KR100592955B1 - Refrigerating system and control method for the same - Google Patents

Abstract

The present invention relates to a refrigeration system having a plurality of compressors that can flexibly respond to the refrigeration load.

The refrigeration system according to the present invention is a plurality of compressors for compressing the refrigerant, and each is installed in the plurality of compressors to guide the oil to be discharged to the outside, and disposed in the middle of the plurality of fungal oil pipes, respectively It includes a plurality of discharge valves to open and close, and a plurality of temperature sensors for measuring the temperature of a plurality of funnels, respectively, by using a temperature sensor to determine the oil level of the oil by measuring the temperature change over a certain unit time of each Accordingly, since it is possible to supply the oversupply oil back to a plurality of compressors, there is an effect that each compressor can maintain the oil level of the optimized oil irrespective of its capacity.

Description

REFRIGERATING SYSTEM AND CONTROL METHOD FOR THE SAME}

1 is a schematic view showing a refrigeration system according to the present invention.

2 is a flow chart showing a control method of a refrigeration system according to the present invention.

Explanation of symbols on the main parts of the drawings

1: compressor 2: condenser

3: inflator 4: evaporator

5: individual discharge pipe 5a: common discharge pipe

6: individual suction pipe 6a: common suction pipe

8: accumulator 9: fungus

9a: discharge valve 9b: temperature sensor

10: bypass tube 11: control unit

The present invention relates to a refrigeration system, and more particularly, to a refrigeration system having a plurality of compressors to be able to flexibly respond to the refrigeration load by changing the number of compressors operating in accordance with the required refrigeration load.

Generally, a refrigeration system is applied to a building's air conditioning system, a compressor for compressing a refrigerant, a condenser for allowing a high temperature and high pressure refrigerant compressed in the compressor to exchange heat with air, and an expansion device for decompressing and expanding the cooled refrigerant; Refrigeration cycle components such as an evaporator that allows the refrigerant to evaporate and heat exchange with air.

Recently, among such refrigeration systems, there is a refrigeration system including a plurality of compressors to flexibly respond to the refrigeration load by controlling some or all of the compressors to operate according to the refrigeration load.

In each compressor applied to such a refrigeration system, oil is contained in the lower part for lubrication and cooling of each driving unit, and in order to distribute the oil evenly to the plurality of compressors, a homogeneous oil pipe is provided at the lower part of the compressor. It was installed to deliver oil to neighboring compressors or to receive oil from neighboring compressors, so that the oil level of the two compressors was maintained to be uniform.

However, if the two compressors applied to the refrigeration system have different capacities and there is a difference in the internal pressure, the compressor compresses the refrigerant at a relatively low pressure in a compressor that compresses the refrigerant at a relatively high pressure regardless of the oil level. Since the compressor flows to the compressor side, there is a problem that oil is insufficient in the compressor compressing the refrigerant at a relatively high pressure, and oil is excessively supplied to the compressor compressing the refrigerant at a relatively low pressure.

The present invention is to solve such a problem, it is an object of the present invention to provide a refrigeration system in which oil can be supplied evenly distributed to a plurality of compressors.

The present invention for achieving the above object, in the refrigeration system including a plurality of compressors for compressing the refrigerant, the plurality of compressors to guide the oil to be discharged to the outside when the height of the oil level contained therein is above a certain A plurality of fungal milk pipes are respectively installed, and a plurality of discharge valves respectively opening and closing the fungal milk pipes and a plurality of temperature sensors respectively measuring the temperatures of the plurality of fungal milk pipes are disposed in the middle of the plurality of fungal milk pipes. It is characterized by being.

In addition, the plurality of fungal oil pipes are connected to a common suction pipe for guiding the refrigerant sucked into the plurality of compressors are connected to each bypass pipe for bypassing the oil discharged from the compressor to the common suction pipe through the fungal oil pipe. It is done.

In addition, the temperature sensor is characterized in that it is disposed in the tube between the compressor and the discharge valve to measure the temperature of the tube between the compressor and the discharge valve.

In addition, the refrigeration system control method according to the present invention, a plurality of compressors for compressing the refrigerant, a plurality of bacteria oil pipes respectively installed in the plurality of compressors to guide the oil to be discharged to the outside, and the plurality of bacteria oil pipes A refrigeration system including a plurality of discharge valves disposed in the middle of the cells to open and close the cells, respectively, and a plurality of temperature sensors for measuring the temperatures of the cells, respectively, Each of the plurality of discharge valves is individually opened to detect a temperature and discharge oil according to the detected temperature.

The discharge valve may be opened when the amount of change during the predetermined unit time of the detected temperature is greater than a predetermined temperature change amount.

Hereinafter, one preferred embodiment of the present invention will be described in detail with reference to the drawings.

As shown in FIG. 1, the refrigeration system according to the present invention includes a plurality of compressors 1 for compressing a refrigerant at high temperature and high pressure, a condenser 2 for exchanging refrigerant with heat exchange with air, and a refrigerant under reduced pressure expansion. Expansion device 3, such as an electronic expansion discharge valve, and a refrigeration cycle component, such as an evaporator 4, in which a refrigerant exchanges heat with air and is evaporated, and each component is connected through a refrigerant pipe to form a closed circuit. .

At this time, the refrigerant pipe is a plurality of individual discharge pipe (5) for guiding each of the refrigerant discharged from each compressor individually, each of the individual discharge pipe (5) is connected and discharged through each individual discharge pipe (5) It includes a common discharge pipe (5a) for collecting the refrigerant to be delivered to the condenser, all from the common suction pipe (6a) and the common suction pipe (6a) for guiding the refrigerant delivered from the condenser (2) to the plurality of compressor (1) side It includes a separate suction pipe (6) and the like branched to deliver the refrigerant to each compressor (1) individually.

In addition, the refrigeration system is provided with an oil separator (7) to separate the oil discharged with the refrigerant from the plurality of compressors (1) in the middle of the common discharge pipe (5a), the middle of each individual suction pipe (6) Accumulators 8 are respectively provided to prevent liquid refrigerant from being sucked into each compressor 1.

Between the oil separator 7 and the common suction pipe 6a, one end is connected to the lower part of the oil separator 7 and the other end is connected to the common suction pipe 6a so that the oil separated from the oil separator 7 is the common suction pipe 6a. An oil return tube 7a is installed to allow the compressor 1 to be distributed and supplied to each compressor 1. An oil return tube 7a increases the flow resistance of the oil return tube 7a in the middle of the oil return tube 7a. A first capillary tube 7b is provided for controlling the flow rate of the oil flowing through 7a).

The refrigeration system according to the present invention is to maintain the oil level of the oil contained in each compressor (1) below a certain level so that the appropriate amount of oil can be distributed and supplied to the plurality of compressors (1), for each compressor In the lower part of (1), each of the fungal oil pipes 9 is installed so that the excess oil supplied to the compressor 1 can be discharged. In the middle of each of the fungal milk pipes 9, the fungal oil pipes 9 are arranged according to the oil level of the oil. Are respectively provided with a discharge valve 9a for opening oil) so that oil can be discharged from the compressor 1.

At this time, each of these bacteria oil pipe (9) so that the oil discharged from the compressor (1) through the bacteria oil pipe (9) can be bypassed to the common suction pipe (6a) again distributed to a plurality of compressors (1) In order to be connected to the bypass pipe 10 is connected to the common suction pipe (6a), respectively, each of the fungal oil pipe (9) to increase the flow resistance of the fungal oil pipe (9) downstream of the discharge valve (9a) The second capillary tube (9c) is arranged so that the flow rate of the oil through the fungal oil tube (9) can be adjusted.

In addition, in order to maintain the oil level of the oil inside each compressor (1) or less, it is necessary to control the discharge valve (9a) for opening the fluid oil pipe (9), for the control of such a discharge valve (9a) A temperature sensor 9b for measuring the temperature of the bacteria oil pipe 9 to detect the oil level of the oil is disposed in the bacteria oil pipe 9 between 1) and the discharge valve 9a, and each temperature sensor ( The control part 11 which controls each discharge valve 9a individually according to the temperature measured by 9b) is provided.

The temperature sensor 9b has a difference in the heat capacity of the refrigerant of gas and the liquid of oil, so that the temperature of the refrigerant of the gas is changed in a relatively wider range than that of the liquid of oil. The control unit 11 can determine the type. That is, when the temperature change amount is larger than the temperature change amount set in the controller 11 by measuring the temperature of the bacteria oil pipe 9 at a predetermined unit time through the temperature sensor 9b, the controller 11 may be the bacteria oil pipe 9. It is determined that the material filled in the gas is a refrigerant in a gaseous state, and the oil level of the oil contained in the compressor 1 is below an appropriate level, and when the temperature change amount is smaller than the temperature change amount set in the control unit 11, the control unit 11 ) Identifies that the substance filled in the fungal oil tube 9 is oil in a liquid state, so that the oil level of the oil contained in the compressor 1 is determined to be higher than an appropriate level.

The following describes the control method of the refrigeration system configured as described above.

In the control method of the refrigeration system according to the present invention, as shown in FIG. 2, the temperature sensor 9b periodically measures the temperature of the fungal milk tube 9 at a predetermined unit time (100), and then the constant temperature is measured. The temperature change amount T during the unit time is calculated (110). The temperature change amount T _Ref , which is calculated by comparing the calculated temperature change amount T and the temperature change amount T _Ref . Set in the control unit 120 and calculated 120, is set in the control unit 11. _In the case of larger than _. ), This means that the material filled in the fungal oil conduit 9 is a gaseous refrigerant, so that the control unit 11 controls the discharge valve 9a to keep the condensed milk conduit 9 closed. do. On the contrary, if the calculated temperature change amount T is less than the temperature change amount T _Ref. Set in the control unit 11, this means that the substance filled in the oil mixture tube 9 is a refrigerant in a liquid state. 11, the discharge valve (9a) is controlled to open the fungal oil pipe (9) 130, the oil is discharged through the fungal oil pipe (9). Subsequently, the discharged oil is delivered to the common suction pipe 6a through the bypass pipe 10 and again distributedly supplied to the plurality of compressors 1.

Therefore, each of the compressors 1 discharges the oversupplied oil through the funnel oil pipe 9 regardless of the capacity and the internal pressure, and the discharged oil is dispersed in the plurality of compressors 1 again. As each compressor is supplied, each compressor 1 maintains a proper oil level.

As described above in detail, the refrigerating system according to the present invention determines the oil level of the oil by measuring the temperature change for a predetermined unit time of each of the fungal oil pipes installed in the plurality of compressors with a temperature sensor, and accordingly excess in the compressor Since the supplied oil can be distributed and supplied again to a plurality of compressors, there is an effect that each compressor can maintain the oil level of the optimized oil irrespective of its capacity.

Claims (5)

In a refrigeration system comprising a plurality of compressors for compressing a refrigerant, The plurality of compressors are each provided with a plurality of fungal oil pipes for guiding oil to be discharged to the outside when the height of the oil level contained therein is above a certain level, each of the plurality of fungal milk pipes to open and close the fungal milk pipes, respectively A plurality of discharge valves and a plurality of temperature sensors for measuring the temperature of the plurality of fungal oil pipes, respectively, characterized in that the refrigeration system is arranged. The method of claim 1, The plurality of fungal oil pipes are connected to a common suction pipe for guiding refrigerant sucked into the plurality of compressors, respectively, and are connected to bypass tubes for bypassing oil discharged from the compressor to the common suction pipe through the fungal oil pipe. Refrigeration system. The method of claim 1, The temperature sensor is a refrigeration system, characterized in that disposed in the tube between the compressor and the discharge valve to measure the temperature of the tube between the compressor and the discharge valve. A plurality of compressors for compressing a refrigerant, a plurality of bacteria oil pipes respectively installed in the plurality of compressors to guide the oil to be discharged to the outside, and disposed in the middle of the plurality of bacteria oil pipes to open and close the bacteria oil pipes, respectively. In the refrigeration system comprising a plurality of discharge valves, and a plurality of temperature sensors for measuring the temperature of the plurality of funnels, respectively, And detecting the temperature of each fungal oil pipe through the temperature sensor, and respectively opening the plurality of discharge valves individually to discharge oil according to the detected temperature. The method of claim 4, wherein And controlling the discharge valve to open the discharge valve when the amount of change during the predetermined unit time of the detected temperature is greater than a predetermined temperature change amount.

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