CN217236533U - Automatic water cooler discharging device and air conditioner formed by same - Google Patents

Abstract

The utility model discloses an automatic put water gauge cold ware device, include: the surface cooler module is provided with a temperature detector on the outer side; the water inlet pipe assembly is connected with a water inlet of the surface cooler module; the water outlet pipe assembly is connected with a water outlet of the surface cooler module; one end of the first one-way electromagnetic valve is connected with the water inlet pipe assembly, and the other end of the first one-way electromagnetic valve is connected with the temperature detector; and one end of the second one-way electromagnetic valve is connected with the water outlet pipe assembly, and the other end of the second one-way electromagnetic valve is connected with the temperature detector. The utility model provides a pair of automatic put water cooler device and air conditioner that forms thereof, when the temperature is low to setting for the threshold value, can automatic control the water cooler and drain, and through the slope setting of pipeline, ensure that medium water is quick and discharge completely in the surface cooler, avoid the pipeline problem of breaking that inside ponding leads to.

Description

Automatic water cooler discharging device and air conditioner formed by same

Technical Field

The utility model relates to a surface cooler drainage field especially relates to an automatic surface cooler device drains and air conditioner that forms thereof.

Background

The surface air cooler is taken as an important part of the air conditioning unit, anti-freezing protection measures for the surface air cooler are required to be considered in winter in severe cold areas, and water is drained in winter aiming at the anti-freezing protection measures for the surface air cooler at present, so that water in fins in the surface air cooler is prevented from freezing and expanding, and pipelines in the surface air cooler are prevented from being damaged.

In practical application, when the surface cooler stop work, need the manual work to open the valve that drains to it, if the surface cooler need frequently start to stop, the step of manual control draining may have forgotten, leads to the surface cooler to be frozen out. Meanwhile, the water inlet pipe assembly, the straight pipe heat exchanger and the water outlet pipe assembly inside the surface cooler are complex and the pipeline is long and thin, internal water cannot be completely discharged, and the pipeline damage of the surface cooler in a low-temperature environment can be caused due to the internal accumulated water.

SUMMERY OF THE UTILITY MODEL

The present invention aims at solving at least one of the problems in the related art to some extent. Therefore, the utility model aims to provide an automatic put water cold ware device and air conditioner that forms thereof, when the temperature is low to setting for the threshold value, can automatic control the cold ware and drain, and through the slope setting of pipeline, ensure that cold media water is quick and discharge completely in the cold ware, avoid the pipeline problem of breaking that inside ponding leads to.

In order to achieve the above object, the utility model provides an automatic put water gauge cold device, include:

the surface cooler module is provided with a temperature detector on the outer side;

the water inlet pipe assembly is connected with a water inlet of the surface cooler module;

the water outlet pipe assembly is connected with a water outlet of the surface cooler module;

one end of the first one-way electromagnetic valve is connected with the water inlet pipe assembly, and the other end of the first one-way electromagnetic valve is connected with the temperature detector;

and one end of the second one-way electromagnetic valve is connected with the water outlet pipe assembly, and the other end of the second one-way electromagnetic valve is connected with the temperature detector.

Furthermore, the water inlet pipe assembly comprises a first water inlet connecting pipe, a first transition pipe and at least one second water inlet connecting pipe, wherein one end of the first water inlet connecting pipe is connected with the water inlet of the device, and the other end of the first water inlet connecting pipe is connected with the first transition pipe;

one end of the second water inlet connecting pipe is connected with the first transition pipe, and the other end of the second water inlet connecting pipe is connected with the surface air cooler module.

Furthermore, first water inlet connecting pipe is horizontal pipeline, first transition pipe is vertical pipeline, second water inlet connecting pipe is the slope pipeline, just second water inlet connecting pipe is kept away from the one end tilt up of first transition pipe.

Further, the first one-way solenoid valve is connected with the bottom end of the first transition pipe.

Furthermore, the water outlet pipe assembly comprises a first water outlet connecting pipe, a second transition pipe and at least one second water outlet connecting pipe, wherein one end of the first water outlet connecting pipe is connected with the water outlet of the device, and the other end of the first water outlet connecting pipe is connected with the second transition pipe;

one end of the second water outlet connecting pipe is connected with the second transition pipe, and the other end of the second water outlet connecting pipe is connected with the surface air cooler module.

Furthermore, first water outlet connecting pipe is horizontal pipeline, second transition pipe is vertical pipeline, second water outlet connecting pipe is the slope pipeline, just second water outlet connecting pipe keeps away from the one end tilt up of second transition pipe.

Furthermore, the second one-way solenoid valve is connected with the bottom end of the second transition pipe.

Furthermore, the surface cooler module comprises a plurality of fin assemblies arranged in parallel;

the fin assembly comprises a plurality of straight pipe heat exchangers, and the tail ends of the straight pipe heat exchangers are welded and communicated with the head end of the next straight pipe heat exchanger through bent pipes; the tail end of the straight pipe heat exchanger is inclined downwards relative to the head end of the straight pipe heat exchanger.

Further, the top end of the surface cooler module is hermetically connected with the upper cover plate, the bottom end of the surface cooler module is hermetically connected with the lower cover plate, and a water receiving disc is arranged below the lower cover plate.

An air conditioner comprises the automatic water cooler discharging device.

Compared with the prior art, the technical scheme provided by the embodiment of the application has the following advantages: the temperature detector is arranged on the outer side of the surface cooler module and used for detecting the environment temperature of the surface cooler, and when the environment temperature is lower than a preset temperature value, the first one-way electromagnetic valve and the second one-way electromagnetic valve which are connected with the temperature detector are opened, so that refrigerant water in the surface cooler module is simultaneously discharged through the water outlet pipe assembly and the water inlet pipe assembly; this application opens according to thermodetector's testing result control first one-way solenoid valve and second one-way solenoid valve and carries out the drainage, and the mode of this kind of control drainage is favorable to realizing the intellectuality and the automation of equipment, and need not to dismantle slope surface cooler device and can realize that refrigerant water discharges fast completely, reduces the improper risk of manual operation, also avoids forgetting the risk that causes the pipeline frost crack because of personnel.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the invention and together with the description, serve to explain the principles of the invention.

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without inventive labor.

In the drawings:

FIG. 1 is a general schematic of a surface cooler apparatus of the present application;

FIG. 2 is a schematic diagram of an overall explosion of the surface cooler apparatus of the present application;

FIG. 3 is a schematic structural view of the intake pipe assembly of FIG. 2;

FIG. 4 is a schematic structural view of the outlet pipe assembly of FIG. 2;

FIG. 5 is a schematic view of the distribution of the straight tube heat exchanger in the fin assembly of FIG. 2;

reference numerals: 1. a water pan; 2. a lower cover plate; 3. a fin assembly; 31. bending the pipe; 32. a straight tube heat exchanger; 4. a side plate; 5. an upper cover plate; 6. a water outlet straight copper pipe; 7. a water outlet pipe assembly; 71. a first water outlet connecting pipe; 72. a second transition duct; 73. a second water outlet connecting pipe; 74. a water inlet hole; 8. a water inlet pipe assembly; 81. a first water inlet connecting pipe; 82. a first transition duct; 83. a second water inlet connecting pipe; 84. a water outlet hole; 9. a water inlet straight copper pipe; 10. a second one-way solenoid valve; 11. a first one-way solenoid valve; 12. a temperature detector.

Detailed Description

In order to clearly understand the technical features, objects, and effects of the present invention, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, it should be understood that the directions or positional relationships indicated by "front", "rear", "upper", "lower", "left", "right", "longitudinal", "lateral", "vertical", "horizontal", "top", "bottom", "inner", "outer", "head", "tail", etc. are configured and operated in specific directions based on the directions or positional relationships shown in the drawings, and are only for convenience of describing the present invention, but do not indicate that the referred mechanism or element must have a specific direction, and thus, should not be construed as limiting the present invention.

It is also noted that, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," "disposed," and the like are intended to be inclusive and mean, for example, that they may be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or may be connected through the use of two elements or the interaction of two elements. When an element is referred to as being "on" or "under" another element, it can be "directly" or "indirectly" on the other element or intervening elements may also be present. The terms "first", "second", "third", etc. are only for convenience in describing the present technical solution, and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated, whereby the features defined as "first", "second", "third", etc. may explicitly or implicitly include one or more of such features. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the following description, for purposes of explanation and not limitation, specific details are set forth, such as particular system structures, techniques, etc. in order to provide a thorough understanding of the embodiments of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced in other embodiments that depart from these specific details. In other instances, detailed descriptions of well-known systems, mechanisms, circuits, and methods are omitted so as not to obscure the description of the present invention with unnecessary detail.

Referring to fig. 1-4, an automatic water cooler discharging device provided in the present application includes: a surface cooler module, the side of which is provided with a temperature detector 12; the water inlet pipe assembly 8 is connected with a water inlet of the surface air cooler module; the water outlet pipe assembly 7 is connected with a water outlet of the surface cooler module; one end of the first one-way electromagnetic valve 11 is connected with the water inlet pipe assembly 8, and the other end of the first one-way electromagnetic valve is connected with the temperature detector 12; one end of the second one-way electromagnetic valve 10 is connected with the water outlet pipe component 7, and the other end is connected with the temperature detector 12.

The refrigerant among the intercooler module can be water or other refrigerants among the prior art in this application, explains with refrigerant water as the example below, and when the refrigerant was other materials, the structure and the theory of operation of this application device all are the same.

Water inlet pipe assembly 8 communicates the inhalant canal of surface cooler module in this application, and the exhalant canal of outlet pipe subassembly 7 intercommunication surface cooler module realizes the heat transfer function of surface cooler module through the circulation of refrigerant water. The temperature detector 12 is arranged on the outer side of the surface cooler module and used for detecting the environment temperature of the surface cooler, and when the environment temperature is lower than a preset temperature value, for example, 1 ℃, a first one-way electromagnetic valve 11 and a second one-way electromagnetic valve 10 which are connected with the temperature detector 12 are opened, so that the refrigerant water in the surface cooler module is simultaneously discharged through the water outlet pipe assembly 7 and the water inlet pipe assembly 8; first one-way solenoid valve 11 and second one-way solenoid valve 10 and thermodetector 12 structure that this application was add ensure that the intercooler module can realize automatic drainage under the low temperature in this application, has avoided the hidden danger that the intercooler device forgot the drainage in frequent start-up stop process.

This application opens according to thermodetector 12's testing result control first one-way solenoid valve 11 and second one-way solenoid valve 10 and carries out the drainage, and the mode of this application control drainage is favorable to realizing the intellectuality and the automation of equipment, reduces the improper risk of manual operation, avoids the manual operation to need dismantling equipment or topples over the injury that equipment caused to the device, also avoids forgetting the risk that leads to the fact the pipeline frost crack because of personnel.

As a specific embodiment, the surface cooler module includes a plurality of parallel arrangement's fin assembly 3 in this application, and 3 numbers of specific fin assembly can set up according to the application scene of surface cooler module etc.. Fin assembly 3 is split into a plurality of independent subassemblies in the surface cooler module, can make up the quantity of fin assembly 3 according to the heat transfer volume is nimble.

Fin subassembly 3 contains a plurality of straight tube heat exchanger 32, and a plurality of straight tube heat exchanger 32 top-down arranges in fin subassembly 3 in proper order, and the number of specific straight tube heat exchanger 32 can set up according to fin subassembly 3's size. In order to connect a plurality of straight tube heat exchangers 32 and form an internal refrigerant channel, the tail ends of the adjacent straight tube heat exchangers 32 and the head end of the next straight tube heat exchanger 32 are welded and communicated through the bent tube 31, so that the single straight tube heat exchanger 32 is connected to form a cold flow channel. Can select in this application all straight tube heat exchangers 32 in every fin subassembly 3 all to weld the intercommunication through return bend 21, also can divide into a plurality of regions with the straight tube heat exchanger 32 in every fin subassembly 3, only pass through return bend 31 welding intercommunication with the straight tube heat exchanger 32 in every region, form a plurality of refrigerant passageways, for example with the straight tube heat exchanger 32 of first half in the fin subassembly 3 through return bend 31 welding intercommunication, the straight tube heat exchanger 32 of the latter half passes through return bend 31 welding intercommunication, thereby form two refrigerant passageways.

Straight tube heat exchanger 32 is the horizontal pipeline usually, in order to ensure that the refrigerant water in the straight tube heat exchanger 32 can discharge completely in drainage process, this application sets up the end downward sloping rather than the head end of straight tube heat exchanger 32. Note that: define straight tube heat exchanger 32 in this application to be end-to-end connection's structure, and the end of the straight tube heat exchanger 32 of the least significant end and the head end of the straight tube heat exchanger 32 of topmost do not connect, in this kind of structure, the end of two adjacent straight tube heat exchangers 32 is located fin assembly 3's both sides, and then form the distribution schematic diagram as shown in figure 5, the end of each straight tube heat exchanger 32 all is the downward sloping for its head end promptly, this kind of structure can be ensured at the drainage in-process, refrigerant water moves towards the play water pipe direction all the time under the action of gravity.

When the surface cooler device stops operating, due to the inclined arrangement mode of the straight pipe heat exchanger 32, refrigerant water in the refrigerant channel can flow into the water outlet pipe assembly 7 and the water inlet pipe assembly 8 by nearly 100%, and when the first one-way electromagnetic valve 11 and the second one-way electromagnetic valve 10 are opened, the refrigerant water in the straight pipe heat exchanger 32 can be completely and quickly discharged in the water discharging process.

The head end and the end of each cold flow channel in this application are connected with the second water inlet connecting pipe 83 and the second water outlet connecting pipe 73 respectively, therefore, the number of the second water inlet connecting pipe 83 and the second water outlet connecting pipe 73 in the water inlet pipe assembly 8 and the water outlet pipe assembly 7 in this application is always equal, and is in one-to-one correspondence with the number of the cold flow channels. For example, when all the straight tube heat exchangers 32 in each fin are welded in sequence to form a cold flow channel, the number of the second water inlet connecting tubes 83 and the number of the second water outlet connecting tubes 73 are respectively 1, and when the upper half portion and the lower half portion of each fin form a cold flow channel, the number of the second water inlet connecting tubes 83 and the number of the second water outlet connecting tubes 73 are respectively 2, as shown in fig. 5, which is a structural schematic diagram of two refrigerant channels.

Of course, in this application, the number of the refrigerant channels can be set to be a plurality of channels greater than two, and no matter what is set is the number, the number of the second water inlet connecting pipes 83 and the number of the second water outlet connecting pipes 73 only need to be set to be the corresponding number.

The water inlet pipe assembly 8 comprises a first water inlet connecting pipe 81, a first transition pipe 82 and at least one second water inlet connecting pipe 83, wherein one end of the first water inlet connecting pipe 81 is connected with the water inlet of the device, and the other end of the first water inlet connecting pipe is connected with the first transition pipe 82; one end of the second water inlet connecting pipe 83 is connected with the first transition pipe 82, and the other end is connected with the surface air cooler module respectively.

First connecting pipe 81 that intakes is arranged in connecting device water inlet and first transition pipe 82 in this application, and the import of refrigerant passageway in first transition pipe 82 and the surface cooler module is connected to second connecting pipe 83 that intakes. Therefore, the number of the first water inlet connection pipes 81 is 1, and the number of the second water inlet connection pipes 83 is equal to the number of the refrigerant passages in the fin assembly 3.

In order to ensure that the intercooler module can fully carry out the drainage in this application, this application sets up first connecting pipe 81 of intaking for the horizontal duct, and first transition pipe 82 is vertical pipeline, and second connecting pipe 83 of intaking is the slope pipeline, and the one end tilt up that first transition pipe 82 was kept away from to second connecting pipe 83 of intaking. That is, the second water inlet connection pipe 83 is inclined upward in a direction away from the first transition pipe 82, as shown in fig. 3, when the refrigerant water in the refrigerant channel is discharged through the first one-way solenoid valve 10, the water in the second water inlet connection pipe 83 moves toward the position of the first one-way solenoid valve 10 under the action of gravity, so as to ensure that the water in the second water inlet connection pipe 83 can be discharged quickly and completely.

This application sets up first connecting pipe 81 of intaking simultaneously for the horizontal pipeline, is in order to ensure at the in-process of intaking, and the hydroenergy of device water inlet can flow smoothly to first transition pipe 82 in, does not influence the normal intaking and the heat transfer of surface cooler.

The inclined second water inlet connection pipe 83 can ensure that water in the refrigerant channel is quickly and completely discharged when the surface cooler module discharges water. Simultaneously, the number of fin subassembly 3 is a plurality of in this application, all contain the same refrigerant passageway in every fin subassembly 3, in order to communicate a plurality of fin subassemblies 3, the second connecting pipe 83 of intaking in this application is connected to each refrigerant passageway's import through the straight copper pipe 9 of intaking, the straight copper pipe 9 of intaking contains a plurality of parallel arrangement's straight copper pipe, and the number of straight copper pipe and fin subassembly 3's number one-to-one, and simultaneously, be provided with the apopore 84 the same with the 3 numbers of fin subassembly on the second connecting pipe 83 of intaking, through apopore 84 and the connection of the straight copper pipe 9 of intaking, evenly carry the refrigerant water in first connecting pipe 81 and the first transition pipe 82 to the refrigerant passageway that parallels among a plurality of fin subassemblies 3 in. The import of refrigerant passageway is the water inlet of surface cooler module in this application, and the export of refrigerant passageway is the delivery port of surface cooler module promptly.

Meanwhile, the first one-way solenoid valve 11 is connected to the bottom end of the first transition pipe 82, so that the refrigerant water in the refrigerant channel can be quickly and completely discharged when the surface air cooler discharges water.

The water outlet pipe assembly 7 in the present application comprises a first water outlet connecting pipe 71, a second transition pipe 72 and at least one second water outlet connecting pipe 73, wherein one end of the first water outlet connecting pipe 71 is connected with the water outlet of the device, and the other end is connected with the second transition pipe 72; one end of the second water outlet connecting pipe 73 is connected with the second transition pipe 72, and the other end is connected with the surface air cooler module.

In the application, the first water outlet connecting pipe 71 is used for connecting the water outlet of the device and the second transition pipe 72, and the second water outlet connecting pipe 73 is connected with the second transition pipe 72 and the outlet of the refrigerant channel in the surface cooler module. Therefore, the number of the first water outlet connecting pipes 71 is one, and the number of the second water outlet connecting pipes 73 is equal to the number of the refrigerant channels in the fin assembly 3.

In order to ensure that the surface cooler module can fully carry out the drainage in this application, this application sets up first play water connecting pipe 71 and is the horizontal pipeline, and second transition pipe 72 is vertical pipeline, and second play water connecting pipe 73 is the slope pipeline, and the one end that second transition pipe 72 was kept away from to second play water connecting pipe 73 inclines up. That is, the second outlet connecting pipe 73 is inclined upward in a direction away from the second transition pipe 72, as shown in fig. 3, when the refrigerant water in the refrigerant channel is discharged through the second one-way solenoid valve 11, the water in the second outlet connecting pipe 73 moves toward the position of the second one-way solenoid valve 11 under the action of gravity, so as to ensure that the water in the second outlet connecting pipe 73 can be discharged quickly and completely.

This application sets up first water connecting pipe 71 simultaneously and is the horizontal pipeline, is in order to ensure that at the water outlet in-process, refrigerant channel normal water can flow to the device delivery port smoothly, does not influence the normal play water of surface cooler and heat transfer.

The inclined second water outlet connecting pipe 73 can ensure that water in the refrigerant channel is quickly and completely discharged when the surface cooler module discharges water. Simultaneously, the number of fin module 3 is a plurality of in this application, all contain the same refrigerant passageway in every fin module 3, in order to communicate a plurality of fin module 3, second play water connecting pipe 73 is connected to the export of each refrigerant passageway through going out water straight copper pipe 6 in this application, it contains a plurality of parallel arrangement's straight copper pipe to go out water straight copper pipe 6, and the number of straight copper pipe and fin module 3's number one-to-one, and simultaneously, be provided with the inlet opening 74 the same with fin module number on the second play water connecting pipe 73, through the connection of inlet opening 74 and play water straight copper pipe 6, export the refrigerant water in the refrigerant passageway that parallels among a plurality of fin module 3 to the device delivery port smoothly through second transition pipe 72 and first play water connecting pipe 71.

Meanwhile, the second one-way solenoid valve 10 is connected to the bottom end of the second transition pipe 72, so that water in the refrigerant channel can be rapidly and completely discharged when the surface air cooler drains water.

In order to reduce the heat loss of the surface cooler module in the working process, the top end of the surface cooler module is connected with an upper cover plate 5 in a sealing mode, the bottom end of the surface cooler module is connected with a lower cover plate 2 in a sealing mode, and a water receiving disc 1 is arranged below the lower cover plate 2; lie in the parallel direction both sides of fin subassembly 3, fin subassembly's outer wall can regard as the closing plate to use, in the one side of inlet tube subassembly and outlet pipe subassembly, need not to set up the closing plate, at the opposite side that inlet tube subassembly and outlet pipe subassembly are relative, is provided with curb plate 4 and seals. Through above-mentioned seal structure, ensure that the surface cooler module is all sealed except that the other sides of business turn over water, the heat loss when preventing the fin subassembly heat transfer. The surface cooler module after sealing is placed above the water pan 1.

The temperature detector 12 may be provided in the upper surface of the drip tray 1 in this application.

The application also provides an air conditioner, which comprises the automatic water discharging surface air cooler device.

It is to be understood that the foregoing examples merely represent preferred embodiments of the present invention, and that the description thereof is more specific and detailed, but not intended to limit the scope of the invention; it should be noted that, for those skilled in the art, the above technical features can be freely combined, and several modifications and improvements can be made without departing from the concept of the present invention, which all belong to the protection scope of the present invention; therefore, all changes and modifications that come within the meaning and range of equivalency of the claims are to be embraced within their scope.

Claims (10)

1. The utility model provides an automatic surface cooler device drains which characterized in that includes:

the surface cooler module is provided with a temperature detector on the outer side;

the water inlet pipe assembly is connected with a water inlet of the surface cooler module;

the water outlet pipe assembly is connected with a water outlet of the surface cooler module;

one end of the first one-way electromagnetic valve is connected with the water inlet pipe assembly, and the other end of the first one-way electromagnetic valve is connected with the temperature detector;

and one end of the second one-way electromagnetic valve is connected with the water outlet pipe assembly, and the other end of the second one-way electromagnetic valve is connected with the temperature detector.

2. The automatic surface cooler discharging device as claimed in claim 1, wherein said water inlet pipe assembly comprises a first water inlet connecting pipe, a first transition pipe and at least one second water inlet connecting pipe, wherein one end of said first water inlet connecting pipe is connected with said water inlet of the device, and the other end is connected with said first transition pipe;

one end of the second water inlet connecting pipe is connected with the first transition pipe, and the other end of the second water inlet connecting pipe is connected with the surface air cooler module.

3. The automatic surface cooler device that drains as set forth in claim 2, wherein the first water inlet connecting pipe is a horizontal pipe, the first transition pipe is a vertical pipe, the second water inlet connecting pipe is an inclined pipe, and an end of the second water inlet connecting pipe away from the first transition pipe is inclined upward.

4. The automatic water surface cooler discharging device according to claim 3, wherein the first one-way solenoid valve is connected with the bottom end of the first transition pipe.

5. The automatic water surface cooler device as claimed in claim 1, wherein said outlet pipe assembly comprises a first outlet connecting pipe, a second transition pipe and at least one second outlet connecting pipe, wherein one end of said first outlet connecting pipe is connected to the outlet of the device, and the other end is connected to said second transition pipe;

one end of the second water outlet connecting pipe is connected with the second transition pipe, and the other end of the second water outlet connecting pipe is connected with the surface air cooler module.

6. The automatic water discharging surface cooler device according to claim 5, wherein the first water outlet connecting pipe is a horizontal pipe, the second transition pipe is a vertical pipe, the second water outlet connecting pipe is an inclined pipe, and one end of the second water outlet connecting pipe, which is far away from the second transition pipe, is inclined upwards.

7. The automatic water surface cooler discharging device according to claim 6, wherein the second one-way solenoid valve is connected with the bottom end of the second transition pipe.

8. The automatic water discharge surface cooler device as claimed in claim 1, wherein said surface cooler module comprises a plurality of fin assemblies arranged in parallel;

the fin component comprises a plurality of straight pipe heat exchangers, and the tail ends of the straight pipe heat exchangers are welded and communicated with the head end of the next straight pipe heat exchanger through a bent pipe; the tail end of the straight pipe heat exchanger is inclined downwards relative to the head end of the straight pipe heat exchanger.

9. The automatic water discharging surface cooler device as claimed in claim 8, wherein the top end of the surface cooler module is hermetically connected with an upper cover plate, the bottom end of the surface cooler module is hermetically connected with a lower cover plate, and a water receiving tray is arranged below the lower cover plate.

10. An air conditioner characterized by comprising the automatic water cooler discharging device as recited in any one of claims 1 to 9.

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