CN215809421U

CN215809421U - Air conditioner circulation system and air conditioner

Info

Publication number: CN215809421U
Application number: CN202122225889.1U
Authority: CN
Inventors: 黄玉优; 林海佳; 赵材波; 康建; 李蓉
Original assignee: Gree Electric Appliances Inc of Zhuhai
Current assignee: Gree Electric Appliances Inc of Zhuhai
Priority date: 2021-09-14
Filing date: 2021-09-14
Publication date: 2022-02-11
Anticipated expiration: 2031-09-14

Abstract

The utility model relates to an air conditioner circulating system and an air conditioner. The main circulation flow path comprises a compressor, a condenser, a working medium processing flow path and a gas-liquid separator which are sequentially arranged along the flowing direction of a working medium, the working medium processing flow path comprises a gating branch communicated with the gas-liquid separator, the gating branch comprises a gating port, and the gating port is provided with an adjusting valve. The parallel first heat exchanger and the parallel second heat exchanger are arranged, the working medium enters the working medium processing flow path from the compressor through the condenser to form a high-pressure high-temperature or high-pressure medium-temperature liquid working medium, the working medium processing flow path is used for processing the working medium, then gas-liquid separation is realized through the gas-liquid separator, the pressure of an air suction port of the compressor can be improved, the power consumption of the compressor is reduced, and meanwhile, the heat offset loss can be avoided.

Description

Air conditioner circulation system and air conditioner

Technical Field

The utility model relates to the field of air treatment, in particular to an air conditioner circulating system and an air conditioner.

Background

At present, in the field of machine room air conditioning, a variable frequency air conditioning system can adjust the refrigerating capacity output of a refrigerating unit according to the heat load of a data center, so that load matching is realized, and the constant temperature and humidity requirements of a data machine room are met. However, since the data center has high requirements for indoor temperature and humidity accuracy, a room air conditioner requiring cooling output throughout the year needs to frequently cope with the fluctuation of heat load and humidity load.

The problem that indoor humidity is too big or the undersize appears easily in the improper control of data center humidity, and dew water appears easily in the too big humidity, and humidity produces static easily too little, and these two kinds of circumstances can all seriously threaten the safe operation of data center equipment. In the south, cold and tide weather is very easy to occur, the indoor humidity of a data center is too high due to the fact that a data center enclosure structure or moisture invaded through doors and windows, and the dehumidification capacity of a machine room air conditioner needs to be increased, so that the evaporation temperature is too low, and the indoor air supply temperature fluctuation is too large. Particularly, under the condition of high humidity and low load of a data center, the operation of the air conditioner in the machine room has a contradiction phenomenon: the unit is matched with low-load output, and the dehumidification capacity is reduced, so that the indoor wet load cannot be reduced; increasing the dehumidification capacity meets the requirement of indoor humidity, which can exceed the requirement of heat load, resulting in too large indoor temperature drop.

For a data center, a common solution is to utilize cold air after electric heating dehumidification and reheating, so that the refrigerating output of a machine room air conditioner is not too small, thereby realizing the constant temperature requirement of the data center, but an electric heating reheating mode is a mode which wastes electric energy, and under the huge electric energy requirement of the data center, energy conservation is a very urgent problem. Therefore, how to solve the problems of constant temperature and humidity control of the machine room air conditioner of the data center under the condition of light-load dehumidification and how to reduce the problem of electric energy waste during the light-load dehumidification operation is a technical difficulty to be solved by the energy-saving high-efficiency machine room air conditioner. Aiming at the actual comfortable air conditioner for civil use and industrial use, the indoor dehumidification requirement in cold weather often appears. At present, most common dehumidification modes of comfortable air conditioners are actually low-wind-speed refrigeration operation at low evaporation temperature, and the indoor temperature is reduced along with the operation, so that the sensible temperature of a user is reduced, and the body discomfort is caused.

Therefore, no matter the existing air conditioner for temperature and humidity regulation is a machine room air conditioner or a civil or commercial air conditioner, the indoor temperature and the indoor humidity cannot be simultaneously regulated to a proper range, and light-load dehumidification cannot be realized.

In view of the above, it is desirable to improve the existing air conditioning structure to achieve light-load dehumidification of the air conditioner.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem that the air conditioning device in the prior art cannot realize light-load dehumidification, the utility model provides an air conditioning circulating system and an air conditioner.

In a first aspect, the present invention provides an air conditioning cycle system comprising:

the main circulation flow path comprises a compressor, a condenser, a working medium processing flow path and a gas-liquid separator which are sequentially arranged along the flow direction of a working medium, the working medium processing flow path comprises a gating branch communicated with the gas-liquid separator, the gating branch comprises a gate, and the gate is provided with an adjusting valve; and the number of the first and second groups,

the heat exchange flow path comprises a first heat exchanger and a second heat exchanger which are positioned in the same space, a first port of the first heat exchanger is communicated with the gas-liquid separator through the working medium processing flow path, and a second port of the first heat exchanger is communicated with the gas-liquid separator through a first expansion valve; a first port of the second heat exchanger is communicated with the regulating valve, and a second port of the second heat exchanger is communicated with the gas-liquid separator through a second expansion valve;

the regulating valve comprises a first state and a second state, a first port of the second heat exchanger is communicated with an outlet of the condenser in the first state, working medium firstly passes through the second heat exchanger and then enters the first heat exchanger, and a first port of the second heat exchanger is communicated with the gas-liquid separator through the gating branch in the second state.

In a preferred embodiment, the working medium treatment flow path comprises a first ejector, the first ejector comprises a first injection port and a first injection port, the first injection port is communicated with the outlet of the condenser, the first port of the first heat exchanger is communicated with the first injection port, and the outlet of the first ejector is communicated with the inlet of the gas-liquid separator; the gating branch comprises a second ejector, the second ejector is provided with a second injection port and a second injection port, the second injection port and the second injection port are communicated to the regulating valve, and the regulating valve is arranged on the upstream side of the second ejector.

Further, in the above embodiment, the regulating valve is placed in the first state, the regulating valve communicates the condenser and the first port of the second heat exchanger, and the second ejector is not operated; the regulating valve is arranged in a second state, and the second ejector is respectively communicated with the condenser and the first port of the second heat exchanger.

Or further, in the above embodiment, the regulating valve is a four-way valve, and the four-way valve is provided with four interfaces to respectively communicate the condenser, the second injection port, and the first port of the second heat exchanger.

In a preferred embodiment, the outlet of the second ejector is provided with a one-way valve.

In a preferred embodiment, a solenoid valve is further disposed on the connection pipe of the first injection port, when the regulating valve is controlled to be regulated to the first state, the first injection port of the first injector is closed through the solenoid valve, and the first injection port and the outlet of the first injector serve as system circulation pipelines.

In a preferred embodiment, the gas-liquid separator is provided with:

the inlet is communicated with the outlet of the working medium treatment flow path;

the liquid passing port is communicated with the first expansion valve and the second expansion valve, and a gating flow path is arranged between the second expansion valve and the first expansion valve so as to convey working media to the first heat exchanger from the second heat exchanger through the gating flow path; and the number of the first and second groups,

and the air outlet is communicated with an air suction port of the compressor.

In a preferred embodiment, the system further includes a first pressure sensor and a second pressure sensor, the first pressure sensor is located at an outlet of the working medium processing flow path, the second pressure sensor is located at a side of the second expansion valve facing the gas-liquid separator, the regulating valve is in the first state, the second expansion valve controls an opening degree according to pressure signals of the first pressure sensor and the second pressure sensor, and whether the liquid passing one-way valve passes through the working medium is determined by comparing pressure values of the first pressure sensor and the second pressure sensor: controlling the pressure of the first pressure sensor to be larger than that of the second pressure sensor, and enabling working media to pass through the liquid-passing one-way valve; or controlling the pressure of the first pressure sensor to be smaller than the pressure of the second pressure sensor, and enabling no working medium to pass through the liquid-passing one-way valve.

In a preferred embodiment, the system further comprises an internal fan to drive the flow of the air stream passing through the first heat exchanger and the second heat exchanger, the first heat exchanger being located on an upstream side of the air stream than the second heat exchanger.

In a preferred embodiment, the system further comprises an external fan and/or a water cooling piece, wherein the external fan is used for driving the airflow which passes through the condenser for heat exchange to flow; the water cooling piece is used for driving cooling water to carry out heat exchange and temperature reduction on the condenser.

In a preferred embodiment, the liquid passing port comprises a liquid passing one-way valve and a liquid passing three-way valve, the liquid passing one-way valve is connected between the gas-liquid separator and the liquid passing three-way valve to control the gas-liquid separator to pass in one way in the direction of the liquid passing three-way valve, the liquid passing three-way valve is provided with three interfaces, a second interface and a third interface are respectively communicated with the first expansion valve and the second expansion valve, and a first interface of the liquid passing three-way valve is communicated with an outlet of the liquid passing one-way valve.

In a second aspect, the utility model further provides an air conditioner and an air conditioner circulation system applying the structure.

Compared with the prior art, the technical scheme provided by the embodiment of the utility model has the following advantages: the parallel first heat exchanger and the parallel second heat exchanger are arranged, the working medium enters the working medium processing flow path from the compressor through the condenser to form a high-pressure high-temperature or high-pressure medium-temperature liquid working medium (possibly containing a small amount of gas), the working medium processing flow path is used for processing the working medium, then gas-liquid separation is realized through the gas-liquid separator, the pressure of an air suction port of the compressor can be improved, the power consumption of the compressor is reduced, and meanwhile, the heat offset loss can be avoided. On the other hand, the second heat exchanger and the working medium processing flow path are connected through the regulating valve, so that the operation state of the second heat exchanger can be switched, the second heat exchanger can operate in a reheating mode or a refrigerating mode, the second heat exchanger can be connected with the first heat exchanger in series on the working medium flow path in the reheating mode, the discharged working medium of the second heat exchanger is prevented from being directly mixed with other working media in the gas-liquid separator, and the heat offset loss is avoided.

In addition, the working medium treatment flow path generally adopts an ejector to recover the expansion work of the air conditioning system, and can improve the pressure of an air suction port of the compressor so as to reduce the power consumption of the operation of the compressor and further realize the light-load operation of the air conditioning system.

A first part of working medium (high pressure and high temperature or high pressure and medium temperature) is processed by the working medium processing flow path and the gas-liquid separator to form a low-temperature working medium, the low-temperature working medium enters the first heat exchanger, the first heat exchanger refrigerates indoor air, and when the indoor air is cooled, water vapor in the indoor air is cooled to form condensed water, so that the effects of refrigeration and dehumidification are achieved.

If the regulating valve is controlled and regulated to the first state, a second part of working medium (high pressure and high temperature or high pressure and medium temperature) directly enters the second heat exchanger, and at the moment, the second heat exchanger heats the indoor air, so that the temperature of the indoor air is increased at the moment. The dehumidified cold air is heated again, so that the temperature of the indoor air is prevented from being reduced when the indoor air is dehumidified, the temperature of the indoor air can be ensured to be in a required control range, and the constant-temperature and constant-humidity control of an indoor space is realized;

if the regulating valve is controlled and regulated to a second state, a second part of working medium (high pressure and high temperature or high pressure and medium temperature) firstly enters the gating branch and the gas-liquid separator to form a low-temperature working medium, and then enters the second evaporator through the second expansion valve, and at the moment, the functions of the second heat exchanger and the first heat exchanger are the same, so that the refrigeration effect is achieved. The indoor air plays a dual refrigeration role when passing through the first heat exchanger and the second heat exchanger, the control of cascade refrigeration can be realized, and the adjustment flexibility of the air refrigeration temperature is improved.

Drawings

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

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

Fig. 1 is a schematic structural diagram of an air conditioning cycle system according to an embodiment of the present invention;

FIG. 2 is a schematic diagram illustrating the operation of the dehumidification and reheating process according to the embodiment of the present invention;

fig. 3 is a schematic diagram illustrating the working principle of the system according to the embodiment of the present invention during the secondary cooling.

Wherein the reference numerals are:

10. a compressor; 20. a condenser; 30. a working medium treatment flow path; 301. a first ejector; 3011. a first injection port; 3012. a first injection port; 31. gating a branch circuit; 311. a second ejector; 3111. a second injection port; 3112. a second injection port; 312. a one-way valve; 313. adjusting a valve; 40. a gas-liquid separator; 41. an inlet; 42. a liquid through port; 421. a liquid-through one-way valve; 422. a liquid tee joint is communicated; 43. an air outlet; 51. a first heat exchanger; 511. a first expansion valve; 52. a second heat exchanger; 521. a second expansion valve; 61. an inner fan; 62. an outer fan; 70. an electromagnetic valve.

The dashed arrows represent the direction of the gas flow and the solid arrows represent the direction of the working medium flow.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

In order to solve the technical problem that the air conditioning device in the prior art cannot achieve light-load dehumidification, referring to fig. 1 to 3, the utility model provides an air conditioning circulation system. The air conditioner circulating system provided by the utility model is suitable for machine room air conditioners and is also suitable for civil and commercial air conditioners.

In a first aspect, referring to fig. 1, the present invention provides an air conditioning cycle system including a main cycle flow path and a heat exchange flow path. The working medium refers to a medium substance which is used by various heat engines or thermal equipment to finish the mutual conversion of heat energy and mechanical energy. Water, refrigerant, air, and the like are common. The working medium in the present invention mainly refers to a refrigerant, which is vaporized by absorbing heat of a cooling medium (water or air, etc.) in an evaporator, and condensed by transferring heat to surrounding air or water in a condenser 20.

The main circulation flow path comprises a compressor 10, a condenser 20, a working medium processing flow path 30 and a gas-liquid separator 40 which are sequentially arranged along the flow direction of a working medium, the working medium processing flow path 30 comprises a gating branch 31 communicated with the gas-liquid separator 40, the gating branch 31 comprises a gating port, and the gating port is provided with an adjusting valve 313. The heat exchange flow path includes a first heat exchanger 51 and a second heat exchanger 52 located in the same space. The first port of the first heat exchanger 51 is connected to the gas-liquid separator 40 through the working fluid processing passage 30, and the second port of the first heat exchanger 51 is connected to the gas-liquid separator 40 through the first expansion valve 511. The first port of the second heat exchanger 52 is connected to the regulator valve 313, and the second port of the second heat exchanger 52 is connected to the gas-liquid separator 40 via the second expansion valve 521.

Referring to fig. 2 and 3, the working medium discharged from the compressor 10 is discharged through the condenser 20, and a first portion of the working medium is separated into a liquid working medium by the working medium treatment flow path 30 and the gas-liquid separator 40 and enters the first heat exchanger 51 through the first expansion valve 511 to exchange heat with air. The second part of the working medium can then enter the first port of the second heat exchanger 52, or the gate branch 31, due to the different state of the regulating valve 313.

The regulator valve 313 includes a first state and a second state:

referring to fig. 2, in the first state, the first port of the second heat exchanger 52 may be connected to the outlet of the condenser 20 through the regulating valve 313. The regulating valve 313 is controlled to operate to a first state, a second part of working medium enters a first port of the second heat exchanger 52 to reheat the air, then enters the first expansion valve 511 and the first heat exchanger 51 after passing through the second expansion valve 521, the working medium firstly passes through the second heat exchanger 52 and then enters the first heat exchanger 51, then the working medium is communicated to the gas-liquid separator 40 through the working medium processing flow path 30, and the gas working medium returns to an air suction port of the compressor 10, so that working medium circulation is realized.

Referring to fig. 3, in the second state, the first port of the second heat exchanger 52 is connected to the inlet 41 of the gas-liquid separator 40 through the gate bypass 31, and at the same time. The regulating valve 313 is controlled to operate to a second state, a second part of working medium enters the gating branch 31 and then enters the gas-liquid separator 40, and then the liquid working medium enters a second port of the second heat exchanger 52 through the second expansion valve 521 and then returns to the gating branch 31 through the second heat exchanger 52 to refrigerate air, so that one working medium cycle is realized.

The first expansion valve 511 and the second expansion valve 521 automatically adjust the opening degrees as necessary: in the dehumidification and reheat operation, the amount of refrigerant flow in the second heat exchanger 52 can be controlled by adjusting the opening degree of the second expansion valve 521, thereby controlling the amount of cold air to be reheated. In the secondary cooling, different evaporating temperatures and different refrigerant flows can be realized between the first heat exchanger 51 and the second heat exchanger 52, so that the cooling capacities of the two heat exchangers are controlled. In particular, the first heat exchanger 51 and the second heat exchanger 52 may be provided as evaporators, and in practical applications, the two evaporators are two ends used in the same space, such as what is commonly referred to as a one-to-two or one-to-many household central air conditioner.

According to the technical scheme, a first heat exchanger 51 and a second heat exchanger 52 which are connected in parallel are arranged, working media enter a working medium processing flow path 30 from a compressor 10 through a condenser 20 to form high-pressure high-temperature or high-pressure medium-temperature liquid working media (possibly containing a small amount of gas):

a first part of working medium (high pressure, high temperature or high pressure and medium temperature) is processed by the working medium processing flow path 30 and the gas-liquid separator 40 to form a low-temperature working medium, the low-temperature working medium enters the first heat exchanger 51, the first heat exchanger 51 refrigerates indoor air, and when the indoor air is cooled, water vapor in the indoor air is cooled to form condensate water, so that the effects of refrigeration and dehumidification are achieved.

Referring to fig. 2, if the adjusting valve 313 is controlled to be adjusted to the first state, the second part of the working medium (high pressure and high temperature or high pressure and medium temperature) directly enters the second heat exchanger 52, and at this time, the second heat exchanger 52 heats the indoor air, and then the temperature of the indoor air is increased. The dehumidified cold air is heated again, so that the temperature of the indoor air can be prevented from being reduced along with the dehumidification, the temperature of the indoor air can be ensured to be in a required control range, and the constant-temperature and constant-humidity control of the indoor space can be realized. Because the second heat exchanger 52 for reheating cold air is directly introduced into the working medium of the condenser 20, the condensing waste heat of the condenser 20 is utilized, and no additional electric heating is needed, so that the constant-temperature dehumidification operation of the system is more energy-saving. Therefore, in the embodiment of the utility model, by controlling the state of the regulating valve 313, the first heat exchanger 51 performs refrigeration and dehumidification, and the second heat exchanger 52 performs temperature rise, so that air can successively pass through the first heat exchanger 51 and the second heat exchanger 52, large dehumidification capacity output under light load dehumidification even zero load can be realized, the problem of moderate dehumidification and insufficient dehumidification of the existing refrigeration is effectively avoided, and the problem of moderate dehumidification and excessive refrigeration is also avoided. By adjusting the heat dissipation distribution between the condenser 20 and the second heat exchanger 52, for example, controlling the rotation speed of the external fan at the condenser 20, the heat dissipation distribution between the condenser 20 and the second heat exchanger 52 of the high-temperature and high-pressure refrigerant can be controlled, and the light-load constant-temperature dehumidification function can be realized.

Referring to fig. 3, if the regulating valve 313 is controlled to be regulated to the second state, a second part of working medium (high pressure, high temperature, or high pressure, medium temperature) firstly enters the gating branch 31 and the gas-liquid separator 40 to form a low-temperature working medium, and then enters the second heat exchanger 52 through the second regulating valve 313, and at this time, the second heat exchanger 52 and the first heat exchanger 51 have the same function, and a refrigeration effect is achieved. The indoor air plays a double refrigeration role when passing through the first heat exchanger 51 and the second heat exchanger 52, and the control of cascade refrigeration can be realized, which is beneficial to improving the adjustment flexibility of the air refrigeration temperature.

Specifically, in the first state of the regulating valve 313, the working mediums of the first heat exchanger 51 and the second heat exchanger 52 flow in opposite directions; in the second state of the regulating valve 313, the working mediums of the first heat exchanger 51 and the second heat exchanger 52 flow in the same direction. The flow directions of the working media are opposite, the flow of the working media in the first heat exchanger 51 and the second heat exchanger 52 is controlled in series, the working media are fully exchanged heat, and the temperature and the pressure of the working media are easier to control.

Referring to fig. 1, in a preferred embodiment, the working medium processing flow path 30 includes a first ejector 301, the first ejector 301 includes a first injection port 3011 and a first injection port 3012, the first injection port 3011 is connected to the outlet of the condenser 20, the first port of the first heat exchanger 51 is connected to the first injection port 3012, and the outlet of the first ejector 301 is connected to the inlet 41 of the gas-liquid separator 40.

Preferably, the solenoid valve 70 is further disposed on the connection pipe of the first injection port 3011, and the solenoid valve 70 is a normally open solenoid valve with power cut, because the solenoid valve 70 needs to be opened most of the time when the system is operating, the solenoid valve 70 can be kept open without power cut, which can reduce energy consumption. After the electromagnetic valve 70 is powered on and closed, the first injection port 3011 of the first ejector 301 may be closed as needed, and the first injection port 3012 may be reserved, and the first injection port 3012 and the outlet may be used as a system circulation pipeline, and the system is formed as a direct expansion refrigeration cycle having a cold air reheating function. Referring to fig. 2, if the regulating valve 313 is controlled to be regulated to the first state, the electromagnetic valve 70 is electrically powered off to close the first injection port 3011 of the first injector 301, the first injection port 3012 and the outlet serve as a system circulation pipeline, the system forms a direct expansion refrigeration cycle with a cold air reheating function, the closing of the first injection port 3011 can maintain the working medium pressure at the first port of the second heat exchanger 52, and it can be ensured that sufficient working medium flows into the second heat exchanger 52. In an embodiment, the regulating valve 313 is controlled to be adjusted to the first state, the solenoid valve 70 can also selectively open the first injection port 3011 of the first ejector 301, and part of the working medium discharged from the condenser 20 enters the first injection port 3011 of the ejector 301 through the solenoid valve 70, so as to increase the pressure of the working medium at the inlet 41 of the gas-liquid separator 40.

In this embodiment, the working medium processing flow path 30 is provided with the first ejector 301, the gating branch 31 is provided with the second ejector 311, the first ejector 301 is communicated with the condenser 20 and the first heat exchanger 51, a first part of the working medium (high-pressure high-temperature or high-pressure medium-temperature refrigerant) enters the first injection port 3011 of the first ejector 301, then high-speed injection is realized, low-pressure working medium (refrigerant) is sucked from the first port of the first heat exchanger 51, the working medium (refrigerant) in the first ejector 301 is mixed and then subjected to speed reduction and pressure increase in the pressure expansion section, finally, a refrigerant with intermediate pressure is formed, then the refrigerant enters the gas-liquid separator 40 to realize gas-liquid separation, and the gas working medium (refrigerant) enters the air suction port of the compressor 10, so that a refrigeration main cycle is completed. Liquid working medium (refrigerant) in the gas-liquid separator 40 enters the first heat exchanger 51, low-temperature and low-pressure working medium in the first heat exchanger 51 absorbs outside air heat and evaporates into gas, and low-pressure gas working medium enters the first injection port 3012 of the first injector 301 under the low-pressure suction effect of the first injector 301, so that an injection cycle is completed.

The first ejector 301 throttles and reduces the pressure of the high-pressure working medium, pumps the low-pressure working medium to mix with the throttled working medium, and forms a refrigerant with intermediate pressure through the diffusion section, so that the pressure of an air suction port of the compressor can be increased, and the power consumption of the compressor is reduced. In the conventional refrigeration equipment, the structure of the regulating valve 313 is adopted alone, the liquid refrigerant flowing through the regulating valve 313 is easy to cause the adverse effects of refrigerant leakage in the valve, the cold quantity and the heat quantity of the liquid refrigerant are easy to offset, and the like, and in the embodiment, the first ejector 301 and the second ejector 311 can effectively prevent the leakage of the refrigerant and the offset loss of the heat quantity.

The second ejector 311 is provided with a second injection port 3111 and a second injection port 3112, the second injection port 3111 and the second injection port 3112 are both communicated with the regulating valve 313, and the regulating valve 313 is provided on the upstream side of the second ejector 311. The regulating valve 313 is used to control whether the second injector 311 is operated.

Further, in the above embodiment, the regulating valve 313 is placed in the first state, the regulating valve 313 communicates the condenser 20 with the first port of the second heat exchanger 52, and the second ejector 311 is not operated; the regulating valve 313 is placed in the second state and the second ejector 311 communicates with the condenser 20 and the first port of the second heat exchanger 52, respectively. The operating state of the regulator valve 313 is combined with the system's working fluid flow requirements and the state of the regulator valve 313 is used to determine whether the second injector 311 is operating. When the regulating valve 313 is in the second state, the second injector 311 operates on the same principle as the first injector 301, and the second heat exchanger 52 operates on the same principle as the first heat exchanger 51.

Further, in the above embodiment, the regulating valve 313 is a four-way valve having four ports for respectively communicating the condenser 20, the second injection port 3111, the second injection port 3112 and the first port of the second heat exchanger 52. The regulating valve 313 is provided as a four-way valve which can be controlled to form various passages as required, and thus can satisfy the requirements of the second ejector 311 in the present invention. Specifically, the outlet of the condenser 20 is connected to a D port of a four-way valve, a C port of the four-way valve is connected to the second injection port 3111 of the second ejector 311, an S port of the four-way valve is connected to the second injection port 3112 of the second ejector 311, and an E port of the four-way valve is connected to the first port of the second heat exchanger 52. The outlet of the second ejector 311 is communicated to the inlet 41 of the gas-liquid separator 40.

Referring to fig. 1, in a preferred embodiment, the outlet of the second injector 311 is provided with a check valve 312. The check valve 312 can effectively ensure the one-way flow of the working medium, and at the output ends of the working medium processing flow path 30 and the gating branch 31, the working medium backflow caused by the mutual influence of the two flow paths is avoided.

Referring to fig. 1, in a preferred embodiment, the gas-liquid separator 40 is provided with an inlet 41, a liquid passage 42, and an air outlet 43. The inlet 41 communicates with the outlet of the working medium treatment flow path 30. The liquid passing port 42 includes a liquid passing one-way valve 421 and a liquid passing three-way 422, the liquid passing one-way valve 421 is connected between the liquid passing port of the gas-liquid separator 40 and the liquid passing three-way 422 to control the liquid passing port to pass in one-way in the direction of the liquid passing three-way 422, the liquid passing three-way 422 has three interfaces, wherein the second interface and the third interface are respectively communicated with the first expansion valve 511 and the second expansion valve 521, the first interface of the liquid passing three-way 422 is communicated with the outlet of the liquid passing one-way valve 421, the first expansion valve 511 is communicated with the second port of the first heat exchanger 51, and the second expansion valve 521 is communicated with the second port of the second heat exchanger 52. The outlet 43 of the gas-liquid separator 40 communicates with the suction port of the compressor 10. In this regard, it can be understood that a gate flow path (a line from the liquid passing tee 422 to the first expansion valve 511) is formed between the second expansion valve 521 and the first expansion valve 511, and the gate flow path supplies the working medium from the second heat exchanger 52 to the first heat exchanger 51.

The inlet 41 is connected with outlets of the working medium processing flow path 30, namely outlets of the working medium processing flow path 30 and the gating branch 31, working mediums output by the working medium processing flow path 30 and the gating branch 31 enter the gas-liquid separator 40 through the inlet 41 to be subjected to gas-liquid separation, then the gas working medium enters an air suction port of the compressor 10 to be subjected to next main circulation, and the liquid working mediums respectively enter the first heat exchanger 51 and the second heat exchanger 52. The gas-liquid separation contributes to the improvement of the heat exchange effect of the first heat exchanger 51 and the second heat exchanger 52.

In a preferred embodiment, the system further comprises a first pressure sensor located at the outlet of working medium treatment flow path 30, and a second pressure sensor located at the side of second expansion valve 521 facing gas-liquid separator 40, and regulating valve 313 is in the first state, and second expansion valve 521 controls the opening degree according to the pressure signals of first pressure sensor and second pressure sensor. The opening degree of the second expansion valve 521, that is, the outlet pressure thereof is controlled. By comparing the pressure values of the first pressure sensor and the second pressure sensor, it can be determined whether the liquid-passing check valve 421 operates.

1) If the pressure of the first pressure sensor is greater than that of the second pressure sensor, the working medium passes through the liquid-passing one-way valve 421;

2) if the pressure of the first pressure sensor is lower than that of the second pressure sensor, no working medium passes through the liquid-passing check valve 421. In an alternative embodiment, for example, in the dehumidification and reheat mode, the opening degree of the second expansion valve 521 may be decreased so that the pressure of the first pressure sensor is greater than the pressure of the second pressure sensor, and the working medium passes through the liquid passing one-way valve 421 and enters the first heat exchanger 51, so as to decrease the temperature of the working medium entering the first heat exchanger 51, and meanwhile, the opening degree of the second expansion valve 521 is decreased to increase the temperature of the working medium in the second heat exchanger 52, so as to increase the dehumidification efficiency, and otherwise, the temperature difference between the two devices may be decreased to decrease the dehumidification efficiency. In the control process, whether working medium passes through the liquid-passing one-way valve 421 can be determined according to the difference value between the first pressure sensor and the second pressure sensor.

In a preferred embodiment, the system further comprises an internal fan 61 to drive the flow of air through the first heat exchanger 51 and the second heat exchanger 52, the first heat exchanger 51 being located on the upstream side of the fan air flow compared to the second heat exchanger 52. After being driven by the inner fan 61, the airflow passes through the first heat exchanger 51 and the second heat exchanger 52 in sequence and is discharged to the indoor side, so that the dehumidification and reheating functions can be realized.

In a preferred embodiment, the system further includes an external fan 62 for driving the flow of air through the condenser 20 for heat exchange. The condenser 20 generates a large amount of heat during operation, and the condenser 20 is cooled by air to ensure efficient operation of the condenser 20. In other preferred embodiments, the system may further include a water cooling device, such as a water pump, for driving the cooling water to cool the condenser 20. The external fan 62 and water cooling elements may also be used in combination to ensure proper operation of the condenser 20 during efficient operation.

In a second aspect, referring to fig. 2, the present invention further provides a control method of an air conditioner, which is applied to the air conditioner circulation system with the above structure, and includes:

acquiring a control signal;

if a signal for switching to the first state is acquired, the regulating valve 313 switches to the first state;

a first part of working medium flows through the first heat exchanger 51 to perform refrigeration, dehumidification and heat exchange, and a second part of working medium flows through the second heat exchanger 52 to perform reheating and heat exchange;

the air flow passes through the first heat exchanger 51 and the second heat exchanger 52 in sequence to realize dehumidification and reheating.

In a preferred embodiment, referring to fig. 3, the method further comprises:

the regulator valve 313 is operated to the second state;

a first part of working medium flows through the first heat exchanger 51 for refrigeration, and a second part of working medium flows through the second heat exchanger 52 for refrigeration;

the gas flow passes through the first heat exchanger 51 and the second heat exchanger 52 in turn to realize secondary refrigeration.

Further, in the above method, the regulating valve 313 is set as a four-way valve, the four-way valve is in the first state (powered on), the second ejector 311 does not work, and dehumidification and reheating are realized; the four-way valve is in the second state (without power), and the second ejector 311 works to realize secondary refrigeration.

According to the technical scheme, the first heat exchanger 51 performs refrigeration and dehumidification and the second heat exchanger 52 performs heating through controlling the state of the regulating valve 313, so that air can successively pass through the first heat exchanger 51 and the second heat exchanger 52, the light-load dehumidification function can be realized, the problem that the existing refrigeration is moderate but the dehumidification is insufficient is effectively avoided, and the problem that the dehumidification is moderate but the refrigeration is excessive is also avoided.

It is noted that, in this document, relational terms such as "first" and "second," and the like, may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

The foregoing are merely exemplary embodiments of the present invention, which enable those skilled in the art to understand or practice the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. An air conditioning cycle system, comprising:

the main circulation flow path comprises a compressor (10), a condenser (20), a working medium processing flow path (30) and a gas-liquid separator (40) which are sequentially arranged along the flowing direction of a working medium, the working medium processing flow path (30) comprises a gating branch path (31) communicated with the gas-liquid separator (40), the gating branch path (31) comprises a gate, and the gate is provided with an adjusting valve (313); and the number of the first and second groups,

the heat exchange flow path comprises a first heat exchanger (51) and a second heat exchanger (52) which are positioned in the same space, a first port of the first heat exchanger (51) is communicated with the gas-liquid separator (40) through the working medium treatment flow path (30), and a second port of the first heat exchanger (51) is communicated with the gas-liquid separator (40) through a first expansion valve (511); a first port of the second heat exchanger (52) is connected to the regulating valve (313), and a second port of the second heat exchanger (52) is connected to the gas-liquid separator (40) through a second expansion valve (521);

the regulating valve (313) comprises a first state and a second state, a first port of the second heat exchanger (52) is communicated with an outlet of the condenser (20) in the first state, and working medium firstly passes through the second heat exchanger (52) and then enters the first heat exchanger (51); in the second state, the first port of the second heat exchanger (52) is connected to the gas-liquid separator (40) via the gate branch (31).

2. The system according to claim 1, wherein the working medium treatment flow path (30) comprises a first ejector (301), the first ejector (301) comprises a first injection port (3011) and a first injection port (3012), the first injection port (3011) is communicated with an outlet of the condenser (20), a first port of the first heat exchanger (51) is communicated with the first injection port (3012), and an outlet of the first ejector (301) is communicated with an inlet (41) of the gas-liquid separator (40); the gating branch (31) comprises a second ejector (311), the second ejector (311) is provided with a second injection port (3111) and a second injection port (3112), the second injection port (3111) and the second injection port (3112) are communicated with the regulating valve (313), and the regulating valve (313) is arranged on the upstream side of the second ejector (311).

3. The system according to claim 2, characterized in that said regulating valve (313) is placed in a first state, said regulating valve (313) communicating said condenser (20) with a first port of said second heat exchanger (52), said second ejector (311) being inactive; the regulating valve (313) is placed in a second state, and the second ejector (311) is communicated with the condenser (20) and the first port of the second heat exchanger (52), respectively.

4. The system according to claim 2, characterized in that the regulating valve (313) is a four-way valve provided with four ports for communicating the condenser (20), the second injection port (3111), the second injection port (3112) and the first port of the second heat exchanger (52), respectively.

5. The system according to claim 2, wherein a solenoid valve (70) is further arranged on the connection pipe of the first injection port (3011), when the regulating valve (313) is controlled to regulate to the first state, the first injection port (3011) of the first ejector (301) is closed through the solenoid valve (70), the first injection port (3012) and the outlet of the first ejector (301) are used as a system circulation pipeline, or the solenoid valve (70) opens the first injection port (3011) of the first ejector (301), and part of the working medium discharged from the condenser (20) enters the first injection port (3011) of the ejector (301) through the solenoid valve (70).

6. The system according to claim 1, wherein the gas-liquid separator (40) is provided with:

the inlet (41) is communicated with the outlet of the working medium treatment flow path (30);

a liquid passing port (42), wherein the liquid passing port (42) is communicated with the first expansion valve (511) and the second expansion valve (521), a gating flow path is further arranged between the second expansion valve (521) and the first expansion valve (511), and working media are conveyed from the second heat exchanger (52) to the first heat exchanger (51) through the gating flow path;

and the air outlet (43) is communicated with an air suction port of the compressor (10).

7. The system according to claim 1, further comprising a first pressure sensor located at an outlet of the working medium processing flow path (30), and a second pressure sensor located at a side of the second expansion valve (521) facing the gas-liquid separator (40), wherein the regulating valve (313) is in the first state, the second expansion valve (521) controls an opening degree according to pressure signals of the first pressure sensor and the second pressure sensor, and the comparison between pressure values of the first pressure sensor and the second pressure sensor determines whether the liquid passing check valve (421) passes through the working medium:

controlling the pressure of the first pressure sensor to be larger than that of the second pressure sensor, so that working medium passes through the liquid-passing one-way valve (421); or,

and controlling the pressure of the first pressure sensor to be smaller than that of the second pressure sensor, so that no working medium passes through the liquid passing one-way valve (421).

8. The system of claim 1, further comprising an internal fan (61) to drive the flow of the air stream flowing through the first heat exchanger (51) and the second heat exchanger (52), the first heat exchanger (51) being located on an upstream side of the air stream than the second heat exchanger (52).

9. The system of claim 6, wherein the liquid passing port (42) comprises a liquid passing one-way valve (421) and a liquid passing three-way valve (422), the liquid passing one-way valve (421) is connected between the gas-liquid separator (40) and the liquid passing three-way valve (422) to control the gas-liquid separator (40) to flow in one direction towards the liquid passing three-way valve (422), the liquid passing three-way valve (422) has three interfaces, a second interface and a third interface are respectively communicated with the first expansion valve (511) and the second expansion valve (521), and a first interface of the liquid passing three-way valve (422) is communicated with an outlet of the liquid passing one-way valve (421).

10. An air conditioner characterized by comprising the air conditioning cycle system as set forth in any one of claims 1 to 9.