KR200477444Y1 - Slurry carrrying pump using oil pressure cylinder - Google Patents

Abstract

The present invention relates to a slurry transfer pump, which comprises a main cylinder (100), a main piston (110) reciprocating within the main cylinder (100) and sucking and discharging the slurry, A first valve housing 210 installed on a part of an outer circumferential surface of the main cylinder 100; A first discharge passage (D1) formed on the lower surface of the first valve housing (210) and communicating with the main cylinder (100); A first suction passage (G1) formed on the front surface of the first valve housing (210) in a direction perpendicular to the first discharge passage (D1) and having a suction pipe (P1); A first valve piston (212) reciprocating within the first valve housing (210); A first hydraulic cylinder (216) reciprocating the first valve piston (212); A second valve housing (230) installed at a part of an outer circumferential surface of the main cylinder (100) in a direction orthogonal to the first valve housing (210); A second suction passage (G2) formed on the front surface of the second valve housing (230) and communicating with the main cylinder (100); A second discharge passage D2 formed on a lower surface of the second valve housing 230 in a direction perpendicular to the second suction passage G2 and having a discharge pipe P2; A second valve piston (232) reciprocating within the second valve housing (210); And a second hydraulic cylinder (236) for reciprocating the second valve piston (232). The present invention relates to a slurry transfer pump using a hydraulic cylinder.
According to the present invention, the sealing force of the valve is excellent and the prevention of the pinching is excellent, so that the suction force and the discharge power of the pump are improved, thereby maximizing the transfer ability of the pump.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a slurry transfer pump using a hydraulic cylinder,

The present invention relates to a slurry transfer pump, and more particularly, to an improved slurry transfer pump capable of transferring a slurry, which is a particle-shaped transfer product, with a full sealing force by attaching a hydraulic cylinder.

Generally, a pump is a device that applies mechanical energy from a prime mover such as an electric motor or an internal combustion engine to impart kinetic energy and pressure energy to the fluid. Depending on the structure and operation principle, a space is provided in the reciprocating portion or the rotary portion, And a turbo type that imparts kinetic energy to the fluid introduced by the rotation of the impeller.

Among them, the volumetric type is mainly used for transporting particulate matter, that is, slurry.

According to Patent No. 0225027, there is shown an example in which a slurry is also conveyed in a centrifugal pump using an impeller. However, particulate matter such as slurry usually causes suction pressure to drop when the impeller is operated, Use is being excluded.

On the other hand, the volumetric pump is a type in which suction and discharge are performed by using a cylinder and a piston, and it is well known from EP0550236.

However, since such a cylindrical slurry transfer pump mainly comprises a ball valve which is opened and closed when the slurry is sucked and discharged according to the reciprocating motion of the piston when the slurry is sucked into the cylinder, which is a kind of suction chamber during slurry transfer The particulate matter is adhered to the inner wall of the pipe or sandwiched between the ball valves which are opened or closed, thereby failing to perform a complete shutoff function, and thus the suction force and the discharge power of the slurry are reduced and the transfer ability of the pump is remarkably deteriorated.

The present invention has been made in view of the above-mentioned problems in the prior art, and it is an object of the present invention to provide a cylinder type slurry transfer pump capable of opening and closing a valve by hydraulic pressure, And to provide a slurry transfer pump using a hydraulic cylinder that maximizes the capability.

The present invention provides a slurry transfer pump including a main cylinder 100 and a main piston 110 reciprocating in the main cylinder 100 to suck and discharge the slurry, A first valve housing 210 installed on a part of an outer circumferential surface of the main cylinder 100; A first discharge passage (D1) formed on the lower surface of the first valve housing (210) and communicating with the main cylinder (100); A first suction passage (G1) formed on the front surface of the first valve housing (210) in a direction perpendicular to the first discharge passage (D1) and having a suction pipe (P1); A first valve piston (212) reciprocating within the first valve housing (210); A first hydraulic cylinder (216) reciprocating the first valve piston (212); A second valve housing (230) installed at a part of an outer circumferential surface of the main cylinder (100) in a direction orthogonal to the first valve housing (210); A second suction passage (G2) formed on the front surface of the second valve housing (230) and communicating with the main cylinder (100); A second discharge passage D2 formed on a lower surface of the second valve housing 230 in a direction perpendicular to the second suction passage G2 and having a discharge pipe P2; A second valve piston (232) reciprocating within the second valve housing (210); And a second hydraulic cylinder (236) for reciprocating the second valve piston (232).

A plurality of first fixing rods 218 are fixed to a rear end surface of the first valve housing 210. A first fixing plate 220 is fixed to an end of the first fixing rods 218, The first hydraulic cylinder 216 is fixed to the first fixed plate 220; A plurality of second fixing rods 238 are fixed to a rear end surface of the second valve housing 230. A second fixing plate 240 is fixed to an end of the second fixing rods 238, The second hydraulic cylinder 236 is fixed to the fixed plate 240.

The configuration including the main cylinder 100 and the first and second valve housings 210 and 230 and the first and second hydraulic cylinders 216 and 236 may be configured such that the longitudinal direction of the main cylinder 100 And also has a feature of being provided in a pair symmetrically.

In the pump according to the present invention, the main piston 110 moves backward in the main cylinder 100 in a state in which the first hydraulic cylinder 216 is reversed and the second hydraulic cylinder 236 is advanced, The first hydraulic cylinder 216 is advanced and the second hydraulic cylinder 236 is advanced and the main piston 110 advances to discharge the fluid.

According to the present invention, the sealing force of the valve is excellent and the prevention of the pinching is excellent, so that the suction force and the discharge power of the pump are improved, thereby maximizing the transfer ability of the pump.

1 is an exemplary perspective view of a slurry transfer pump according to the present invention.
FIG. 2 is a cross-sectional view of the main part of the slurry transfer pump according to the present invention.

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

Prior to the description of the present invention, the following specific structures or functional descriptions are merely exemplified for the purpose of describing the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. It is to be understood, however, that the appended claims are intended to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the appended claims, rather than limiting the embodiments in accordance with the concepts herein.

As shown in FIGS. 1 and 2, the slurry transfer pump according to the present invention includes a main cylinder 100.

At this time, the main cylinder 100 may be provided with a pair symmetrically on both sides as shown in the figure.

That is, if the main cylinder 100 is coupled with another main cylinder 100 'to provide a pair, the two pumps can be operated by using one main piston 110, so that the pumping ability is doubled .

In the following description, however, the valve 200 connected to both the main cylinders 100 and 100 'has the same configuration, so only one will be described as an example.

Although not shown in detail, the main piston 100 is installed in the main cylinder 100 and reciprocates within the main cylinder 100 to suck and discharge the object, that is, the slurry. Since it is known as an existing technology, a detailed description thereof will be omitted.

The first valve housing 210 is fixed to one side of the main cylinder 100, that is, a part of the outer circumferential surface of the main cylinder 100 opposite to the end of the main piston 110.

The interior of the first valve housing 210 communicates with the main cylinder 100 through a first exhaust passage D1 and is communicated with the first valve housing 210 in a direction orthogonal to the first exhaust passage D1. A first suction passage G1 is formed on a front surface of the first suction passage 210 and a suction pipe P1 is connected to the first suction passage G1.

A first valve piston 212 is reciprocally mounted within the first valve housing 210. A first cylinder rod 214 is connected to a rear end of the first valve piston 212, The first cylinder rod 214 is connected to the first hydraulic cylinder 216.

In addition, a plurality of first fixing rods 218 are fixedly connected to the rear end of the first valve housing 210 so as not to interfere with the first valve piston 212 and the first cylinder rod 214, The first fixing plate 220 is fixed to an end of the first fixing rod 218 and the first hydraulic cylinder 216 is fixed to the first fixing plate 220.

A second valve housing 230 is disposed in a direction orthogonal to the first valve housing 210 on the other side of the main cylinder 100, that is, a part of the outer circumferential surface of the main cylinder 100 opposite to the end of the main piston 110. .

At this time, the inside of the second valve housing 230 is communicated with the main cylinder 100 through a second suction passage G2 formed on the front surface, and the second valve housing 230 is connected to the second suction passage G2, A second exhaust passage D2 is formed on a lower surface of the valve housing 230 and a discharge pipe P2 is connected to the second exhaust passage D2.

A second valve piston 232 is reciprocatably installed in the second valve housing 230. A second cylinder rod 234 is connected to a rear end of the second valve piston 232, The second cylinder rod 234 is connected to the second hydraulic cylinder 236.

In addition, a plurality of second fixing rods 238 are fixedly connected to the rear end of the second valve housing 230 so as not to interfere with the second valve piston 232 and the second cylinder rod 234, The second fixing plate 240 is fixed to an end of the second fixing rod 238 and the second hydraulic cylinder 236 is fixed to the second fixing plate 240.

As described above, the sludge transfer pump according to the present invention has a cylinder type valve.

The sludge transfer pump according to the present invention having such a configuration has the following operating relationship.

First, when the first hydraulic cylinder 216 is moved backward and the second hydraulic cylinder 236 is advanced, the main piston 110 moves backward in the main cylinder 100.

Then, the first suction passage G1 and the first discharge passage D1 are opened, and the second suction passage G2 and the second discharge passage D2 are closed.

Accordingly, the suction force generated by the backward movement of the main piston 110 acts on the suction pipe P1, and the slurry in the suction pipe P1 passes through the first suction passage G1 to the inside of the first valve housing 210 And then flows into the main cylinder 100 through the first discharge passage D1 of the first valve housing 210. [

In this state, the first hydraulic cylinder 216 is advanced, and the second hydraulic cylinder 236 is moved backward, so that the main piston 110 advances.

Then, the first suction passage G1 and the first discharge passage D1 are closed, and the second suction passage G2 and the second discharge passage D2 are opened.

Accordingly, the slurry sucked into the main cylinder 100 is pushed by the pumping pressure of the main piston 110 and flows into the second valve housing 230 through the second suction passage G2, 2 discharge line D2 to the discharge pipe P2.

As the process is repeatedly and rapidly performed, the slurry in the suction pipe P1 can be discharged to the discharge pipe P2 using the suction pressure and the discharge pressure of the main cylinder 100, thereby pumping the slurry to a desired location As shown in FIG.

In particular, as described at the beginning, when the main cylinders are installed in pairs, the amount of transfer can be increased, and the transfer time can be reduced.

In this embodiment, since the valve itself is implemented by a hydraulic cylinder, particulate matter, that is, slurry is adhered to the inner wall of the first and second valve housings 210 and 230, or the first and second suction passages G1 and G2, Since the first and second valve pistons 212 and 232 are pushed out with a strong pressure even if they are caught on the first and second discharge flow paths D1 and D2, It is possible to completely block and seal the pipe diameter at the time of suction and discharge of the slurry by the operation of the main piston 110 and the suction force and discharge pressure due to pipe stenosis or sealing failure, So that the phenomenon of falling does not occur.

In addition, the maintenance period can be extended, and the cost of replacing the repair can be reduced, which makes it possible to extend the service life.

100: main cylinder 110: main piston
200: valve 210: first valve housing
230: second valve housing

Claims (4)

1. A slurry transfer pump comprising: a main cylinder (100); a main piston (110) reciprocating in the main cylinder (100) and sucking and discharging the slurry;
A first valve housing 210 installed on a part of an outer circumferential surface of the main cylinder 100;
A first discharge passage (D1) formed on the lower surface of the first valve housing (210) and communicating with the main cylinder (100);
A first suction passage (G1) formed on the front surface of the first valve housing (210) in a direction orthogonal to the first discharge passage (D1) and having a suction pipe (P1);
And a rear portion of the first valve housing 210 reciprocates back and forth in the first valve housing 210 in a state where the rear end of the first valve housing 210 protrudes from the rear surface of the first valve housing 210, A valve piston 212;
A first cylinder rod 214 connected to the rear surface of the first valve piston 212 so as to be inserted in a front end thereof and not exposed to the first discharge passage D1 when the first valve piston 212 reciprocates;
A first hydraulic cylinder 216 connected to a rear end of the first cylinder rod 214 and reciprocating the first valve piston 212;
A second valve housing (230) installed at a part of an outer circumferential surface of the main cylinder (100) in a direction orthogonal to the first valve housing (210);
A second suction passage (G2) formed on the front surface of the second valve housing (230) and communicating with the main cylinder (100);
A second discharge passage D2 formed on a lower surface of the second valve housing 230 in a direction orthogonal to the second suction passage G2 and having a discharge pipe P2;
And a rear portion of the second valve housing (230) is reciprocated back and forth in the second valve housing (230) in a state of protruding to the rear surface of the second valve housing (230) A valve piston 232;
A second cylinder rod 234 connected to the rear surface of the second valve piston 232 so as to be inserted into the front end of the second valve piston 232 and not exposed to the second discharge passage D2 when the second valve piston 232 reciprocates; And
A second hydraulic cylinder (236) connected to a rear end of the second cylinder rod (234) and reciprocating the second valve piston (232); / RTI >
The configuration including the main cylinder 100 and the first and second valve housings 210 and 230 and the first and second hydraulic cylinders 216 and 236 is the same as that of the main cylinder 100, Wherein the pair of slurry conveying pumps are symmetrically arranged in a longitudinal direction of the slurry conveying pump. The method of claim 1,
A plurality of first fixing rods 218 are fixed to a rear end surface of the first valve housing 210. A first fixing plate 220 is fixed to an end of the first fixing rods 218, The first hydraulic cylinder 216 is fixed to the fixed plate 220;
A plurality of second fixing rods 238 are fixed to a rear end surface of the second valve housing 230. A second fixing plate 240 is fixed to an end of the second fixing rods 238, And the second hydraulic cylinder (236) is fixed to the fixed plate (240). delete A main cylinder 100;
A main piston 110 reciprocating in the main cylinder 100 to suck and discharge the slurry;
A first valve housing 210 installed on a part of an outer circumferential surface of the main cylinder 100;
A first discharge passage (D1) formed on the lower surface of the first valve housing (210) and communicating with the main cylinder (100);
A first suction passage (G1) formed on the front surface of the first valve housing (210) in a direction orthogonal to the first discharge passage (D1) and having a suction pipe (P1);
And a rear portion of the first valve housing 210 reciprocates back and forth in the first valve housing 210 in a state where the rear end of the first valve housing 210 protrudes from the rear surface of the first valve housing 210, A valve piston 212;
A first cylinder rod 214 connected to the rear surface of the first valve piston 212 so as to be inserted in a front end thereof and not exposed to the first discharge passage D1 when the first valve piston 212 reciprocates;
A first hydraulic cylinder 216 connected to a rear end of the first cylinder rod 214 and reciprocating the first valve piston 212;
A second valve housing (230) installed at a part of an outer circumferential surface of the main cylinder (100) in a direction orthogonal to the first valve housing (210);
A second suction passage (G2) formed on the front surface of the second valve housing (230) and communicating with the main cylinder (100);
A second discharge passage D2 formed on a lower surface of the second valve housing 230 in a direction orthogonal to the second suction passage G2 and having a discharge pipe P2;
And a rear portion of the second valve housing (230) is reciprocated back and forth in the second valve housing (230) in a state of protruding to the rear surface of the second valve housing (230) A valve piston 232;
A second cylinder rod 234 connected to the rear surface of the second valve piston 232 so as to be inserted into the front end of the second valve piston 232 and not exposed to the second discharge passage D2 when the second valve piston 232 reciprocates; And
A second hydraulic cylinder (236) connected to a rear end of the second cylinder rod (234) and reciprocating the second valve piston (232); / RTI >
The configuration including the main cylinder 100 and the first and second valve housings 210 and 230 and the first and second hydraulic cylinders 216 and 236 is the same as that of the main cylinder 100, 1. A slurry transfer pump using a pair of hydraulic cylinders symmetrically arranged in the longitudinal direction,
When the first hydraulic cylinder 216 is reversed and the second hydraulic cylinder 236 is advanced, the main piston 110 moves backward in the main cylinder 100 to suck the fluid,
Wherein the main piston (110) advances and discharges the fluid in a state in which the first hydraulic cylinder (216) is advanced and the second hydraulic cylinder (236) is in a reverse state.

Images