkle removal section A, the removal conditions can be further satisfied and wrinkles and wrinkles in the clothing can be reliably removed.

The control unit 700 may stop driving the moving hanger 1000 after the wrinkle removal section (A) or drive the moving hanger 1000 at a third frequency (3 rpm) that is slower than the second frequency. . As a result, it is possible to prevent overload of the moving hanger 1000 and save energy during the drying process.

The first frequency may be set lower than the third frequency. As a result, the moving hanger 1000 can be prevented from consuming excessive energy to shake heavy clothing with high moisture content, and vibration occurring in the entire clothing processing device can be minimized.

When the control unit 700 drives the moving hanger 1000 while the steam heater 840 is operating, the moving hanger 1000 operates for at least some sections after the operation of the steam heater 840 ends. It can run faster. Additionally, after that, the moving hanger 1000 can be driven slowly.

The control unit 700 may drive the moving hanger 1000 at the second frequency after the steam supply unit 800 is driven.

As a result, the laundry treatment apparatus of the present invention may drive the moving hanger 1000 or drive it at the fastest speed in at least some sections of the constant rate stage, and may not drive the moving hanger 1000 or drive it at the slowest speed before that.

If the above process is described focusing on the driving of the moving hanger 1000, it can be analyzed as follows.

The control unit 700 may drive the moving hanger 1000 at a first frequency or maintain a stopped state in a section where the temperature inside the inner case is below the set temperature.

In addition, the control unit 700 may drive the moving hanger 1000 at a second frequency faster than the first frequency from the section in which the temperature inside the inner case exceeds the set temperature for the second time.

When the control unit 700 drives the moving hanger 1000 at the second frequency for a set time, it can then drive it at a third frequency lower than the second frequency.

When the temperature rise rate inside the inner case becomes higher than the reference value or when the temperature inside the inner case reaches a drying temperature higher than the set temperature, the control unit 700 operates the moving hanger 1000 at a slower speed than the second frequency. It can be driven at 3 frequencies.

The control unit 700 may set the driving frequency of the moving hanger 1000 differently depending on the internal temperature of the inner case 200.

Specifically, the control unit 700 drives the moving hanger 1000 at a first frequency until the inner temperature of the inner case rises to the set temperature for the second time and reaches the set temperature, and the inner case temperature rises the second time to reach the set temperature. After reaching the set temperature, it can be driven at a second frequency that is faster than the first frequency.

The control unit 700 may drive the moving hanger 1000 at a third frequency lower than the second frequency in the section after the inner case temperature reaches a drying temperature higher than the set temperature.

The control unit 700 may drive the moving hanger 1000 at the second frequency for a set time and then drive it at a third frequency lower than the second frequency.

The second frequency (2rpm) may be set to the fastest frequency at which the moving hanger operates while performing the course.

When the internal temperature of the inner case 200 reaches the drying temperature or higher, the control unit 700 may stop driving the compressor 342 and maintain at least part of the driving of the blowing fan 352.

The present invention can be modified and implemented in various forms, and its scope is not limited to the above-described embodiments. Therefore, if the modified embodiment includes elements of the claims of the present invention, it should be considered to fall within the scope of the present invention.

100 cabinets
200 inner case
300 machine room
341 evaporator
342 compressor
343 condenser
800 heat supply unit
841 1st heater
842 2nd heater
1000 moving hanger

Claims (14)

cabinet;
an inner case provided inside the cabinet to accommodate clothing;
a machine room provided with a heat supply unit that supplies hot air inside the inner case and a steam supply unit that supplies steam;
a control unit provided in the machine room to control the heat supply unit and the steam supply unit to perform a drying process for drying the clothes;
It includes a temperature sensor provided in the inner case or the machine room to detect the temperature of the air inside the inner case,
The heat supply unit
It includes a circulation duct that circulates the air discharged from the inner case, a heat exchanger installed in the circulation duct to dehumidify and reheat the air, and a compressor that compresses and supplies refrigerant provided to exchange heat with the air in the heat exchanger. do,
The steam supply unit
A steam case storing water that generates the steam,
It includes a steam heater accommodated in the steam case and heating the water,
The control unit
When the drying process is performed, the steam heater is driven until the inner temperature of the inner case reaches a set temperature or higher to remove wrinkles from the clothing,
A clothing treatment device, characterized in that the steam heater is driven above a guaranteed temperature that can ensure that the inner temperature of the inner case reaches the set temperature again when the compressor is driven even when operation of the steam heater is terminated.
According to paragraph 1,
The set temperature is set to 37 degrees or higher,
A clothing treatment device, characterized in that the guaranteed temperature is set higher than the set temperature.

According to paragraph 1,
The control unit
A clothing treatment device, wherein when the steam heater is operated until the inner temperature of the inner case reaches the guaranteed temperature or higher, re-operating the steam heater is blocked thereafter.
According to paragraph 1,
It further includes a moving hanger that holds the clothing inside the inner case and drives the clothing to shake,
The control unit
A clothing treatment device, characterized in that the moving hanger is driven at least when the inner case temperature exceeds the set temperature for the second or third time.
According to clause 4,
The control unit
The inner case temperature exceeds the set temperature for the second or third time?? Before reaching the point, stop driving the moving hanger or drive it at the first frequency,
The inner case temperature exceeds the set temperature for the second or third time?? A clothing processing device characterized in that the moving hanger is driven at a second frequency that is faster than the first frequency after reaching the first frequency.
According to clause 5,
The control unit
A clothing treatment device, characterized in that the moving hanger is driven at a third frequency slower than the second frequency before the rate of increase in temperature inside the inner case becomes greater than a reference value or reaches the guaranteed temperature again.
According to clause 5,
The control unit
Driving the moving hanger at the second frequency for a set time,
After that, the clothing treatment device is driven at a third frequency that is slower than the second frequency.

According to clause 6 or 7,
A clothing treatment device, wherein the third frequency is set to be greater than the first frequency.
According to clause 5,
The control unit
A clothing treatment device, characterized in that the section in which the steam heater operates and the section in which the moving hanger operates at the second frequency are arranged to be spaced apart from each other.
According to paragraph 1,
The control unit
A clothing treatment device, characterized in that the compressor is driven after the steam heater is completed.
According to clause 10,
The control unit
A clothing treatment device characterized in that the compressor is maintained until drying of the clothing is completed.

According to clause 10,
The control unit
Driving the compressor before driving the steam heater,
A clothing treatment device characterized in that the compressor stops operating while the steam heater is operating.
According to paragraph 1,
A clothing treatment device, characterized in that the steam heater is provided as a single heater accommodated inside the steam case.
According to paragraph 1,
The steam heater is
It includes a first heater that generates the steam, and a second heater that is spaced apart from the first heater and heats the water to generate the steam,
The control unit
When the drying process is performed,
A clothing treatment device, characterized in that the first heater and the second heater are simultaneously operated until the inner temperature of the inner case reaches the guaranteed temperature or higher.