KR100255863B1 - Cooling system and its control method - Google Patents

Abstract

PURPOSE: A refrigeration system and method for controlling operation of refrigeration system is provided to achieve an improved cooling efficiency by maintaining constant amount of residual oil within the compressor and allowing cooling and lubrication operation of the compressor to be smoothly performed. CONSTITUTION: A refrigeration system comprises an oil separator(35) mounted between a compressor(30) and a condenser(31) and which returns the separated oil to the compressor; a return pipe(36) for guiding oil from the oil separator to the compressor; an oil tank(40) mounted at the return pipe for storage of oil; an open/shut-off valve(41) mounted between the oil tank and the compressor; a by-pass pipe(45) arranged at the refrigerant pipe connecting the oil tank, an evaporator(32) and the compressor; a motor-operated expansion valve(42) mounted at the by-pass pipe and which adjust pressure of the oil tank; an oil sensing unit(20) for sensing the amount of oil within the compressor; and a control unit for controlling operation of the open/shut-off valve in accordance with the signal output from the oil sensing unit.

Description

Refrigeration system and its control method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a refrigeration system and a control method thereof, and more particularly, to a refrigeration system and a control method thereof capable of smoothly cooling and lubricating a compressor by appropriately adjusting oil returned from an oil separator to a compressor.

In general, a refrigeration system that uses a refrigerant such as a refrigerator or an air conditioner to perform a cooling operation, as illustrated in FIG. 4, heat exchanges the refrigerant from the compressor 80 with a compressor 80 that compresses the refrigerant at a high temperature and high pressure. A refrigeration cycle consisting of the condenser 81 and the evaporator 82 for evaporating the refrigerant from the condenser 81 is formed, wherein a capillary tube 83 for expanding the refrigerant is formed between the condenser 81 and the evaporator 82. It is. The compressor 80, the condenser 81 and the evaporator 82 are interconnected by a refrigerant pipe.

As shown in FIG. 5, the compressor 80 includes a cylinder device 60 for compressing a refrigerant in the sealed casing 51 and a drive motor 55 for driving the cylinder device 60. The drive motor 55 includes a stator 52 in which a coil is wound, a rotor 53 accommodated in the stator 52 to rotate, and a rotor 53 that is press-fitted to the rotor 53 to rotate integrally with the rotor 53. It has a rotating shaft 54 to. On the other hand, inside the distal end of the rotating shaft 54, an oil supply piece 64 for supplying oil from the oil receiving portion 65 at the lower portion of the casing 51 between the rotor 53 and the rotating shaft 54 is installed. It is.

On the other hand, the cylinder device 60 includes a cylindrical cylinder 58 having a suction port on one side, an eccentric portion 61 accommodated in the cylinder 58 and the rotation shaft 54 is eccentrically formed, and an eccentric portion 61. It consists of a roller (59) for enclosing and contacting the inner wall of the cylinder (58) and compressing the refrigerant, and an upper flange (57) and a lower flange (56) for holding the cylinder (58). Here, a discharge port (not shown) for discharging a coolant is formed in one region of the upper flange 57, and a discharge muffler 70 covering the upper flange 57 is provided above the upper flange 57.

Power is applied to the hermetic rotary compressor 80, and when the rotor and the rotating shaft rotate, the refrigerant is compressed by the eccentric portion 61 and the roller 59, and the oil is moved upward from the oil receiving portion 65 of the lower portion. It is supplied to cool the heat generated during the rotational friction of each component and to smoothly drive. By the way, while the refrigerant is compressed in the cylinder 58, the oil supplied in the cylinder 58 is granulated by high pressure and discharged together with the high temperature refrigerant to the discharge port, and the refrigerant containing the oil is frozen through the discharge pipe. When introduced into the cycle, the overall efficiency of the refrigeration cycle is reduced, and due to the lack of oil in the compressor 80, the cooling and lubrication of the components in the compressor 80 may not be performed smoothly.

To remedy this problem, an oil separator 85 for filtering the oil mixed in the refrigerant is installed between the compressor 80 and the condenser 81, and the oil separator 85 and the compressor 80 return to each other. The pipe 86 was installed. By the way, the oil mixed in the refrigerant in the oil separator 85 is not separated all but part of the oil circulates again in the refrigeration cycle and remains on the refrigerant pipe in the refrigeration cycle. In particular, when employing an inverter motor capable of variable speed, the amount of refrigerant and the amount of oil flowing into the refrigeration cycle is different depending on the speed, so the degree of separation of the oil varies greatly depending on the speed. Therefore, the amount of oil in the compressor 80 gradually decreases, so that the cooling and lubrication of the compressor 80 is not performed smoothly, and thus the compressor 80 is damaged due to high heat.

Accordingly, it is necessary to keep the amount of oil in the compressor 80 constant so that the cooling and lubrication of the compressor 80 is desired to prevent damage to the compressor 80.

Accordingly, it is an object of the present invention to provide a refrigeration system and a method of controlling the same, which maintain a constant amount of oil in the compressor to facilitate cooling and lubrication of the compressor.

1 is a block diagram of a refrigeration system having a refrigeration cycle according to the present invention,

2 is a sectional view of a compressor according to the present invention;

3 is a control block diagram for controlling the refrigeration cycle of FIG.

4 is a block diagram of a refrigeration system having a conventional refrigeration cycle,

5 is a cross-sectional view of a conventional compressor.

<Description of the symbols for the main parts of the drawings>

5: drive motor 10: cylinder device

13 control unit 15 oil receiving unit

20: oil detection device 21: plotter

22: plotter detection sensor 23: detection tube

30 compressor 35 oil separator

36: return piping 37: return capillary

40: oil tank 41: on-off valve

42: electric expansion valve 45: bypass piping

The object of the present invention is a refrigeration system having a compressor, a condenser and an evaporator for exchanging a refrigerant from the compressor, wherein the oil separator provided between the compressor and the condenser returns oil separated to the compressor. A return pipe for guiding oil from the oil separator to the compressor, an oil tank provided on the return pipe to store the oil, an on / off valve provided between the oil tank and the compressor, and It is achieved by a refrigeration system, characterized in that it has an oil detecting unit for detecting the amount of oil, and a control unit for controlling the opening and closing the opening and closing valve in accordance with the detection signal from the oil detecting unit.

Here, it is preferable that a capillary tube is formed between the oil separator and the compressor to relax the oil return speed. Meanwhile, a bypass pipe is installed between the oil tank and the refrigerant pipe connecting the evaporator and the compressor, and a pressure control valve for adjusting the pressure of the oil tank is installed on the bypass pipe to be introduced into the compressor. The amount of oil can be adjusted.

The oil detection unit may include a tubular sensing tube connected to an upper end portion of the compressor and a lower oil storage portion storing oil, a floater flowing in the sensing tube, and a floater sensing sensor sensing the flow of the floater. It is preferable to include. The controller may open the on / off valve and adjust the opening of the pressure regulating valve according to the position of the plotter when the plotter is lowered below a predetermined range from the plotter detection sensor.

On the other hand, according to another field of the present invention, the object of the refrigeration system having a compressor, a condenser and an evaporator for heat exchange the refrigerant from the compressor, and an oil separator provided between the compressor and the condenser to separate the oil A control method comprising the steps of: providing an oil tank for storing oil between the oil separator and the compressor, guiding oil from the oil separator to the oil tank, and detecting the amount of oil in the compressor And, it may be achieved by the control method of the refrigeration system comprising the step of introducing the oil from the oil tank to the compressor in accordance with the detected value of the oil amount.

The detecting of the amount of oil may include providing a sensing tube connecting the upper and lower oil receptacles of the compressor, a floater lifting and lowering according to the amount of oil in the sensing tube, and a sensing sensor sensing the plotter in the sensing tube. It is preferable to include the step of providing. The supplying of the oil may include opening the oil tank when the plotter is lowered below a predetermined range.

Hereinafter, the present invention will be described in detail with reference to the drawings.

1 is a block diagram of a refrigeration system having a refrigeration cycle according to the present invention. As shown, the refrigeration cycle is a circulation formed by the compressor (30) for compressing the refrigerant to a high temperature and high pressure, the condenser 31 and the evaporator (32) for heat exchange the refrigerant from the compressor (30) are interconnected by the refrigerant pipe It's a loop.

Here, the compressor 30, as shown in Figure 2, the cylinder device 10 for compressing the refrigerant at a high temperature and high pressure in the sealed casing 1, and the drive motor 5 for driving the cylinder device 10. Consisting of, the lower portion in the casing (1) is formed with an oil receiving portion (15) for receiving oil. When the compressor 30 is driven to compress the refrigerant, oil remaining in the cylinder device 10 is granulated by high pressure when the refrigerant is compressed for lubrication and cooling of the cylinder device, and flows into the refrigeration cycle together with the refrigerant. do. Accordingly, the compressor 30 is provided with an oil detecting device 20 to detect the amount of oil remaining in the compressor 30.

The oil detecting device 20 includes a tubular sensing tube 23 connecting the upper portion of the casing 1 in which the refrigerant is present and the lower portion of the casing 1 in which the oil receiving portion 15 is formed, and the sensing tube 23. It includes a plotter 21 for lifting and lowering in the inside, and a plotter sensor 22 for sensing the flow of the plotter 21. Here, the coolant is present in the upper portion and the oil is present in the lower portion of the sensing tube 23, the floater 21 is floating on the oil is raised and lowered according to the increase and decrease of the oil. In addition, the plotter detection sensor 22 detects the lift of the plotter 21 within an appropriate range necessary for cooling and lubricating the compressor 30.

On the other hand, the oil separator 35 is installed between the compressor 30 and the condenser 31 in order to separate the oil mixed in the refrigerant and flows into the refrigeration cycle on the refrigeration cycle, the oil separator 35 and the compressor 30. Between the return pipe 36 for the return of the oil is further formed. In addition, an oil tank 40 for storing oil recovered from the oil separator 35 is installed on the return pipe 36, and the oil from the oil separator 35 is separated between the oil separator 35 and the oil tank 40. A return capillary tube 37 is provided to reduce the return speed of the oil returning to the tank 40. On the other hand, between the oil tank 40 and the compressor 30 is provided with an opening and closing valve 41 for opening and closing the oil tank 40, the compressor into which the refrigerant from the oil tank 40 and the evaporator (32) ( The inlet pipe 30 is interconnected by a bypass pipe 45. On the bypass pipe 45, an electric expansion valve 42 capable of adjusting the opening degree is installed to adjust the pressure in the oil tank 40 according to the opening degree. When the opening degree of this electric expansion valve 42 is made large, the refrigerant | coolant from the evaporator 32 flows into the oil tank 40, and the pressure in the oil tank 40 will rise. Accordingly, the amount of oil flowing into the compressor 30 is increased.

3 is a control block diagram for controlling the refrigeration system. The control unit 13 receives signals from the power supply unit 9, the external operation panel unit 12, and the plotter detection sensor 22, and the compressor driving circuit 50 and the open / close valve based on the input signals. The signal is output to the drive circuit 46 and the motor expansion valve drive circuit 42. Accordingly, when the power is applied and the operation signal of the device is input, the control unit 13 drives the compressor 30 to compress the refrigerant, according to the flow of the plotter 21 detected from the plotter detection sensor 22. The on-off valve 41 is turned on and off and the opening degree of the electric expansion valve 42 is adjusted.

When power is supplied to the refrigeration system and the operation signal is input, the control unit 13 drives the compressor 30. The refrigerant mixed with oil while being compressed at a high temperature and high pressure in the compressor 30 flows out into the refrigeration cycle and is filtered by the oil separator 35. The oil separated from the refrigerant in the oil separator 35 is returned to the oil tank 40 along the return pipe 36. At this time, the amount of oil returned by the return capillary tube 37 becomes substantially constant.

On the other hand, the control unit 13 receives the detection signal from the plotter detection sensor 22, and when the oil amount in the compressor 30 is reduced from the plotter detection sensor 22 to a predetermined level or less, the on-off valve 41 and the electric expansion valve (42) is opened. At this time, the control unit 13 may divide the amount of oil from the plotter sensor 22 into a plurality of stages so as to adjust the opening degree of the electric expansion valve 42 according to each stage, and continuously according to the amount of oil The opening degree of the electric expansion valve 42 may be adjusted. When the on-off valve 41 and the electric expansion valve 42 are opened, the inflow rate of oil flowing into the compressor 30 is determined according to the opening degree of the electric expansion valve 42. When the oil flows in and the floater rises, the control unit 13 closes the on / off valve 41 and the electric expansion valve 42 when it detects that a predetermined amount or more of oil flows from the plotter detection sensor 22.

Thus, the oil tank 40, the opening-closing valve 41, and the electric expansion valve 42 are provided on the return pipe 36 in which the refrigerant on the refrigerating cycle is returned, and the compressor 30 has oil in the compressor 30. By providing an oil detecting device 20 capable of detecting the remaining amount, it is possible to always have a certain amount of oil in the compressor (30).

As described above, according to the present invention, by maintaining a constant oil residual amount in the compressor, it is possible to smooth the cooling and lubrication of the compressor to improve the overall cooling efficiency of the refrigeration system.

Claims (6)

A refrigeration system comprising a compressor, a condenser and an evaporator for exchanging heat from a refrigerant from the compressor, An oil separator installed between the compressor and the condenser to return the separated oil to the compressor; A return pipe for guiding oil from the oil separator to the compressor; An oil tank installed on the return pipe to store the oil; An on / off valve installed between the oil tank and the compressor; A bypass pipe installed between the oil tank and the refrigerant pipe connecting the evaporator and the compressor; A pressure control valve installed on the bypass pipe for controlling pressure of the oil tank; An oil detecting unit for detecting an amount of oil in the compressor; And a control unit for controlling the opening / closing valve according to the detection signal from the oil detecting unit. The method of claim 1, Refrigerating system, characterized in that the capillary is formed between the oil separator and the compressor to reduce the return speed of the oil. The method of claim 1, The oil detecting unit includes a tubular sensing tube connected to the upper end of the compressor and an oil storage unit at the bottom storing oil, a floater flowing in the sensing tube, and a plotter detecting sensor sensing the flow of the plotter. ; The control unit, the refrigeration system, characterized in that when the plotter is lowered below the predetermined range from the plotter detection sensor, opening and closing the valve, and adjusts the opening of the pressure control valve according to the position of the plotter. A control method of a refrigeration system having a compressor, a condenser and an evaporator for exchanging a refrigerant from the compressor, and an oil separator provided between the compressor and the condenser to separate oil, Providing an oil tank for storing oil between the oil separator and the compressor; Guiding oil from the oil separator to the oil tank; Detecting the amount of oil in the compressor; And introducing the oil from the oil tank into the compressor according to the detected value of the oil amount. The method of claim 4, wherein The detecting of the amount of oil may include providing a sensing tube connecting the upper and lower oil receptacles of the compressor, a floater lifting and lowering according to the amount of oil in the sensing tube, and a sensing sensor sensing the plotter in the sensing tube. The control method of the refrigeration system comprising the step of providing. The method of claim 4, wherein The supplying of oil may include opening the oil tank when the plotter is lowered below a predetermined range.

Images