CN219199347U - Dehumidifier - Google Patents

Abstract

The present disclosure relates to a dehumidifier, a control method thereof, and an intelligent home system, the dehumidifier comprising: the machine body comprises an air inlet, a first air outlet and a second air outlet, and the air inlet and the first air outlet are arranged oppositely; the evaporator is arranged in the machine body close to the air inlet; the condenser is arranged in the machine body close to the first air outlet; the baffle component is movably arranged in the machine body, and in a first state, the baffle component opens the second air outlet and is abutted to the evaporator so as to separate the machine body into a first air channel and a second air channel which are overlapped, and simultaneously, cold air operation and dehumidification operation are performed; in the second state, the baffle component closes the second air outlet to execute dehumidification operation. According to the technical scheme, the technical problem of single function of the traditional dehumidifier is effectively solved, so that the dehumidifier has a dehumidification function and an air cooling function simultaneously, and the practicability and the adaptability of the dehumidifier are effectively improved.

Description

Dehumidifier

Technical Field

The present disclosure relates to the field of household appliances, and more particularly, to a dehumidifier.

Background

A dehumidifier, which is also called a dehumidifier, dehumidifier or dehumidifier, is configured to liquefy moisture in air into water droplets by using the operation of an internal compressor and the circulation of air, thereby maintaining the relative humidity of the environment at 50 to 60%. In the related art, a dehumidifier mainly comprises a compressor, a heat exchanger, fan blades, a water tank and other parts. The dehumidifier firstly sucks the moist air into the dehumidifier by utilizing the fan blades, then liquefies the moisture in the air into water drops through the low-temperature heat exchanger, finally collects the water drops through the water tank, and discharges the treated dry air out of the dehumidifier to finish the drying of the moist air.

However, the main function of the conventional dehumidifier is to adjust the ambient humidity, and the conventional dehumidifier does not have a cooling function. Thus, after the dehumidifier is operated for a long time, the ambient temperature can be increased, and the comfort of the ambient temperature is reduced.

Disclosure of Invention

The present disclosure provides a dehumidifier to solve the technical problem of single function of the conventional dehumidifier.

To this end, in a first aspect, the present disclosure provides a dehumidifier comprising:

the machine body comprises an air inlet, a first air outlet and a second air outlet, and the air inlet and the first air outlet are arranged oppositely;

the evaporator is arranged in the machine body close to the air inlet;

the condenser is arranged in the machine body close to the first air outlet;

the baffle component is movably arranged in the machine body, and in a first state, the baffle component opens the second air outlet and is abutted to the evaporator so as to separate the machine body into a first air channel and a second air channel which are overlapped, and simultaneously, cold air operation and dehumidification operation are performed; in the second state, the baffle component closes the second air outlet to execute dehumidification operation.

In one possible embodiment, the baffle assembly includes a first support member and a blocking member connected, the first support member being disposed between the evaporator and the condenser, the blocking member being movable relative to the first support member to open or close the second air outlet.

In one possible embodiment, the barrier assembly further comprises a rotation shaft and a rotation driving member, the barrier being rotatably connected to the first support member by the rotation shaft; the output end of the rotation driving piece is connected with the rotation shaft so as to drive the blocking piece to rotate.

In one possible embodiment, the first support comprises a support frame and two coamings respectively connected to two opposite sides of the support frame, one side of the two coamings away from the support frame is abutted to the evaporator, and the support frame is abutted to the condenser;

the separation piece is rotatably connected to the support frame and is positioned above the condenser.

In one possible implementation mode, the support frame comprises a wind passing frame, a sealing plate and a protection plate, wherein a wind passing window is arranged on the wind passing frame, the sealing plate is connected to the wind passing frame, and the sealing plate extends back to the evaporator to form an inverted L-shaped structure; the protective plate is arranged on one side of the sealing plate, which is far away from the air passing frame, and extends back to the air passing frame;

the condenser is embedded in the inverted L-shaped structure, and the blocking piece is rotationally connected to one side of the sealing plate, which is far away from the evaporator.

In one possible embodiment, the dehumidifier further comprises a compressor assembly, the compressor assembly comprises a second support piece, a compressor and a water receiving piece, the second support piece is arranged in the machine body, the water receiving piece is connected to the second support piece, the water receiving piece is transversely arranged to divide the machine body into an air duct chamber and a chassis chamber which are overlapped, and the compressor is arranged in the chassis chamber;

the evaporator, the condenser and the baffle assembly are all connected to the water receiving piece and are all positioned in the air duct cavity.

In one possible embodiment, the housing is provided with a mounting slot, the mounting slot being in communication with the water piece, and the compressor assembly further comprises a water tank detachably connected to the mounting slot.

In one possible embodiment, the baffle assembly is disposed between the evaporator and the condenser, the dehumidifier further comprises a first air duct assembly and a second air duct assembly, the first air duct assembly is connected between the condenser and the first air outlet to form a first chamber between the condenser and the first air duct assembly; the second air duct component is connected between the evaporator and the second air outlet, and is connected above the baffle component in a sealing way so as to form a second cavity among the evaporator, the baffle component and the second air duct component;

in the first state, the barrier assembly separates the second chamber to form two independent stacked cells.

In one possible implementation manner, the first air duct assembly comprises a first guide ring, first fan blades and a first driving piece, wherein the first guide ring is connected between the condenser and the first air outlet, the first fan blades are rotationally connected with the first guide ring, and the first driving piece is used for driving the first fan blades to rotate;

the second air duct component comprises a second guide ring, second fan blades and a second driving piece, wherein the second guide ring is connected between the evaporator and the second air outlet, the second fan blades are rotationally connected to the second guide ring, and the second driving piece is used for driving the second fan blades to rotate.

In one possible embodiment, the machine body comprises a front shell, a rear shell and a base, and the front shell is buckled with the rear shell in the width direction of the machine body; in the height direction of the machine body, the front shell and the rear shell are both connected to the base;

the air inlet is arranged on the front shell, and the first air outlet and the second air outlet are arranged on the rear shell.

According to the dehumidifier provided by the present disclosure, the dehumidifier includes: the machine body comprises an air inlet, a first air outlet and a second air outlet, and the air inlet and the first air outlet are arranged oppositely; the evaporator is arranged in the machine body close to the air inlet; the condenser is arranged in the machine body close to the first air outlet; the baffle component is movably arranged in the machine body, and in a first state, the baffle component opens the second air outlet and is abutted to the evaporator so as to separate the machine body into a first air channel and a second air channel which are overlapped, and simultaneously, cold air operation and dehumidification operation are performed; in the second state, the baffle component closes the second air outlet to execute dehumidification operation. According to the technical scheme, the specific configuration of the dehumidifier is optimally arranged to enrich the use functions of the dehumidifier, so that the dehumidifier can realize the dehumidification function and the cooling function, the requirements of users are met to the maximum extent, and the satisfaction of the users is improved. Specifically, the dehumidifier is configured to include at least a combination member of a body, an evaporator, a condenser, and a barrier member, and the evaporator, the condenser, and the barrier member are all configured in the body. The separation assembly can separate the inside of the machine body into at least two air channels by changing the relative position relationship of the separation assembly so as to realize the cold air effect and the warm air effect at the same time, thereby achieving the combined effect of reducing the indoor temperature during dehumidification; the baffle assembly can also close the second air outlet by changing the relative position of the baffle assembly, so that only a single warm air duct is formed in the machine body, and the dehumidification effect is achieved. In addition, the first air duct and the second air duct are overlapped, so that reasonable application to the body space is realized, and the miniaturization process of the dehumidifier is facilitated.

Drawings

In order to more clearly illustrate the embodiments of the present disclosure or the solutions in the prior art, the drawings that are required for the description of the embodiments or the prior art will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort. In addition, in the drawings, like parts are designated with like reference numerals and the drawings are not drawn to actual scale.

Fig. 1 is a schematic perspective view of a first perspective view of a dehumidifier according to an embodiment of the present disclosure;

fig. 2 is a schematic view of a second perspective structure of a dehumidifier according to an embodiment of the present disclosure;

FIG. 3 is a cross-sectional view of FIG. 2 on side D-D, wherein short arrows indicate air flow direction;

fig. 4 is a first partial schematic structural view of a dehumidifier provided in an embodiment of the present disclosure;

FIG. 5 is a cross-sectional view of FIG. 4 on side B-B;

FIG. 6 is a schematic view of a second partial structure provided by an embodiment of the present disclosure;

FIG. 7 is a cross-sectional view of FIG. 6 on side A-A;

FIG. 8 is an exploded view of a spacer assembly provided by an embodiment of the present disclosure;

FIG. 9 is a schematic view of a third partial structure provided by an embodiment of the present disclosure;

fig. 10 is a cross-sectional view of fig. 9 at the side C-C in a first state;

FIG. 11 is a cross-sectional view of FIG. 9 at the side C-C in a second state;

FIG. 12 is an exploded view of a compressor assembly provided by an embodiment of the present disclosure;

FIG. 13 is an exploded view of a first air chute assembly provided by an embodiment of the present disclosure;

FIG. 14 is an exploded view of a second air chute assembly provided by an embodiment of the present disclosure;

fig. 15 is an exploded view of a body provided in an embodiment of the present disclosure.

Reference numerals illustrate:

100. a body; 101. an air inlet; 102. a first air outlet; 103. a second air outlet; 110. a front shell; 120. a rear case; 130. a base;

200. an evaporator;

300. a condenser;

400. a spacer assembly; 410. a first support; 411. a support frame; 4111. a wind passing frame; 4112. a sealing plate; 4113. a protective plate; 412. coaming plate; 420. a barrier; 430. a rotating shaft; 440. a rotary driving member;

500. a compressor assembly; 510. a second support; 520. a compressor; 530. a water receiving member; 540. a water tank;

600. a first air duct assembly; 610. a first deflector ring; 620. a first fan blade; 630. a first driving member;

700. a second air duct assembly; 710. a second guide ring; 720. a second fan blade; 730. a second driving member;

alpha, a first air duct; beta, the second air duct; gamma, a first chamber; delta, a second chamber; z, height direction; x, width direction.

Detailed Description

For the purposes of making the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present disclosure, and it is apparent that the described embodiments are some, but not all, embodiments of the present disclosure. All other embodiments, which can be made by one of ordinary skill in the art without undue burden from the disclosure, are within the scope of the disclosure.

Referring to fig. 1 to 5, an embodiment of the present disclosure provides a dehumidifier including: the refrigerator body 100, the evaporator 200, the condenser 300 and the barrier assembly 400.

The machine body 100 comprises an air inlet 101, a first air outlet 102 and a second air outlet 103, wherein the air inlet 101 and the first air outlet 102 are oppositely arranged;

the evaporator 200 is arranged in the machine body 100 near the air inlet 101;

the condenser 300 is arranged in the machine body 100 near the first air outlet 102;

the baffle assembly 400 is movably arranged in the machine body 100, and in a first state, the baffle assembly 400 opens the second air outlet 103 and is abutted to the evaporator 200 so as to separate the machine body 100 into a first air channel alpha and a second air channel beta which are overlapped, and simultaneously, cold air operation and dehumidification operation are performed; in the second state, the barrier assembly 400 closes the second air outlet 103 to form the first air duct α in the machine body 100, and performs the dehumidification operation.

In this embodiment, the specific configuration of the dehumidifier is set up in an optimized manner, so as to enrich the use functions of the dehumidifier, so that the dehumidifier not only can realize the dehumidification function, but also can realize the cooling function, thereby meeting the user demands to the maximum extent and improving the user satisfaction.

Specifically, the dehumidifier is configured to include at least a combination member of the body 100, the evaporator 200, the condenser 300, and the barrier assembly 400, and the evaporator 200, the condenser 300, and the barrier assembly 400 are all disposed in the body 100. The machine body 100 at least comprises an air inlet 101 and two air outlets, and air enters the machine body 100 from the air inlet 101 and is blown out from the two air outlets respectively, so as to achieve different effects.

The evaporator 200 is arranged near the air inlet 101 and is used for forming cold air; the condenser 300 is disposed near the first air outlet 102 for forming warm air. When the baffle assembly 400 is in the first state, it is abutted to the evaporator 200 to separate the machine body 100 into two stacked air channels, thereby forming a dual air channel system, wherein the first air channel α is communicated with the air inlet 101 and the first air outlet 102, and the second air channel β is communicated with the air inlet 101 and the second air outlet 103. Thus, the air entering the machine body 100 from the air inlet 101 flows through the evaporator 200 to form cold air; then, part of the air flows through the condenser 300 in the first air duct alpha, and forms warm air to flow out from the first air outlet 102, so that a dehumidification effect is achieved; the other part of air flows through the second air duct beta and flows out from the second air outlet 103, so that the cooling effect is achieved; thereby realizing the effects of dehumidifying and cooling simultaneously. When the barrier assembly 400 is in the second state, it covers the second air outlet 103, and at this time, only one warm air duct (the first air duct α) remains inside the machine body 100. In this way, the air entering the machine body 100 from the air inlet 101 flows through the evaporator 200, then flows through the condenser 300 entirely, forms warm air, and flows out from the first air outlet 102, thereby achieving the dehumidification effect. In addition, in the second state, since the second air outlet 103 is closed, the air entering the body 100 flows out only from the first air outlet 102, and the dehumidifier has the maximum dehumidifying capability at this time.

It can be appreciated that the present embodiment enables the dehumidifier to realize the dehumidifying function and the cooling function by simultaneously configuring the evaporator 200 and the condenser 300. In addition, by changing the relative position of the baffle assembly 400, the air duct composition in the variable machine body 100 is in a variable state, rather than being constant, so that different functions of the dehumidifier are realized.

In addition, in the first state, the first air duct alpha and the second air duct beta are overlapped, so that reasonable application to the internal space of the machine body 100 is effectively improved, the miniaturized arrangement of the dehumidifier is facilitated, and the industrial production of the multifunctional dehumidifier is realized.

In one example, the condenser 300 and the evaporator 200 are sized to optimize the relative positional and connection relationships of the components within the body 100. Specifically, in the height direction Z of the body 100, the height of the condenser 300 is smaller than the height of the evaporator 200, and the barrier assembly 400 is located above the condenser 300. The present example ensures that the condenser 300 is fully accommodated in the first air duct α without affecting the air temperature in the second air duct β by configuring the size of the condenser 300 to be smaller than the size of the evaporator 200 to directly dispose the barrier assembly 400 above the condenser 300.

In an example, the air inlet 101 and the first air outlet 102 are both disposed on a side wall of the baffle assembly 400, and the second air outlet 103 is disposed on a top wall of the baffle assembly 400. The barrier assembly 400 may have a cross-shaped structure in which a vertical portion thereof extends in the height direction Z of the body 100 and a lateral portion thereof is movable along the vertical portion. The adjustment mechanism of the relative position of the spacer assembly 400 is as follows: in the first state, the two ends of the transverse portion are respectively abutted against the evaporator 200 and the side wall of the machine body 100, so as to separate the internal space of the machine body 100 into two independent air channels, at this time, the first air outlet 102 is communicated with the first air channel α, and the second air outlet 103 is communicated with the second air channel β. In the second state, the transverse portion abuts against the inner side of the top wall of the machine body 100, so as to close the second air outlet 103, so that only the first air channel α remains in the machine body 100, thereby achieving the dehumidification effect.

Referring to fig. 5, 6 and 8, in one possible embodiment, the barrier assembly 400 includes a first support 410 and a barrier 420 connected, the first support 410 being disposed between the evaporator 200 and the condenser 300, the barrier 420 being movable relative to the first support 410 to open or close the second air outlet 103.

In this embodiment, the specific structure of the spacer assembly 400 is optimized. Specifically, the barrier assembly 400 is configured as a combined member including at least the first support 410 and the barrier 420, and the barrier 420 is movably connected to the first support 410, and the second air outlet 103 is opened or closed by changing the relative position between the barrier 420 and the first support 410. For example, but not limited to, the barrier 420 is a baffle.

In one example, to increase the independence of the two air paths, to reduce the interference of air entering the two air paths, a seal is also provided on the side of the barrier 420 adjacent the evaporator 200. The seal abuts the evaporator 200 when the barrier 420 is in the first state, so that on one hand, air interference at the gap between the barrier 420 and the evaporator 200 is reduced, and on the other hand, impact forces experienced when the barrier 420 abuts the evaporator 200 are reduced, and mechanical damage/damage to the evaporator 200 by the barrier 420 is reduced. Such as, but not limited to, a bead seal, a layer of sealant, and the like.

In an example, the air inlet 101 and the first air outlet 102 are both disposed on a side wall of the baffle assembly 400, and the second air outlet 103 is disposed on a top wall of the baffle assembly 400. The barrier 420 is vertically connected to the first support 410 to form a cross-shaped structure. The barrier 420 is reciprocable between the first air outlet 102 and the second air outlet 103. In the first state, the blocking member 420 and the second air outlet 103 have an air channel distance therebetween, at this time, two ends of the blocking member 420 are respectively abutted against the side walls of the evaporator 200 and the machine body 100, and separate the machine body 100 to form two independent air channels, the first air outlet 102 is communicated with the first air channel α, and the second air outlet 103 is communicated with the second air channel β, so that dehumidification and cooling effects can be simultaneously achieved. In the second state, the blocking member 420 abuts against the inner side of the top wall of the machine body 100 to close the second air outlet 103, so that only the first air channel α remains in the machine body 100, thereby achieving the dehumidification effect.

Referring to fig. 8, in one possible embodiment, the barrier assembly 400 further includes a rotation shaft 430 and a rotation driving member 440, and the barrier member 420 is rotatably coupled to the first support member 410 through the rotation shaft 430; the output end of the rotation driving member 440 is connected to the rotation shaft 430 to drive the blocking member 420 to rotate.

In this embodiment, the specific structure of the spacer assembly 400 is optimized to optimize the specific connection mode of the spacer 420 and the first support assembly. Specifically, the spacer assembly 400 is configured to at least include a first supporting member 410, a blocking member 420, a rotating shaft 430, and a combination member of a rotation driving member 440, wherein the rotating shaft 430 is connected to the first supporting member 410, the blocking member 420 is movably connected to the first supporting member 410 through the rotating shaft 430, and the rotation driving member 440 is drivingly connected to the rotating shaft 430, so that the rotating shaft 430 is driven to rotate by the rotation driving member 440, thereby driving the blocking member 420 to rotate, and further realizing adjustment of the position of the blocking member 420. For example, but not limited to, the rotary drive 440 is a drive motor.

Referring to fig. 8, in one possible embodiment, the first support 410 includes a support 411 and two coamings 412 connected to opposite sides of the support 411, respectively, one side of the two coamings 412 away from the support 411 being abutted to the evaporator 200, and the support 411 being abutted to the condenser 300;

the blocking member 420 is rotatably connected to the supporting frame 411 and is located above the condenser 300.

In this embodiment, the specific structure of the first support 410 is optimized to optimize the relative positions of the internal components of the machine body 100, so as to save the occupied space. Specifically, the first support 410 is configured as a combined member including at least a support 411 and two coamings 412, and the two coamings 412 are oppositely connected at two sides of the support 411 to form a C-shaped slot structure. The supporting frame 411 is abutted to one side of the condenser 300 facing the evaporator 200, the shroud 412 is abutted to one side of the evaporator 200 facing the condenser 300, and the blocking member 420 is located above the condenser 300 and rotatably abutted to the evaporator 200, so that a partial chamber with a first air channel α is enclosed by the blocking member 420, the two shroud 412, the evaporator 200 and the condenser 300. It should be appreciated that after entering the partial chamber, air may flow through the condenser 300 through the support 411 and out the first air outlet 102.

In one example, a seal is provided on the side of the shroud 412 remote from the support frame 411 to improve the tightness of the joint between the shroud 412 and the evaporator 200 and to reduce air interference at the gap between the shroud 412 and the evaporator 200. Such as, but not limited to, a bead seal, a layer of sealant, and the like.

Referring to fig. 8, in one possible embodiment, the support 411 includes a wind frame 4111, a sealing plate 4112 and a protection plate 4113, wherein the wind frame 4111 is provided with a wind window, the sealing plate 4112 is connected to the wind frame 4111, and the sealing plate 4112 extends away from the evaporator 200 to form an inverted L-shaped structure; the protection plate 4113 is disposed on a side of the sealing plate 4112 away from the wind frame 4111, and the protection plate 4113 extends away from the wind frame 4111;

the condenser 300 is embedded in the inverted-L structure, and the blocking member 420 is rotatably connected to a side of the sealing plate 4112 away from the evaporator 200.

In this embodiment, the specific structure of the supporting frame 411 is optimized to optimize the positional relationship and the connection relationship of the condenser 300 and the baffle assembly 400, so as to improve the structural compactness of the dehumidifier. Specifically, the support 411 is configured to include at least a combination member of a wind frame 4111, a sealing plate 4112, and a protection plate 4113, which are sequentially connected, and has an inverted L-shaped structure. The configuration of the sealing plate 4112 is advantageous in improving the sealing performance of the first air duct α and the second air duct β, on the one hand, and in enhancing the rigidity protection of the condenser 300, on the other hand. Meanwhile, since the blocking member 420 is rotatably disposed on the side of the sealing plate 4112 away from the evaporator 200, the sealing plate 4112 is disposed to enhance the rigid support of the blocking member 420 and the connection stability between the blocking member 420 and the supporting frame 411.

In a specific example, the air passing frame 4111 is provided with an air passing window, and the air passing frame 4111 has a rectangular frame structure. For example, but not limited to, the wind frame 4111 is formed by connecting two long posts and two short posts end to end. At this time, the sealing plate 4112 is connected to one of the short sides of the wind frame 4111.

In a specific example, the protection plate 4113 includes two side plates and a C-shaped plate, the notch of the C-shaped plate is located at a side far from the sealing plate 4112, the two side plates are respectively connected to opposite sides of the C-shaped plate, and a side far from the C-shaped plate of the two side plates is respectively connected to the two enclosing plates 412. The connection between the C-shaped plate and the sealing plate 4112 is provided with a rotating groove, in which the rotating shaft 430 is movably disposed, and the blocking member 420 rotates between the two plates.

Referring to fig. 5 to 12, in one possible embodiment, the dehumidifier further includes a compressor assembly 500, the compressor assembly 500 includes a second support 510, a compressor 520 and a water receiving member 530, the second support 510 is disposed in the machine body 100, the water receiving member 530 is connected to the second support 510, and the water receiving member 530 is transversely disposed to divide the machine body 100 into an air duct chamber and a chassis chamber stacked, and the compressor 520 is disposed in the chassis chamber;

the evaporator 200, the condenser 300 and the baffle assembly 400 are all connected to the water receiving member 530 and are all located in the air duct chamber.

In this embodiment, the specific structure of the dehumidifier is optimized. Specifically, the dehumidifier is configured to include at least a combination member of the body 100, the evaporator 200, the condenser 300, the barrier assembly 400, and the compressor assembly 500, and the evaporator 200, the condenser 300, the barrier assembly 400, and the compressor assembly 500 are all configured in the body 100. The compressor assembly 500 divides the interior of the housing 100 into two separate chambers, and the dehumidification or cool air operation occurs in the air duct chamber.

Further, the compressor assembly 500 is configured as a combined member including at least the second support 510, the compressor 520, and the water receiving member 530. The second support assembly is connected between the bottom wall of the machine body 100 and the water receiving member 530, and the compressor 520 is disposed on the bottom wall of the machine body 100 and below the water receiving member 530. The water receiving member 530 is transversely disposed, the evaporator 200 is connected to a side of the water receiving member 530 adjacent to the air inlet 101, the condenser 300 is connected to a side of the water receiving member 530 adjacent to the first air outlet 102, and the baffle assembly 400 is connected to the water receiving member 530 and located between the evaporator 200 and the condenser 300. For example, but not limited to, the second support 510 is a support plate and the water receiving member 530 is a water receiving tray.

Referring to fig. 2 and 15, in one possible embodiment, the body 100 is provided with a mounting groove communicating with the water member 530, and the compressor assembly 500 further includes a water tank 540, the water tank 540 being detachably connected to the mounting groove.

In this embodiment, the specific structure of the body 100 is optimized to further optimize the specific structure of the compressor assembly 500. Specifically, the housing 100 is provided with a mounting groove, and the compressor assembly 500 is configured as a combined member including at least the second support 510, the compressor 520, the water receiving member 530, and the water tank 540. The second supporting member 510, the compressor 520 and the water receiving member 530 are disposed inside the machine body 100, the water tank 540 is disposed outside the machine body 100, and the water receiving member 530 is communicated with the mounting groove, so that the accumulated water collected on the water receiving member 530 is transferred to the water tank 540, which is convenient for the user to pour the dehumidified accumulated water in time.

For example, and without limitation, the mounting slot is a C-shaped slot and the water tank 540 may be drawn or fitted into the C-shaped slot. The top of the C-shaped groove is provided with a through hole which communicates with the bottom of the water receiving piece 530. The water tank 540 is an open box body, when the water tank 540 is embedded into the installation groove, accumulated water received by the water receiving part 530 flows into the water tank 540, so that the transfer of accumulated water inside the dehumidifier is completed.

Referring to fig. 9 to 14, in one possible embodiment, the barrier assembly 400 is disposed between the evaporator 200 and the condenser 300, and the dehumidifier further includes a first air duct assembly 600 and a second air duct assembly 700, the first air duct assembly 600 being connected between the condenser 300 and the first air outlet 102 to form a first chamber γ between the condenser 300 and the first air duct assembly 600; the second air duct assembly 700 is connected between the evaporator 200 and the second air outlet 103, and the second air duct assembly 700 is hermetically connected above the barrier assembly 400 to form a second chamber δ among the evaporator 200, the barrier assembly 400 and the second air duct assembly 700;

in the first state, the barrier assembly 400 separates the second chamber δ to form two separate chambers that are stacked.

In this embodiment, the specific structure of the dehumidifier is optimized to optimize the adjustment modes of the first air duct α and the second air duct β. Specifically, the dehumidifier is configured to include at least a combination member of the body 100, the evaporator 200, the condenser 300, the barrier assembly 400, the first air duct assembly 600, and the second air duct assembly 700, and the evaporator 200, the condenser 300, and the barrier assembly 400 are all configured in the body 100. The baffle assembly 400 is disposed between the evaporator 200 and the condenser 300, the evaporator 200 is disposed near the air inlet 101, the condenser 300 is disposed near the first air outlet 102, the first air duct assembly 600 is connected between the condenser 300 and the first air outlet 102, and the second air duct assembly 700 is connected between the evaporator 200 and the second air outlet 103. Thus, the first air duct alpha and the second air duct beta are adjusted by adjusting the communication condition of the first chamber gamma and the second chamber delta.

Specifically, in the first state, the barrier assembly 400 separates the second chamber δ to form two independent chambers stacked up and down, and at this time, the first chamber γ communicates with the independent chambers below to form a space of the first air duct α, and the independent chambers above form a space of the second air duct β separately. Thus, the air entering the machine body 100 from the air inlet 101 flows through the evaporator 200, then is split, and part of the air enters the independent chamber above and flows out from the second air outlet 103 so as to send cold air to the room, thereby realizing the adjustment of the room temperature; the other part enters the independent chamber below, passes through the baffle assembly 400, flows through the condenser 300, enters the first chamber gamma, and flows out from the first air outlet 102 to send warm air to the room, so that the humidity of the room is adjusted.

In the second state, the barrier assembly 400 closes the second air outlet 103, and at this time, the second chamber δ is a complete chamber, and air entering the machine body 100 from the air inlet 101 flows through the evaporator 200, then enters the second chamber δ, then passes through the barrier assembly 400, flows through the condenser 300, enters the first chamber γ, and flows out from the first air outlet 102, so as to send warm air to the room, and realize adjustment of the humidity of the room.

Referring to fig. 13 and 14, in one possible embodiment, the first air duct assembly 600 includes a first guide ring 610, a first fan blade 620, and a first driving member 630, wherein the first guide ring 610 is connected between the condenser 300 and the first air outlet 102, the first fan blade 620 is rotatably connected to the first guide ring 610, and the first driving member 630 is used for driving the first fan blade 620 to rotate;

the second air duct assembly 700 includes a second guiding ring 710, a second fan blade 720 and a second driving member 730, the second guiding ring 710 is connected between the evaporator 200 and the second air outlet 103, the second fan blade 720 is rotatably connected to the second guiding ring 710, and the second driving member 730 is used for driving the second fan blade 720 to rotate.

In this embodiment, the specific structures of the first air duct assembly 600 and the second air duct assembly 700 are optimized. Specifically, the first air duct assembly 600 is configured as a combined component at least including the first guide ring 610, the first fan blades 620, and the first driving element 630. The first deflector 610 is in sealing communication with the condenser 300 and the first air outlet 102 to form a first chamber γ. The first driving member 630 is connected to the first fan 620 to drive the first fan 620 to rotate, and to make the first fan 620 generate an axial suction force, so that the air entering the first chamber γ is blown away from the first fan 620 in the axial direction. Meanwhile, the second air duct assembly 700 is configured as a combined member including at least the second guide ring 710, the second fan blades 720, and the second driving piece 730. The second deflector 710 is in sealed communication with the evaporator 200 and the second air outlet 103 to form a portion of the second chamber δ. The second driving member 730 is connected to the second fan blade 720 to drive the second fan blade 720 to rotate, and to make the second fan blade 720 generate an axial suction force, so that the air entering the second chamber δ is blown away from the second fan blade 720 in the radial direction. For example, and without limitation, the first drive 630 is a drive motor and the second drive 730 is a drive motor.

In an example, the first air duct assembly 600 further includes a first bracket, the first bracket is connected to the first air guiding ring 610, the first driving member 630 is connected to the first bracket, the first fan blade 620 is connected to the first air guiding ring 610, and an output end of the first driving member 630 is connected to the first fan blade 620 to drive the first fan blade 620 to rotate, so as to generate an axial suction force. The second air duct assembly 700 further includes a second support, the second support is connected to the second guide ring 710, the second driving member 730 is connected to the second support, the second fan blade 720 is connected to the second guide ring 710, and an output end of the second driving member 730 is connected to the second fan blade 720, so as to drive the second fan blade 720 to rotate, and generate an axial suction force.

In an example, the first air guiding ring 610 includes a first air guiding ring and a first sealing rib, one end of the first air guiding ring is abutted to the condenser 300, the other end of the first air guiding ring passes out of the first air outlet 102, the first sealing rib is connected to one end of the first air guiding ring close to the condenser 300, and the first sealing member covers the top of the condenser 300, so as to improve the sealing performance of the connection part of the condenser 300 and the first air guiding ring, and improve the rigidity protection of the condenser 300.

In an example, the second air guiding ring 710 includes a second air guiding ring, one end of the second air guiding ring is abutted to the evaporator 200, the other end of the second air guiding ring is abutted to the inner wall of the machine body 100 corresponding to the second air outlet 103, the second sealing rib is disposed at one side of the second air guiding ring away from the baffle assembly 400, and the second sealing rib covers the top of the evaporator 200, so as to improve the sealing performance of the joint between the evaporator 200 and the second air guiding ring; in addition, one side of the second sealing rib away from the second wind guiding ring is abutted to the top wall of the machine body 100, so as to improve the stability of the whole structure.

Referring to fig. 15, in one possible embodiment, the machine body 100 includes a front case 110, a rear case 120, and a base 130, and the front case 110 is fastened to the rear case 120 in a width direction X of the machine body 100; in the height direction Z of the machine body 100, the front case 110 and the rear case 120 are both connected to the base 130;

the air inlet 101 is disposed on the front shell 110, and the first air outlet 102 and the second air outlet 103 are disposed on the rear shell 120.

In this embodiment, the specific structure of the machine body 100 is optimized. Specifically, the body 100 is configured as a combined member including at least a front case 110, a rear case 120, and a base 130, and the front case 110 and the rear case 120 are fitted and then connected to the base 130. The evaporator 200, condenser 300 and baffle assembly 400 are all connected to the base 130. For example, but not limited to, the base 130 is a bottom plate.

In an example, the front shell 110 and the rear shell 120 are dustpan-shaped, the air inlet 101 is formed on the bottom wall of the front shell 110, the first air outlet 102 is formed on the bottom wall of the rear shell 120, and the second air outlet 103 is formed on the top wall of the rear shell 120. Of course, in other embodiments, the second air outlet 103 and the first air outlet 102 may be formed on the same bottom wall of the rear housing 120 at intervals.

It should be noted that in this document, relational terms such as "first" and "second" and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The foregoing is merely a specific embodiment of the disclosure to enable one skilled in the art to understand or practice the disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the present disclosure is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. A dehumidifier, comprising:

the machine body comprises an air inlet, a first air outlet and a second air outlet, wherein the air inlet and the first air outlet are oppositely arranged;

the evaporator is arranged in the machine body close to the air inlet;

the condenser is arranged in the machine body close to the first air outlet;

the baffle component is movably arranged in the machine body, and in a first state, the baffle component opens the second air outlet and is abutted to the evaporator so as to separate the machine body into a first air channel and a second air channel which are overlapped, and simultaneously, cold air operation and dehumidification operation are performed; and in the second state, the baffle component closes the second air outlet so as to execute dehumidification operation.

2. The dehumidifier of claim 1, wherein the baffle assembly comprises a first support and a barrier connected, the first support being disposed between the evaporator and the condenser, the barrier being movable relative to the first support to open or close the second air outlet.

3. The dehumidifier of claim 2, wherein the barrier assembly further comprises a rotational shaft and a rotational drive, the barrier being rotatably coupled to the first support via the rotational shaft; the output end of the rotation driving piece is connected with the rotation shaft so as to drive the blocking piece to rotate.

4. The dehumidifier of claim 2, wherein the first support comprises a support frame and two coamings connected to opposite sides of the support frame, respectively, one side of the two coamings remote from the support frame being in abutment with the evaporator, the support frame being in abutment with the condenser;

the blocking piece is rotatably connected to the supporting frame and is positioned above the condenser.

5. The dehumidifier of claim 4, wherein the support comprises a wind frame, a sealing plate and a protection plate, wherein the wind frame is provided with a wind window, the sealing plate is connected to the wind frame, and the sealing plate extends away from the evaporator to form an inverted-L structure; the protection plate is arranged on one side of the sealing plate, which is far away from the air passing frame, and extends back to the air passing frame;

the condenser is embedded in the inverted-L-shaped structure, and the blocking piece is rotationally connected to one side, away from the evaporator, of the sealing plate.

6. The dehumidifier of claim 1, further comprising a compressor assembly including a second support, a compressor and a water receiving member, the second support being disposed within the body, the water receiving member being connected to the second support and the water receiving member being disposed transversely to divide the body into an stacked air duct chamber and a chassis chamber, the compressor being disposed within the chassis chamber;

the evaporator, the condenser and the baffle assembly are all connected to the water receiving piece and are all located in the air duct cavity.

7. The dehumidifier of claim 6, wherein the housing is provided with a mounting slot, wherein the mounting slot is in communication with the water receiving member, and wherein the compressor assembly further comprises a water tank removably connected to the mounting slot.

8. The dehumidifier of claim 1, wherein the baffle assembly is disposed between the evaporator and the condenser, the dehumidifier further comprising a first air duct assembly and a second air duct assembly, the first air duct assembly being connected between the condenser and the first air outlet to form a first chamber between the condenser and the first air duct assembly; the second air duct component is connected between the evaporator and the second air outlet, and is connected above the baffle component in a sealing way so as to form a second cavity among the evaporator, the baffle component and the second air duct component;

in the first state, the baffle component separates the second chamber to form two independent stacked cells.

9. The dehumidifier of claim 8, wherein the first air duct assembly comprises a first deflector ring, first fan blades and a first driving member, the first deflector ring is connected between the condenser and the first air outlet, the first fan blades are rotatably connected to the first deflector ring, and the first driving member is used for driving the first fan blades to rotate;

the second air duct component comprises a second guide ring, second fan blades and a second driving piece, wherein the second guide ring is connected between the evaporator and the second air outlet, the second fan blades are rotationally connected with the second guide ring, and the second driving piece is used for driving the second fan blades to rotate.

10. The dehumidifier of claim 1, wherein the body comprises a front shell, a rear shell and a base, and wherein the front shell is fastened to the rear shell in a width direction of the body; in the height direction of the machine body, the front shell and the rear shell are both connected to the base;

the air inlet is arranged on the front shell, and the first air outlet and the second air outlet are arranged on the rear shell.

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