KR102120088B1 - 2nd Unloader System for Mid - High Pressure Air Compressor - Google Patents

Abstract

Disclosed is a two-stepped unloader system for a mid- to high-pressure air compressor, which can maintain an airtight state not only in a non-load operation but also in a normal operation for pressurizing, and thus, can operate without a lowered efficiency. To this end, according to the present invention, the lower limit position of the unloader system piston is determined by the lower end stop surface in the housing, and the upper limit position is determined by the upper end stop surface of the cover. A lower O-ring and an upper O-ring, which selectively come in contact with the lower end stop surface and the upper end stop surface, are assembled with a lower side and an upper side of a piston ring arranged on the piston. Accordingly, When the two-stepped unloader system for the mid- to high-pressure air compressor performs a pressurizing operation or an initial operation and a non-load operation in accordance with full charge of a reserve tank, the leak of air pressure is prevented regardless of the operation position of the unloader piston such that the air is absorbed into and discharged from the two-stepped compressor pump without loss, thereby preventing decline of the operation efficiency to make high-efficiency operation possible and enhance the reliability of operation, and the operation noise is minimized to make the silent operation possible.

Description

2nd Unloader System for Mid-High Pressure Air Compressor}

The present invention relates to a two-stage unloader system for a medium- and high-pressure air compressor to reduce the driving load of the piston when no-load operation is required, such as when the reserve tank is fully charged or in the initial operation.

In general, an air compressor is used for inhaling and compressing air, and filling compressed air into a reservoir tank to accumulate necessary air pressure to provide air pressure necessary for various tool operations.

There is no need to continuously pressurize the air after inhaling the air and filling the reservoir with the desired pressure, and if the air pressure is consumed in the process of operation, pressurization using the compression pump must be performed again.

In this process, if the air pressure of the reservoir tank changes frequently, it is not desirable to frequently cut off the power supplied to the motor of the compression pump, so if pressure is not required in the reservoir tank, press the suction valve of the compression pump to open it. The piston load of the compression pump is reduced, and when pressurization is required, the intake valve is opened only when inhaled and only the outlet valve is opened when compressed, so that normal pressurization is performed.

When air pressure is not required in this way, the unloader system is utilized to reduce the piston load by pressing the suction valve of the compression pump to reduce the piston load, so that no load due to initial operation or frequent operation is possible. .

A representative example of such an unloader system can be seen by the People's Republic of China Patent Publication No. 108131279 (invention name: unloading type air compressor; hereinafter referred to as'citation invention 1'), which is illustrated in FIG. 1.

As can be seen from this, the cited invention 1 includes a compressed gas cylinder 1, and also a compressed gas cylinder 1, an air inlet 2 and an air hole 3 communicating with each other, and compressed gas The air inlet 2 and the air hole 3 are respectively installed in the cylinder 1, the check valve 4 and the exhaust unidirectional valve 5 are introduced, and the air inlet 2 and atmospheric pressure pass through each other, An unloading cylinder 6 is installed on the air inlet 2 side, and a cylinder rod presses the gas supply check valve 4 in the unloading cylinder 6, and the air hole 3 communicates with the gas tank. And, the air hole (3) is connected to the relief valve (7), the relief valve (7) and the pneumatic chamber of the unloading cylinder (6) communicate with each other, and the piston (8) in the compressed gas cylinder (1) ) Is connected to the power source 10 through the crank link mechanism 9, it is achieved by implementing the reciprocating operation of the piston (8).

Citation Invention 1 of such a structure is actually made of an unloading piston (hereinafter referred to as'Quote Invention 2') of the structure shown in the picture illustrated in FIG. 2.

The unloader piston according to the Cited Invention 2 is the initial operation in which the relief valve is operated or the piston 10 is lowered during no-load operation, so that the O-ring 11 at the bottom of the piston 10 is guide 21 at the top of the body 20 Is in close contact with

In the case of the medium-pressure compressor, the pressure of the air flowing into the lower side of Citation Invention 2 for the second stage compression during normal operation is already a high pressure of about 5 kgf/cm2, so it passes through the circumferential surface of the Piston 10 of Citation Invention 2 ( 11) It leaks downward, which is a problem that there is a high possibility that the relief valve (7) will flow backward to the piping side and lower the compression efficiency.

People's Republic of China Patent Publication No. 108131279 (Name of invention: Unloading type air compressor)

In order to solve this problem, the present invention provides a two-stage unloader system for medium and high-pressure air compressors that is capable of maintaining an airtight state during initial operation or no-load operation as well as normal operation for pressurization, thereby preventing continuous leakage. It is aimed at.

In order to achieve this object, the present invention is a housing fixed above the suction valve of the air compressor header, a spring mounted on a support jaw provided inside the housing, and a lower end penetrated through the spring to expose the suction. The piston so as to be located above the valve, and the upper portion of the piston is sealed with a cover connected to a pipe connected to a relief valve,

The lower limit position of the piston is determined by the lower stop surface inside the housing, and the upper limit position is determined by the upper stop surface of the cover, and the lower and upper o-rings selectively contacting the lower and upper stop surfaces are provided on the piston. It is to be equipped with a two-stage unloader system for medium and high pressure air compressors, characterized in that it is to be assembled to the lower and upper parts of the piston ring.

In this way, the present invention prevents leakage of air pressure regardless of the operating position of the unloader piston during the pressurization operation of the two-stage compression pump for medium and high-pressure air compressors or during the initial operation and no-load operation due to full charge of the reservoir tank, thereby preventing loss. However, since compressed air can be sucked in and discharged, there is a useful effect that prevents deterioration in operating efficiency and enables high-efficiency operation.

1 is an explanatory view showing a conventional unloading type air compressor.
Figure 2 is a photograph showing a conventional unloading piston.
Figure 3 is a longitudinal sectional view showing the operating standby state of the two-stage unloader system for medium and high pressure air compressor according to the present invention.
Figure 4 is a longitudinal sectional view showing the unloading operation state of the two-stage unloader system for a medium and high pressure air compressor according to the present invention.
Figure 5 is an exploded perspective view of main parts of the present invention.
Figure 6 is an enlarged longitudinal sectional view of a main assembly state of the present invention.
Figure 7 is a longitudinal sectional view showing the operating standby state of the two-stage unloader system for a medium and high pressure air compressor of the present invention according to another embodiment.
Figure 8 is a longitudinal sectional view showing the unloading operation state of the two-stage unloader system for a medium and high pressure air compressor according to another embodiment of the present invention.

The embodiments of the present invention will be described in detail below so that those skilled in the art to which the present invention pertains can easily implement the present invention with reference to the accompanying drawings.

The overall configuration of the present invention is shown in Figures 3 and 4. As can be seen from this, the two-stage unloader system for a medium and high pressure air compressor according to the present invention includes a housing 200 fixed to the intake valve 103 of the air compressor header 100, and the housing 200 A spring 400 mounted on the support jaw 202 provided in the inside, and a piston 300 having a lower end penetrated through the spring 400 and exposed downward to be positioned above the suction valve 103, Sealed with a cover 210 provided with a connecting hole 212 for connecting the upper side of the piston 300 with a relief valve,

The lower limit position of the piston 300 is determined by the bottom stop surface 201 inside the housing 200 that blocks the descending of the piston 300, and the upper limit position covers 210 to block the rise of the piston 300 ) Is determined by the top stop surface 211, the lower ore 312 and the upper ore 311 selectively contacting the lower stop surface 201 and the upper stop surface 211, the piston ring of the piston 300 It is made to be assembled to the lower part and the upper part of 310.

In the present invention, the primary compressed air is introduced through the inlet 101 of the header 100 in the standby state of operation, and the compressed pump piston (previously known as reference numeral 8 in FIG. 1 and illustration is omitted) As this descending, the intake valve 103 of the header 100 is pulled downward in the drawing to open, thereby introducing air into the cylinder (previously shown in FIG. 1, reference numeral 1, and not shown), and then the compressed pump piston When the intake air is compressed while rising and the exhaust valve is opened and discharged to the outlet 102, the process of allowing air pressure to accumulate through the outlet 102 to an unshown reservoir tank is repeated. It rises to the set level.

Accordingly, the pressure switch operates the relief valve to apply air pressure to the piston 300 through the connecting hole 212, and as shown in FIG. 4, the lower step formed under the piston 300 of the housing 200 (203) while compressing the spring 400, the attachment 500 is fastened by the fastening nut 501 to the piston screw portion 301 of the lower end thereof, and the lower end of the attachment 500 The intake valve 103 is pressed, which causes the intake valve 103 to be opened, and this state is maintained until the normal pressing operation.

Therefore, even if the compressed pump piston repeatedly moves up and down, the air is introduced and discharged through the suction valve 103, so that the load is not applied to the compressed pump piston, so that no-load operation is possible.

At this time, in the present invention, when the piston 300 is lowered, the lower o-ring 312 of the piston ring 310 comes into close contact with the lower stop surface 201 of the housing 200, and as a result, the second stage of the air compressor for medium and high pressure ( It is possible to prevent leakage even if the high air pressure is full during the compression process.

In addition, in the present invention, since the air pressure by the relief valve is lost during the normal pressurization operation, the pneumatic pressure applied to the piston 300 upward through the connecting hole 212 disappears, so that the spring 300 is resilient to the piston 300. The lower step 203 is pushed up, and as a result, the upper o-ring 311 of the piston ring 310 is shown in FIG. 3 in close contact with the upper top surface 211 of the cover 210. As a result, the high pressure air filled around the intake valve 103 is blocked from moving to the cover 210 and the connection hole 212, thereby completely blocking air leakage.

As described above, the present invention is the intake valve 103 during the unloading operation by the lowering of the piston 300 inside the housing 200 or the standby operation by the rise inside the housing 200 of the piston 300 It is possible to prevent high-pressure air filled in the surroundings from leaking to the outside, such as a relief valve, through the connection hole 212, thereby enabling stable medium pressure.

In addition, in the present invention, the downward stop operation of the piston 300 inside the housing 200 is accurately limited by the lower end surface 201 of the housing 200 and the lower O-ring 312 below the piston ring 310. Accordingly, the downward stop position of the attachment 500 fastened by the fastening nut 501 of the piston threaded portion 301 can be accurately controlled, so that the attachment 500 excessively presses the suction valve 103 There is a useful effect that prevents the related parts from being deformed, thereby preventing a failure and realizing a reliable operation.

In addition, the present invention, in addition to the structure for fastening the attachment 500 below the piston 300 with the fastening nut 501 in the form shown in FIGS. 6 and 7, the piston 300 and the attachment 500 are integrated. It is possible to fasten the attachment 500 in various forms, such as manufacturing.

In addition, the present invention shows the shape of the attachment 500 to reduce the weight of the attachment 500 so as to minimize the adverse effect on the operation of the piston 300, and to ensure that the opening and closing of the suction valve 103 is stable. It is of course preferred to have a "c" cross-sectional structure as described above, and of course, various other shapes can be applied.

In addition, the present invention may be separately assembled to the housing 200 as shown in FIGS. 3 to 6 and assembled to the header 100 using the housing screw portion 204,

That is, the present invention forms a lower stop surface 201 and a supporting jaw 202 above the suction valve 103 of the header 100 in the form without a separate housing 200 as shown in FIGS. 7 and 8. Then, the spring 400, the upper o-ring 311, the lower o-ring 312 is assembled with the piston 300 is provided with a piston ring 310 is assembled, the piston 300 above the upper stop surface 211 ), and can be implemented by fastening the cover 210.

In addition, FIG. 7 is a longitudinal cross-sectional view of a state waiting for operation, and FIG. 8 is a longitudinal cross-sectional view showing an operating state in which the intake valve 103 is opened by descending of the piston 300, and the specific operation of FIGS. 7 and 8 Since it is the same as described above, the description is omitted, and according to the embodiment of the present invention shown in FIGS. 7 and 8, it is not necessary to separately manufacture and assemble the housing 200, thereby reducing manufacturing cost and simplifying the structure. It has the utility of being able to contribute to weight reduction and miniaturization of products, and to increase durability.

In addition, the present invention is the impact and noise generated by directly colliding the lower part of the housing 200 and the cover 210 and the upper end of the cover 210 with a metal component when the piston 300 is raised or lowered. By lowering the lower O-ring 312, the upper O-ring 311, and the spring 400, operation noise is minimized without any damage even after frequent stops and starts, and quiet operation is possible.

In the above, the technical idea for the present invention has been described together with the accompanying drawings, but this is an exemplary description of the best embodiment of the present invention, and is not intended to limit the present invention, as long as those skilled in the art It is obvious that anyone can make various modifications and imitation of dimensions, shapes, structures, etc. without departing from the scope of the technical idea of the present invention, and such modifications and imitations are included in the scope of the technical idea of the present invention.

100: header 101: inlet 102: outlet 103: intake valve
200: housing 201: bottom stop 202: support jaw 203: lower jaw
204: housing screw 210: cover 211: top stop 212: connecting hole
300: piston 301: piston screw portion 310: piston ring 311: upper O-ring
312: lower O-ring 400: spring 500: attachment 501: fastening nut

Claims (4)

A housing fixed above the intake valve of the air compressor header,
A spring mounted on a support jaw provided inside the housing,
A piston having a lower end penetrating through the spring and being exposed downward and positioned above the suction valve;
The upper portion of the piston is sealed with a cover connected to a pipe connected to a relief valve, but the lower limit position of the piston is determined by the bottom stop surface inside the housing blocking the lowering of the piston, and the upper limit position blocks the rise of the piston. Determined by the top stop of the cover,
A two-stage unloader system for a medium and high pressure air compressor, characterized in that the lower and upper o-rings selectively contacting the lower and upper stops are assembled to the lower and upper portions of the piston ring provided in the piston. The method of claim 1, wherein the piston is provided with a piston screw portion at the lower side, a two-stage unloader system for a medium and high pressure air compressor, characterized in that the attachment is fixed by fastening a fastening nut to the piston screw portion. 3. The two-stage unloader system for a medium and high pressure air compressor according to claim 2, wherein a cross-sectional shape of the attachment is in a "c" shape. delete

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