CN216790414U - Mixed refrigeration system - Google Patents

Abstract

The utility model provides a hybrid refrigeration system which comprises a main circulation loop, a first through-flow device and a water-cooling circulation loop, wherein the water-cooling circulation loop is connected with the main circulation loop, and the main circulation loop comprises an evaporator, a compressor, a radiator and a throttling device which are sequentially connected through pipelines; the water cooling circulation loop comprises a water storage device, a first driving device, a refrigeration water tank and an evaporation filtering device which are sequentially connected through a pipeline; the evaporation filtering device comprises a loose and porous water absorbing part and a fixing part for mounting the water absorbing part, and the water absorbing part is respectively arranged corresponding to a water outlet of the refrigeration water tank, the first through-flow device and a water inlet of the water storage device; the evaporator is arranged in the refrigerating water tank.

Description

Mixed refrigeration system

Technical Field

The utility model relates to the field of refrigeration, in particular to a hybrid refrigeration system.

Background

At present, a fan is still widely used as a traditional cooling household appliance due to the advantages of environmental protection, effectiveness, less electricity consumption and the like. However, the existing fans are mainly divided into two types, one type is that hot air is blown out when the fan is normally used; the other is that the humidifying function is arranged on the basis of the first fan, and hot air with humidity is blown out during normal use. Therefore, the fan in the prior art can only blow out hot air when working normally, and can not achieve the effect of refrigeration.

Therefore, the problem that the fan cannot refrigerate is solved by the air conditioner refrigeration effect, but the air conditioner is high in using power and high in energy consumption.

Therefore, there is a need for a hybrid refrigeration system that integrates refrigeration and energy conservation.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: the utility model provides a mix refrigerating system, solve current household electrical appliances and have the not good or high problem of power consumption of refrigeration effect.

In order to solve the technical problems, the utility model adopts the technical scheme that: providing a hybrid refrigeration system, wherein the hybrid refrigeration system comprises a main circulation loop, a first through-flow device and a water-cooling circulation loop connected with the main circulation loop, wherein the main circulation loop comprises an evaporator, a compressor, a radiator and a throttling device which are sequentially connected through pipelines; the water cooling circulation loop comprises a water storage device, a first driving device, a refrigeration water tank and an evaporation filtering device which are sequentially connected through pipelines; the evaporation filtering device comprises a loose and porous water absorbing part and a fixing part for mounting the water absorbing part, and the water absorbing part is respectively arranged corresponding to a water outlet of the refrigeration water tank, the first through-flow device and a water inlet of the water storage device; the evaporator is arranged in the refrigeration water tank, and the first driving device is used for driving a pipeline to suck liquid in the water storage device to the refrigeration water tank for cooling; the water absorption part in the evaporation filtering device is used for absorbing liquid in the refrigerating water tank; the first through-flow device is used for blowing out the liquid absorbed by the evaporation and filtration device in the form of aerial fog to cool the surrounding air.

Furthermore, the heat dissipation device further comprises a heat dissipation passage, the heat dissipation passage comprises a second driving device and a spraying device, the second driving device is connected with the water storage device, the spraying device is connected with the second driving device, and an outlet of the spraying device is arranged corresponding to the radiator.

Further, the heat dissipation passage further comprises a second through-flow device and a ventilation duct, the second through-flow device is arranged corresponding to the heat dissipation part of the heat sink, and the ventilation duct is connected with an air outlet of the second through-flow device.

Further, the fixing part is an installation frame; the water absorption part is loose and porous bubble paper.

Further, the water storage device further comprises a water level sensor, wherein the water level sensor is arranged in the refrigeration water tank and used for controlling the water quantity in the water storage device through a first driving device.

Further, the throttling device is a manual throttling valve or an automatic throttling valve.

Further, the compressor comprises a high-pressure pipe and a low-pressure pipe, and the compressor is connected with the evaporator through the high-pressure pipe; the compressor is connected with the radiator through the low-pressure pipe.

Furthermore, the radiator also comprises a dry filter, one end of the dry filter is connected with the radiator, and the other end of the dry filter is connected with the throttling device.

Further, the first driving device and the second driving device are both water pumps.

Further, the first cross flow device and the second cross flow device are both fans.

The utility model has the beneficial effects that: the system is characterized in that a main circulation loop, a first through flow device and a water-cooling circulation loop connected with the main circulation loop are arranged, and the main circulation loop comprises an evaporator, a compressor, a radiator and a throttling device which are sequentially connected through pipelines; the water cooling circulation loop comprises a water storage device, a first driving device, a refrigeration water tank and an evaporation filtering device which are sequentially connected through pipelines; the evaporation filtering device comprises a loose and porous water absorbing part and a fixing part for mounting the water absorbing part, and the water absorbing part is respectively arranged corresponding to a water outlet of the refrigeration water tank, the first through-flow device and a water inlet of the water storage device; place in the evaporimeter refrigeration water tank, first drive arrangement drive pipeline absorbs liquid among the water storage device and cools down to refrigeration water tank, and the liquid after will cooling passes through pipeline transmission to the portion of absorbing water among the evaporation filter equipment and absorbs liquid, first continuous flow device blows off the liquid in the portion of absorbing water with the form of aerial fog for cool down the ambient air, this system refrigeration effect is obvious, energy-conserving power saving.

Drawings

Fig. 1 is a schematic view of a first structure of the hybrid refrigeration system of the present invention.

Fig. 2 is a second structural schematic diagram of the hybrid refrigeration system of the present invention.

The reference numbers are as follows:

01-an air inlet; 02-a first air outlet; 03-a second air outlet; 10-a first through-flow device; 21-an evaporator; 22-a compressor; 23-a heat sink; 24-a throttling device; 31-a water reservoir; 32-a first drive; 33-a refrigeration water tank; 34-an evaporative filtration unit; 41-second driving means; 42-a spray device; 43-second through-flow means; 44-a ventilation duct; 50-water level sensor.

Detailed Description

In order to explain technical contents, structural features, and objects and effects of the present invention in detail, the following detailed description is given with reference to the accompanying drawings in conjunction with the embodiments.

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the utility model and are not to be construed as limiting the utility model.

Referring to fig. 1, in the prior art, commonly used cooling devices are mainly fans and air conditioners, wherein hot air is blown out by the fans, and the cooling effect cannot be achieved, so that more users can select to use the air conditioners, but the air conditioners also have certain problems, such as high power and high energy consumption, and therefore, the problems need to be improved.

Referring to fig. 1, fig. 1 is a schematic diagram of a first structure of a hybrid refrigeration system according to the present invention. The first aspect of the utility model provides a hybrid refrigeration system, which comprises a main circulation loop, a first through-flow device 10 and a water-cooling circulation loop connected with the main circulation loop, wherein the main circulation loop comprises an evaporator 21, a compressor 22, a radiator 23 and a throttling device 24 which are sequentially connected through pipelines; the water-cooling circulation loop comprises a water storage device 31, a first driving device 32, a refrigeration water tank 33 and an evaporation filtering device 34 which are sequentially connected through pipelines; the evaporation filtering device 34 includes a porous water-absorbing part and a fixing part for mounting the water-absorbing part, and the water-absorbing part is respectively arranged corresponding to the water outlet of the refrigeration water tank 33, the first through-flow device 10 and the water inlet of the water storage device 31; the evaporator 21 is built in the refrigeration water tank 33, and the first driving device 32 is used for driving a pipeline to suck the liquid in the water storage device 31 to the refrigeration water tank 33 for cooling; a water absorption part in the evaporation filter device 34 is used for absorbing the liquid in the refrigeration water tank 33; the first through-flow device 10 is used to blow out the liquid sucked by the evaporation filter device 34 in the form of a gas mist to cool the ambient air.

In this embodiment, the hybrid refrigeration system is a novel intermediate product between a fan and an air conditioner, and on one hand, the hybrid refrigeration system has a refrigeration function that the existing fan does not have, and on the other hand, although the air conditioner has a refrigeration function, the air conditioner has a high power and a high energy consumption. Through the implementation of this embodiment, the first driving device 32 drives the pipeline to suck the liquid in the water storage device 31 to the cooling water tank 33 for cooling, and the liquid after cooling is conveyed to the water suction portion in the evaporation filtering device 34 through the pipeline to suck the liquid, and the first through-flow device 10 blows out the liquid on the water suction portion in the form of aerosol for discharging the hot air entering from the air inlet 01 through the first air outlet 02, thereby cooling the ambient air.

In addition, when the air conditioner is adopted as a refrigerating device in the prior art, cold air is blown out of the air conditioner, and cold air enters the air conditioner and is easy to get ill when a user uses the air conditioner for a long time.

Further, the fixing part is an installation frame; the water absorbing part is loose and porous bubble paper.

In this embodiment, the evaporation filtering device 34 includes an installation frame and a water absorption portion, wherein the installation frame is used for placing the water absorption portion, and a fixed position is provided for the water absorption portion, the water absorption portion is made of porous material, and the water absorption portion can be made of other materials such as bubble paper or sponge. The water outlet hole is formed in one side or the bottom of the refrigeration water tank 33, when the hybrid refrigeration system works, liquid in the refrigeration water tank 33 flows downstream to the water absorption part through the water outlet hole or a pipeline externally connected to the water outlet hole, the water absorption part absorbs the liquid to achieve a certain absorption state, the first through-flow device 10 can be arranged on one side of the water absorption part, specifically, the air outlet of the first through-flow device 10 is aligned with the water absorption part, and the first through-flow device 10 blows out the liquid in the water absorption part in a water mist mode by means of wind power of the first through-flow device to achieve the effect of cooling the indoor space. The number of water-absorbing portions and the number of first through-flow devices 10 are not limited to 1, 2, or more, and may be specifically set according to specific needs.

In addition, the water absorption and storage of the water absorption part are limited, when the water absorption degree of the water absorption part exceeds the self-storage degree, the water absorption part can drip water in a liquid form exceeding the storage part, and at the moment, the water storage device 31 is arranged right below the water absorption part, and the liquid dripping downwards from the water absorption part drips to the opening part of the water storage device 31, so that the effects of water circulation and water resource saving can be achieved. Furthermore, the evaporation filter device 34 may be provided with a filter assembly, i.e. the liquid coming out of the refrigerant tank 33 is first filtered by the filter assembly to remove any impurities that may be present, so that the liquid reaching the water absorption portion is clean and pollution-free.

Further, the water level control device further includes a water level sensor 50, the water level sensor 50 is disposed in the cooling water tank 33, and the water level sensor 50 is used to control the amount of water in the water storage device 31 by the first driving device 32. The water level sensor 50 is arranged to sense the water level height in the refrigeration water tank 33, when the water level is higher than a certain threshold value, the first driving device 32 is stopped to supply water to the refrigeration water tank 33, when the water level height is lower than the certain threshold value, the first driving device 32 is started to supply water to the refrigeration water tank 33, and when the water level height is lower than the certain threshold value, the evaporator 21 is stored to a certain amount, so that the evaporator 21 performs centralized refrigeration, and the loss of electric energy is avoided.

Further, the main circulation circuit includes an evaporator 21, a compressor 22, a radiator 23, and a throttle device 24, which are connected in this order by pipes. Wherein, the evaporator 21 can be any one of a single-pass type evaporator, a circulation type evaporator, a batch type evaporator and a continuous type evaporator, or other types of evaporators are selected according to specific requirements; the compressor 22 is a piston compressor, a screw compressor, a centrifugal compressor, a linear compressor, or the like. The radiator 23 may be a compression condenser; the restriction 24 may be a capillary tube and a throttle valve. The specific refrigeration process is that the compressor 22 sucks low-temperature low-pressure freon gas from the evaporator 21, the low-temperature low-pressure freon gas is compressed into high-temperature high-pressure freon gas, then the high-temperature high-pressure freon gas flows through a thermal expansion valve (capillary tube) and is throttled into low-temperature low-pressure freon gas-liquid two-phase objects, then the low-temperature low-pressure freon liquid is absorbed in the evaporator 21 to be refrigerated in the refrigeration water tank 33 to become low-temperature low-pressure freon gas, and the low-temperature low-pressure freon gas is sucked by the compressor 22. After the liquid to be refrigerated has passed through the evaporator 21, heat is released and the temperature drops. So compression, condensation, throttle evaporation is circulated repeatedly, and the refrigerant constantly takes away the heat of treating the refrigeration liquid in refrigeration water tank 33 to the temperature of treating the refrigeration liquid has been reduced.

Further, the heat dissipation device further includes a heat dissipation path including a second driving device 41 and a shower device 42, the second driving device 41 is connected to the water storage device 31, the shower device 42 is connected to the second driving device 41, and an outlet of the shower device 42 is provided corresponding to the radiator 23. The heat dissipation path further includes a second flow-through device 43 and a ventilation duct 44, the second flow-through device 43 is provided corresponding to the heat dissipation portion of the heat sink 23, and the ventilation duct 44 is connected to an air outlet of the second flow-through device 43.

In the present embodiment, a heat dissipation path is further provided, the heat dissipation path is mainly composed of the second driving device 41 and the spraying device 42, when the heat sink 23 works for a long time, a large amount of heat is emitted, so that the heat sink 23 generates heat, and the heat dissipation path is provided for cooling the heat sink 23. The water outlet can be arranged on one side of the water storage device 31 close to the radiator 23, the water outlet is connected with the second driving device 41 through a pipeline, the second driving device 41 is connected with the spraying device 42 in the working process, the second driving device 41 drives the water pipe to extract liquid in the water storage device 31, the liquid is sprayed on the radiator 23 through the spraying device 42, the heat of the radiator 23 is dissipated by utilizing water vapor, the heat transfer capacity of the water is 16 times that of air positioning, therefore, the working efficiency of the hybrid refrigeration system is improved, and a better refrigeration effect is achieved. In addition, the heat dissipation path further includes a second through-flow device 43 and a ventilation duct 44, the system is connected to the outside through the ventilation duct 44, the second through-flow device 43 blows hot air upwards by utilizing the characteristic that hot air is light and floats upwards, or when the system is used indoors, the hot air can be blown out to the outside air through the second air outlet 03 by connecting the ventilation duct 44, and the refrigeration efficiency is further improved. The first driving device 32 and the second driving device 41 are both water pumps. The first and second flow devices 10 and 43 are fans.

In addition, the air conditioner in the prior art is generally large in size and is installed indoors, and the hybrid refrigeration device obtained through the hybrid refrigeration system adopted by the utility model is generally a plug-in power supply, can be used indoors and outdoors as required and is convenient to carry.

In summary, the present invention provides a hybrid refrigeration system, in which a first driving device 32 drives a pipeline to suck the liquid in a water storage device 31 into a refrigeration water tank 33 for cooling, and the cooled liquid is transported to a water suction part in an evaporation filter device 34 through the pipeline to suck the liquid, and the first flow device 10 blows out the liquid on the water suction part in the form of gas mist for cooling the ambient air. And then, by providing a heat dissipation passage to cool the heat radiator 23, the hybrid refrigeration system not only can realize the refrigeration effect, but also can obtain the effects of saving energy and avoiding electric energy loss.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes performed by the present specification and drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. A hybrid refrigeration system is characterized by comprising a main circulation loop, a first through flow device and a water-cooling circulation loop connected with the main circulation loop, wherein the main circulation loop comprises an evaporator, a compressor, a radiator and a throttling device which are sequentially connected through pipelines; the water cooling circulation loop comprises a water storage device, a first driving device, a refrigeration water tank and an evaporation filtering device which are sequentially connected through pipelines; the evaporation filtering device comprises a loose and porous water absorbing part and a fixing part for mounting the water absorbing part, and the water absorbing part is respectively arranged corresponding to a water outlet of the refrigeration water tank, the first through-flow device and a water inlet of the water storage device; the evaporator is arranged in the refrigeration water tank, and the first driving device is used for driving a pipeline to suck liquid in the water storage device to the refrigeration water tank for cooling; the water absorption part in the evaporation filtering device is used for absorbing liquid in the refrigerating water tank; the first through-flow device is used for blowing out the liquid absorbed by the evaporation and filtration device in the form of aerial fog to cool the surrounding air.

2. A hybrid refrigeration system as set forth in claim 1 further including a heat dissipation path including a second drive and a spray device, said second drive being connected to said water reservoir, said spray device being connected to said second drive, said spray device having an outlet disposed in correspondence with said heat sink.

3. The hybrid refrigeration system according to claim 2, wherein the heat dissipation path further comprises a second flow-through device and a ventilation duct, the second flow-through device is disposed corresponding to the heat dissipation portion of the heat sink, and the ventilation duct is connected to an air outlet of the second flow-through device.

4. A hybrid refrigeration system as set forth in claim 1 wherein said stationary portion is a mounting bracket; the water absorption part is loose and porous bubble paper.

5. A hybrid refrigeration system as set forth in claim 1 and including a water level sensor disposed in said refrigerant tank for controlling the amount of water in said water reservoir by means of a first drive means.

6. A hybrid refrigeration system as set forth in claim 1 wherein said throttling means is a manual throttle or an automatic throttle.

7. A hybrid refrigeration system as set forth in claim 2 wherein said compressor includes a high pressure line and a low pressure line, said compressor being connected to said evaporator by said high pressure line; the compressor is connected with the radiator through the low-pressure pipe.

8. A hybrid refrigeration system as set forth in claim 1 and including a dry filter, said dry filter being connected at one end to said heat sink and at another end to said throttling means.

9. A hybrid refrigeration system as set forth in claim 2 wherein said first drive means and said second drive means are both water pumps.

10. A hybrid refrigeration system of claim 3, wherein the first and second cross flow devices are each fans.

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