WO2016115925A1

WO2016115925A1 - Reversible direct-cooling system, refrigerator and refrigeration control method

Info

Publication number: WO2016115925A1
Application number: PCT/CN2015/091097
Authority: WO
Inventors: 张奎; 刘建如; 吴贤栋
Original assignee: 青岛海尔股份有限公司; 青岛海尔电冰箱有限公司
Priority date: 2015-01-23
Filing date: 2015-09-29
Publication date: 2016-07-28
Also published as: CN104654646A; CN104654646B

Abstract

A reversible direct-cooling system (100'), a refrigerator and a refrigeration control method. The reversible direct-cooling system (100') comprises a compressor (1), a condenser (2), a dry filter (3), throttling devices (41, 42), evaporators (5, 6), a return air pipe (7) and a four-way valve (8). The evaporators (5, 6) comprise a refrigerating evaporator (5) and a freezing evaporator (6) arranged in series. The four-way valve (8) comprises a first port (A) connected to the throttling devices (41, 42), a second port (B) connected to the refrigerating evaporator (5), a third port (C) connected to the freezing evaporator (6), and a fourth port (D) connected to the return air pipe (7). By the use of the reversible direct cooling system (100') with this construction and the refrigeration control method, the area matching problem of the evaporator of the refrigerator under different ambient temperatures can be solved, with the effects of saving energy and reducing consumption, and meanwhile the manufacturing cost can be reduced.

Description

Reversible direct cooling system, refrigerator and refrigeration control method

This application claims the priority of the Chinese patent application entitled "Reversible Direct Cooling System, Refrigerator and Refrigeration Control Method" on January 23, 2015, application number 201510037173.5, the entire contents of which are incorporated herein by reference. In the application.

Technical field

The invention relates to the technical field of refrigerators, in particular to a reversible direct cooling system, a refrigerator and a refrigeration control method.

Background technique

The evaporator area of the existing single-system direct-cooling refrigerator is fixed, and the refrigerant flow direction of the refrigerator refrigeration system is also fixed. When the ambient temperature is lower than 10 °C, the heat load of the refrigerator compartment is reduced. At this time, the refrigerant flow rate is too large, and the evaporator area is also too large, thereby causing additional energy consumption; likewise, in the environment. When the temperature is high, the heat load of the refrigerating compartment of the refrigerator increases, and the required cooling capacity is large. At this time, the refrigerant flow rate is small, and the evaporator area is also small, which causes the compressor starting frequency to increase and the energy consumption to increase.

Nowadays, in order to solve the problem of matching the refrigeration system of the refrigerator with the environment, the method is to set the pipeline in parallel with the evaporator, and the refrigeration medium is controlled by the solenoid valve to complete the cycle through different paths, as disclosed in Chinese patent CN202928252U. A refrigeration circuit technical solution for setting a sub-evaporator and a through-line parallel to the sub-evaporator. However, the above technical solution needs to increase the length of the evaporator pipe, and the manufacturing cost increases.

Therefore, it is necessary to provide a new reversible direct cooling system, refrigerator and refrigeration control method.

Summary of the invention

The object of the present invention is to provide a reversible direct cooling system, a refrigerator and a refrigeration control method, which can solve the problem of matching the evaporator area under different ambient temperatures of the refrigerator, and have the effect of energy saving and consumption reduction, and at the same time reduce the refrigerating compared with the prior art scheme. Evaporator area reduces manufacturing costs.

In order to achieve the above object, the present invention provides a reversible direct cooling system including a press, a condenser, a drying filter, a throttling device, an evaporator, and a return air pipe, and the reversible direct cooling system further includes a four-way valve. The evaporator includes a refrigerating evaporator and a refrigerating evaporator arranged in series, the four-way valve including a first port connecting the throttling device, a second port connecting the refrigerating evaporator, and a connection to the refrigerating evaporator a third port and a fourth port connected to the air return pipe, wherein the fourth port is in communication with the third port when the first port is in communication with the second port; and when the first port is connected to the third port The fourth port is in communication with the second port.

As a further improvement of the present invention, the reversible direct cooling system further includes a three-way valve connected to the drying filter, the throttling device being a first capillary and a second capillary disposed in parallel and having different flow rates. The two outlets of the three-way valve are respectively connected to the first capillary and the second capillary, and the first capillary and the second capillary are both connected to the first port of the four-way valve.

The present invention also provides a refrigerator including a refrigerating compartment and a freezing compartment, the refrigerator further comprising the above-mentioned refrigerator compartment And a reversible direct cooling system for cooling in the freezer compartment.

The invention also provides a refrigeration control method for a reversible direct cooling system, the reversible direct cooling system further comprising an ambient temperature sensor for detecting an ambient temperature T _e .

The control method includes detecting an ambient temperature T _e and comparing the ambient temperature T _e with a first preset temperature T1;

When T _e ≥ T1, the first port is in communication with the second port, the fourth port is in communication with the third port, and the refrigerant flows from the refrigerating evaporator to the freezing evaporator;

When T _e <T1, the first port is in communication with the third port, the fourth port is in communication with the second port, and refrigerant flows from the freezing evaporator to the refrigerating evaporator.

The present invention also provides a refrigeration control method for another reversible direct cooling system, wherein the throttling device is two capillary tubes having different flow rates disposed in parallel, and the flow rate of the first capillary tube is greater than the flow rate of the second capillary tube. The reversible direct cooling system also includes an ambient temperature sensor for detecting the ambient temperature T _e .

The control method includes detecting an ambient temperature T _e and comparing the ambient temperature T _e with a second preset temperature T2, a third preset temperature T3, and a fourth preset temperature T4 (T2<T3<T4);

When T _e <T2, the three-way valve controls the first capillary to be closed, and the second capillary is connected; meanwhile, the first port is in communication with the third port, and the fourth port is in communication with the second port, cooling a reagent flowing from the freezing evaporator to the refrigerating evaporator;

When T2≤T _e <T3, the three-way valve controls the first capillary to be closed, and the second capillary is connected; meanwhile, the first port is in communication with the second port, and the fourth port is in communication with the third port a refrigerant flowing from the refrigerating evaporator to the refrigerating evaporator;

When T3≤T _e <T4, the three-way valve controls the second capillary to be closed, the first capillary is in communication, and at the same time, the first port is in communication with the third port, and the fourth port is in communication with the second port Refrigerating agent flows from the freezing evaporator to the refrigerating evaporator;

When T _e ≥ T4, the three-way valve controls the second capillary to be closed, the first capillary is in communication, and at the same time, the first port is in communication with the second port, and the fourth port is in communication with the third port, cooling The agent flows from the refrigerated evaporator to the refrigerating evaporator.

The invention has the beneficial effects that the reversible direct cooling system, the refrigerator and the refrigeration control method provided by the invention can solve the problem of matching the evaporator area of the refrigerator under different ambient temperatures, and has the effect of energy saving and consumption reduction, and at the same time compared with the existing The technical solution reduces the area of the refrigerated evaporator and reduces the manufacturing cost.

DRAWINGS

1 is a schematic view showing the basic structure of a reversible direct cooling system of the present invention;

2 is a schematic structural view of another preferred embodiment of the reversible direct cooling system of the present invention.

detailed description

The invention will be described in detail below with reference to the embodiments shown in the drawings. However, the embodiment does not limit the present invention, and the structure, method, or functional transformation made by those skilled in the art according to the embodiment is included in the present invention. Within the scope of protection.

FIG. 1 is a schematic diagram showing the basic structure of a reversible direct cooling system 100 according to the present invention. The reversible direct cooling system 100 comprises a press 1, a condenser 2, a drying filter 3, a throttling device 4, a refrigerated evaporator 5 arranged in series, a refrigerating evaporator 6, a return air pipe 7, and a corresponding pipeline. The phases are connected to form a closed refrigerant circuit.

The reversible direct cooling system 100 further includes a four-way valve 8 including a first port A connecting the throttling device 4, a second port B connecting the refrigerating evaporator 5, and a connection station The third port C of the freezing evaporator 6 and the fourth port D connecting the return air pipe 7 are described. When the first port A is connected to the second port B, the fourth port D is in communication with the third port C; when the first port A is connected to the third port C, the fourth port D is The second port B is in communication, and the first port A and the fourth port D of the four-way valve 8 are not in direct communication.

The present invention also provides a refrigeration control method for the above-described reversible direct cooling system 100, the reversible direct cooling system 100 further comprising an ambient temperature sensor for detecting the ambient temperature T _e .

When T _e ≥ T1, the first port A is in communication with the second port B, the fourth port D is in communication with the third port C, and the refrigerant flows from the refrigerating evaporator 5 to the freezing evaporator 6;

When T _e <T1, the first port A communicates with the third port C, the fourth port D communicates with the second port B, and the refrigerant flows from the freezing evaporator 6 to the refrigerating evaporator 5.

That is, when the ambient temperature T _{e is} low, the heat load of the refrigerating evaporator 5 is small, and the refrigerant is controlled by the four-way valve 8 to flow from the refrigerating evaporator 6 to the refrigerating evaporator 5 to improve freezing during the refrigeration cycle. The refrigeration efficiency of the evaporator 6; similarly, when the ambient temperature T _{e is} high, the heat load of the refrigerating evaporator 5 is increased, and the required cooling amount is required to be large, and the refrigerant is controlled from the refrigerating evaporation by the four-way valve 8 The flow of the device 5 to the refrigerating evaporator 6 reduces the frequency of starting the reversible direct cooling system and effectively reduces energy consumption.

As shown in FIG. 2, another embodiment of the present invention, the reversible direct cooling system 100' further includes a three-way valve 9 connected to the drying filter 3. The throttling device 4 is a first capillary 41 and a second capillary 42 which are disposed in parallel and have different flow rates, and the flow rate of the first capillary 41 is greater than the flow rate of the second capillary 42. The two outlets of the three-way valve 9 are respectively connected to the first capillary 41 and the second capillary 42 , and the first capillary 41 and the second capillary 42 are both connected to the first port of the four-way valve 8 A. Obviously, when the ambient temperature is high, the refrigerant is controlled to circulate through the first capillary 41 through the three-way valve 9; when the ambient temperature is low, the refrigerant is controlled by the three-way valve 9 to pass through the second capillary 42 Loop.

The present invention also provides a refrigeration control method for the reversible direct cooling system 100' of the above another embodiment, the reversible direct cooling system 100' further comprising an ambient temperature sensor for detecting the ambient temperature T _e .

When T _e <T2, the three-way valve 9 controls the first capillary 41 to be closed, and the second capillary 42 to communicate; meanwhile, the first port A is in communication with the third port C, and the fourth port D is The second port B is connected, the refrigerant flows from the freezing evaporator 6 to the refrigerating evaporator 5;

When T2 ≤ T _e < T3, the three-way valve 9 controls the first capillary 41 to be closed, and the second capillary 42 is in communication; meanwhile, the first port A is in communication with the second port B, and the fourth port D is in communication with the third port C, the refrigerant flows from the refrigerated evaporator 5 to the freezing evaporator 6;

When T3≤T _e <T4, the three-way valve 9 controls the second capillary 42 to be closed, and the first capillary 41 is in communication; meanwhile, the first port A is in communication with the third port C, and the fourth port D is in communication with the second port B, the refrigerant flows from the freezing evaporator 6 to the refrigerating evaporator 5;

When T _e ≥ T4, the three-way valve 9 controls the second capillary 42 to be closed, the first capillary 41 is in communication, and at the same time, the first port A is in communication with the second port B, and the fourth port D is The third port C is in communication, and the refrigerant flows from the refrigerating evaporator 5 to the refrigerating evaporator 6.

The second preset temperature T2 is set to 5 to 15 ° C; the third preset temperature T3 is set to 15 to 30 ° C; and the fourth preset temperature T4 is set to 30 to 40 ° C. According to the difference of the ambient temperature T _e , the refrigeration cycle mode of the reversible direct cooling system 100 ′ is manually or automatically switched to achieve better matching between the evaporator and the ambient temperature T _e , thereby achieving the effect of energy saving and consumption reduction. At the same time, compared with the existing direct cooling system, the area of the refrigerating evaporator 5 can be reduced by 20-30%, which effectively reduces material and manufacturing costs.

The present invention also provides a refrigerator including a refrigerating compartment and a freezing compartment, the refrigerator further comprising a reversible direct cooling system 100 (100') for cooling the refrigerating compartment and the freezing compartment.

In summary, the reversible direct cooling system 100 (100'), the refrigerator and the refrigeration control method provided by the invention can solve the problem of matching the evaporator area under different environmental temperatures T _e of the refrigerator, and have the effects of energy saving and consumption reduction. At the same time, the area of the refrigerating evaporator 5 is reduced compared with the prior art solution, and the manufacturing cost is reduced.

It should be understood that, although the description is described in terms of embodiments, the embodiments are not intended to be construed as a single. The technical solutions in the embodiments may also be combined as appropriate to form other embodiments that can be understood by those skilled in the art.

The series of detailed descriptions set forth above are merely illustrative of the possible embodiments of the present invention, and are not intended to limit the scope of the present invention. Changes are intended to be included within the scope of the invention.

Claims

A reversible direct cooling system comprising a press, a condenser, a drying filter, a throttling device, an evaporator and a return air pipe, wherein the reversible direct cooling system further comprises a four-way valve, the evaporator comprising a refrigerating evaporator and a refrigerating evaporator arranged in series, the four-way valve including a first port connecting the throttling device, a second port connecting the refrigerating evaporator, a third port connecting the refrigerating evaporator, and a fourth port connected to the air return pipe, wherein the fourth port is in communication with the third port when the first port is in communication with the second port; and when the first port is connected to the third port, The four ports are in communication with the second port.
The reversible direct cooling system according to claim 1, wherein said reversible direct cooling system further comprises a three-way valve connected to said drying filter, said throttling devices being arranged in parallel and having different flows a first capillary and a second capillary, wherein the two outlets of the three-way valve are respectively connected to the first capillary and the second capillary, and the first capillary and the second capillary are both connected to the fourth valve One port.
A refrigerator comprising a refrigerating compartment and a freezing compartment, characterized in that the refrigerator comprises the reversible direct cooling system for cooling the refrigerating compartment and the freezing compartment according to any one of claims 1-2.
A refrigeration control method for a reversible direct cooling system according to claim 1, wherein said reversible direct cooling system further comprises an ambient temperature sensor for detecting an ambient temperature T e ,

The control method includes detecting an ambient temperature T e and comparing the ambient temperature T e with a first preset temperature T1;

When T e ≥ T1, the first port is in communication with the second port, the fourth port is in communication with the third port, and the refrigerant flows from the refrigerating evaporator to the freezing evaporator;

When T e <T1, the first port is in communication with the third port, the fourth port is in communication with the second port, and refrigerant flows from the freezing evaporator to the refrigerating evaporator.
A refrigeration control method for a reversible direct cooling system according to claim 2, wherein: the flow rate of said first capillary is greater than the flow rate of said second capillary, said reversible direct cooling system further comprising detecting ambient temperature T e ambient temperature sensor,

The control method includes detecting an ambient temperature T e and comparing the ambient temperature T e with a second preset temperature T2, a third preset temperature T3, and a fourth preset temperature T4 (T2<T3<T4);

When T e <T2, the three-way valve controls the first capillary to be closed, and the second capillary is connected; meanwhile, the first port is in communication with the third port, and the fourth port is in communication with the second port, cooling a reagent flowing from the freezing evaporator to the refrigerating evaporator;

When T2≤T e <T3, the three-way valve controls the first capillary to be closed, and the second capillary is connected; meanwhile, the first port is in communication with the second port, and the fourth port is in communication with the third port a refrigerant flowing from the refrigerating evaporator to the refrigerating evaporator;

When T3≤T e <T4, the three-way valve controls the second capillary to be closed, the first capillary is in communication, and at the same time, the first port is in communication with the third port, and the fourth port is in communication with the second port Refrigerating agent flows from the freezing evaporator to the refrigerating evaporator;

When T e ≥ T4, the three-way valve controls the second capillary to be closed, the first capillary is in communication, and at the same time, the first port is in communication with the second port, and the fourth port is in communication with the third port, cooling The agent flows from the refrigerated evaporator to the refrigerating evaporator.