CN207094913U - A kind of air-conditioning system - Google Patents

Abstract

The utility model provides a kind of air-conditioning system, and the air-conditioning system includes：The refrigerant outlet of condenser is connected by the first pipeline with indoor evaporator, and the refrigerant outlet of indoor evaporator is connected by the second pipeline with condenser；Fluorine parallel connection of pumps is on the first pipeline, and compressor parallel is on the second pipeline；Condenser is used to give the refrigerant transfer exported to fluorine pump when outdoor temperature is less than default first temperature, when outdoor temperature is more than default second temperature by the refrigerant transfer exported to indoor evaporator, wherein the first temperature is less than second temperature；Indoor evaporator is used for the refrigerant transfer exported when outdoor temperature is less than the first temperature to condenser, when outdoor temperature is more than second temperature by the refrigerant transfer exported to compressor；Fluorine pump is used to be transferred to indoor evaporator after pressurizeing to the refrigerant received；Compressor is used to be transferred to condenser after being compressed acting to the refrigerant received.This programme can reduce refrigeration cost.

Description

an air conditioning system

technical field

The utility model relates to the technical field of electrical engineering, in particular to an air conditioning system.

Background technique

Air conditioner is the abbreviation of air conditioner (Air Conditioner), which is a device that can adjust and control the temperature, humidity, cleanliness, speed and other parameters of the ambient air in a building or structure. There are usually multiple servers deployed in the data center. In order to ensure the normal operation of each server, it is necessary to equip the data center with an air conditioner to prevent the server from going down due to excessive temperature.

Currently, air conditioning systems used in data centers usually use compressor cooling. Compressor refrigeration is to compress the high-temperature and low-pressure refrigerant vapor through the compressor, so that the refrigerant becomes high-temperature and high-pressure vapor and enters the condenser. The high-temperature and high-pressure refrigerant vapor enters the evaporator after being condensed into a low-temperature and low-pressure liquid Evaporation, the evaporation process absorbs heat to achieve the purpose of refrigeration.

Due to the high power of the compressor, the air-conditioning system used in the data center needs to run all year round. Therefore, using the existing air-conditioning system to cool the data center consumes a lot of electric energy, resulting in high cooling costs.

Utility model content

The embodiment of the utility model provides an air conditioning system, which can reduce cooling costs.

In the first aspect, the embodiment of the utility model provides an air conditioning system, including: a condenser, an indoor evaporator, a compressor and a fluorine pump;

The refrigerant outlet of the condenser is connected to the refrigerant inlet of the indoor evaporator through a first pipeline, and the refrigerant outlet of the indoor evaporator is connected to the refrigerant inlet of the condenser through a second pipeline;

The fluorine pump is connected in parallel on the first pipeline, and the compressor is connected in parallel on the second pipeline;

The condenser is used to transmit the output refrigerant to the fluorine pump when the outdoor temperature is lower than the preset first temperature; and when the outdoor temperature is higher than the preset second temperature, pass through the first pipe The circuit transmits the output refrigerant to the indoor evaporator; wherein, the first temperature is lower than the second temperature;

The indoor evaporator is configured to transmit the output refrigerant to the condenser through the second pipeline when the outdoor temperature is lower than the first temperature; and when the outdoor temperature is higher than the second temperature, delivering the output refrigerant to the compressor;

The fluorine pump is used to pressurize the received refrigerant and transmit it to the indoor evaporator;

The compressor is used to compress and perform work on the received refrigerant and transmit it to the condenser.

Optionally,

The condenser is further used to transmit the output refrigerant to the fluorine pump when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature;

The indoor evaporator is further configured to transmit the output refrigerant to the compressor when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature;

The compressor is further used to compress and perform work on the received refrigerant at a corresponding frequency according to the outdoor temperature when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, and then transmit it to the condensing device.

Optionally,

The air conditioning system further includes: a controller and at least four solenoid valves;

The first solenoid valve among the four solenoid valves is connected to the first pipeline;

The second solenoid valve among the four solenoid valves is connected in series with the fluorine pump, and both the second solenoid valve and the fluorine pump are connected in parallel with the first solenoid valve;

The third solenoid valve among the four solenoid valves is connected to the second pipeline;

The fourth solenoid valve among the four solenoid valves is connected in series with the compressor, and both the fourth solenoid valve and the compressor are connected in parallel with the third solenoid valve;

The controller is configured to close the first solenoid valve and the fourth solenoid valve and open the second solenoid valve and the third solenoid valve when the outdoor temperature is lower than the first temperature ; and when the outdoor temperature is greater than the second temperature, the first solenoid valve and the fourth solenoid valve are opened, and the second solenoid valve and the third solenoid valve are closed; and at the outdoor temperature When the first temperature is greater than or equal to the first temperature and less than or equal to the second temperature, the first electromagnetic valve and the third electromagnetic valve are closed, and the second electromagnetic valve and the fourth electromagnetic valve are opened.

Optionally,

The air conditioning system further includes: a subcooler;

The subcooler is connected to the first pipeline, wherein the input end of the subcooler is connected to the condenser, and the main output end of the subcooler is connected to the indoor evaporator and the fluorine The pump is connected, and the auxiliary output end of the subcooler is connected with the input end of the compressor;

The subcooler is used to receive the refrigerant transmitted by the condenser, and when the outdoor temperature is greater than the second temperature, use the first part of the received refrigerant to counteract the second part of the received refrigerant The refrigerant undergoes cooling treatment, and the second part of the cooled refrigerant is transferred to the indoor evaporator through the main output end, and the first part of the cooled refrigerant is transferred to the indoor evaporator through the auxiliary output end. the compressor; and when the outdoor temperature is lower than the first temperature, transmit the received refrigerant to the fluorine pump through the main output port.

Optionally,

The air conditioning system further includes: a gas-liquid separator;

The gas-liquid separator is connected in series with the compressor and in parallel with the second pipeline;

The output end of the gas-liquid separator is connected to the input end of the compressor, and the input end of the gas-liquid separator is respectively connected to the refrigerant outlet of the indoor evaporator and the auxiliary output end of the subcooler ;

The gas-liquid separator is used to receive the refrigerant transmitted by the subcooler and the indoor evaporator, separate the liquid refrigerant from the gas refrigerant, and transmit the gas refrigerant to the compressor.

Optionally,

The air conditioning system further includes: a liquid reservoir;

The liquid accumulator is connected to the first pipeline, wherein the input end of the liquid accumulator is connected with the condenser, and the output end of the liquid accumulator is respectively connected with the fluorine pump and the indoor evaporator ;

The liquid receiver is used for cooling the refrigerant output by the condenser to liquefy the gaseous refrigerant.

Optionally,

The condenser includes: a cooling water tank, a water pump, a water distributor, a fan and a heat exchange coil;

The water distributor is connected to the bottom of the cooling water tank through the water pump;

The top of the cooling water tank is provided with an air outlet, the side wall of the cooling water tank is provided with at least one air inlet, and the fan is arranged on the air outlet;

The inlet of the heat exchange coil is connected to the second pipeline, and the outlet of the heat exchange coil is connected to the first pipeline;

The water pump is used to extract cooling water from the bottom of the cooling water tank, and transfer the extracted cooling water to the water distributor;

The water distributor is used to spray the cooling water transferred by the water pump onto the heat exchange coil;

The fan is used to draw out the air inside the cooling water tank, so as to increase the speed of air circulation inside the cooling water tank.

Optionally,

The condenser further includes: a water baffle;

The water baffle is arranged between the fan and the air outlet;

The water baffle is used to block the cooling water entrained in the air flowing out from the air outlet.

In the second aspect, the embodiment of the utility model also provides a cooling method based on any air-conditioning system provided in the first aspect, including:

detecting whether the outdoor temperature is lower than the first temperature;

If so, use the fluorine pump to pressurize the refrigerant output from the condenser and then transfer it to the indoor evaporator, and transfer the refrigerant output from the indoor evaporator to the indoor evaporator through the second pipeline. the condenser;

If not, detecting whether the outdoor temperature is greater than the second temperature;

When the outdoor temperature is greater than the second temperature, use the first pipeline to transfer the refrigerant output from the condenser to the indoor evaporator, and use the compressor to refrigerate the output of the indoor evaporator The agent is compressed and delivered to the condenser after doing work.

Optionally,

After the detection of whether the outdoor temperature is greater than the second temperature, further comprising:

When the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, use the fluorine pump to pressurize the refrigerant output from the condenser and transfer it to the indoor evaporator, and use the The compressor compresses and works the refrigerant output from the indoor evaporator at a corresponding frequency according to the outdoor temperature, and then transmits it to the condenser.

In the air conditioning system and refrigeration method provided by the embodiments of the present invention, the first temperature and the second temperature higher than the first temperature are preset, and when the outdoor temperature is lower than the first temperature, the condenser transmits the refrigerant to the fluorine pump, and the fluorine pump The refrigerant is pressurized and transferred to the indoor evaporator, and the refrigerant is transferred to the condenser after absorbing heat and evaporating in the indoor evaporator; when the outdoor temperature is greater than the second temperature, the condenser transfers the refrigerant to the indoor evaporator, cooling After the refrigerant absorbs heat and evaporates in the indoor evaporator, it is transmitted to the compressor, and the compressor compresses the refrigerant and then transmits it to the condenser. It can be seen that the air conditioning system realizes cooling through the fluorine pump when the outdoor temperature is lower than the first temperature, and realizes cooling through the compressor when the outdoor temperature is higher than the second temperature. Since the power consumption of the fluorine pump is smaller than that of the compressor, the outdoor temperature Refrigeration by fluorine pump can reduce the cost of refrigeration under the premise of meeting the refrigeration requirements.

Description of drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the embodiments or the prior art. Obviously, the accompanying drawings in the following description These are some embodiments of the present utility model. Those skilled in the art can also obtain other drawings based on these drawings without any creative work.

Fig. 1 is a schematic diagram of an air-conditioning system provided by an embodiment of the present invention;

Fig. 2 is the schematic diagram of another kind of air-conditioning system provided by one embodiment of the utility model;

Fig. 3 is a schematic diagram of an air conditioning system including a subcooler provided by an embodiment of the present invention;

Fig. 4 is a schematic diagram of an air-conditioning system including a gas-liquid separator provided by an embodiment of the present invention;

Fig. 5 is a schematic diagram of an air conditioning system including a liquid accumulator provided by an embodiment of the present invention;

Fig. 6 is a schematic diagram of a condenser provided by an embodiment of the present invention;

Fig. 7 is a schematic diagram of another condenser provided by an embodiment of the present invention;

Fig. 8 is a schematic diagram of another air conditioning system provided by an embodiment of the present invention;

Fig. 9 is a flowchart of a refrigeration method provided by an embodiment of the present invention;

Fig. 10 is a flowchart of another refrigeration method provided by an embodiment of the present invention.

Detailed ways

In order to make the purpose, technical solutions and advantages of the embodiments of the utility model more clear, the technical solutions in the embodiments of the utility model will be clearly and completely described below in conjunction with the accompanying drawings in the embodiments of the utility model. Obviously, the described The embodiments are part of the embodiments of the present utility model, rather than all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative work are all It belongs to the protection scope of the utility model.

As shown in Figure 1, the embodiment of the utility model provides an air conditioning system, including: a condenser 10, an indoor evaporator 20, a compressor 30 and a fluorine pump 40;

The refrigerant outlet of the condenser 10 is connected to the refrigerant inlet of the indoor evaporator 20 through a first pipeline, and the refrigerant outlet of the indoor evaporator 20 is connected to the refrigerant of the condenser 10 through a second pipeline. The agent inlet is connected;

The fluorine pump 40 is connected in parallel on the first pipeline, and the compressor 30 is connected in parallel on the second pipeline;

The condenser 10 is used to transmit the output refrigerant to the fluorine pump 40 when the outdoor temperature is lower than a preset first temperature; A pipeline transmits the output refrigerant to the indoor evaporator 20; wherein, the first temperature is lower than the second temperature;

The indoor evaporator 20 is used to transmit the output refrigerant to the condenser 10 through the second pipeline when the outdoor temperature is lower than the first temperature; and when the outdoor temperature is higher than the second temperature , the output refrigerant is delivered to the compressor 30;

The fluorine pump 40 is used to pressurize the received refrigerant and transmit it to the indoor evaporator 20;

The compressor 30 is configured to perform compression and work on the received refrigerant and transmit it to the condenser 10 .

The embodiment of the utility model provides an air conditioning system. The first temperature and the second temperature higher than the first temperature are preset. When the outdoor temperature is lower than the first temperature, the condenser transmits the refrigerant to the fluorine pump, and the fluorine pump The refrigerant is pressurized and transferred to the indoor evaporator, and the refrigerant is transferred to the condenser after absorbing heat and evaporating in the indoor evaporator; when the outdoor temperature is greater than the second temperature, the condenser transfers the refrigerant to the indoor evaporator, and the refrigerant After the indoor evaporator absorbs heat and evaporates, it is transmitted to the compressor, and the compressor compresses the refrigerant and then transmits it to the condenser. It can be seen that the air conditioning system realizes cooling through the fluorine pump when the outdoor temperature is lower than the first temperature, and realizes cooling through the compressor when the outdoor temperature is higher than the second temperature. Since the power consumption of the fluorine pump is smaller than that of the compressor, the outdoor temperature Refrigeration by fluorine pump can reduce the cost of refrigeration under the premise of meeting the refrigeration requirements.

Optionally, as shown in Figure 1,

When the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, the condenser 10 transmits the output refrigerant to the fluorine pump 40, and the fluorine pump 40 pressurizes the received refrigerant and then transmits it to the indoor evaporator 20; After the refrigerant absorbs heat and evaporates in the indoor evaporator 20, the indoor evaporator 20 transmits the refrigerant after absorbing heat and evaporation to the compressor 30; the compressor 30 compresses the refrigerant according to the outdoor temperature and performs work on the refrigerant, and The compressed refrigerant is delivered to the condenser 10 . Wherein, the compressor 30 is an inverter compressor.

When the outdoor temperature is between the first temperature and the second temperature, the cooling effect of the indoor evaporator is not enough to ensure the cooling effect of the indoor evaporator by simply cooling by the fluorine pump, but the cooling effect of the indoor evaporator will exceed the demand by simply cooling by the compressor, resulting in energy consumption. waste. Therefore, when the outdoor temperature is between the first temperature and the second temperature, the condenser transmits the refrigerant to the fluorine pump, and the fluorine pump pressurizes the refrigerant and transmits it to the indoor evaporator, and the indoor evaporator absorbs heat and evaporates The final refrigerant is transmitted to the compressor, and the compressor compresses the refrigerant at a corresponding frequency according to the outdoor temperature, and transmits the compressed refrigerant to the condenser to realize cycle refrigeration. Since the compressor can compress the refrigerant at a corresponding frequency according to the outdoor temperature, and assist the fluorine pump for cooling with a small power consumption to meet the cooling requirements of the indoor evaporator, make full use of the low temperature outside, and relatively simply use the compressor for cooling. Electric energy consumption in the cooling process can still be reduced, thereby further reducing cooling costs.

In the embodiment of the present utility model, after the outdoor temperature is higher than the second temperature, refrigeration is performed simply by the compressor. Since the cooling effect of the fluorine pump is poor when the outdoor temperature is high, turning on the fluorine pump will not improve the cooling effect of the indoor evaporator but will waste electricity. Waste of electrical energy by the pump.

Optionally, on the basis of the air conditioning system shown in Figure 1, the air conditioning system may also include a controller and at least four solenoid valves, as shown in Figure 2,

The first solenoid valve 501 among the four solenoid valves is connected to the first pipeline;

The second solenoid valve 502 in the four solenoid valves is connected in series with the fluorine pump 40, and both the second solenoid valve 502 and the fluorine pump 40 are connected in parallel with the first solenoid valve 501;

The third solenoid valve 503 among the four solenoid valves is connected to the second pipeline;

The fourth solenoid valve 504 in the four solenoid valves is connected in series with the compressor 30, and both the fourth solenoid valve 504 and the compressor 30 are connected in parallel with the third solenoid valve 503;

The controller is used to close the first solenoid valve 501 and the fourth solenoid valve 504 and open the second solenoid valve 502 and the third solenoid valve 503 when the outdoor temperature is lower than the first temperature; when the outdoor temperature is higher than the second temperature , open the first electromagnetic valve 501 and the fourth electromagnetic valve 504, and close the second electromagnetic valve 502 and the third electromagnetic valve 503; and when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, the second The first solenoid valve 501 and the third solenoid valve 503 are closed, and the second solenoid valve 502 and the fourth solenoid valve 504 are opened.

The controller can control the opening and closing of 4 solenoid valves according to the outdoor temperature. According to the switch combination of the 4 solenoid valves, the air conditioning system has the following 3 working modes:

Mode 1: When the outdoor temperature is lower than the first greenhouse, the first solenoid valve 501 and the fourth solenoid valve 504 are closed, and the second solenoid valve 502 and the third solenoid valve 503 are opened. At this time, the condenser 10 transmits the refrigerant to the fluorine pump 40 through the second electromagnetic valve 502, and the fluorine pump 40 transmits the refrigerant to the indoor evaporator 20, and the indoor evaporator 20 transmits the refrigerant to the indoor evaporator through the third electromagnetic valve 503. Condenser 10 realizes circulating refrigeration through fluorine pump 40;

Mode 2: When the outdoor temperature is greater than the second temperature, the first solenoid valve 401 and the fourth solenoid valve 504 are turned on, and the second solenoid valve 502 and the third solenoid valve 503 are turned off. At this time, the condenser 10 transmits the refrigerant to the indoor evaporator 20 through the first electromagnetic valve 501, and the indoor evaporator 20 transmits the refrigerant to the compressor 30 through the fourth electromagnetic valve 504, and the compressor 30 transmits the refrigerant to the condenser. The device 10 realizes circulating refrigeration through the compressor 30;

Mode 3: When the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, the first solenoid valve 501 and the third solenoid valve 503 are closed, and the second solenoid valve 502 and the fourth solenoid valve 504 are opened. At this time, the condenser 10 transmits the refrigerant to the fluorine pump 40 through the second electromagnetic valve 502, and the fluorine pump 40 transmits the refrigerant to the indoor evaporator 20, and the indoor evaporator 20 transmits the refrigerant to the compressor through the fourth electromagnetic valve 504. The compressor 30 transmits the refrigerant to the condenser 10, so that the compressor 30 assists the fluorine pump 40 to perform circulating refrigeration.

The controller detects the outdoor temperature, and controls the opening and closing of each solenoid valve according to the outdoor temperature, so that the air conditioning system can automatically switch between different modes for cooling at different outdoor temperatures. On the one hand, there is no need to manually switch the cooling mode of the air-conditioning system, which improves the user experience; on the other hand, the controller controls the opening and closing of the solenoid valve to ensure that the air-conditioning system can accurately switch the corresponding mode according to the outdoor temperature. Reduce cooling costs under the premise.

Optionally, on the basis of the air conditioning system shown in Figure 1, the air conditioning system may also include a subcooler, as shown in Figure 3,

The supercooler 60 is connected on the first pipeline, wherein the input end of the supercooler 60 is connected with the condenser 10, the main output end of the supercooler 60 is connected with the indoor evaporator 20 and the fluorine pump 40, and the The auxiliary output end is connected with the input end of the compressor 30;

If the outdoor temperature is greater than the second temperature, after receiving the refrigerant output from the condenser 10, the supercooler 60 uses the first part of the refrigerant in the received refrigerant to cool the second part of the refrigerant in the received refrigerant, The second part of the cooled refrigerant is sent to the indoor evaporator 20 through the main output end, and the first part of the cooled refrigerant is sent to the compressor 30 through the auxiliary output end;

If the outdoor temperature is lower than the first temperature, after receiving the refrigerant output from the condenser 10 , the supercooler 60 directly transmits all the refrigerant received to the fluorine pump 40 through the main output port.

When the air conditioning system is connected with long pipes, the liquid coolant output from the condenser needs to go through a long pipeline to reach the indoor evaporator. The liquid coolant will cause pressure loss when it is transmitted in the pipeline. When the pressure loss reaches a certain value In the end, the liquid coolant will vaporize in the pipeline, resulting in a decrease in cooling effect. A subcooler is connected between the condenser and the indoor evaporator. The subcooler consumes part of the liquid coolant to cool the rest of the liquid coolant, increasing the subcooling degree of the cooled liquid coolant, and the subcooling of the liquid coolant The increase of temperature can prevent the liquid coolant from vaporizing in advance, so that the liquid coolant can be vaporized after reaching the indoor evaporator, so as to ensure the cooling effect of the air conditioning system.

Optionally, on the basis of the air conditioning system shown in Figure 3, the air conditioning system can also include a gas-liquid separator, as shown in Figure 4,

The gas-liquid separator 70 is connected in series with the compressor 30 and connected in parallel with the second pipeline;

The output end of the gas-liquid separator 70 is connected to the input end of the compressor 30, and the input end of the gas-liquid separator 70 is respectively connected to the refrigerant outlet of the indoor evaporator 20 and the sub-output end of the subcooler 60;

The gas-liquid separator 70 is used to receive the refrigerant transmitted by the subcooler 60 and the indoor evaporator 20 , separate the liquid refrigerant from the gas refrigerant, and transmit the gas refrigerant to the compressor 30 .

Since the liquid refrigerant cannot be completely vaporized in the indoor evaporator and subcooler to form a gaseous refrigerant, in order to prevent the liquid refrigerant from entering the compressor and causing liquid shock to damage the compressor, a gas-liquid separator is installed at the air inlet of the compressor. Separate the gaseous refrigerant from the liquid refrigerant, and only let the gaseous refrigerant enter the compressor to protect the compressor.

Optionally, on the basis of the air-conditioning system shown in Figure 1, the air-conditioning system may also include a liquid reservoir, as shown in Figure 5,

The liquid accumulator 80 is connected to the first pipeline, the input end of the liquid accumulator 80 is connected with the condenser 10, and the output end of the liquid accumulator 80 is respectively connected with the fluorine pump 40 and the indoor evaporator 20;

The accumulator 80 is used to cool the refrigerant output from the condenser 10 to liquefy the gaseous refrigerant.

Liquid refrigerant is stored in the liquid receiver. After the refrigerant output from the condenser enters the liquid receiver, on the one hand, it can liquefy part of the gaseous refrigerant carried in the liquid refrigerant to improve the cooling effect; on the other hand, it can evaporate into the room. The evaporator continuously supplies refrigerant to ensure the continuity of indoor evaporator cooling.

Optionally, as shown in FIG. 6, the condenser includes: a cooling water tank 101, a water pump 102, a water distributor 103, a fan 104 and a heat exchange coil 105;

The water distributor 103 is connected to the bottom of the cooling water tank 101 through the water pump 102;

The top of the cooling water tank 101 is provided with an air outlet, the side wall of the cooling water tank 101 is provided with at least one air inlet 106, and the fan 104 is arranged on the air outlet;

The inlet 1051 of the heat exchange coil 105 is connected to the second pipeline, and the outlet 1052 of the heat exchange coil 105 is connected to the first pipeline;

The water pump 102 extracts cooling water from the bottom of the cooling water tank 101, and transfers the extracted cooling water to the water distributor 103, and the water distributor 103 sprays the cooling water transferred by the water pump 102 onto the heat exchange coil 105;

The fan 104 is used to extract the air inside the cooling water tank 101 to speed up the air circulation inside the cooling water tank 101 .

The refrigerant entering the heat exchange coil has a high temperature. After the water distributor sprays the cooling water on the heat exchange coil, the cooling water absorbs heat and evaporates to reduce the temperature of the heat exchange coil, thereby cooling the refrigerant. the goal of. The fan draws air from the air outlet of the cooling water tank, the air with a lower temperature outside the cooling water tank enters from the air inlet, and the air with a higher temperature inside the cooling water tank flows out from the air outlet. cooling effect. Therefore, through the evaporative cooling of the cooling water and the forced convection of the fan, the heat exchange efficiency of the condenser is improved, which is more energy-saving than the air-cooled method.

Optionally, on the basis of the condenser shown in Figure 6, the condenser may also include a water baffle, as shown in Figure 7,

The water baffle 107 is arranged between the air outlets on the cooling water tank 101;

The water baffle 107 is used to block the cooling water entrained in the air flowing out from the air outlet.

When the fan draws air from the cooling water tank, the air flowing out from the air outlet on the cooling water tank carries cooling water. In order to prevent the cooling water from being drawn out by the fan, a water baffle is set between the fan and the air outlet of the cooling water tank. The plate can block the cooling water flowing out from the air outlet, so that the cooling water falls to the bottom of the cooling water tank.

As shown in Figure 8, another embodiment of the present invention provides an air conditioning system, wherein,

The refrigerant outlet of the condenser 10 is connected to the input end of the accumulator 80, the output end of the liquid accumulator 80 is connected to the input end of the subcooler 60, and the main output end of the subcooler 60 is connected to one end of the liquid pipe stop valve 120 The other end of the liquid pipe cut-off valve 120 is connected to the refrigerant inlet of the indoor evaporator 20 through the check valve 1101, the first solenoid valve 501 and the electronic expansion valve 100; the input end of the second solenoid valve 502 is connected to the liquid pipe cut-off Between the valve 120 and the one-way valve 1101, the output end of the second electromagnetic valve 502 is connected to the input end of the fluorine pump 40, and the output end of the fluorine pump 404 is connected between the first electromagnetic valve 501 and the electronic expansion valve 100;

The refrigerant outlet of the indoor evaporator 20 is connected to the refrigerant inlet of the condenser 10 through the air pipe stop valve 130, the third electromagnetic valve 503 and the one-way valve 1103; the input end of the fourth electromagnetic valve 504 is connected to the air pipe stop valve 130 and the first Between the three electromagnetic valves 503, the output end of the fourth electromagnetic valve 504 is connected to the input end of the gas-liquid separator 70, the output end of the gas-liquid separator 70 is connected to the input end of the compressor 30, and the output end of the compressor 30 is passed through The one-way valve 1102 and the oil separator 90 are connected between the one-way valve 1103 and the condenser 10 .

It should be noted that the above-mentioned components are all connected through pipelines for transporting refrigerant.

As shown in Figure 9, an embodiment of the present invention provides a method for cooling using the air-conditioning system provided by any of the above-mentioned embodiments, the method may include:

Step 901: Detect whether the outdoor temperature is lower than the first temperature, if yes, execute step 902, otherwise execute step 903;

Step 902: Use the fluorine pump to pressurize the refrigerant output from the condenser and then transfer it to the indoor evaporator, transfer the refrigerant output from the indoor evaporator to the condenser through the second pipeline, and end the current process;

Step 903: Detect whether the outdoor temperature is greater than the second temperature, if yes, perform step 904, otherwise end the current process;

Step 904: Use the first pipeline to transmit the refrigerant output from the condenser to the indoor evaporator, and compress the refrigerant output from the indoor evaporator through the compressor to perform work and then transmit it to the condenser.

The embodiment of the utility model provides a refrigeration method. When the outdoor temperature is lower than the first temperature, the refrigeration is realized by the fluorine pump, and when the outdoor temperature is higher than the second temperature, the refrigeration is realized by the compressor. Since the power consumption of the fluorine pump is smaller than that of the compressor , so when the outdoor temperature is low, refrigeration through the fluorine pump can reduce refrigeration costs while meeting refrigeration requirements.

Optionally, after it is judged in step 903 that the outdoor temperature is not higher than the second temperature, use the fluorine pump to pressurize the refrigerant output from the condenser and transmit it to the indoor evaporator, and use the compressor to cool the refrigerant at a corresponding frequency according to the outdoor temperature. The refrigerant output from the indoor evaporator undergoes compression and work and then is transmitted to the condenser.

When the outdoor temperature is between the first temperature and the second temperature, the condenser transmits the refrigerant to the fluorine pump, which pressurizes the refrigerant and transmits it to the indoor evaporator, and the indoor evaporator evaporates the refrigerant after absorbing heat The refrigerant is transmitted to the compressor, and the compressor compresses the refrigerant at a corresponding frequency according to the outdoor temperature, and transmits the compressed refrigerant to the condenser to realize cycle refrigeration. Since the compressor can compress the refrigerant at a corresponding frequency according to the outdoor temperature, and assist the fluorine pump for cooling with a small power consumption to meet the cooling requirements of the indoor evaporator, make full use of the low temperature outside, and relatively simply use the compressor for cooling. Electric energy consumption in the cooling process can still be reduced, thereby further reducing cooling costs.

The refrigeration method provided by the embodiment of the present invention will be further described in detail in conjunction with the air-conditioning system shown in FIG. 8. As shown in FIG. 10, the method may include the following steps:

Step 1001: use the controller to detect in real time whether the outdoor temperature is lower than the first temperature, if yes, execute step 1002, otherwise execute step 1003;

In an embodiment of the present invention, the first temperature and the second temperature are preset, wherein the first temperature is lower than the second temperature. The controller detects whether the outdoor temperature is lower than the first temperature, if yes, it means that the outdoor temperature is low, and the cooling of the air conditioning system can be realized by the fluorine pump, and step 1002 is executed accordingly.

For example, the first temperature is preset to be 10°C, and the second temperature is set to be 20°C. When the controller detects that the outdoor temperature is less than 10° C., step 1002 is executed accordingly; otherwise, step 1003 is executed.

Step 1002: the controller closes the first solenoid valve and the fourth solenoid valve, opens the second solenoid valve and the third solenoid valve, cools through the fluorine pump, and ends the current process.

In one embodiment of the present invention, as shown in Figure 8, when the controller detects that the outdoor temperature is lower than the first temperature, the controller closes the first solenoid valve 501 and the fourth solenoid valve 504, and closes the second solenoid valve 502 and the third solenoid valve 503 is opened. At this time, after the condenser 10 transmits the liquid refrigerant to the subcooler 60 through the liquid receiver 80, the subcooler 60 transmits all the received liquid refrigerant to the fluorine through the liquid pipe stop valve 120 and the second solenoid valve 502. pump 40; the fluorine pump 40 pressurizes the received liquid refrigerant, and transmits the pressurized liquid refrigerant to the indoor evaporator 20 through the electronic expansion valve 100, and the liquid refrigerant absorbs and vaporizes in the indoor evaporator 20, To achieve the purpose of cooling the room; the indoor evaporator 20 transmits the vaporized refrigerant to the condenser 10 through the air pipe stop valve 130, the third solenoid valve 503 and the one-way valve 1103, and the gaseous refrigerant is cooled by the condenser 10 to form Liquid refrigerant, realize cycle refrigeration.

For example, when the outdoor temperature is lower than 10°C in winter, the compressor stops working, and the air conditioning system realizes cooling through the fluorine pump.

Step 1003: use the controller to detect whether the outdoor temperature is greater than the second temperature, if yes, execute step 1004, otherwise execute step 1005;

In one embodiment of the present invention, after the controller detects that the outdoor temperature is not less than the first temperature, the controller further detects whether the outdoor temperature is greater than the second temperature, if yes, it indicates that the outdoor temperature is high, and the air conditioning needs to be realized through the compressor Cooling of the system, correspondingly execute step 1004, otherwise, it means that the outdoor temperature is between the first temperature and the second temperature, correspondingly execute step 1005.

For example, when the controller detects that the outdoor temperature is greater than 20°C, step 1004 is performed accordingly; when the outdoor temperature is greater than or equal to 10°C and less than or equal to 20°C, step 1005 is correspondingly performed.

Step 1004: the controller opens the first solenoid valve and the fourth solenoid valve, closes the second solenoid valve and the third solenoid valve, uses the compressor for refrigeration, and ends the current process.

In one embodiment of the present invention, when the controller detects that the outdoor temperature is greater than the second temperature, as shown in FIG. and the third solenoid valve 503 is closed. At this time, the condenser 10 transmits the liquid refrigerant to the subcooler 60 through the liquid receiver 80, and after the subcooler 60 uses the first part of the refrigerant to cool the second part of the refrigerant, the subcooler 60 passes through the auxiliary output port The first part of refrigerant that has been vaporized is delivered to the gas-liquid separator 70, and after the subcooler 60 outputs the cooled second part of refrigerant through the main output port, the second part of refrigerant passes through the liquid pipe shut-off valve 120, single The directional valve 1101, the first electromagnetic valve 501 and the electronic expansion valve 100 reach the indoor evaporator 20, and the second part of the refrigerant absorbs heat and vaporizes in the indoor evaporator 20 to achieve the purpose of cooling the room; the indoor evaporator 20 passes through the air pipe stop valve 130. The fourth solenoid valve 504 transmits the vaporized second part of refrigerant to the gas-liquid separator 70; the gas-liquid separator 70 separates the refrigerant from the indoor evaporator 20 and the subcooler 60 into gas-liquid, and separates The output gaseous refrigerant is transmitted to the compressor 30; the compressor 30 compresses the received gaseous refrigerant to form a high-temperature and high-pressure gaseous refrigerant, and transmits the high-temperature and high-pressure gaseous refrigerant to the condenser 10 through the oil separator 90, The high-temperature and high-pressure gaseous refrigerant is cooled by the condenser 10 to form a low-temperature and high-pressure liquid refrigerant to realize cycle refrigeration.

For example, when the outdoor temperature is higher than 20°C in summer, the fluorine pump stops working, and the air conditioning system realizes cooling through the compressor.

Step 1005: the controller closes the first solenoid valve and the third solenoid valve, opens the second solenoid valve and the fourth solenoid valve, and the compressor assists the fluorine pump to perform refrigeration.

In one embodiment of the present invention, when the controller detects that the room temperature is between the first temperature and the second temperature, as shown in FIG. 8, the controller closes the first solenoid valve 501 and the third solenoid valve 503, The second solenoid valve 502 and the fourth solenoid valve 504 are turned on. At this time, the condenser 10 transmits the liquid refrigerant to the subcooler 60 through the liquid receiver 80, and after the subcooler 60 uses the first part of the refrigerant to cool the second part of the refrigerant, the subcooler 60 passes through the auxiliary output port The first part of refrigerant that has been vaporized is delivered to the gas-liquid separator 70, and after the subcooler 60 outputs the cooled second part of refrigerant through the main output port, the second part of refrigerant passes through the liquid pipe shut-off valve 120, the first The second electromagnetic valve 502 reaches the fluorine pump 40; after the fluorine pump 40 pressurizes the received liquid refrigerant, the pressurized liquid refrigerant is transmitted to the indoor evaporator 20 through the electronic expansion valve 100, and the liquid refrigerant evaporates indoors The heat is absorbed and vaporized in the device 20 to achieve the purpose of cooling the room; the indoor evaporator 20 transmits the vaporized refrigerant to the gas-liquid separator 70 through the air pipe stop valve 130 and the fourth electromagnetic valve 504; The refrigerant in the indoor evaporator 20 and the subcooler 60 undergoes gas-liquid separation, and transmits the separated gaseous refrigerant to the compressor 30; the compressor 30 compresses the received gaseous refrigerant with a corresponding frequency according to the outdoor temperature. A high-temperature and high-pressure gaseous refrigerant is formed, and the high-temperature and high-pressure gaseous refrigerant is transmitted to the condenser 10 through the oil separator 90, and the high-temperature and high-pressure gaseous refrigerant is cooled by the condenser 10 to form a low-temperature and high-pressure liquid refrigerant to realize cycle refrigeration .

For example, in the transition season (spring and autumn), when the outdoor temperature is between 10 and 20°C, the compressor uses the corresponding frequency to compress the gaseous refrigerant according to the outdoor temperature, and assists the fluorine pump to perform refrigeration.

To sum up, the air conditioning system and refrigeration method provided by the embodiments of the present utility model have at least the following beneficial effects:

1. In the embodiment of the present utility model, the first temperature and the second temperature greater than the first temperature are preset, and when the outdoor temperature is lower than the first temperature, the condenser transmits the refrigerant to the fluorine pump, and the fluorine pump controls the refrigerant After pressurized, the refrigerant is transferred to the indoor evaporator, and the refrigerant is transferred to the condenser after absorbing heat and evaporating in the indoor evaporator; when the outdoor temperature is greater than the second temperature, the condenser transfers the refrigerant to the indoor evaporator, and the refrigerant in the indoor After the evaporator absorbs heat and evaporates, it is transmitted to the compressor, and the compressor compresses the refrigerant and then transmits it to the condenser. It can be seen that the air conditioning system realizes cooling through the fluorine pump when the outdoor temperature is lower than the first temperature, and realizes cooling through the compressor when the outdoor temperature is higher than the second temperature. Since the power consumption of the fluorine pump is smaller than that of the compressor, the outdoor temperature Refrigeration by fluorine pump can reduce the cost of refrigeration under the premise of meeting the refrigeration requirements.

2. In the embodiment of the utility model, when the outdoor temperature is between the first temperature and the second temperature, the condenser transmits the refrigerant to the fluorine pump, and the fluorine pump pressurizes the refrigerant and then transmits it to the indoor evaporator , the indoor evaporator transmits the heat-absorbed and evaporated refrigerant to the compressor, and the compressor compresses the refrigerant at a corresponding frequency according to the outdoor temperature, and transmits the compressed refrigerant to the condenser to realize cycle refrigeration. Since the compressor can compress the refrigerant at a corresponding frequency according to the outdoor temperature, and assist the fluorine pump for cooling with a small power consumption to meet the cooling requirements of the indoor evaporator, make full use of the low temperature outside, and relatively simply use the compressor for cooling. Electric energy consumption in the cooling process can still be reduced, thereby further reducing cooling costs.

3. In the embodiment of the utility model, the controller detects the outdoor temperature, and controls the opening and closing of each solenoid valve according to the outdoor temperature, so that the air conditioning system can automatically switch between different modes for cooling at different outdoor temperatures. On the one hand, there is no need to manually switch the cooling mode of the air-conditioning system, which improves the user experience; on the other hand, the controller controls the opening and closing of the solenoid valve to ensure that the air-conditioning system can accurately switch the corresponding mode according to the outdoor temperature. Reduce cooling costs under the premise.

4. In the embodiment of the utility model, a supercooler is connected between the condenser and the indoor evaporator, and the supercooler consumes a part of the liquid coolant to cool the remaining part of the liquid coolant, increasing the supercooler of the cooled liquid coolant. The increase of the subcooling degree of the liquid coolant can prevent the liquid coolant from vaporizing in advance, so that the liquid coolant can be vaporized after reaching the indoor evaporator, so as to ensure the cooling effect of the air conditioning system.

5. In the embodiment of the utility model, the condenser includes components such as a cooling water tank, a water pump, a water distributor, a fan, a water baffle, and a heat exchange coil, and cools the refrigerant through evaporative cooling and forced convection to improve The heat exchange efficiency of the condenser is improved, and it is more energy-saving than the air-cooled method.

It should be noted that in this article, relational terms such as first and second are only used to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply that there is a relationship between these entities or operations. There is no such actual relationship or sequence. Furthermore, the term "comprises", "comprises" or any other variation thereof is intended to cover a non-exclusive inclusion such that a process, method, article, or apparatus comprising a set of elements includes not only those elements, but also includes elements not expressly listed. other elements of or also include elements inherent in such a process, method, article, or device. Without further limitations, an element defined by the phrase "comprising a "..." does not exclude the presence of additional same elements in the process, method, article or apparatus comprising said element.

Those of ordinary skill in the art can understand that all or part of the steps to realize the above method embodiments can be completed by program instructions related hardware, and the aforementioned programs can be stored in a computer-readable storage medium. When the program is executed, the It includes the steps of the above method embodiments; and the aforementioned storage medium includes: ROM, RAM, magnetic disk or optical disk and other various media that can store program codes.

Finally, it should be noted that the above descriptions are only preferred embodiments of the utility model, and are only used to illustrate the technical solution of the utility model, and are not used to limit the protection scope of the utility model. All modifications, equivalent replacements, improvements, etc. made within the spirit and principles of the present utility model are included in the protection scope of the present utility model.

Claims (8)

1. A kind of air-conditioning system, is characterized in that, comprises: condenser, indoor evaporator, compressor and fluorine pump; The refrigerant outlet of the condenser is connected to the refrigerant inlet of the indoor evaporator through a first pipeline, and the refrigerant outlet of the indoor evaporator is connected to the refrigerant inlet of the condenser through a second pipeline; The fluorine pump is connected in parallel on the first pipeline, and the compressor is connected in parallel on the second pipeline; The condenser is used to transmit the output refrigerant to the fluorine pump when the outdoor temperature is lower than the preset first temperature; and when the outdoor temperature is higher than the preset second temperature, pass through the first pipe The circuit transmits the output refrigerant to the indoor evaporator; wherein, the first temperature is lower than the second temperature; The indoor evaporator is configured to transmit the output refrigerant to the condenser through the second pipeline when the outdoor temperature is lower than the first temperature; and when the outdoor temperature is higher than the second temperature, delivering the output refrigerant to the compressor; The fluorine pump is used to pressurize the received refrigerant and transmit it to the indoor evaporator; The compressor is used to compress and perform work on the received refrigerant and transmit it to the condenser. 2. The air conditioning system according to claim 1, characterized in that, The condenser is further used to transmit the output refrigerant to the fluorine pump when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature; The indoor evaporator is further configured to transmit the output refrigerant to the compressor when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature; The compressor is further used to compress and perform work on the received refrigerant at a corresponding frequency according to the outdoor temperature when the outdoor temperature is greater than or equal to the first temperature and less than or equal to the second temperature, and then transmit it to the condensing device. 3. The air conditioning system according to claim 2, further comprising: a controller and at least four solenoid valves; The first solenoid valve among the four solenoid valves is connected to the first pipeline; The second solenoid valve among the four solenoid valves is connected in series with the fluorine pump, and both the second solenoid valve and the fluorine pump are connected in parallel with the first solenoid valve; The third solenoid valve among the four solenoid valves is connected to the second pipeline; The fourth solenoid valve among the four solenoid valves is connected in series with the compressor, and both the fourth solenoid valve and the compressor are connected in parallel with the third solenoid valve; The controller is configured to close the first solenoid valve and the fourth solenoid valve and open the second solenoid valve and the third solenoid valve when the outdoor temperature is lower than the first temperature ; and when the outdoor temperature is greater than the second temperature, the first solenoid valve and the fourth solenoid valve are opened, and the second solenoid valve and the third solenoid valve are closed; and at the outdoor temperature When the first temperature is greater than or equal to the first temperature and less than or equal to the second temperature, the first electromagnetic valve and the third electromagnetic valve are closed, and the second electromagnetic valve and the fourth electromagnetic valve are opened. 4. The air conditioning system according to claim 1, further comprising: a subcooler; The subcooler is connected to the first pipeline, wherein the input end of the subcooler is connected to the condenser, and the main output end of the subcooler is connected to the indoor evaporator and the fluorine The pump is connected, and the auxiliary output end of the subcooler is connected with the input end of the compressor; The subcooler is used to receive the refrigerant transmitted by the condenser, and when the outdoor temperature is greater than the second temperature, use the first part of the received refrigerant to counteract the second part of the received refrigerant The refrigerant undergoes cooling treatment, and the second part of the cooled refrigerant is transferred to the indoor evaporator through the main output end, and the first part of the cooled refrigerant is transferred to the indoor evaporator through the auxiliary output end. the compressor; and when the outdoor temperature is lower than the first temperature, transmit the received refrigerant to the fluorine pump through the main output port. 5. The air conditioning system according to claim 4, further comprising: a gas-liquid separator; The gas-liquid separator is connected in series with the compressor and in parallel with the second pipeline; The output end of the gas-liquid separator is connected to the input end of the compressor, and the input end of the gas-liquid separator is respectively connected to the refrigerant outlet of the indoor evaporator and the auxiliary output end of the subcooler ; The gas-liquid separator is used to receive the refrigerant transmitted by the subcooler and the indoor evaporator, separate the liquid refrigerant from the gas refrigerant, and transmit the gas refrigerant to the compressor. 6. The air conditioning system according to claim 1, further comprising: an accumulator; The liquid accumulator is connected to the first pipeline, wherein the input end of the liquid accumulator is connected with the condenser, and the output end of the liquid accumulator is respectively connected with the fluorine pump and the indoor evaporator ; The liquid receiver is used for cooling the refrigerant output by the condenser to liquefy the gaseous refrigerant. 7. The air conditioning system according to claim 1, wherein the condenser comprises: a cooling water tank, a water pump, a water distributor, a fan, and a heat exchange coil; The water distributor is connected to the bottom of the cooling water tank through the water pump; The top of the cooling water tank is provided with an air outlet, the side wall of the cooling water tank is provided with at least one air inlet, and the fan is arranged on the air outlet; The inlet of the heat exchange coil is connected to the second pipeline, and the outlet of the heat exchange coil is connected to the first pipeline; The water pump is used to extract cooling water from the bottom of the cooling water tank, and transfer the extracted cooling water to the water distributor; The water distributor is used to spray the cooling water transferred by the water pump onto the heat exchange coil; The fan is used to draw out the air inside the cooling water tank, so as to increase the speed of air circulation inside the cooling water tank. 8. The air conditioning system according to claim 7, wherein the condenser further comprises: a water baffle; The water baffle is arranged between the fan and the air outlet; The water baffle is used to block the cooling water entrained in the air flowing out from the air outlet.