JP2004036809A - Check valve device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily adjust an opening/closing degree of a swing valve by facilitating adjustment of a weight of a check valve. <P>SOLUTION: This check valve device comprises a swing valve element 2 interposed in a horizontal flow path 1 and opening/closing the flow path 1, a lever 4 fixed to a valve shaft 3 of the swing valve element 2 and turning around the axis of the valve shaft 3 along with swing of the swing valve element 2, and a cylindrical tube 6 fixed to the lever 4. The tube 6 is fixed to the lever 4 in a manner that its longitudinal direction is along a rotation direction of the lever 4, accommodates a spherical weight 5 inside, and varies an opening/closing moment acting on the valve shaft 3 by the movement of the weight 5 accompanied with the turning of the lever 4. Because the weight 5 rolls and moves in the tube 6, a center of gravity is smoothly moved to the lever 4, and its trajectory is always constant, so as to stabilize an opening/closing action of the swing valve element 2. The spherical weight 5 is easily inserted in or pulled out of the tube 6, and if a metallic ball and an elastic ball with different specific gravities are used in combination, an opening/closing degree of the swing valve element 2 is easily adjusted. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a check valve device used for a pipe for transporting a liquid or a gas.
[0002]
[Prior art]
This type of check valve device using a swing valve element is disclosed in Japanese Patent Application Laid-Open No. 62-278385, Japanese Utility Model Publication No. 7-16946, etc., and is shown in FIGS. There is.
[0003]
For example, the check valve device shown in FIGS. 5 and 6 is fixed to the swing valve body 2 interposed in the flow path 1 and the valve shaft 3 of the swing valve body 2 and rotates together with the valve shaft 3. It consists of a lever 10. As shown in FIG. 6, a long space 11 extending from the base 10b to the tip 10a of the lever 10 is formed in the lever 10 in the longitudinal direction, and the space 11 is made of a fluid such as sand. 12 are enclosed. The gradient of the space 11 changes in accordance with the rotation of the lever 10, and the enclosed weight 12 flows in the space 11 in accordance with the change in the gradient.
[0004]
The check valve device shown in FIG. 7 includes a swing valve body 2 interposed in a flow path 1 and a lever 10 fixed to a valve shaft 3 of the swing valve body 2 and rotating together with the valve shaft 3. A weight 12 rotatably supported on a rail 11 whose gradient changes in accordance with the rotation of the lever 10. The weight 12 includes a shaft portion that is supported through the rail 11 and weight portions fixed to both ends of the shaft. The shaft rotates smoothly on the rail 11.
[0005]
Generally, when the amount of fluid flowing in the flow path 1 in the forward direction A is small, the oscillating check valve device does not exert a sufficient valve opening force on the oscillating valve body 2. As shown by arrow D, the swing valve body 2 may swing repeatedly near the fully closed position. Further, when the flow in the flow path 1 is stopped, when the swing valve body 2 closes and approaches the fully closed position, the closing moment acting on the valve shaft 3 in the valve closing direction decreases, so that the swing valve body 2 closes. The operation may stop halfway and the swing valve body 2 may swing repeatedly near the fully closed position. These repetitive swings not only impair the function of the check valve for stopping the flow of the fluid in the reverse direction B, but also impede the flow of the fluid in the forward direction A, which is not preferable for smooth fluid transfer.
[0006]
In order to prevent these repetitive swings, in the check valve device shown in FIGS. 5 and 6, the space 11 faces downward toward the downstream side when the swing valve body 2 is in the fully closed position. The lever 10 is located. The weight 12 flows in the space 11 in the direction of the distal end portion 10a (downstream side), moves away from the valve shaft 3, and exerts a closing moment on the valve shaft 3 by its own weight, so that the swing valve body 2 moves to the valve seat. It is designed to avoid repeated movements in contact.
[0007]
In this closed state, when the fluid flows in the flow path 1 in the forward direction A, the flow of the fluid causes the swing valve body 2 to slightly open and swing in the direction of the fully open position. Is rotated to change the space 11 downward toward the upstream side. The weight 12 flows in the space 11 toward the base 10 b (upstream side) and approaches the valve shaft 3, and reduces the closing moment acting on the valve shaft 3 by its own weight. However, the swing valve body 2 is easy to open, so that the flow of the fluid is hardly affected.
[0008]
Further, in the check valve device shown in FIG. 7, the lever 10 is positioned so that the rail faces downward toward the downstream side in a state where the swing valve body 2 is in the fully closed position a indicated by a solid line in the figure. I do. Then, the weight 12 rolls to the downstream side (the valve closing side of the oscillating valve body 2), and a closing moment acts on the valve shaft 3 by its own weight, so that the oscillating valve body 2 comes into contact with its valve seat. Do not repeat exercise.
[0009]
In this closed state, when a fluid flows in the flow path 1 in the forward direction A, if the swing valve body 2 slightly swings in the direction of the fully open position b due to the flow of the fluid, the lever 10 rotates. Then, the rail 11 changes downward toward the upstream side. The weight 12 rolls the vertical line C passing through the valve shaft 3 from left to right, that is, from the solid line in FIG. 7 to the upstream side (the valve closing side of the swing valve body 2). By applying an opening moment in the valve opening direction to the valve shaft 3, the oscillating valve body 2 is largely opened so that the flow of the fluid is not hindered.
[0010]
In this open state, if the flow of the fluid in the flow path 1 stops and the fluid flows in the reverse direction B, the swing valve body 2 moves from the fully open position b to the fully closed position a due to its own weight and the flow of the fluid. Move to
[0011]
[Problems to be solved by the invention]
However, in the check valve device of FIGS. 5 and 6, since the weight 12 is a fluid, the weight of the fluid in the space 11 depends on the rotation speed of the lever 10 and the difference in impact at the time of rotation. The movement varies. For this reason, since the locus of movement of the center of gravity of the weight 12 changes every time the swing valve body 2 is opened and closed, the degree of opening and closing of the swing valve body 2 is not constant. Further, in order to adjust the degree of opening and closing of the swing valve body 2, it is necessary to change the weight of the weight 12 by adjusting the amount of the fluid filled in the space 11. Getting in and out is complicated.
[0012]
Further, in the check valve device shown in FIG. 7, since a mechanism that allows the weight 12 to smoothly rotate on the rail 11 needs to be provided on the rail 11 or the weight 12, the structure becomes complicated.
[0013]
Therefore, an object of the present invention is to make the structure simple and to easily adjust the opening / closing degree of the swing valve body.
[0014]
[Means to solve the problem]
In order to solve the above-described problems, the present invention fixes a lever that rotates around the axis together with the valve shaft to a valve shaft of the oscillating valve that constitutes a oscillating check valve. A cylindrical tube that extends in the longitudinal direction along the same direction as the rotation direction is fixed to the lever, and a spherical weight is placed inside the tube, and the weight can roll freely in the longitudinal direction of the tube. So that the weight is movably supported by the lever. When the weight is made up of two or more spheres, each sphere can be appropriately selected from a metal sphere made of metal or an elastic sphere made of an elastic body and used in combination. Further, the metal sphere may be one obtained by subjecting the surface of the metal sphere to elastic lining. In this case, the impact in the tube due to the rolling of the metal ball can be reduced.
[0015]
In this configuration, when the flow of the fluid in the flow path interposed with the swing valve changes, the swing valve swings in accordance with the flow, and the lever rotates simultaneously with the swing. In the rotation of the lever, when the oscillating valve is opened, the weight rolls and moves in a downward direction toward the upstream side (opening side of the oscillating valve body), and on the other hand, when the oscillating valve is closed. The weight rolls and moves in the downward direction toward the downstream side (the valve closing side of the swing valve body). Due to the movement of the weight, the center of gravity formed by the weight and the lever largely moves to the upstream side or the downstream side across the valve shaft, so that the opening and closing moments acting in the valve opening direction and the valve closing direction of the valve shaft, respectively. Changes greatly.
[0016]
As described above, since the opening / closing moment acting on the valve shaft changes, if the fluid flows in the positive direction of the flow path and the swing valve opens, a large opening moment acts on the valve shaft due to the movement of the weight, Move the swing valve to the fully open position. On the other hand, when the fluid stops flowing in the forward direction or flows in the reverse direction and the swing valve closes, a large closing moment acts on the valve shaft due to the movement of the weight, and the swing valve shifts to the fully closed position. And prevent repetitive swings.
[0017]
In this configuration, the weight rolls in the tube along with the rotation of the lever, moves on a fixed trajectory, and the opening / closing moment acting on the valve shaft always becomes a predetermined value. Becomes stable.
[0018]
If a part of the tube is made openable and closable, the weight can be easily added or taken out.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
One embodiment is shown in FIGS. 1 to 4, wherein a check valve device according to this embodiment includes a swing valve body 2 interposed in a horizontal flow path 1 and opening and closing the flow path 1, and a swing valve body thereof It is a rocking type comprising a lever 4 fixed above the second valve shaft 3 and rotating around the axis together with the valve shaft 3 and a cylindrical tube 6 fixed to the lever 4.
[0020]
As shown in FIG. 4, one end of an arm 13 that rotates around the axis together with the valve shaft 3 is fixed to the valve shaft 3. A damper 14 is juxtaposed to the swing valve, and a rod 15 of the damper 14 is connected to a piston in the cylinder, penetrates the cylinder in the axial direction, and a tip of the rod 15 is outside the cylinder. The other end of the arm 13 is pin-joined. Therefore, when the swing valve body 2 swings, the arm 13 simultaneously rotates, and the rotation of the arm 13 causes the rod 15 to move together with the piston in the movable direction of the piston.
[0021]
As shown in FIG. 1, the tube 6 is fixed above the lever 4 so that the longitudinal direction thereof is along the rotation direction of the lever 4, and a spherical weight 5 is provided in the tube 6. To be able to roll freely in the longitudinal direction. The weight 5 is composed of one steel metal ball 5b and two rubber elastic balls 5a and 5c, and the elastic balls 5a and 5c are arranged on both sides of the metal ball 5b in a line. 6, and these weights 5 are movably supported by the lever 4.
[0022]
When the flow of the fluid in the flow path 1 changes, the swing valve body 2 swings in accordance with the flow, and the lever 4 rotates simultaneously with the swing. The rotation of the lever 4 changes the direction of the gradient of the tube 6, and the gradient descends toward the upstream side (the valve-opening side of the oscillating valve 2) when the oscillating valve 2 is opened. When the oscillating valve body 2 is closed, the direction is downward toward the downstream side (the closing side of the oscillating valve body 2). Since the weight 5 rolls to move upstream or downstream in accordance with the change in the gradient, the position of the center of gravity formed by the lever 4, the tube 6, and the weight 5 is shifted with respect to the vertical line C passing through the valve shaft 3 shown in FIG. As a result, it is smoothly displaced upstream (left side in FIG. 1) and downstream side (right side in FIG. 1), and the opening / closing moment acting on the valve shaft 3 greatly changes.
[0023]
Therefore, as shown by the solid line in FIG. 1, when the fluid flows in the flow path 1 in the forward direction A while the swing valve body 2 is in the fully closed position a, the swing valve body 2 is moved from the fully closed position a. Swing in the direction of the fully open position b indicated by the chain line in the figure. Due to this swing, the tube 6 is inclined downward toward the upstream side (a posture inclined toward the valve-opening side of the swing valve body 2), and the weight 5 moves down this gradient by its own weight, and the valve is opened. Displace the center of gravity to the side. Due to the displacement of the center of gravity, the position of the center of gravity formed by the lever 4, the tube 6, and the weight 5 moves from right to left with respect to the vertical line C passing through the valve shaft 3, so that a large opening moment is applied to the valve shaft 3, and The valve train 2 is stabilized in the fully open position b.
[0024]
As described above, when the swing valve body 2 swings by a certain opening degree or more, a large opening moment due to the movement of the weight 5 acts on the valve shaft 3, so that the swing valve body 2 immediately shifts to the fully open position b.
[0025]
On the other hand, when the swing valve body 2 is in the fully open position b, the closing moment acting on the valve shaft 3 by the own weight of the swing valve body 2 is increased by the own weight of the lever 4, the tube 6, and the weight 5. The weight and the moving range (the length of the tube 6) of the weight 5 are set in advance so that the opening moment acting on the weight 5 becomes slightly larger.
[0026]
Therefore, when the flow of the fluid in the flow path 1 is stopped or when there is an inflow in the reverse direction B, the swing valve body 2 is fully opened by the closing moment acting on the valve shaft 3 due to its own weight and the flow of the fluid. It swings from the posture b in the direction of the fully closed posture a. When the oscillating valve body 2 approaches the fully closed position a and the tube 6 has a downward gradient toward the downstream side (a posture in which the oscillating valve body 2 is inclined toward the valve closing side), the weight 5 has its own weight. , And displaces the center of gravity toward the valve closing side. Due to this displacement of the center of gravity, the position of the center of gravity formed by the lever 4, the tube 6, and the weight 5 moves from left to right with respect to the vertical line C passing through the valve shaft 3, so that a closing moment acts on the valve shaft 3 further. Since the swing valve body 2 is stabilized in the fully closed position a, it does not swing repeatedly.
[0027]
The angle at which the tube 6 and the lever 4 are fixed is such that the distance between the downstream end 6b (the valve closing side of the swing valve body 2) of the tube and the valve shaft 3 is the upstream end 6a (the swinging end). The tube 6 and the lever 4 are fixed so that the distance between the valve 6 and the valve shaft 3 is shorter than the distance between the valve 6 and the valve shaft 3. When the weight 5 moves toward the valve opening side, the distance between the valve shaft 3 and the center of gravity of the weight 5 increases, and the opening moment acting on the valve shaft 3 increases. As the distance between the shaft 3 and the center of gravity of the weight 5 becomes shorter, the closing moment acting on the valve shaft 3 becomes smaller.
[0028]
When the opening / closing moment is adjusted in this manner, in the fully closed position a of the swing valve body 2, since the acting closing moment is small, the swing valve body 2 can be opened by a small flow of fluid into the flow path 1, and In the fully open position b of the swing valve body 2, the opening moment is large, so that the fully open position b of the swing valve body 2 can be stabilized.
[0029]
Further, the arm 13 rotates as the swing valve body 2 swings, and the rod 15 of the damper 14 connected to the arm 13 moves in the movable direction of the piston together with the piston in the cylinder of the damper 14. The movement of the piston gives a resistance to the movement of the rod 15, the rotation of the arm 13 becomes gentle, and the rapid opening and closing of the swing valve body 2 is reduced. At this time, when such a function to loosen the opening and closing of the swing valve body 2 is not required, the installation of the arm 13, the damper 14, the rod 15, and the like may be omitted.
[0030]
The order in which the weights 5 are stored in the tube 6 is not limited to this embodiment. For example, the elastic balls 5a and 5c serve as cushioning materials, absorb the impact on the tube ends 6a and 6b when the metal balls roll, and move the center of gravity of the lever smoothly. In order to enhance the effect of absorbing the shock, a buffer material made of an elastic material such as rubber may be provided on the inner walls of the end surfaces of the tube ends 6a and 6b.
[0031]
A configuration in which the surface of the metal sphere 5b is lined with an elastic body and the whole sphere is covered with an elastic body such as rubber may be used. According to this configuration, the effect of the shock absorption can be further enhanced.
[0032]
The weight 5 can be used only with the metal sphere 5b. However, if the weight 5 is used in combination with the elastic spheres 5a and 5c having relatively small specific gravity, the metal sphere 5b and the elastic sphere 5a, By changing the number, order and size and weight of the 5c and storing them in the tube 6, the weight of the entire weight 5 and the range of the center of gravity movement can be easily adjusted.
[0033]
The method of adjusting the weight of the weight 5 is as follows. First, a metal ball 5b having a large specific gravity is stored in the tube 6, and a metal ball 5b suitable for use is determined from several metal balls having different weights. The elastic spheres 5a and 5c having a small specific gravity are appropriately stored before and after the metal sphere 5b to finely adjust the weight of the entire weight 5 and the range of movement of the center of gravity.
[0034]
If necessary, as shown in FIG. 1, an adjusting bolt 9 may be provided at the tube ends 6a, 6b so that the tip protrudes into the tube 6. When the adjustment bolt 9 moves in the longitudinal direction of the tube 6, the amount of protrusion of the tip of the adjustment bolt 9 into the tube 6 can be adjusted, so that the moving range of the weight 5 can be changed. According to this method, the range of movement of the center of gravity of the weight 5 can be adjusted more finely.
[0035]
Further, since the weight 5 is spherical, if a part of the tube 6 is made openable and closable, it can be easily put into and taken out of the tube 6. The opening / closing portion may be in any form that does not hinder the movement of the weight 5. For example, the end surfaces of the tube ends 6 a and 6 b may be covered with a lid, and the lid may be removable. An opening may be provided in a part and a lid that can be opened and closed may be provided in the opening.
[0036]
Incidentally, in this embodiment, rubber is used as the material of the elastic body spheres 5a and 5c of the weight 5, but any other sphere made of synthetic resin having elasticity can be used. In addition, although the steel ball is used as the metal ball 5b, any metal other than steel or a material having a large specific gravity such as a stone can be used.
[0037]
【The invention's effect】
As described above, according to the present invention, the structure of the check valve device is simple, and the degree of opening and closing of the swing valve is easily adjusted.
[Brief description of the drawings]
1 is a cut-away front view showing a check valve structure according to one embodiment; FIG. 2 is a right-cut side view of the embodiment; FIG. 3 is a plan view of the embodiment; FIG. 4 is a front view of the embodiment; FIG. 5 is a cutaway front view showing a conventional check valve structure. FIG. 6 is a detailed view of a conventional lever. FIG. 7 is a cutaway front view showing a conventional check valve structure.
DESCRIPTION OF SYMBOLS 1 Flow path 2 Oscillating valve body 3 Valve shaft 4, 10 Lever 5 Weight 5a, 5c Elastic body sphere 5b Metal sphere 6 Tube 11 Space 12 Weight 13 Arm 14 Damper 15 Rod

Claims (3)

A swing valve body 2 interposed in the flow path 1 for opening and closing the flow path 1, a lever 4 fixed to a valve shaft 3 of the swing valve body 2 and rotating together with the valve shaft 3 around the axis; A check valve device comprising a weight 5 movably supported by the lever 4, wherein the movement of the weight 5 with respect to the lever 4 changes the opening / closing moment acting on the valve shaft 3.
A tubular tube 6 is fixed to the lever 4 so that the longitudinal direction of the tube 6 is along the rotation direction of the lever 4, and a spherical weight 5 is placed in the tube 6 in the longitudinal direction of the tube 6. A check valve device, wherein the check valve device is rotatably housed and a weight 5 is movably supported with respect to the lever 4. 2. The check valve device according to claim 1, wherein the plurality of weights 5 are a combination of a metal ball and an elastic ball. 3. The check valve device according to claim 2, wherein when the weight (5) is made of a metal ball, the surface of the metal ball is provided with an elastic lining.

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