JP2004271127A - Freezing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a freezing device capable of preventing the occurrence of excessive compression when performing low compression ratio condition operation of a scroll compressor. <P>SOLUTION: This freezing device is constituted in such a way that the scroll compressor SC, a condenser 43, a liquid receiver 44, a pressure reducing device, and an evaporator are sequentially and circularly connected and the device is provided with a liquid injection circuit 50 for supplying liquid refrigerant to an intermediate pressure part in a scroll compression element of the scroll compressor from the liquid receiver. It is provided with a bypass circuit 56 branched from the liquid injection circuit and communicating with a discharge pipe 32 of the scroll compressor. The intermediate pressure part in the scroll compression element is communicated with the discharge pipe through the liquid injection circuit and the bypass circuit when compression ratio in the scroll compression element of the scroll compressor is reduced below a specified value. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigeration apparatus including a liquid injection circuit for cooling a scroll compressor.
[0002]
[Prior art]
Conventionally, in refrigeration, refrigeration and air conditioning equipment, if the discharge gas temperature of the compressor that constitutes the refrigeration cycle of the refrigeration system rises abnormally, it will cause seizure of the sliding parts of the compressor and burning of the windings. Cooling system by injection is adopted. In this cooling method, the liquid refrigerant in the liquid receiver is supplied to the intermediate pressure portion of the scroll compression element of the scroll compressor by the liquid injection circuit and evaporated to lower the discharge gas temperature of the compressor (for example, , See Patent Document 1).
[0003]
Here, the scroll compressor includes an electric element having a rotating shaft in a sealed container, and a scroll compression element driven by the electric element. The scroll compression element has a spiral wrap on the end plate. It is composed of an oscillating scroll that is erected, and a fixed scroll that has a spiral wrap standing on the end plate that faces and engages the oscillating scroll. By rotating while rotating, a plurality of compression spaces formed by the fixed scroll and the orbiting scroll are gradually reduced from the outside to the inside to perform compression (for example, see Patent Document 2). .
[0004]
The liquid injection circuit is communicated with a compression space serving as an intermediate pressure in the scroll compression element.
[0005]
[Patent Document 1]
JP-A-5-215413 [Patent Document 2]
JP-A-3-246388
[Problems to be solved by the invention]
Here, a discharge hole (discharge port) for communicating the high-pressure chamber in the hermetic container and the compression space is formed in the central portion of the end plate of the fixed scroll, and a predetermined compression ratio (high pressure / The refrigerant compressed at a low pressure is discharged from the discharge hole into the high pressure chamber, and the high pressure gas refrigerant is discharged into the refrigerant circuit from a discharge pipe provided in communication with the high pressure chamber.
[0007]
However, when the scroll compressor is operated at a low compression ratio condition, especially when the electric element is operated at a low speed, overcompression occurs between the fixed scroll and the orbiting scroll, thereby causing an input (compression) (Work) increases, the coefficient of performance deteriorates, the characteristics of the compressor deteriorate, and the load applied to the bearing of the electric element in the sealed container also increases.
[0008]
An object of the present invention is to provide a refrigeration apparatus that can prevent the occurrence of over-compression during operation of the scroll compressor under a low compression ratio condition and eliminate the above disadvantages.
[0009]
[Means for Solving the Problems]
In the refrigeration apparatus of the present invention, the scroll compressor, the condenser, the liquid receiver, the pressure reducing device, and the evaporator are sequentially connected in an annular shape, and liquid refrigerant is supplied from the liquid receiver to the intermediate pressure portion of the scroll compression element of the scroll compressor. When a liquid injection circuit is provided, a bypass circuit branched from the liquid injection circuit and communicated with the discharge pipe of the scroll compressor is provided, and when the compression ratio in the scroll compression element of the scroll compressor is lower than a specified value, Since the intermediate pressure part in the scroll compression element is connected to the discharge pipe via the liquid injection circuit and the bypass circuit, when the compression ratio in the scroll compression element falls below the specified value, the compression space that becomes the intermediate pressure of the scroll compressor Liquid injection circuit and bypass circuit And it is possible to discharge the refrigerant to a discharge pipe of the scroll compressor.
[0010]
As a result, over-compression can be prevented between the fixed scroll and the orbiting scroll wrap as shown in claim 3 during operation of the scroll compressor under a low compression ratio condition. Accordingly, an increase in input (compression work) of the scroll compressor can be prevented, a characteristic deterioration due to a deterioration of the coefficient of performance can be eliminated, and an increase in load applied to the rotary bearing of the electric element can be prevented. Thus, the life of the scroll compressor can be extended.
[0011]
Further, if a valve device is provided in the bypass circuit as in claim 2, the communication between the intermediate pressure portion of the scroll compression element and the discharge pipe can be accurately controlled.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Next, an embodiment of the present invention will be described in detail with reference to the drawings. FIG. 1 is a refrigerant circuit diagram of a refrigeration apparatus 40 according to the present invention. In FIG. 1, SC is a scroll compressor (compressor), 42 is an oil separator, 43 is an air-cooled condenser (condenser), 44 is a liquid receiver (receiver tank), 45 is a filter dryer, 46 is a moisture indicator, 47 Is a strainer and 48 is an accumulator. The moisture indicator 46 is connected to the inlet of an expansion valve as a decompression device (not shown), and the strainer 47 is connected to the outlet of an evaporator (not shown).
[0013]
The scroll compressor SC, the oil separator 42, the condenser 43, the liquid receiver 44, the filter dryer 45, the moisture indicator 46, the expansion valve, the evaporator, the strainer 47, and the accumulator 48 are sequentially connected in an annular manner by refrigerant piping. The refrigeration cycle of the refrigeration apparatus 40 is configured. Reference numeral 49 denotes a blower for air-cooling the condenser 43.
[0014]
The liquid receiver 44 is provided with a liquid injection circuit 50 communicated with an intermediate pressure section (described later) in the compressor SC as will be described later. The liquid injection circuit 50 includes a strainer 51, a motor operated valve 52, an electromagnetic valve. A valve 54 and the like are sequentially provided. Further, a bypass circuit 56 branches from between the motor operated valve 52 and the strainer 51 of the liquid injection circuit 50, and the bypass circuit 56 is connected to the discharge pipe 32 of the scroll compressor SC. The bypass circuit 56 is provided with an electromagnetic valve (valve device) 57.
[0015]
Next, FIG. 2 shows a vertical side view of the scroll compressor SC. In this figure, reference numeral 1 denotes an airtight container. The airtight container 1 houses a scroll compression element 2 (compression element) on the upper side, and an electric element 3 for driving the scroll compression element 2 on the lower side. Reference numeral 4 denotes a frame, and the frame 4 supports the rotating shaft 5 of the electric element 3 at the center.
[0016]
The scroll compression element 2 includes a fixed scroll 7 and a swing scroll 8. The fixed scroll 7 includes a disk-shaped end plate 11 that divides the sealed container 1 into a high-pressure chamber 9 and a low-pressure chamber 10, an annular wall 12 that protrudes from one surface of the end plate 11, and the annular wall 12. It is composed of an involute shape surrounded by an end plate 11 surrounded by a spiral or a spiral wrap 13 having a curve similar to the involute shape. The fixed scroll 7 is provided with the projecting direction of the annular wall 12 and the wrap 13 downward.
[0017]
The orbiting scroll 8 includes a disc-shaped end plate 14, a spiral wrap 15 having an involute shape or a curve approximating the involute formed on one surface of the end plate 14, and the center of the other surface of the end plate 14. And a pin portion 16 projecting from the pin. The orbiting scroll 8 has the protruding direction of the wrap 15 upward so that the wrap 15 faces and engages with the wrap 13 of the fixed scroll 7 so that a plurality of crescent-shaped compression spaces 17 are formed inside. . Further, the compression space 17 is gradually reduced from the outside to the inside, and the sucked refrigerant is compressed.
[0018]
A drive unit 19 is provided at the tip of the rotary shaft 5 and is inserted into the pin portion 16 of the orbiting scroll 8. The center of the drive unit 19 is provided eccentric to the axis of the rotary shaft 5. Reference numeral 20 denotes an Oldham ring that revolves on a circular path so that the rocking scroll 8 does not rotate with respect to the fixed scroll 7.
[0019]
On the other hand, a discharge port 18 that connects the compression space 17 and the high-pressure chamber 9 is provided at the center of the end plate 11 of the fixed scroll 7. Similarly, a compression space 17 (a compression space serving as an intermediate pressure portion located outward from the central compression space 17) and the high-pressure chamber 9 are communicated with the end plate 11 located outside the discharge port 18. Liquid injection ports 21 and 21 are formed at symmetrical positions with the discharge port 18 in between. The liquid injection circuit 50 is connected to each liquid injection port 21, 21.
[0020]
The discharge port 18 is closed from the high pressure chamber 9 side by a discharge valve 22 made of a thin plate. The discharge valve 22 is held on the end plate 11 by a guide 24 and opens when the pressure of the discharge port 18 reaches the pressure of the high-pressure chamber 9 to connect the discharge port 18 and the high-pressure chamber 9.
[0021]
A suction passage (not shown) that guides the refrigerant to the scroll compression element 2 is provided on the outer periphery of the frame 4. Reference numeral 31 denotes a suction pipe attached to the sealed container 1, and the suction pipe 31 communicates with the low pressure chamber 10 in the sealed container 1 below the frame 4. Reference numeral 32 denotes the discharge pipe attached to the upper part of the sealed container 1, and the discharge pipe 32 communicates with the high-pressure chamber 9 in the sealed container 1.
[0022]
Returning to FIG. 1, the discharge pipe 32 is connected to an oil separator 42, and the suction pipe 31 is connected to an accumulator 48. In this figure, 58 is a low pressure sensor, which detects the pressure (low pressure) of the low pressure chamber 10 of the scroll compressor SC. A high pressure sensor 59 detects the pressure (high pressure) in the high pressure chamber 9 of the scroll compressor SC. A control device 61 controls the electromagnetic valves 57 and 53 and the motor-operated valve 52 based on the outputs of the sensors 58 and 59.
[0023]
When the electric element 3 of the scroll compressor SC is operated with the above configuration, the orbiting scroll 8 is driven via the rotating shaft 5. That is, the orbiting scroll 8 is driven by a drive unit 19 (eccentric with respect to the axis of the rotating shaft 5) inserted in the pin portion 16 so that the Oldham ring 20 does not rotate with respect to the fixed scroll 7. It can be swung while revolving on a circular orbit. The fixed scroll 7 and the orbiting scroll 8 gradually reduce the compression space 17 formed between the wraps 13 and 15 from the outside toward the inside.
[0024]
On the other hand, the refrigerant that has flowed into the low pressure chamber 10 in the sealed container 1 from the suction pipe 31 is guided to the compression space 17 of the scroll compression element 2 through the suction passage on the outer periphery of the frame 4. It is gradually compressed from the outside to the inside by turning.
[0025]
Here, if the compression ratio during normal operation of the scroll compressor SC is 3 (for example, the high pressure is 18 kg / cm ² and the low pressure is 6 kg / cm ² ), the pressure in the high pressure chamber 9 is 18 kg / cm ² . Therefore, by the turning of the orbiting scroll 8 with respect to the fixed scroll 7 as described above, the compression space 17 between the laps 13 and 15 is gradually compressed from the outside to the inside, and the position of the discharge port 18 at the center of the end plate 11 When the pressure reaches the pressure in the high pressure chamber 9, the discharge valve 22 is opened and the compressed refrigerant gas is discharged into the high pressure chamber 9. The refrigerant gas discharged into the high pressure chamber 9 is discharged out of the sealed container 1 from the discharge pipe 32.
[0026]
The high-temperature and high-pressure refrigerant gas discharged to the discharge pipe 32 of the scroll compressor SC enters the condenser 43 through the oil separator 42, is air-cooled by the condenser 43, is condensed and liquefied, and then is supplied to the liquid receiver 44. Once stored, the pressure is reduced by the expansion valve and then evaporated by the evaporator. The refrigeration apparatus 40 exhibits a cooling capacity by the endothermic effect generated at this time. Thus, since the high-temperature refrigerant gas is discharged from the scroll compressor SC, the temperature of the discharge pipe 32 (discharge temperature) rises rapidly.
[0027]
When the temperature of the discharge pipe 32 rises, a discharge temperature sensor (not shown) senses this, and the control device 61 opens the electromagnetic valve 53 to increase the valve opening of the motor operated valve 52. As a result, a part of the liquid refrigerant in the liquid receiver 44 flows into the liquid injection circuit 50, and is throttled by the strainer 51 and the electric valve 52, then through the electromagnetic valve 53, the liquid injection port 21 of the scroll compressor SC, 21 is supplied (injected) into the compression space 17 at an intermediate pressure from 21 to lower the discharge gas temperature of the scroll compressor SC. Further, when the discharge temperature of the scroll compressor SC decreases, the control device 61 reduces the valve opening of the motor operated valve 52.
[0028]
Here, for example, when the electric element 3 is operated at a low speed, the compression ratio falls below a specified value such as 2 (for example, the high pressure is 12 kg / cm ² and the low pressure is 6 kg / cm ² ), and the low compression ratio condition In this case, the pressure in the high pressure chamber 9 in the sealed container 1 is 12 kg / cm ² . In this case as well, when the orbiting scroll 8 turns with respect to the fixed scroll 7, the compression space 17 between the wraps 13 and 15 of the scrolls 7 and 8 is gradually compressed from the outside toward the inside.
[0029]
In this case, the compression space 17 at the position where the liquid injection ports 21 and 21 are formed is overcompressed. Based on the outputs of the low pressure sensor 58 and the high pressure sensor 59, the control device 61 opens the electromagnetic valves 53 and 57 and fully opens the motor operated valve 52 when the compression ratio falls below the specified value 2. Accordingly, the compression space 17 serving as an intermediate pressure portion is communicated with the discharge pipe 32 via the liquid injection ports 21 and 21, the liquid injection circuit 50 and the bypass circuit 56, and the liquid injection circuit 50 and the liquid injection circuit 50 and The refrigerant gas is discharged from the compression space 17 (intermediate pressure portion) to the discharge pipe 32 through the bypass circuit 56.
[0030]
By discharging the refrigerant gas from the liquid injection ports 21 and 21, over-compression of the scroll compression element 2 during the low compression ratio condition operation is prevented. As a result, an increase in input (compression work) of the scroll compressor SC is prevented, and a characteristic deterioration due to a reduction in the coefficient of performance is eliminated. Further, since an increase in load applied to the frame 4 that receives the rotating shaft 5 of the electric element 3 is also prevented, deterioration of the components of the scroll compressor SC can be suppressed, and a longer life can be achieved. Become.
[0031]
When the compression ratio returns to the specified value or more, the control device 61 closes the electromagnetic valve 57 and returns the control of the electromagnetic valve 53 and the motor operated valve 52 to the normal state.
[0032]
【The invention's effect】
According to the present invention, the scroll compressor, the condenser, the liquid receiver, the pressure reducing device, and the evaporator are sequentially connected in an annular shape, and the liquid refrigerant is supplied from the liquid receiver to the intermediate pressure portion of the scroll compression element of the scroll compressor. In the refrigeration apparatus comprising the liquid injection circuit, a bypass circuit branched from the liquid injection circuit and communicated with the discharge pipe of the scroll compressor is provided, and the compression ratio in the scroll compression element of the scroll compressor is lower than a specified value. In this case, since the intermediate pressure portion in the scroll compression element is communicated with the discharge pipe via the liquid injection circuit and the bypass circuit, when the compression ratio in the scroll compression element falls below a specified value, the compression that becomes the intermediate pressure of the scroll compressor Liquid injection circuit and space from space It is possible to discharge the refrigerant to a discharge pipe of the scroll compressor through the scan circuit.
[0033]
As a result, over-compression can be prevented between the fixed scroll and the orbiting scroll wrap as shown in claim 3 during operation of the scroll compressor under a low compression ratio condition. Accordingly, an increase in input (compression work) of the scroll compressor can be prevented, a characteristic deterioration due to a deterioration of the coefficient of performance can be eliminated, and an increase in load applied to the rotary bearing of the electric element can be prevented. Thus, the life of the scroll compressor can be extended.
[0034]
Further, if a valve device is provided in the bypass circuit as in claim 2, the communication between the intermediate pressure portion of the scroll compression element and the discharge pipe can be accurately controlled.
[Brief description of the drawings]
FIG. 1 is a refrigerant circuit diagram of a refrigeration apparatus to which the present invention is applied.
2 is a longitudinal side view of the scroll compressor of the refrigeration apparatus of FIG. 1. FIG.
[Explanation of symbols]
SC scroll compressor 1 hermetic container 3 electric element 2 scroll compression element 7 fixed scroll 8 swing scroll 9 high pressure chamber 10 low pressure chamber 21 liquid injection port 40 refrigeration unit 43 condenser 44 receiver 50 liquid injection circuit 56 bypass circuit 61 control apparatus

Claims (3)

A liquid injection circuit that sequentially connects a scroll compressor, a condenser, a liquid receiver, a pressure reducing device, and an evaporator, and supplies liquid refrigerant from the liquid receiver to an intermediate pressure portion of a scroll compression element of the scroll compressor. In a refrigeration apparatus comprising:
A bypass circuit branched from the liquid injection circuit and connected to a discharge pipe of the scroll compressor, and the liquid injection circuit and the bypass circuit when the compression ratio in the scroll compression element of the scroll compressor is lower than a specified value; A refrigeration apparatus comprising: an intermediate pressure portion in the scroll compression element communicating with the discharge pipe via 2. The refrigeration apparatus according to claim 1, wherein a valve device is provided in the bypass circuit. The scroll compressor includes the scroll compression element and an electric element that drives the scroll compression element in a sealed container,
The scroll compression element is composed of an orbiting scroll in which a spiral wrap is erected on an end plate, and a fixed scroll in which a spiral wrap is erected on an end plate that is opposed to the oscillating scroll. Turning the orbiting scroll while revolving with respect to the fixed scroll so as to perform compression by gradually reducing the plurality of compression spaces formed by the scroll and the orbiting scroll from the outside to the inside,
The refrigeration apparatus according to claim 1 or 2, wherein the liquid injection circuit is communicated with the compression space serving as an intermediate pressure.

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