CN111609592B - Dual-temperature air conditioning system, control method and air conditioner - Google Patents

Abstract

The invention provides a dual-temperature air conditioning system, a control method and an air conditioner, wherein the dual-temperature air conditioning system comprises: the air conditioner comprises a compressor, an outdoor heat exchanger, a first indoor heat exchanger and a second indoor heat exchanger, wherein the compressor comprises a first cylinder and a second cylinder; the outdoor heat exchanger is communicated with the first indoor heat exchanger through a first pipeline, the first pipeline is provided with a first throttling device, the outdoor heat exchanger is also communicated with the second indoor heat exchanger through a second pipeline, and the second pipeline is provided with a second throttling device; the opening degrees of the first throttling device and the second throttling device are adjusted according to the difference value between the corresponding temperature of the indoor heat exchanger and the preset temperature of the indoor heat exchanger. According to the invention, the two throttling devices can be stably controlled, the condition that the opening degrees of the two throttling devices are mutually influenced and cannot be stably controlled due to coupling in actual control is prevented, and the stable, reliable and efficient operation of the dual-temperature air conditioning system is ensured.

Description

Dual-temperature air conditioning system, control method and air conditioner

Technical Field

The invention relates to the technical field of air conditioners, in particular to a dual-temperature air conditioner system, a control method and an air conditioner.

Background

The existing air conditioning system usually adopts a single-suction single-row compressor, and a refrigeration cycle loop is formed by the single-row compressor and single-row or multi-row heat exchangers indoors and outdoors, so that indoor air is heated or cooled, and the requirement of indoor environment comfort is met. The air conditioning system can only realize one evaporation temperature and one condensation temperature because the compressor is only connected with the indoor heat exchanger and the outdoor heat exchanger through the suction port and the exhaust port. In order to realize step heating or cooling of indoor air, patent application No. CN105444453A proposes a dual-temperature air conditioning system with two parallel-connected cylinders to improve system energy efficiency and slow down the attenuation speed of energy efficiency under the working condition of low-temperature heating and frosting. The double-temperature air conditioning system is provided with two throttling devices, and the control of the two throttling devices plays an important role in the performance of the system.

Because the dual-temperature air conditioning system in the prior art needs two throttling devices, the two throttling devices are in parallel connection, and the opening degrees of the two throttling devices are mutually influenced, the technical problems of mutual coupling, difficulty in stable control and the like exist in the actual system control, and therefore the dual-temperature air conditioning system, the control method and the air conditioner are researched and designed.

Disclosure of Invention

Therefore, the technical problem to be solved by the present invention is to overcome the defect that the two throttling devices in the dual-temperature air conditioning system in the prior art cannot realize stable control, so that the system cannot operate stably, reliably and efficiently, thereby providing a dual-temperature air conditioning system, a control method and an air conditioner.

In order to solve the above problems, the present invention provides a dual temperature air conditioning system, comprising:

the compressor comprises a first cylinder and a second cylinder, the first cylinder is provided with a first air suction port and a first exhaust port, and the second cylinder is provided with a second air suction port and a second exhaust port; the outdoor heat exchanger is capable of being communicated to the first exhaust port and the second exhaust port simultaneously, the first indoor heat exchanger is capable of being communicated to the first suction port, and the second indoor heat exchanger is capable of being communicated to the second suction port; or, the outdoor heat exchanger may be communicated to the first suction port and the second suction port at the same time, the first indoor heat exchanger may be communicated to the first exhaust port, and the second indoor heat exchanger may be communicated to the second exhaust port;

or, the first cylinder has a first air suction port, the second cylinder has a second air suction port, and the gas discharged from the first cylinder and the gas discharged from the second cylinder are mixed in the shell of the compressor and then discharged through a third air discharge port: the outdoor heat exchanger is communicable to the third air outlet, the first indoor heat exchanger is communicable to the first air intake, and the second indoor heat exchanger is communicable to the second air intake; or, the outdoor heat exchanger can be communicated to the first air suction port and the second air suction port at the same time, the first indoor heat exchanger can be communicated to the third air discharge port, and the second indoor heat exchanger can be communicated to the third air discharge port;

a first pipeline communicated with the first indoor heat exchanger and a second pipeline communicated with the second indoor heat exchanger are converged and then communicated to the outdoor heat exchanger through a third pipeline, a first throttling device is arranged on the first pipeline or the third pipeline, and a second throttling device is arranged on the second pipeline;

the opening degree of the first throttling device can be adjusted according to a first difference value between the temperature of a first indoor heat exchanger of the first indoor heat exchanger and the preset temperature of the first indoor heat exchanger; the opening degree of the second throttling device can be adjusted according to a second difference value between the temperature of the second indoor heat exchanger and the preset temperature of the second indoor heat exchanger.

Preferably, the first and second electrodes are formed of a metal,

the adjustment amount of the opening degree adjustment of the first throttling device is positively correlated with the first difference value; the adjustment amount of the opening degree adjustment of the second throttle device is positively correlated with the second difference.

Preferably, the first and second electrodes are formed of a metal,

in the flowing direction of the circulating airflow, the first indoor heat exchanger and the second indoor heat exchanger are respectively positioned at the upstream and the downstream of the circulating airflow, and when the dual-temperature air-conditioning system operates in a refrigerating mode, the preset temperature of the second indoor heat exchanger is determined according to the indoor environment temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is used for heating, the preset temperature of the second indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency.

Preferably, when the dual-temperature air conditioning system operates in a refrigerating mode, the preset temperature of the first indoor heat exchanger is determined according to the indoor environment temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is in heating operation, the preset temperature of the first indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency; and/or when the air conditioner runs in a refrigerating mode, at the same detection moment, the temperature of the preset first indoor heat exchanger is higher than that of the preset second indoor heat exchanger.

Preferably, the first and second electrodes are formed of a metal,

during refrigerating operation, the outdoor heat exchanger is communicated to the first exhaust port and the second exhaust port at the same time, the first indoor heat exchanger is communicated to the first air suction port, and the second indoor heat exchanger is communicated to the second air suction port; when the air conditioner works for heating, the outdoor heat exchanger is communicated to the first air suction port and the second air suction port at the same time, the first indoor heat exchanger is communicated to the first exhaust port, and the second indoor heat exchanger is communicated to the second exhaust port.

Preferably, the first and second electrodes are formed of a metal,

the oil return device is arranged at the second air outlet and can return oil in the gas exhausted by the second air outlet to the bottom of the inner cavity of the compressor;

the oil return device comprises an oil separator and an oil return assembly, the second exhaust port is communicated with the oil separator through an exhaust pipeline, the bottom of the oil separator is communicated to the bottom of an inner cavity of the compressor through an oil return pipeline, and the oil return assembly comprises a first oil return control valve arranged on the oil return pipeline; or,

the oil return device comprises an oil separator and an oil return assembly, the second exhaust port is communicated with the oil separator through an exhaust pipeline, the bottom of the oil separator is communicated to the bottom of an inner cavity of the compressor through an oil return pipeline, the oil return assembly comprises a second oil return control valve arranged on the oil return pipeline and a parallel pipeline connected with the second oil return control valve in parallel, and an oil return capillary is arranged on the parallel pipeline.

The invention also provides a control method suitable for the dual-temperature air conditioning system, which comprises the following steps:

detecting the indoor environment temperature, the indoor relative humidity, the compressor running frequency, the first indoor heat exchanger temperature and the second indoor heat exchanger temperature;

acquiring an operation mode of a dual-temperature air conditioning system;

acquiring a preset first indoor heat exchanger temperature and a preset second indoor heat exchanger temperature according to the acquired operation mode;

comparing the obtained temperature of the first indoor heat exchanger with the preset temperature of the first indoor heat exchanger to obtain a first difference value, and comparing the obtained temperature of the second indoor heat exchanger with the preset temperature of the second indoor heat exchanger to obtain a second difference value;

and respectively adjusting the opening degrees of the first throttling device and the second throttling device, wherein the opening degree adjustment quantity of the first throttling device is positively correlated with the first difference value, and the opening degree adjustment quantity of the second throttling device is positively correlated with the second difference value.

Preferably, the first and second electrodes are formed of a metal,

the operation modes comprise a cooling mode and a heating mode;

in the flowing direction of circulating airflow, the first indoor heat exchanger and the second indoor heat exchanger are respectively positioned at the upstream and the downstream of the circulating airflow, and when the operation mode is a refrigeration mode, the preset temperature of the second indoor heat exchanger is determined according to the acquired indoor environment temperature and the indoor relative humidity; and/or when the operation mode is the heating mode, the preset temperature of the second indoor heat exchanger is determined according to the acquired indoor environment temperature and the compressor operation frequency.

Preferably, the first and second electrodes are formed of a metal,

the operation modes comprise a cooling mode and a heating mode;

in the flowing direction of circulating airflow, the first indoor heat exchanger and the second indoor heat exchanger are respectively positioned at the upstream and the downstream of the circulating airflow, and when the operation mode is a refrigeration mode, the preset temperature of the first indoor heat exchanger is determined according to the acquired indoor environment temperature and the indoor relative humidity; and/or when the operation mode is a heating mode, the preset temperature of the first indoor heat exchanger is determined according to the acquired indoor environment temperature and the compressor operation frequency.

The invention also provides an air conditioner which comprises the dual-temperature air conditioning system.

The invention provides a dual-temperature air conditioning system, a control method and an air conditioner, wherein compressors of at least two independent cylinders respectively form the dual-temperature air conditioning system with two evaporation temperatures or condensation temperatures together with a first indoor heat exchanger, a second indoor heat exchanger, an outdoor heat exchanger, a first throttling device, a second throttling device and corresponding pipelines, through the independent control of the first throttling device and the second throttling device, and the correlation between the corresponding control strategy and the first difference value or the second difference value of the preset temperature of the indoor heat exchanger, the stable control of the two throttling devices in the dual-temperature air-conditioning system can be effectively realized, the situation that the opening degree of the two throttling devices in the actual system control is influenced mutually to generate coupling to cause unstable control is prevented, and the stable, reliable and efficient operation of the dual-temperature air-conditioning system is ensured.

Drawings

FIG. 1 is a system diagram of a dual temperature air conditioning system according to one embodiment of the present invention;

FIG. 2 is a system diagram of a dual temperature air conditioning system according to another embodiment of the present invention;

FIG. 3 is a system diagram of a dual temperature air conditioning system according to yet another embodiment of the present invention;

FIG. 4 is a block diagram of a double suction double row compressor in accordance with one embodiment of the present invention;

fig. 5 is a system diagram of a dual temperature air conditioning system according to still another embodiment of the present invention.

The reference numerals are represented as:

1. a compressor; 21. a first four-way valve; 22. a second four-way valve; 3. an outdoor heat exchanger; 41. a first throttling device; 42. a second throttling device; 51. a first indoor heat exchanger; 52. a second indoor heat exchanger; 6. an oil separator; 7. a first oil return control valve; 8. an indoor fan; 9. an outdoor fan; 10. a second return oil control valve; 11. an oil return capillary tube; 12. a first pipeline; 13. a second pipeline; 14. a third pipeline; 101. a first air intake port; 102. a second air suction port; 103. a first exhaust port; 104. a second exhaust port; 105. an oil return port; 106. a third exhaust port.

Detailed Description

Referring to fig. 1 to 5 in combination, the present invention provides a dual temperature air conditioning system, including: the air conditioner comprises a compressor 1, an outdoor heat exchanger 3 (and an outdoor fan 9 corresponding to the outdoor heat exchanger), a first indoor heat exchanger 51 and a second indoor heat exchanger 52, wherein the compressor 1 comprises a first cylinder and a second cylinder, the first cylinder is provided with a first air suction port 101 and a first air exhaust port 103, and the second cylinder is provided with a second air suction port 102 and a second air exhaust port 104; the outdoor heat exchanger 3 can be communicated to the first exhaust port 103 and the second exhaust port 104 at the same time, the first indoor heat exchanger 51 can be communicated to the first suction port 101, and the second indoor heat exchanger 52 can be communicated to the second suction port 102, for example, when the system shown in fig. 1 is in a cooling condition; alternatively, the outdoor heat exchanger 3 can be communicated to the first suction port 101 and the second suction port 102 at the same time, the first indoor heat exchanger 51 can be communicated to the first exhaust port 103, and the second indoor heat exchanger 52 can be communicated to the second exhaust port 104, for example, when the system shown in fig. 1 is in a heating condition; or, the first cylinder has a first air intake 101, the second cylinder has a second air intake 102, and the gas discharged from the first cylinder and the gas discharged from the second cylinder are mixed in the interior of the compressor casing and then discharged through a third air discharge 106: the outdoor heat exchanger 3 may be communicated to the third discharge port 106, the first indoor heat exchanger 51 may be communicated to the first suction port 101, and the second indoor heat exchanger 52 may be communicated to the second suction port 102; alternatively, the outdoor heat exchanger 3 may be communicated to the first suction port 101 and the second suction port 102 at the same time, the first indoor heat exchanger 51 may be communicated to the third discharge port 106, and the second indoor heat exchanger 52 may also be communicated to the third discharge port 106; a first pipeline 12 communicated with the first indoor heat exchanger 51 and a second pipeline 13 communicated with the second indoor heat exchanger 52 are converged and then communicated to the outdoor heat exchanger 3 through a third pipeline 14, a first throttling device 41 is arranged on the first pipeline 12 or the third pipeline 14, and a second throttling device 42 is arranged on the second pipeline 13; the opening degree of the first throttling device 41 can be adjusted according to a first difference value between the first indoor heat exchanger temperature of the first indoor heat exchanger 51 and a preset first indoor heat exchanger temperature; the opening degree of the second throttling device 42 can be adjusted according to a second difference value between the second indoor heat exchanger temperature of the second indoor heat exchanger 52 and the preset second indoor heat exchanger temperature. In the technical scheme, the compressors of at least two independent cylinders respectively form a dual-temperature air conditioning system with two evaporation temperatures or condensation temperatures with the first indoor heat exchanger 51, the second indoor heat exchanger 52, the outdoor heat exchanger 3, the corresponding first throttling device 41, the second throttling device 42 and the corresponding pipelines, the stable control of the two throttling devices in the dual-temperature air conditioning system can be effectively realized by independently controlling the first throttling device 41 and the second throttling device 42, and the first difference value or the second difference value between the corresponding control strategy and the preset indoor heat exchanger temperature is correlated, the condition that the opening degrees between the two throttling devices in actual system control are mutually influenced to generate coupling to cause unstable control is prevented, and the stable, reliable and efficient operation of the dual-temperature air conditioning system is ensured.

Preferably, the adjustment amount of the opening degree adjustment of the first throttling device 41 is positively correlated with the first difference; the adjustment amount of the opening degree adjustment of the second throttle device 42 is positively correlated with the second difference. Specifically, the larger the first difference or the second difference is, the larger the respective opening degree adjustment amounts of the corresponding first throttling device 41 and the second throttling device 42 are, and conversely, the smaller the first difference or the second difference is, the smaller the respective opening degree adjustment amounts of the corresponding first throttling device 41 and the second throttling device 42 are. Further, whether the opening degree adjustment amount is adjusted towards a direction of increasing or decreasing depends on the operation mode of the dual-temperature air conditioning system, for example, when the dual-temperature air conditioning system performs cooling operation, if the first difference is greater than 0, it indicates that the temperature of the first indoor heat exchanger 51 is higher, at this time, the opening degree of the first throttling device 41 should be adjusted towards a direction of decreasing, and if the first difference is larger, the opening degree adjustment amount is also larger, so that the temperature of the first indoor heat exchanger 51 can more rapidly approach the preset first indoor heat exchanger temperature until the same, that is, the first difference is 0, and conversely, if the first difference is smaller than 0, it indicates that the temperature of the first indoor heat exchanger 51 is lower, at this time, the opening degree of the first throttling device 41 should be adjusted towards a direction of increasing, and if the first difference is larger, the opening degree adjustment amount is also larger, so that the temperature of the first indoor heat exchanger 51 can more rapidly approach the preset first indoor heat exchanger temperature until the preset first indoor heat exchanger temperature is the same; and for the second difference value and when the dual-temperature air conditioning system operates for heating, the opening degree adjustment principle of the throttling device is consistent with that during refrigeration, and details are not repeated here.

It is understood that the aforementioned predetermined first indoor heat exchanger temperature and predetermined second indoor heat exchanger temperature may be determined according to a plurality of common detection values of the compressor operation frequency, the indoor ambient temperature, the indoor relative humidity, etc., and a specific calculation or obtaining method (such as experimental statistics) is a conventional technique in the art, and the present invention is not intended to improve the determination method, and it is preferable that, in the flow direction of the ventilation air flow, the first indoor heat exchanger 51 and the second indoor heat exchanger 52 are respectively located upstream and downstream of the ventilation air flow, and in the cooling operation of the dual-temperature air conditioning system, the predetermined second indoor heat exchanger temperature is determined according to the indoor ambient temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is in heating operation, the preset temperature of the second indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency; when the dual-temperature air conditioning system operates in a refrigerating mode, the temperature of the preset first indoor heat exchanger is determined according to the indoor environment temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is used for heating, the preset temperature of the first indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency. The possibility that condensation can be generated in the cooling mode and the possibility that condensation cannot be generated in the heating mode is fully considered, so that when the system is in cooling operation, the indoor environment temperature and the indoor relative humidity are selected as the preset first indoor heat exchanger temperature or the preset second indoor heat exchanger temperature obtaining basis parameters, and the condensation generation probability can be effectively avoided. Further, during the cooling operation, at the same detection time, the preset temperature of the first indoor heat exchanger is higher than the preset temperature of the second indoor heat exchanger, so that the gradient of the temperature is reduced when the circulating airflow sequentially flows through the first indoor heat exchanger 51 and the second indoor heat exchanger 52, and the energy efficiency of the air conditioning system is improved. In this technical solution, although the acquisition basis parameter of the preset first indoor heat exchanger temperature and the acquisition basis parameter of the preset second indoor heat exchanger temperature may be the same in different operation modes, the acquisition basis parameter may be set at a specific preset value (temperature value), and as described above, in a specific application process, the preset temperature value of the heat exchanger (corresponding to the second indoor heat exchanger 52 in fig. 1) located downstream in the flowing direction of the circulating airflow is set to be smaller than the preset temperature value of the heat exchanger (corresponding to the first indoor heat exchanger 51 in fig. 1) located upstream in the flowing direction of the circulating airflow.

Specifically, a specific example of determining the preset second indoor heat exchanger temperature in the cooling mode is given in the following table, and it can be seen in the table that both the indoor ambient temperature and the indoor relative humidity determine the preset second indoor heat exchanger temperature at a certain detection time, for example, when the indoor ambient temperature is 25 ℃ and the indoor relative humidity is 61%, the preset second indoor heat exchanger temperature at this time corresponds to 17 ℃, and the corresponding first indoor heat exchanger temperature may be set to be slightly higher, for example, 19 ℃.

The following table shows a specific example of determining the preset temperature of the second indoor heat exchanger in the heating mode, where it can be seen that the indoor ambient temperature, the compressor operating frequency and the damper level jointly determine the preset temperature of the second indoor heat exchanger at a certain detection time (the damper level may not be considered, but is preferably considered to ensure that the preset temperature is obtained more accurately), and specifically, for example, when the indoor ambient temperature is 17 ℃, the compressor operating frequency is 19Hz, and the damper level is a high damper, the preset temperature of the second indoor heat exchanger at this time corresponds to 33 ℃, and the corresponding temperature of the first indoor heat exchanger may be set to be slightly higher, for example, 32 ℃, it can be understood that the parameter ranges in the following table are only one specific example of the technical solution of the present application, and do not limit the protection range structure of the technical solution of the present invention, nor are full examples given of the various states.

In order to ensure the smooth switching between the cooling working condition and the heating working condition of the dual-temperature air conditioning system, preferably, the outdoor heat exchanger 3 is communicated to the first exhaust port 103 and the second exhaust port 104 at the same time, the first indoor heat exchanger 51 is communicated to the first air inlet 101, and the second indoor heat exchanger 52 is communicated to the second air inlet 102, so as to ensure that the dual-temperature air conditioning system has the cooling working condition; the outdoor heat exchanger 3 is communicated to the first air inlet 101 and the second air inlet 102 at the same time, the first indoor heat exchanger 51 is communicated to the first exhaust port 103, and the second indoor heat exchanger 52 is communicated to the second exhaust port 104, so as to ensure that the dual-temperature air conditioning system has a heating working condition. Specifically, for example, the dual temperature air conditioning system further includes a first four-way valve 21 and a second four-way valve 22, four ports of the first four-way valve 21 are respectively communicated to the first suction port 101, the first exhaust port 103, the outdoor heat exchanger 3 and the first indoor heat exchanger 51, and four ports of the second four-way valve 22 are respectively communicated to the second suction port 102, the second exhaust port 104, the outdoor heat exchanger 3 and the second indoor heat exchanger 52.

First cylinder and second cylinder are preferred through the parallel connection mode of same pivot drive, the first gas vent 103 of first cylinder with compressor 1's casing inner chamber intercommunication, and the casing inner chamber of compressor then realizes the fluid separation effect of first gas vent 103, and to the second gas vent 104 of second cylinder then can design solitary oil return device best, oil return device sets up second gas vent 104 department, in order to can with oil among the second gas vent combustion gas flows back extremely compressor 1's inner chamber bottom. In order to ensure the energy efficiency utilization rate of the first indoor heat exchanger 51 and the second indoor heat exchanger 52, preferably, the volume ratio of the first cylinder to the second cylinder is 0.2 to 2.5, so that the reasonable distribution of the flow rates of the refrigerant in the first indoor heat exchanger 51 and the second indoor heat exchanger 52 can be ensured, and the efficiency of the dual-temperature air conditioning system is improved more obviously.

As shown in fig. 1, the oil return device includes an oil separator 6 and an oil return assembly, the second exhaust port 104 is communicated with the oil separator 6 through an exhaust pipe, the bottom of the oil separator 6 is communicated to an oil return port 105 of the compressor 1 through an oil return pipe to return oil separated by the oil separator 6 to the bottom of the inner cavity of the compressor 1, the oil return assembly includes a first oil return control valve 7 arranged on the oil return pipe, in the technical scheme, the opening and closing of an oil return passage can be effectively controlled through the arrangement of the first oil return control valve 7 and the oil return pipe, and an effective oil return effect can be performed when oil return is required; alternatively, as shown in fig. 2, the oil return device includes an oil separator 6 and an oil return assembly, the second exhaust port 104 communicates with the oil separator 6 through an exhaust line, the bottom of the oil separator 6 is communicated to the bottom of the inner cavity of the compressor 1 through an oil return pipeline, the oil return assembly comprises a second oil return control valve 10 arranged on the oil return pipeline and a parallel pipeline connected with the second oil return control valve in parallel, an oil return capillary tube 11 is arranged on the parallel pipeline, in the technical scheme, the opening and closing of the oil return passage can be effectively controlled through the arrangement of the second oil return control valve 10 and the oil return pipeline, effective oil return effect (large flow) can be carried out when needs carry out the oil return, can also carry out the oil return effect (small flow) that has the throttle degree through oil return capillary 11 when second oil return control valve 10 closes, can effectively guarantee that the oil return process lasts effectual going on.

Preferably, an indoor fan 8 is further included, the first indoor heat exchanger 51 and the second indoor heat exchanger 52 are arranged side by side, and the indoor fan 8 is arranged at one side of the second indoor heat exchanger 52, so that the airflow sequentially flows through the first indoor heat exchanger 51, the second indoor heat exchanger 52 and the indoor fan 8; or, the indoor fan 8 is disposed at one side of the first indoor heat exchanger 51, so that the airflow sequentially flows through the second indoor heat exchanger 52, the first indoor heat exchanger 51 and the indoor fan 8, in the technical scheme, the two indoor heat exchangers are overlapped in the flowing direction of the airflow, and one indoor fan performs a heat exchange effect on the two indoor heat exchangers, so that effective integration of the heat exchangers is realized, the structure is compact, the airflow step cooling effect can be realized, the heat exchange temperature difference is reduced, and the energy efficiency level of the system is improved.

According to an embodiment of the present invention, there is also provided a control method for the dual-temperature air conditioning system, including:

detecting the indoor environment temperature, the indoor relative humidity, the compressor running frequency, the first indoor heat exchanger temperature and the second indoor heat exchanger temperature;

acquiring an operation mode of a dual-temperature air conditioning system;

acquiring a preset first indoor heat exchanger temperature and a preset second indoor heat exchanger temperature according to the acquired operation mode;

comparing the obtained temperature of the first indoor heat exchanger with the preset temperature of the first indoor heat exchanger to obtain a first difference value, and comparing the obtained temperature of the second indoor heat exchanger with the preset temperature of the second indoor heat exchanger to obtain a second difference value;

the opening degrees of the first throttle device 41 and the second throttle device 42 are adjusted, respectively, the opening degree adjustment amount of the first throttle device 41 is positively correlated with the first difference, and the opening degree adjustment amount of the second throttle device 42 is positively correlated with the second difference.

Preferably, the first and second electrodes are formed of a metal,

the operation modes comprise a cooling mode and a heating mode; when the operation mode is a refrigeration mode, the preset temperature of the first indoor heat exchanger is determined according to the acquired indoor environment temperature and indoor relative humidity; and/or when the operation mode is a heating mode, the preset temperature of the first indoor heat exchanger is determined according to the acquired indoor environment temperature and the compressor operation frequency; when the operation mode is a refrigeration mode, the preset temperature of the second indoor heat exchanger is determined according to the acquired temperature of the first indoor heat exchanger and the acquired indoor relative humidity; and/or when the operation mode is a heating mode, the preset first indoor heat exchanger temperature is determined according to the acquired first indoor heat exchanger temperature and the compressor operation frequency.

According to an embodiment of the invention, an air conditioner is also provided, which comprises the dual-temperature air conditioning system.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention. The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (10)

1. A dual temperature air conditioning system, comprising:

the air conditioner comprises a compressor (1), an outdoor heat exchanger (3), a first indoor heat exchanger (51) and a second indoor heat exchanger (52), wherein the compressor (1) comprises a first cylinder and a second cylinder, the first cylinder is provided with a first air suction port (101) and a first air exhaust port (103), and the second cylinder is provided with a second air suction port (102) and a second air exhaust port (104); the outdoor heat exchanger (3) is connectable to the first exhaust port (103) and the second exhaust port (104) at the same time, the first indoor heat exchanger (51) is connectable to the first intake port (101), and the second indoor heat exchanger (52) is connectable to the second intake port (102); or, the outdoor heat exchanger (3) may be communicated to the first suction port (101) and the second suction port (102) at the same time, the first indoor heat exchanger (51) may be communicated to the first exhaust port (103), and the second indoor heat exchanger (52) may be communicated to the second exhaust port (104);

or, the first cylinder is provided with a first air suction port (101), the second cylinder is provided with a second air suction port (102), and the gas discharged by the first cylinder and the gas discharged by the second cylinder are mixed in the shell of the compressor and then discharged through a third air discharge port (106): the outdoor heat exchanger (3) is communicable to the third exhaust port (106), the first indoor heat exchanger (51) is communicable to the first suction port (101), and the second indoor heat exchanger (52) is communicable to the second suction port (102); or, the outdoor heat exchanger (3) can be communicated to the first suction port (101) and the second suction port (102) at the same time, the first indoor heat exchanger (51) can be communicated to the third discharge port (106), and the second indoor heat exchanger (52) can also be communicated to the third discharge port (106);

a first pipeline (12) communicated with the first indoor heat exchanger (51) and a second pipeline (13) communicated with the second indoor heat exchanger (52) are converged and then communicated to the outdoor heat exchanger (3) through a third pipeline (14), a first throttling device (41) is arranged on the first pipeline (12) or on the third pipeline (14), and a second throttling device (42) is arranged on the second pipeline (13);

the opening degree of the first throttling device (41) can be adjusted according to a first difference value between the temperature of the first indoor heat exchanger (51) and the preset temperature of the first indoor heat exchanger; the opening degree of the second throttling device (42) can be adjusted according to a second difference value between the second indoor heat exchanger temperature of the second indoor heat exchanger (52) and the preset second indoor heat exchanger temperature.

2. Dual temperature air conditioning system according to claim 1,

the adjustment amount of the opening degree adjustment of the first throttling device (41) is positively correlated with the first difference value; the adjustment amount of the opening degree adjustment of the second throttle device (42) is positively correlated with the second difference.

3. Dual temperature air conditioning system according to claim 1,

in the flowing direction of circulating airflow, the first indoor heat exchanger (51) and the second indoor heat exchanger (52) are respectively positioned at the upstream and the downstream of the circulating airflow, and when the dual-temperature air-conditioning system operates in a refrigerating mode, the preset temperature of the second indoor heat exchanger is determined according to the indoor environment temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is used for heating, the preset temperature of the second indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency.

4. A dual temperature air conditioning system as set forth in claim 3,

when the dual-temperature air conditioning system operates in a refrigerating mode, the temperature of the preset first indoor heat exchanger is determined according to the indoor environment temperature and the indoor relative humidity; and/or when the dual-temperature air conditioning system is in heating operation, the preset temperature of the first indoor heat exchanger is determined according to the indoor environment temperature and the compressor operation frequency; and/or when the air conditioner runs in a refrigerating mode, at the same detection moment, the temperature of the preset first indoor heat exchanger is higher than that of the preset second indoor heat exchanger.

5. Dual temperature air conditioning system according to any one of claims 1 to 4,

during cooling operation, the outdoor heat exchanger (3) is communicated with the first exhaust port (103) and the second exhaust port (104) at the same time, the first indoor heat exchanger (51) is communicated with the first suction port (101), and the second indoor heat exchanger (52) is communicated with the second suction port (102); when the air conditioner is operated for heating, the outdoor heat exchanger (3) is communicated to the first air suction port (101) and the second air suction port (102) at the same time, the first indoor heat exchanger (51) is communicated to the first exhaust port (103), and the second indoor heat exchanger (52) is communicated to the second exhaust port (104).

6. A dual temperature air conditioning system as set forth in claim 5, wherein:

the oil return device is arranged at the second exhaust port (104) and can return oil in the gas exhausted by the second exhaust port to the bottom of the inner cavity of the compressor (1);

the oil return device comprises an oil separator (6) and an oil return assembly, the second exhaust port (104) is communicated with the oil separator (6) through an exhaust pipeline, the bottom of the oil separator (6) is communicated to the bottom of an inner cavity of the compressor (1) through an oil return pipeline, and the oil return assembly comprises a first oil return control valve (7) arranged on the oil return pipeline; or,

the oil return device comprises an oil separator (6) and an oil return assembly, the second exhaust port (104) is communicated with the oil separator (6) through an exhaust pipeline, the bottom of the oil separator (6) is communicated to the bottom of an inner cavity of the compressor (1) through an oil return pipeline, the oil return assembly comprises a second oil return control valve (10) arranged on the oil return pipeline and a parallel pipeline connected with the second oil return control valve in parallel, and an oil return capillary tube (11) is arranged on the parallel pipeline.

7. A control method suitable for the dual temperature air conditioning system of any one of claims 1 to 6, comprising:

detecting the indoor environment temperature, the indoor relative humidity, the compressor running frequency, the first indoor heat exchanger temperature and the second indoor heat exchanger temperature;

acquiring an operation mode of a dual-temperature air conditioning system;

acquiring a preset first indoor heat exchanger temperature and a preset second indoor heat exchanger temperature according to the acquired operation mode;

comparing the obtained temperature of the first indoor heat exchanger with the preset temperature of the first indoor heat exchanger to obtain a first difference value, and comparing the obtained temperature of the second indoor heat exchanger with the preset temperature of the second indoor heat exchanger to obtain a second difference value;

and the opening degrees of the first throttling device (41) and the second throttling device (42) are respectively adjusted, the opening degree adjustment amount of the first throttling device (41) is positively correlated with the first difference value, and the opening degree adjustment amount of the second throttling device (42) is positively correlated with the second difference value.

8. The control method according to claim 7,

the operation modes comprise a cooling mode and a heating mode;

in the flowing direction of circulating airflow, the first indoor heat exchanger (51) and the second indoor heat exchanger (52) are respectively positioned at the upstream and the downstream of the circulating airflow, and when the operation mode is a cooling mode, the preset temperature of the second indoor heat exchanger is determined according to the acquired indoor environment temperature and the indoor relative humidity; and/or when the operation mode is the heating mode, the preset temperature of the second indoor heat exchanger is determined according to the acquired indoor environment temperature and the compressor operation frequency.

9. The control method according to claim 7,

the operation modes comprise a cooling mode and a heating mode;

in the flowing direction of circulating airflow, the first indoor heat exchanger (51) and the second indoor heat exchanger (52) are respectively positioned at the upstream and the downstream of the circulating airflow, and when the operation mode is a cooling mode, the preset first indoor heat exchanger temperature is determined according to the acquired indoor environment temperature and the indoor relative humidity; and/or when the operation mode is a heating mode, the preset temperature of the first indoor heat exchanger is determined according to the acquired indoor environment temperature and the compressor operation frequency.

10. An air conditioner characterized by comprising the dual temperature air conditioning system of any one of claims 1 to 6.

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