CN104937359A

CN104937359A - Air conditioning apparatus of circulation structure

Info

Publication number: CN104937359A
Application number: CN201380071152.4A
Authority: CN
Inventors: 洪铉轸; 朴璨汀; 金炯泰; 姜相宇; 金起秀
Original assignee: Woongjin Coway Co Ltd
Current assignee: Coway Co Ltd
Priority date: 2013-01-29
Filing date: 2013-12-03
Publication date: 2015-09-23
Anticipated expiration: 2033-12-03
Also published as: KR20140096971A; KR102196725B1; KR20140096964A; JP6452624B2; JP2016511384A; CN104937359B

Abstract

Disclosed is an air conditioning apparatus of circulation structure for circulating air throughout the inside of a room by discharging upwardly the air sucked from the outside through a lower part. The air conditioning apparatus of circulation structure includes: a housing having an internal space, an air suction part, and an air discharge part; a dehumidifying part provided in the inside of the housing for dehumidifying the air moving from the air suction part to the air discharge part; a blowing part provided at the side of the air discharge part for blowing the air inside the housing through the air discharge part toward an object to be dried; a flow line part arranged behind the dehumidifying part for guiding the air passing through the dehumidifying part to the blowing part; and a duct part with one side connected to the flow line part and the other side provided with the blowing part for forming a flowing passage to enable the outside air to flow toward the blowing part.

Description

There is the conditioner of loop structure

Technical field

The present invention relates to the conditioner with loop structure, more specifically, relate to the conditioner had the loop structure of the air of outside from bottom suction and from top discharge thus in the circulation of interior space formation integrated air.

Background technology

Existing dehumidifier comprises: the compressor reducer form the shell of inner space, compressing to circulating refrigerant, the condenser liquefied to the cold-producing medium of the HTHP after compression, the expansion valve that the cold-producing medium of condensed HTHP is expanded and make the evaporation of the cold-producing medium of the HTHP of post liquefaction thus convert the evaporimeter etc. of the cold-producing medium of the low-temp low-pressure of vaporization to.

Existingly carry out drying to room air thus make the dehumidifier of drying object have dehumidification portion and air supplying part in portion in the enclosure, therefore there are the following problems: the pressure loss of the air quantity spued when air supplying part is run increases.

Therefore, in order to carry out drying to dry object ideally, need the air quantity increasing air supplying part, need the output improving air supplying part, in the case, there are the following problems for this reason: compared with the air quantity increased, the noise produced is larger.

In addition, in order to ensure the air quantity of abundance, when arranging jumbo air supplying part, the size of air supplying part increases, therefore there are the following problems: in order to the air supplying part of increase being arranged on the inside of shell of dehumidifier, the size comprising the dehumidifier of shell itself also can maximize.

In addition, when existing dehumidifier, the discharge-amount of air supplying part is limited as described above, and therefore there are the following problems: use in the interior space of dehumidifier and not easily form overall air circulation.

In addition, when existing dehumidifier, due to the air supplying part that is arranged at enclosure and the air discharge portion be integrally formed with shell, there are the following problems: the direction that spues of the dry air spued from dehumidifier is limited.

Summary of the invention

Technical problem

The present invention recognize in the requirement or problem occurred in prior art as described above at least one come.

According to an aspect of the present invention, its object is to provide a kind of conditioner with loop structure, air supplying part is not arranged at enclosure but gives prominence in housing exterior and forms air supplying part by it, thus reduces the pressure loss of the air quantity that spues of air supplying part.

According to an aspect of the present invention, its object is to provide a kind of conditioner with loop structure, it fully guarantees the pressure that spues of air supplying part, thus forms overall air circulation in the interior space.

According to an aspect of the present invention, its object is to provide a kind of conditioner with loop structure, it is directly blown and drying to dry object by the air outlet being formed at shell front surface, and suck humid air by the air intake portion being formed at shell front surface, thus form overall air circulation.

According to an aspect of the present invention, its object is to provide a kind of conditioner with loop structure, air supplying part and shell are not integrally formed, but in housing exterior outstanding formation air supplying part, thus easily regulate the wind direction of the dry air spued to dry object.

According to an aspect of the present invention, its object is to provide a kind of conditioner with loop structure, consist of a mode of selecting and perform dehumidification function and air circulatory function, thus dehumidification function and air circulatory function efficiency are separately improved.

The technical scheme that technical solution problem adopts

As the one side at least partially reached in above-mentioned purpose, the invention provides the conditioner with loop structure, this device comprises: shell, and this shell possesses inner space and is provided with air intake portion and air discharge portion; Dehumidification portion, this dehumidification portion is located at the inside of above-mentioned shell and is dehumidified to the air moving to above-mentioned air discharge portion from above-mentioned air intake portion; Air supplying part, this air supplying part is located at above-mentioned air discharge portion side and the air of inside of the above-mentioned shell that spued to dry object by above-mentioned air discharge portion; Flow path portion, this flow path portion is configured at the rear end of above-mentioned dehumidification portion and the dry air by above-mentioned dehumidification portion is guided to above-mentioned air supplying part; And pipe section, the side of this pipe section is connected with above-mentioned flow path portion, and opposite side is provided with above-mentioned air supplying part, is formed and forms the breakthrough part that extraneous air can flow into the path of above-mentioned air supplying part.

In one embodiment, above-mentioned air intake portion can be located at the bottom of above-mentioned shell, and above-mentioned air discharge portion is located at the top of the front surface of above-mentioned shell.

In addition, in one embodiment, above-mentioned pipe section can be configured to change the air supply direction of above-mentioned air supplying part.

In addition, in one embodiment, above-mentioned pipe section can be configured to can relative to above-mentioned flow path portion in left-right direction with at least one party in above-below direction to rotating.

In addition, in one embodiment, above-mentioned pipe section is set to and can rotates in left-right direction relative to above-mentioned flow path portion, and can possess the first drive division that pipe section is rotated in left-right direction.

In addition, in one embodiment, above-mentioned pipe section can rotate along the vertical direction relative to above-mentioned flow path portion, and can possess the second drive division that pipe section is rotated along the vertical direction.

In addition, in one embodiment, above-mentioned pipe section can comprise: be set to first pipe section that can rotate in left-right direction relative to above-mentioned flow path portion and the first drive division that above-mentioned first pipe section is rotated in left-right direction; Be set to and can rotate along the vertical direction relative to above-mentioned first pipe section and the second pipe portion being provided with above-mentioned air supplying part and the second drive division that above-mentioned second pipe portion is rotated along the vertical direction.

In addition, in one embodiment, above-mentioned pipe section can be provided with the open and close member making above-mentioned breakthrough part opening and closing.

In addition, in one embodiment, can comprise handle portion further, this handle portion is located at the outside of above-mentioned shell, is connected and external force is delivered to above-mentioned open and close member with above-mentioned open and close member.

In addition, in one embodiment, above-mentioned open and close member and handle portion carry out hinge combination in the mode that can rotate along the vertical direction in above-mentioned pipe section, when above-mentioned handle portion is configured to the upside of above-mentioned shell, above-mentioned open and close member is configured to above-mentioned breakthrough part open, when above-mentioned handle portion is configured to the side of above-mentioned shell, above-mentioned open and close member is configured to above-mentioned breakthrough part to close.

In addition, in one embodiment, above-mentioned dehumidification portion can be made up of the heat exchanger of kind of refrigeration cycle.

The conditioner with loop structure involved by one embodiment of the invention with said structure can have at least one in following pattern: state air supplying part work and above-mentioned dehumidification portion quits work thus make the air circulation mode of indoor air circulation the state that above-mentioned breakthrough part is open is upper and lower; State air supplying part and above-mentioned dehumidification portion work thus room air dehumidified and the drying mode of the air after dehumidifying being blown to dry object the state that above-mentioned breakthrough part is open is upper and lower; And the state of to close at above-mentioned breakthrough part is upper and lower states air supplying part and above-mentioned dehumidification portion work thus the indoor dehumidification pattern dehumidified to room air.

In addition, the conditioner with loop structure involved by another embodiment of the present invention can comprise: shell, and this shell possesses inner space and is provided with air intake portion and air discharge portion; Humidifying part, this humidifying part is located at the inside of above-mentioned shell and is provided moisture to the air moving to above-mentioned air discharge portion from above-mentioned air intake portion; Air supplying part, this air supplying part is located at above-mentioned air discharge portion side and the air of inside of the above-mentioned shell that spued by above-mentioned air discharge portion; Flow path portion, this flow path portion is configured at the rear end of above-mentioned humidifying part and the humid air by above-mentioned humidifying part is guided to above-mentioned air supplying part; And pipe section, the side of this pipe section is connected with above-mentioned flow path portion, and opposite side is provided with air supplying part, is formed and forms the breakthrough part that extraneous air can flow into the path of above-mentioned air supplying part.

Wherein, above-mentioned humidifying part can by receiving humidification water from the tank of water and air to the internal flow at above-mentioned shell provides the humidifying unit of moisture to form.

In addition, the conditioner with loop structure involved by another embodiment of the present invention can comprise: shell, and this shell possesses inner space and is provided with air intake portion and air discharge portion; Air cleaning filter, this air cleaning filter is located at the inside of above-mentioned shell and is purified the air moving to above-mentioned air discharge portion from above-mentioned air intake portion; Air supplying part, this air supplying part is located at above-mentioned air discharge portion side and the air of inside of the above-mentioned shell that spued by above-mentioned air discharge portion; Flow path portion, this flow path portion is configured at the rear end of above-mentioned air cleaning filter and guides to above-mentioned air supplying part by by purifying air of above-mentioned air cleaning filter; And pipe section, the side of this pipe section is connected with above-mentioned flow path portion, and opposite side is provided with air supplying part, is formed and forms the breakthrough part that extraneous air can flow into the path of above-mentioned air supplying part.

Wherein, can comprise ultraviolet ray generating apparatus further, it carries out sterilization to the air of the inside flowing into above-mentioned shell and regenerates above-mentioned air cleaning filter.

Invention effect

According to one embodiment of the invention as above, air supplying part is formed at shell front surface top outstanding, by air air-supply to the interior space, suck air by the air intake portion of outer casing underpart, thus have and form integrated air in the interior space and to circulate this effect.

According to one embodiment of the invention, air supplying part is not located at enclosure, but is given prominence to and be formed at housing exterior, thus there is this effect of the pressure loss of the air quantity that spues reducing air supplying part.

According to one embodiment of the invention, use the turbine fan of high air quantity fully to guarantee the air quantity that spues, therefore have and form integrated air in the interior space and to circulate this effect.

According to one embodiment of the invention, air supplying part and shell are not integrally formed, but are formed at housing exterior by outstanding for air supplying part, therefore have this effect of wind direction easily regulating the air spued.

According to one embodiment of the invention, have and the air after humidification, dehumidifying and purification can be carried out the effect of blowing with high air quantity.

According to one embodiment of the invention, be configured to optionally to perform by the function of air dewetting, humidification and purification and the function that makes air circulate, therefore there is the effect by the function of air dewetting, humidification and purification and the function efficiency maximization separately that makes air circulate.

Accompanying drawing explanation

Fig. 1 is that removing is according to the stereogram under the state with the shell of the conditioner of loop structure of one embodiment of the invention.

Fig. 2 is the sectional view with the conditioner of loop structure shown in Fig. 1.

Fig. 3 is the rear isometric view with the conditioner of loop structure shown in Fig. 1.

Fig. 4 is the stereogram of first pipe section with anti-transfer part.

Fig. 5 is the sectional view of the bonding state representing the first pipe section and second pipe portion.

Fig. 6 and Fig. 7 represents that the above-below direction wind direction of the conditioner shown in Fig. 1 with loop structure regulates the sectional view of action.

Fig. 8 represents that the left and right directions wind direction of the conditioner shown in Fig. 1 with loop structure regulates the top view of action.

Fig. 9 with Figure 10 be represent relevant with the opening and closing of breakthrough part, the first mobile route of air and the sectional view of the second mobile route.

Figure 11 is the isometric front view with the conditioner of loop structure according to one embodiment of the invention.

Figure 12 is the rear isometric view with the conditioner of loop structure shown in Figure 11.

Figure 13 is the isometric front view had after the shell of the conditioner of loop structure shown in removing Figure 11.

Figure 14 is the rear isometric view with the shell of the conditioner of loop structure of removing shown in Figure 11.

Figure 15 is the stereogram of the open and close member that comprises of the conditioner with loop structure shown in Figure 11 and handle.

Figure 16 is the sectional view representing the state that breakthrough part is closed by the open and close member with the conditioner of loop structure shown in Figure 11.

Figure 17 is the sectional view representing the state that breakthrough part is opened by the open and close member with the conditioner of loop structure shown in Figure 11.

Figure 18 and Figure 19 represents that the above-below direction wind direction of the conditioner shown in Figure 11 with loop structure regulates the sectional view of action.

Figure 20 is the stereogram representing ultraviolet ray generating apparatus.

Detailed description of the invention

The term that this description uses only is used for specific embodiment is described, is not intended to limit the present invention.In addition, the odd number in this description is expressed and can be comprised plural number expression, unless clearly represented contrary within a context.

Below, with reference to accompanying drawing, the preferred embodiments of the present invention are described.

First, referring to figs. 1 through Figure 10, observe the conditioner 100 with loop structure involved by one embodiment of the invention.

As shown in Figures 1 to 10, the conditioner 100 with loop structure involved by one embodiment of the invention comprises: shell 200, air supplying part 400, flow path portion 500 and pipe section 600, also can comprise auxiliary blowing fan (not shown) further.

In addition, the conditioner 100 with loop structure involved by one embodiment of the invention, according to the function of process air, can comprise at least one in dehumidification portion 310, humidifying part 320 and air cleaning filter 330.

Therefore, in Fig. 1 to Figure 10, dehumidification portion 310, humidifying part 320 and air cleaning filter 330 are unified into a structural element and illustrate.

Herein, the air that above-mentioned dehumidification portion 310 can move to air discharge portion 220 to the air intake portion 210 from following shell 200 dehumidifies.

This dehumidification portion 310 can be made up of the heat exchanger of known kind of refrigeration cycle (evaporimeter).

In addition, above-mentioned humidifying part 320 can be made up of humidifying unit (humidifying filter, heater, ultrasonic vibrator), and this humidifying unit receives humidification water and air to the internal flow at following shell 200 provides moisture from the tank of water.

And above-mentioned air cleaning filter 330 can be consisted of the filter element of also purification by making the air moving to air discharge portion 220 from the air intake portion 210 of following shell 200.

As mentioned above, the conditioner 100 with loop structure involved by one embodiment of the invention possesses at least one in dehumidification portion 310, humidifying part 320 and air cleaning filter 330, can be embodied as the product of the various ways such as dehumidifier, humidifier, air purifier, dehumidifying humidifier, dehumidifying clarifier, Humidifier and dehumidifying humidifying air clarifier.

In addition, above-mentioned shell 200 forms the outward appearance of the conditioner 100 with loop structure involved by one embodiment of the invention, and it has inner space and has air intake portion 210 and air discharge portion 220.

In the inner space of this shell 200, the structural elements such as following air supplying part 400, flow path portion 500, pipe section 600, dehumidification portion 310, humidifying part 320, air cleaning filter 330 can be provided with.

In one embodiment, above-mentioned air intake portion 210 can be formed at the bottom of shell 200, and air discharge portion 220 can be formed at the top of the front surface of shell 200.

As mentioned above, the air of shell 200 periphery can be made to circulate up and down in the structure in shell more than 200 under type configuration air discharge portion 220 and air intake portion 210.

Especially, when possessing dehumidification portion 310, by the air intake portion 210 that is arranged at the bottom of shell 200 to the high heavy air of the humidity sucking shell 200 periphery, the air discharge portion 220 by being arranged at the front surface top of shell 200 spues dry air.

In addition, in one embodiment, ventilating opening 230 can be formed at the back side of shell 200.

Above-mentioned ventilating opening 230 is communicated with the following breakthrough part 630 at the back side being formed at pipe section 600, can form the path that extraneous air flows into conditioner 100 inside with loop structure.

In addition, above-mentioned air supplying part 400 forms air-flow according to the actuating speed of drive motor, thus import air to dehumidification portion 310, humidifying part 320 and air cleaning filter 330, and the air after spuing by dehumidification portion 310, humidifying part 320 and air cleaning filter 330.

In one embodiment, as the blowing fan of air supplying part 400, the turbine fan (turbofan) of high air quantity can be used.

The air supplying part 400 possessing the turbine fan of high air quantity forms air circulation with high wind in the interior space, can to spue high wind to certain objects.

As shown in Figures 3 to 8, air supplying part 400 can be configured to can along the vertical direction and/or left and right directions or up and down direction air supply direction is changed.

Air supplying part 400 is arranged at pipe section 600, pipe section 600 be configured to can along the vertical direction and/or left and right directions rotate, thus be configured to change the air supply direction of air supplying part 400.

Herein, the direction of rotation of air supplying part 400 or the anglec of rotation can carry out multiple setting by user.

In addition, setting can be carried out to air supplying part 400 to make it carry out periodic variation according to controlled condition to spue air quantity.

In addition, in one embodiment, air supplying part 400 is configured to mount and dismount from above-mentioned pipe section 600, and the air supplying part 400 of dismounting can be fixed on the other shelf (not shown) being connected with power supply, thus is used as other air circulator.

Now, air supplying part 400 has power connector end in bottom, is configured to accept power supply from shelf.

On the other hand, above-mentioned flow path portion 500 is configured at the rear end of dehumidification portion 310, humidifying part 320 and air cleaning filter 330, forms and makes the air that have passed after dehumidification portion 310, humidifying part 320 and air cleaning filter 330 move to the mobile route of the air of air supplying part 400.

In one embodiment, one end of flow path portion 500 can be connected with dehumidification portion 310, and the other end can be connected with pipe section 600.

In addition, in one embodiment, flow path portion 500 can have engaging rail 510 on the end direction of pipe section 600 side, and the first pipe section 610 of pipe section 600 can have at the end direction of flow path portion 500 side and is inserted in engaging rail 510 and the insertion rail 611 that blocks.

Above-mentioned engaging rail 510 and insert rail 611 slippage, thus pipe section 600 can be configured to rotate in left-right direction relative to flow path portion 500.

On the other hand, pipe section 600 is configured to side and is connected with flow path portion 500, and opposite side is provided with above-mentioned air supplying part 400, thus can perform the function changed the air supply direction of air supplying part 400.

This pipe section 600 be configured to can relative to flow path portion 500 in left-right direction and/or above-below direction rotate.

For this reason, in one embodiment, the first drive division 650 making pipe section 600 movement to left and right direction can be had.

In addition, in one embodiment, the second drive division 660 making pipe section 600 towards above-below direction movement can be had.

As shown in Fig. 3, Fig. 6 and Fig. 7, the end of pipe section 600 and flow path portion 500 with can in left-right direction or the mode of above-below direction slippage be combined, thus be configured to can in left-right direction and/or above-below direction rotate.

In addition, as shown in Figures 3 to 6, pipe section 600 comprises: the first pipe section 610, can rotate in left-right direction relative to flow path portion 500; And second pipe portion 620, carry out along the vertical direction rotating and being provided with air supplying part 400 relative to the first pipe section 610.

In one embodiment, as shown in Figure 2, the first pipe section 610 of pipe section 600 can be provided with inserts rail 611, and flow path portion 500 can be provided with engaging rail 510.

Herein, flow path portion 500 has engaging rail 510 on the end direction of pipe section 600 side, and the first pipe section 610 of pipe section 600 has at the end direction of flow path portion 500 side and is inserted in engaging rail 510 and the insertion rail 611 that blocks.

Above-mentioned engaging rail 510 and the slippage of insertion rail 611, thus pipe section 600 can be rotated in left-right direction relative to flow path portion 500.

On the other hand, second pipe portion 620 is arranged in the mode of the outer peripheral face surrounding the first pipe section 610, can carry out slippage under making the state connected with the inner peripheral surface in second pipe portion 620 at the outer peripheral face of the first pipe section 610.

By this structure, second pipe portion 620 can rotate along the vertical direction relative to the first pipe section 610.

In one embodiment, pipe section 600 is provided with the first drive division 650 making the movement in left-right direction of above-mentioned first pipe section 610, and is provided with the second drive division 660 making the movement along the vertical direction of above-mentioned second pipe portion 620.

Herein, above-mentioned first drive division 650 represents the driver element making pipe section 600 movement in left-right direction, and above-mentioned second drive division 660 represents the driver element making pipe section 600 movement along the vertical direction.

In one embodiment, the first drive division 650 can be made up of the first tooth bar 651, first pinion 652 and the first drive motor 653, and the second drive division 660 can be made up of the second tooth bar 651, second pinion 662 and the second drive motor 663.

Herein, first, second drive motor can be made up of stepping motor, to the actuating speed of stepping motor and can rotate forward, the direction of rotation such as reverse rotation controls thus regulate the air supply direction of air.

Then, with reference to Fig. 3 and Fig. 6, the spinning movement of the left and right directions of the first pipe section 610 that the first drive division 650 causes is described.

The first tooth bar 651 is circumferentially formed in the end, direction towards above-mentioned flow path portion 500 of above-mentioned first pipe section 610, be provided with first pinion 652 and first drive motor 653 corresponding with above-mentioned first tooth bar 651 in above-mentioned flow path portion 500, thus the first pipe section 610 can be made to rotate in left-right direction.

As shown in Figure 3, above-mentioned first pipe section 610 is provided with the first tooth bar 651 circumferentially formed in the end, direction towards above-mentioned flow path portion 500 of the first pipe section 610, and the first drive motor 653 being arranged at flow path portion 500 can be provided with first pinion 652 corresponding with above-mentioned first tooth bar 651.

If the first drive motor 653 drives, then the first pinion 652 rotates, and the first tooth bar 651 be connected with the first pinion 652 is rotated, and thus, the first pipe section 610 rotates in left-right direction.

Now, the second pipe portion 620 be connected with the first pipe section 610 also rotates in left-right direction along with the rotation of the first pipe section 610, and the air supplying part 400 making the front surface in second pipe portion 620 carry out combining rotates in left-right direction.

Then, with reference to Fig. 3, Fig. 6 and Fig. 7, the spinning movement of the above-below direction in the second pipe portion 620 that the second drive division 660 causes is described.

The second tooth bar 651 is formed along the longitudinal direction at above-mentioned first pipe section 610 upper surface, be provided with second pinion 662 and second drive motor 663 corresponding with above-mentioned second tooth bar 651 in above-mentioned second pipe portion 620, thus second pipe portion 620 can be made to rotate along the vertical direction.

As shown in Figure 3, can be provided with the second tooth bar 651 along the longitudinal direction at the upper surface of the first pipe section 610, the second drive motor 663 being located at the upper surface in second pipe portion 620 can be provided with second gear 662 corresponding with the second tooth bar 651.

If the second drive motor 663 drives, then the second pinion 662 rotates, and the second tooth bar 651 be connected with the second pinion 662 is rotated, and thus, second pipe portion 620 rotates along the vertical direction.

Thus, the air supplying part 400 that the front surface in second pipe portion 620 carries out combining together rotates along the vertical direction.

Can form as follows as another embodiment: namely, be provided with the second tooth bar 651 in a side of the first pipe section 610, the second drive motor 663 being located at a side in second pipe portion 620 is provided with second gear 662 corresponding with the second tooth bar 651.

On the other hand, in one embodiment, the first pipe section 610 and second pipe portion 620 can be provided with the anti-transfer part 670 preventing the rotation caused by the own wt of above-mentioned air supplying part 400.

As an example, above-mentioned anti-transfer part 670 can by being formed at the projection 671 of the first pipe section 610 or groove 672 and being formed at the groove 672 of correspondence in second pipe portion 620 or projection 671 is formed.

In this above-mentioned anti-transfer part 670, by being formed at the combination between the projection 671 of the first pipe section 610 and the groove 672 corresponding with above-mentioned projection 671 being formed at second pipe portion 620, or in contrast, be formed at the combination between the groove 672 of the first pipe section 610 and the projection 671 corresponding with above-mentioned groove 672 being formed at second pipe portion 620, prevent from rotating because of the own wt of air supplying part 400.

On the other hand, the breakthrough part 630 that extraneous air can be made to flow into can be provided with at the back side of pipe section 600.

Breakthrough part 630 is configured to be connected with the ventilating opening 230 of the back part being formed at shell 200, forms the path that extraneous air can flow into shell 200 inside.

In addition, in one embodiment, pipe section 600 can comprise the open and close member 640 breakthrough part 630 being carried out to opening and closing further, thus regulates the amount of flow of the air being flow into pipe section 600 by breakthrough part 630.

Although not shown, open and close member 640 can utilize tooth bar, pinion and drive motor to carry out on-off action.

That is, open and close member 640 is provided with tooth bar (not shown), and drive motor (not shown) is provided with the pinion (not shown) corresponding with above-mentioned tooth bar (not shown).

Herein, if drive motor drives, then pinion rotates, and tooth bar is also along with rotation, thus open and close member 640 moves along the vertical direction and carries out opening and closing to breakthrough part 630.

Opening and closing by open and close member 640 changes the mobile route of air, can regulate the amount of flow of the air through dehumidification portion 310, humidifying part 320 and air cleaning filter 330.

As shown in Figure 9, by air intake portion 210 leaked-in air through the path of flow path portion 500, pipe section 600, air supplying part 400 when, the blast spued when air supplying part 400 is run likely reduces.

Therefore, as shown in Figure 10, when the necessity of the air-treatment function (dehumidifying, humidification and purification of air) by dehumidification portion 310, humidifying part 320 and air cleaning filter 330 is lower, the breakthrough part 630 being located at pipe section 600 can be opened and directly imports air by ventilating opening 230 from outside, thus strengthen the blast of air supplying part 400.

In other words, the conditioner 100 with loop structure involved by one embodiment of the invention can have 2 air flow passage (hereinafter referred to as the first mobile route and the second mobile route).

First mobile route is through the path of air intake portion 210, flow path portion 500, pipe section 600 and air supplying part 400, and the second mobile route is through the path of ventilating opening 230, breakthrough part 630, pipe section 600 and air supplying part 400.

When utilizing open and close member 640 that ventilating opening 230 is open, if the structure of the mobile route of consideration air and length etc., compared to the first mobile route, suck more air by the second mobile route.

On the other hand, as shown in Figure 9, when utilizing open and close member 640 to be closed by breakthrough part 630, the second mobile route of air is closed, and air flows into by means of only the first mobile route via air intake portion 210, flow path portion 500, pipe section 600 and air supplying part 400.

Below, to be provided with above-mentioned air flow passage, the type that the conditioner 100 with loop structure arranged dehumidification portion 310 is described.

When the conditioner 100 with loop structure is provided with dehumidification portion 310, if the humidity of indoor is fully low thus drive the necessity of dehumidification portion 310 less and only also can dry object by the high wind amount of air supplying part 400, then utilize open and close member 640 that breakthrough part 630 is open, extraneous air flows into by the second mobile route.

On the contrary, the humidity due to indoor higher and need drive dehumidification portion 310 when, utilize open and close member 640 to be closed by breakthrough part 630, extraneous air by first mobile route flow into.

Whether the conditioner 100 with loop structure involved by one embodiment of the invention that can carry out above-mentioned action can open according to breakthrough part 630 and whether dehumidification portion 310 works, and arranges air circulation mode, drying mode and indoor dehumidification pattern.

In above-mentioned air circulation mode, above-mentioned breakthrough part 630 is open, and above-mentioned air supplying part 400 works, and above-mentioned dehumidification portion 310 can not work.

Thus, according to air circulation mode action one embodiment of the invention involved by the conditioner 100 with loop structure can when not to making it circulate when indoor air dehumidification.

In addition, in above-mentioned drying mode, above-mentioned breakthrough part 630 is open, and above-mentioned air supplying part 400 and dehumidification portion 310 may work.

Thus, according to drying mode action one embodiment of the invention involved by the conditioner 100 with loop structure can by suppress to dry object by dehumidifying after air blow.

In addition, in above-mentioned indoor dehumidification pattern, above-mentioned breakthrough part 630 is closed, and above-mentioned air supplying part 400 and dehumidification portion 310 may work.

Thus, although according to indoor dehumidification Modal action one embodiment of the invention involved by the conditioner 100 with loop structure will not suppress air to dry object and blow, can dehumidify to room air with low noise.

In addition, in one embodiment, pipe section 600 can be formed according to folding bellow-shaped.

Bellows structure is the tubular element of the foldable structure be made up of the material of softness, and an end of the pipe section 600 formed with bellow-shaped is connected with flow path portion 500, and the other end is connected with air supplying part 400.

By pipe section 600 being formed as tensible and folding bellow-shaped structure, on upper and lower, left and right directions, flexibly air supply direction can be changed.

Bellow-shaped pipe section 600 is made up of the material of softness, therefore himself not easily supports the air supplying part 400 be combined with pipe section 600, can arrange the other fixed component that air supplying part 400 can be fixed on shell 200 support air supplying part 400 this.

On the other hand, as shown in figure 20, be provided with in the type of air cleaning filter 330 at the conditioner 100 with loop structure involved by one embodiment of the invention, can add to be provided with and sterilization is carried out and the ultraviolet ray generating apparatus 340 of regeneration air polishing filter 330 to the air flowing into shell 200 inside.

In one embodiment, ultraviolet ray generating apparatus 340 is configured at the one side of air cleaning filter 330, carries out sterilization to the air flowed by air cleaning filter 330, and air cleaning filter 330 can be made to regenerate.

In addition, although not shown, above-mentioned auxiliary blowing fan (not shown) can be located at the rear end of dehumidification portion 310, humidifying part 320 and air cleaning filter 330 in the inside of shell 200.

In one embodiment, auxiliary blowing fan is configured at the rear of dehumidification portion 310, humidifying part 320 and air cleaning filter 330, the soakage being drawn into the air of shell 200 inside is increased, thus increase the air quantity of air supplying part 400 by air intake portion 210.

In addition, this auxiliary blowing fan can increase the amount of the air by dehumidification portion 310, humidifying part 320 and air cleaning filter 330, therefore can increase spued by air supplying part 400 dehumidifying, humidification, air after purified treatment amount.

In addition, in one embodiment, auxiliary blowing fan and air supplying part 400 can work independently of one another.

Then, with reference to Figure 11 to Figure 19, the conditioner (100) with loop structure involved by another embodiment of the present invention is observed.

As shown in Figure 11 to Figure 19, the conditioner 100 with loop structure involved by another embodiment of the present invention is with the difference of the conditioner 100 with loop structure involved by the one embodiment of the invention set forth referring to figs. 1 through Figure 10, and the external force that the open and close member 910 carrying out opening and closing to breakthrough part 630 is configured to according to being transmitted by handle portion 920 manually carries out action.

In addition, the drier 100 involved by another embodiment of the present invention can add and comprise motion detection unit 950, and the on-off action of this motion detection unit 950 to above-mentioned open and close member 910 detects.

In addition to the above described differences, the shell 200, dehumidification portion 310, humidifying part 320, air cleaning filter 330, air supplying part 400, flow path portion 500, the pipe section 600 that comprise with the conditioner 100 with loop structure involved by the one embodiment of the invention set forth referring to figs. 1 through Figure 10 of shell 200, dehumidification portion 310, humidifying part 320, air cleaning filter 330, air supplying part 400, flow path portion 500, pipe section 600 and auxiliary blowing fan (not shown) is identical in fact with auxiliary blowing fan (not shown).

Therefore, below mainly open and close member 910, handle portion 920 and motion detection unit 950 are described, other structural element is not described.

In another embodiment of the invention, above-mentioned open and close member 910 is the components that can carry out opening and closing to breakthrough part 630.

In addition, this open and close member 910 is made to carry out work by external force.

In another embodiment, open and close member 910 is located at inner side or the outside of the first pipe section 610, can carry out opening and closing to the breakthrough part 630 formed in pipe section 600.

In addition, above-mentioned handle portion 920 is located at the outside of shell 200 and is connected with open and close member 910, thus external force is passed to open and close member 910.

Herein, external force refer in order to open and close member 910 is started thus opening and closing breakthrough part 630, power that handle portion 920 starts by user.

In addition, in another embodiment, open and close member 910 is combined with pipe section 600 hinge, makes to rotate along the vertical direction and carries out opening and closing to breakthrough part 630.

Herein, handle portion 920 can be configured to combine with the rotating shaft 930 of open and close member 910, is subject to external force and rotates along the vertical direction, and open and close member 910 is rotated.

Particularly, as shown in Figure 11 to Figure 15, open and close member 910 is located at the inner side of the first pipe section 610, and the rotating shaft 730 being located at the both sides of open and close member 910 can be carried out hinge with the both sides in the first pipe section 610 and second pipe portion 620 and be combined.

In addition, handle portion 920 can be combined with the rotating shaft 930 of open and close member 910 by the notch 270 being formed at the both sides of shell 200.

Herein, the mobile space of rotating shaft 930 moved left and right in order to ensure the left and right directions along with pipe section 600 rotates, the fore-and-aft direction that the notch 270 being formed at shell 200 is preferably along shell 200 extends to form rectangularly.

On the other hand, as shown in Figure 16 and Figure 17, in the conditioner 100 with loop structure involved by another embodiment of the present invention, opening/closing unit 700 can be configured to when handle portion 920 is configured to the upside of shell 200, and open and close member 910 is open by breakthrough part 630.

On the contrary, when handle portion 920 is configured to the rear side of shell 200, open and close member 910 can be configured to breakthrough part 630 to close.

In such an embodiment, handle portion 920, by handle portion 920 being pulled to upside thus being opened by breakthrough part 630, is pulled to the rear side of shell 200 thus is closed by breakthrough part 630 by user.

On the other hand, in the conditioner 100 with loop structure involved by embodiments of the invention, air-treatment function is not used only to use air circulatory function to environment residing for user, then by sucking in the bottom of shell 200 and towards top bending, the bending structure of air flow circuit that again bends towards the front surface of shell 200, air quantity can being reduced.

If carry out supplementing to it thus will to be formed at the breakthrough part 630 in air supplying part 400 dead astern open, then can spue not by the air of dehumidification portion 310, humidifying part 320 and air cleaning filter 330, air-treatment efficiency thus may reduce.

In order to address this problem, the conditioner 100 with loop structure involved by another embodiment of the present invention can be configured to, when breakthrough part 630 is open, dehumidification portion 310 and humidifying part 320 cease operation automatically, only when breakthrough part 630 is closed, dehumidification portion 310 and humidifying part 320 carry out work.

For this reason, the conditioner 100 with loop structure involved by another embodiment of the present invention can comprise above-mentioned motion detection unit 800.

Whether motion detection unit 800 opens breakthrough part 630 by open and close member 910 is detected.

In one embodiment, motion detection unit 800 can be configured to the switch linking to carry out on/off with the on-off action of opening/closing unit 700.

Such as, motion detection unit 800 is arranged at above-mentioned pipe section 600, can be made up of, but be not limited thereto the microswitch, reed switch etc. carrying out on/off when open and close member 910 is positioned at the position closed by breakthrough part 630 with its interlock.

The conditioner 100 with loop structure involved by another embodiment of the present invention with this structure can be configured to, if user will start handle pull-up, then the work of dehumidification portion 310 stops automatically, if it is drop-down again will to start handle, then dehumidification portion 310 carries out work automatically.

In addition, as mentioned above, the conditioner 100 with loop structure involved by another embodiment of the present invention is configured to, if user is pull-up handle portion 920 in order to mobile device main body, then the work of dehumidification portion 310 and humidifying part 320 stops automatically, and tool has the following advantages: mobile product under the state that can not work in dehumidification portion 310 and humidifying part 320.

The present invention illustrates specific embodiment and illustrates, but carries out various correction and change to the present invention in the scope being to be understood that the thought of the present invention that those of ordinary skill in the art can record in the claims below not departing from and field.

Claims

1. there is a conditioner for loop structure, it is characterized in that, comprising:

Shell, this shell possesses inner space and is provided with air intake portion and air discharge portion;

Dehumidification portion, this dehumidification portion is located at the inside of described shell and is dehumidified to the air moving to described air discharge portion from described air intake portion;

Air supplying part, this air supplying part is located at described air discharge portion side and the air of inside of the described shell that spued to dry object by described air discharge portion;

Flow path portion, this flow path portion is configured at the rear end of described dehumidification portion and the dry air by described dehumidification portion is guided to described air supplying part; And

Pipe section, the side of this pipe section is connected with described flow path portion, and opposite side is provided with above-mentioned air supplying part, and is formed with breakthrough part, and this breakthrough part forms the path that extraneous air can flow into described air supplying part.

2. there is the conditioner of loop structure as claimed in claim 1, it is characterized in that,

Described air intake portion is located at the bottom of described shell,

Described air discharge portion is located at the top of the front surface of described shell.

3. there is the conditioner of loop structure as claimed in claim 1, it is characterized in that,

Described pipe section is configured to change the air supply direction of described air supplying part.

4. there is the conditioner of loop structure as claimed in claim 3, it is characterized in that,

Described pipe section is configured to rotate with at least one direction in above-below direction in left-right direction relative to described flow path portion.

5. there is the conditioner of loop structure as claimed in claim 4, it is characterized in that,

Described pipe section can rotate in left-right direction relative to described flow path portion, and is provided with the first drive division that described pipe section is rotated in left-right direction.

6. there is the conditioner of loop structure as claimed in claim 4, it is characterized in that,

Described pipe section is set to and can rotates along the vertical direction relative to described flow path portion, and is provided with the second drive division that described pipe section is rotated along the vertical direction.

7. there is the conditioner of loop structure as claimed in claim 4, it is characterized in that,

Described pipe section comprises:

Be set to first pipe section that can rotate in left-right direction relative to described flow path portion and the first drive division that described first pipe section is rotated in left-right direction;

Be set to and can rotate along the vertical direction relative to described first pipe section and the second pipe portion being provided with described air supplying part and the second drive division that described second pipe portion is rotated along the vertical direction.

8. there is the conditioner of loop structure as claimed in claim 1, it is characterized in that,

Described pipe section is provided with the open and close member described breakthrough part being carried out to opening and closing.

9. there is the conditioner of loop structure as claimed in claim 8, it is characterized in that,

Comprise handle portion further, this handle portion is located at the outside of described shell, is connected and external force is passed to described open and close member with described open and close member.

10. there is the conditioner of loop structure as claimed in claim 9, it is characterized in that,

Described open and close member and handle portion carry out hinge combination in the mode that can rotate along the vertical direction in described pipe section,

When described handle portion is configured to the upside of described shell, described open and close member is configured to described breakthrough part open, and when described handle portion is configured to the side of described shell, described open and close member is configured to described breakthrough part to close.

11. conditioners as claimed in claim 1 with loop structure, is characterized in that,

Described dehumidification portion is made up of the heat exchanger of kind of refrigeration cycle.

12. conditioners as claimed in claim 1 with loop structure, is characterized in that,

Have under the state that described breakthrough part is open, described air supplying part work and described dehumidification portion quits work thus make the air circulation mode of indoor air circulation.

13. conditioners as claimed in claim 1 with loop structure, is characterized in that,

Have under the state that described breakthrough part is open, described air supplying part and described dehumidification portion work thus room air is dehumidified and the drying mode of the air after dehumidifying being blown to dry object.

14. conditioners as claimed in claim 1 with loop structure, is characterized in that,

Under there is the state of closing at described breakthrough part, described air supplying part and described dehumidification portion work thus the indoor dehumidification pattern that room air is dehumidified.

15. conditioners as claimed in claim 1 with loop structure, is characterized in that having at least one in following pattern:

Under the state that described breakthrough part is open, described air supplying part work and described dehumidification portion quits work thus make the air circulation mode of indoor air circulation;

Under the state that described breakthrough part is open, described air supplying part and described dehumidification portion work thus room air is dehumidified and the drying mode of the air after dehumidifying being blown to dry object;

Under the state that described breakthrough part is closed, described air supplying part and described dehumidification portion work thus the indoor dehumidification pattern that room air is dehumidified.

16. 1 kinds of conditioners with loop structure, is characterized in that, comprising:

Humidifying part, this humidifying part is located at the inside of described shell and is provided moisture to the air moving to described air discharge portion from described air intake portion;

Air supplying part, this air supplying part is located at described air discharge portion side and the air of inside of the described shell that spued by described air discharge portion;

Flow path portion, this flow path portion is configured at the rear end of described humidifying part and the humid air by described humidifying part is guided to described air supplying part; And

Pipe section, the side of this pipe section is connected with described flow path portion, and opposite side is provided with air supplying part, and is formed with breakthrough part, and this breakthrough part forms the path that extraneous air can flow into described air supplying part.

17. conditioners as claimed in claim 16 with loop structure, is characterized in that,

Described air intake portion is located at the bottom of described shell,

18. conditioners as claimed in claim 16 with loop structure, is characterized in that,

19. conditioners as claimed in claim 18 with loop structure, is characterized in that,

20. conditioners as claimed in claim 19 with loop structure, is characterized in that,

Described pipe section comprises:

21. conditioners as claimed in claim 16 with loop structure, is characterized in that,

22. conditioners as claimed in claim 21 with loop structure, is characterized in that,

23. conditioners as claimed in claim 16 with loop structure, is characterized in that,

Described humidifying part is by receiving humidification water from the tank of water and air to the internal flow at described shell provides the humidifying unit of moisture to form.

24. 1 kinds of conditioners with loop structure, is characterized in that, comprising:

Air cleaning filter, this air cleaning filter is located at the inside of described shell and is purified the air moving to described air discharge portion from described air intake portion;

Flow path portion, this flow path portion is configured at the rear end of described air cleaning filter and guides to described air supplying part by by purifying air of described air cleaning filter; And

25. conditioners as claimed in claim 24 with loop structure, is characterized in that,

Described air intake portion is located at the bottom of described shell,

26. conditioners as claimed in claim 24 with loop structure, is characterized in that,

27. conditioners as claimed in claim 26 with loop structure, is characterized in that,

28. conditioners as claimed in claim 27 with loop structure, is characterized in that,

Described pipe section comprises:

29. conditioners as claimed in claim 24 with loop structure, is characterized in that,

30. conditioners as claimed in claim 29 with loop structure, is characterized in that,

31. conditioners as claimed in claim 24 with loop structure, is characterized in that,

Comprise further and sterilization is carried out to the air of the inside flowing into described shell and regenerates the ultraviolet ray generating apparatus of described air cleaning filter.