ES2717515T3 - Air conditioning system and method to control an air conditioning system - Google Patents

Description

DESCRIPTION

Air conditioning system and method to control an air conditioning system

TECHNICAL FIELD OF THE INVENTION

The disclosure relates to the field of air conditioners, and in particular, to an air conditioning system and to a method for controlling an air conditioning system.

BACKGROUND OF THE INVENTION

As shown in Figure 1, an existing air conditioning system includes a condenser 10, an evaporator 20, a variable capacity and variable frequency compressor 30, a throttling device 40, a four way valve 60, a valve of solenoid 70 and a unidirectional valve 50, in which the variable capacity and variable frequency compressor 30 is switched by means of the movements of the unidirectional valve 50 and the solenoid valve 70. When the solenoid valve 70 is opened, a high-pressure coolant on an exhaust side flows into a suction port of a lower cylinder of the compressor, so that the high pressure is formed at one end of the lower cylinder suction, and the variable capacity and variable frequency compressor 30 can operate with a single cylinder. When the solenoid valve 70 is closed, a low-pressure refrigerant from a gas-liquid separator flows into the suction orifice of the lower cylinder, and the variable-capacity and variable-frequency compressor is switched to operate with two cylinders.

The prior art has the following disadvantages.

(1) When a single-cylinder operation is switched to two-cylinder operation or multi-cylinder operation, the solenoid valve is closed. However, since a connecting tube from the suction port of the lower cylinder to the solenoid valve is still in a high pressure state and the unidirectional valve is in a closed state due to the existence of a pressure difference, The low-pressure refrigerant of the gas-liquid separator can not flow to a lower cylinder, thus easily causing instability of the system during switching from single-cylinder operation to two-cylinder operation.

(2) During the operation of a single cylinder, the connecting tube of the lower cylinder of the compressor to the solenoid valve is on a high pressure side. However, since the refrigerant is under a steady state, the temperature of the refrigerant drops together with the exchange of heat at an outdoor ambient temperature, and the refrigerant readily condenses in a liquid state when the temperature drop is very long. weather. At this time, if the operation of a single cylinder is switched to the operation of two cylinders, the refrigerant in liquid state will flow to the lower cylinder, so that a liquid impact is activated in the lower cylinder, and therefore, the compressor will it hurts

(3) In order to solve the problem in (1), if a capillary tube is additionally provided in the connection tube of the suction port of the lower cylinder and the solenoid valve and connected to an inlet of the gas separator- liquid, when the operation of a single cylinder is switched to the operation of two cylinders, the high-pressure refrigerant in the suction hole of the lower cylinder is decompressed at the inlet of the gas-liquid separator through the capillary tube, the refrigerant of Low pressure is formed in the suction hole of the lower cylinder, and commutation is easily achieved. However, since the capillary tube flows for a long time, the circulation of refrigerants will be reduced accordingly to cause a loss of heat.

It should be noted that European Patent Publication EP 1655 492 A1 discloses a rotary type closed compressor and a refrigeration cycle apparatus in which a fin of a first cylinder is compressed and pushed by a spring member. A fin of a second cylinder is compressed and pushed corresponding to a differential pressure between a guided intra-casing pressure in a fin chamber and a suction pressure or discharge pressure guided in the cylinder chamber. A pressure change mechanism guiding the suction pressure or the discharge pressure has a bypass tube having one end connected to a high pressure side of the refrigeration cycle, and the other end connected to a suction tube , and a first activation-deactivation valve in an intermediate portion, and a second activation-deactivation valve or a check valve that is provided in the suction tube on an upstream side of a connection portion of the bypass pipe. and on one side downstream of an oil return opening in an accumulator.

Summary of the invention

The main purpose of the disclosure is to provide an air conditioning system and a method for controlling an air conditioning system, which are intended to solve the problem of the prior art that switching easily fails in a switching process of an operation of a single cylinder and a two-cylinder operation of a compressor of the air conditioning system.

In order to achieve the objective, according to one aspect of the disclosure, an air conditioning system is provided, comprising a two-cylinder variable capacity compressor, the variable capacity two-cylinder compressor having a suction orifice. of an upper cylinder, a suction hole of a lower cylinder and an exhaust hole. The air conditioning system may further comprise a first solenoid valve. One end of the first solenoid valve can be connected to the exhaust port of the two-cylinder variable capacity compressor, and the other end of the first solenoid valve can be connected to a unidirectional valve and to the suction port of the lower cylinder of the Two-cylinder variable capacity compressor, respectively. One end of the unidirectional valve can be connected to the first solenoid valve, and the other end of the unidirectional valve can communicate with an inner chamber of a gas-liquid separator. The air conditioning system may further comprise a second solenoid valve, provided in a pipe connecting the suction port of the lower cylinder of the two-cylinder variable capacity compressor to an inlet of the gas-liquid separator.

In addition, the air conditioning system may further comprise a capillary tube, connected in series to the second solenoid valve.

In addition, the air conditioning system can further comprise a temperature sensor, arranged in a pipe of the suction orifice of the lower cylinder.

In addition, the air conditioning system may further comprise a high pressure sensor, arranged in a pipeline of the exhaust port.

According to another aspect of the disclosure, there is provided a method for controlling an air conditioning system, which can be applied to the air conditioning system. The control method comprises: Step 10, when a two-cylinder variable capacity compressor is under a single cylinder operating state and has to be switched to a two-cylinder operating state, a pipe connecting an orifice Suction of a lower cylinder of the variable capacity compressor of two cylinders with an inlet of a gas-liquid separator is opened.

In addition, in Step 10, the pipe connecting the suction port of the lower cylinder of the variable capacity compressor two cylinders with the inlet of the gas-liquid separator is opened through a second solenoid valve, and a first valve of Solenoid can be closed after a period of time ts. In addition, the control method further comprises: Step 20, when the two-cylinder variable capacity compressor has been under the operating state of a single cylinder for a period of time t1, a lower temperature of the suction port of the cylinder. lower cylinder of the two-cylinder variable capacity compressor and a temperature Tsuperior of an exhaust port of the two-cylinder variable capacity compressor are compared in a time interval of t2, and if Tinferior is less than or equal to Tsuperior, the second Solenoid valve closes after having been open for a period of time t3.

In addition, the time ts in Stage 10 may be relevant for an outdoor outdoor ambient temperature TW. When TW is greater than or equal to ° C, ts may be equal to t5, when TW is greater than or equal to B ° C and is less than A ° C, ts may be equal to t6, and when TW is less than B ° C, ts can be equal to t7, where t5, t6 and t7 can be predetermined time constants, and A and B can be preset temperature constants.

In addition, Step 10 may further comprise that: the second solenoid valve is closed after the first solenoid valve has been closed for a period of time t4.

By means of the technical solutions, a drain bypass pipe provided with a solenoid valve is additionally provided between the suction port of the lower cylinder and the inlet of the liquid gas separator, and a high pressure refrigerant on a suction side of the The lower cylinder is decompressed in the gas-liquid separator through the drain bypass pipe, optimizing in this way the stability of the system when switching from the operation of a single cylinder to the operation of two cylinders.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings in the specification forming a part of the disclosure are intended to provide a greater understanding of the disclosure. The embodiments and schematic descriptions of the disclosure are intended to explain the disclosure, and do not form undue limits of the disclosure. In the drawings:

Figure 1 shows an air conditioning system with a variable capacity and variable frequency compressor in the prior art;

Figure 2 shows an air conditioning system according to the disclosure; Y

Figure 3 shows a flow chart of an air conditioning system control method according to the disclosure.

Detailed description of the embodiments

It is important to note that the embodiments of the disclosure and features in the embodiments can be combined under the condition of not having any conflict. The disclosure is described below with reference to the drawings and embodiments in detail.

As shown in Figure 2, in accordance with the disclosure, based on the prior art, a drain bypass pipe is additionally provided between a suction port of a lower cylinder of a two-cylinder variable capacity compressor and an inlet of a gas-liquid separator. The drain bypass line comprises mainly a capillary tube and a second solenoid valve 72, a high pressure sensor 100 is additionally provided to an exhaust side of the two cylinder variable capacity compressor to detect a Tsuperior condensing temperature, and A temperature sensor 90 is additionally provided in the suction hole of the lower cylinder and serves as a detection tool for detecting a temperature Tferior of the suction port of the lower cylinder. Under a specific condition, the second solenoid valve 72 of the drain bypass pipe is opened so as to perform decompression and drainage movements. When the suction hole of the lower cylinder is under a liquid collecting state, a liquid refrigerant in a connecting tube between the lower cylinder of the two cylinder variable capacity compressor 30 and a first solenoid valve 71 can be discharged to the gas-liquid separator by means of automatic detection. When a single-cylinder operation is switched to two-cylinder operation, a high-pressure refrigerant on one side of the lower cylinder suction is decompressed in the gas-liquid separator through the drain bypass pipe, that the operation of a single cylinder is successfully switched to the operation of two cylinders, thereby improving the stability of the system during the switching operation.

As shown in Figure 2, an air conditioning system according to the disclosure comprises a two-cylinder variable capacity compressor 30 and the gas-liquid separator. A suction port of an upper cylinder, the suction port of the lower cylinder and an exhaust port are led to the variable capacity compressor of two cylinders 30. The variable capacity compressor of two cylinders 30, a first heat exchanger 10 , a choke assembly 40 and a second heat exchanger 20 are connected to form a circuit. The air conditioning system further comprises a four-way valve 60, the first solenoid valve 71 and a unidirectional valve 50. The first heat exchanger 10 and the second heat exchanger 20 are selectively connected to the variable capacity compressor. of two cylinders 30 through the four-way valve 60; one end of the first solenoid valve 71 is connected to the exhaust port of the variable capacity compressor of two cylinders 30, and the other end of the first solenoid valve 71 is connected to the unidirectional valve 50 and to the suction port of the cylinder lower respectively; one end of the unidirectional valve 50 is connected to a pipe, the pipe of the first solenoid valve 71 leading to the suction hole of the lower cylinder, and the other end of the unidirectional valve 50 communicates with an inner chamber of the gas separator -liquid; and the flow of the unidirectional valve 50 from the gas-liquid separator to the suction orifice of the lower cylinder is allowed. In the disclosure, additionally, a bypass is provided formed by the second solenoid valve 72 and the capillary tube connected in series thereto and connected between a suction port pipe of the lower cylinder of the compressor and a pipe of the separator inlet. of gas-liquid.

The capillary tube in a drain bypass circuit has the function of controlling the drainage flow. If a capillary tube is too thick and too short, the flow will be excessively high, the reduction of the lower cylinder pressure will occur, and the operation of a single cylinder will not be able to continue in case of pressure shortage and will be changed to operation of two cylinders. If a capillary tube is too thin and too long, the flow will be lower, the rate of drainage will be too low, and the drainage movement can not be completed within a set time. Therefore, a moderate capillary tube is needed for the drain bypass circuit.

As shown in Figure 3, a method for controlling an air conditioning system according to the disclosure comprises:

(1) When a two-cylinder variable capacity compressor 30 is under the operation of a single cylinder and the operating time of a single cylinder of the two-cylinder variable capacity compressor 30 exceeds a period of time t1,

(2) When the two-cylinder variable capacity compressor 30 is under the operation of a single cylinder and switching to the operation of two cylinders is necessary, a first solenoid valve 71 is closed after the second solenoid valve 72 has been opened for a period of time ts, and the second solenoid valve 72 is closed after the first solenoid valve 71 has been closed for a period of time t4 in order to achieve a decompression effect.

(3) Since the liquid collection situations of different outdoor ambient temperatures TW are different, the time ts in Stage (2) is relevant for outdoor ambient temperatures. For example, (A and B are preset temperature constants that can be determined through experiments) a) when TW is greater than or equal to A ° C, ts equals t5;

b) when TW is greater than or equal to B ° C and is less than A ° C, ts equals t6; Y

c) when TW is less than B ° C, ts equals t7. (Where t i, t2, t3, t4, t5, t6 and t7 are preset times that can be determined through experiments.)

In the disclosure, an adjustment range of the cooling / heating capacity of the system is expanded by the combination of a variable-frequency two-cylinder or multi-cylinder compressor with the gas-liquid separator and a capacity variation technology. . The bypass formed by the second solenoid valve and capillary tube has the following main functions. When it is necessary to close the first solenoid valve, the second solenoid valve opens to reduce the pressure of the pipe pipe between the suction port of the lower cylinder and the first solenoid valve to be consistent with the low pressure in order to guarantee that the compressor commutes rapidly changed to be under the operation of two cylinders after the first solenoid valve closes. When the air conditioning system is under the operation of a single cylinder, it can be evaluated if the liquid is collected in the suction hole of the lower cylinder by means of the temperature detected by a temperature sensor in the pipe in the hole Suction of the lower cylinder of the compressor and the temperature at high pressure detected by a high pressure sensor. When evaluating the liquid collection, the second solenoid valve is opened for a period of time, so that the effect of avoiding a liquid impact when the compressor is switched from the operation of a single cylinder to the operation of two cylinders after operation It takes a long time for a single one.

The foregoing are only the preferred embodiments of the disclosure, and are not intended to limit the disclosure. There may be several modifications and variations in the disclosure for those skilled in the art. Any modification, equivalent substitutions, improvements and the like will fall within the scope of protection defined by the appended claims.

Claims (9)

An air conditioning system, comprising a two-cylinder variable capacity compressor (30), the two cylinder variable capacity compressor (30) having a suction port of a top cylinder, a suction port of a lower cylinder and an exhaust port, and the air conditioning system further comprises a first solenoid valve (71), one end of the first solenoid valve (71) is connected to the exhaust port of the variable capacity compressor of two cylinders (30), and the other end of the first solenoid valve (71) is connected to a unidirectional valve (50) and to the suction port of the lower cylinder of the two-cylinder variable capacity compressor (30), respectively; one end of the unidirectional valve (50) is connected to the first solenoid valve (71), and the other end of the unidirectional valve (50) is connected to an inner chamber of a gas-liquid separator; where the air conditioning system further comprises a second solenoid valve (72), provided in a tube connecting the suction port of the lower cylinder of the two-cylinder variable capacity compressor (30) to an inlet of the gas-liquid separator . The air conditioning system according to claim 1, wherein it further comprises a capillary tube, connected in series to the second solenoid valve (72). 3. The air conditioning system according to claim 1, wherein it further comprises a temperature sensor (90), provided in a suction port of the lower cylinder. The air conditioning system according to claim 1, wherein it further comprises a high pressure sensor (100), provided in an exhaust orifice pipe. A method for controlling an air conditioning system, wherein, applied to an air conditioning system according to any one of claims 1 to 4, the control method comprises: Step 10, when a capacity compressor Two-cylinder variable (30) is in the operating state of a single cylinder and it has to switch to a two-cylinder operating state, open a pipe connecting a suction hole of a lower cylinder of variable capacity compressor of two cylinders (30) to an inlet of a gas-liquid separator. The method for controlling an air conditioning system according to claim 5, wherein in Step 10, the tube connecting the suction port of the lower cylinder of the two-cylinder variable capacity compressor (30) to the inlet of the gas-liquid separator opens through a second solenoid valve (72), and a first solenoid valve (71) closes after a period of time ts. The method for controlling an air conditioning system according to claim 6, wherein the control method further comprises: Step 20, when the two-cylinder variable capacity compressor (30) has been in the operating state of a single cylinder for more than a period of time t1, the temperature Tinferior of the suction port of the lower cylinder of the variable capacity compressor of two cylinders (30) is compared to a temperature Tsuperior of the exhaust port of the variable capacity compressor of two cylinders (30) in a time interval of t2, and if Tinferior is less than or equal to Tsuperior, the second solenoid valve (72) is closed after being open for a period of time t3. The method for controlling an air conditioning system according to claim 6, wherein the time ts in Step 10 is relevant with respect to an outdoor ambient temperature TW; and when tW is greater than or equal to A ° C, ts is equal to t5, when TW is greater than or equal to B ° C and is less than A ° C, ts is equal to t6, and when TW is less than B ° C, ts is equal to t7, where t5, t6 and t7 are preset time constants, and A and B are preset temperature constants. The method for controlling an air conditioning system according to claim 6, wherein Step 10 further comprises: closing the second solenoid valve (72) after closing the first solenoid valve (71) during a period of time t4.