KR200447996Y1 - Booster pump - Google Patents

Abstract

The present invention relates to a booster pump, and more particularly, to a booster pump that prevents fluid from rising from the fluid compression space along the circumferential surface of the compression piston and outflowing into the main operating space. A booster pump comprising a vertical through hole formed so as to penetrate a lifting piston shaft at an upper portion of the booster pump, wherein a fluid pumping fluid seals a circumference of the lifting piston shaft and rises along a circumferential surface of the lifting piston shaft. Drain packing means for draining the filled fluid tank is characterized in that it is provided.

Drain packing means, main seal packing, secondary seal packing, air outlet

Description

Booster pump

The present invention relates to a booster pump, and more particularly to a booster pump to prevent the fluid from the fluid compression space is raised along the circumferential surface of the compression piston to flow out to the main operating space.

In general, a booster pump refers to a pump capable of raising the pressure of a liquid or gas (hereinafter referred to as "fluid") to low pressure air pressure (minimum 0.2-7 kg / cm ² ) 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.

4 is a view illustrating a state in which an air driving piston of a conventional booster pump is raised, FIG. 4A is a cross-sectional view, FIG. 4B is a plan view, and FIG. 4C is an enlarged view of portion C of FIG. 4A. 5 is a view showing a state in which the air driving piston of the conventional booster pump is lowered, Figure 5a is a sectional view, Figure 5b is a plan view.

Thus, the conventional booster pump, as shown in Figure 4, is provided with a working space 11 therein, the upper and lower shaft mounting holes 12 and the fluid compression space (13) in the operating space (11). A lifting piston including a housing (1) provided with a) and an air driving piston (21) inserted into the shaft mounting hole (12) and the fluid compression space (13) and provided in the working space (11). A shaft 22, a spring 22 provided between the air driving piston 21 and a lower portion of the working space 11, a fluid inlet 131 provided in cooperation with the fluid compression space 13, and It is composed of a fluid discharge part 132 and the air driving valve unit 3 which is provided inside the upper portion of the working space 11 to elevate the air driving piston 21 through the inlet and discharge of air from the outside.

In addition, the air driving valve unit 3 includes a vertical hole 31 including an upper operation chamber 311 provided at an upper side of the housing 1, and downward through a spring 322 in the vertical hole 31. A valve shaft 32 including the upper sealing cap 321 and the air passing through the circumference and the inside thereof is formed in a longitudinal direction at the side of the vertical hole 31 and communicates with the vertical hole 31. It includes a communication hole 331 and the air inlet hole 33 is always hung air pressure, and is provided in the transverse direction in communication with the upper operating chamber 311 in the rear of the vertical hole 31 is moved to the left and right through the air pressure The lateral hole 34 to which the direction switching splice 341 is mounted is provided in communication with the operating space 11 on the left side of the horizontal hole 34 so as to raise the operating space when the air driving piston 21 is raised ( 11) is provided between the air hole 36 for discharging the air of the silencer 14 (silencer), and between the shaft mounting hole 12 and the vertical hole (31) It includes a discharge hole 35 for discharging the air of the air drive valve portion 3 to the outside when the lifting piston shaft (2) is lowered.

In addition, the fluid inlet 131 and the fluid outlet 132 is provided with check valves (131a, 132a) to prevent the back flow of the fluid.

In addition, a vertical through hole 133 through which the lifting piston shaft 2 is mounted is formed in an upper portion of the fluid compression space 13, and a sealing packing 134 is mounted around an inner circumference of the vertical through hole 133. It is.

On the other hand, the outer side of the housing 1 is provided with a silencer 14 for discharging the air passing through the air hole 36 from the working space (11).

Therefore, as shown in FIGS. 4 and 5, when the lifting piston shaft 2 is raised, air pressure is always applied to the air inlet hole 33, and the upper surface of the air driving piston 21 is the valve shaft. (32) is pushed upwards. Therefore, when the valve shaft 32 is pressed, the air flowing from the air inlet hole 33 moves the direction change splice 341 to the left side, and then flows into the working space 11 through the air hole 36. The driving piston 21 is lowered.

When the air driving piston 21 is lowered, the lifting piston shaft 2 is also lowered, thereby operating the chamber 311 through the periphery of the vertical hole 31 and the discharge hole 35 and the shaft mounting hole 12. ) And the air filled in the right side of the direction switching splicing 341 is discharged to the outside, and by this operation the direction changing splice 341 is moved to the right, and the air hole 36 is opened to the right. Then, as the spring 22 positioned below the air driving piston 21 is extended, the air driving piston 21 is raised due to the compression force of the spring 22, and the air filled in the working space 11 is filled with air holes ( After passing through 36, the air driving piston 21 is completed by being discharged to the silencer 14.

In addition, when the ascending of the air driving piston 21 is completed as described above, as described above, as the direction change splice 341 is moved to the left, the operation of lowering the air driving piston 21 proceeds.

Therefore, as described above, by repeatedly raising and lowering the air driving piston 21 through the operation of the air drive valve unit 3 and the compression force of the spring 22, a high-speed pumping operation is possible.

However, in the operation as described above, the lifting piston shaft is pumped while the lifting operation is performed more than about 400 times per minute.

Accordingly, as the lifting piston shaft repeats the rapid lifting as described above, the sealing packing formed on the inside of the piston through hole formed in the upper portion of the fluid compression space is rapidly worn, so that the fluid in the fluid compression space is along the circumferential surface of the compression piston. It rises and flows into the main working space.

Therefore, the fluid consumption of the fluid increases as the fluid in the fluid compression space leaks into the working space.

In addition, as the fluid flowing into the working space leaks to the outside of the main body, the leaking fluid flows into the silencer provided on the main body side to contaminate the silencer. As it became dirty, the slippery surroundings had a dangerous problem for safety.

In addition, when the air is filled in the fluid compression space during the initial operation of the pump had a problem that the pumping efficiency is sharply lowered.

The present invention is designed to solve the above problems, by having a drain packing means for receiving the fluid rising along the circumference of the piston to guide the tank inside the piston through-hole formed in the upper portion of the fluid compression space, It is an object of the present invention to provide a booster pump that can prevent fluid from entering the working space from the fluid compression space.

In addition, there is another object to further improve the sealing effect by double sealing the lifting piston shaft through the main sealing packing and the auxiliary sealing packing.

In addition, there is another purpose to allow the air filled in the fluid compression space to be discharged to the outside at the initial pumping.

The present invention for achieving the above object, in the booster pump including a vertical through hole formed so that the lifting piston shaft through the upper portion of the fluid compression space, around the vertical through hole, sealing the circumference of the lifting piston shaft And a drain packing means for draining the fluid ascending along the circumferential surface of the lifting piston shaft to a fluid tank filled with a pumping fluid, wherein the drain packing means includes a main seal packing provided at a middle circumference of the vertical through hole, and the main seal. A drain bracket including a discharge hole formed at a side of the fluid inlet groove and having a fluid inlet groove formed around the inner circumference of the central through hole, and fixed to a lower portion of the main operating space to press the top of the drain bracket. Press plate and the drain hole for communicating the discharge hole and the fluid tank, characterized in that All.

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In addition, the middle of the drain hole, characterized in that the air discharge portion for selectively discharging the air in the fluid compression space to the fluid tank is further provided.

In addition, the air discharge portion is connected to the drain hole in the middle of the fluid compression space, the horizontal discharge hole including a tap portion formed in the inner exhaust hole and a small inner exhaust hole and the outside outside, and is fastened to the tab portion of the horizontal valve hole Characterized in that it comprises a valve bolt including a horizontal valve shaft for opening and closing the inner exhaust hole through the loosening and tightening.

In addition, the inside of the central through hole of the pressing plate, characterized in that the auxiliary sealing packing is further provided.

The present invention, as described above, can prevent the fluid from flowing into the main working space from the compression space to prevent the fluid is consumed to maximize the pumping efficiency, as well as to introduce the fluid into the working space Blocking has the effect of preventing fluid from leaking out of the working space to contaminate the silencer.

In addition, by double sealing the compression piston through the main seal packing and the secondary seal packing, there is also an effect that can block the amount of fluid rising along the compression piston through the secondary seal packing.

In addition, by discharging the air filled in the fluid compression space to the outside at the beginning of the pumping, there is also an effect that can be prevented in advance to lower the pumping efficiency.

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

1 is a perspective view illustrating a booster pump of the present invention, FIG. 2 is a cross-sectional view taken along line A-A of FIG. 1, and FIG. 3 is an enlarged view of portion B of FIG. 1.

Accordingly, the booster pump of the present invention includes a vertical through hole 133 formed so that the lifting piston shaft 2 penetrates the upper portion of the fluid compression space 13, and the periphery of the vertical through hole 133 is increased. There is provided a drain packing means (4) for sealing the circumference of the lifting piston shaft (2) and draining the fluid rising along the circumferential surface of the lifting piston shaft (2) to a fluid tank (7) filled with pumping fluid. It is characterized by.

The booster pump may include a housing 1 having an operating space 11 therein, and having a shaft mounting hole 12 and a fluid compression space 13 disposed above and below the operating space 11, An elevating piston shaft 2 including an air driving piston 21 inserted into the shaft mounting hole 12 and the fluid compression space 13 and provided in the working space 11, and the air driving piston ( A spring 22 provided between the lower portion 21 and the operating space 11, the fluid inlet 131 and the fluid discharge portion 132 provided in communication with the fluid compression space 13, the working space It is provided in the upper portion of the 11 is composed of an air drive valve unit 3 for elevating the air driving piston 21 through the inlet and discharge of air from the outside, the specific configuration and operation will be described in the prior art Therefore, in the following description of the present invention, the lifting operation of the lifting piston shaft (2) Names omitted.

The present invention, as described above, is provided with a vertical through hole 133 through which the lifting piston shaft 2 passes through the upper portion of the fluid compression space 13, and the vertical packing hole 133 has drain packing means. (4) is provided.

The main part of the present invention will be described in more detail as follows.

As shown in FIG. 3, the drain packing means 4 has a main seal packing 41 provided around a middle circumference of the vertical through hole 133 and presses an upper portion of the main seal packing 41 to form a center. The inner circumference of the through hole 421 is formed with a fluid inlet groove 422 and a drain bracket 42 including a discharge hole 423 formed on the side of the fluid inlet groove 422, and the drain bracket 42 The pressing plate 43 fixed to the housing 1 to press the upper portion, and the drain hole 5 for communicating the discharge hole 423 and the fluid tank 7 mutually.

That is, the drain hole 5 is provided with a connection pipe connected to the fluid tank 7, so that the fluid discharged through the train hole 5 flows back into the fluid tank 7.

In addition, the pressing plate 43 is fixed to the upper portion of the lower portion of the main operating space 11 formed in the housing 1 by a bolt, thereby pressing the drain bracket 42 from the upper side to the lower side.

In the middle of the drain hole 5, an air discharge part 6 for selectively discharging air in the fluid compression space 13 to the fluid tank 7 is provided.

In addition, the air discharge part 6 penetrates outwardly in communication with the drain hole 5 in the middle of the fluid compression space 13, and has an inner exhaust hole 611 having a small diameter and a tab part 612 formed on an inner outer side thereof. And a valve shaft 621 coupled to the tab portion 612 of the horizontal exhaust hole 61 to open and close the inner exhaust hole 611 through loosening and tightening. It is composed of a valve bolt (62).

On the other hand, the inside of the central through-hole 431 of the pressing plate 43 is further provided with an auxiliary sealing packing 432 that can prevent the fluid rises finely.

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

As shown in FIGS. 1 to 3, the fluid filled in the fluid tank 7 is compressed from the fluid inlet 131 while the lifting piston shaft 2 is lifted through the operation of the air driving valve part 3. The operation of discharging to the fluid discharge unit 132 is performed through the process of discharging.

And in compressing and conveying the fluid as described above, as mentioned in the prior art, the lifting piston shaft 2 is lifted and operated at least about 400 times per minute.

As described above, as the number of lifting and lowering of the lifting piston shaft 2 is increased, a phenomenon in which the main sealing packing 41 sealing the periphery of the lifting piston shaft 2 is rapidly worn occurs.

Therefore, a phenomenon in which the fluid filled in the fluid compression space 13 rises along the circumferential surface of the lifting piston shaft 2 is generated, and the rising fluid is formed in the middle of the central through hole 421 of the drain bracket 42. After entering the inside of the fluid inlet groove 422, and then pass through the discharge hole 35 formed in the drain bracket 42 is passed through the drain hole 5 to the fluid tank (7).

Therefore, as the above-mentioned fluid is drained to the fluid tank 7, the fluid rising along the circumferential surface of the lifting piston shaft 2, the fluid from the fluid compression space 13 enters the main working space 11. It can be prevented.

Thus, as described above, the fluid from the fluid compression space 13 is prevented from leaking into the main working space 11, so that the consumption of the fluid is increased in advance.

In addition, the fluid introduced into the main working space 11 is prevented from entering the main working space to prevent the fluid from leaking out of the housing. Therefore, it is possible to prevent the phenomenon that the silencer 14 is contaminated by preventing fluid from flowing into the silencer 14 provided at the side of the housing 1.

On the other hand, as shown in Figure 3, in the initial stage of pumping to operate the booster pump by releasing the valve bolt 62 of the air discharge section 6 to move the horizontal valve shaft 621 to the horizontal exhaust hole 61 The inner exhaust hole 611).

Then, the air filled in the fluid compression space 13 is moved through the drain pipe 5 through the inner exhaust hole 611 and the horizontal exhaust hole 61. Therefore, it is possible to prevent the phenomenon in which the pumping efficiency is lowered by preventing the air from remaining in the fluid compression space 13 at the beginning of the pumping.

1 is a perspective view showing a booster pump of the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is an enlarged view of a portion B of FIG. 1;

4 is a view showing a state in which the air driving piston of the conventional booster pump is raised,

       4A is a sectional view,

       4B is a plan view,

       4C is an enlarged view of a portion C of FIG. 4A.

5 is a view showing a state in which the air driving piston of the conventional booster pump is lowered,

       5A is a sectional view,

       5B is a plan view.

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

1: housing

    11: operating space

    12: shaft mounting hole

    13 fluid compression space

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

         132a: check valve, 133: vertical through hole

    14: silencer

2: lifting piston shaft

    21: Air Driven Piston

    22: spring

3: air drive valve

    31: vertical hole

         311: operating room

    32: valve shaft

         321: upper sealing cap, 322: spring

    33: air inlet hole

         331: communication hole

    34: horizontal hole

         341: diverting direction

    35: discharge hole

    36: air hole

4: Drain packing means

    41: main seal packing

    42: drain bracket

         421: center through hole, 422: fluid inlet groove, 423: outlet hole

    43: pressing plate

         431: center through hole, 432: secondary seal packing

5: drain hole

6: air outlet

    61: horizontal exhaust hole

         611: inner exhaust hole, 612: tab portion

    62: valve bolt

         621: horizontal valve shaft

7: fluid tank

Claims (5)

delete In the booster pump comprising a vertical through-hole 133 formed so that the lifting piston shaft 2 penetrates the fluid compression space 13, A drain sealing the periphery of the lifting piston shaft 2 around the vertical through hole 133 and draining the fluid rising along the periphery of the lifting piston shaft 2 to the fluid tank 7 filled with the pumping fluid. Packing means 4 is provided, The drain packing means 4 is a main sealing packing 41 provided around the middle of the vertical through hole 133, Pressing the upper portion of the main sealing packing 41 and the inner circumference of the central through hole 421 is formed with a fluid inlet groove 422 and a drain including a discharge hole 35 formed on the side of the fluid inlet groove 422 Bracket (42), Press plate 43 is fixed to the lower portion of the main operating space 11 to press the upper portion of the drain bracket 42, Booster pump, characterized in that consisting of a drain hole (5), the discharge hole 35 and the fluid tank (7) in communication with each other. The method of claim 2, wherein in the middle of the drain hole (5), Booster pump, characterized in that it is further provided with an air outlet (6) for selectively discharging the air in the fluid compression space (13) to the fluid tank (7). The method of claim 3, wherein the air outlet 6, A horizontal discharge hole 61 including an inner exhaust hole 611 having a small diameter and a tab portion 612 formed at an inner outer side of the fluid compression space 13 so as to communicate with the drain hole 5 in the middle; , The valve bolt 62 includes a horizontal valve shaft 32 that is connected to the tab portion 612 of the horizontal valve hole 61 to open and close the inner exhaust hole 611 through loosening and tightening. Booster pump. The inner side of the center through hole 431 of the pressing plate 43, Booster pump, characterized in that further provided with a sealing seal (432).

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