KR20070006251A - Hermetic type compressor - Google Patents

Abstract

A hermetic compressor is provided to increase compression efficiency and stabilize discharge fluctuation by adding a secondary discharge valve for selectively opening a coolant passage. A hermetic compressor includes a cylinder block(420), a cylinder block, a valve plate(450), a suction valve seat(460), a first discharge valve, and a second discharge valve(470b). The cylinder block includes a cylinder in which a piston is installed, a discharge muffler for reducing discharge fluctuation of the discharged coolant, and a coolant passage. The cylinder block is engaged with the cylinder block to seal the cylinder and has a coolant discharge chamber. The valve plate includes a coolant suction chamber for communicating the coolant suction chamber with the cylinder, a first coolant discharge hole for communicating the cylinder with the coolant discharge chamber, and a second coolant discharge hole for communicating the coolant discharge chamber with the coolant passage. The suction valve seat has a suction valve for opening and closing the coolant suction chamber. The first discharge valve opens and closes the first coolant discharge hole. The second discharge valve opens and closes the second coolant discharge hole.

Description

Hermetic Compressor {HERMETIC TYPE COMPRESSOR}

1 is a schematic cross-sectional view of a general hermetic compressor.

2 is a perspective view illustrating a cylinder assembly of a hermetic compressor according to the related art.

3 is a perspective view showing a cylinder assembly of the hermetic compressor according to the present invention.

4 is a perspective view of the discharge valve seat in which the shape of the secondary discharge valve shown in FIG. 3 is added.

FIG. 5 is an assembled cross-sectional view of a cylinder assembly showing the flow of refrigerant by the intake valve and the first discharge valve of the present invention shown in FIG.

FIG. 6 is an assembled cross-sectional view of the cylinder assembly showing the flow of the refrigerant by the second discharge valve of the present invention shown in FIG.

Explanation of symbols on the main parts of the drawings

420: cylinder block 421: discharge muffler

422: refrigerant flow path 430: cylinder head

450: valve plate 451: refrigerant inlet hole

452a: first refrigerant discharge hole 452b: second refrigerant discharge hole

460: suction valve seat 461: suction valve

470a: first discharge valve 470b: second discharge valve

The present invention relates to a hermetic compressor, and more particularly to a valve assembly interposed between a cylinder block and a cylinder head of a hermetic compressor.

As shown in FIG. 1, a general hermetic compressor includes a hermetic case 100 and a transmission part 200 and a compression part 300 installed in the hermetic case.

The closed case 100 is composed of an upper case 110 and a lower case 120, the lubricant is stored at the bottom of the lower case 120.

The transmission unit 200 is a crank installed to rotate integrally with the stator 210 and the rotor 220, the rotor 220 is installed to rotate inside the stator 210, fixed inside the sealed case 100. And a shaft 230.

The compression unit 300 is connected to the eccentric portion 240 of the crankshaft 230 and the connecting rod 310 for converting the rotational movement of the rotor 220 to the reciprocating linear movement of the connecting rod 310 It includes a piston 320 and a cylinder assembly 400 coupled to one end.

 The conventional cylinder assembly 400 has a cylinder block 420 having a cylinder 410, and a cylinder head 430 coupled with the cylinder block 420 to seal the cylinder 410, as shown in FIG. 2. And a valve assembly 440 interposed with the gaskets 480 and 490 between the cylinder block 420 and the cylinder head 430.

The valve assembly 440 includes a suction valve seat 460 having a suction valve 461, a valve plate 450 having a refrigerant suction hole 451 and a refrigerant discharge hole 452, and the refrigerant discharge hole 452. It is formed as a discharge valve 470 to selectively open.

The refrigerant suction chamber 432 and the refrigerant discharge chamber 433 are formed in the cylinder head 430 by partition walls 431. In addition, an inlet hole 434 is formed at one side of the cylinder head 430 to connect the refrigerant suction chamber.

The cylinder block 420 has a discharge muffler 421 to reduce noise caused by the flow of the compressed refrigerant exiting the cylinder 410. The discharge muffler 421 is connected to the refrigerant discharge chamber 433 of the cylinder head 430 through the refrigerant passage 422 formed on one side of the cylinder block.

The suction process and the compression process of the conventional hermetic compressor are as follows. When the piston 320 moves from the top dead center of the cylinder 410 to the bottom dead center, when the suction valve 461 flows to the cylinder 410 by the negative pressure of the cylinder, the refrigerant suction hole 451 is opened. The refrigerant in the refrigerant suction chamber 432 flows into the cylinder 410 through the refrigerant suction hole 451.

In addition, during the compression stroke, that is, the piston 320 moves from the bottom dead center of the cylinder 410 to the top dead center to compress the introduced refrigerant, and thus the pressure of the cylinder 410 is gradually increased. At this time, the suction valve 461 flows to the opposite side of the cylinder 410 to close the refrigerant suction hole 451.

In the closed state, the piston 320 continues to move toward the top dead center, and the cylinder pressure becomes higher and higher so that the discharge valve 470 is opposed to the cylinder 410 at a pressure outside the elastic limit of the discharge valve 470. When the fluid flows to the side, the refrigerant discharge hole 452 is opened, and the refrigerant compressed in the cylinder is discharged into the refrigerant discharge chamber 433 of the cylinder head 430 through the refrigerant discharge hole 452, and then the refrigerant of the cylinder block 420 is discharged. It moves to the discharge muffler 421 via the flow path 422.

However, the conventional valve assembly having such a configuration has a problem in that the compression valve is deteriorated because the discharge valve is pre-opened so that the refrigerant does not reach the required pressure before the piston having the maximum pressure in the cylinder reaches the top dead center.

In addition, after the compression stroke, the piston is vibrated by the discharge valve during the down stroke, there is a problem that the instability and noise of the discharge pulsation occurs.

The present invention is to solve this problem, when the piston in the hermetic compressor reaches the top dead center of the cylinder when the piston reaches the top dead center of the cylinder to open the discharge valve to improve the compression capacity and to stabilize the discharge pulsation The purpose is to reduce the noise.

In order to achieve the above object, the present invention provides a cylinder block including a cylinder in which a piston is installed, a discharge muffler for reducing the discharge pulsation of the refrigerant discharged from the cylinder, and a refrigerant passage so that the refrigerant flows into the discharge muffler. and; A cylinder head coupled to the cylinder block to seal the cylinder and having a refrigerant suction chamber and a refrigerant discharge chamber therein; A refrigerant suction hole for communicating the cylinder and the refrigerant suction chamber, a first refrigerant discharge hole for communicating the cylinder and the refrigerant discharge chamber, and a second refrigerant discharge hole for communicating the refrigerant discharge chamber and the refrigerant passage; A valve plate; A suction valve seat having a suction valve for opening and closing the refrigerant suction hole; A first discharge valve for opening and closing the first refrigerant discharge hole; And a second discharge valve for opening and closing the second refrigerant discharge hole.

The second discharge valve may be formed by cutting a part of the suction valve seat interposed between the cylinder block and the valve plate.

In addition, the diameter of the second discharge valve may be larger than the diameter of the second refrigerant discharge hole to completely seal the second refrigerant discharge hole.

In addition, at one side of the cylinder block in which the refrigerant passage is formed, a rectangular groove recessed inward to open the second refrigerant discharge hole while the second discharge valve flows toward the refrigerant passage by the pressure of the refrigerant discharge chamber is provided. Characterized in that formed.

Hereinafter, a hermetic compressor according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. For reference, in the following description of the present invention, the same reference numerals refer to the same parts as those in the related art.

As shown in Figure 3, the cylinder assembly of the hermetic compressor according to the present invention includes a cylinder block 420 having a cylinder, a cylinder head 430 coupled with the cylinder block 420 to seal the cylinder 410, and A valve assembly 400 is disposed between the cylinder block 420 and the cylinder head 430 together with the gaskets 480 and 490.

 The valve assembly 400 includes a valve plate 450, a suction valve seat 460, and a first discharge valve 470a.

In the cylinder head 430, a refrigerant suction chamber and a refrigerant discharge chamber are partitioned up and down by partition walls. In addition, an inlet hole 434 is formed at one side of the cylinder head 430 to connect the suction muffler (not shown) and the refrigerant suction chamber 432.

The cylinder block 420 includes a cylinder 410 in which a piston is installed, and a discharge muffler 421 for reducing the discharge pulsation of the refrigerant discharged from the cylinder 410. Further, at one side of the cylinder block 420 A rectangular groove 423 recessed into the cylinder block 420 is formed to allow the secondary discharge valve 470b to be described later to flow. A refrigerant passage 422 is formed in the groove 423 to be connected to the discharge muffler 421.

The valve plate 450 has a refrigerant suction hole 451, a first refrigerant discharge hole 452a, and a second refrigerant discharge hole 452b, respectively. The cylinder 410 of the cylinder block 420 and the refrigerant suction chamber of the cylinder head 430 communicate with each other by the refrigerant suction hole 451, and the cylinder block 420 of the cylinder block 420 communicates with the first refrigerant discharge hole 452a. The refrigerant discharge chamber of the cylinder 410 and the cylinder head 430 communicate with each other. In addition, the second refrigerant discharge hole 452b communicates with the refrigerant discharge chamber of the cylinder head 430 and the refrigerant passage 422 of the cylinder block 420.

The first discharge valve 470a is installed on the cylinder head 430 side of the valve plate 450 to selectively open the first refrigerant discharge hole 452a. A stopper 471 and a keeper 472 which restrict the lift amount of the first discharge valve 470b are sequentially provided at the rear portion of the first discharge valve 470a.

4 is a perspective view of a suction valve seat as a key feature of the present invention. As shown in FIG. 4, the suction valve 461 is installed to be located at the cylinder block 420 side of the valve plate 450 to selectively open the refrigerant suction hole 451 formed in the valve plate 450. .

 The suction valve 461 is formed by cutting a portion of the suction valve seat 460 interposed between the cylinder block 420 and the valve plate 450 at a position corresponding to the refrigerant suction hole 451.

In addition, the hole 462 is formed to communicate the first refrigerant discharge hole 452a of the valve plate 450 and the cylinder 410 so that the refrigerant compressed in the cylinder is discharged into the refrigerant discharge chamber of the cylinder head.

In addition, the second discharge valve 470b is installed to be located at the cylinder block 420 side of the valve plate 450 to selectively open the second refrigerant discharge hole 452b formed in the valve plate 450.

The second discharge valve 470b is a position corresponding to the refrigerant passage 422 and the second refrigerant discharge hole 452b in the suction valve seat 460 interposed between the cylinder block 420 and the valve plate 450. It is formed by cutting a part in.

The diameter R1 of the second discharge valve head 470b 'is larger than the diameter R2 of the second refrigerant discharge hole 4502b so as to completely close the second refrigerant discharge hole 452b of the valve plate 450. Should be large

In addition, the depth of the groove 423 formed at one side of the cylinder block 420 is such that the second discharge valve 470b flows toward the groove 423 by the pressure of the refrigerant discharge chamber to completely fill the first refrigerant discharge hole 452b. It is preferable that the height is such that it does not come into contact with the bottom surface of the groove 423 in which the coolant flow path 422 is formed.

Hereinafter, the operation and effects of the hermetic compressor according to the present invention will be described.

The suction valve 461, the first discharge valve 470a, and the second discharge valve 470b flow in accordance with the pressure of the refrigerant and discharge the refrigerant suction hole 451, the first refrigerant discharge hole 452a, and the second refrigerant discharge. The hole 452b is selectively opened and closed, whereby the refrigerant in the refrigerant suction chamber 432 flows into the cylinder 410 and the refrigerant introduced into the cylinder 410 is compressed and discharged through the refrigerant discharge chamber 433. Discharged to the muffler 421.

The operation of the cylinder assembly will be described in detail with reference to FIGS. 5 to 6 as follows.

As shown in FIG. 5, when the piston 320 moves from the top dead center to the bottom dead center, the suction valve 461 has the cylinder 410 as shown in a dotted line in the drawing by the negative pressure of the cylinder 410. As the refrigerant flows through the side, the refrigerant suction hole 451 is opened, and the refrigerant in the refrigerant suction chamber 432 is introduced into the cylinder 410 through the refrigerant inlet hole 451.

Then, the piston 320 compresses the refrigerant introduced while moving from the bottom dead center to the top dead center, thereby increasing the pressure of the cylinder 410. At this time, the intake valve 460 flows as shown by a solid line in the drawing by the pressure of the cylinder to close the refrigerant intake hole 451, and the cylinder is entirely sealed by the first discharge valve 470a. .

When the piston 320 continues to move toward the top dead center in the closed state as described above, the pressure of the cylinder 410 is further increased, so that the first discharge valve (at a pressure point outside the elastic limit of the first discharge valve 470a) 470a flows as shown by a dotted line in the drawing, opening the first refrigerant discharge hole 452a so that the compressed refrigerant in the cylinder passes through the first refrigerant discharge hole 452a to the refrigerant discharge chamber 433 of the cylinder head. Are gathered.

 As shown in FIG. 6, the pressure of the refrigerant discharge chamber 433 in the cylinder head 430 increases due to the use of the second discharge valve 470b, which causes the first discharge valve 470a to open. By delaying the time point it is possible to increase the pressure of the refrigerant than before.

As the first discharge valve 470a is opened and the compressed refrigerant flows into the refrigerant discharge chamber 433, the secondary discharge valve 470b is broken at a pressure point outside the elastic limit of the secondary discharge valve 470b. As shown in FIG. 2, the refrigerant compressed by opening the second refrigerant discharge hole 452b while moving is moved to the discharge muffler 421 through the refrigerant passage 422.

As such, the present invention increases the pressure of the refrigerant discharge chamber in the head cylinder due to the use of the secondary discharge valve selectively opening the refrigerant passage communicating the discharge muffler and the refrigerant discharge chamber of the cylinder head. By delaying the opening time can be kept closed to the desired pressure, which increases the compression efficiency.

In addition, the use of the secondary discharge valve serves to filter the pressure pulsation once in the refrigerant discharge chamber of the cylinder head to stabilize the discharge pulsation and thereby reduce the noise.

As described in detail above, the hermetic compressor according to the present invention increases the compression efficiency by adding a secondary discharge valve for selectively opening the refrigerant passage communicating with the discharge muffler provided in the cylinder block and the refrigerant discharge chamber provided in the cylinder head. Stabilizing the discharge pulsation has the effect of reducing the noise.

Therefore, the present invention has the effect of reducing the material cost by obtaining the above-described effect only by adding a new shape to the existing component without adding a separate additional device.

Claims (4)

A cylinder block including a cylinder in which a piston is installed, a discharge muffler for reducing the discharge pulsation of the refrigerant discharged from the cylinder, and a refrigerant passage to allow the refrigerant to flow into the discharge muffler;  A cylinder head coupled to the cylinder block to seal the cylinder and having a refrigerant suction chamber and a refrigerant discharge chamber therein;  A refrigerant suction hole for communicating the cylinder and the refrigerant suction chamber, a first refrigerant discharge hole for communicating the cylinder and the refrigerant discharge chamber, and a second refrigerant discharge hole for communicating the refrigerant discharge chamber and the refrigerant passage; A valve plate;  A suction valve seat having a suction valve for opening and closing the refrigerant suction hole;  A first discharge valve for opening and closing the first refrigerant discharge hole;  And a second discharge valve for opening and closing the second refrigerant discharge hole.  The method of claim 1,  The second discharge valve is formed by cutting a part of the suction valve seat interposed between the cylinder block and the valve plate. The method of claim 2,       The diameter of the second discharge valve is a hermetic compressor, characterized in that formed larger than the diameter of the second refrigerant discharge hole to completely seal the second refrigerant discharge hole. The method of claim 2,      One side of the cylinder block in which the coolant flow path is formed is formed with a rectangular groove recessed inward so that the second discharge valve flows toward the coolant flow path by the pressure of the coolant discharge chamber and opens the second coolant discharge hole. Hermetic compressor.

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