KR19990026295A - Cooling structure of compressor - Google Patents

Abstract

The present invention relates to a cooling structure that can more effectively cool the cylinder block and the piston of the compressor, and to provide a cooling structure of the compressor that can improve the cooling efficiency of the cylinder block and the piston.

In order to realize the above object, the present invention provides a cooling structure of a compressor including a bank (65) formed in a cylinder block (55) so that the lubricating oil of the compressor is stored, the oil (0) stored in the bank (65). It is characterized in that it comprises a circulation means formed to cool between the cylinder block 55 and the piston 57 and discharged to the housing 50 while flowing between the cylinder block 55 and the piston 57.

Description

Cooling structure of compressor

The present invention relates to a cooling structure, and more particularly to a cooling structure that can more effectively cool the cylinder block and the piston of the compressor.

In general, a compressor is a device that pressurizes a fluid to change the pressure, temperature, and the like of the fluid to suit a predetermined purpose. The compressor is classified into a rotary type, a piston type, and a scroll type according to an operation type.

As shown in FIG. 3, the piston-type compressor includes a housing 50, a stator 51 fixedly installed in the housing 50, and a rotor 52 inserted into and rotated in the stator 51. The crank shaft 54 is pressed into the rotor 52 and has an eccentric shaft 53 formed at one end thereof, and the eccentric shaft 53 is inserted into one end thereof and the bore 56 of the cylinder block 55 is inserted therein. It consists of a connecting rod 58 is inserted into the other end of the piston (57) sliding in the) and the cylinder head (60) coupled via the cylinder block 55 and the valve assembly (59) have.

In particular, the bearing 61 is fixed to the stator 51 and the crank shaft 54 is inserted to support and lubricate the rotation of the crank shaft 54, the bearing 61 and the rotor 52. A washer 62 interposed between the lubricating washer 62, a spiral oil groove 63 formed on the outer circumferential surface of the crankshaft 54 to supply oil to the bearing 61 and the connecting rod 58, An oil pickup 64 is provided to suck oil 0 filled in the bottom surface of the housing 50 by the crankshaft 54.

In particular, the bank 65 is formed on the upper surface of the cylinder block 55 to cool the cylinder block 55 and the piston 57 while the oil flowing down the bearing 61 is stored.

Referring to the operation of the compressor described above, when the rotor 52 is rotated by the magnetic fields of the stator 51 and the rotor 52, the crank shaft 54 fixed thereto is rotated.

When the crankshaft 54 rotates, the connecting rod 58 and the piston 57 reciprocate. The fluid is sucked and compressed into the cylinder head 59 by the reciprocating motion of the piston 57. will be.

In addition, the oil is sucked from the oil pickup 64 when the crank shaft 54 rotates, which rises through the spiral oil groove 63 of the crank shaft 54.

The oil (0) raised through the helical oil groove (63) flows out of the bearing (61) while cooling and lubricating between the bearing (61) and the crankshaft (54).

Oil (0) flowing down the bearing 61 is filled in the bank 65 formed on the outer periphery of the cylinder block 55, the oil (0) is to cool the cylinder block (55).

However, there is a problem that the cooling effect of the cylinder block and the piston is low when cooling the cylinder block and the piston with oil flowing down through the bearing after forming the groove-shaped bank on the outer circumference of the cylinder block as described above.

That is, the lubricated oil is stored in the outer bank of the cylinder block to cool the cylinder block and the piston, thereby lowering the cooling effect of the cylinder and the piston.

Accordingly, an object of the present invention is to provide a cooling structure of a compressor that can improve the cooling efficiency of the cylinder block and the piston as to solve the above problems. In order to realize the above object, the present invention provides a cooling structure of a compressor including a bank formed in a cylinder block so that the lubricating oil of the compressor is stored, wherein the oil stored in the bank is introduced between the cylinder block and the piston, and And circulation means configured to cool the piston and discharge it to the housing.

1 is a cross-sectional view showing a compressor to which the present invention is applied;

Figure 2 is a perspective view of the bush in Figure 1,

3 is a cross-sectional view showing a typical piston compressor.

* Explanation of symbols for main parts of the drawings

1: inlet hole 2: bush

3: outlet hole 4: guide groove

55 cylinder block 65 bank

1 is a cross-sectional view of a compressor showing a cooling structure of a compressor according to the present invention, in which oil (0) stored in a bank (65) flows between a cylinder block (55) and a piston (57), and a cylinder block (55) and a piston. A circulation means formed to cool the 57 and discharge to the housing 50 is provided between the cylinder block 55 and the piston 57.

The circulation means includes an inflow hole 1 formed through the cylinder block 55 so that the oil 0 of the bank 65 flows into the cylinder block 55, and the oil introduced into the inflow hole 1. (0) is inserted into the cylinder bore 56 to cool the cylinder block 55 and the piston 57 without refrigerant mixing, and forms a certain space between the cylinder block 55 and the cylinder block 55 ) And a discharge hole 3 formed in the cylinder block 55 so that the oil 0 passing through the bush 2 is discharged to the housing 50.

In particular, a spiral guide groove 4 is formed on the surface of the bush 2 so that oil 0 circulates and diffuses to the entire surface of the bush 2 to increase the cooling efficiency.

Referring to the operation and effect of the present invention as described above, the crank shaft 54 is rotated according to the operation of the compressor to reciprocate the inside of the bore 56, the piston 57 connected to the connecting rod 58.

When the piston 57 reciprocates, the refrigerant is compressed. At this time, oil (0) lubricating and cooling the crankshaft 54 and the bearing 61 flows down the bearing 61 outside. The bank 65 is filled.

The oil (0) filled in the bank (65) is introduced into the cylinder block (55) by the inlet hole (1) formed in the cylinder block (55).

The oil (0) introduced into the inlet hole (1) flows into the spiral guide groove (4) formed between the bush (2) and the cylinder block 55, the oil introduced into the spiral guide groove (4) (0) circulates through the entire surface of the bush (2) by the guide groove (4) described above.

When oil (0) circulates through the entire surface of the bush (2), the entire bush (2) in contact with the piston (57) is cooled, and the piston (57) is cooled by the cooling of the bush (2). .

Of course, the cylinder block 55 is also cooled by the oil (0), so as to cool the piston 57, the cylinder block 55 and the bush (2) inside the cylinder block 55 as described above. As a result, the cooling efficiency is significantly improved compared to cooling with the oil (0) outside the cylinder block (55).

The oil (0) passing through the helical guide groove (4) is introduced into the discharge hole (3) formed in the cylinder block 55 when passing through the lower side in the drawing, which falls into the housing 50, the oil circulates Be sure to

Of course, some of the oil continues the cooling action by circulating the spiral guide groove 4 of the bush 2 continuously.

When the oil (0) is supplied between the cylinder block (55) and the bush (2), the oil (0) is a cylinder bore because the bush (2) blocks the space inside the cylinder bore (56). (56) It does not flow into the inside and does not mix with the refrigerant.

Here, the bush 2 is not worn when the piston 57 operates by using the same or similar material as the cylinder block 55.

As described above, the present invention is advantageous in that the cooling efficiency of the cylinder block and the piston can be improved by supplying the oil stored in the bank to the bush provided between the cylinder block and the piston.

Claims (3)

In the cooling structure of the compressor comprising a bank formed in the cylinder block so that the lubricating oil of the compressor is stored, the oil is stored in the bank flows between the cylinder block and the piston while being formed to cool the cylinder block and the piston and discharged to the housing Cooling means of the compressor, characterized in that it comprises means. According to claim 1, wherein the circulation means is such that the inlet hole formed through the cylinder block so that the oil in the bank flows into the cylinder block, and the oil introduced into the inlet hole to cool the cylinder block and the piston without mixing with the refrigerant In addition to being inserted into the cylinder bore and forming a predetermined space between the cylinder block and the bush formed of the same material as the cylinder block, and the discharge hole formed in the cylinder block so that the oil passing through the bush is discharged to the housing, characterized in that Cooling structure of the compressor. The cooling structure of a compressor according to claim 2, wherein the surface of the bush includes a spiral guide groove formed to circulate and diffuse oil to the entire surface of the bush to increase cooling efficiency.