KR101890206B1 - Backward Preventing Vacuum Pump Inlet - Google Patents

Abstract

The present invention relates to a suction port which is attached to the outside of a vacuum pump, and is a tubular member which serves as an air inflow passage. The tubular member includes a first flow path (101) of small diameter inserted into the body of the vacuum pump, A suction port body (100) forming a second flow path (102) protruding outward; A buoyant body support 110 provided at a boundary between the first flow path 101 and the second flow path 102 inside the inlet port body 100 and spaced apart from each other and protruding upward; A buoyant body 200 mounted on the buoyant body support 110; A tubular member fastened to the threaded portion formed on the outer circumferential surface of the suction port body 100 to provide a passage for air and having a large diameter providing a space for the buoyancy body 200 together with the second flow path 102 An inlet cap 300 forming a small-diameter fourth flow path 304 for preventing the third flow path 303 from separating from the buoyancy body 200; And the fourth passage (304), and abuts against the buoyant body (200) which rises when the oil in the vacuum pump flows backward to close the oil passage And an O-ring for sealing (410) for sealing.

Description

Background of the Invention [0002] Vacuum pump inlets (backward preventing pumps)

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a suction port structure of a vacuum pump, and more particularly, to a suction port having a function of blocking oil from flowing out of a vacuum pump even when the regulator inside the vacuum pump is damaged.

1, the oil pressure formed by the oil pump 140 flows through the oil passage 201 to the upper oil space 271 of the piston operating space 270 A valve plate 211 descending in the pump intake space to open the pump intake port 101 when the pump module 110 is in operation and being actuated to shut off the intake port 101 when the pump module 110 is stopped, A valve cover 280 for forming an upper oil space 271 and guiding the sliding up and down of the piston, a valve cover 280 for opening and closing the upper oil space 271, A sealing seal 260 for maintaining the oil pressure, and a return spring 220 for elastically pushing the piston upward in the lower oil space 272 to float the piston 210 when the pump module is stopped . The oil passage 201 communicating with the upper oil space 271 is connected to the oil passage 202 through the operating valve 250 and the oil passage 203 communicating with the oil reservoir 131, Lt; / RTI >

The operating valve 250 is installed in the valve space 251 located at the branch point of the flow path 1 201 flowing into the upper oil space 271 from the oil pump 140 and the flow path 203 203 passing through the oil reservoir The valve body 252 is formed of a valve body 253 having a U-shape in section and biased by a spring 253. Between the outer diameter of the valve body 252 and the inner diameter of the valve space 251, An oil passage 254 made of a small gap is formed and the spring 251 and the valve body 252 are operated according to the relative sizes of the oil pressure of the first oil passage 201 and the second oil passage 202.

That is, when the pump device normally operates, the hydraulic pressure of the oil passage 2 supplied from the oil pump 140 presses the valve body 252 and the spring 253 provided therein, And closes the flow path 3 (203).

Accordingly, oil pressure is formed in the upper oil space 271 to lower the piston 210, and at the same time, the valve plate 211 is separated from the intake port 101 to perform vacuum suction pumping.

When the pump module 110 is stopped and the oil pressure of the oil passage 202 is released, the valve body 252 closes the oil passage 202 by the elasticity of the spring 253 of the operation valve, When the oil pressure in the upper oil space 271 is released due to the opening of the oil passage 203 passing through the piston 210 and the oil passage 131 to the piston 210, the piston 210 rises due to the elastic force of the return spring 220, The integrally moving valve plate 211 is raised to block the inlet port 101 and prevent the oil from flowing back to the vacuum equipment. At this time, the oil staying in the upper oil space is pushed up by the return spring and is recovered through the oil passage 1 and the oil passage 3.

Such a conventional technique has some serious problems. When the pump module is stopped, the return spring 220 slowly returns to the upper oil space while pushing up the oil filled in the upper oil space. As a result, the return time is delayed. There is a problem that the fluid such as foreign matter flows backward to the vacuum equipment from the vacuum pump during the lag of time and seriously damages the operating valve 250. The operating valve 250 prevents the piston upper oil space 271 and the oil reservoir 131, And when the pump 3 is operated normally, the flow path 3 (203) is shut off. When the oil is contaminated by the constituents of the working material to be pumped or the foreign substance is contained in the oil, the foreign matter Is deposited between the outer diameter of the valve body, which is the clearance oil passage 254, and the inner wall of the valve space, thereby obstructing the operation of the valve body 252. As a result, the upper oil space 271 and the oil passage 3 are opened and oil pressure is not formed in the oil passage 201 and the valve plate 211 is not opened. The operation valve 250 is installed in the body of the first cylinder 111 of the pump module 110 so that the operation valve 250 is connected to the pump module 170 The valve body 252, the spring 253, and the valve space 251 for operating the valve body are additionally provided to increase the number of parts and assemblies, and the valve body 252, There is a problem that the manufacturing cost is increased due to the precision machining of the valve space.

In order to solve such a problem, as shown in FIG. 2, a pump housing 70, which is provided with a piston, a piston operating space and a flow path, which is resiliently biased by a spring to shut off the intake port 101 when the pump module is stopped, A rotary valve type vacuum pump (Patent Publication No. 10-2005-0029747) including a backflow prevention valve device provided with a valve cover (80) for guiding the lifting and lowering of the piston and maintaining the airtightness of the working space is disclosed. A valve stem 12 is coupled to an upper portion of the valve plate 11 for opening and closing the oil chamber 101 and the working space 71 is divided into an upper oil space 71a and a lower oil space 71b, A piston 10 having an oil passage P for communicating the lower oil space 71a with the lower oil space 71b; A first spring (20) installed below the piston to resiliently urge the piston (10); An oil passage A (31) extending from the oil pump provided on the pump module side to the upper oil space (71a) of the piston; And an oil passage B (32) communicating with the oil reservoir from the lower oil space (71b) of the piston.

However, even in the case of such an improved invention, the backflow prevention structure is still complicated, resulting in a high frequency of occurrence of faults and an increase in production cost.

[Prior Art Literature]

Published Patent No. 10-2005-0029747

In order to solve the above-mentioned problems, the object of the present invention is as follows.

First, it is an object of the present invention to provide a vacuum pump suction port having a simple structure, which reduces manufacturing cost and improves durability.

Secondly, another object of the present invention is to provide a vacuum pump inlet of a new structure which can minimize the increase of air resistance and the generation of noise according to a high flow rate during the initial operation of the vacuum pump.

Thirdly, another object of the present invention is to provide a vacuum pump inlet having a new structure that can be quickly replaced only when a part needs to be replaced due to deterioration or damage.

Technical features of the present invention, which is created to achieve the object of the present invention, are as follows.

The present invention relates to a suction port which is attached to the outside of a vacuum pump, and is a tubular member which serves as an air inflow passage. The tubular member includes a first flow path (101) of small diameter inserted into the body of the vacuum pump, A suction port body (100) forming a second flow path (102) protruding outward; A buoyant body support 110 provided at a boundary between the first flow path 101 and the second flow path 102 inside the inlet port body 100 and spaced apart from each other and protruding upward; A buoyant body 200 mounted on the buoyant body support 110; A tubular member fastened to the threaded portion formed on the outer circumferential surface of the suction port body 100 to provide a passage for air and having a large diameter providing a space for the buoyancy body 200 together with the second flow path 102 An inlet cap 300 forming a small-diameter fourth flow path 304 for preventing the third flow path 303 from separating from the buoyancy body 200; And the fourth passage (304), and abuts against the buoyant body (200) which rises when the oil in the vacuum pump flows backward to close the oil passage And an O-ring for sealing (410) for sealing.

Technical effects of the configuration of the present invention are as follows.

First, since the structure is simple, the manufacturing cost can be reduced and the durability can be improved.

In other words, the structure in which the buoyant body 200 having a simple structure is mounted in the buoyant body support 110 in the suction port, can secure the oil passage and prevent the oil from flowing out of the vacuum pump by blocking the oil passage when the oil flows backward The manufacturing cost of the bar can be reduced and durability can be improved.

Second, during the initial operation of the vacuum pump, it is possible to minimize the increase of air resistance and the generation of noise according to the high flow rate.

In other words, when a high-speed air flows around the buoyancy body 200 by applying a buoyancy body having a surface groove 210 like a golf ball or applying a conical buoyancy body, the air resistance and the generated noise are reduced So that the working efficiency of the vacuum pump is not affected.

Third, when parts need to be replaced due to aging or damage, it is possible to quickly replace only those parts, which can drastically reduce maintenance costs.

In other words, even if the sealing O-ring 410 and the buoyant body 200 are damaged, the inlet cap 300 can be simply opened and the corresponding parts can be replaced quickly and conveniently, thereby reducing the maintenance cost.

Figures 1 and 2 illustrate the prior art.
3 shows a specific embodiment of the inlet body 100. Fig.
FIG. 4 shows a specific embodiment of the inlet cap 300.
5 shows a state in which (a) the buoyant body 200 is mounted on the buoyant body support 110, (b) when the oil flows backward, the buoyant body 200 rises and comes in close contact with the sealing o- Respectively.
FIG. 6 shows another embodiment of the buoyancy body 200 in which (a) the surface groove 210 is formed on the surface of the lower hemisphere, (b) the upper portion is conical and the lower portion is hemispherical, (c) (D) a case where the upper portion is hemispherical and the lower portion is cone-shaped, respectively.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention relates to a suction port attached to the outside of a vacuum pump.

3, the suction port body 100 is a tubular member that serves as an air inflow passage as shown in FIG. 3. The suction port body 100 includes a first flow path 101 of small diameter inserted into the body of the vacuum pump, The second flow path 102 of the large diameter is formed.

3, a flange portion having a bolt hole through which the bolt passes may be provided on the outer side of the intake port body 100. The bolt may be coupled to the flange portion to connect the inlet port body 100 to the body of the vacuum pump do.

A plurality of buoyant support rods 110 protrude upward to support the buoyant buoyant body 200 at the boundary between the first flow path 101 and the second flow path 102 inside the suction port body 100, The passage of the air is maintained in a space where the body support 110 does not protrude, so that the vacuum pump operates normally.

The buoyant body 200 is mounted on the buoyant body support 110 and behaves like a buoyant body 200. The buoyant body 200 is preferably made of a material having specific gravity that can rise when the oil flows backward or a back pressure of a certain magnitude or more is applied It can be manufactured in a state where the interior is empty by using various kinds of general synthetic resin materials.

4, the suction port cap 300 is a tubular member that provides a passage for air and is fastened to a threaded portion formed on the upper outer circumferential surface of the suction port body 100. In the upper end portion of the suction port body 100, An O-ring 420 for tightening the O-ring 420 closely contacts the inner surface of the suction port 300 to maintain an air leak or an oil leak through the joint between the suction port body 100 and the suction port 300, .

The suction port cap 300 is provided with a second flow path 102 and a large-diameter third flow path 303 for providing a space for the buoyant body 200 and a fourth small- Thereby forming a flow path 304.

5, the buoyant body 200 is formed in a space defined by the second flow path 102 and the third flow path 303 in a state where the inlet port body 100 and the inlet port cap 300 are coupled to each other, When the vacuum pump is normally operated, the buoyant body 200 is lowered to be mounted on the buoyant support 110 as shown in FIG. 5 (a). When the oil flows backward, So that the fourth flow path 304 is shut off and the oil does not flow out of the vacuum pump.

The sealing O-ring 410 is attached to the boundary between the third flow path 303 and the fourth flow path 304 and abuts against the buoyant body 200 that rises as the oil in the vacuum pump flows backward to close the gap, Thereby preventing the backflow oil from flowing out through the four flow paths 304.

The channel expanding groove 120 is cut at a preset depth along the region where the buoyant body support 110 is absent at the edge of the boundary between the first channel 101 and the second channel 102 of the suction port body 100, So that air flows smoothly at the beginning of operation of the vacuum pump.

The buoyant body 200 may be manufactured in various shapes as shown in FIG. 6 as well as a simple sphere as shown in FIG.

6 (a), the surface of the upper hemisphere of the sphere is a smooth curved surface, and a plurality of surface grooves 210 are formed on the surface of the lower hemisphere in a shape similar to the surface of the golf ball And the weight of the lower hemisphere is biased so as to be heavier than the weight of the upper hemisphere to prevent the up-down conduction. Accordingly, the problem that the surface grooves 210 are in contact with the sealing O-ring 410 due to the up-and-down conduction of the buoyant body 200 prevents a gap from being generated and the surface grooves 210 are provided, It is possible to expect more effects at the initial stage of operation of the vacuum pump in which a large amount of air passes at a high speed.

6 (b), the lower portion is a hemisphere and the upper portion is conical. In the case of FIG. 6 (c), the lower hemispherical surface of the buoyant body 200 is provided with a plurality of surface grooves 210 .

6 (d), unlike FIG. 6 (b), the lower portion is conical and the upper portion is hemispherical. Although not shown in the accompanying drawings, the surface grooves 210 may be formed on the conical lower surface in FIG. 6 (d).

When the conical shape is introduced in this way, resistance and noise due to high-speed air passing through the suction port of the vacuum pump can be reduced, and the operation efficiency can be improved.

In some cases, the buoyancy body 200 having an elliptical rotor shape may be used instead of a simple circular shape, although not shown in the drawing.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Addition or deletion of a technique, and limitation of a numerical value are included in the protection scope of the present invention.

The following symbols apply to FIGS. 3 to 6 and do not apply to FIGS. 1 and 2, which are drawings related to the prior art.
100: inlet port body
101: First Euro
102:
110: buoyancy support
120: Euro expanding groove
200: Buoyant body
210: surface groove (dimple)
300: inlet cap
303: Third Euro
304: 4th euro
410: O-ring for sealing
420: O-ring for fastening

Claims (6)

The present invention relates to a suction port attached to the outside of a vacuum pump,
Shaped member that serves as an air inflow passage and has a small-diameter first flow path 101 inserted into the body of the vacuum pump and a large-diameter second flow path 102 protruding outside the body of the vacuum pump A suction inlet body (100);
A buoyant body support 110 provided at a boundary between the first flow path 101 and the second flow path 102 inside the inlet port body 100 and spaced apart from each other and protruding upward;
A buoyant body 200 mounted on the buoyant body support 110;
A tubular member fastened to the threaded portion formed on the outer circumferential surface of the suction port body 100 to provide a passage for air and having a large diameter providing a space for the buoyancy body 200 together with the second flow path 102 An inlet cap 300 forming a small-diameter fourth flow path 304 for preventing the third flow path 303 from separating from the buoyancy body 200; And
And a sealing member which is attached to a boundary portion between the third flow path 303 and the fourth flow path 304 and abuts against the buoyant body 200 rising when the oil in the vacuum pump flows backward, An O-ring 410;
And,
The buoyancy member (200)
A sphere,
The surface of the upper hemisphere is a smooth surface,
A plurality of surface grooves 210 in the form of a golf ball surface are provided on the surface of the lower hemisphere to reduce the resistance and noise of air passing around the buoyancy body 200,
The weight of the lower hemisphere is relatively heavier than the weight of the upper hemisphere,
When the oil in the vacuum pump flows back and the buoyant body 200 is raised, the surface of the upper hemisphere of the buoyant body abuts against the sealing O-ring 410 to prevent the backflow of the oil,
The upper end of the suction port body 100 is provided with a fastening O-ring 420 which closely contacts the inner surface of the suction port 300 to maintain airtightness.
Further,
A channel extension groove 120 is formed at a predetermined depth along a region where the buoyant support 110 is absent at a boundary surface between the first channel 101 and the second channel 102 of the suction port body 100.
Wherein the vacuum pump has a backflow prevention function. The present invention relates to a suction port attached to the outside of a vacuum pump,
Shaped member that serves as an air inflow passage and has a small-diameter first flow path 101 inserted into the body of the vacuum pump and a large-diameter second flow path 102 protruding outside the body of the vacuum pump A suction inlet body (100);
A buoyant body support 110 provided at a boundary between the first flow path 101 and the second flow path 102 inside the inlet port body 100 and spaced apart from each other and protruding upward;
A buoyant body 200 mounted on the buoyant body support 110;
A tubular member fastened to the threaded portion formed on the outer circumferential surface of the suction port body 100 to provide a passage for air and having a large diameter providing a space for the buoyancy body 200 together with the second flow path 102 An inlet cap 300 forming a small-diameter fourth flow path 304 for preventing the third flow path 303 from separating from the buoyancy body 200; And
And a sealing member which is attached to a boundary portion between the third flow path 303 and the fourth flow path 304 and abuts against the buoyant body 200 rising when the oil in the vacuum pump flows backward, An O-ring 410;
And,
The buoyancy member (200)
The lower part is hemisphere, the upper part is coniform,
The upper conical surface is a smooth curved surface,
A plurality of surface grooves 210 in the form of a golf ball surface are provided on the lower hemispherical surface to reduce the resistance and noise of air passing around the buoyancy body 200,
The weight of the lower hemisphere is relatively heavy compared to the weight of the upper cone,
When the oil in the vacuum pump flows back and the buoyant body 200 is raised, the upper conical surface of the buoyant body abuts against the sealing O-ring 410 to prevent the backflow of the oil,
The upper end of the suction port body 100 is provided with a fastening O-ring 420 which closely contacts the inner surface of the suction port 300 to maintain airtightness.
Further,
A channel extension groove 120 is formed at a predetermined depth along a region where the buoyant support 110 is absent at a boundary surface between the first channel 101 and the second channel 102 of the suction port body 100.
Wherein the vacuum pump has a backflow prevention function. The present invention relates to a suction port attached to the outside of a vacuum pump,
Shaped member that serves as an air inflow passage and has a small-diameter first flow path 101 inserted into the body of the vacuum pump and a large-diameter second flow path 102 protruding outside the body of the vacuum pump A suction inlet body (100);
A buoyant body support 110 provided at a boundary between the first flow path 101 and the second flow path 102 inside the inlet port body 100 and spaced apart from each other and protruding upward;
A buoyant body 200 mounted on the buoyant body support 110;
A tubular member fastened to the threaded portion formed on the outer circumferential surface of the suction port body 100 to provide a passage for air and having a large diameter providing a space for the buoyancy body 200 together with the second flow path 102 An inlet cap 300 forming a small-diameter fourth flow path 304 for preventing the third flow path 303 from separating from the buoyancy body 200; And
And a sealing member which is attached to a boundary portion between the third flow path 303 and the fourth flow path 304 and abuts against the buoyant body 200 rising when the oil in the vacuum pump flows backward, An O-ring 410;
And,
The buoyancy member (200)
The lower part is conical, the upper part is hemisphere,
The upper hemispherical surface is a smooth curved surface,
A plurality of surface grooves 210 in the form of a golf ball surface are provided on the lower conical surface to reduce the resistance and noise of air passing around the buoyant body 200,
The weight of the lower cone is relatively heavier than the weight of the upper hemispherical shape,
When the oil in the vacuum pump flows backward to raise the buoyant body 200, the upper hemispherical surface of the buoyant body abuts against the sealing O-ring 410 to prevent the backflow of the oil,
The upper end of the suction port body 100 is provided with a fastening O-ring 420 which closely contacts the inner surface of the suction port 300 to maintain airtightness.
Further,
A channel extension groove 120 is formed at a predetermined depth along a region where the buoyant support 110 is absent at a boundary surface between the first channel 101 and the second channel 102 of the suction port body 100.
Wherein the vacuum pump has a backflow prevention function. delete delete delete

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