CN116294260A - Refrigerating system and double-layer test box - Google Patents

Abstract

The invention discloses a refrigerating system and a double-layer test box. The refrigerating system comprises a refrigerating main circuit and a refrigerating branch circuit; the refrigerating main circuit comprises a compressor, a condenser and an evaporator; the refrigeration branch comprises the compressor, a refrigeration pipeline and the evaporator; a part of refrigerant gas discharged by the compressor is transmitted to a condenser through a main refrigeration path to be condensed into refrigerant liquid and flows into the evaporator; a part of the refrigerant gas discharged by the compressor is mixed with the refrigerant liquid through a refrigeration branch and then is transmitted to the evaporator; the refrigerating branch comprises a first refrigerating branch and a second refrigerating branch which are arranged in parallel; when the amount of the refrigerating liquid required to flow into the evaporator is large, the first refrigerating branch and the second refrigerating branch are controlled to simultaneously transmit the refrigerating gas; when the amount of the refrigerating liquid required to flow into the evaporator is small, the first refrigerating branch and the second refrigerating branch are controlled to alternately transmit the refrigerating gas. The invention can ensure the stability of the refrigerating system and avoid the waste of energy sources in the refrigerating system.

Description

Refrigerating system and double-layer test box

The application is named: double-deck refrigerating system and double-deck proof box, application number is: the patent of 202210319904.5 is filed separately, and the application date of the parent application is 2022, 03 and 29.

Technical Field

The invention relates to the technical field of refrigeration, in particular to a refrigeration system and a double-layer test box.

Background

The test box is suitable for reliability tests of products at different temperatures, and various performance indexes of parts and materials of related products are tested under the condition of cyclic variation of different temperatures.

Among them, the test chamber requires a refrigerating system for performing a low temperature test, which is a system for transferring heat from a substance (or environment) having a relatively high temperature to a substance (or environment) having a relatively low temperature by using external energy. The working principle of the heat exchanger is to exchange heat through the state change of working media. The existing two-box type high-low temperature test box is characterized in that each box body in the test box is independently provided with a refrigerating system, but the problems of low stability and energy waste of the refrigerating system exist.

Disclosure of Invention

In view of the above, the embodiment of the invention provides a refrigeration system and a double-layer test box, which are used for solving the problems of low stability and energy waste of the existing refrigeration system.

In a first aspect, an embodiment of the present invention provides a refrigeration system, where the refrigeration system includes a refrigeration main circuit and a refrigeration branch circuit;

the refrigerating main circuit comprises a compressor, a condenser and an evaporator;

the refrigeration branch comprises the compressor, a refrigeration pipeline and the evaporator which are arranged in series;

a part of the first refrigeration gas discharged by the compressor is transmitted to the condenser through the refrigeration main path to be condensed into refrigeration liquid, and flows into the evaporator;

a part of the first refrigeration gas discharged by the compressor is mixed with the refrigeration liquid through the refrigeration branch and then is transmitted to the evaporator;

the refrigerating branch comprises a first refrigerating branch and a second refrigerating branch which are arranged in parallel; the first refrigeration branch and the second refrigeration branch simultaneously or alternately transmit the first refrigeration gas to realize the mixing of the first refrigeration gas discharged by the compressor and the refrigeration liquid;

controlling the first refrigeration branch and the second refrigeration branch to simultaneously transmit the first refrigeration gas based on the fact that the evaporator needs to be more in refrigerating liquid quantity;

and controlling the first refrigeration branch and the second refrigeration branch to alternately transmit the first refrigeration gas based on the condition that the amount of the refrigeration liquid required to flow into the evaporator is smaller.

Optionally, the first refrigeration branch comprises a first refrigeration pipeline, and the second refrigeration branch comprises a second refrigeration pipeline;

the compressor transmits the discharged first refrigeration gas to the evaporator through the first refrigeration pipeline and the second refrigeration pipeline respectively;

the first refrigeration branch further comprises a first branch switch assembly arranged in the first refrigeration pipeline, and the first branch switch assembly comprises a first electromagnetic valve;

the second refrigeration branch further comprises a second branch switch assembly arranged in the second refrigeration pipeline, and the second branch switch assembly comprises a second electromagnetic valve;

the first solenoid valve and the second solenoid valve are both used for controlling the flow rate of the first refrigeration gas transmitted to the inlet of the evaporator.

Optionally, the refrigeration system further comprises a main circuit switch assembly serially arranged on the refrigeration main circuit;

the main circuit switch assembly comprises an electronic expansion valve, the electronic expansion valve is arranged on the refrigerating main circuit between the outlet of the condenser and the inlet of the evaporator in series, and the electronic expansion valve is used for controlling the flow of the refrigerating fluid.

Optionally, the refrigeration system further comprises a temperature detection device arranged on the refrigeration main circuit in series;

the temperature detection device comprises a first temperature sensor and a second temperature sensor;

the first temperature sensor is used for detecting the temperature of the exhaust port of the compressor, and the second temperature sensor is used for detecting the temperature of the outlet of the condenser.

Optionally, the refrigeration system further comprises an oil return branch and an oil separator which is arranged on the oil return branch in series;

the oil separator is positioned at the exhaust port of the compressor;

and an outlet of the oil separator is connected with an air inlet of the compressor based on the oil return branch, and part of oil in the oil separator is returned to the compressor based on the oil return branch.

Optionally, the refrigeration system further comprises a regulating branch;

the condenser transmits the discharged refrigerating liquid to the compressor through the regulating branch; the adjusting branch further comprises an adjusting switch assembly which is arranged on the adjusting branch in series;

the regulating switch assembly comprises a liquid spraying electromagnetic valve, and the liquid spraying electromagnetic valve is used for controlling the refrigerating liquid to flow into the compressor.

Optionally, the refrigeration system further comprises a pressure detection device arranged on the refrigeration main circuit in series;

the pressure detection device comprises a first pressure sensor and a second pressure sensor;

the first pressure sensor is used for detecting the pressure at the inlet of the condenser, and the second pressure sensor is used for detecting the pressure at the air inlet of the compressor.

Optionally, the refrigeration system further comprises a gas-liquid separation device arranged on the refrigeration main path in series;

the gas-liquid separation device is arranged at the outlet of the evaporator and the air inlet of the compressor in series, the evaporator evaporates the refrigerating liquid into second refrigerating gas, and the gas-liquid separation device is used for separating the second refrigerating gas from the refrigerating liquid.

Optionally, the condenser is provided with a condensing fan, and the high-temperature and high-pressure refrigerant gas discharged by the compressor, namely the first refrigerant gas, is condensed into the refrigerant liquid by the condensing fan.

In a second aspect, an embodiment of the present invention provides a double-deck test chamber, where the double-deck test chamber includes a first refrigeration system and a second refrigeration system; the first refrigeration system and the second refrigeration system each comprise a refrigeration system of any of the first aspects.

The embodiment of the invention provides a refrigeration system, which comprises a refrigeration main circuit and a refrigeration branch circuit; the refrigerating main circuit comprises a compressor, a condenser and an evaporator; the refrigeration branch comprises the compressor, a refrigeration pipeline and the evaporator; a part of the refrigerant gas discharged by the compressor is transmitted to the condenser through the refrigeration main path to be condensed into refrigeration liquid, and flows into the evaporator; a part of the refrigerating gas discharged by the compressor is mixed with the refrigerating liquid through the refrigerating branch and then is transmitted to the evaporator; controlling the first refrigeration branch and the second refrigeration branch to simultaneously transmit the refrigeration gas based on the fact that the evaporator needs to be more in quantity of the refrigeration liquid; and controlling the first refrigeration branch and the second refrigeration branch to alternately transmit the refrigeration gas based on the condition that the amount of the refrigeration liquid required to flow into the evaporator is smaller. By additionally arranging two refrigeration branches on the basis of the refrigeration main path and controlling the conduction mode of the two refrigeration branches according to the volume of the refrigeration liquid required by the evaporator, the flow of the refrigeration liquid in the evaporator is improved, the stability of the refrigeration system is ensured, and the waste of energy sources in the refrigeration system can be avoided.

Drawings

In order to more clearly illustrate the technical solution of the exemplary embodiments of the present invention, a brief description is given below of the drawings required for describing the embodiments. It is obvious that the drawings presented are only drawings of some of the embodiments of the invention to be described, and not all the drawings, and that other drawings can be made according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic structural diagram of a dual-layer refrigeration system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram of another dual-layer refrigeration system according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a double-layer test chamber according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be fully described below by way of specific embodiments with reference to the accompanying drawings in the examples of the present invention. It is apparent that the described embodiments are some, but not all, embodiments of the present invention, and that all other embodiments, which a person of ordinary skill in the art would obtain without making inventive efforts, are within the scope of this invention.

The embodiment of the invention provides a double-layer refrigerating system, fig. 1 is a schematic structural diagram of the double-layer refrigerating system provided by the embodiment of the invention, and as shown in fig. 1, a double-layer refrigerating system 10 comprises a first refrigerating system A and a second refrigerating system B; the first refrigeration system A and the second refrigeration system B comprise a refrigeration main circuit a1 and a refrigeration branch circuit a2; the first and second refrigeration systems a and B include a compressor 100, a condenser 200, and an evaporator 300 disposed in series; wherein, the inlet 200A of the condenser is connected with the exhaust port 100B of the compressor, and the condenser 200 is used for liquefying the first refrigerant gas discharged from the compressor 100 into a refrigerant liquid; the inlet 300A of the evaporator is connected with the outlet 200B of the condenser, and the evaporator 300 is used for evaporating the refrigeration liquid into a second refrigeration gas; wherein the pressure of the first refrigerant gas is higher than the pressure of the second refrigerant gas, and the temperature of the first refrigerant gas is higher than the temperature of the second refrigerant gas; the air inlet 100A of the compressor is connected with the outlet 300B of the evaporator, and the compressor 100 is used for receiving the second refrigerant gas; the refrigeration branch a2 includes a compressor 100, a refrigeration line a2', and an evaporator 300 disposed in series, and the compressor 100 transfers the discharged refrigerant gas to the evaporator 300 through the refrigeration line a 2'.

The double-layer refrigeration system 10 comprises a first refrigeration system A and a second refrigeration system B, the temperature can be adjusted under the two refrigeration systems, the first refrigeration system A and the second refrigeration system B are independently arranged, mutual interference is avoided, and the refrigeration efficiency of the double-layer refrigeration system 10 is improved. Specifically, the first refrigeration system a and the second refrigeration system B both include a refrigeration main path a1 and a refrigeration branch path a2, and stability of the double-layer refrigeration system 10 is ensured by adding the refrigeration branch path a2 on the basis of the refrigeration main path a1, i.e. two lines.

Specifically, as shown in fig. 1, the first refrigeration system a and the second refrigeration system B in the dual-layer refrigeration system 10 have the same structure, and the first refrigeration system a is specifically described as an example. The compressor 100, the condenser 200 and the evaporator 300 included in the cooling main path a1 are used for adjusting the temperature of the environment. Specifically, the compressor 100 is a core component of the entire refrigeration system 10, the air inlet 100A of the compressor is filled with low-temperature low-pressure refrigerant gas, the low-temperature low-pressure refrigerant gas is compressed by internal operation, and then high-temperature high-pressure refrigerant gas is discharged at the air outlet 100B of the compressor, and the compressor 100 provides circulating power for the entire refrigeration system 10. Specifically, the inlet 100A of the compressor is fed with the second refrigerant gas, and the outlet 100B of the compressor is discharged with the first refrigerant gas, wherein the pressure of the first refrigerant gas is higher than the pressure of the second refrigerant gas, and the temperature of the first refrigerant gas is higher than the temperature of the second refrigerant gas. For example, the specification model of the compressor 100 may be ZF15KQE, and the specific model of the compressor 100 is not limited in the embodiment of the present invention. The condenser 200 has a condensing fan by which high-temperature and high-pressure refrigerant gas discharged from the compressor 100, i.e., first refrigerant gas, is condensed into a refrigerant liquid, so as to flow on the refrigeration main path a1 and complete the cycle of the refrigeration system 10. For example, the specification and model of the condenser 200 may be T210130T, and the specification and model of the condensing fan may be YWF E-400S, and the specific model of the condenser 200 is not limited in the embodiment of the present invention. The refrigerant liquid flows into the evaporator 300, the evaporator 300 evaporates the refrigerant liquid to form a low-temperature low-pressure refrigerant gas, namely a second refrigerant gas, and the evaporation process is accompanied by heat absorption, so that the ambient temperature is reduced, and the specification model of the evaporator 300 may be exemplified by T210021T, and the specific model of the evaporator 300 is not limited in the embodiment of the present invention. Optionally, the air outlet direction of the evaporator 300 may be a horizontal air outlet, and meanwhile, the inlet 300A of the evaporator and the outlet 300B of the evaporator may be wrapped with insulation cotton and then plugged into the insulation layer, so that uniformity of temperature adjustment can be ensured. More needle valves and ball valves may also be present in the first refrigeration system a and the second refrigeration system B included in the dual-layer refrigeration system 10 provided in the embodiment of the present invention, which are not shown in fig. 1, and the embodiment of the present invention is not limited in particular.

Specifically, the refrigeration branch a2 includes the compressor 100, the refrigeration pipeline a2 'and the evaporator 300 arranged in series, so that the first refrigerant gas discharged from the compressor 100 is transferred to the inlet 300A of the evaporator 300 through the refrigeration pipeline a 2'. That is, a part of the first refrigerant gas discharged from the compressor 100 may be transferred to the condenser 200 through the refrigeration main path a1 to be condensed into a refrigerant liquid, and flow into the evaporator 300, and a part of the first refrigerant gas discharged from the compressor 100 may be mixed with the refrigerant liquid through the refrigeration branch path a2 and then transferred to the evaporator 300. By mixing the first refrigerant gas and the refrigerant liquid and then flowing the mixture into the evaporator 300, the heat and cold of the refrigerant liquid before flowing into the evaporator 300 can be counteracted, and the flow rate of the refrigerant liquid entering the evaporator 300 can be increased. That is, by providing the refrigeration branch a2, the first refrigeration gas discharged from the compressor 100 is mixed with the refrigeration liquid condensed by the condenser 200, so that the cold and hot offset of the refrigerant is realized, the refrigerant is more stably and stably transmitted to the evaporator 300, the effective refrigeration liquid flowing into the evaporator 300 is ensured, and the consumption of energy sources in the first refrigeration system A is reduced. The first refrigeration system a and the second refrigeration system B are arranged in the same manner, so that the energy loss of the first refrigeration system a and the second refrigeration system B can be avoided being reduced, namely the energy loss of the double-layer refrigeration system 10 is reduced.

Optionally, filters (not shown) may be added to the first refrigeration system a and the second refrigeration system B, so that impurities in the refrigeration liquid are filtered out by the filters, and subsequent operations of the evaporator 300 are not affected.

In summary, the double-layer refrigeration system provided by the embodiment of the invention comprises a first refrigeration system and a second refrigeration system, wherein the first refrigeration system and the second refrigeration system both comprise a refrigeration main path and a refrigeration branch path, and by means of simultaneously setting the refrigeration main path and the refrigeration branch path, a part of first refrigeration gas discharged by a compressor is transmitted to a condenser to be condensed into refrigeration liquid through the refrigeration main path and flows into an evaporator, and the other part of the first refrigeration gas discharged by the compressor is mixed with the refrigeration liquid through the refrigeration branch path and then is transmitted to the evaporator. The first refrigerating gas and the refrigerating liquid are mixed and then flow into the evaporator, the flow of the refrigerating liquid entering the evaporator is increased through the counteraction of the cold and the heat of the refrigerating liquid, and meanwhile, the energy loss of the double-layer refrigerating system is reduced.

Fig. 2 is a schematic structural diagram of another dual-layer refrigeration system according to an embodiment of the present invention, and referring to fig. 2, a refrigeration branch a2 includes a first refrigeration branch a21 and a second refrigeration branch a22 that are arranged in parallel; the first refrigeration branch a21 includes a first refrigeration line a21', the second refrigeration branch a22 includes a second refrigeration line a22', and the compressor 100 transfers the discharged refrigerant gas to the evaporator 300 through the first refrigeration line a21 'and the second refrigeration line a22', respectively.

The first refrigeration branch a21 and the second refrigeration branch a22 are arranged in parallel, that is, any refrigeration branch a2 of the first refrigeration branch a21 and the second refrigeration main a22 can complete the transmission of the first refrigeration gas discharged from the compressor 100 to the inlet 300A of the evaporator. The first refrigeration branch a21 and the second refrigeration branch a22 can simultaneously or alternately transmit the first refrigeration gas, so as to realize mixing of the discharged first refrigeration gas of the compressor 100 and the refrigeration liquid, namely, when the amount of the inflow refrigeration liquid required by the evaporator 300 is large, the first refrigeration branch a21 and the second refrigeration branch a22 are controlled to simultaneously transmit the first refrigeration gas, namely, when the amount of the inflow refrigeration liquid required by the evaporator 300 is small, the first refrigeration branch a21 and the second refrigeration branch a22 are controlled to alternately transmit the first refrigeration gas. By controlling the parallel refrigeration branches a2 to reliably complete the mixing of the first refrigerant gas and the refrigerant liquid before flowing into the evaporator 300 and the cold and heat cancellation, the stable and reliable operation of the refrigeration system 10 is ensured. Further, as shown in fig. 2, in the first refrigeration system a, the first refrigeration branch a21 includes a first refrigeration pipeline a21', the second refrigeration branch a22 includes a second refrigeration pipeline a22', the first refrigeration gas is transferred to the evaporator 300 through the first refrigeration pipeline a21 'and the second refrigeration pipeline a22', and the first refrigeration gas and the refrigeration liquid discharged from the condenser 200 are subjected to cold and hot offset, so that the flow of the refrigeration liquid in the evaporator 300 is improved. The arrangement in the second refrigeration system B is the same as that of the first refrigeration system a, and redundant description of the second refrigeration system B is omitted here. Further, when the content of the refrigerant liquid required to flow into the evaporator 300 is high, the first refrigerant gas required to be mixed with the refrigerant liquid is also high, and in this case, the first refrigerant gas can be simultaneously transferred by controlling the first refrigerant pipeline a21 'and the second refrigerant pipeline a22', so as to ensure that the content of the refrigerant liquid required by the evaporator 300 is met. Further, when the amount of the refrigerant liquid required to flow into the evaporator 300 is small, the amount of the first refrigerant gas required to be mixed with the refrigerant liquid is small, and in this case, the first refrigerant line a21 'is controlled to be conducted to transmit the first refrigerant gas or the second refrigerant line a22' is controlled to transmit the first refrigerant gas. The embodiment of the present invention is not particularly limited thereto. The first refrigeration pipeline a21 'and the second refrigeration pipeline a22' ensure the lifting of the flow of the refrigeration liquid in the evaporator 300 in the first refrigeration system A and the second refrigeration system B, and avoid the waste of energy sources, namely the waste of energy sources in the double-layer refrigeration system 10.

With continued reference to fig. 2, the first refrigeration branch a21 further includes a first branch switch assembly 410 disposed in the first refrigeration circuit a21', the first branch switch assembly 410 including a first solenoid valve 411; the second refrigeration branch a22 further includes a second branch switch assembly 420 disposed in the second refrigeration line a22', the second branch switch assembly 420 including a second solenoid valve 421; the first solenoid valve 411 and the second solenoid valve 421 are each used to control the flow rate of the first refrigerant gas transferred to the inlet 300A of the evaporator.

As shown in fig. 2, the first refrigeration system a further includes a first bypass switch assembly 410 and a second bypass switch assembly 420, where the first bypass switch assembly 410 is located in the first refrigeration pipeline a21', the first bypass switch assembly 410 is used for controlling the first refrigeration pipeline a21' to transmit the first refrigerant gas to the inlet 300A of the evaporator when turned on, the second bypass switch assembly 420 is located in the second refrigeration pipeline a22', and the second bypass switch assembly 420 is used for controlling the second refrigeration pipeline a22' to transmit the first refrigerant gas to the inlet 300A of the evaporator when turned on. The second refrigeration system B has the same configuration, and will not be described in detail here.

Further, the first bypass switch assembly 410 includes a first solenoid valve 411, and the second bypass switch assembly 420 includes a second solenoid valve 421, i.e., the first solenoid valve 411 provided in the first cooling line a21 'controls the on and off of the first cooling line a21', and the second solenoid valve 421 provided in the second cooling line a22 'controls the on and off of the first cooling line a 22'. For example, the specification model of the first solenoid valve 411 and the second solenoid valve 421 may be FDF8A, and the specific model of the first solenoid valve 411 and the second solenoid valve 421 is not limited in the embodiment of the present invention. The control of the on and off of the refrigeration branch a2 is realized by setting the on and off of the first electromagnetic valve 411 and the second electromagnetic valve 421, and thus the control of the on and off of the first refrigeration branch a21 and the second refrigeration branch a22 can be realized.

Specifically, when the amount of the refrigerant liquid required to flow into the evaporator 300 is large, the amount of the first refrigerant gas required to be mixed with the refrigerant liquid is also large, in which case the first solenoid valve 411 is controlled to conduct the first refrigerant gas, and the second solenoid valve 421 is controlled to conduct the first refrigerant gas. When the amount of the refrigerant liquid required to flow into the evaporator 300 is small, the amount of the first refrigerant gas required to be mixed with the refrigerant liquid is small, and in this case, the intermittent conduction of the first solenoid valve 411 is controlled to intermittently transfer the first refrigerant gas, or the intermittent conduction of the second solenoid valve 421 is controlled to intermittently transfer the first refrigerant gas. Or when the amount of the refrigerant flowing into the evaporator 300 is small, the intermittent time of the first electromagnetic valve 411 or the second electromagnetic valve 421 is controlled, so that the mixing of the first refrigerant gas and the refrigerant liquid can be further reduced. Illustratively, the first solenoid valve 411 and the second solenoid valve 421 are simultaneously opened, i.e., the first refrigeration branch a21 and the second refrigeration branch a22 simultaneously transfer the first refrigerant gas to the inlet 300A of the evaporator, thereby increasing the first refrigerant gas transfer speed and flow rate. The first electromagnetic valve 411 is alternately opened and closed, and the second electromagnetic valve 421 is alternately opened and closed, that is, the first refrigeration branch a21 alternately transmits the first refrigeration gas, and the second refrigeration branch a22 also alternately transmits the first refrigeration gas, so that the flow of the first refrigeration gas can be more effectively controlled.

With continued reference to fig. 2, the first refrigeration system a and the second refrigeration system B further include a main circuit switch assembly 430 disposed in series on the refrigeration main circuit a 1; the main circuit switch assembly 430 includes an electronic expansion valve 431, the electronic expansion valve 431 is serially arranged on the refrigeration main circuit a1 between the outlet 200B of the condenser and the inlet 300A of the evaporator, and the electronic expansion valve 431 is used for controlling the flow rate of the refrigerant liquid.

As shown in fig. 2, the main switch assembly 430 is disposed on the refrigeration main path a1 of the first refrigeration system a and the second refrigeration system B, and the main switch assembly 430 includes an electronic expansion valve 431, which is specifically illustrated and described in fig. 2 by taking the first refrigeration system a as an example. A better control of the flow of the refrigerant liquid into the evaporator 400 can be achieved by providing the electronic expansion valve 431.

Specifically, the electronic expansion valve 431 can realize a 45-200 step adjustment interval, accurately control the flow of the refrigerant liquid entering the evaporator 300, can realize accurate adjustment of the evaporation temperature of the evaporator 300, avoid the inflow of excessive refrigerant liquid, and can greatly reduce the temperature overshoot. The working efficiency of the double-layer refrigerating system 10 is improved, the waste of energy is avoided, and the accurate control of temperature is realized. For example, the electronic expansion valve 431 may have a specification type UKV D, and the embodiment of the present invention is not limited to the specific type of the main switch assembly 430.

With continued reference to fig. 2, the first refrigeration system a and the second refrigeration system B further include a temperature detecting device 500 disposed in series on the refrigeration main path a 1; the temperature detection device 500 includes a first temperature sensor 510 and a second temperature sensor 520; the first temperature sensor 510 is used to detect the temperature of the compressor's discharge port 100B, and the second temperature sensor 520 is used to detect the temperature of the condenser's outlet 200A.

As shown in fig. 2, in the first refrigeration system a and the second refrigeration system B, the temperature detection device 500 is serially arranged on the refrigeration main path a1, so as to detect temperatures at the inlet and outlet positions of different devices on the refrigeration main path a1, prevent abnormal trip temperatures, facilitate the transmission of the first refrigeration gas and the refrigeration liquid, and ensure the stability of the double-layer refrigeration system 10.

Specifically, the temperature detection device 500 includes a first temperature sensor 510 and a second temperature sensor 520, wherein the first temperature sensor 510 detects the temperature of the discharge port 100B of the compressor that discharges the first refrigerant gas, and the second temperature sensor 520 detects the temperature of the outlet 200B of the condenser that generates the refrigerant liquid. Based on the temperature information acquired by the temperature detection device 500, the flow rate of the refrigerant liquid is controlled. Illustratively, the opening of the electronic expansion valve 431 is adaptively adjusted to adjust the flow rate of the refrigerant liquid based on the temperature detected by the second temperature sensor 520. For example, the specification model of the first temperature sensor 510 may be NTC, and the specification model of the second temperature sensor 520 may be NTC, and the specific model of the temperature detection module 500 is not limited in the embodiment of the present invention. By adding the temperature detection device 500, the double-layer refrigeration system 10 is ensured to be safer and more reliable, and energy is saved.

With continued reference to fig. 2, the first refrigeration system a and the second refrigeration system B each include an oil return branch a3; the first refrigeration system a and the second refrigeration system B further comprise an oil separator 700 disposed in series on the oil return branch a3; the oil separator 700 is located at the discharge port 100B of the compressor; the outlet 700B of the oil separator is connected to the intake port 100A of the compressor based on the oil return branch line a3, and returns part of the oil in the oil separator 700 to the compressor 100 based on the oil return branch line a 3.

As shown in fig. 2, the first refrigeration system a and the second refrigeration system B each include an oil return branch a3, the oil separator 700 is disposed in the oil return branch a3, the oil separator 700 separates lubricating oil in the first refrigerant gas discharged from the compressor 100, and the separated lubricating oil is retransmitted to the compressor 100 through the oil return branch a3, so that the lubricating oil is prevented from flowing into the subsequent refrigeration main circuit a1 or the refrigeration branch a2, multiple uses of the lubricating oil are realized, and meanwhile, waste of resources is avoided. By way of example, the oil separator 700 may be of the type A-WZ55824, and embodiments of the invention are not specifically limited thereto.

With continued reference to fig. 2, both the first refrigeration system a and the second refrigeration system B include a conditioning branch a4; the condenser 200 delivers the discharged refrigerant liquid to the compressor 100 through the conditioning branch a4; the adjusting branch a4 further comprises an adjusting switch assembly 440 arranged in series on the adjusting branch a4; the regulating switch assembly 440 includes a spray solenoid valve 441, and the spray solenoid valve 441 is used to control the flow rate of the first refrigerant gas discharged from the compressor 100. The second refrigeration system B has the same configuration, and will not be described in detail here.

Further, the first refrigeration system a and the second refrigeration system B each include a regulating branch a4, and a spraying electromagnetic valve 441 on the regulating branch a4 can control the flow of the refrigeration liquid back to the compressor 100. Specifically, the temperature at the discharge port 100B of the compressor may be obtained based on the first temperature sensor 510, and the liquid spraying electromagnetic valve 441 may adjust the temperature at the discharge port 100B of the compressor by controlling the back flow of the refrigerant liquid based on the temperature information obtained by the first temperature sensor 510. The compressor 100 is ensured to operate stably and reliably, and the working stability of the refrigerating system 10 is improved.

With continued reference to fig. 2, the first refrigeration system a and the second refrigeration system B further include a pressure detection device 600 disposed in series on the refrigeration main path a 1; the pressure detecting device 600 includes a first pressure sensor 610 and a second pressure sensor 620; the first pressure sensor 610 is used to detect the pressure at the inlet 200A of the condenser and the second pressure sensor 620 is used to detect the pressure at the inlet 100A of the compressor.

As shown in fig. 2, in the first refrigeration system a and the second refrigeration system B, the pressure detection device 600 is serially arranged on the refrigeration main path a1, so as to detect the pressures at the inlet and outlet positions of different devices on the refrigeration main path a1, prevent the occurrence of pressure abnormality, facilitate the transmission of the first refrigeration gas and the refrigeration liquid, and ensure the stability of the double-layer refrigeration system 10.

Specifically, the pressure detecting device 600 includes a first pressure sensor 610 and a second pressure sensor 620, the first pressure sensor 610 detecting the pressure at the inlet 200A of the condenser, and the second pressure sensor 620 detecting the pressure at the inlet 100A of the compressor. The flow rate of the first refrigerant gas discharged from the compressor 100 is adaptively adjusted based on the pressure detected by the pressure detecting means 600. For example, the specification and model of the first pressure sensor 610 may be H20PS B2.5/1.8-2500, and the specification and model of the second pressure sensor 620 may be H20PS B2.5/-0.5-2500, which is not limited by the specific model of the pressure detecting device 600 in the embodiment of the present invention. By adding the pressure detection device 600, the double-layer refrigeration system 10 is ensured to be safer and more reliable, and energy is saved.

With continued reference to fig. 2, the first refrigeration system a and the second refrigeration system B further include a gas-liquid separation device 800 disposed in series on the refrigeration main path a 1; the gas-liquid separation device 800 is disposed in series at the outlet 300B of the evaporator and the inlet 100A of the compressor, and the gas-liquid separation device 800 is used for separating the second refrigerant gas from the refrigerant liquid.

The first refrigeration system a and the second refrigeration system B further include a gas-liquid separation device 800 disposed on the refrigeration main path a1 in series, and the gas-liquid separation device 800 is configured to separate the refrigeration liquid before being transferred to the compressor 100 from the second refrigeration gas, so as to ensure that only the second refrigeration gas is transferred to the compressor 100, and ensure that the compressor 100 is provided with power for working, i.e. ensure that the whole refrigeration system 10 provides stable circulating power. The specification model of the gas-liquid separation device 800 may be FA-207, and the specific model of the gas-liquid separation device 800 is not limited in the embodiment of the present invention.

Based on the same inventive concept, the embodiment of the present invention further provides a double-layer test chamber, and fig. 3 is a schematic structural diagram of the double-layer test chamber provided by the embodiment of the present invention, and as shown in fig. 3, the double-layer test chamber 1 includes the double-layer refrigeration system 10 described in any of the foregoing embodiments, so that the double-layer test chamber 1 provided by the embodiment of the present invention has the corresponding beneficial effects in the foregoing embodiments, which are not repeated herein.

Note that the above is only a preferred embodiment of the present invention and the technical principle applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, and that various obvious changes, rearrangements, combinations, and substitutions can be made by those skilled in the art without departing from the scope of the invention. Therefore, while the invention has been described in connection with the above embodiments, the invention is not limited to the embodiments, but may be embodied in many other equivalent forms without departing from the spirit or scope of the invention, which is set forth in the following claims.

Claims (10)

1. A refrigeration system, characterized by comprising a refrigeration main circuit and a refrigeration branch circuit;

the refrigerating main circuit comprises a compressor, a condenser and an evaporator;

the refrigeration branch comprises the compressor, a refrigeration pipeline and the evaporator which are arranged in series;

a part of the first refrigeration gas discharged by the compressor is transmitted to the condenser through the refrigeration main path to be condensed into refrigeration liquid, and flows into the evaporator;

a part of the first refrigeration gas discharged by the compressor is mixed with the refrigeration liquid through the refrigeration branch and then is transmitted to the evaporator;

the refrigerating branch comprises a first refrigerating branch and a second refrigerating branch which are arranged in parallel; the first refrigeration branch and the second refrigeration branch simultaneously or alternately transmit the first refrigeration gas to realize the mixing of the first refrigeration gas discharged by the compressor and the refrigeration liquid;

controlling the first refrigeration branch and the second refrigeration branch to simultaneously transmit the first refrigeration gas based on the fact that the evaporator needs to be more in refrigerating liquid quantity;

and controlling the first refrigeration branch and the second refrigeration branch to alternately transmit the first refrigeration gas based on the condition that the amount of the refrigeration liquid required to flow into the evaporator is smaller.

2. The refrigeration system of claim 1, wherein the first refrigeration branch comprises a first refrigeration circuit and the second refrigeration branch comprises a second refrigeration circuit;

the compressor transmits the discharged first refrigeration gas to the evaporator through the first refrigeration pipeline and the second refrigeration pipeline respectively;

the first refrigeration branch further comprises a first branch switch assembly arranged in the first refrigeration pipeline, and the first branch switch assembly comprises a first electromagnetic valve;

the second refrigeration branch further comprises a second branch switch assembly arranged in the second refrigeration pipeline, and the second branch switch assembly comprises a second electromagnetic valve;

the first solenoid valve and the second solenoid valve are both used for controlling the flow rate of the first refrigeration gas transmitted to the inlet of the evaporator.

3. The refrigeration system of claim 1, further comprising a main circuit switch assembly disposed in series on the refrigeration main circuit;

the main circuit switch assembly comprises an electronic expansion valve, the electronic expansion valve is arranged on the refrigerating main circuit between the outlet of the condenser and the inlet of the evaporator in series, and the electronic expansion valve is used for controlling the flow of the refrigerating fluid.

4. The refrigeration system of claim 1, further comprising a temperature sensing device disposed in series on the refrigeration circuit;

the temperature detection device comprises a first temperature sensor and a second temperature sensor;

the first temperature sensor is used for detecting the temperature of the exhaust port of the compressor, and the second temperature sensor is used for detecting the temperature of the outlet of the condenser.

5. The refrigeration system of claim 1, further comprising an oil return branch and an oil separator disposed in series on the oil return branch;

the oil separator is positioned at the exhaust port of the compressor;

and an outlet of the oil separator is connected with an air inlet of the compressor based on the oil return branch, and part of oil in the oil separator is returned to the compressor based on the oil return branch.

6. The refrigeration system of claim 1, further comprising a conditioning branch;

the condenser transmits the discharged refrigerating liquid to the compressor through the regulating branch; the adjusting branch further comprises an adjusting switch assembly which is arranged on the adjusting branch in series;

the regulating switch assembly comprises a liquid spraying electromagnetic valve, and the liquid spraying electromagnetic valve is used for controlling the refrigerating liquid to flow into the compressor.

7. The refrigeration system of claim 1, further comprising a pressure sensing device disposed in series on the refrigeration circuit;

the pressure detection device comprises a first pressure sensor and a second pressure sensor;

the first pressure sensor is used for detecting the pressure at the inlet of the condenser, and the second pressure sensor is used for detecting the pressure at the air inlet of the compressor.

8. The refrigeration system of claim 1, further comprising a gas-liquid separation device disposed in series on the refrigeration main circuit;

the gas-liquid separation device is arranged at the outlet of the evaporator and the air inlet of the compressor in series, the evaporator evaporates the refrigerating liquid into second refrigerating gas, and the gas-liquid separation device is used for separating the second refrigerating gas from the refrigerating liquid.

9. The refrigeration system according to claim 1, wherein the condenser has a condensing fan by which high-temperature and high-pressure refrigerant gas discharged from the compressor, i.e., the first refrigerant gas, is condensed into the refrigerant liquid.

10. The double-layer test box is characterized by comprising a first refrigerating system and a second refrigerating system; the first refrigeration system and the second refrigeration system each comprise a refrigeration system of any of claims 1-9.

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