CN218955158U - Cabinet air conditioner - Google Patents

Abstract

The utility model provides a cabinet air conditioner, which belongs to the field of air conditioning and comprises an upper axial flow fan blade, a lower axial flow fan blade and a water receiving disc assembly, wherein the upper axial flow fan blade, the lower axial flow fan blade and the water receiving disc assembly are arranged at intervals from top to bottom in the height direction, the rotation axis of the upper axial flow fan blade and the rotation axis of the lower axial flow fan blade are parallel and horizontal, the water receiving disc assembly comprises a water receiving disc body, a water taking area is arranged on the water receiving disc body, the lower axial flow fan blade is arranged corresponding to the water taking area, the lower axial flow fan blade is provided with a water drawing structure, and in the rotation process of the lower axial flow fan blade in a first rotation direction, the water drawing structure can pump condensed water in the water taking area onto the lower axial flow fan blade and/or the upper axial flow fan blade. The utility model can reasonably utilize the condensed water of the cabinet air conditioner, thus keeping the fan blade clean, preventing the breeding of germs thereon and ensuring the physical health of users to a certain extent.

Description

Cabinet air conditioner

Technical Field

The utility model belongs to the field of air conditioning, and particularly relates to a cabinet air conditioner.

Background

In the use process of the air conditioner, a large amount of condensed water can be generated to flow into the water tank after the air conditioner operates in a long-time refrigeration or dehumidification mode, and is generally discharged through the water receiving disc, and part of window machines or mobile air conditioners adopt a water-pumping motor to drive the flywheel to spray the condensed water to the condenser for cooling, and meanwhile, the condensed water in the water tank is evaporated. In cabinet air conditioners (i.e., cabinet air conditioners), due to the limitations of structure and height, condensate water generated by a heat exchanger (evaporator) is utilized less, and is generally directly discharged through a drain pipe, so that larger cold energy waste is caused. In addition, the air conditioner has long service life, and the fan blades and the evaporator can accumulate dust, germs and the like, so that the refrigeration effect and the physical health of a user are adversely affected.

Disclosure of Invention

Therefore, the utility model provides a cabinet air conditioner, which can solve the technical problems that the cabinet air conditioner in the prior art lacks a water-taking structure, condensed water is directly discharged outdoors and is not reasonably utilized, and a heat exchanger or fan blades cannot be cleaned necessarily, so that the cabinet air conditioner is not beneficial to the health of users.

In order to solve the problems, the utility model provides a cabinet air conditioner, which comprises an upper axial flow fan blade, a lower axial flow fan blade and a water receiving disc assembly, wherein the upper axial flow fan blade, the lower axial flow fan blade and the water receiving disc assembly are arranged at intervals from top to bottom along the height direction, the rotation axis of the upper axial flow fan blade and the rotation axis of the lower axial flow fan blade are parallel and horizontal, the water receiving disc assembly comprises a water receiving disc body, the water receiving disc body is provided with a water pumping area, the lower axial flow fan blade is arranged corresponding to the water pumping area, and the water pumping structure can pump condensed water in the water pumping area to the lower axial flow fan blade and/or the upper axial flow fan blade in the first rotation direction of the lower axial flow fan blade.

In some embodiments, the water drawing structure comprises a hook, and a concave side of the hook faces to a central area of the lower axial flow fan blade.

In some embodiments, the lower axial flow fan blade further has a water pushing structure, and in the process that the lower axial flow fan blade rotates in a second rotation direction, the water pushing structure can push condensed water in the water pumping area to a heat exchanger adjacent to the lower axial flow fan blade, and the second rotation direction is opposite to the first rotation direction.

In some embodiments, the water pushing structure has a connection portion and a water pushing portion having a water pushing slope inclined toward the heat exchanger.

In some embodiments, the lower axial flow fan blade further comprises a water ring, the water ring is connected around the outer circumference of the lower axial flow fan blade, and the water drawing structure and the water pushing structure are connected to the water ring.

In some embodiments, the water drawing structure and the water pushing structure are connected into a whole to form a water pumping member, the water pumping member has a plurality of water pumping members, and the plurality of water pumping members are arranged at intervals along the circumferential direction of the water pumping ring.

In some embodiments, the water receiving tray body is further provided with a water receiving area, and the water receiving tray assembly further comprises a water diversion piece, wherein the water diversion piece is provided with a water diversion position capable of leading condensed water in the water receiving area to the water diversion area.

In some embodiments, the water diversion member comprises a rotating shaft and a water diversion channel arranged on the rotating shaft, the water diversion channel is provided with a blocking part, the water receiving disc body is provided with a drain hole, and when the water diversion member is arranged at the water diversion position, the blocking part is inserted in the drain hole to block the drain hole.

In some embodiments, the water diversion member further has a water drainage position allowing the water drainage hole to drain, and the rotating shaft is in driving connection with the rotary driving part so as to realize switching of the water diversion member between the water drainage position and the water diversion position.

In some embodiments, the outer circumferential wall of the shaft has a seal member thereon that is clamped between the shaft and the water pan body to divide the water-tapping area within the water pan body when the water-tapping member is in the water-tapping position.

In some embodiments, the shaft has a chute extending along its length and the seal has a snap-fit portion slidably coupled within the chute.

In some embodiments, a heat-insulating current collector is disposed in the water receiving area, the heat-insulating current collector has a water falling hole, the water falling hole is disposed corresponding to the water draining hole, and the blocking portion can block the water falling hole.

In some embodiments, the thermally insulated current collector is formed using foam fabrication; and/or a circulation gap is arranged between the heat-insulating current collector and the water receiving disc body; and/or the height of the edge position of the heat insulation current collector is higher than the height of the middle position, and the height of the water falling hole is the lowest.

In some embodiments, the water pan assembly further has a water injection structure in communication with the water tapping area.

The lower axial flow fan blade positioned below the two axial flow fan blades in the height direction is provided with the water drawing structure, so that condensed water in a water receiving area in the lower water receiving disc can be lifted onto the lower axial flow fan blade and the upper axial flow fan blade along with the rotation of the lower axial flow fan blade, the two axial flow fan blades are cleaned, that is, the condensed water of the cabinet air conditioner is reasonably utilized, the fan blades can be kept clean, the breeding of germs on the fan blades can be prevented, and the physical health of a user can be guaranteed to a certain extent.

Drawings

Fig. 1 is an exploded view of a cabinet air conditioner according to an embodiment of the present utility model;

fig. 2 is a schematic view (longitudinal section) of an internal structure of the cabinet air conditioner shown in fig. 1;

FIG. 3 is an axial projection of the lower axial flow fan blade of FIG. 1;

FIG. 4 is an enlarged view of a portion of FIG. 3 at A;

FIG. 5 is a schematic perspective view of the water pan assembly of FIG. 1 with the water diversion member in a diversion position;

FIG. 6 is a cross-sectional view of FIG. 5;

FIG. 7 is a schematic perspective view of the water pan assembly of FIG. 1 with the water diversion member in a drainage position;

FIG. 8 is a schematic control logic diagram of several modes of operation of the cabinet air conditioner of the present utility model under a water-using condition;

fig. 9 is a schematic control logic diagram of several operation modes of the cabinet air conditioner under another water consumption condition according to the present utility model.

The reference numerals are expressed as:

1. upper axial flow fan blades; 2. lower axial flow fan blades; 21. a water ring is arranged; 211. a water drawing structure; 212. a water pushing structure; 2121. pushing water inclined plane; 3. a water pan assembly; 31. a water pan body; 311. a water beating area; 312. a water receiving area; 32. a water guiding member; 321. a rotating shaft; 322. a water diversion channel; 3221. a blocking part; 323. a seal; 33. a rotation driving part; 34. a water injection structure; 4. a heat exchanger; 5. a heat insulating current collector; 51. a water falling hole; 61. sealing the bowl; 62. a drain pipe; 63. a motor bracket; 100. an air outlet assembly; 101. an air inlet assembly; 102. an electrical box.

Detailed Description

Referring to fig. 1 to 9, according to an embodiment of the present utility model, a cabinet air conditioner is provided, which includes a housing, the housing includes an air outlet assembly 100 and an air inlet assembly 101 spaced from front to back, an upper axial flow fan 1, a lower axial flow fan 2 and a water receiving tray assembly 3 are disposed in the housing from top to bottom along a height direction, wherein a rotation axis of the upper axial flow fan 1 and a rotation axis of the lower axial flow fan 2 are parallel and horizontal, the water receiving tray assembly 3 includes a water receiving tray body 31, a water beating area 311 is disposed on the water receiving tray body 31, the lower axial flow fan 2 is disposed corresponding to the water beating area 311, the lower axial flow fan 2 has a water drawing structure 211, and the water drawing structure 211 can pump condensed water in the water beating area 311 onto the lower axial flow fan 2 and/or the upper axial flow fan 1 in a first rotation direction. In the technical scheme, the lower axial flow fan blade 2 which is arranged below the lower axial flow fan blade in the height direction is provided with the water drawing structure 211, so that condensed water in the water drawing area 311 in the lower water receiving disc can be lifted onto the lower axial flow fan blade 2 and the upper axial flow fan blade 1 along with the rotation of the lower axial flow fan blade 2, the two axial flow fan blades are cleaned, that is, condensed water of the cabinet air conditioner is reasonably utilized in the utility model, the fan blades can be kept clean, the breeding of germs on the fan blades is prevented, and the physical health of a user is ensured to a certain extent. The first rotation direction may be, for example, a reverse rotation.

Referring to fig. 4, the water drawing structure 211 includes a hook, and a hook indent side of the hook faces a central area of the lower axial flow fan blade 2, so that a certain amount of condensed water can be contained by using the hook indent of the hook, and splashing cleaning of the lower axial flow fan blade 2 and the upper axial flow fan blade 1 can be realized by using the high and low rotation speeds of the lower axial flow fan blade 2, and the water drawing structure is simple in structure and convenient to manufacture.

In a preferred embodiment, the lower axial flow fan blade 2 further has a water pushing structure 212, and in the process of rotating the lower axial flow fan blade 2 in the second rotation direction, the water pushing structure 212 can push the condensed water in the water beating area 311 onto the heat exchanger 4 adjacent to the lower axial flow fan blade 2, where the second rotation direction is opposite to the first rotation direction, that is, when the first rotation direction is the reverse rotation, the second rotation direction is the forward rotation. In the technical scheme, the water pushing structure 212 pushes condensed water in the water beating area 311 to the heat exchanger 4 in the second rotation direction process of the lower axial flow fan blade 2, so that the overall cleaning of the height direction of the heat exchanger 4 can be realized by controlling the high and low rotation speeds of the fan blade, the heat exchange efficiency of the heat exchanger 4 is improved, and the heat exchange effect of the air conditioner is ensured.

Referring to fig. 4 specifically, the water pushing structure 212 has a connection portion and a water pushing portion, the water pushing portion has a water pushing inclined plane 2121 inclined towards the heat exchanger 4, the inclination angle of the water pushing inclined plane 2121 is reasonably selected according to the relative position between the lower axial flow fan blade 2 and the heat exchanger 4, and it can be understood that the inclination angle is selected according to the principle that the water pushing inclined plane 2121 can wash the condensed water in the water pumping area 311 along the whole coverage from the bottom end to the top end of the heat exchanger 4 in the process of changing the low rotation speed and the high rotation speed of the lower axial flow fan blade 2.

The water drawing structure 211 and the water pushing structure 212 may be separately disposed on each blade of the lower axial flow fan blade 2, but this way obviously increases the difficulty in manufacturing the blades, in a preferred embodiment, the lower axial flow fan blade 2 further includes a water-beating ring 21, the water-beating ring 21 is connected around the outer circumference of the lower axial flow fan blade 2, for example, the water drawing structure 211 and the water pushing structure 212 may be connected to the water-beating ring 21 by corresponding connecting arms to form reliable connection with each blade, in a specific embodiment, the water drawing structure 211 and the water pushing structure 212 may be integrally formed with the water-beating ring 21, thereby greatly simplifying the assembly process of the components. Furthermore, the water drawing structure 211 and the water pushing structure 212 are integrally connected to form a plurality of water pumping members, and the plurality of water pumping members are arranged at intervals along the circumferential direction of the water pumping ring 21, so that the water drawing structure 211 and the water pushing structure 212 are integrally formed, and the manufacturing process can be simplified.

Referring to fig. 5 to 7, the water receiving tray body 31 is further provided with a water receiving area 312, the water receiving tray assembly 3 further comprises a water diversion member 32, the water diversion member 32 is provided with a water diversion position capable of guiding condensed water in the water receiving area 312 to the water diversion area 311, that is, condensed water collected and received in the water receiving area 312 is guided to the water diversion area 311 by the water diversion member 32 in the technical scheme so as to be used for water diversion in the rotation process of the lower axial flow fan blade 2. It can be understood that the water receiving area 312 corresponds to an area disposed below the heat exchanger 4, and the water pumping area 311 corresponds to an area disposed below the lower axial flow fan blade 2, and the positions of the two areas are different due to the different disposed positions of the heat exchanger 4 and the lower axial flow fan blade 2. It should be specifically noted that, in this technical solution, the condensed water in the water receiving area 312 is drained to the water pumping area 311 through the guiding action of the water diversion member 32, so that the positions of the two areas do not need to be closely adjacent, which is beneficial to flexible arrangement of the components corresponding to the two areas respectively, meanwhile, the water storage area of the water pumping area 311 can be relatively smaller, and can have a higher condensed water level on the premise of the same water quantity, which is obviously beneficial to water pumping.

Referring to fig. 6 and 7, the water diversion member 32 includes a rotating shaft 321 and a water diversion channel 322 on the rotating shaft 321, the water diversion channel 322 has a blocking portion 3221, specifically, the blocking portion 3221 is configured on the outer side of the bottom wall of the water diversion channel 322 and extends downward, the water receiving tray body 31 has a drain hole (not shown in the drawings, not indexed), a drain pipe 62 is connected below, when the water diversion member 32 is at the water diversion position, the blocking portion 3221 is inserted into the drain hole to block the drain hole, so that the condensed water collected and received at the water receiving area 312 can be prevented from being discharged, and the condensed water can be guided and collected at the water diversion area 311 in time.

In some working conditions, the operation of the air conditioner does not need to utilize condensed water, and at this time, the condensed water needs to be drained in time, so as to prevent bacteria from growing in the water receiving disc and even corroding related components due to long-term retention of the condensed water, therefore, the water diversion member 32 also has a drainage position for allowing the drainage hole to drain water, as a preferred embodiment, the rotating shaft 321 is in driving connection with the rotation driving component 33 so as to realize the switching of the water diversion member 32 between the drainage position and the water diversion position, and the rotation driving component 33 can be, for example, a stepping motor so as to be capable of being controlled to automatically operate according to the instruction of the control component of the air conditioner to realize the switching of the positions.

In some embodiments, the sealing member 323 is provided on the outer circumferential wall of the rotating shaft 321, when the water diversion member 32 is at the water diversion position, the sealing member 323 is clamped between the rotating shaft 321 and the water receiving disc body 31 to form a water diversion area 311 in a separated mode in the water receiving disc body 31, so that condensed water drained from the water diversion member is guaranteed to be stored in the water diversion area 311 formed by the separated mode, and when the water diversion member 32 is at the water drainage position, the sealing member 323 rotates along with the rotating shaft 321 and is separated from contact with the water receiving disc body 31, at this time, it can be understood that condensed water in the water diversion area 311 is discharged out of the water receiving disc in time through the water drainage hole. The sealing member 323 is specifically, for example, a rubber strip.

In some embodiments, the rotating shaft 321 has a sliding groove extending along a length direction of the rotating shaft, the sealing member 323 has a clamping portion, the clamping portion is slidably connected in the sliding groove, and the sealing member 323 is a consumable part, so that replacement and maintenance of the sealing member 323 can be facilitated by adopting a sliding clamping manner.

In some embodiments, the heat-insulating current collector 5 is disposed in the water receiving area 312, the heat-insulating current collector 5 is provided with a water falling hole 51, the water falling hole 51 is correspondingly disposed with the water draining hole, and the blocking portion 3221 can block the water falling hole 51, and by disposing the heat-insulating current collector 5 in the water receiving area 312, the condensed water can be prevented from directly contacting the water receiving disc body 31, due to too low temperature, the condensation phenomenon is formed on the outer side of the water receiving disc body 31, and it can be understood that the heat-insulating current collector 5 completely covers the water receiving area 312, and a corresponding water receiving space is configured thereon. Generally, the heat-insulating and current-collecting member 5 is made of foam, which has good heat-insulating effect, low cost and small mass, and in order to timely discharge the condensed water in the water-draining area 311 when the water-guiding member 32 is at the water-draining position, a circulation gap is provided between the heat-insulating and current-collecting member 5 and the water-receiving disc body 31, and the circulation gap is communicated with the water-draining hole on the water-receiving disc body 31.

The height of the edge position of the heat insulating header 5 is higher than the height of the intermediate position, and the height of the water falling hole 51 is lowest, so that the condensed water therein can be smoothly discharged when the water diversion member 32 is at the water discharge position.

In a preferred embodiment, the water pan assembly 3 further has a water injection structure 34, the water injection structure 34 is communicated with the water beating area 311, through which water can be added into the water beating area 311 by a user when the amount of condensed water formed by the air conditioner is insufficient, so as to ensure the normal operation of the air conditioner under the water using condition, for example, when the temperature and humidity of the current environment are low, the condensed water formed by low-temperature condensation at the heat exchanger is insufficient to be watered, the air conditioner can detect the real-time water level in the water beating area 311 through the corresponding liquid level sensor, and a corresponding prompt is sent to prompt the user to add water into the water beating area to meet the requirements of cleaning, humidifying or rapid heating.

According to an embodiment of the present utility model, there is also provided a control method of a cabinet air conditioner, for controlling the cabinet air conditioner, including the steps of:

acquiring an operation mode of an air conditioner;

judging whether the operation mode is a water use working condition according to the operation mode, wherein the operation mode corresponding to the water use working condition comprises at least one of a heat exchanger cleaning mode, a fan blade cleaning mode, a drain pipe cleaning mode, a humidifying mode and a rapid heating mode;

when the operating mode is the water use condition, the water diversion member 32 is controlled to be in the diversion position.

In this technical scheme, when the operation mode is the operation mode that the water consumption operating mode corresponds, then control water diversion spare 32 is in the diversion position, forms sealed area of fetching water that holds the comdenstion water on water collector body 31, can concentrate the comdenstion water that heat exchanger 4 formed in area 311 of fetching water fast through water diversion spare 32, does benefit to the follow-up utilization to the comdenstion water.

Referring to fig. 8, when the operation mode is a heat exchanger cleaning mode and the condensed water level in the water pumping area 311 reaches the first set height h1, the lower axial flow fan blade 2 is controlled to alternately rotate at a low speed and a high speed along the second rotation direction (for example, forward direction and downward direction) for a first preset period of time, so that the heat exchanger 4 is cleaned from bottom to top in an omnibearing manner; or when the operation mode is a fan blade cleaning mode and the condensed water level in the water taking area 311 reaches a second set height h2, the lower axial flow fan blade 2 is controlled to alternately rotate at a low speed and a high speed along a first rotation direction (such as reverse direction and same direction) for a second preset time period, so that the lower axial flow fan blade 2 and the upper axial flow fan blade 1 are cleaned; or, when the operation mode is a drain pipe cleaning mode and the condensed water level in the water pumping area 311 reaches the third set height h3, the lower axial flow fan blade 2 is controlled to be static and the water diversion piece 32 is controlled to be at the discharging position, the process can be alternately performed for a plurality of times under the condition that the condensed water amount is enough according to the condition, and the cleaning of the drain pipe is realized by utilizing the impulsive force of the condensed water. Referring to fig. 9, when the operation mode is the humidification mode and the condensed water level in the water-beating area 311 reaches the fourth set height h4, the lower axial flow fan blade 2 is controlled to alternately rotate at a low speed and a high speed along the second rotation direction for a third preset period, and then the air conditioner is controlled to operate in the cooling or heating mode, so that condensed water is splashed on the heat exchanger 4, and the indoor space can be humidified during the subsequent cooling or heating mode operation, thereby improving the comfort of users; or, when the operation mode is the rapid heating mode and the condensed water level in the water beating area 311 reaches the fifth set height h5, the lower axial flow fan blade 2 is controlled to alternately rotate along the second rotation direction at a low speed and a high speed for a fourth preset time period, and then the air conditioner is controlled to operate the heating mode, so that when the air conditioner is operated to rapidly heat, heat in condensed water in at least room temperature state in the water beating area 311 can be fully utilized, cold air blowing phenomenon in the initial stage of the rapid heating mode operation is prevented, and meanwhile, the phenomenon that refrigerant enters an outdoor side heat exchanger at the position of an indoor side heat exchanger at too low temperature to cause serious frosting can be prevented, and frosting can be at least slowed down.

The aforementioned degrees h1, h2, h3, h4, and h5 may be the same or different according to actual needs, and the aforementioned first preset duration, second preset duration, third preset duration, and fourth preset duration may be the same or different.

In some embodiments, when the operation mode is a water use condition and the water diversion member 32 is at the water diversion position, acquiring the temperature and humidity of the current environment; when the acquired temperature and humidity of the current environment are lower than the target temperature and humidity, prompting a user to fill water into the water-taking area 311, preventing insufficient accumulated condensation water in the water-taking area 311 caused by unsuitable temperature and humidity, and reducing the effect of cleaning or humidifying and rapid heating modes; and/or after the operation of each operation mode corresponding to the water use condition is finished, the water diversion member 32 is controlled to be positioned at the water drainage position, so that the residual condensed water at the water taking area 311 or the sewage generated by cleaning can be timely discharged out of the water receiving disc.

Those skilled in the art will readily appreciate that the advantageous features of the various aspects described above may be freely combined and stacked without conflict.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model. The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (14)

1. The utility model provides a cabinet air conditioner, its characterized in that includes upper axial fan blade (1), lower axial fan blade (2) and water collector subassembly (3) that follow the interval of direction of height top-down set up, wherein, the axis of rotation of upper axial fan blade (1) with the axis of rotation of lower axial fan blade (2) is parallel and all horizontal, water collector subassembly (3) include water collector body (31), have on water collector body (31) and beat water region (311), lower axial fan blade (2) correspond to beat water region (311) setting, lower axial fan blade (2) have draw water structure (211) lower axial fan blade (2) are with first rotation direction rotation in-process, draw water structure (211) can with the comdenstion water in the area of beating water (311) raise to lower axial fan blade (2) and/or on upper fan blade (1).

2. A cabinet air conditioner according to claim 1, wherein the water drawing structure (211) comprises a hook, and the concave side of the hook faces to the central area of the lower axial flow fan blade (2).

3. The cabinet air conditioner according to claim 2, wherein the lower axial flow fan blade (2) further has a water pushing structure (212), and in the process that the lower axial flow fan blade (2) rotates in a second rotation direction, the water pushing structure (212) can push condensed water in the water beating area (311) to a heat exchanger (4) adjacent to the lower axial flow fan blade (2), and the second rotation direction is opposite to the first rotation direction.

4. A cabinet air conditioner according to claim 3, characterized in that the water pushing structure (212) has a connection portion and a water pushing portion having a water pushing inclined surface (2121) inclined toward the heat exchanger (4).

5. The cabinet air conditioner according to claim 4, wherein the lower axial flow fan blade (2) further comprises a water-beating ring (21), the water-beating ring (21) is connected around the outer circumference of the lower axial flow fan blade (2), and the water drawing structure (211) and the water pushing structure (212) are connected to the water-beating ring (21).

6. The cabinet air conditioner according to claim 5, wherein the water drawing structure (211) and the water pushing structure (212) are integrally connected to form a water pumping member, the water pumping member has a plurality of water pumping members, and the plurality of water pumping members are arranged at intervals along the circumferential direction of the water pumping ring (21).

7. The cabinet air conditioner according to any one of claims 1 to 6, wherein the water receiving tray body (31) further has a water receiving area (312), the water receiving tray assembly (3) further comprises a water diversion member (32), and the water diversion member (32) has a water diversion position capable of leading condensed water in the water receiving area (312) to the water diversion area (311).

8. The cabinet air conditioner according to claim 7, wherein the water diversion member (32) includes a rotating shaft (321) and a water diversion channel (322) on the rotating shaft (321), the water diversion channel (322) has a blocking portion (3221), the water receiving tray body (31) has a drain hole, and when the water diversion member (32) is at the water diversion position, the blocking portion (3221) is inserted into the drain hole to block the drain hole.

9. A cabinet air conditioner according to claim 8, wherein the water diversion member (32) further has a water drainage position allowing the water drainage hole to drain, and the rotation shaft (321) is drivingly connected with a rotation driving part (33) to realize switching of the water diversion member (32) between the water drainage position and the water diversion position.

10. The cabinet air conditioner according to claim 9, wherein the rotary shaft (321) has a sealing member (323) on an outer circumferential wall thereof, and the sealing member (323) is sandwiched between the rotary shaft (321) and the water receiving tray body (31) to form the water draining area (311) separately within the water receiving tray body (31) when the water draining member (32) is at the water draining position.

11. The cabinet air conditioner according to claim 10, wherein the rotation shaft (321) has a sliding groove extending along a length direction thereof, and the sealing member (323) has a clamping portion slidably coupled in the sliding groove.

12. The cabinet air conditioner according to claim 8, wherein a heat insulation current collector (5) is disposed in the water receiving area (312), a water falling hole (51) is formed in the heat insulation current collector (5), the water falling hole (51) is disposed corresponding to the water draining hole, and the blocking portion (3221) can block the water falling hole (51).

13. Cabinet air conditioner according to claim 12, characterized in that the heat insulation and current collector (5) is formed by foam; and/or a circulation gap is arranged between the heat-insulating current collector (5) and the water pan body (31); and/or the height of the edge position of the heat insulation current collector (5) is higher than the height of the middle position, and the height of the water falling hole (51) is the lowest.

14. A cabinet air conditioner according to claim 1, wherein the water pan assembly (3) further has a water injection structure (34), the water injection structure (34) being in communication with the water tapping area (311).

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