KR102127386B1 - Laundry Machine and Control method for Laundry Machine - Google Patents

Abstract

The present invention relates to an apparatus for treating clothes, and more specifically, a tub through which laundry is introduced, an air supply device including a heat pump for dehumidifying and heating air of the tub, and an air flow path through which air is circulated between the tub and the air supply device In the control method of the garment processing apparatus having a temperature sensing step of sensing the temperature of the air and a preheating step of preheating the temperature of the air flow path when the detected temperature is below the set temperature.

Description

{Laundry Machine and Control method for Laundry Machine}

The present invention relates to a clothing processing apparatus and a control method of the clothing processing apparatus. More specifically, the present invention relates to a clothing processing apparatus including a preheating process for driving a heat pump in a clothing processing apparatus using a heat pump, and a control method of the clothing processing apparatus.

In general, the clothes processing apparatus may include, for example, a clothes processing apparatus exclusively for washing that performs normal washing, and a clothes processing apparatus for drying and drying that includes a drying function. Here, the laundry treatment apparatus for washing is a product that removes various contaminants attached to clothes and bedding by using an emulsifying effect of a detergent, a friction action of a water stream due to rotation of a pulsator or a drum, and an impact action on laundry. The automatic washing machine, which has recently appeared, automatically proceeds through a series of courses leading to a washing course, a rinsing course, and a dehydration course without user intervention.

In addition, the clothes processing apparatus for drying and drying is a type of washing machine capable of performing the functions of the above-described laundry treatment apparatus and washing and drying the laundry.

The drying and combined clothes processing apparatus supplies high temperature air (hot air) to the clothes, and may be classified into an exhaust type and a circulation type (condensation type) clothes processing device based on the air flow method.

The exhaust-type clothes processing apparatus is a method in which heated air is supplied to the clothes receiving unit, but the air discharged from the clothes receiving unit is not circulated but is discharged to the outside of the clothing processing unit.

The circulating clothing processing device is a structure that circulates the air of the clothes receiving portion where clothing is stored, removes moisture from the air discharged from the clothing receiving portion (dehumidifies), heats it, and re-supplies it to the clothing receiving portion.

Hereinafter, with reference to FIG. 1, a circulating drying combined clothes processing apparatus according to the prior art will be briefly described. As shown in the drawing, the clothes handling device for combined use with a circulating drying type forms a receiving space therein and a cabinet 10 provided with an inlet 12 through which laundry is input and a door 14 for opening and closing the inlet 12. , Supplying dry air to the tub 20 accommodated in the interior of the cabinet 10, the drum 40 rotatably installed inside the tub 20 and receiving laundry to be dried, and the tub 20 It is provided with an air supply device 50 for drying the laundry.

Here, the air supply device 50 is a condensation duct 51 formed on the outside of the tub 20 so that air containing moisture generated from the tub 20 can be condensed, and a condensation duct along the flow direction of air The heating duct 54 connected to the downstream side of 51 and heating the air by the heater 56 to provide the inside of the tub 20, and the air of the tub 20 condensation duct 51 and heating duct It has a blower fan 53 to be circulated along the (54).

The drying combined clothes processing apparatus 1 as described above is heated by the heater 56 provided in the heating duct 54 when the air moved to the blowing fan 53 is dried when the laundry is dried, and the heated air is a tub 20. ) Is supplied to the inside to dry the laundry by the rotation and hot air of the drum 40. Thereafter, the heated air for drying the laundry is converted into humid air according to drying of the laundry, and is introduced into the condensation duct 51 in the tub 20 to remove moisture from the condensation duct 51.

Here, a separate cooling water is supplied to the condensation duct 51 to condense humid air. On the other hand, the air introduced into the condensation duct 51 is supplied to the heating duct 54 again by the blowing fan 53, and is provided to circulate the air by repeating the above-described process.

On the other hand, in the case of the above-described condensation duct 51, it is provided in the form of a pipe in consideration of the blowing capacity of the blowing fan 53 and the smooth flow of air. It is to remove moisture by condensing the moisture contained in the air. To this end, in order to condense moisture in the humid air flowing into the condensation duct 51, a large amount of cooling water must be continuously supplied during the drying process of the laundry.

On the other hand, the air supply device 50 provided in the conventional drying and combined clothes processing apparatus is a heating duct for heating the air flowing by the blowing fan 53 and the blowing fan 53 to discharge the air inside the clothes receiving unit ( 54).

That is, in the conventional clothing processing apparatus 1, when the air flow direction is referenced, the blowing fan 53 is positioned before the heating duct 54, so that the air drawn out from the clothes receiving unit (that is, the tub 20) is blown. After passing through the fan (53) and the heating duct (54) sequentially, it is re-supplied to the clothes receiving portion.

On the other hand, the clothes processing apparatus for drying and drying according to the prior art as described above uses a heater for heating air to supply hot air (hot air) to the clothes, thereby heating the air to supply hot air to the clothes.

These heaters include a gas heater that heats air by burning gas, and an electric heater that heats air by electrical resistance. Recently, electric heaters that are easy to install and have a simple structure are in use.

However, when the air is heated by the electric heater as described above, high-temperature heat of the heater may be directly transferred to the garment, thereby damaging the garment or further causing a fire in the garment processing apparatus.

In addition, since the electric heater heats air by using electricity, in order to heat the air to a desired temperature, there is a problem in that the consumption of electricity increases due to the large amount of electricity consumption.

In addition, there is a problem that an excessively large amount of cooling water is required because a large amount of cooling water must be sprayed inside the condensation duct to remove moisture contained in the dry air of the garment.

Accordingly, recently, a heat pump using an evaporator, a compressor, a condenser, and an expander in which a refrigerant circulates, and a clothing processing device that generates hot air through a blower have been developed, and the range of use thereof is gradually widening.

In the case of such a clothes drying and drying apparatus using a heat pump, the moisture contained in the air is removed from the evaporator, and the air is heated in the condenser to be supplied and circulated to the tub to dry the clothes.

However, in the case of the clothes processing apparatus for drying and drying using a heat pump, the operating environment is important for the initial start-up of the heat pump. On the other hand, if you look at the installation environment of the clothes handling apparatus, it is usually installed in a location where separate heating is not formed, such as a separate laundry room, multi-purpose room, or veranda. Therefore, in the season when the temperature is low, such as in winter, the operating environment of the clothing processing device is forced to form a low temperature.

On the other hand, in the case of a heat pump, if the initial operating environment is not suitable, an overload occurs in the compressor of the heat pump, or it takes a lot of energy and time to preheat the heat pump to form a condition in which the heat pump itself can operate smoothly. There is a problem.

That is, when the operating temperature of the heat pump is excessively low, the movement of the refrigerant moved by the compressor is not smooth, and when the condensate of the evaporator remains, the condensed water of the evaporator freezes during the initial operation of the heat pump to smoothly function the evaporator. It may not be performed.

The present invention has been devised to solve the problems as described above, and an object of the present invention is to provide a clothing processing apparatus that improves the structure of an air supply device for supplying heated air for drying laundry to increase drying efficiency. .

In addition, an object of the present invention is to provide a clothing processing apparatus that can increase the heat exchange efficiency by allowing the air moved by the blower fan to pass through the entire area of the heat exchange area of the air supply device.

In addition, the present invention improves the structure of the heat exchanger provided in the drying duct of the air supply device to increase the heat exchange efficiency of air passing through the drying duct, and at the same time to provide a clothing processing device that can simplify the structure of the heat exchanger. It is aimed at.

In addition, an object of the present invention is to provide an apparatus for treating clothes that reduces an external volume and minimizes the volume by improving an installation position of an air supply device for supplying heated air.

In addition, an object of the present invention is to provide a control method of a clothing processing apparatus that improves the operating efficiency of a heat pump by improving the initial operating environment of a heat pump that heats air.

The control method of the garment treatment apparatus according to an embodiment of the present invention for achieving the above object is a tub into which laundry is introduced, an air supply apparatus including a heat pump for dehumidifying and heating the air of the tub, and the tub and the A control method of a clothes treating apparatus having an air flow path through which air is circulated between air supply devices, the method comprising: a temperature sensing step of sensing the temperature of the air; If the detected temperature is below the set temperature, it is preferable to include a preheating step of preheating the temperature of the air passage.

In the temperature sensing step, it is preferable to detect the temperature at the front end or the rear end of the evaporator of the heat pump.

Preferably, the temperature sensing step senses the temperature in the tub.

In the preheating step, it is preferable that air in the tub is heated by a washing water heating heater provided in the tub.

After the preheating step, it is preferable to stop the operation of the heater and perform a drying step of drying the laundry.

Preferably, the air supply device is composed of a suction duct that sucks air from the tub, a connection duct connected to the suction duct, a blowing fan connected to the connection duct, and a discharge duct that supplies air to the tub.

It is preferable that the evaporator and the condenser of the heat pump are provided inside the connection duct.

In the temperature sensing step, it is preferable to detect the temperature inside the connection duct.

In the temperature sensing step, it is preferable to partially circulate the air inside the tub by operating the blowing fan and sense the temperature of the air.

The preheating step includes: a water supply step of supplying a predetermined amount of washing water to the tub; A heating step of operating the washing water heater provided in the tub; And a blowing step of operating the blowing fan for a predetermined period of time.

Preferably, the preheating step includes a determination step of determining whether the temperature of the air is within an operating temperature range of the heat pump.

A heater stopping step of stopping the operation of the heater when the air is included in the operating temperature range; And it is preferable to further include a draining step for draining the wash water of the tub.

Clothing processing apparatus according to an embodiment of the present invention for achieving the above object is a tub provided with a heater for heating the washing water, and connected to the tub, a heat pump for dehumidifying and heating the air in the tub It is preferable to include an included air supply device, a temperature sensor for sensing the temperature of the air, and a control unit for heating the air by operating the heater when the temperature detected by the temperature sensor is lower than or equal to a set temperature.

The air supply device, a suction duct for sucking the air of the tub; A connection duct connected to the suction duct and equipped with an evaporator and a condenser of the heat pump; A blowing fan connected to the connection duct; It is preferable to include an exhaust duct that supplies air to the tub.

The temperature sensor is preferably provided at the front end or the rear end of the evaporator.

Preferably, the blowing fan is driven for a predetermined time when the temperature sensor is operated.

Preferably, the blowing fan is driven for a predetermined time when the heater is operated.

It is preferable that a predetermined amount of washing water is supplied to the tub when the heater is operated.

Preferably, the control unit performs a drying process after the preheating of the air is over.

According to the clothing treatment apparatus of the present invention as described above, it is possible to reduce the external volume of the clothing treatment apparatus and provide a clothing treatment apparatus that can be minimized by using an air supply apparatus using a heat pump.

In addition, according to the clothing processing apparatus of the present invention as described above, by using an air supply apparatus using a heat pump, there is an effect that can provide a clothing processing apparatus capable of improving the air supply structure and the air heating structure.

In addition, according to the clothing processing apparatus of the present invention as described above, by using an air supply device using a heat pump, to provide a clothing processing apparatus that can increase the heat exchange efficiency by improving the movement path of the heat exchanger of the heat pump It has the effect.

In addition, according to the clothing treatment apparatus of the present invention as described above, by using an air supply apparatus using a heat pump and simultaneously integrating a heat exchanger of the air supply apparatus, a clothing treatment apparatus capable of increasing the heat exchange efficiency of the heat exchanger is provided. It has the effect.

In addition, according to the control method of the clothing processing apparatus of the present invention as described above, by creating an environment for the initial operation of the heat pump has the effect that the heat pump can perform the initial operation smoothly.

1 is a perspective view showing a garment processing apparatus according to the prior art.
Figure 2 is a perspective view showing a garment processing apparatus according to the present invention.
3 is a cross-sectional view briefly showing a clothing processing apparatus according to the present invention.
4 is a perspective view showing a main configuration of a clothing processing apparatus according to the present invention.
5 is a plan view showing the main configuration of a clothing processing apparatus according to the present invention.
6 is a simplified view showing an air supply device of the clothing processing apparatus according to the present invention.
7 is a flow chart showing a preheating process according to an embodiment of the present invention.

In describing the present invention, the names of the elements defined are defined in consideration of functions in the present invention. Therefore, it should not be construed as limiting the technical components of the present invention. In addition, each name defined in each component may be referred to as another name in the art.

On the other hand, the configuration or control method of the apparatus to be described below is only for explaining an embodiment of the present invention and is not intended to limit the scope of the present invention, and the same reference numerals are used throughout the specification. Indicate

In addition, clothes and laundry referred to herein include objects that can be worn by a person, such as shoes, socks, gloves, and hats, as well as clothes and clothes, and include all objects capable of washing laundry. Can.

Hereinafter, a garment processing apparatus according to the present invention will be described in detail with reference to the accompanying drawings. Figure 2 is a perspective view showing a clothing processing apparatus according to the present invention, Figure 3 is a cross-sectional view briefly showing the internal structure of the clothing processing apparatus according to the present invention.

2 and 3, the clothing processing apparatus 100 according to the present invention includes a cabinet 110 forming an exterior and an inside of the cabinet 110, where the laundry is stored, where the laundry is stored. It is provided with an air supply device 160 for supplying hot air.

The cabinet 110 includes an inlet 114 through which clothing is introduced, and a door 115 rotatably provided in the cabinet 110 to open and close the inlet 114. A control panel provided with at least one of an input unit 112 for inputting a control command for the operation of the garment processing apparatus 100 and a display unit 113 for displaying a control history of the garment processing apparatus at an upper portion of the input port 114. 111) and a control unit (not shown) that controls each of the above-described components according to a control command input through the input unit 112.

Here, the input unit 112 is provided on the control panel 111 in the form of a button or a rotary knob, a program for washing or drying set in the clothing processing apparatus (laundry course, drying course), washing time, amount of washing water, It is a means to input control commands such as hot air supply time to the control unit.

In addition, the display unit 113 is a means for displaying information (remaining time, etc.) generated by the operation of the clothes processing apparatus 100 according to a control command (such as a course name) input through the input unit and an input control command.

On the other hand, when the clothing processing apparatus 100 of the present invention is provided as a dryer for drying only laundry, the clothing receiving unit may be provided only with the drum 150 rotatably provided inside the cabinet 110.

However, when the clothing processing apparatus 100 of the present invention is provided as a device capable of simultaneously washing and drying laundry, the clothing receiving unit is provided inside the cabinet as shown in FIG. 2, and the tub 120 and the tub where laundry is stored are stored. It is rotatably provided therein and may be provided as a drum 150 in which laundry is stored.

Hereinafter, for convenience of description, the tub 120 and the drum 150 will be described based on the clothes receiving unit.

As shown in FIG. 3, the tub 120 is provided with an empty cylindrical shape inside and is supported or fixed by a separate suspension (not shown) inside the cabinet 110. In addition, the tub opening 122 for entering and exiting laundry is provided at a position corresponding to the inlet 114 of the cabinet 110 on the front of the tub 120.

Here, the gasket 130 is provided between the tub opening 122 and the inlet 114, the gasket 130 not only prevents the washing water stored inside the tub 120 from leaking out of the tub 120, but also the drum It is a means to prevent the vibration generated in the tub 120 during the rotation of the 150 is transmitted to the cabinet 110. Therefore, the gasket 130 may be provided as a vibration insulating member such as rubber.

Meanwhile, the tub 120 may be provided to be parallel to the ground on which the cabinet 110 is supported, as shown in FIG. 3, or may be provided to be inclined at a predetermined angle with respect to the ground. However, when the tub 120 is provided to be inclined at a predetermined angle with respect to the ground, the inclination angle of the tub 120 is preferably provided to be less than 90 degrees.

Here, the upper portion of the circumferential surface of the tub 120 is provided with an air discharge hole 123 through which air inside the tub 120 is discharged, and the lower portion of the tub 120 drains the washing water stored in the tub 120. For the drain sump 124 is formed. Here, the drain sump 124 is formed in a shape that is embedded in the lower portion of the tub 120 so that the wash water in the tub 120 can be collected.

In addition, a drainage portion 126 for draining the wash water collected in the drainage sump is connected to an outer lower portion of the drainage sump 124. Here, the drainage unit 126 discharges the wash water collected in the drain sump by the drain pipe and the drain pump.

On the other hand, the inside of the drain sump 124 is provided with a heater 125 for heating the washing water stored in the tub 120, the heater 125 can increase the washing effect during washing by heating the washing water. .

In addition, the heater 125 heats the washing water remaining in the drain sump 124 to facilitate the operation of the heat pump provided in the air supply device 160 when drying the laundry, and the heater 125 is heated by the air supply device 160. The circulation passages 162, 163, and 168 of the circulated air may be preheated.

In addition, the air discharge hole 123 is provided along the longitudinal direction of the tub 120, but is preferably provided spaced apart from the straight line passing through the center of the tub 120).

Here, the position of the air discharge hole 123 is to allow the air inside the tub 120 to be easily discharged from the tub 120 through the air discharge hole 123 when the drum 150 is rotated.

The drum 150 is provided inside an empty cylindrical shape and is located inside the tub 120, and is rotated inside the tub 120 by a motor 140 provided outside the tub 120.

Here, the motor 140 is a stator 141 fixed to the rear surface of the tub 120, the stator 141 and the rotor 142 rotating by electromagnetic action, through the rear surface of the tub 120, the drum 150 ) May be provided as a rotating shaft 152 connecting the rear surface of the rotor 142.

On the other hand, the drum 150 is provided with a drum opening 151 communicating with the inlet 114 and the tub opening 122, so that the user may input laundry into the drum 150 through the inlet 114, or the drum (150) It is possible to withdraw the laundry stored therein to the outside of the cabinet (110).

When the clothing processing apparatus 100 of the present invention is provided in a form capable of washing and drying laundry, a detergent supply unit 180 in which detergent supplied to the tub 120 is stored may be further provided inside the cabinet 110. .

The detergent supply unit 180 guides the detergent stored in the storage unit 181 (see FIG. 5) and the detergent stored in the storage unit 181 into the tub 120 in a drawer shape that can be withdrawn from the cabinet 110. Detergent supply pipe 182 (see Fig. 5), located on one side of the control panel 111 may be provided with a storage unit handle 183 that allows the user to withdraw the storage unit 181 from the cabinet 110. .

The storage unit 181 receives water from a water supply source (not shown) provided on the outside of the clothing processing apparatus 100. When water is supplied to the storage unit 181 through the water supply source, detergent in the storage unit 181 is provided. Is supplied to the tub 120 through the detergent supply pipe 182 together with water.

As shown in FIG. 4, the air supply device 160 guides air drawn from the inside of the tub 120 to the front surface of the tub 120 (one surface of the tub formed in the direction in which the inlet 114 is located). It includes a circulation flow path (162, 163, 168), an air supply device 160 provided inside the circulation flow path (162, 163, 168), a blowing fan 167 for circulating the air inside the tub 120.

The circulation passages 162, 163, and 168 may be provided so that air drawn from the rear of the tub 120 moves into the tub 120 through the front surface of the tub 120. The air is drawn from the upper rear of the circumferential surface of 120), and the circulation passages 162, 163, and 168 for discharging air to the tub 120 through the upper front of the circumferential surface of the tub 120 are illustrated as an example.

Meanwhile, the circulation passages 162, 163, and 168 connect the suction duct 162 fixed to the air discharge hole 123 provided in the tub 120, the suction duct 162 and the blowing fan 167 to supply air. A connection duct 163 to which the device 160 is fixed may be provided as a discharge duct 168 connecting the blowing fan 167 and the gasket 130. The circulation passages 162, 163, and 168 may be provided along the diagonal direction with respect to the upper surface of the tub 120.

The suction duct 162 is a flow path through which air inside the tub 120 is drawn through the air discharge hole 123 located at the rear of the circumferential surface of the tub 120, and the suction duct 162 is a vibration insulating member (rubber, etc. City) is preferred. The vibration isolating member is to prevent the vibration transmitted to the tub 120 when the drum 150 rotates from being transmitted to the connection duct 163 and the air supply device 160 through the suction duct 162.

In addition, the suction duct 162 may be further provided with bellows in order to more effectively prevent the vibration transmitted to the tub 120 from being transmitted to the connection duct 163 and the air supply device 160. Here, the corrugated pipe may be provided in the entire area of the suction duct 162, or may be provided only in a partial area of the suction duct 162 (eg, a coupling portion of the connection duct 163).

The discharge duct 168 is a means for guiding the air discharged from the connection duct 163 through the blowing fan 167 into the tub 120, one end being fixed to the blowing fan 167 and the other end to the gasket 130 It is connected to the provided duct connection hole (131).

When the drum 150 rotates, the gasket 130 and the discharge duct 168 are prevented from being transmitted to the tub 120 through the discharge duct 168 to the blowing fan 167 or the connection duct 163. ) It is preferable that at least one of the vibration insulating member (or elastic member) is provided.

On the other hand, since the blowing fan 167 is provided between the air supply device 160 and the discharge duct 168, the blowing fan 167 provided in the present invention is positive pressure (positive pressure, positive pressure) in front of the air supply device 160. ) Is generated so that air does not pass through the air supply device 160, but generates negative pressure (negative pressure) at the rear of the air supply device 160 to allow air to pass through the air supply device 160.

Here, when the blowing fan 167 generates a positive pressure in front of the air supply device 160 so that the air passes through the air supply device 160, a part of the air inside the connection duct 163 air supply device 160 It is easily moved to, but there is a problem that some cannot be easily moved to the air supply device 160.

That is, most of the air discharged from the blower fan 167 is easily moved toward the air supply device 160, but some of the air discharged from the blower fan 167 has the shape of the connection duct 163 or the structure of the blower fan. In some cases, the air supply device 160 may not move quickly.

Therefore, in the structure in which the blower fan 167 is positioned before the air supply device 160 and forcibly blows air toward the air supply device 160 (a structure that forms a positive pressure in front of the air supply device 160), the connection duct ( Since the amount of air passing through the cross section of 163) is not constant depending on the position of the connection duct 163, a problem may arise in that heat exchange efficiency is low.

However, the blower fan 167 provided in the clothing processing apparatus 100 of the present invention is located between the air supply unit 160 and the discharge duct 168 connected to the front surface of the tub (air supply unit 160 and Since the blower fan 167 is sequentially passed), the above-described problem can be solved.

Therefore, in the case of the air supply device 160 of the present invention, as shown in FIG. 6, a blower fan is positioned between the air supply device 160 and the discharge duct 168 to generate sound pressure at the rear of the air supply device 160. To be able to.

That is, when a negative pressure is generated at the rear of the air supply device 160, the amount of air moving along the connection duct 163 to the air supply device 160 becomes constant over the entire cross-section of the connection duct 163 so that the blowing fan ( 167) compared to the structure located at the tip of the air supply device 160, the heat exchange efficiency between the air and the air supply device 160 is high, thereby providing a clothes processing device having high drying efficiency.

Meanwhile, the air supply device 160 of the present invention may be provided to heat and supply air by a heat pump. When the air supply device 160 is provided with a heat pump, the heat exchange unit 200 (evaporator 220 and condenser 240) of the heat pump is fixed inside the connection duct 163, and the compressor 165 of the heat pump Is provided on the outside of the connection duct 163.

Here, the heat pump is provided with a compressor 165, a condenser 240, an expansion valve (not shown), an evaporator 220, and refrigerant by the compressor to the compressor 165, the condenser 240, the expansion valve, the evaporator 220 The air is heated while circulating.

Here, the evaporator 220 and the condenser 240 are located inside the connection duct 163. Meanwhile, the connection duct 163 provided with the evaporator 220 and the condenser 240 is located above the circumferential surface of the tub 120, and the evaporator 220 and the condenser 240 are inside the connection duct 163. It is arranged in a direction parallel to the axial direction of the tub 120.

Therefore, the space in which the evaporator 220 is located and the space in which the condenser 240 is located may be different in size due to a difference in the circumferential surface of the tub 120. That is, the height of the connection duct 163 of the portion where the evaporator 220 is fixed may be lower than the height of the connection duct 163 of the portion where the condenser 240 is fixed.

When the width of the connection duct 163 formed along the longitudinal direction of the tub 120 is constant, if the heights of the spaces provided with the evaporator 220 and the condenser 240 are different from each other, one of the other is changed by one heat exchange capacity. The heat exchange capacity of may be limited. To prevent this, the area ratio of the evaporator 220 and the condenser 240 provided in the present invention is preferably 1:1.3 to 1:1.6.

The heat exchange unit 200 is circulated between the condenser 240, the expansion valve, and the evaporator 220 by the compressor 165. At the same time, while the blowing fan 167 of the air supply device 160 is operated, the air of the tub 120 is circulated through the flow path (suction duct 162, connection duct 163, air supply device 160, exhaust duct 168). ).

Here, the refrigerant is compressed in the compressor 165 and is supplied to the condenser 240 of the air supply device 160 to heat the circulated air, and the refrigerant that has passed through the condenser 240 is moved to the evaporator 220 and evaporator ( 220) to remove the moisture contained in the air.

Here, the evaporator 220 is located first on the air movement path, and the condenser 240 is located later. Therefore, the moisture of the air sucked from the tub 120 is first removed from the evaporator 220 in the movement path of the air circulating through the tub 120 and the air supply device 160, and the air from which the moisture is removed is the condenser 240 It is heated while passing through and is supplied to the tub 120 again.

Here, when the condensed water formed in the evaporator 220 remains inside the connection duct 163, the connection inside the connection duct 163 may be corroded or mixed with moving air and supplied to the laundry being dried. (163) may further include a means for discharging the condensate remaining inside the air supply unit 160 to the outside. Means for discharging the condensed water to the outside of the connection duct 163 may be provided in various forms, a drainage passage (not shown) connecting the air supply unit 160 and the drain 126 or the tub 120 may be an example. Can.

In addition, a separate temperature sensor 161 may be provided inside the heat exchanger 200 to sense the temperature of the air passing through the heat exchanger 200. The temperature sensor 161 detects the temperature of the heat exchange unit 200 itself and provides it to the control unit. Here, the temperature sensor 161 may be preferably provided at the front end or the rear end of the evaporator 220 provided in the heat exchange unit, and the internal temperature and drying of the air supply device 160 according to the temperature detection of the temperature sensor 161 It can also detect the dryness of the laundry.

Here, the control unit controls the operation of the air supply device 160 (specifically a heat pump) according to the temperature detected by the temperature sensor 161. That is, the control unit is an air supply device when the temperature of the air supply device 160 is sensed at a relatively low temperature that is not suitable for performing a drying operation according to the temperature of the air supply device 160 (or the temperature of the clothing processing device). The air supply device is operated after performing the preheating of the air supply device 160 without directly performing the operation of 160.

That is, in the case of the heat pump applied in the present invention, when the initial operation is performed at an excessively low temperature, the condensed water remaining in the evaporator 220 of the heat exchanger 200 is frozen by the low temperature of the evaporator 220 and the evaporator ( The air passage of 220) may be blocked. In this case, heat exchange is not performed in the evaporator 220 of the heat pump, and thus an overload may occur in the compressor 165. In addition, the resistance of the air flow path of the air supply device 160 becomes large, and an overload may be generated in the blowing fan 167 circulating air.

Meanwhile, the controller performs preheating of the air supply device 160 when it is determined that the temperature of the air supply device 160 (or the clothes processing device) detected by the temperature sensor 161 is 5°C or less.

Here, the preheating of the air supply device 160 is provided in the tub 120 may be performed through the heater 125 for heating the washing water. That is, the controller supplies a predetermined amount to the tub 120 (preferably an amount such that the heater 125 provided in the drain sump 124 is locked or an amount such that the heater 125 does not overheat), and the heater (125) is used to heat the washing water supplied.

Thereafter, the control unit may drive the blower fan 167 to circulate the heated air to preheat the flow path of the air supply device 160. Here, the air moved by the blower fan 167 includes moisture generated while the washing water is heated, so that the initial heat exchange operation of the evaporator 220 and the condenser 240 can be smoothly performed.

On the other hand, the compressor 165 is preferably located in a space formed between the circulation passages 162, 163, and 168 and the cabinet 110 among the spaces located above the tub 120. That is, in the case of the circulation passages 162, 163, and 168, the compressor 165 is formed to extend diagonally with respect to the upper surface of the tub 120 to prevent the compressor 165 from overlapping the circulation passages 162, 163, and 168. It is preferably installed in the space between the cabinet and one side of the circulation passage (162, 163, 168).

In addition, the air supply device 160 of the present invention may further include a filter unit 170 to prevent foreign matter such as lint from being deposited on the air supply device 160 by filtering the air.

The filter unit 170 is preferably provided to be detachable from the connection duct 163 through the cabinet 110 as shown in FIGS. 4 to 5. To this end, a filter guide 164 for guiding the movement of the filter unit 170 is formed in the connection duct 163. The cabinet 110 may be further provided with a filter detachable hole (not shown) through which the filter unit 170 may pass.

When the detergent supply unit 180 is not provided in the clothing processing apparatus 100 of the present invention, the filter attachment/detachment unit 119 may be provided to penetrate the cabinet 110 or may be provided to penetrate the control panel 111.

Alternatively, if the detergent supply unit 180 is provided, the filter attaching/detaching unit 119 is provided between the detergent supply unit 180 (preferably provided in a position parallel to the control panel 111) and the control panel 111. Located in the space of the but may be provided to penetrate the cabinet (110).

In addition, the filter attaching and detaching portion 119 is preferably located on the upper portion of the clothing processing apparatus 100, which is compared to the case where the filter portion 170 is located on the lower portion of the clothing processing apparatus 100 without bending the user's back. Since the filter unit 170 can be separated from the clothing processing apparatus 100, there is an effect of improving user convenience.

The filter guide 164 is provided to connect the filter detachable part 119 and the connection duct 163 so that the filter part 170 inserted into the filter detachable part 119 is the suction duct 162 and the air supply device 160 Between them.

Meanwhile, the filter unit 170 includes a filter frame 171 provided with a filter and a handle 172 for entering/exiting the filter unit. In addition, between the filter frame 171 and the handle 172, an elastic part formed of an elastic member or an elastic material may be further provided to allow the filter frame 171 to flow with respect to the handle. The elastic portion 173 so that the filter frame 171 is detachable from the connection duct 163 when the filter detachable portion and the connection duct 163 are not arranged in parallel with a straight line perpendicular to the front surface of the cabinet 110. It is to do.

Hereinafter, a control method of a clothing processing apparatus according to the present invention will be described in detail with reference to the accompanying FIG. 7.

Here, since the control method of the clothing processing apparatus 100 according to an embodiment of the present invention is related to the operation of the air supply device 160 during the initial operation of the drying process, a description of the washing process, the rinsing process, the dehydration process, etc. Is omitted.

In addition, in the case of the control method of the clothing processing apparatus 100 according to an embodiment of the present invention, when the initial operating environment of the clothing processing apparatus 100 is formed at a very low temperature, the heat pump is operated smoothly. Therefore, detailed description of the operation process in the general environment will be omitted.

First, the control unit (not shown) of the clothing processing apparatus 100 according to the present invention detects the temperature of the air supply device 160. Here, the control unit receives the temperature of the air supply device 160 sensed by the temperature sensor 161, and compares the preset temperature to perform preheating of the air supply device 160, or immediately the air supply device 160 ) Is determined (step S110).

Meanwhile, the control unit operates the blowing fan 167 of the air supply device 160 prior to the detection of the temperature sensor 161 to circulate the air inside the tub 120 to the air supply device 160, thereby causing the inside of the tub 120 to be circulated. It is also possible to detect the temperature to detect the temperature of the entire clothing processing apparatus 100.

Here, the preset temperature compared by the control unit may be a temperature at which the evaporator 220 can operate smoothly. Preferably it may have a temperature or a temperature range of about 5 ℃.

Meanwhile, the controller performs preheating of the air supply device 160 when the temperature provided from the temperature sensor 161 does not reach the preset temperature.

First, the controller supplies a predetermined amount of washing water to the tub 120 (step S120). Here, the water supply of the washing water is the same as that of the existing washing water, and there is only a difference in the water supply. In the case of water supply for preheating of the air supply device 160, the amount of the heater 125 provided in the drain sump 124 formed in the tub 120 is locked or the amount of the heater 125 is not overheated. do.

Thereafter, the controller supplies power to the heater 125 located in the drain sump 124 to operate the heater 125 (step S130). Here, as the heater 125 operates, the washing water stored in the drain sump 124 where the heater 125 is located is heated, and the temperature in the tub 120 rises as the washing water is heated.

Meanwhile, the control unit drives the blowing fan of the air supply device 160 as the washing water is heated by the heater 125 (step S140). Here, the heated air in the tub 120 is moved along the flow path of the air supply device 160 by the operation of the blowing fan 167, and the moved air is transferred to the heat exchange unit 200 of the air supply device 160. Pre-heat the evaporator 220 and the condenser 240 located.

Thereafter, the control unit senses the temperature in the air supply device 160 again using the temperature sensor 161, and determines whether the temperature in the air supply device 160 falls within the operating temperature range (step S150). Here, when the temperature in the air supply device 160 is lower than the operating temperature range, the operation of the heater 125 and the blowing fan 167 is maintained to continue preheating the air supply device 160.

Meanwhile, the control unit stops preheating of the air supply device 160 when the temperature in the air supply device 160 is included in the operating temperature range. Here, the operating temperature of the air supply device 160 may be 50°C to 70°C.

Looking at the process of stopping the preheating of the air supply device 100, first, the control unit stops the operation of the washing water heater 125 (step S160). Then, the washing water supplied to the tub is drained (step S170). Here, when the washing water is drained before the heater is stopped, there is a possibility that the heater is overheated. Therefore, the power supply to the heater is stopped first, and the washing water is drained.

Thereafter, the control unit drives the compressor of the heat pump of the air supply device to proceed with the drying process.

Here, the drying process is briefly described, first, the refrigerant circulates between the condenser 240, the expansion valve (not shown), and the evaporator 220 by the compressor 165 of the hint pump. At the same time, while the blowing fan 167 of the air supply device 160 is operated, the air of the tub 120 is a circulation path (suction duct 162, connection duct 163, air supply device 160, exhaust duct 168) ).

Here, the refrigerant is compressed in the compressor 165 and is supplied to the condenser 240 of the air supply device 160 to heat the circulated air, and the refrigerant that has passed through the condenser 240 is moved to the evaporator 220 and evaporator ( 220) to remove the moisture contained in the air.

Here, the evaporator 220 is located first on the air movement path, and the condenser 240 is located later. Therefore, the moisture of the air sucked from the tub 120 is first removed from the evaporator 220 in the movement path of the air circulating through the tub 120 and the air supply device 160, and the air from which the moisture is removed is the condenser 240 It is heated while passing through and supplied back to the tub 120 to dry the object to be dried in the tub 120.

Since the present invention can be implemented in various forms, the scope of the right is not limited to the above-described embodiment. Therefore, if the modified embodiment includes the components of the claims of the present invention, it should be regarded as belonging to the scope of the present invention.

Claims (19)

A tub in which laundry is input and a washing water heater for heating washing water is provided, an air supply device including a heat pump for dehumidifying and heating the air of the tub, and air in which the air is circulated between the tub and the air supply device In the control method of the clothes processing apparatus having a flow path
A temperature sensing step of operating a blower fan to partially circulate the air inside the tub and sensing the temperature of the air;
And a preheating step of preheating the temperature of the air flow path when the detected temperature is lower than a set temperature.
The preheating step,
A water supply step of supplying a predetermined amount of washing water to the tub;
A heating step of heating the air in the tub by operating a washing water heater provided in the tub;
A blowing step of operating the blowing fan for a predetermined time; And
And a determination step of determining whether the temperature of the air is within an operating temperature range of the heat pump,
A heater stopping step of stopping the operation of the washing water heater when the air is included in the operating temperature range; And
And a draining step of draining the washing water of the tub. The method of claim 1, wherein the temperature sensing step detects the temperature at the front end or rear end of the evaporator of the heat pump. The method of claim 1, wherein the temperature sensing step detects the temperature in the tub. delete The control method of claim 1, wherein the washing water heater is stopped after the preheating step, and a drying step of drying the laundry is performed. According to claim 1, The air supply device, the suction duct for sucking the air of the tub, a connecting duct connected to the suction duct, a blowing fan connected to the connecting duct, an exhaust duct for supplying air to the tub Control method of the garment processing apparatus, characterized in that made. The method of claim 6, wherein the evaporator and condenser of the heat pump are provided inside the connection duct. The method of claim 6, wherein the temperature sensing step detects the temperature inside the connection duct. delete delete delete delete A tub equipped with a washing water heater for heating the washing water,
It is connected to the tub, the air supply device including a heat pump for dehumidifying and heating the air in the tub,
It has a control unit for controlling the operation of the air supply and the heat pump,
The air supply device,
A suction duct that sucks air from the tub;
A connection duct connected to the suction duct and equipped with an evaporator and a condenser of the heat pump;
A blowing fan connected to the connection duct;
An exhaust duct that supplies air to the tub; And
Included in the connection duct includes a temperature sensor for sensing the temperature of the air,
The control unit
When the temperature detected by the temperature sensor is lower than the set temperature, the tub is supplied with a predetermined amount of washing water, and the washing water heater is operated to heat the air in the tub,
When the temperature of the heated air is included in the operating temperature range of the heat pump, the clothes processing apparatus characterized by draining the washing water of the tub. delete The clothes processing apparatus according to claim 13, wherein the temperature sensor is provided at the front end or the rear end of the evaporator. The clothes processing apparatus according to claim 13, wherein the blowing fan is driven for a predetermined time when the temperature sensor is operated. The clothes processing apparatus according to claim 13, wherein the blowing fan is driven for a predetermined time when the heater is operated. 14. The apparatus according to claim 13, wherein a predetermined amount of washing water is supplied to the tub when the heater is operated. The clothes processing apparatus according to claim 13, wherein the control unit performs a drying process after the preheating of the air is over.

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