KR100315802B1 - Free step rotary compressor - Google Patents

Abstract

The present invention is because the conventional variable capacity rotary compressor to control the capacity of the two stages of 100% or 50% only because there is a problem that can not be freely controlled according to the change in the temperature of the room,

A refrigerant suction unit through which the low pressure refrigerant gas passes through the evaporator, a cylinder into which the refrigerant gas is compressed, a roller that rotates inside the cylinder to compress the refrigerant, and one end of the high pressure unit inside the cylinder by contacting the roller. And a vane for dividing the low pressure part, a refrigerant discharge part in which the compressed high-pressure gas refrigerant is discharged and connected to the condenser, and a return path used as a passage through which some of the refrigerant of the high pressure part is returned to the refrigerant suction part, It is composed of a flow rate control unit for changing the compression capacity by controlling the flow rate of the return refrigerant by adjusting the opening amount,

Since the load on the compressor can be adjusted according to the cooling load, the present invention relates to a variable capacity rotary compressor capable of operating the system in an optimal operating state without wasting energy by actively controlling the capacity of the compressor according to a change in operating conditions.

Description

Variable Rotary Compressor {Free step rotary compressor}

The present invention relates to a rotary compressor used for compressing a refrigerant in a refrigeration circuit, and in particular, to allow a part of the compressed refrigerant to be recycled so as to change the capacity of the refrigeration circuit by varying the amount of refrigerant flowing in the circuit. One capability variable rotary compressor.

In general, the variable capacity rotary compressor is mainly used in a refrigeration circuit of a cooling device such as an air conditioner, as shown in FIG. That is, the rotary compressor 10 is used to compress the refrigerant. The refrigerant compressed in the rotary compressor 10 is cooled and condensed while passing through the condenser 30, and the condensed liquid refrigerant is configured to reduce the pressure reducing valve 40. As it passes through, part of it is vaporized to become a two-phase refrigerant, and in the evaporator 20, the two-phase refrigerant is completely vaporized while cooling the surrounding air to become a low-pressure gas refrigerant. The low pressure gas refrigerant is supplied to the rotary compressor 10 again to be compressed and then circulated again in the above path.

Here, the rotary compressor 10 changes the compression capacity by using the refrigerant pressure on the side of the condenser 30 or the evaporator 20 as the capacity change. That is, when the low pressure on the evaporator 20 side is applied to the flow rate controller 17 of the rotary compressor 10, the capacity of the compressor 10 drops to 50%, and when the high pressure on the condenser 30 side is applied, the compressor 10 ) 100% of the ability to demonstrate.

As described above, the conventional variable capacity rotary compressor includes a refrigerant suction part 14 through which a low pressure refrigerant gas passes through the evaporator 20 and a cylinder 11 into which the refrigerant gas is compressed, as shown in FIGS. 2A and 2B. And a roller 12 rotating the inside of the cylinder 11 to compress the refrigerant, and a vane 13 having one end contacting the roller 12 to partition the high pressure part and the low pressure part inside the cylinder 11. A return path 16 used as a passage through which the compressed high-pressure gas refrigerant is discharged and the refrigerant discharge part 15 connected to the condenser 30, and a part of the refrigerant of the high pressure part is returned to the refrigerant suction part 11 side; And a flow rate control unit 17 installed on the return path 16 to change the capacity of the compressor 10 by opening and closing the return path 16 using a piston 17 ', and the flow rate adjusting unit 17. Capacity of the compressor 10 by changing the position of the piston 17 'by applying a high or low pressure It consists of a three-way valve 18 for changing the pressure.

The conventional variable capacity rotary compressor configured as described above is changing the compression capacity by applying a high pressure or a low pressure to the flow rate control unit to change the position of the piston.

When operating the compressor at 100% capacity, high pressure is applied to the flow control unit 17 as shown in FIG. 2A. That is, since the A channel of the three-way valve 18 is opened, the refrigerant pressure in the front of the condenser 30 is applied to the flow rate control unit 17 through the three-way valve 18. Therefore, the piston 17 'of the flow rate controller 17 is raised to block the return path 16, and as the return path 16 is blocked, all of the high pressure refrigerant in the high pressure part of the cylinder 11 is refrigerant. It is supplied to the condenser 30 through the discharge part 15. At this time, since a part of the refrigerant supplied to the condenser 30 is applied to the flow rate control unit 17 through the three-way valve 18, the pressure on both sides of the piston 17 'is balanced so that the piston 17' That position.

If it is determined that the capacity of the compressor 10 is excessive, only 50% of the capacity may be exerted. In this case, the channel A of the three-way valve 18 is blocked and the channel B is opened so that the low pressure on the evaporator 20 side is applied to the flow rate controller 17. Therefore, the piston 17 'of the flow regulating part 17 is lowered by the pressure difference of both sides, and the return path 16 is opened with the lowering of the piston 17', and the high pressure in the high pressure part of the cylinder 11 is carried out. A part of the coolant flows to the coolant suction part 14 through the return path 16. As a result, the pressure of the refrigerant flowing into the cylinder 11 is increased and the work of the compressor 10 is reduced by about half.

However, the conventional variable capacity rotary compressor configured as described above has a problem that it is impossible to control freely according to the temperature change of the room because the control of the capacity is controlled only in two stages of 100% or 50%.

In other words, the conventional variable capacity rotary compressor controls the rotary compressor's capacity in two stages of 100% or 50% by applying high pressure and low pressure to the flow control part as necessary. Although it is necessary to control more precisely, there is no free control.

The present invention has been made to solve the above problems of the prior art, by varying the opening amount of the return path by controlling the pressure applied to the flow rate control unit in multiple stages, so that the capacity of the compressor changes according to the change in the room temperature The purpose of the present invention is to provide a variable capacity rotary compressor capable of operating the system in an optimal operating state without wasting energy.

1 is a configuration diagram showing a refrigerating circuit including a conventional variable capacity rotary compressor,

2A is an operation diagram showing the state of the compressor when the conventional variable capacity rotary compressor exhibits 100% capacity;

2B is an operation diagram showing the state of the compressor when the conventional variable capacity rotary compressor exerts 50% of its capacity;

3 is a block diagram showing a variable capacity rotary compressor according to the present invention,

Figure 4 is a block diagram showing a refrigeration circuit including a variable capacity rotary compressor of the present invention.

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

50: rotary compressor 51: cylinder

52: roller 53: vane

54: refrigerant suction unit 55: refrigerant discharge unit

56: return route

60: flow rate control unit 61: servo motor

62: body 63: piston

64: male thread 65: outdoor temperature sensor

70: evaporator 80: condenser

90: pressure reducing valve

The present invention for achieving the above object is a refrigerant suction unit through which a low pressure refrigerant gas is passed through the evaporator, a cylinder into which the refrigerant gas is compressed, a roller for compressing the refrigerant while rotating in the cylinder, and one end A vane contacting the roller and partitioning the high pressure part and the low pressure part inside the cylinder, a compressed high pressure gas refrigerant is discharged and connected to the condenser, a refrigerant discharge part connected to the condenser, and a part of the refrigerant of the high pressure part returned to the refrigerant suction part side; It is characterized in that it is composed of a return path to be used, and a flow rate control unit for changing the compression capacity by controlling the flow rate of the returning refrigerant by adjusting the opening amount of the return path.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

3 and 4, the variable capacity rotary compressor according to the present invention includes a refrigerant suction part 54 into which refrigerant gas of low pressure passing through the evaporator 70 is introduced, and a cylinder 51 into which refrigerant gas is compressed. A roller 52 rotating the inside of the cylinder 51 to compress the refrigerant, one end of the roller 52 being in contact with the roller 52 to define a high pressure part and a low pressure part inside the cylinder 51; A compressed air discharge unit 55 discharged from the compressed high-pressure gas refrigerant and connected to the condenser 80, and a return path 56 used as a passage through which some of the high-pressure refrigerant flows back to the refrigerant suction unit 54; It is composed of a flow rate control unit 60 for changing the compression capacity by controlling the opening amount of the return path 56 to control the flow rate of the returning refrigerant.

The flow rate control unit 60 is a body 62 installed on the return path 56, and positioned inside and inside the body and moved forward and backward, the tip is formed in a conical shape to change the opening amount of the outlet of the body 62. Piston 63, a step motor 61 for moving the piston 63 forward and backward, and conversion means for converting the rotational movement of the step motor 61 into a linear motion of the piston 63. Here, the conversion means is a male screw 64 formed on the shaft of the step motor 61, and a female screw 63 formed on the piston 63 and interlocked with the male screw 64 so that the piston 63 moves linearly. ').

The conversion means may use a rack formed on one side of the piston 63 and a pinion coupled to the shaft of the step motor 61 and engaged with the rack instead of using a screw coupling.

In addition, the variable capacity rotary compressor 50 is an outdoor temperature sensor 65 for sensing the outdoor temperature in order to vary the capacity of the compressor 50 according to the cooling load, such as the refrigeration circuit shown in FIG. Used together.

The variable capacity compressor of the present invention configured as described above reduces operating costs by changing its capacity according to the cooling load.

During the day when the cooling load is high, the flow rate control unit 60 allows the compressor 50 to exert its capacity 100%. That is, by operating the step motor 61 so that the piston 63 is advanced, the outlet of the body 62 is blocked, so that the refrigerant in the high pressure portion of the cylinder 51 flows along the return path 56. Do not flow to the side. That is, the rotational movement of the male screw 64 is interlocked with the female screw 63 'formed in the piston 63 to linearly move the piston 63. Accordingly, the conical tip of the piston 63 blocks the outlet of the body 62, and all of the refrigerant in the high pressure portion of the cylinder 51 is transferred to the condenser 80 through the refrigerant discharge part 55.

The high pressure refrigerant delivered to the condenser 80 cools the room while passing through the pressure reducing valve 90 and the evaporator 70, and the refrigerant from the evaporator 70 passes through the refrigerant suction unit 54 of the compressor 50. It flows into the low pressure part of the cylinder 51. The refrigerant introduced into the cylinder 51 is compressed according to the rotation of the roller 52 and then discharged through the refrigerant discharge unit 55 to be delivered to the condenser 80 to continue to circulate the above path.

At night when the cooling load is lowered, the step motor 61 is rotated in the opposite direction according to the signal of the outdoor temperature sensor 65. That is, as the step motor 61 rotates, the piston 63 is retracted to open the outlet of the body 62, so that a part of the high pressure refrigerant in the high pressure portion of the cylinder 51 opens the return path 56. Accordingly, the pressure of the refrigerant flowing into the cylinder 51 is increased by being supplied to the refrigerant suction unit 54. When the pressure of the refrigerant flowing into the cylinder 51 is increased, the work performed by the compressor 50 is reduced, and the load on the compressor 50 is reduced, so the operating cost is reduced.

Here, since the cooling load is calculated according to the signal of the outdoor temperature sensor 65, the control signal can be sent to the step motor 61 to determine the position of the piston 63, so that the adjustment of the opening / closing amount of the outlet of the body 62 is controlled. It is possible to adjust the amount of refrigerant returned to the refrigerant intake unit 54 through the return path 56 accordingly. In other words, the load on the compressor 50 can be adjusted according to the cooling load.

As such, the variable capacity rotary compressor of the present invention can adjust the load applied to the compressor according to the cooling load, and thus the system can be operated in an optimal operating state without wasting energy by actively controlling the compressor's capacity according to the change of operating conditions. There is an advantage to this.

In addition, since there is no need for a separate pipe for the refrigerant control unit for adjusting the amount of the refrigerant is returned, there is another advantage that the facility cost is reduced.

Claims (4)

A refrigerant suction unit through which the low pressure refrigerant gas passes through the evaporator, a cylinder into which the refrigerant gas is compressed, a roller that rotates inside the cylinder to compress the refrigerant, and one end of the high pressure unit inside the cylinder by contacting the roller. And a vane partitioning the low pressure section, a refrigerant discharge section in which the compressed high pressure gas refrigerant is discharged and connected to the condenser, and a return path used as a passage through which some of the refrigerant of the high pressure section returns to the refrigerant suction section. And a flow rate control unit configured to change the compression capacity of the compressor by controlling the flow rate of the refrigerant returned by adjusting the opening amount of the return path. The method of claim 1, The flow rate control unit includes a body installed on the return path, a piston positioned inside and back of the body and moved forward and backward to form a conical tip to change an opening amount of the outlet of the body, and a step motor for moving the piston back and forth. And converting means for converting the rotational motion of the step motor into a linear motion of the piston. The method of claim 2, The converting means is a variable capacity rotary compressor, characterized in that consisting of a male screw formed on the shaft of the step motor, and a female screw formed on the piston and interlocked with the male screw to linearly move the piston. The method of claim 1, The converting means is a variable capacity rotary compressor comprising a rack formed on one side of the piston, the pinion is coupled to the shaft of the step motor and meshed with the rack.