KR100272946B1 - Structure of two-way valve - Google Patents

Abstract

PURPOSE: Structure of a two-way valve is provided to prevent the clogging of a pipe with a viscous fluid by making the flow direction of the fluid changed easily. CONSTITUTION: A two-way valve comprises a body(20) forming a T-shaped flow path to connect an upper pipe(15) with a lower pipe(16), valve seats(23) installed on the flow paths of the upper pipe and the lower pipe, an upper ball(21) movably installed between the valve seats on the flow path of the upper pipe to open and close the flow path, a lower ball(22) movably installed between the valve seats on the flow path of the lower pipe to open and close the flow path, and shafts(27) rotatably installed on respective valve seats and having protruded portions(37) for restraining the contacting of the balls with the valve seats. A sufficient sectional flow area is secured by the protrusions of the shafts when the upper ball contacts with the lower ball.

Description

Bidirectional valve structure

The present invention relates to a bidirectional valve structure, and more particularly, to a bidirectional valve structure for preventing the clogging of the pipe by the viscous fluid by allowing the flow direction of the fluid to be easily switched.

1 is a block diagram showing a conventional ball check valve in a partial cross section.

The ball check valve is composed of a body 10 having a T-shaped flow path and an upper sphere 11 and a lower sphere 12 mounted through a valve seat 13 therein. The upper tube 15 and the lower tube 16 are connected to the top and bottom of the body 10, respectively, and the pump 14 is connected to the middle of the body 10 to form a bidirectional pump. Although not shown, the pump 14 is generally composed of a cylinder and a piston and performs a pumping action by reciprocating the piston according to the movement of the frank shaft.

During operation of the pump 14, the fluid flowing into the lower tube 16 while pushing up the lower sphere 12 while the upper sphere 11 comes into close contact with the valve seat 13 and blocks the flow path in the backward stroke of the piston, causes the body to be pushed up. Filled in (10), the lower sphere 12 is in close contact with the valve seat 13 in the forward stroke of the piston is discharged to the upper tube (15) through the upper sphere (11) while blocking the flow path.

As described above, a valve having an upper sphere 11 and a lower sphere 12 having a check valve function is connected to the pump 14 to transfer the fluid in one direction. Such a valve may be a fluid having a viscosity such as mortar. When used for the purpose of transfer, there is a disadvantage in that the fluid is easily accumulated in the place where the flow is stopped and the pipeline is blocked.

Accordingly, the present invention is to solve the above-described disadvantages, by adding a configuration for switching the flow path to the ball check valve type to easily change the flow direction of the fluid to prevent the clogging of the pipe by the fluid having a viscous bidirectional It is an object to provide a valve structure.

1 is a block diagram showing a conventional ball check valve in a partial cross section.

2 is a block diagram showing the interior of the bidirectional valve according to the present invention.

Figure 3 is a block diagram showing a state after the operation of the bidirectional valve according to the present invention.

4 is a configuration diagram showing an operation mechanism of the bidirectional valve according to the present invention.

5 is a block diagram showing the interior of the bidirectional valve according to a modification of the present invention.

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

* Explanation of symbols for main parts of the drawings

10, 20, 50: body 11, 21,: upper sphere

12, 22: lower sphere 13, 23, 53: valve seat

14 pump 15 upper pipe

16: lower pipe 27, 57: shaft

37: projection 47, 67: boss

48: gear train

In order to achieve this object, the present invention includes a body 20 constituting a ″ T ″ -shaped flow path so that the upper pipe 15 and the lower pipe 16 are connected to both sides on which the pump 14 is mounted; Valve seats 23 mounted in pairs on flow paths on the upper pipe 15 and the lower pipe 16 in the body 20; An upper sphere 21 mounted to be movable between the pair of valve seats 23 on the flow path on the upper pipe 15 side to open and close the flow path; A lower sphere 22 mounted on the lower channel 16 to move between the pair of valve seats 23 to open and close the channel; In addition, one surface of the protrusion 37 is rotatably mounted on each valve seat 23 and interferes with the upper and lower spheres 21 and 22 so as not to be in close contact with the valve seat 23. The edge is characterized in that it comprises a shaft (27).

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

2 is a block diagram showing the interior of the bidirectional valve according to the present invention.

The valve according to the present invention uses a body 20 constituting a ″ T ″ shaped flow path so that the upper pipe 15 and the lower pipe 16 are connected to both sides on which the pump 14 is mounted. The body 20 The valve seat 23 is mounted in pairs on the flow path on the upper pipe 15 and the lower pipe 16, respectively. When the pump 14 is centered, the pair of valve seats 23 having the same configuration is mounted on the upper side thereof, and the pair of valve seats 23 having the same configuration is mounted on the lower side thereof. .

In addition, according to the present invention is mounted on the flow path on the upper pipe 15 side between the pair of valve seat 23 is mounted to the upper sphere 21 for opening and closing the flow path, the lower pipe 16 A lower sphere 22 is mounted on the side flow path so as to be movable between the pair of valve seats 23 to open and close the flow path.

The pair of valve seats 23 are mounted so as to maintain an interval such that the upper or lower spheres 21 or 22 can sufficiently open the flow path. If the interval between the valve seat 23 is too small, the amount of movement of the upper sphere 21 or the lower sphere 22 is insignificant, so that the transfer resistance of the fluid is increased and the transfer amount is reduced.

Further, according to the present invention, the shaft 27 is rotatably mounted on each valve seat 23 independently. Since the shaft 27 reduces the flow path through the valve seat 23, it is preferable to appropriately increase the flow cross-sectional area of the valve seat 23 in view of this. Packing is interposed in the rotational contact of the shaft 27 to maintain the airtightness according to the transport of the fluid. The packing may also serve to prevent the shaft 27 from being arbitrarily rotated by the resistive force of the fluid transfer.

One surface of the shaft 27 is provided with a protrusion 37 that interferes with the upper and lower spheres 21 and 22 so as not to be in close contact with the valve seat 23. The protrusion 37 is positioned at the center of the flow path formed in the valve seat 23. The protruding portion 37 has a height such that the flow cross-sectional area formed on the valve seat 23 when the upper sphere 21 or the lower sphere 22 is in contact with each other is sufficiently secured.

3 is a block diagram showing a post-operation state of the bidirectional valve according to the present invention. In FIG. 2, the upper sphere 21 and the lower sphere 22 respectively contact the protrusions 37 at the upper shaft 27 to open the flow path, thereby transferring the fluid from the lower tube 16 to the upper tube 15. On the other hand, in FIG. 3, the upper sphere 21 and the lower sphere 22 respectively contact the protrusions 37 on the lower shaft 27 to open the flow path, thereby opening the lower tube 16 in the upper tube 15. To convey fluid.

In FIG. 2 and FIG. 3, it can be seen that the projections 37 on the upper and lower sides are kept in a state perpendicular to each other in either case. In this way, the upper and lower protrusions 37 may be interlocked so as to form a right angle at all times to transfer the fluid in one selected direction and to prevent the backflow of the fluid in the opposite direction. Arrows shown in the upper and lower tubes 15 and 16 indicate the direction in which the fluid is conveyed.

At this time, the shaft 27 of the present invention has a boss 47 having a rectangular cross section for exposing the direction of the protrusion 37 and exposed to the outside. For example, when the boss portion 47 has a rectangular cross section, it is easy to rotate the shaft 27 using a tool such as a spanner. At one end of the shaft 27, the position of the protrusion 37 is displayed so that there is no error during the flow path switching operation. As shown in the figure, mounting the shafts 27 so that the bosses 47 all face the same direction facilitates the flow path switching operation.

4 is a block diagram showing the operation mechanism of the bidirectional valve according to the present invention.

As a variant of the invention, the shaft 27 may also be configured to additionally have a gear train 48 to each boss portion 47 that meshes with each other so as to rotate simultaneously at the same angle. The gears mounted on the respective boss portions 47 can rotate the shaft 27 at the same angle by using the same specifications as modulus, number of teeth, and the like.

When the distance between the shafts 27 is not constant, it is also possible to use an idle gear as shown. Depending on the gear arrangement in the gear train 48, the rotation direction of the shaft 27 may be different from each other, but it does not affect the realization of the above-described second and third embodiments.

When the gear train 48 is used in this way, while the other shaft 27 is also interlocked while the one shaft 27 is rotated, the turning direction of the flow path becomes more rapid and accurate. Mounting the handle on one of the gear trains 48 may also improve the convenience of operation.

Meanwhile, although not shown in the figure instead of the above-described gear train 48, it is also possible to use sprockets and chains. In this case, when one shaft 27 is rotated, the other shafts 27 rotate in the same direction so that the interlocking motion of the shaft 27 is used rather than using the gear train 48 to realize the states of FIGS. 2 and 3. Note that this is likely to be incorrect.

When the bidirectional valve of the present invention is used for transferring viscous fluid such as mortar, the mortar is transferred from the lower tube 16 to the upper tube 15 in the state of FIG. In addition to changing the transfer direction of the mortar from the tube 15 to the lower tube 16, it is possible to eliminate the accumulation of mortar in the place where the flow is stopped by using for a long time in one direction.

5 is a configuration diagram showing the inside of the bidirectional valve according to a modification of the present invention, which surrounds the outer circumferential surfaces of the upper and lower spheres 21 and 22 instead of the shaft 27 mounted on the valve seat 23. It is also possible to use a shaft 57 that is molded in a semicircular shape and rotatably mounted on the body 50.

In this case, the thickness of the conventional valve seat 23 can be reduced, so that the overall size can be reduced. When the shaft 57 is rotated by 180 °, the flow path switching function as shown in FIGS. 2 and 3 is performed. . The boss portion 67 is formed at one end of the shaft 57 to facilitate rotation. When the gear train 48 as shown in FIG. 4 is applied to the boss portion 67, the flow path switching operation is performed quickly at the same time.

FIG. 6 is a cross-sectional view of the AA portion of FIG. 5, in which a shaft 57 formed using rod-shaped material restrains the upper ends of the upper and lower spheres 21 and 22 while stopping the movement of the fluid. So that the upward transfer proceeds.

On the other hand, an embodiment of the present invention is shown and described with respect to the clogging of the fluid pipe having a viscosity, but can also be applied to the purpose of conveying a fluid that does not have a viscosity, such as water in both directions.

The bidirectional valve structure of the present invention having the above-described configuration and action has an effect of preventing the blockage of the pipe by the viscous fluid by adding a configuration for converting the flow path to the ball check valve so that the flow direction of the fluid is easily changed. have.

Claims (4)

A body constituting a flow path having a “T” shape so that the upper pipe and the lower pipe are connected to both sides on which the pump is mounted; Valve seats are mounted in pairs on the flow path of the upper tube and the lower tube side in the body; An upper sphere mounted on the upper flow path on the upper pipe side so as to be movable between the pair of valve seats to open and close the flow path; A lower sphere configured to be movable between the pair of valve seats on the flow path on the lower pipe side to open and close the flow path; And a shaft rotatably mounted on each of the valve seats, the shaft having protrusions on one surface of the upper and lower spheres interfering with each other so as not to be in close contact with the valve seat. 2. The bidirectional valve structure according to claim 1, wherein the shaft has a boss portion that is exposed to the outside and has a rectangular cross section for changing the direction of the protrusion. 3. The bidirectional valve structure according to claim 2, wherein the shaft further has gear trains meshing with each other so as to rotate simultaneously at the same angle. The bidirectional valve structure according to claim 1, wherein a shaft that is formed in a semicircle shape surrounding the outer circumferential surfaces of the upper and lower spheres is rotatably mounted on the body instead of the shaft mounted on the valve seat.