KR100494527B1 - Cylinder assembly for hermetic compressor - Google Patents

Abstract

A cylinder assembly of a hermetic compressor according to the present invention, comprising: a cylinder block having a cylinder in which a piston slides back and forth; A cylinder head coupled to the cylinder block to seal the cylinder, and having a refrigerant inlet hole and having first and second refrigerant discharge chambers of a predetermined volume constituting the discharge refrigerant path formed by partition walls; And a valve assembly interposed between the cylinder block and the cylinder head to control refrigerant flow into and out of the cylinder while operating by a pressure difference inside / outside the cylinder. According to this, the sound waves due to the impact applied to the valve plate by the intake and discharge valves are reduced by the transmission loss of the partition wall while exiting the discharge muffler through the first and second refrigerant discharge chambers, and thus, occur during operation of the compressor. Can reduce the amount of noise produced.

Description

Cylinder assembly for hermetic compressor {Cylinder assembly for hermetic compressor}

The present invention relates to a compressor, and more particularly to a cylinder assembly of a hermetic compressor.

In general, the hermetic compressor includes a hermetic casing 100, a power transmission unit 200 and a compression mechanism unit 300 installed in the hermetic casing 100, as shown in FIGS. 1 and 2.

The hermetic casing 100 is composed of upper and lower casing 110, 120, the refrigerant suction pipe 130 is installed. Lubricating oil is stored at the bottom of the lower casing 120.

The motor mechanism 200 is a stator 210 fixed in the hermetic casing 100, a rotor 220 installed to rotate inside the stator 210, and a crank installed to rotate integrally with the rotor 220. And a shaft 230.

The compression mechanism 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 into a reciprocating linear motion, and the connecting rod 310 It includes a piston 320 and a cylinder assembly 400 coupled to one end.

The cylinder assembly 400 includes a cylinder block 420 having a cylinder 410, a cylinder head 430 coupled with the cylinder block 420 to seal the cylinder 410, a cylinder block 420 and a cylinder. A valve assembly 440 interposed with the gaskets 480 and 490 between the heads 430.

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 suction muffler 500 and the refrigerant suction chamber 432.

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 at one side of the cylinder block 420.

The valve assembly 440 includes a valve plate 450, a suction valve 460, and a discharge valve 470.

Refrigerant suction holes 451 and refrigerant discharge holes 452 are formed in the valve plate 450, respectively. The cylinder 410 of the cylinder block 420 and the refrigerant suction chamber 432 of the cylinder head 430 communicate with each other by the refrigerant suction hole 451, and the cylinder block 420 by the refrigerant discharge hole 452. Cylinder 410 and the refrigerant discharge chamber 433 of the cylinder head 430 communicate with each other.

The suction valve 460 is installed to be located at the cylinder block 420 side of the valve plate 450 to selectively open the refrigerant suction hole 451. The suction valve 460 is formed by cutting a part of the suction valve seat 461 interposed between the cylinder block 420 and the valve plate 450. In addition, the discharge valve 470 is installed to be located at the cylinder head 430 side of the valve plate 450 to selectively open the refrigerant discharge hole 452. The stopper 471 and the keeper 472 which restrict | limit the lift amount of this discharge valve 470 are provided in the rear part of the discharge valve 470 in order.

The suction valve 460 and the discharge valve 470 open and close the refrigerant suction hole 451 and the refrigerant discharge hole 452 while flowing according to the pressure of the cylinder 410, whereby the refrigerant in the refrigerant suction chamber 432. Is introduced into the cylinder 410 or the refrigerant of the cylinder 410 can be discharged to the refrigerant discharge chamber (433). The operation of the conventional cylinder assembly 400 will be described in detail with reference to FIG. 3 as follows.

In the suction stroke in which the piston 320 moves from the top dead center to the bottom dead center, the suction valve 460 flows as shown by a dotted line in the drawing due to the negative pressure of the cylinder 410, and thus 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.

Subsequently, 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 the solid line in the drawing by the pressure of the cylinder 410 to close the refrigerant intake hole 451.

In this state, the piston 320 continues to move toward the top dead center, and the pressure of the cylinder 410 is further increased. When the piston 320 is moved close to the top dead center, the pressure of the cylinder 410 becomes maximum, and at this time, the discharge valve 470 flows as indicated by the dotted line in the drawing by the pressure of the cylinder 410. While opening the refrigerant discharge hole 452. Therefore, the refrigerant compressed in the cylinder 410 is discharged to the refrigerant discharge chamber 433 of the cylinder head 430 through the refrigerant discharge hole 452.

On the other hand, the piston 320 has reached the top dead center is moved toward the bottom dead center again, at this time, the discharge valve 470 flows as shown by the solid line in the drawing by the elasticity to close the refrigerant discharge hole 452 As the negative pressure is formed in the cylinder 410 again, the suction valve 460 opens the refrigerant suction hole 451.

However, the cylinder assembly 400 of the conventional hermetic compressor as described above, the discharge valve 470 when the suction valve 460 and the discharge valve 470, especially the discharge valve 470 opens and closes the refrigerant discharge hole 452. The discharge valve 470 closes while strongly hitting the valve plate 450 by the elastic force of the neck portion 470a of the c) and the elastic force of the bending portion 471a of the stopper 471. As such, the impact energy that appears when the valve plate 450 is impacted generates a sound wave that causes noise, thereby causing noise when the compressor is driven.

In addition, the size of the valve plate 450 and the suction valve seat 461 and the structure of the valve assembly 440 is complicated, there is a problem that the manufacturing cost increases.

The present invention has been made in view of the above problems, the sound wave generated by the discharge valve hits the valve plate to escape to the discharge muffler side through the two independent refrigerant discharge chamber provided in the cylinder head to the boundary interference It is an object of the present invention to provide a cylinder assembly of a hermetic compressor which can reduce the noise of the compressor by reducing the transmission loss of the partition wall.

Another object of the present invention is to provide a cylinder assembly of a hermetic compressor which can reduce the material cost and the assembly cost by employing a valve assembly of a small and simple shape.

A cylinder assembly of a hermetic compressor according to the present invention for achieving the above object comprises a cylinder block having a cylinder in which the piston slides reciprocating; A cylinder head coupled to the cylinder block to seal the cylinder, and having a refrigerant inlet hole and having first and second refrigerant discharge chambers of a predetermined volume constituting a discharge refrigerant path formed by partition walls; And a valve assembly interposed between the cylinder block and the cylinder head to control refrigerant flow into and out of the cylinder while operating by a pressure difference inside / outside the cylinder.

Here, the partition wall may be provided with at least one connection hole for connecting the first and second refrigerant discharge chamber.

The partition wall is formed in a cylindrical shape, an inner side of the cylindrical partition wall is formed as the first refrigerant discharge chamber, and an outer side is formed as the second refrigerant discharge chamber, and the refrigerant inlet hole is formed in the first refrigerant discharge chamber. It is preferable that the valve assembly seating surface on which the valve assembly is installed is located to be cut off from the refrigerant discharge chamber and has a predetermined depth.

The valve assembly may further include a valve plate having a refrigerant suction hole for communicating the refrigerant inlet hole and the cylinder, and a refrigerant discharge hole for communicating the cylinder and the first refrigerant discharge chamber; A suction valve seat having a suction valve for opening and closing the refrigerant suction hole; A discharge valve seat having a discharge valve for opening and closing the refrigerant discharge hole; And interposed between the discharge valve seat and the seating surface of the valve assembly to block the refrigerant inlet hole and the first refrigerant discharge chamber, and to secure a gap between the discharge valve seats and the ribs of the discharge valve. It is preferable to include a; gasket provided with an opening for.

In addition, it is preferable that the stopper wall for regulating the lift amount of the discharge valve is formed in the first refrigerant discharge chamber so as to have the same height as or lower than the seating surface of the valve assembly.

In addition, a cylinder gasket may be interposed between the cylinder head and the cylinder block for sealing between the second refrigerant discharge chamber and the cylinder.

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

As shown in FIG. 4, the cylinder assembly 600 of the hermetic compressor according to the present invention includes a cylinder block 610, a cylinder head 620, and a valve assembly 630.

The cylinder block 610 includes a cylinder 611 in which the piston 320 is installed and a discharge muffler 612 (see FIGS. 6 and 7) for reducing the discharge pulsation of the refrigerant discharged from the cylinder 611. In addition, a refrigerant passage 613 is formed through one side of the cylinder block 610 so as to be connected to the discharge muffler 612.

The cylinder head 620 is coupled to the cylinder block 610 to seal the cylinder 611, and the partition 621 is provided therein. The partition wall 621 may be provided in various forms in addition to the circular as shown. The interior of the cylinder head 620 is partitioned into first and second refrigerant discharge chambers 622 and 623 by the partition wall 621. The inside of the first refrigerant discharge chamber 622 is provided with a refrigerant inlet hole 624 for introducing refrigerant and a valve assembly seating surface 625 on which the valve assembly 630 is seated to a predetermined depth. Since the refrigerant inlet hole 624 is connected to the refrigerant inlet pipe 510 coupled to the suction muffler 500, the refrigerant of the suction muffler 500 flows along the refrigerant inlet pipe 510 and the refrigerant inlet hole 624. Flows into.

The first refrigerant discharge chamber 622 and the second refrigerant discharge chamber 623 are connected by connecting holes 621a formed in the partition wall 621, and the second refrigerant discharge chamber 623 is connected to the cylinder block 610. It is connected to the refrigerant passage 613. One or more connecting holes 621a may be formed, and the compressed refrigerant discharged from the cylinder 611 is discharged to the first refrigerant discharge chamber 622 and then the second refrigerant discharge chamber through the connection holes 621a. Discharged to 623.

The stopper wall 626 is provided in the first refrigerant discharge chamber 622 at the same height as or lower than the valve assembly seating surface 625. The stopper wall 626 regulates the lift amount of the discharge valve 636 of the valve assembly 630 so that the discharge valve 636 can open and close the refrigerant discharge hole 633b quickly.

The valve assembly 630 has a circular shape whose outer circumferential surface corresponds to the inner circumferential surface of the partition wall 621 so that the valve assembly 630 may be installed in close contact with the partition wall 621. The valve assembly 630 includes a gasket 631, a discharge valve seat 632, a valve plate 633, and an intake valve seat 634, and includes a gasket 631, a discharge valve seat 632, and a valve plate 633. ) And the suction valve seat 634 are inserted into the first refrigerant discharge chamber 622 in order. Here, the installation height of the valve assembly 630 is substantially equal to the height of the partition wall 621.

Refrigerant suction holes 631a, 632a and 633a connected to the refrigerant inlet hole 624 are formed in the gasket 631, the discharge valve seat 632 and the valve plate 633, and the valve plate 633 and The suction valve seat 634 has refrigerant discharge holes 633b and 634a connected to the cylinder 611.

The gasket 631 may be spaced apart from the valve assembly seating surface 625 and the discharge valve seat 632 by a predetermined interval so that the discharge valve 636 of the discharge valve seat 632 may be lifted toward the first refrigerant discharge chamber 622. To help. That is, the gasket 631 has an opening 631b having a portion thereof separated from the gasket 631, and the opening 631b is provided between the valve assembly seating surface 625 and the discharge valve seat 632. A lifting gap as much as the thickness is formed. Therefore, the discharge valve 636 may be lifted toward the first refrigerant discharge chamber 622 through the opening portion 631b.

The suction valve seat 634 is provided with a suction valve 635 for selectively opening the refrigerant suction hole 633a in a form in which a part of the suction valve seat 634 is cut out. In addition, the discharge valve seat 632 is provided with a discharge valve 636 for selectively opening the refrigerant discharge hole 633b in a form in which a part of the discharge valve seat 632 is cut out.

Meanwhile, a cylinder gasket 640 is interposed between the cylinder block 610 and the cylinder head 620, and the cylinder gasket 640 flows between the second refrigerant discharge chamber 633 and the cylinder 611. The second refrigerant discharge chamber 633 and the cylinder 611 are sealed so as not to be generated. One side of the cylinder gasket 640 is provided with a refrigerant passage hole 640a for connecting the second refrigerant discharge chamber 633 and the refrigerant passage 613 of the cylinder block 610.

When the valve assembly 630 is installed inside the partition 621, the valve assembly 630 is because the installation height thereof is equal to or slightly larger than the height D of the partition 621 illustrated in FIG. 5. ) And the cylinder gasket 640 is in close contact without generating a gap.

Hereinafter, the operation of the cylinder assembly according to the present invention will be described in detail with reference to FIGS. 6 and 7.

When the piston 320 moves from the top dead center to the bottom dead center, the suction valve 635 flows to the cylinder 611 side as shown in FIG. 6 by the negative pressure of the cylinder 611, whereby the valve As the refrigerant suction hole 633a of the plate 633 is opened, the refrigerant of the refrigerant inlet pipe 510 flows into the cylinder 611 through the refrigerant suction hole 633a.

Thereafter, the refrigerant introduced as the piston 320 moves from the bottom dead center to the top dead center is compressed, thereby increasing the pressure of the cylinder 611. At this time, the suction valve 635 flows by the pressure of the cylinder 611 as shown by a dotted line in the figure to close the refrigerant suction hole 633a.

In this state, the piston 320 continues to move toward the top dead center, and the pressure of the cylinder 611 is further increased. When the piston 320 is moved close to the top dead center, the pressure of the cylinder 611 is maximized, and at this time, the discharge valve 636 is opened by the pressure of the cylinder 611, as shown in FIG. The refrigerant discharge hole 633b is opened while flowing toward the first refrigerant discharge chamber 622 of the cylinder head 620 through the opening 631b of the 631. At this time, the discharge valve 636 hits the stopper wall 626 of the first refrigerant discharge chamber 622 and its lift amount is regulated, and the refrigerant compressed in the cylinder 611 passes through the refrigerant discharge hole 633b. The first refrigerant discharge chamber 622 of the head 620 is discharged.

 After the refrigerant discharged into the first refrigerant discharge chamber 622 is moved to the second refrigerant discharge chamber 623 through the connection hole 621a, the cylinder block (640a) passes through the refrigerant passage hole 640a of the cylinder gasket 640. It flows into the discharge muffler 612 along the refrigerant | coolant flow path 613 of 610.

In the refrigerant compression action as described above, the present invention provides a discharge pulsation while the refrigerant discharged from the cylinder 611 passes through the first and second refrigerant discharge chambers 622 and 623 respectively provided in the cylinder head 620 independently. Is reduced. In addition, the acoustic wave generated by the impact generated when the suction valve 635 or the discharge valve 636 strikes the valve plate 633 is discharged through the first and second refrigerant discharge chambers 622 and 623 through the discharge muffler 612. As it exits, the transmission loss of the partition wall due to boundary interference is generated, which reduces the sound wave energy.

According to the present invention as described above, the first and second refrigerant discharge chamber is provided in the cylinder head independently by the partition wall, the valve assembly is installed on the valve assembly seating surface provided inside the first refrigerant discharge chamber Therefore, the sound waves due to the impact applied to the valve plate by the intake and discharge valves are reduced by the transmission loss of the partition wall while exiting the discharge muffler through the first and second refrigerant discharge chambers, and thus are generated during operation of the compressor. The noise level can be reduced.

In addition, as the refrigerant discharged from the cylinder flows to the discharge muffler through the first and second refrigerant discharge chambers, the discharge pulsation of the refrigerant is reduced.

Further, according to the present invention, since the components constituting the valve assembly such as the valve plate, the suction valve seat, and the discharge valve seat are small in size and simple to be press-fitted into the first refrigerant discharge chamber formed in the partition wall, The manufacturing cost of the cylinder assembly, such as material costs and assembly costs, can be reduced.

While the invention has been shown and described with respect to preferred embodiments for illustrating the principles of the invention, the invention is not limited to the construction and operation as shown and described. Rather, those skilled in the art will appreciate that many modifications and variations of the present invention are possible without departing from the spirit and scope of the appended claims. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

1 is a cross-sectional view schematically showing a general hermetic compressor,

Figure 2 is an exploded perspective view of a conventional cylinder assembly,

3 is an assembly cross-sectional view showing the action of the conventional cylinder assembly shown in FIG.

4 is an exploded perspective view showing a cylinder assembly of a hermetic compressor according to a preferred embodiment of the present invention;

5 is an assembly cross-sectional view of the cylinder assembly of the present invention shown in FIG. 4, and

6 and 7 are cross-sectional views showing the operation of the cylinder assembly of the hermetic compressor according to the preferred embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

600; cylinder assembly 610; cylinder block

611; cylinder 612; discharge muffler

613; refrigerant flow path 620; cylinder head

621; barrier ribs 622, 623; first and second refrigerant discharge chambers

625; valve assembly seating surface 631; gasket

632; discharge valve seat 633; valve plate

634; suction valve seat 635; suction valve

636; discharge valve 640; cylinder gasket

Claims (6)

A cylinder block having a cylinder in which the piston slides and reciprocates; A cylinder head coupled to the cylinder block to seal the cylinder, and having a refrigerant inlet hole and having first and second refrigerant discharge chambers of a predetermined volume constituting a discharge refrigerant path formed by partition walls; And A valve assembly interposed between the cylinder block and the cylinder head, the valve assembly controlling the flow of refrigerant into the cylinder while operating by a pressure difference in / outside the cylinder, wherein the partition wall is formed in a cylindrical shape. A cylinder assembly of the hermetic compressor, wherein an inner side is formed by the first refrigerant discharge chamber, and an outer side is formed by the second refrigerant discharge chamber. The method of claim 1, The partition wall has a cylinder assembly of the hermetic compressor, characterized in that it comprises at least one connection hole for connecting the first and second refrigerant discharge chamber. The method of claim 1, The cylinder assembly of the hermetic compressor, wherein the refrigerant inlet hole is positioned to be blocked from the first refrigerant discharge chamber and the valve assembly seating surface on which the valve assembly is installed is formed to have a predetermined depth. The method of claim 3, wherein the valve assembly, A valve plate having a refrigerant suction hole for communicating the refrigerant inlet hole and the cylinder, and a refrigerant discharge hole for communicating the cylinder and the first refrigerant discharge chamber; A suction valve seat having a suction valve for opening and closing the refrigerant suction hole; A discharge valve seat having a discharge valve for opening and closing the refrigerant discharge hole; And Interposed between the discharge valve seat and the seating surface of the valve assembly to block the refrigerant inlet hole and the first refrigerant discharge chamber, wherein a portion of the discharge valve is positioned to secure a rib clearance of the discharge valve. And a gasket provided with an opening portion. The method of claim 4, wherein And the stripper wall for regulating the lift amount of the discharge valve has a height equal to or lower than a seating surface of the valve assembly in the first refrigerant discharge chamber. The method of claim 1, The cylinder assembly of the hermetic compressor, characterized in that between the cylinder head and the cylinder block is interposed a cylinder gasket for sealing between the second refrigerant discharge chamber and the cylinder.