KR200219263Y1 - Overcurrent prevention device of hermetic rotary compressor - Google Patents

Abstract

The present invention relates to an overcurrent prevention device of a hermetic rotary compressor, and is connected to an external terminal installed on the upper cover to prevent the operation of the compressor when an overcurrent occurs. Each bimetal is fixedly installed by a fixing pin, and a plurality of ground pieces which are installed to abut on both ends of the bimetal are protruded on an upper surface of the case, and a lower surface of the case is in contact with the upper cover and the respective bimetal is fixed. By providing an overcurrent protection device for a hermetic rotary compressor, the radiator having an integrally formed diaphragm is installed so as to be partitioned, so that it can be operated sensitive to temperature, so that the compressor is driven by minute overcurrent generated in the main winding and the auxiliary winding. Can block It relates to an overcurrent prevention system for a hermetic rotary compressor.

Description

An apparatus for preventing the over load of a rotary compressor

The present invention relates to an overcurrent protection device of a hermetic rotary compressor, and more particularly, an overcurrent protection device connected to the main winding and the auxiliary winding of an external terminal installed on the upper cover of the hermetic rotary compressor to block the operation of the compressor when an overcurrent occurs. The present invention relates to an overcurrent prevention device of a hermetic rotary compressor that can be operated sensitively so that the operation of the compressor can be blocked even by minute overcurrent generated in the main winding and the auxiliary winding.

In general, the hermetic rotary compressor is mainly installed and used in an air conditioner, and the configuration thereof includes a suction pipe 52 for sucking refrigerant gas of low temperature and low pressure evaporated from the evaporator to the outside of the body 50. It is installed together with the accumulator 54, and a rotating shaft 42 having an eccentric portion 42a on the inner circumference of the body 50 and an electric motor 40 in which the rotor 44 is built are installed inside the body 50. In the lower part, the motor bearing 32 is installed on the upper side, and the pump bearing 34 is installed on the lower side, and the eccentric portion 42a of the rotary shaft 42 and the roller 35 are integrally installed on the inner circumference. Is formed.

The body 50 has an upper cover 501 on which an external terminal 55, a discharge tube 56, and an overcurrent prevention device 57 are installed, and a base cover 504 on which a fastening hole 504a is formed ( 505 and the body 503.

An inlet 37 is formed in one side of the cylinder 30 to suck the refrigerant gas passing through the accumulator 54 to one side, and the other side of the cylinder 30 is discharged so that the compressed refrigerant gas is opened and discharged by a discharge valve (not shown). (Not shown) is formed, and a vane (not shown) is provided to divide the high pressure side and the low pressure side when the roller 35 is operated.

The operation of the hermetic rotary compressor 100 configured as described above accumulates low and low pressure refrigerant gas evaporated in the evaporator through the suction pipe 52 to remove the liquid refrigerant and foreign substances contained in the refrigerant gas. Through the suction port 37 is sucked into the cylinder 30 through.

In this way, the sucked refrigerant gas is the motor rotational force of the electric motor 40 is transmitted directly to the rotating shaft 42 to rotate the refrigerant gas introduced through the suction port 32 to the oil film contact between the eccentric portion 42a and the roller 35. Due to the rotation by the compression chamber is compressed, the compressed refrigerant gas is discharged to the discharge port by the action of the discharge valve.

The high temperature and high pressure refrigerant gas discharged through the discharge port is discharged to the condenser through the discharge pipe 58 formed in the upper cover 501 through the body 503.

The closed rotary compressor 100 configured and operated as described above is operated by a current applied through an external terminal 55 installed in the upper cover 501. When an overcurrent occurs on the side of the external terminal 55, In order to protect the compressor, an over load protector (OLP) 57 as illustrated in FIG. 4 is installed to be connected to the external terminal 55 as shown in FIG. 5.

In the conventional overcurrent prevention device 57, two ground pieces 574 protrude from the upper surface of the case 572 so as to be connected to the external terminal 55 to which the main winding 110 and the auxiliary winding 112 are connected. In the center between the ground piece 574, a bimetal 576 is installed to be installed by the fixing pin 575 to abut the ground piece 574.

The conventional overcurrent prevention device 57 as described above operates mainly on the overcurrent generated only in the main winding 110, that is, a large amount of current is consumed when the compressor is started up, so that only the high overcurrent generated by the large current is generated. The bimetal 576 connected to the ground piece 574 does not operate smoothly in the overcurrent generated from the auxiliary winding 112 connected to supply the current smaller than the current at the time of driving used when the driving is completed. Therefore, a problem occurs that a failure occurs in the compressor.

Therefore, the present invention has been made to solve the above problems, and is connected to the main winding and the auxiliary winding of the external terminal installed on the upper cover of the hermetic rotary compressor, the overcurrent prevention device which blocks the operation of the compressor when the overcurrent occurs is sensitive to temperature The purpose of the present invention is to enable the operation of the compressor to be blocked by the minute overcurrent generated in the main winding and the auxiliary winding.

1 is a schematic sectional view showing main parts of an overcurrent prevention apparatus of the present invention,

Figure 2 is a schematic plan view of the main part showing a state in which the overcurrent protection device and the external terminal of the present invention is connected,

3 is a schematic sectional view showing main parts of a structure of a general hermetic rotary compressor,

4 is a schematic cross-sectional view illustrating main parts of a conventional overcurrent prevention device installed in a hermetic rotary compressor.

FIG. 5 is a schematic plan view showing a main part of a state in which a conventional overcurrent protection device and an external terminal are connected.

Explanation of Signs of Major Parts of Drawings

10: overcurrent protection device 12: case

13: fixed pin 14: bimetal

15: ground piece 16: heat sink

16a: Plate 55: External terminal

501: upper cover

The present invention for achieving the above object is in the overcurrent prevention device of the hermetic rotary compressor which is connected to the external terminal installed on the upper cover to block the operation of the compressor when the overcurrent occurs, the fixing pins on both sides of the inner case Each bimetal is supported by a spring and is fixedly installed, and a plurality of ground pieces which are installed in contact with both ends of the bimetal are protruded through the upper surface of the case, and the bottom of the case is fitted with the bottom of the upper cover. By providing an overcurrent protection device for a hermetic rotary compressor, wherein the heat sink is formed integrally with the diaphragm so as to partition each of the bimetals, thereby achieving the above object.

Hereinafter, a preferred embodiment of the present invention by the accompanying drawings as follows.

1 is a schematic cross-sectional view showing a main part of the overcurrent prevention device of the present invention, each of the bimetal 14 is fixed to the fixing pin 13 on both sides of the case 12 is installed by being supported by a common spring, On the upper surface of the case 12, a plurality of ground pieces 15 installed to abut on both ends of the bimetal 14 penetrate and protrude, and the bottom of the case 12 is a bottom surface of the upper cover of the hermetic rotary compressor. The overcurrent prevention device 10 in which the radiator 16 in which the diaphragm 16a is integrally formed so that the said bimetals 14 may be divided in contact with each other is shown.

FIG. 2 is a schematic plan view showing a state in which an overcurrent protection device and an external terminal of the present invention are connected, and separate lead wires are drawn from the main winding 110 and the auxiliary winding 112 connected to the external terminal 55. Is installed so as to be in contact with the bimetal 14 installed in the case 12, which is an overcurrent prevention device 10 of the present invention, and is connected to a plurality of ground pieces 15 protruding upward. .

When described in more detail by the accompanying drawings the working relationship of the present invention configured as described above are as follows.

First, each of the bimetals 14 is fixed to the upper cover 501 of the hermetic rotary compressor 100 by fixing pins 13 on both sides of the case 12, and is installed to be fixed by a spring. A plurality of ground pieces 15 installed in contact with both ends of the bimetal 14 penetrate and protrude from an upper surface thereof, and a plate is formed so that each of the bimetals 14 is partitioned at the bottom of the case 12. The radiator 16 of the overcurrent prevention device 10, in which the radiator 16 formed integrally with the 16a) is installed, is installed to be in close contact with the upper beaker 501.

When the installation of the overcurrent protection device 10 is completed in the upper cover 501 as described above, separate lead wires from the main winding 110 and the auxiliary winding 112 of the external terminal 55 installed to the side as shown in FIG. Are drawn and connected to the ground pieces 15 of the overcurrent protection device 10, respectively.

As such, when the connection between the external terminal 55 and the overcurrent protection device 10 is completed, the compressor is driven when a current is applied through the external terminal 55. At this time, the main winding 110 drives the compressor. A large amount of current required initially flows, and when the driving is completed, a current is smaller than the initial current of the driving through the auxiliary winding 112 so that the compressor is driven.

Meanwhile, when the compressor is driven, a large amount of heat is generated by the interactions operated therein, and the heat is transferred to the upper cover 501, and the heat transferred to the upper cover 501 is a case of the overcurrent protection device 10. (12) It is installed to the bottom surface is to be transmitted to the heat through the heat sink 16 made of a material having excellent heat transfer to contact the upper cover 501 serves to heat the inside of the case (12).

Therefore, due to the effect of heating the inside of the case 12 has a condition that the bimetal 14 installed inside the case 12 can react sensitively, the main winding 110 or auxiliary winding Even when a minute overcurrent occurs more than necessary at 112, the bimetal 14 is spaced apart from the ground piece 15 to stop the operation of the compressor.

As described above, the overcurrent prevention device of the present invention connects a separate lead wire to each of the main winding and the auxiliary winding to the overcurrent prevention device of the present invention, which prevents the detection of the overcurrent generated in either the main winding or the auxiliary winding. As a result, not only the above problems can be solved, but the bimetal has a condition that can operate sensitively to temperature, and thus, the compressor can be safely stopped by quickly stopping the operation of the compressor even with minute overcurrent.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible.

Claims (1)

In the overcurrent protection device of a hermetic rotary compressor which is connected to an external terminal installed on the upper cover to block the operation of the compressor when an overcurrent occurs, each bimetal 14 with fixing pins 13 on both sides of the case 12. ) Is supported by a spring and is fixedly installed, and a plurality of ground pieces 15 installed to abut on both ends of the bimetal 14 are protruded through the upper surface of the case 12, and the case 12 is installed. ) Is provided on the bottom of the upper cover 501 and the over-current of the hermetic rotary compressor, characterized in that the radiator 16 is formed integrally with the diaphragm (16a) so that the bimetal 14 is partitioned. Prevention device.