KR100986342B1 - Compressure For High Pressure Air And Gas - Google Patents

Abstract

The present invention relates to a high-pressure air or gas compressor, the piston is inserted into the cylinder of the multi-stage high-pressure air or gas compressor is formed with an insertion groove for inserting the piston ring, the insertion groove is formed through the hole, Depending on the degree of compression, the number and shape of the through holes are selected and applied differently.

Accordingly, when air or gas is introduced into the through hole, the rubber ring and the piston ring are pushed outward by the pressure of the air or the gas to be in close contact with the inner surface of the cylinder, thereby preventing the air or the gas from leaking from the cylinder.

Cylinder, piston, through hole, rubber ring, piston ring

Description

Compressure For High Pressure Air And Gas

The present invention relates to a high pressure air or gas compressor that compresses air or gas at high pressure, and more particularly, to a high pressure air or gas compressor that prevents air from leaking and makes compression better.

In general, an air compressor compresses, produces, and stores air at high pressure, and supplies it to each high-pressure tool as needed. A conventional air compressor includes a compressor body and a tank for storing compressed air.

In addition, such an air compressor is usually formed in multiple stages, and the compressed air from the cylinder of the lower stage through the piston is sequentially compressed to a high pressure while moving to the cylinder of the high stage.

That is, the connecting rod connected to the crankshaft which transmits the rotational force of the motor vertically reciprocates the piston, whereby the air is sucked and compressed inside the cylinder surrounding the piston.

The air compressor is classified into a low pressure air compressor and a high pressure air compressor according to the compression capacity. Among the high pressure air compressors, each cylinder is configured in series when the air is compressed, and the compressed air is passed through a single discharge path. It is formed into a structure to be supplied.

Here, the piston does not move in the cylinder, and is formed by forming a rocking prevention groove so that the sucked air does not leak and insert the rocking prevention ring in the groove.

However, the piston of the conventional high pressure air compressor is not able to push the piston ring to the outside, ie in close contact with the cylinder, it was difficult to maintain the airtight between the piston and the cylinder.

An object of the present invention is to solve the problems as described above, to provide a high-pressure air or gas compressor that is easy to maintain the airtight between the piston and the cylinder by pushing the piston ring fitted to the piston outward.

In order to achieve the above object, the high pressure air or gas compressor of the present invention has a plurality of cylinders connected in series to form a multi-stage, and a piston is inserted into each of the multi-stage cylinders to move reciprocally to move from low to high stages. Compressed air is generated and finally compressed air is discharged from the high stage cylinder. The cylinder includes first to fourth stages, and the first stage to the fourth stage achieves a high pressure. Insertion grooves into which piston rings are inserted are formed in each of the first to fourth stage pistons inserted into the first to fourth stage cylinders, and a through hole is formed in the insertion groove, between the insertion groove and the piston ring. Is inserted into the rubber ring, the through hole of the first stage piston is formed to penetrate from the upper surface of the first stage piston to the uppermost insertion groove, The through hole of the second stage piston is spaced apart from the first through hole to be close to the longitudinal central axis of the second through piston from the first through hole formed from the upper surface of the second stage piston to the uppermost insertion groove. And a second through hole formed from an upper surface of the second stage piston to an insertion groove below the uppermost insertion groove, and the through hole of the third stage piston penetrates from an upper surface of the third stage piston to an uppermost insertion groove. A first through hole formed therein and a second through hole spaced apart from the first through close to the longitudinal center axis of the third end piston from an upper surface of the third end piston to an insertion groove below the uppermost insertion groove; And a bar of the insertion groove below the insertion groove in which the second through hole is formed from an outer side surface of the third stage piston adjacent to a lower portion of the opening side of the insertion groove in which the second through hole is formed. It is made of a third through-shaped inclined to the doc side, the insertion groove of the fourth stage piston is made of a plurality, the outer side of the piston adjacent to the lower side of the opening side of the insertion grooves in each region between the insertion grooves It characterized in that a plurality of through-holes inclined from the side to the bottom side of the insertion grooves.

delete

delete

delete

delete

In addition, the piston ring is characterized in that formed in multiple stages, such as a coil spring.

As described above, according to the piston of the high-pressure air or gas compressor according to the present invention, when air or gas is introduced into the through-hole, the rubber ring and the piston ring are pushed out by the pressure of the air or gas to be in close contact with the inner surface of the cylinder This prevents air or gas from leaking out of the cylinder.

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

The pistons 20 of the high pressure air or gas compressor according to the present invention are inserted into cylinders (not shown) of the high pressure air or gas compressor, respectively, and pistons 1P to 4P having different shapes are formed according to respective stages.

In this case, the diameter of the cylinder decreases as it goes from the first stage to the high stage, and thus, the diameter of the piston 20 also decreases as the diameter goes toward the high stage corresponding to the cylinder.

The piston 20 is formed in a cylindrical shape, a plurality of insertion grooves 21 formed with grooves along the outer surface of the piston 20 is formed at regular intervals. Then, the rubber ring 22 formed of a rubber-like material is inserted into the insertion groove 21, and the piston ring 23 is inserted again to contact the rubber ring 22.

Here, the rubber ring 22 is formed in a circular ring shape, the piston ring 23 is formed by rotating the circular shape 2 to 3 times like a spring.

In addition, the upper and lower portions of the piston 20, or both the upper and lower portions are formed with a rocking prevention groove 24 to assist the piston 20 does not move in the cylinder is fitted with a rocking prevention ring 25.

Here, the rocking prevention ring 25 has a ring shape, and some sections of the rocking prevention ring 25 are cut so that some sections of the ring shape are spaced apart from each other.

Then, a plurality of through holes 30 are connected to the insertion groove 21 in the upper surface or the outer peripheral surface of the piston 20 is formed.

In this case, the through hole 30 may be formed in various forms.

First, as shown in FIG. 1, the first through-hole 31 formed in the vertical direction from the upper surface of the first stage piston 1P is connected to the insertion groove 21a at the uppermost end and flows in from the outside of the first stage piston 20. Air or gas can be moved to the insertion groove (21a).

In addition, the inlet is blocked by the rubber ring 22 of the through hole 31 on the insertion groove 21a side.

Meanwhile, as shown in FIG. 2, the second stage piston 2P has a first through hole 31 connected from the upper surface to the insertion groove 21a at the uppermost end in the vertical direction, and is inserted into the insertion groove 21b at the bottom thereof. One more second through hole 32 in the vertical direction is formed.

The second through hole 32 is formed closer to the center side than the first through hole 31 when viewed from the upper surface of the second stage piston 2P, and the first through hole 31 and the second through hole 32 are separated from each other. It is formed with.

Accordingly, the vertically formed second through-hole 32 is vertically formed to the position of the insertion groove 21b and bent at the end thereof to be connected to the insertion groove 21b.

As shown in FIG. 3, the third stage piston 3P includes both the first through hole 31 and the second through hole 32 formed therein, and the insertion groove 21 b having the second through hole 32 formed therein. A third through hole 33 is further formed between the lower insertion grooves 21c of the insertion groove 21b.

At this time, the third through hole 33 is formed by connecting from the outer surface of the third stage piston (3P) to the insertion groove (21c) of the lower side formed with the second through hole (32), wherein the third through hole (33) It is preferable to form the inclined toward the insertion groove (21c) from the outer surface of the third stage piston (3P).

4 and 5, only the third through holes 33: 33a to 33e inclined toward the insertion grooves 21: 21a to 21e on the outer surface of the fourth stage piston 4P. . At this time, the third through holes 33: 33a to 33e are respectively formed in the insertion grooves 21: 21a to 21e formed in the fourth stage piston 4P.

In this case, the third through holes 33: 33a to 33e formed in the respective insertion grooves 21: 21a to 21e may be formed at the same position, and may be formed at staggered positions to be perpendicular to each other.

The first stage piston to the fourth stage pistons 1P to 4P are selectively used according to the number of cylinder stages and the degree of compression of each of the high-pressure air or gas compressors formed as described above, where more through holes 30 are formed. It is recommended to install in high voltage stage.

Operation of the piston (20: 1P ~ 4P) of the high pressure air or gas compressor configured as described above is as follows.

In the compression step for compressing air or gas in the cylinder, air or gas is introduced into the through hole 30 of the pistons 20: 1P to 4P to push the rubber ring 22 outward, that is, to the side in contact with the cylinder. The ring 23 is also pushed outward by the rubber ring 22.

Accordingly, the piston ring 23 is in close contact with the inner surface of the cylinder to facilitate the airtight maintenance of air or gas in the cylinder.

In addition, since the air or the gas does not push the rubber ring 22 in the suction step, the resistance is reduced between the cylinder and the piston, so that the movement is easy.

In addition, the fourth stage piston (4P) consisting of only the third through hole 33 is the same process as described above in several steps.

That is, even when the air or gas is not kept airtight in the rubber ring 22 or the piston ring 23 in the insertion groove 21a having the uppermost third through hole 33a, In 21b), the rubber ring 22 and the piston ring 23 are pushed outward.

In addition, since the pressure of air or gas increases as the pressure increases, the inner surfaces of the respective piston rings 23 and the cylinder are closely contacted by the third through holes 33a to 33e formed in each of the insertion grooves 21a to 21e. Or it is easy to keep the gas tight.

1 shows an embodiment of a low stage piston (first stage piston) according to the invention;

Figure 2 shows another embodiment of a piston (second stage piston) according to the present invention.

Figure 3 shows another embodiment of a piston (third stage piston) according to the present invention.

Figure 4 shows an embodiment of a high stage piston (fourth stage piston) according to the present invention.

5 is a cross-sectional view of the piston according to the embodiment of FIG. 4.

Explanation of symbols on the main components of the drawings

10: cylinder

20: piston

21: Insertion groove

22: rubber ring

23: piston ring

24: rocking groove

25: rocking ring

30: through

31: first through hole

32: second opening

33: third hole

Claims (6)

A plurality of cylinders are connected in series to form a multistage, and a piston is inserted into each of the multistage cylinders to reciprocate to generate high-pressure compressed air while going from the low stage to the high stage to discharge the finally compressed air from the high stage cylinder. High pressure air or gas compressor, The cylinder is composed of the first to fourth stages, the high pressure toward the fourth stage from the first stage, Insertion grooves 21 into which the piston ring 23 is inserted are formed in each of the first to fourth stage pistons 1P to 4P inserted into the first to fourth stage cylinders, The through hole 30 is formed in the insertion groove 21, A rubber ring 22 is inserted between the insertion groove 21 and the piston ring 23, The through-hole 30 of the first stage piston (1P) is made of a first through-hole 31 formed to penetrate from the upper surface of the first stage piston (1P) to the uppermost insertion groove (21a), The through hole 30 of the second stage piston 2P includes a first through hole 31 formed to penetrate from an upper surface of the second stage piston 2P to an uppermost insertion groove 21a, and the first through hole ( 31 spaced apart from the vertical central axis of the second stage piston 2P to penetrate from an upper surface of the second stage piston 2P to an insertion groove 21b below the uppermost insertion groove 21a. The second through-hole 32, The through hole 30 of the third stage piston 3P includes a first through hole 31 formed therethrough from an upper surface of the third stage piston 3P to an uppermost insertion groove 21a, and the first through hole ( 31 spaced apart from the vertical central axis of the third stage piston 3P and penetrating from an upper surface of the third stage piston 3P to an insertion groove 21b below the uppermost insertion groove 21a. The second through hole 32 is formed from an outer surface of the third stage piston 3P adjacent to the lower side of the opening side of the insertion groove 21b in which the second through hole 32 and the second through hole 32 are formed. A third through hole 33 formed to be inclined to the bottom side of the insertion groove 21c below the insertion groove 21b, The insertion groove 21 of the fourth stage piston 4P includes a plurality of insertion grooves 21a to 21e, and the through hole 30 of the fourth stage piston 4P includes the insertion grooves ( In each of the regions between 21a to 21e, the lower side of the opening side of the insertion grooves 21a to 21e and the outer side of the neighboring fourth stage piston 4P are inclined from the bottom side of the insertion grooves 21a to 21e. High pressure air or gas compressor, characterized in that consisting of a plurality of third through holes (33: 33a ~ 33e) formed. The method of claim 1, The piston ring 23 is a high pressure air or gas compressor, characterized in that formed in the form of a coil spring. delete delete delete delete

Images