CN219103174U - Air conditioner integrated machine - Google Patents

Abstract

The utility model discloses an air conditioner integrated machine, which comprises an outdoor unit part and an atomization device, wherein the outdoor unit part comprises an outdoor side heat exchanger, a water receiving structure and an air outlet structure, the water receiving structure is used for collecting defrosting water generated by the outdoor side heat exchanger, and the air outlet structure is used for communicating with an outdoor space. The atomizing device is arranged at the outdoor unit and is used for atomizing the defrosting water and then discharging atomized liquid drops out of the outdoor space through the air outlet structure. According to the technical scheme, atomization and discharge of the defrosting water are realized, and therefore the installation of the air conditioner integrated machine is facilitated.

Description

Air conditioner integrated machine

Technical Field

The utility model relates to the technical field of air conditioners, in particular to an air conditioner integrated machine.

Background

In cold winter, when the air conditioner integrated machine heats, the surface temperature of the condenser in the outdoor unit is usually lower than zero, and the surface of the condenser is easy to frost, so that the air conditioner integrated machine needs to frequently start a defrosting mode, so that the frost on the surface of the condenser is melted to form a large amount of moisture, and the formed moisture after defrosting needs to be discharged in time.

In the prior art, a mode adopted for discharging the defrosting water is usually an external drainage pipeline, the drainage pipeline is communicated with a sewer pipeline of a toilet, and then the defrosting water is discharged through the sewer. However, the installation position of the general air conditioner integrated machine is far away from a bathroom, and a long distance is needed for the arrangement of the drainage pipeline, so that the installation complexity of the air conditioner integrated machine can be increased, the installation cost can be increased, and the satisfaction degree of users and installation workers can be reduced.

Disclosure of Invention

The utility model mainly aims to provide an air conditioner integrated machine, which aims to realize atomization and discharge of defrosting water and further facilitates installation of the air conditioner integrated machine.

In order to achieve the above object, the present utility model provides an air conditioner integrated machine, comprising:

the outdoor unit comprises an outdoor side heat exchanger, a water receiving structure and an air outlet structure, wherein the water receiving structure is used for collecting defrosting water generated by the outdoor side heat exchanger, and the air outlet structure is used for being communicated with an outdoor space; and

and the atomization device is arranged at the outdoor unit and is used for atomizing the defrosting water and then discharging atomized liquid drops to the outdoor space through the air outlet structure.

Optionally, the water receiving structure comprises a water receiving disc arranged below the outdoor side heat exchanger.

Optionally, the water receiving structure further comprises a water collecting disc adjacent to the water receiving disc, the defrosting water collected by the water receiving disc can flow to the water collecting disc, and the atomizing device is used for atomizing the defrosting water in the water collecting disc.

Optionally, the bottom of the water pan is provided with a supporting part, the water pan is provided with a suspension section protruding laterally from the supporting part, the bottom of the suspension section is provided with a water leakage hole, and the water collecting plate is at least partially arranged below the suspension section.

Optionally, the air outlet structure comprises an air outlet arranged on the shell of the outdoor unit and an exhaust pipe connected with the air outlet;

the atomizing device comprises an atomizing shell arranged adjacent to the exhaust pipe and an atomizer arranged in the atomizing shell, and a mist discharge port communicated with the exhaust pipe is arranged between the atomizing shell and the exhaust pipe.

Optionally, the exhaust pipe automatically sucks atomized liquid drops in the atomization shell from the mist exhaust port through negative pressure generated by self air outlet airflow.

Optionally, the atomizing device still includes locates the aqua storage tank in the atomizing shell, the atomizer include atomizing motor, and with atomizing motor is connected the atomizing wheel of beating water, beat water atomizing wheel at least part and be located the aqua storage tank.

Optionally, the mist discharging port is positioned at one side of the radial direction of the water spraying atomizing wheel.

Optionally, the atomizing device further comprises a water pump, and the water pump is used for conveying the defrosting water in the water receiving structure into the atomizing shell so as to atomize the atomizing shell.

Optionally, the water receiving structure is provided with a water level detection device, the air conditioner integrated machine further comprises a controller, the controller is electrically connected with the water level detection device, the water pump and the atomizer, and the controller is used for controlling the working states of the water pump and the atomizer according to the water level detection result of the water level detection device.

Optionally, the controller is further configured to control the working state of the air conditioner integrated machine according to the water level detection result of the water level detection device.

Optionally, the water level detection device comprises a low water level switch and a high water level switch which are electrically connected with the controller, wherein the controller is used for controlling the water suction pump and the atomizer to be turned on according to the low water level switch, and controlling the air conditioner integrated machine to stop according to the high water level switch.

Optionally, the outdoor unit further comprises a compressor, the air outlet structure further comprises an air duct assembly, the compressor is located at one side of the outdoor side heat exchanger, which is away from the air duct assembly, and the water suction pump is located at one side of the outdoor side heat exchanger, which is close to the compressor.

According to the technical scheme, the outdoor unit comprises an outdoor side heat exchanger, a water receiving structure and an air outlet structure, wherein the water receiving structure is used for collecting defrosting water generated by the outdoor side heat exchanger, and the air outlet structure is used for communicating with an outdoor space. The defrosting water after defrosting of the outdoor side heat exchanger is collected by the water receiving structure, and the air outlet structure directly leads to the outdoor space, so that the gas after heat exchange of the heat exchanger is discharged to the outdoor space. And the outdoor unit is provided with an atomization device, the atomization device can pump water in the water receiving structure into the atomization device, and atomized liquid drops after atomization are discharged to the outdoor space through atomization of the atomization device. The atomized liquid drops are discharged into the air outlet structure, and the atomized liquid drops are carried out by the air flow generated by the outdoor unit, so that the possibility that the atomized liquid drops contact the outdoor side heat exchanger is reduced, and the possibility that the outdoor side heat exchanger frosts again is further reduced. Through increase atomizing device in the outdoor casing to with defrosting water atomizing discharge, thereby avoid extra pipeline of arranging to discharge defrosting water, thereby made things convenient for the installation of air conditioner all-in-one, the reduction installation degree of difficulty.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present utility model, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic view illustrating an angle structure of an outdoor unit in an embodiment of an air conditioner in accordance with the present utility model;

fig. 2 is a schematic view illustrating another angle structure of the outdoor unit of fig. 1;

fig. 3 is a schematic structural view of the atomizing device in the outdoor unit of fig. 1.

Reference numerals illustrate:

the achievement of the objects, functional features and advantages of the present utility model will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, if directional indications (such as up, down, left, right, front, and rear … …) are included in the embodiments of the present utility model, the directional indications are merely used to explain the relative positional relationship, movement conditions, etc. between the components in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description of "first", "second", etc. in the embodiments of the present utility model, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" as it appears throughout is meant to include three side-by-side schemes, for example, "a and/or B", including a scheme, or B scheme, or a scheme that is satisfied by both a and B. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

The utility model provides an air conditioner integrated machine.

In the embodiment of the present utility model, as shown in fig. 1 to 3, the air conditioner includes an outdoor unit 100 and an atomization device 140, the outdoor unit 100 includes an outdoor heat exchanger 110, a water receiving structure 120 and an air outlet structure 130, the water receiving structure 120 is used for collecting the defrosting water generated by the outdoor heat exchanger 110, and the air outlet structure 130 is used for communicating with an outdoor space. The atomizing device 140 is disposed in the outdoor unit 100, and is configured to atomize the defrosting water and then discharge the atomized droplets to the outdoor space through the air outlet structure 130.

Specifically, the temperature in winter is low, the temperature of the outdoor unit 100 of the air conditioner is low, and the surface temperature of the outdoor heat exchanger 110 is usually lower than zero, so that the surface of the outdoor heat exchanger 110 is prone to frosting. The air conditioner integrated machine is generally provided with a defrosting mode for defrosting treatment, so that frost on the surface of the outdoor side heat exchanger 110 is melted, a large amount of water is formed, and formed defrosting water after defrosting is collected by the water receiving structure 120, but if the defrosting water cannot be timely discharged, the water receiving structure 120 has the water receiving capacity reaching the upper limit, and the air conditioner integrated machine has the risk of dripping water outwards, so that the air conditioner integrated machine fails. The measure of taking at present is usually through external drainage pipeline, with defrosting water conservancy diversion to the bathroom sewer in, so the setting needs extra arrangement pipeline, increases installation cost, and promotes the installation degree of difficulty. And the installation position of the air conditioner integrated machine is usually far away from a bathroom, and the installation difficulty of the air conditioner integrated machine can be increased again. Therefore, the atomizing device 140 is provided, and the atomizing device 140 can pump the water in the water receiving structure 120 into the atomizing device 140, and the water is atomized by the atomizing device 140, so that atomized droplets are discharged to the outdoor space. The atomized droplets cannot contact the outdoor heat exchanger 110 again, or the outdoor heat exchanger 110 is extremely prone to re-frosting, so that the atomized droplets cannot be directly discharged from the outdoor unit 100 and must be separated from the outdoor heat exchanger 110. In this embodiment, the atomized droplets are discharged into the air outlet structure 130, and the atomized droplets are carried out by the air flow generated by the outdoor unit 100, so that the possibility that the atomized droplets contact the outdoor heat exchanger 110 is reduced. In other embodiments, an additional pipe may be provided, which connects the mist outlet 143 and the exhaust duct 131 on the housing of the outdoor unit 100, so as to directly discharge the atomized droplets atomized by the atomizing device 140 to the outdoor space. And an atomizing fan is arranged in the atomizing device 140, so that atomized liquid drops are blown into the exhaust structure, and then the defrosting water is discharged to the outdoor space from the water receiving structure 120.

According to the technical scheme, the outdoor unit part 100 is arranged, the outdoor unit part 100 comprises an outdoor side heat exchanger 110, a water receiving structure 120 and an air outlet structure 130, the water receiving structure 120 is used for collecting defrosting water generated by the outdoor side heat exchanger 110, and the air outlet structure 130 is used for communicating with an outdoor space. The defrosting water after defrosting of the outdoor side heat exchanger 110 is collected by the water receiving structure 120, and the air outlet structure 130 directly leads to the outdoor space, thereby discharging the air after heat exchange of the heat exchanger to the outdoor space. The outdoor unit 100 is provided with an atomizer 140, and the atomizer 140 can pump the water in the water receiving structure 120 into the atomizer 140, and atomize the water by the atomizer 140, thereby discharging atomized droplets to the outdoor space. The atomized droplets are discharged into the air outlet structure 130, and the atomized droplets are carried out by the air flow generated by the outdoor unit 100, so that the possibility that the atomized droplets contact the outdoor heat exchanger 110 is reduced, and the possibility of re-frosting of the outdoor heat exchanger 110 is further reduced. Through increasing atomizing device 140 in the outdoor casing to atomize and discharge defrosting water, thereby avoid extra pipeline of arranging to discharge defrosting water, thereby made things convenient for the installation of air conditioner all-in-one, the reduction installation degree of difficulty.

In one embodiment, the water receiving structure 120 includes a water receiving tray 121 disposed below the outdoor heat exchanger 110. Specifically, the water tray 121 is located below the outdoor side heat exchanger 110 and extends along the extending direction of the outdoor side heat exchanger 110, thereby ensuring that the water tray 121 can completely collect the defrost water. And the water receiving disc 121 is communicated with the atomizing device 140, i.e. the atomizing device 140 can directly pump water from the water receiving disc 121 for atomization.

Further, referring to fig. 2, the water receiving structure 120 further includes a water collecting tray 122 adjacent to the water receiving tray 121, the defrosting water collected by the water receiving tray 121 can flow to the water collecting tray 122, and the atomizing device 140 is configured to atomize the defrosting water in the water collecting tray 122. Specifically, if the atomizing device 140 is directly connected to the water receiving tray 121, on the one hand, the water receiving tray 121 is located below the outdoor side heat exchanger 110, and the gap between the outdoor side heat exchanger 110 and the water receiving tray 121 is generally smaller, the difficulty of installing and fixing the water pumping pipe is greater. Therefore, the water collecting tray 122 is arranged near the water collecting tray 121, and the water collecting tray 121 is communicated with the water collecting tray 122, so that the defrosting water in the water collecting tray 121 flows into the water collecting tray 122, and the atomizing device 140 directly takes water from the water collecting tray 122, so that the atomizing device 140 is conveniently communicated with the water collecting structure 120. In order to further reduce the occupied space of the outdoor unit 100, the water collecting tray 122 is at least partially disposed below the air outlet structure 130, thereby improving the compactness of the outdoor unit 100.

Further, a supporting portion 123 is disposed at the bottom of the water collecting tray 121, and the water collecting tray 121 has a suspension section 124 protruding laterally from the supporting portion 123, a water leakage hole is disposed at the bottom of the suspension section 124, and the water collecting tray 122 is at least partially disposed below the suspension section 124. Specifically, the supporting portion 123 is configured to carry the water-receiving tray 121, so that, on one hand, the distance between the water-receiving tray 121 and the outdoor heat exchanger 110 is reduced, and splashing of the defrosting water is reduced, and on the other hand, a height difference is formed between the water-receiving tray 121 and the water-collecting tray 122, so that the defrosting water in the water-receiving tray 121 can flow into the water-collecting tray 122 in time for atomization treatment. And the water pan 121 has a suspension section 124 protruding laterally from the supporting portion 123, the suspension section 124 is suspended above the water pan 122, and a water leakage hole is formed at the bottom of the suspension section 124, so that the liquid in the water pan 121 can be completely discharged into the water pan 122, and the possibility of stacking of defrosting water in the water pan 121 is reduced. In addition, a pipeline is not required to be additionally arranged to be communicated with the water collecting disc 122, so that the installation of the air conditioner integrated machine is facilitated. Of course, in other embodiments, the water receiving tray 121 may be equal to the water collecting tray 122 in height, and then the defrosting water in the water receiving tray 121 is discharged into the water collecting tray 122 through the pipeline. Or the end wall of the water collecting tray 121 is shared with the side wall of the water collecting tray 122, and the side wall is provided with a communication hole, so that the water collecting tray 122 is communicated with the water collecting tray 121.

Referring to fig. 1 and 2 in combination, in one embodiment, the air outlet structure 130 includes an air outlet provided on a casing of the outdoor unit 100, and an air discharge duct 131 connected to the air outlet;

the atomizing device 140 includes an atomizing housing 141 disposed adjacent to the exhaust duct 131, and an atomizer 142 disposed in the atomizing housing 141, and a mist outlet 143 communicating with the atomizing housing 141 and the exhaust duct 131 is provided.

Specifically, the air outlet structure 130 further includes an air duct assembly 132, an air outlet of the air duct assembly 132 is communicated with an air inlet of the exhaust pipe 131, and an air outlet on the housing is communicated with an air outlet of the exhaust pipe 131, so that the air of the outdoor unit 100 flows to the exhaust pipe 131 from the air duct assembly 132 and is exhausted to the outdoor space after heat exchange of the outdoor side heat exchanger 110. The atomizing device 140 is disposed adjacent to the exhaust pipe 131, and a mist outlet 143 is provided between the atomizing housing 141 and the exhaust pipe 131. The atomized droplets atomized by the atomizer 142 are discharged from the mist discharge port 143 to the exhaust duct 131, and the gas discharged through the exhaust duct 131 brings the atomized droplets to the outdoor space. In order to ensure that atomized liquid is timely discharged from the atomization shell 141 into the exhaust pipe 131, an atomization wind wheel can be arranged in the atomization shell 141, so that the flow of atomized liquid drops is quickened, and the discharge efficiency of the atomized liquid drops is improved. In other embodiments, the atomizing device 140 may also be disposed near the air outlet of the air duct assembly 132, and the atomizing housing 141 is in communication with the air duct assembly 132 through the mist outlet 143, so as to discharge the atomized liquid to the air outlet of the air duct assembly 132, thereby discharging the atomized liquid droplets to the outdoor space.

Further, the exhaust pipe 131 self-sucks atomized droplets in the atomizing housing 141 from the mist discharge port 143 by negative pressure generated by the air-out flow of the exhaust pipe itself. Specifically, when the air flow accelerated by the outdoor unit wind wheel flows through the exhaust pipe 131, the air flow in the exhaust pipe 131 is accelerated to reduce the pressure in the exhaust pipe 131, so that the pressure in the exhaust pipe 131 is smaller than the pressure in the atomization shell 141, thereby forming a pressure difference, and the exhaust pipe 131 can absorb the atomized liquid drops into the exhaust pipe 131, thereby continuously taking away the atomized liquid drops. Thereby reducing the number of additional steps for installing the atomizing wind wheel, reducing the installation steps and the cost, and improving the compactness of the outdoor unit 100.

In an embodiment, referring to fig. 1 to 3, the atomizing device 140 further includes a water storage tank 144 disposed in the atomizing housing 141, and the atomizer 142 includes an atomizing motor 145, and a water atomizing wheel 146 connected to the atomizing motor 145, wherein the water atomizing wheel 146 is at least partially disposed in the water storage tank 144. Specifically, the atomizing motor 145 drives the water atomizing wheel 146 to rotate at a high speed, and the water atomizing wheel 146 rotating at a high speed collides with the defrosting water pumped into the atomizing housing 141, so that atomized liquid drops are generated and distributed in the whole atomizing housing 141. And a water storage tank 144 is arranged in the atomizing shell 141, and a water spraying atomizing wheel 146 is at least partially positioned in the water storage tank 144. The water storage tank 144 is used for storing the defrosting water pumped into the atomizing housing 141, and the defrosting water atomizing wheel 146 rotates at a high speed in the defrosting water to form atomized liquid drops. Wherein the water storage tank 144 is positioned at the bottom of the atomizing shell 141, i.e. the depth of the atomizing shell 141 at the water spraying atomizing wheel 146 is increased, thereby facilitating the processing of the water storage tank 144. Of course, in other embodiments, the atomizer 142 may be an ultrasonic atomizer 142, and the ultrasonic atomizer 142 is disposed near the water storage tank 144, and water is taken from the water storage tank 144 into the ultrasonic atomizer 142 to be atomized to form atomized droplets.

Further, in an embodiment, the mist discharge port 143 is located at one side in the radial direction of the water atomizing wheel 146. Specifically, the water spraying direction of the water spraying atomizing wheel 146 is set towards the mist discharge opening 143, so that the defrosting water moves towards the mist discharge opening 143 due to inertia after being sprayed by the water spraying atomizing wheel 146, and therefore part of atomized liquid drops can directly reach the mist discharge opening 143 and then be carried out by the exhaust pipe 131 as soon as possible. The possibility of the atomized liquid drops turning in the atomizing shell 141 and liquefying again is reduced, and the mist discharging efficiency of the atomizing device 140 is further improved. Reducing the likelihood of accumulation of defrost water within the water receiving structure 120.

In an embodiment, the atomizing device 140 further includes a water pump 147, and the water pump 147 is configured to convey the defrosting water in the water receiving structure 120 into the atomizing housing 141 for the atomizer 142 to atomize. Specifically, in the present embodiment, the atomizing device 140 is disposed close to the exhaust pipe 131 and is disposed at the top of the outdoor side heat exchanger 110 together with the exhaust pipe 131, and the water receiving structure 120 is disposed at the bottom of the outdoor side heat exchanger 110, so that the atomizing device 140 is far away from the water receiving structure 120, and the atomizing device 140 is higher than the water receiving structure 120, and therefore the water pump 147 is required to pump the defrosting water from the water receiving structure 120 into the atomizing device 140. Of course, in other embodiments, the exhaust pipe 131 may be located at a side portion, a back portion, etc. of the outdoor heat exchanger 110 according to actual installation requirements, and the atomizing device 140 is disposed adjacent to the exhaust pipe 131, so as to achieve a better effect of discharging the defrosting water.

In an embodiment, the water receiving structure 120 is provided with a water level detecting device 150, and the air conditioner integrated machine further includes a controller electrically connected to the water level detecting device 150, the water pump 147 and the atomizer 142, and the controller is configured to control the working states of the water pump 147 and the atomizer 142 according to the water level detecting result of the water level detecting device 150. Specifically, the water level detecting device 150 can timely detect the amount of the defrost water in the water receiving structure 120. The water level detecting device 150 is generally disposed on the water collecting tray 122. In this embodiment, the water collecting tray 122 is mainly used for storing the defrosting water and is communicated with the atomizing device 140. If the atomizing device 140 is directly connected to the water pan 121, that is, only the water pan 121 is provided on the chassis of the outdoor unit 100, the water level detecting device 150 is provided on the water pan 121. Taking the example that the water level detecting device 150 is disposed on the water collecting tray 122, the water level detecting device 150 can judge the water amount in the water collecting tray 122 according to the water level in the water collecting tray 122, and the water level detecting device 150 is electrically connected with the controller, so that the water level detecting result of the water level detecting device 150 is transmitted to the controller, and the controller is electrically connected with the water pump 147 and the atomizer 142, so as to control the water pump 147 and the atomizer 142 to work. The controller may turn off the water pump 147 and atomizer 142 in time, such as when the water level in the drip tray 122 is too low or there is no defrost water. Thereby improving the intellectualization of the air conditioner integrated machine.

Further, the controller is further configured to control the working state of the air conditioner according to the water level detection result of the water level detection device 150. Specifically, the controller may be further electrically connected to a control module of the air conditioner integrated machine, when the water level detecting device 150 detects that the water receiving structure 120 is abnormal, for example, the water receiving disc 121 or the water collecting disc 122 is blocked or the defrosting speed is too fast, so that the water collecting disc 122 and/or the water receiving disc 121 are blocked, and when the atomizing speed of the atomizing device 140 is slow or the atomizing device 140 fails, the water level detecting result of the water level detecting device 150 may be transmitted to the controller in time, the result is processed by the controller, and then a signal is transmitted to the control module of the air conditioner integrated machine, so that the control module stops the operation of the air conditioner integrated machine in time, or the power supply of the control module is cut off, thereby facilitating the maintenance of staff. The warning module can be arranged in the air conditioner integrated machine, so that a user can be timely reminded when the controller fails.

Referring to fig. 2, in an embodiment, the water level detecting device 150 includes a low water level switch and a high water level switch, both electrically connected to a controller, and the controller is configured to control the water pump 147 and the atomizer 142 to be turned on according to the low water level switch, and to control the air conditioning integrated machine to be stopped according to the high water level switch. Specifically, the water level detecting device 150 includes a low water level switch and a high water level switch that are electrically connected to the controller, where the low water level switch is disposed at a lower water level of the water collecting tray 122, and the water level may be a preset lowest position of the water level of the water collecting tray 122, and is the lowest water amount without opening the atomizing device 140, and when the defrosting water in the water collecting tray 122 is lower than the water level, the water pump and the atomizing device 140 do not need to be started to operate; when the defrost water in the water collection tray 122 reaches or is higher than the water level, the low water level switch state is changed and a signal is transmitted to the controller, which turns on the water pump 147 and the atomizer 142. The controller may turn off the water pump 147 and atomizer 142 in time, such as when the water level in the drip tray 122 is too low or there is no defrost water. The high water level switch is disposed at a higher water level of the water collecting tray 122, the water level may be a preset highest position of the water level of the water collecting tray 122, and if the water level is higher than the water level, atomized water is at risk of overflowing from the water collecting tray 122. Such as when the drip tray 121 or the drip tray 122 is clogged or the defrosting speed is too high, resulting in the drip tray 122 and/or the drip tray 121, and the atomizing device 140 is low in atomizing speed or the atomizing device 140 is out of order, the atomized water is at risk of overflowing from the drip tray 122. If the water level in the water collecting tray 122 is lower than the position of the high water level switch, the air conditioner is normally operated to defrost and atomize, and when the water level in the water collecting tray 122 is higher than or reaches the position of the high water level switch, the state of the high water level switch is changed and signals are transmitted to the controller, so that the control module stops the operation of the air conditioner in time, or cuts off the power supply of the control module, the use safety of the air conditioner is ensured, and the use experience of a user is improved.

In an embodiment, referring to fig. 1 to 2, the outdoor unit part 100 further includes a compressor 160, the air outlet structure 130 further includes an air duct assembly 132, the compressor 160 is located at a side of the outdoor side heat exchanger 110 facing away from the air duct assembly 132, and the water pump 147 is located at a side of the outdoor side heat exchanger 110 adjacent to the compressor 160. Specifically, the compressor 160 is located at a side of the outdoor side heat exchanger 110 facing away from the air duct assembly 132, and the air duct assembly 132 is disposed side by side with the outdoor side compressor 160, so as to improve the layout of components in the outdoor unit 100, thereby improving the structural compactness thereof and reducing the overall volume of the air conditioner. The compressor 160 side usually has a larger installation space, so that the water pump 147 is arranged on the side of the outdoor side heat exchanger 110 facing the compressor 160, and the idle space between the compressor 160 and the outdoor side heat exchanger 110 can be reasonably utilized, so that no installation space is required for the water pump 147. On the one hand, the compactness of the space and the heat exchange efficiency are ensured compared to the case where the suction pump 147 is disposed at the side of the outdoor side heat exchanger 110 facing the air duct assembly 132. The clearance between outdoor side heat exchanger 110 and wind channel subassembly 132 is usually less, is difficult to reserve sufficient suction pump 147 position and installation space, and is connected through the suction pipe between atomizing device 140 and the water collecting tray 122, sets up suction pump 147 in outdoor side heat exchanger 110 towards the one side of wind channel subassembly 132, also can increase the connection degree of difficulty of arranging of suction pipe. Not only the space in the casing of the outdoor unit 100 cannot be saved, but also unnecessary installation difficulties are caused. If the heat exchanger is attached to one end of the outdoor heat exchanger, the mounting space between the outdoor heat exchanger 110 and the casing of the outdoor unit 100 is increased. The suction pump 147 is fixed on the chassis of the outdoor unit casing through a supporting frame, so that the installation stability of the suction pump 147 is improved.

The foregoing description is only of the preferred embodiments of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structural changes made by the description of the present utility model and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the utility model.

Claims (13)

1. An air conditioner all-in-one, characterized by comprising:

the outdoor unit comprises an outdoor side heat exchanger, a water receiving structure and an air outlet structure, wherein the water receiving structure is used for collecting defrosting water generated by the outdoor side heat exchanger, and the air outlet structure is used for being communicated with an outdoor space; and

and the atomization device is arranged at the outdoor unit and is used for atomizing the defrosting water and then discharging atomized liquid drops to the outdoor space through the air outlet structure.

2. The air conditioner integrated machine as set forth in claim 1, wherein said water receiving structure includes a water receiving tray provided under said outdoor side heat exchanger.

3. The air conditioner all-in-one machine according to claim 2, wherein the water receiving structure further comprises a water collecting disc adjacent to the water receiving disc, the defrosting water collected by the water receiving disc can flow to the water collecting disc, and the atomizing device is used for atomizing the defrosting water in the water collecting disc.

4. The air conditioner all-in-one machine according to claim 3, wherein a supporting portion is arranged at the bottom of the water receiving disc, the water receiving disc is provided with a suspension section protruding laterally from the supporting portion, a water leakage hole is formed in the bottom of the suspension section, and the water collecting disc is at least partially arranged below the suspension section.

5. The air conditioner as set forth in any one of claims 1 to 4, wherein the air outlet structure includes an air outlet provided at a casing of the outdoor unit part, and an exhaust duct connected to the air outlet;

the atomizing device comprises an atomizing shell arranged adjacent to the exhaust pipe and an atomizer arranged in the atomizing shell, and a mist discharge port communicated with the exhaust pipe is arranged between the atomizing shell and the exhaust pipe.

6. The air conditioner as set forth in claim 5, wherein said exhaust duct automatically sucks atomized liquid droplets in said atomizing case from said mist discharge port by negative pressure generated by an air-out flow of said exhaust duct itself.

7. The air conditioning all-in-one machine according to claim 6, wherein the atomizing device further comprises a water storage tank arranged in the atomizing shell, the atomizer comprises an atomizing motor and a water spraying atomizing wheel connected with the atomizing motor, and the water spraying atomizing wheel is at least partially positioned in the water storage tank.

8. The air conditioning all-in-one machine according to claim 7, wherein the mist discharge port is located on one side in a radial direction of the water atomizing wheel.

9. The air conditioning unit as set forth in claim 5, wherein said atomizing device further comprises a water pump for delivering said defrost water in said water receiving structure into said atomizing housing for atomization by said atomizer.

10. The air conditioner all-in-one machine according to claim 9, wherein the water receiving structure is provided with a water level detection device, the air conditioner all-in-one machine further comprises a controller, the controller is electrically connected with the water level detection device, the water pump and the atomizer, and the controller is used for controlling the working states of the water pump and the atomizer according to the water level detection result of the water level detection device.

11. The air conditioner as set forth in claim 10, wherein said controller is further configured to control an operation state of said air conditioner according to a water level detection result of said water level detection means.

12. The air conditioner integrated machine according to claim 11, wherein the water level detection device comprises a low water level switch and a high water level switch which are electrically connected with the controller, and the controller is used for controlling the water suction pump and the atomizer to be turned on according to the low water level switch and controlling the air conditioner integrated machine to stop according to the high water level switch.

13. The air conditioner as set forth in claim 9, wherein said outdoor unit further comprises a compressor, said air outlet structure further comprises an air duct assembly, said compressor is located at a side of said outdoor heat exchanger facing away from said air duct assembly, and said suction pump is located at a side of said outdoor heat exchanger adjacent to said compressor.

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