KR100865908B1 - Booster pump - Google Patents

Abstract

A booster pump includes a valve body having changeable elevation angle. Therefore, the booster pump prevents abrasion of the circumference of the valve body and a guideline locking part, and extends the lifetime of the pump. The booster pump comprises an air supply part(111), a drain part(112), an exhaustion part, a housing, a piston, a slide valve(5), a piston shaft, and a connection pipe(6). The slide valve provides a valve body, a subsidence part, and a guide locking part(53). A plurality of grooves are formed at the outer side of valve body. The subsidence part is formed corresponding to the grooves. The guide locking part guides the elevation of the valve body while diversifying ascent and descent angle and the length.

Description

Booster pump

The present invention relates to a booster pump, and more particularly to a booster pump that can prevent the slide valve portion that changes the flow of air from being easily damaged.

Generally, booster pumps are referred to as low pressure air pressure (minimum 0.2-7 kg / cm ² ).

It refers to a pump capable of raising the pressure of a liquid or gas (hereinafter referred to as "fluid") to 2000 kg / cm ² or more.

Therefore, the present invention is an improvement of the conventional booster pump. First, the conventional booster pump will be described.

Figure 4 is a cross-sectional view showing a conventional booster pump.

Conventional booster pumps; It is formed to be reduced in the upper portion of the main operating space (11) formed in the middle, the upper and lower valve operating space 12 is provided with air supply, the drain (111, 112), and to be reduced in the lower portion of the main operating space (11) A housing (1) formed and including a fluid compression space (13) having fluid inlets and outlets (131, 132) on both sides; A compression piston 3 inserted into the fluid compression space 13, an operation piston 4 mounted horizontally in the main operation space 11, and a slide valve unit 100 mounted in the valve operation space 12. A lifting piston shaft 2 provided with; It consists of a connecting pipe (6) for interconnecting the lower portion of the main operating space 11 and the middle of the valve operating space (12).

The slide valve unit 100 is inserted into the valve operation space 12 so as to be lifted up and down, and an outer protruding jaw 201 is formed at an outer circumference thereof and upper and lower circumferential grooves 202 and 203 at upper and lower ends thereof. The formed valve body 200, a plurality of horizontal movement locking unit 300 is provided in the circumference of the valve operating space 12 and selectively inserted into the upper and lower circumferential grooves (202, 203), and the valve body ( It is provided between the spring elastic part 400 provided between the inside of the 200 and the lifting piston shaft 2, and the lifting piston shaft 2 which is between the said spring elastic part 400 and the operation piston 4. As shown in FIG. It consists of a working tube (500).

In addition, the horizontal moving locking unit 300, the locking shaft 301 is to be moved forward and backward due to the spring force of the 302. And the horizontal moving locking portion 300 is typically provided with four at equal intervals around the valve operating space (12).

In addition, the spring shot portion 400, the projection jaw 401 and the stop ring 402 of the lower and upper periphery of the inner hole of the valve body 200, and the projection jaw 401 and the stop ring 402 of An operating lifting body 406 inserted between the upper and lower operating plates 403 and 404 provided between the upper and lower operating plates 403 and 404 and the lifting piston shaft 2 between the upper and lower operating plates 403 and 404 through the compression spring 405 therebetween. It consists of.

In addition, the fluid inlet and outlet parts 131 and 132 are provided with a check valve 133 to prevent the back flow of the fluid.

Therefore, when air is introduced into the valve operating space 12 through the air supply 111, the introduced air flows into the upper portion of the main operating space 11, thereby lowering the operating piston 4, thereby compressing the compressed piston. Move (3) to the compression position. Then, the valve body 200 constituting the slide valve unit 100 is lowered, so that the locking shaft 301 constituting the horizontal moving locking unit 300 is located at the lower circumference of the valve body 200. It is located in the groove 203.

Then, the air flowing into the air supply 111 is introduced into the connecting pipe 6 through a space formed around the valve body 200, and then flows into the lower portion of the main working space 11 to operate the piston 4. To the top again. Then, as the working piston 4 is raised, the compression piston 3 is moved to the suction position, and the valve body 200 constituting the slide valve part 100 is raised, thereby raising the horizontal moving locking part 300. Locking shaft 301 constituting the is located in the upper circumferential groove 202 located in the lower circumference of the valve body (200).

In the process of lifting and lowering the operating piston 4 and the valve body 200 as described above, the air is drained from the air drain 112 formed in the valve operating space 12.

That is, while the above operation is repeated, the fluid supplied through the fluid inlet 131 is compressed to be continuously discharged to the fluid outlet 132.

However, in the operation as described above, when the valve body constituting the slide valve portion is compressed and stored in the compression spring inside to switch the lifting direction, when the upper or lower operating plate reaches a certain position, the valve body is momentarily about a minute Lifting operation is performed more than 400 times.

Therefore, a severe friction phenomenon occurs between the locking shaft constituting the horizontal moving locking portion and the circumferential surface of the valve body in the process of repeating the rapid lifting and lowering the valve body as described above.

Therefore, there was a problem that a severe wear phenomenon occurs in the locking shaft that slides horizontally with the circumference of the valve body.

Accordingly, the present invention has been invented to solve the conventional problems as described above, by providing a guide locking portion for guiding the lifting and lowering of the valve body so that the angle can be changed, wear of the circumference of the valve body and the guide locking portion It is an object to provide a booster pump that can be prevented.

In addition, there is another object to further increase the pumping efficiency by reusing the force stored in the expansion spring constituting the guide locking portion.

In addition, the upper and lower stoppers for controlling the valve body are provided at upper and lower portions of the valve body to be lifted and lowered to prevent excessive shear force from occurring in the snap pins constituting the guide locking portion during operation.

The present invention for achieving the above object, the upper and lower portions of the main operating space, the air supply, the valve operating space having a drain portion and the fluid inlet, discharge housing having a compression space having a discharge portion, and the fluid compression space A lifting piston shaft having a compression piston inserted therein, an operation piston mounted on the main operation space, and a slide valve unit mounted on the valve operation space, and interconnecting a lower portion of the main operation space and a middle of the valve operation space. A booster pump comprising a connector; The slide valve portion, the valve body is formed in the valve operating space and the intermediate projection jaw formed with a plurality of recessed grooves on the outside, and formed in a corresponding position of the respective recessed grooves around the valve operating space And a booster pump including a depression portion and a guide locking portion for guiding the momentary elevation of the valve body while the angle and length of the valve body are changed between the depression grooves and the depressions.

In addition, the guide locking portion, the outer end is in close contact with the recessed portion and the inside is formed with an insertion hole is opened inside, the snap pin is movably inserted into the insertion hole of the tube and one end is in close contact with the recessed groove And, it is characterized in that it is composed of a spring stretched on the other side of the snap pin.

In addition, the recessed groove and the depression is formed as a conical groove, the other end of the tube and one end of the snap pin is characterized in that formed in a conical shape.

The valve body may further include a circumferential recessed groove formed in the upper and lower portions of the outer circumference.

In addition, the circumference of the main operating space is characterized in that consisting of a metal tube consisting of a single plate.

In addition, the circumference of the working piston is characterized in that the O-ring is recessed.

As described above, the present invention has an effect of maximally extending the life of the pump by providing a guide locking portion for guiding the lifting and lowering of the valve body to prevent the wear phenomenon around the valve body and the guide locking portion. There is.

In addition, by reusing the force stored in the expansion spring constituting the guide locking portion to further improve the pumping efficiency, there is also an effect of providing a high-efficiency booster pump.

In addition, the upper and lower stoppers for controlling the valve body are provided at upper and lower parts of the elevating valve body to prevent excessive shear force from being generated on the snap pins constituting the guide locking part during operation, thereby preventing failure in advance. have.

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

1 is a cross-sectional view showing a pump of the present invention.

Thus, the pump of the present invention, the upper and lower parts of the main operating space 11, the air supply, the valve operating space 12 having the drain portion (111, 112) and the fluid compression space having a fluid inlet, discharge portion (131, 132) 13 ) Is provided with a housing (1), a compression piston (3) inserted into the fluid compression space (13), an operation piston (4) and the valve operation space (12) mounted to the main operation space (11). A lifting piston shaft 2 provided with a slide valve portion 5 to be mounted, and a connecting pipe 6 interconnecting a lower portion of the main operating space 11 and a middle of the valve operating space 12. In the booster pump, the phenomenon of abrasion of the valve body (51) constituting the slide valve part (5) and the guide locking portion (53) for guiding the lifting and lowering of the valve body (51) is improved. Characterized in that it can be minimized.

That is, the slide valve 5 constituting the present invention is inserted into the valve operating space 12, the valve body 51 is provided with an intermediate protrusion 511 formed with a plurality of recessed grooves 512 on the outside. And a plurality of recesses 113 formed at corresponding positions of the respective recesses 512 around the valve operation space 12, and each of the recesses 512 and the recess 113. It includes a guide locking portion 53 for guiding the instantaneous lifting and lowering of the valve body 51 while the angle and length of the valve body 51 during the lifting and lowering. In addition, the depression 113 is formed on the inside of the cap that is fastened to the valve operating space 12 so that the guide locking portion 53 can be easily assembled from the outside.

And the guide locking portion 53, the outer end is in close contact with the depression 113, the inner side of the tube 531 is formed with an insertion hole is opened, and the insertion hole of the tube 531 to be movable One end is inserted into a snap pin 532 that is in close contact with the recessed groove 512, and is composed of an elastic spring 533 that is installed on the other side of the snap pin 532. In addition, the guide locking portion 53 is provided with a plurality of equal intervals around the valve operating space (12).

In particular, the slide valve portion is provided between the spring shot portion 54 provided between the inside of the valve body 51 and the lifting piston shaft 2, and the spring shot portion 54 and the operating piston 4. It further includes an operation tube 55 provided between the lifting piston shaft 2.

In addition, the spring shot 54 is formed of the projection jaw 541 and the stop ring 542 and the projection jaw 541 and the stop ring 542 provided around the lower and upper portions of the inner hole of the valve body 51, respectively. An operating lifting body 546 inserted into the lifting piston shaft 2 between the upper and lower operating plates 543 and 544 provided up and down through the compression spring 545 and the upper and lower operating plates 543 and 544. It consists of.

FIG. 2 is an enlarged view of a portion A of FIG. 1, wherein the recess 512 and the recess 113 are formed as a conical groove, and the other end of the tube 531 and one end of the snap pin 532 are conical. It is formed as.

The valve body 51 further includes a circumferential recessed groove 513 formed in the upper and lower portions of the outer circumference.

In addition, the circumference of the main operating space 11 is composed of a metal tube composed of a single plate, thereby simplifying the structure of the main operating space 11 constituting the housing 1, thereby reducing the cost of manufacturing the pump. . In addition, it is preferable to use an aluminum tube having strong workability and corrosion resistance as the metal tube.

In addition, the O-ring 41 is recessedly mounted around the operating piston 4 to improve the adhesion between the circumference of the operating piston 4 and the circumferential surface of the main operating space 11 during the operation of the operating piston 4. To ensure the stability of the operation.

Hereinafter, the operational relationship of the present invention configured as described above are as follows.

Figure 3 shows the operating relationship according to the present invention, Figure 3a shows the falling state, Figure 3b shows the falling state, Figure 3c shows the rising state, Figure 3d shows the rising state.

When operating the pump according to the present invention, when the air flows into the valve operating space 12 into the air supply 111, the introduced air is introduced into the upper portion of the main operating space 11, the operating piston By lowering (4), the compression piston 3 is moved to the compression position (see FIG. 3A).

Then, the valve body 51 constituting the slide valve portion 5 is lowered, thereby maintaining the position where the inside of the guide locking portion 53 is inclined downward (see FIG. 3B).

Then, the air flowing into the air supply 111 is introduced into the connecting pipe 6 through a space formed around the valve body 51, and then flows into the lower portion of the main working space 11 to operate the piston 4. This is pulled upward again (see FIG. 3C).

Then, as the working piston 4 is raised, the compression piston 3 is moved to the suction position, and the valve body 51 constituting the slide valve portion 5 is raised. Therefore, when the valve body 51 is raised as described above, the guide locking portion 53 in which the inner side is inclined downward is maintained to be inclined again to the raised position (see FIG. 3D).

In addition, in the process of elevating the operating piston 4 and elevating the valve body 51 as described above, the operation of draining air from the air drain 112 formed in the valve operating space 12 is performed.

Accordingly, as the above operation is repeatedly performed, the fluid supplied through the fluid inlet 131 is compressed to be continuously discharged to the fluid outlet 132.

More specifically, as shown in FIGS. 1 to 3, when the valve body 51 is operated while repeatedly moving up and down, the snap pins 532 constituting the guide locking portion 53 are elastic springs. The expansion and contraction through 533 supports the lifting and lowering of the valve body 51 by simply changing the angle.

Therefore, when the valve body 51 is elevated, the guide locking portion 53 simply changes its angle, so that the inner side of the snap pin 532 constituting the guide talking portion 53 and the outside of the pipe 531 are worn out. The phenomenon can be minimized, and a recess formed around the recess 512 and the valve operating space 12 of the valve body 51 in which the inner end and the outer end of the guide locking portion 53 are in close contact with each other. The wear phenomenon of 113 can be minimized.

Therefore, the service life of the pump can be extended to the maximum by minimizing the wear of the valve body 51 and the guide locking portion 53.

In addition, the recessed groove 512 formed around the outer circumference of the valve body 51 and the recessed portion 113 formed around the inner circumference of the valve operating space are formed as conical grooves, and the pipe forming the guide locking portion 53. Since the outer end of the 531 and the inner end of the snap pin 532 is formed in a conical shape, the wear phenomenon during operation can be minimized.

That is, as the inner and outer ends of the guide locking portion 53 is in conical contact with the recessed groove 512 and the recessed portion 113 as described above, the occurrence of wear can be reduced to a minimum by reducing the contact area to a minimum. It is.

Moreover, the characteristic of the pump which concerns on this invention is characterized by the operation | movement which raises and lowers the valve body 51 instantaneously through the springing action of the spring shot part 54 which comprises the slide valve part 5.

Therefore, in the process of raising or lowering the valve body 51 instantaneously, the pumping efficiency can be further improved by adding the elastic force stored in the elastic spring 533 constituting the guide locking portion 53 to the operating force. It also has advantages.

In addition, an upper stopper 7 configured as a lower end of the upper cover 14 constituting the housing 1 is provided at an upper portion of the valve body 51, and a lower portion of the valve body 51 is provided at the valve. The lower stopper 8 is provided in the lower portion of the working space 12 is provided.

And the lower stopper 8 is composed of a snap ring fitted around the lower portion of the valve operating space (12).

Therefore, in the process of repeatedly raising and lowering the valve body 51, the raising and lowering of the valve body 51 is interrupted by the upper stopper 7 and the lower stopper 8, so that the shear force transmitted to the guide locking part 53 is reduced. It can be reduced to a minimum.

Therefore, the snap pin 532 constituting the guide locking portion 53 can be prevented in advance from being easily bent or broken due to the shear force.

1 is a cross-sectional view showing a pump of the present invention.

2 is an enlarged view of a portion A of FIG. 1;

3 shows an operating relationship according to the invention,

       3a shows a state of descent,

       3b is a lowered state,

       3C shows the rising state,

       3D shows the elevated state.

Figure 4 is a cross-sectional view showing a conventional booster pump.

5 is an enlarged view of a portion B of FIG. 4.

<Explanation of symbols for the main parts of the drawings>

1: housing

    11: main operating space

    12: valve operating space

         111: air supply portion, 112: air drain portion, 113: depression

    13 fluid compression space

         131: fluid inlet, 132: fluid outlet, 133: check valve

    14: top cover

2: lifting piston shaft

3: compression piston

4: working piston

5: slide valve unit

    51: valve body

         511: middle projection jaw, 512: recessed groove, 513: peripheral groove

    53: guide locking unit

         531: tube, 532: snap pin, 533: elastic spring

    54: spring bullet portion

         541: protruding jaw, 542: retaining ring, 543: upper working plate,

         544: lower working plate, 545: compression spring, 546: working lifting body

    55: operating tube

6: connector

7: operating tube

8: lower stopper

Claims (6)

Upper and lower portions of the main operating space 11 are provided with a valve operating space 12 having air supply and drain portions 111 and 112 and a fluid compression space 13 having fluid inlet and outlet portions 131 and 132. ), A compression piston 3 inserted into the fluid compression space 13, an operation piston 4 mounted on the main operation space 11, and a slide valve part 5 mounted on the valve operation space 12. A booster pump comprising a lifting piston shaft (2) having a) and a connecting pipe (6) interconnecting a lower portion of the main operating space (11) and a middle of the valve operating space (12); The slide valve unit 5, A valve body 51 inserted into the valve operation space 12 and having an intermediate protruding jaw 511 having a plurality of recessed grooves 512 on the outside thereof; A plurality of recesses 113 formed at corresponding positions of the respective recesses 512 around the valve operation space 12; A plurality of guide locking parts 53 for guiding the lifting and lowering of the valve body 51 while the angle and length of the valve body 51 are changed between each of the recessed grooves 512 and the recess 113, Booster pump comprising a. According to claim 1, The guide locking portion 53, And the outer end is in close contact with the recess 113, the inner tube 531 is formed with an insertion hole is opened inside, A snap pin 532 which is inserted into the insertion hole of the tube 531 to be movable and one end thereof is in close contact with the recessed groove 512; Booster pump, characterized in that consisting of elastic springs (533) that is installed on the other side of the snap pin (532). The method of claim 2, wherein the recess 512 and the recess 113 is formed as a conical groove, Booster pump, characterized in that the other end of the tube (531) and one end of the snap pin (532) is formed in a conical shape. 3. An upper stopper (7) according to claim 1 or 2, wherein an upper stopper (7) consisting of a lower end of an upper cover (14) constituting said housing (1) is provided at an upper portion of said valve element (51) Booster pump, characterized in that the lower portion of the valve body 51 is provided with a lower stopper (8) provided in the lower portion of the valve operating space (12). The booster pump according to claim 1 or 2, wherein the circumference of the main working space (11) is composed of a metal tube composed of a single plate. Booster pump according to claim 5, characterized in that an o-ring (41) is recessedly mounted around the actuating piston (4).

Images