KR20000020374A - High efficiency valve unit for hermetic vibrating compressor - Google Patents

Abstract

PURPOSE: A high efficiency valve unit is provided to prevent the leakage of coolant gas by producing a plate of valve with a steel plate without pores, to improve the efficiency of the compressor and the mechanical property such as the corrosion resistance, and to devise the reduction of producing costs and the improvement of the productivity. CONSTITUTION: A rivet slot(215) is formed in both sides by forming a recessed groove(211) having the low depth(h') without giving the change into a minimum thickness of a valve plate(210). A vent valve(220), a plate spring(230), and a valve stopper(240) are arrived on the recessed groove and combined with the riveting. A packing(250) and a valve cover(260) is combined on the valve plate with a bolt. The valve plate(210) is formed through a process of press such as a coining and a blanking.

Description

High efficiency valve device of hermetic electric compressor

The present invention relates to a hermetic electric compressor that is installed in a refrigerator or the like to compress and discharge refrigerant sucked in a sealed case.

More particularly, the present invention relates to a highly efficient valve device of a hermetic electric compressor, which improves efficiency and durability by improving the structure and assembly method of the valve device, which is a suction and discharge means of the refrigerant in the compressor, and contributes to the reduction of manufacturing cost and productivity. .

In general, a compressor is a device that converts mechanical energy into compressive energy of a compressive fluid, and examples thereof include a reciprocating compressor, a rotary compressor, and a turbo compressor.

These compressors serve to increase the condensation pressure by compressing the low pressure refrigerant gas sucked from the evaporator.

1 shows a cross-sectional view of a hermetic electric compressor mainly used for a refrigerator.

As shown in the figure, the sealed electric compressor has a main body embedded in the sealed upper and lower cases 10 and 20.

The main body has a frame 30 that acts as a skeleton, a drive unit (or motor unit 40) installed at the lower portion of the frame to rotate the shaft 50, and an upper portion of the frame to rotate the shaft. It is composed of a mechanical portion 50 for sucking, compressing and discharging the refrigerant gas by converting it into a linear motion.

The upper and lower cases 10 and 20 are welded and completely sealed to accommodate all the parts constituting the compressor therein.

The frame 30 is supported by the upper and lower cases (10, 20) through the leaf spring 70 and the coil spring 80, which is a cushioning and noise preventing means, and the drive unit 40 and the mechanical unit 60 itself. Will be supported.

The driving unit 40 is composed of a stator 90 supported by a frame to serve as a stator, a rotor 100 serving as a rotor, and a shaft 50 to rotate together with the rotor.

The mechanical part 50 is fixed to the upper end of the frame and includes a cylinder 110 having a valve device 140 which is a suction and discharge means of the refrigerant gas, and is inserted into the cylinder to contact the crank part 51 of the shaft 50. It consists of a piston 120 for sucking, compressing and discharging the refrigerant gas while reciprocating by the piston rod 130.

The valve device 140, which is a suction and discharge means of the refrigerant gas, supplies the refrigerant gas sucked through the suction muffler to the cylinder 110 and circulates the high pressure refrigerant gas discharged from the cylinder through the discharge muffler and the discharge pipe. Let's do it.

Figure 2 is an exploded perspective view of such a conventional valve device, Figure 3 is a cross-sectional view of the valve plate.

As shown in the drawing, the valve device 150 is formed of a sintered alloy to form the groove 151, the round hole 154, the discharge port 152, and the suction port 153 at the same time. In this way, the reason why the valve plate is formed of a small alloy is that the depth h of the groove 151 is too deep.

After the molding of the valve plate 150 is completed, the discharge valve 160 and the leaf spring 170 for restoring the movement of the discharge valve in the groove 151 and the bent portion to contact one end of the leaf spring ( 181, in turn, seated the bent valve stopper 180.

Thereafter, the packing 190 having the protrusion 191 contacting the bent portion 181 is finally seated at the upper end of the valve plate 150, and the pressing part positioned at the upper end of the protrusion 191 at the upper end of the packing plate 191. 201) seats the valve cover 200 formed integrally, and then bolts the valve cover, the packing, and the valve plate with bolts, and one end of the discharge valve and the leaf spring, and both ends of the valve stopper and the packing, respectively. The pressing portion 201 is to be fixed by the clamping force of the bolt.

In this compressor, as shown in FIG. 4, after the rotational movement of the shaft 50 is converted by the piston rod 130 in contact with the crank part 51, the piston rod moves the piston 120 into the cylinder 110. In the reciprocating motion, a clearance volume C exists to prevent interference between the bottom surface of the valve plate 150 and the top surface of the piston, and the clearance volume C corresponds to the size of the discharge port 153. It is further increased in proportion to the length.

In addition, the gap volume C is a space in which the refrigerant gas compressed at high pressure remains, and the suction amount of the refrigerant decreases due to the expansion of the residual high pressure gas during the suction stroke of the refrigerant, thereby significantly reducing the performance of the compressor. The valve device was intended to increase the performance of the compressor by reducing the gap volume (C) while reducing the length of the discharge port 153 by integrally forming the groove 151 during the sintering molding of the valve plate 150.

However, since the valve device is difficult to press-form the groove of the valve plate, it is formed of a small alloy due to its workability. Therefore, there are various problems as follows.

First, such a valve plate has the unique pores of the small alloy, so that the refrigerant leaks at the minimum thickness (a) minus the depth (h) of the groove from the original thickness (H), thereby reducing the performance of the compressor. It was the cause of the fall.

Second, the wear caused by the movement of the discharge valve is generated in the seating portion in which the discharge valve of the groove is seated, the fixability of the discharge valve is lowered, which has a problem of immediately lowering the efficiency and reliability of the compressor.

Third, post-processing, such as lapping, is required to match the desired roughness of both sides of the valve plate and the circumferential opening of the discharge port, which causes cost increase and productivity.

The present invention is to solve this problem, the technical problem is to prevent the leakage of the refrigerant gas by improving the respective parts constituting the valve and the assembly method thereof to be able to manufacture the valve plate with a steel plate without pores, To improve the mechanical properties such as the performance and wear resistance of the compressor, and to provide a highly efficient valve device that can contribute to the reduction of manufacturing cost and productivity.

1 is a cross-sectional view of a general hermetic electric compressor

2 is an exploded perspective view of a conventional valve device

3 is a cross-sectional view of the valve plate in the conventional valve device

Figure 4 is a sectional view of the main part showing the gap volume of the conventional valve plate and the piston.

5 is an exploded perspective view of the valve device according to the present invention;

6 is a cross-sectional view of the valve plate valve valve according to the present invention.

※ Explanation of code for main part of drawing

10: upper case 20: lower case

30 frame 40 drive unit

50: shaft 60: mechanical part

90: stator 100: rotor

150,210: Valve Plate 151,211: Groove

152,212: discharge port 153,213: suction port

160,220: discharge valve 170,230: leaf spring

180,240: Valve Stopper 190,250: Packing

200,260: Valve cover 270: Rivet

H: Thickness of valve plate h, h ': Depth of groove

a: minimum thickness

The valve device of the present invention for achieving the above object is to tighten the valve, the leaf spring and the valve stopper to the groove of the valve plate by riveting (Riveting) to reduce the depth of the groove without changing the minimum thickness of the valve plate Processing is a reality.

According to the present invention configured as described above, the valve plate may be made of a steel plate without pores through press processing such as coining and blanking, and thus leakage of refrigerant gas may be reliably prevented, thereby improving performance of the compressor. As the structure of the groove is dense, the strength and hardness are improved, which can contribute to the durability and reliability of the product.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

5 is an exploded perspective view of the valve device according to the present invention, Figure 6 shows a cross-sectional view of the valve plate.

As shown in the drawing, the valve device of the present invention has a groove plate 211 having a predetermined depth h, a valve plate 210 having discharge and suction ports 212 and 213 around the discharge plate, and a discharge valve sequentially stacked on the groove. In the valve device of the compressor consisting of a 220, a leaf spring 230 and a valve stopper 240, a packing 250 and a valve cover 260 fastened to the upper end of the valve plate with a bolt,

The depth h 'of the groove 211 is formed low without changing the minimum thickness of the valve plate 210 to form a rivet hole 215 on both sides thereof, and the discharge valve 220 on the top of the groove. And the leaf spring 230 and the valve stopper 240 are seated in turn to be fastened by the riveting, and the packing 250 and the valve cover 260 are fastened to the upper end of the valve plate by bolts.

The valve plate 210 is formed by pressing a steel plate without pores such as coining and blanking, which is a kind of machining.

In addition, through the above press working, holes such as the discharge port 212, the suction port 213, and the rivet hole 215, including the groove 211, into which the round hole 214 is fitted, have unique dimensions, shapes, and tolerances. Is formed.

In other words, the groove 211, the discharge port 212, the suction port 213, the round hole 214, and the like are integrally formed by one press work.

At this time, the depth h 'of the groove 211 is formed lower than the conventional one.

In addition, the end of the discharge valve 220 and the leaf spring 230 and the valve stopper 240 which is fastened to the valve plate 210 by riveting, the rivet holes 221, 231, 241 for the insertion of the rivet 270 are integrally formed. Is formed.

In addition, the packing 250 and the valve cover 260 which are fastened to the valve plate 210 by bolts, the edges thereof are fastened to the valve plate and the bolts.

Referring to the operation of the present invention configured as described above are as follows.

First, since the valve plate 210 of the present invention forms the iron plate through press working such as coining and blanking without changing the thickness of the minimum thickness portion (a), it is easy to manufacture and post-processing such as lapping. Since it is not necessary, the wheel manufacturing cost is lower than that of the conventional small alloy.

In addition, by reducing the depth (h ') of the groove (211) to realize the processing, and by tightening the valve stopper 240 by riveting, it is excellent in fixing, it is possible to increase the reliability of the product, and to reduce the production cost and improve the productivity .

In addition, since the valve plate 210, which is made of steel, has a forging process in which the groove 211 is forged during press processing, a much dense structure can be obtained compared to other places, and thus has a strength and hardness of about 4 to 5 times higher than that of a conventional small alloy. Excellent mechanical properties such as leakage prevention and abrasion resistance improve the compressor performance and durability.

In addition, since the discharge valve 220, the leaf spring 230 and the valve stopper 240 is fastened by the rivet 270, the packing 250 and the valve cover 260 are formed with pressing means such as protrusions and pressing parts. These parts also contribute to a reduction in manufacturing costs.

As described above, in the configuration of the valve device of the hermetic electric compressor, the valve, the leaf spring, and the valve stopper are fastened by riveting to the groove of the valve plate without changing the minimum thickness of the valve plate. By reducing the depth of the groove, the machining becomes a reality, which enables the valve plate to be manufactured from a steel plate without pores.

Therefore, leakage of the refrigerant gas is prevented, and thus the performance of the compressor is improved, and mechanical properties such as wear resistance are improved, which is excellent in durability, and contributes to reduction in manufacturing cost and productivity.

In addition, since the valve plate is manufactured through press processing such as coining and blanking, it is not only simple to manufacture but also high strength and hardness, thereby contributing to improved product reliability.

Claims (2)

A valve plate 210 having grooves 211 having a predetermined depth h 'and discharge and suction ports 212 and 213 around them, a discharge valve 220 and a leaf spring 230 which are sequentially stacked on the grooves. And a valve stopper 240 and a packing device 250 and a valve cover 260 fastened by bolts to an upper end of the valve plate. The depth h 'of the groove 211 is formed low without changing the minimum thickness of the valve plate 210, and a rivet hole 215 is formed in the groove to discharge the discharge valve 220 and the leaf spring ( 230) and the valve stopper 240 is fastened by the riveting, the valve device of the hermetic electric compressor, characterized in that the fastening of the packing 250 and the valve cover 260 to the upper end of the valve plate with a bolt. The valve apparatus of claim 1, wherein the valve plate 210 is formed by pressing a steel plate through blanking, coining, and the like.