CN219083278U

CN219083278U - Fluorine-cooled three-integrated variable-frequency dehumidifier

Info

Publication number: CN219083278U
Application number: CN202123346800.3U
Authority: CN
Inventors: 曾祥钦; 王星; 陈�峰; 刘永德; 罗明
Original assignee: Guangzhou Fenni Swimming Pool Equipment Technology Co ltd
Current assignee: Guangzhou Fenni Swimming Pool Equipment Technology Co ltd
Priority date: 2021-12-27
Filing date: 2021-12-27
Publication date: 2023-05-26
Anticipated expiration: 2031-12-27

Abstract

The utility model discloses a fluorine-cooling three-integration variable-frequency dehumidifier which comprises a circulating loop formed by connecting a compressor, a condensing device, a throttling device and an evaporating device end to end, and also comprises an electric box heat exchanger arranged in an electric box, wherein the electric box heat exchanger is connected between the condensing device and the throttling device, so that liquid refrigerant output by the condensing device is conveyed to the throttling device after passing through the electric box heat exchanger. The liquid refrigerant flowing in the heat exchanger of the electric box can continuously take away heat in the electric box, so that the heat dissipation of the compressor driving plate is quickened, the service life of the variable-frequency driving plate is prolonged, the operable frequency range of the compressor is prolonged, and the maximum capacity of the compressor is exerted; in addition, the temperature difference between the electric box heat exchanger and the electric box is not too large, and the phenomenon of short circuit burning of the circuit board caused by the condensation phenomenon in the electric box is effectively avoided.

Description

Fluorine-cooled three-integrated variable-frequency dehumidifier

Technical Field

The application relates to the technical field of heat pumps, in particular to a fluorine-cooling three-integration variable-frequency dehumidifier.

Background

The existing swimming pool variable frequency heat pump dehumidifier usually accelerates the heat dissipation of the compressor driving plate in an air cooling mode, namely, an electric appliance box provided with the compressor driving plate extends into an air channel of the heat exchanger, and the heat on the surface of the electric appliance box is taken away by utilizing the air flow rapidly flowing in the air channel, so that the heat dissipation of the compressor driving plate is accelerated. However, in general, the temperature in the air duct is about 15-27 ℃, the temperature difference between the air duct and the high-temperature environment (up to 85 ℃) in the electric cabinet of the compressor driving plate is large, and the junction temperature is far lower than the dew point temperature of the environment in the electric cabinet, so that serious condensation risks exist in the electric cabinet. If auxiliary heat dissipation measures are not taken, the temperature of components in the driving plate is increased due to the fact that heat dissipation is poor, the driving plate is lowered, the frequency of the compressor is lowered, and the capacity of the whole machine is lowered.

Disclosure of Invention

The aim of the embodiment of the utility model is that: the utility model provides a fluorine-cooled three-in-one variable frequency dehumidifier which can solve the problems in the prior art.

In order to achieve the above purpose, the present application adopts the following technical scheme:

the utility model provides a cold three integrative variable frequency dehumidifier that gathers of fluorine, includes the circulation loop that forms by compressor, condensing equipment, throttling arrangement and evaporation plant end to end, still includes the electrical apparatus box heat exchanger that sets up in the electrical apparatus box, electrical apparatus box heat exchanger connect in condensing equipment with between the throttling arrangement, thereby by the liquid refrigerant of condensing equipment output is passed through after the electrical apparatus box heat exchanger carries again to throttling arrangement.

Optionally, the electrical box heat exchanger is connected with a compressor driving plate.

Optionally, the condensing device includes a first condenser, a second condenser and a third condenser connected in parallel, wherein the first condenser is arranged indoors for heating swimming pool water, the second condenser is arranged indoors for heating indoor air, and the third condenser is arranged outdoors for radiating heat into outdoor air.

Optionally, the front end of the first condenser is provided with a first electromagnetic valve, the front end of the second condenser is provided with a second electromagnetic valve, and the front end of the third condenser is provided with a third electromagnetic valve.

Optionally, the first condenser rear end is equipped with first check valve, the second condenser rear end is equipped with the second check valve, the third condenser rear end is equipped with the third check valve.

Optionally, an oil separator is connected between the compressor and the condensing device, a recovery end of the oil separator is connected with a front end of an oil recovery pipeline, and a rear end of the oil recovery pipeline is connected between the evaporating device and the compressor.

Optionally, a filter and a capillary tube are arranged in the oil recovery pipeline, and the filter is positioned at the front end of the capillary tube.

Optionally, the method further comprises:

the front end of the first refrigerant recovery pipeline is connected between the first condenser and the first one-way valve, and the rear end of the first refrigerant recovery pipeline is connected with the front end of the filter;

the front end of the second refrigerant recovery pipeline is connected between the second condenser and the second one-way valve, and the rear end of the second refrigerant recovery pipeline is connected with the front end of the filter;

and the front end of the third refrigerant recovery pipeline is connected between the third condenser and the third one-way valve, and the rear end of the third refrigerant recovery pipeline is connected with the front end of the filter.

Optionally, a fourth electromagnetic valve is arranged in the first refrigerant recovery pipeline, a fifth electromagnetic valve is arranged in the second refrigerant recovery pipeline, and a sixth electromagnetic valve is arranged in the third refrigerant recovery pipeline.

Optionally, the first condenser is a titanium tube heat exchanger, and the second condenser and the third condenser are fin type heat exchangers.

The beneficial effects of this application are: the utility model discloses a fluorine-cooling three-integration variable-frequency dehumidifier, wherein an electric box heat exchanger is arranged in a refrigerant circulation loop, the electric box heat exchanger is connected between a condensing device and a throttling device, the refrigerant is condensed and liquefied in the condensing device, a large amount of heat is released, the temperature of liquid refrigerant flowing out of a condenser is generally between 40 and 50 ℃, and the temperature is lower than the temperature in an electric box; therefore, the liquid refrigerant flowing in the heat exchanger of the electric box can continuously take away heat in the electric box, so that the heat dissipation of the compressor driving plate is quickened, the service life of the variable-frequency driving plate is prolonged, the operable frequency range of the compressor is prolonged, and the maximum capacity of the compressor is exerted; in addition, the temperature difference between the electric box heat exchanger and the electric box is not too large, and the phenomenon of short circuit burning of the circuit board caused by the condensation phenomenon in the electric box is effectively avoided.

Drawings

The present application is described in further detail below with reference to the drawings and examples.

FIG. 1 is a block diagram of a fluorine-cooled three-in-one variable frequency dehumidifier according to an embodiment of the present application;

FIG. 2 is a schematic diagram of a fluorine-cooled three-in-one variable frequency dehumidifier according to an embodiment of the present application in a constant temperature dehumidification mode;

FIG. 3 is a schematic diagram of a fluorine-cooling three-in-one variable frequency dehumidifier in a heating dehumidification mode according to an embodiment of the present application;

fig. 4 is a schematic diagram of the fluorine-cooling three-integrated variable frequency dehumidifier according to the embodiment of the application in a cooling and dehumidifying mode.

In the figure:

1. a compressor; 2. a condensing device; 21. a first condenser; 211. a first electromagnetic valve; 212. a first one-way valve; 213. a fourth electromagnetic valve; 22. a second condenser; 221. a second electromagnetic valve; 222. a second one-way valve; 223. a fifth electromagnetic valve; 23. a third condenser; 231. a third electromagnetic valve; 232. a third one-way valve; 233. a sixth electromagnetic valve; 3. an electric box heat exchanger; 4. a throttle device; 5. an evaporation device; 61. an oil separator; 62. a filter; 63. a capillary tube; 7. an oil storage tank; 8. a second filter; 9. and a gas separator.

Detailed Description

In order to make the technical problems solved, the technical solutions adopted and the technical effects achieved by the present application more clear, the technical solutions of the embodiments of the present application are described in further detail below, and it is obvious that the described embodiments are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments herein without making any inventive effort, are intended to be within the scope of the present application.

In the description of the present application, unless explicitly stated and limited otherwise, the terms "connected," "secured" and "fixed" are to be construed broadly, as for example, they may be fixedly connected, detachably connected, or integrated; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

In this application, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, and may also include the first and second features not being in direct contact but being in contact with each other by way of additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

The embodiment provides a fluorine-cooling three-in-one variable frequency dehumidifier which is particularly applied to a dehumidifying heat pump of a swimming pool and provides a temperature and humidity adjusting function for an indoor swimming pool.

As shown in fig. 1, the embodiment includes a circulation loop formed by connecting a compressor 1, a condensing device 2, a throttling device 4 and an evaporating device 5 end to end, and further includes an electrical box heat exchanger 3 disposed in an electrical box, wherein the electrical box heat exchanger 3 is connected between the condensing device 2 and the throttling device 4, so that a liquid refrigerant output by the condensing device 2 is conveyed to the throttling device 4 after passing through the electrical box heat exchanger 3.

Similar to the conventional refrigeration and heating principle, the high-pressure liquid refrigerant enters the condensing device 2 to be condensed and liquefied under the driving of the compressor 1, and a large amount of heat is released in the process; then the high-pressure liquid refrigerant is throttled by the throttling device 4 and then outputs a low-pressure liquid refrigerant, the low-pressure liquid refrigerant enters the evaporation device 5 to be evaporated and gasified, and a large amount of heat is absorbed in the process; then, a low-pressure gaseous refrigerant is formed and is pressurized in the compressor 1.

When the device is specifically applied, the mounting positions of the condensing device 2 and the evaporating device 5 are reasonably arranged, so that the required temperature and humidity adjusting function can be realized.

The principle of the electric box heat exchanger 3 is the same as that of a conventional heat exchanger, a refrigerant circulates in the electric box heat exchanger 3, a certain temperature difference exists between the refrigerant and the external environment of the electric box heat exchanger 3, and the refrigerant exchanges heat with the external environment through the wall surface of the electric box heat exchanger 3, so that a heat exchange function is realized. Generally, the temperature of the liquid refrigerant output by the condensing device 2 is between 40 ℃ and 50 ℃, and the temperature of a high-temperature area in the electric box can reach 85 ℃, compared with the temperature in the electric box, the liquid refrigerant flowing in the electric box heat exchanger 3 is a low-temperature medium, so that the flowing liquid refrigerant can continuously absorb heat in the electric box, and the aim of accelerating heat dissipation in the electric box is fulfilled.

Meanwhile, the electric box heat exchanger 3 is utilized for refrigerating, and the temperature difference of the refrigerant in the electric box heat exchanger 3 in the electric box is not too large, so that the risk of condensation in the electric box is avoided.

Preferably, the electric box heat exchanger 3 is connected with a compressor driving plate. Specifically, the compressor drive plate is a main heating element in the electric box, and the electric box heat exchanger 3 is directly attached to the compressor drive plate, so that heat emitted in the working process of the compressor drive plate can be taken away most directly and most rapidly. For easy understanding, the structure can refer to the existing water-cooled computer host, the compressor driving board is analogous to the main board of the computer host, and the electric box heat exchanger 3 is a heat exchanger connected with the main board, and the structure has the advantages of high heat dissipation speed and high efficiency.

Further, to achieve multiple operation modes, the condensing device 2 includes a first condenser 21, a second condenser 22 and a third condenser 23 connected in parallel, wherein the first condenser 21 is disposed indoors for heating swimming pool water, the second condenser 22 is disposed indoors for heating indoor air, and the third condenser 23 is disposed outdoors for radiating heat into outdoor air.

Specifically, based on different condenser put into operation, the following three different modes of operation can be realized:

constant temperature dehumidification mode: referring to fig. 2, in this mode, the first condenser 21 is turned on, the second condenser 22 and the third condenser 23 are turned off, and the first condenser 21 is used to heat the pool water. Specifically, pool water is continuously evaporated in a room, and pool water heat is accompanied by evaporated water vapor, so that the pool water temperature is continuously reduced; the evaporation device 5 of the embodiment is arranged in a room, the evaporation device 5 cools and dehumidifies indoor air when in operation, the first condenser 21 is used for heating swimming pool water, the first condenser 21 continuously heats the swimming pool water when in operation, and the heat emitted into the air by the swimming pool water is supplemented, so that the constant temperature treatment of the swimming pool water is realized, and meanwhile, the heat of the swimming pool water is continuously emitted into the air, so that the constant temperature of the indoor air can be basically ensured; therefore, in the mode, the indoor air can be subjected to dehumidification treatment, and meanwhile, the heat of the swimming pool water can be recovered, so that the constant-temperature treatment of the swimming pool water is realized.

And (3) a heating and dehumidifying mode: referring to fig. 3, in this mode, the second condenser 22 is turned on, the first condenser 21 and the third condenser 23 are turned off, and the second condenser 22 is used to heat the indoor air. Specifically, the evaporation device 5 of the embodiment is disposed in the room, and when in operation, the evaporation device 5 cools and dehumidifies the indoor air, and the second condenser 22 is also disposed in the room, for heating the indoor air; in operation, the heat release of the refrigerant in the second condenser 22 is composed of three parts: (1) sensible heat emitted from the indoor air at the evaporation device 5; (2) the latent heat of condensation of the moisture condensed by the indoor air on the evaporation device 5; (3) compression work of the compressor 1; sensible heat released by cooling the indoor air flow on the evaporation device 5 is the same as the heat release amount of the (1) part of the second condenser 22, and the heat release amounts of the (2) part and the (3) part of the second condenser 22 form the net heating of the indoor air, so that the indoor air is heated and warmed; therefore, in this mode, the temperature-increasing dehumidification process of the indoor air can be realized.

Cooling and dehumidifying modes: referring to fig. 4, in this mode, the third condenser 23 is turned on, the first condenser 21 and the second condenser 22 are turned off, and the third condenser 23 is disposed outdoors. Specifically, the evaporation device 5 of the embodiment is disposed in the room, and the evaporation device 5 cools and dehumidifies the indoor air during operation, and the third condenser 23 is disposed outdoors, so that the heat of the refrigerant carried indoors is dissipated outdoors by the third condenser 23; therefore, in this mode, the cooling and dehumidifying process for the indoor air is realized based on the evaporation device 5.

Further, in order to switch the three modes, in this embodiment, a first electromagnetic valve 211 is disposed at the front end of the first condenser 21, a second electromagnetic valve 221 is disposed at the front end of the second condenser 22, and a third electromagnetic valve 231 is disposed at the front end of the third condenser 23.

Specifically, when the constant temperature dehumidification mode is operated, the first solenoid valve 211 is opened, and the second solenoid valve 221 and the third solenoid valve 231 are both closed; when the temperature-increasing dehumidification mode is operated, the second solenoid valve 221 is opened, and both the first solenoid valve 211 and the third solenoid valve 231 are closed; when in the cooling and dehumidifying mode, the third solenoid valve 231 is opened, and both the first solenoid valve 211 and the second solenoid valve 221 are closed.

Further, in order to prevent the refrigerant from flowing backward, the rear end of the first condenser 21 is provided with a first check valve 212, the rear end of the second condenser 22 is provided with a second check valve 222, and the rear end of the third condenser 23 is provided with a third check valve 232. That is, for the condenser in the off-line state, the check valve on the branch of the condenser can prevent the refrigerant in the main path from flowing back into the condenser, thereby avoiding the occurrence of insufficient flowing refrigerant.

Further, an oil separator 61 is connected between the compressor 1 and the condensing device 2, a recovery end of the oil separator 61 is connected to a front end of an oil recovery pipe, and a rear end of the oil recovery pipe is connected between the evaporating device 5 and the compressor 1.

Specifically, the oil separator 61 is arranged to separate out the lubricating oil contained in the refrigerant at the front end of the condensing device 2, so that the lubricating oil of the compressor 1 is prevented from entering the condensing device 2 along with the refrigerant; while the lubricating oil separated by the oil separator 61 is fed back into the compressor 1 through an oil recovery line to ensure the normal operation of the compressor 1.

Preferably, a filter 62 and a capillary tube 63 are disposed in the oil recovery line, and the filter 62 is located at the front end of the capillary tube 63.

Specifically, the impurities in the oil recovery pipeline can be filtered out through the filter 62, and because the oil recovery pipeline is a high-pressure area, a low-pressure area is arranged between the evaporation device 5 and the compressor 1, and the capillary 63 is arranged to have a depressurization effect, so that the high-pressure impact effect is avoided.

When the operation mode is switched, more refrigerant is reserved in the original operation condenser, and the refrigerant reserved in the original operation condenser needs to be recovered to ensure the sufficiency of the refrigerant operated in the pipeline.

Therefore, the present embodiment further includes:

a first refrigerant recovery pipe, the front end of which is connected between the first condenser 21 and the first check valve 212, and the rear end of which is connected to the front end of the filter 62;

a second refrigerant recovery pipe, the front end of which is connected between the second condenser 22 and the second check valve 222, and the rear end of which is connected to the front end of the filter 62;

and a third refrigerant recovery pipe, the front end of which is connected between the third condenser 23 and the third check valve 232, and the rear end of which is connected to the front end of the filter 62.

Specifically, after the operation mode is switched, the refrigerant stored in the condenser that is originally operated can flow into the oil recovery pipeline through the refrigerant recovery pipeline connected with the branch, and then is recovered into the compressor 1 through the oil recovery pipeline.

For convenient control, further, a fourth electromagnetic valve 213 is disposed in the first refrigerant recovery pipeline, a fifth electromagnetic valve 223 is disposed in the second refrigerant recovery pipeline, and a sixth electromagnetic valve 233 is disposed in the third refrigerant recovery pipeline.

Specifically, for the condenser running at present, the electromagnetic valve of the corresponding refrigerant recovery pipeline needs to be kept closed, so that the influence on the normal operation of the unit caused by the fact that the refrigerant flowing out of the condenser directly enters the oil recovery pipeline is avoided. After the mode is switched, the refrigerant recovery is completed after a certain time of operation, and at the moment, all the electromagnetic valves in the refrigerant recovery pipelines are closed.

Preferably, the first condenser 21 is a titanium tube heat exchanger, and the second condenser 22 and the third condenser 23 are fin heat exchangers.

Further, an oil storage tank 7 is connected to the rear end of the electric box heat exchanger 3, a second filter 8 is connected to the rear end of the oil storage tank 7, and a gas separator 9 is connected between the compressor 1 and the evaporation device 5.

In summary, the embodiment discloses a fluorine-cooling three-in-one variable frequency dehumidifier, in a refrigerant circulation loop, an electric box heat exchanger 3 is arranged, the electric box heat exchanger 3 is connected between a condensing device 2 and a throttling device 4, the refrigerant is condensed and liquefied in the condensing device 2, a large amount of heat is released, the temperature of a liquid refrigerant flowing out of the condenser is generally between 40 ℃ and 50 ℃, and the temperature is lower than the temperature in the electric box; therefore, the liquid refrigerant flowing in the electric box heat exchanger 3 can continuously take away heat in the electric box, so that the heat dissipation of the driving plate of the compressor 1 is quickened, the service life of the variable-frequency driving plate is prolonged, the operable frequency range of the compressor 1 is prolonged, and the maximum capacity of the compressor 1 is exerted; in addition, the temperature difference between the electric box heat exchanger 3 and the electric box is not too large, and the phenomenon of short circuit burning of the circuit board caused by the condensation phenomenon in the electric box is effectively avoided.

In the description herein, it should be understood that the terms "upper," "lower," "left," "right," and the like are merely for convenience of description and to simplify the operation, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the application. Furthermore, the terms "first," "second," and the like, are used merely for distinguishing between descriptions and not for providing a special meaning.

In the description herein, reference to the term "one embodiment," "an example," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in the foregoing embodiments, and that the embodiments described in the foregoing embodiments may be combined appropriately to form other embodiments that will be understood by those skilled in the art.

The technical principles of the present application are described above in connection with specific embodiments. These descriptions are provided only for the purpose of illustrating the principles of the present application and should not be construed as limiting the scope of the present application in any way. Other embodiments of the present application will be apparent to those skilled in the art from consideration of the specification without undue burden from the present disclosure.

Claims

1. The utility model provides a cold three integrative variable frequency dehumidifier that gathers of fluorine, its characterized in that, includes by compressor (1), condensing equipment (2), throttling arrangement (4) and evaporation plant (5) end to end's the circulation loop that forms, still including setting up electrical apparatus box heat exchanger (3) in the electrical apparatus box, electrical apparatus box heat exchanger (3) connect in condensing equipment (2) with between throttling arrangement (4), thereby by liquid refrigerant of condensing equipment (2) output is passed through after electrical apparatus box heat exchanger (3) carry again throttling arrangement (4).

2. The fluorine-cooled three-in-one variable frequency dehumidifier according to claim 1, wherein the electrical box heat exchanger (3) is connected with a compressor driving plate.

3. The fluorine-cooled three-integrated variable frequency dehumidifier according to claim 2, characterized in that the condensing means (2) comprises a first condenser (21), a second condenser (22) and a third condenser (23) connected in parallel with each other, wherein the first condenser (21) is arranged indoors for heating swimming pool water, the second condenser (22) is arranged indoors for heating indoor air, and the third condenser (23) is arranged outdoors for radiating heat into outdoor air.

4. A fluorine-cooled three-integration variable frequency dehumidifier according to claim 3, characterized in that the front end of the first condenser (21) is provided with a first electromagnetic valve (211), the front end of the second condenser (22) is provided with a second electromagnetic valve (221), and the front end of the third condenser (23) is provided with a third electromagnetic valve (231).

5. The fluorine-cooled three-integration variable frequency dehumidifier according to claim 4, wherein the rear end of the first condenser (21) is provided with a first one-way valve (212), the rear end of the second condenser (22) is provided with a second one-way valve (222), and the rear end of the third condenser (23) is provided with a third one-way valve (232).

6. The fluorine-cooled three-in-one variable frequency dehumidifier according to claim 5, characterized in that an oil separator (61) is connected between the compressor (1) and the condensing device (2), a recovery end of the oil separator (61) is connected with a front end of an oil recovery pipeline, and a rear end of the oil recovery pipeline is connected between the evaporating device (5) and the compressor (1).

7. The fluorine-cooled three-in-one variable frequency dehumidifier according to claim 6, wherein a filter (62) and a capillary tube (63) are arranged in the oil recovery pipeline, and the filter (62) is positioned at the front end of the capillary tube (63).

8. The fluorine-cooled three-in-one variable frequency dehumidifier of claim 7, further comprising:

a first refrigerant recovery pipe, the front end of which is connected between the first condenser (21) and the first check valve (212), and the rear end of which is connected with the front end of the filter (62);

the front end of the second refrigerant recovery pipeline is connected between the second condenser (22) and the second one-way valve (222), and the rear end of the second refrigerant recovery pipeline is connected with the front end of the filter (62);

and the front end of the third refrigerant recovery pipeline is connected between the third condenser (23) and the third one-way valve (232), and the rear end of the third refrigerant recovery pipeline is connected with the front end of the filter (62).

9. The fluorine-cooled three-integration variable frequency dehumidifier according to claim 8, wherein a fourth electromagnetic valve (213) is arranged in the first refrigerant recovery pipeline, a fifth electromagnetic valve (223) is arranged in the second refrigerant recovery pipeline, and a sixth electromagnetic valve (233) is arranged in the third refrigerant recovery pipeline.

10. A fluorine-cooled three-in-one variable frequency dehumidifier according to claim 3, characterized in that the first condenser (21) is a titanium tube heat exchanger, and the second condenser (22) and the third condenser (23) are fin heat exchangers.