KR20190079153A - Check valve apparatus - Google Patents

Abstract

Disclosed is a check valve apparatus in which a valve housing through which a fluid passes and a valve member allowing or blocking distribution of the fluid are formed to be gently curved. Accordingly, generation of an eddy can be prevented by smooth flow of the fluid, and thus a loss of pressure can be minimized. In addition, a venturi effect is generated between the valve housing and the valve member to enable the fluid to flow more smoothly, thereby increasing energy efficiency by minimizing the loss of pressure.

Description

CHECK VALVE APPARATUS

The present invention relates to a check valve device that improves energy efficiency by minimizing pressure loss due to structural factors.

 Generally, check valves are installed at the inlet or outlet of a pipe or machinery and are used to set the flow of fluid only in one direction. In addition, the check valve has a function of opening the valve when the fluid pressure is in a low pressure state, allowing the fluid to pass therethrough and shutting off the fluid flow in the reverse direction.

However, since the conventional check valve uses a mechanical mechanism, if the mechanical wear occurring during use or the coupling state between the parts is not good, the check valve can not be completely sealed due to the closing operation of the check valve, .

Particularly, since the check valve flows only in one direction and is closed in the opposite direction to the opposite direction, pressure loss occurs due to internal structural factors when the valve is kept open. That is, when the check valve is opened, the fluid continuously flows. Since there is no consideration for smooth flow of the fluid, the fluid flow is disturbed, and the pressure loss is generated by the vortex generation, there is a problem.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as an admission that the prior art is known to those skilled in the art.

KR 10-2017-0099511 (2017.09.01.)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a check valve device in which energy flow is improved by minimizing pressure loss due to structural factors, have.

The check valve device according to the present invention comprises: a valve housing formed with an upper end and a lower end opened to form a flow passage through which fluid flows, the flow passage being gently rounded; And a valve member provided in the flow passage of the valve housing to open the flow passage when the valve member is moved upward and close the flow passage when the valve member is moved downwardly, and the valve member has a valve mechanism formed to gently round the outer circumferential surface .

The flow path includes an inflow portion through which the fluid flows, a space portion through which the fluid introduced through the inflow portion is passed and in which the valve member is provided, and a discharge portion through which the fluid in the space portion flows out.

The width of the space portion is formed to be larger than the width of the inlet portion and the outlet portion, and the width of the inlet portion is formed to be smaller than the width of the outlet portion.

And the width of the inflow portion is gradually reduced toward the upper side.

Wherein the valve member is formed such that the lower end portion is in close contact with the inlet portion, the upper end portion is formed to be smaller than the width of the discharge portion, and the intermediate portion is formed to protrude toward the space portion and smaller than the width of the space portion.

The distance between the intermediate portion of the valve member and the space portion is formed to be smaller than the distance between the upper end portion of the valve member and the discharge portion in a state in which the valve member is positioned to open the flow passage.

The distance between the lower end of the valve member and the inflow portion is formed to be smaller than the distance between the intermediate portion and the space portion of the valve member in a state in which the valve member is positioned to open the flow passage.

And the lower end of the valve member is formed to protrude so as to be inserted into the passage of the inflow portion, and is provided with a sealing member which is in contact with the inflow portion.

The valve mechanism includes: a guide portion fixed to the flow passage and provided so as to be guided and moved in the vertical direction; And an elastic portion provided on the guide portion and elastically supporting the valve member downwardly.

The guide part is composed of a fixing bracket fixed to the flow passage and fixed to the guide bracket, and a guide shaft vertically extending from the fixing bracket and connected to the valve member so as to be movable in the vertical direction.

The fixing bracket includes a fastening portion screwed to the flow passage, a rib portion disposed to be spaced apart from the periphery of the fastening portion and extending toward the center of the flow passage, a boss fastened to the rib portion at the center of the flow passage, .

The valve member is provided with a through hole through which the guide shaft passes and a support groove into which the support end is inserted to the upper side of the through hole. The elastic portion is provided in the support groove, .

A guide groove recessed toward the guide shaft is formed at the upper end of the valve member, and a fixing pin inserted into the guide groove is protruded from the upper end of the guide shaft.

And a bypass valve movably inserted from the outside into the flow passage side at a side of the valve housing so that the valve member is moved upward when the bypass valve is in contact with the valve member provided in the flow passage.

A bypass hole is formed at a side of the valve housing, and a bypass valve is formed of a body portion formed to extend into the valve member and inserted into the bypass hole, and a head portion exposed to the outside of the valve housing, .

The bypass valve has a trunk portion bent at an end thereof and an outer circumferential surface of the valve member is formed such that a portion corresponding to the bypass valve is depressed or inclined in a state where the valve member is positioned to close the flow passage, The valve member is pushed upward and is moved.

And an overpressure prevention valve connected to the side of the valve housing so as to communicate with the flow passage and being opened when the inside of the flow passage is higher than a set pressure to discharge the fluid inside the flow passage.

The overpressure prevention valve includes a valve body having an inlet communicating with the flow passage and an outlet through which the fluid is discharged to the outside; A valve disc installed inside the valve body to open and close the outlet; And a spring portion elastically supporting the valve disc in the valve body inside the valve body and allowing the valve disc to open and close the outlet in accordance with the pressure input to the inlet side.

According to the check valve device having the above-described structure, the shape of the valve member permitting or blocking the flow of the fluid with the valve housing through which the fluid is passed is formed so as to bend gently so that vortex generation is prevented by the smooth fluid flow , Thereby minimizing the pressure loss. In addition, as the venturi effect is generated between the valve housing and the valve member, the flow of the fluid becomes more smooth, thereby improving the energy efficiency due to the minimization of the pressure loss.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 shows a check valve arrangement according to an embodiment of the invention.
Fig. 2 is a view showing a state in which the valve mechanism of the check valve device shown in Fig. 1 is opened. Fig.
3 is a view for explaining the check valve device shown in Fig. 1; Fig.
4 is a view showing an operation state of a bypass valve of the check valve device shown in Fig.
5 is a view for explaining an overpressure prevention valve of the check valve device shown in Fig.

Hereinafter, a check valve device according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a view showing a check valve device according to an embodiment of the present invention, FIG. 2 is a view showing a state in which a valve mechanism of the check valve device shown in FIG. 1 is opened, FIG. 4 is a view showing an operation state of the bypass valve of the check valve device shown in FIG. 1, and FIG. 5 is a view for explaining the check valve device of the check valve device shown in FIG. Fig.

1, the check valve apparatus according to the present invention includes a flow passage 120 through which a fluid flows, the upper and the lower ends being open, and the flow passage 120 is formed in a valve housing 100); And a valve member 220 installed in the flow passage 120 of the valve housing 100 and allowing the flow passage 120 to open when it is moved upward and closing the flow passage 120 when it is downwardly moved, The member 220 includes a valve mechanism 200 that is configured to gently round the outer circumferential surface.

The valve member 220 of the valve mechanism 200 is movably provided in the flow passage 120 of the valve housing 100 and the valve member 220 of the flow passage 120 is moved downward The flow path 120 is closed when the valve member 220 is moved, and the flow path 120 is opened when the valve member 220 is moved upward.

1, the flow passage 120 of the valve housing 100 is formed to gently loosen, and the outer circumferential surface of the valve member 220 is formed to gently round the flow passage, The valve member 220 can be smoothly moved along the curved shape.

In the prior art, the valve merely serves to close the inlet, and there is a problem that a vortex is generated due to a structural factor as a result of not considering the flow of the fluid, thereby causing a pressure loss. However, according to the present invention, since the shape of the inner circumferential surface of the flow path 120 of the valve housing 100 and the shape of the outer circumferential surface of the valve member 220 form a gentle shape so that the fluid can smoothly flow, the pressure loss is minimized.

1, the flow path 120 includes an inflow portion 122 through which a fluid flows, an inflow portion 122 through which the fluid flows, And a discharge part 126 through which the fluid in the space part 124 flows out, so that the inflow part (the fluid part) 122 flows through the space portion 124 and flows out to the discharge portion 126.

The width of the space 124 is larger than the width of the inlet 122 and the outlet 126 so that the valve mechanism 200 can be moved up and down in the space 124 The width of the inflow portion 122 is formed to be smaller than the width of the discharge portion 126 so that the fluid can be discharged at a high speed through the inflow portion 122 and then discharged smoothly through the discharge portion 126.

In addition, since the width of the inflow portion 122 is gradually decreased toward the upper side, the flow rate of the fluid flowing into the inflow portion 122 can be increased. As the flow rate of the fluid flowing into the flow path 120 is secured by the shape of the inflow portion 122, the fluid can flow into the space portion 124 while moving the valve member 220 upward, The force for pressing the valve member 220 downward is reduced as the fluid flows out through the discharge portion 126 formed in the width, so that the opening operation of the valve member 220 can be performed smoothly.

The lower end of the valve member 220 is formed to be in close contact with the inlet 122 and the upper end of the valve member 220 is formed to be smaller than the width of the discharge portion 126. The center portion of the valve member 220 protrudes toward the space 124, As shown in FIG. The lower end of the valve member 220 is formed to be inserted into the inlet 122 so that the valve member 220 can be moved downward to hermetically close the inlet 122 when the inlet member 122 contacts the inlet 122, The fluid can be discharged through the discharge portion 126 even if the valve member 220 is moved upward. The intermediate portion of the valve member 220 protrudes toward the space portion 124 and is formed to be smaller than the width of the space portion 124 so that the fluid can pass outside the valve member 220. In the present invention, the outer circumferential surface shape of the valve member 220 and the shape of the flow path 120 are rounded so that the fluid smoothly rides on the outer circumferential surface of the valve member 220 and the curved surface of the inner circumferential surface of the flow path 120 Can be moved.

2, the distance (i) between the intermediate portion of the valve member 220 and the space portion 124 is set so that the valve member 220 is positioned to open the flow passage 120, May be smaller than the distance (j) between the upper end of the valve member 220 and the discharge portion 126.

That is, when the distance i between the intermediate portion of the valve member 220 and the space portion 124 is formed to be smaller than the distance j between the upper end portion of the valve member 220 and the discharge portion 126, A venturi effect is generated in which the flow velocity of the fluid is increased as the diameter between the intermediate portion of the fluid passage 220 and the space portion 124 is narrowed. In this way, when the fluid passing through the flow path 120 passes through the intermediate portion of the valve member 220, the flow rate of the fluid is increased by the venturi effect, so that the flow of the fluid passing through the flow path 120 can be made more smooth .

The distance g between the lower end of the valve member 220 and the inflow portion 122 is set to be shorter than the distance between the intermediate portion of the valve member 220 and the lower end of the valve member 220, May be formed to be smaller than the distance (j) between the space portions (124).

As the diameter between the lower end portion of the valve member 220 and the inflow portion 122 becomes narrower, the venturi effect of increasing the flow velocity of the fluid is generated, so that the flow velocity of the fluid flowing through the inflow portion 122 can be increased have.

That is, the distance i between the intermediate portion of the valve member 220 and the space portion 124 of the flow path 120 and the distance g between the lower end portion of the valve member 220 and the inlet portion of the flow path 120 ), The flow velocity of the fluid according to the venturi effect is secured, and the venturi effect is generated at the two points, so that the flow of the fluid can be secured and the flow of the fluid can be guided more smoothly. Accordingly, in a state where the valve member 220 is positioned to open the flow passage 120, the flow rate of the fluid passing through the flow passage 120 is increased, and the fluid can flow smoothly.

1 and 2, the lower end of the valve member 220 is formed to be protruded to be inserted into the passage of the inlet 122, and a sealing member 220a contacting the inlet 122 is provided When the valve member 220 is moved downward and contacts the inlet 122, the lower end of the valve member 220 is inserted into the inlet 122 to close the inlet 122 and the valve member 220 The gap between the inflow portions 122 can be sealed by the sealing member 220a to block the flow of the fluid.

Hereinafter, the valve mechanism 200 will be described in detail.

As shown in FIGS. 1 and 2, the valve mechanism 200 includes a guide unit 240 fixed to the flow path 120 and installed to move the valve member 220 in a vertically guided manner; And an elastic part 260 installed on the guide part 240 and elastically supporting the valve member 220 downward.

The valve mechanism 200 includes a guide part 240 and an elastic part 260. The valve part 220 provided on the guide part 240 so as to be movable up and down is supported by the elastic part 260, The valve member 220 is moved upward while compressing the elastic part 260 by the force of the fluid being moved by the fluid flowing through the flow path 120, The valve member 220 can be moved downward by the elastic portion 260 to close the flow path 120. In this case,

2 to 3, the guide unit 240 includes a fixing bracket 242 fastened to and fixed to the flow passage 120, a valve member 220 vertically extending from the fixing bracket 242, And a guide shaft 244 which is vertically movably connected. That is, the fixing bracket 242 is fixed to the flow passage 120, and the fluid can pass therethrough. The guide shaft 244 is vertically installed at the center of the fixing bracket 242, And can be moved up and down along the guide shaft 244 at the center of the flow path 120 when installed on the shaft 244. [

3, the stationary bracket 242 includes a fastening portion 242a that is screwed to the flow passage 120 and a fastening portion 242b that is spaced apart from the fastening portion 242a around the fastening portion 242a, And a boss portion 242c which is coupled to the rib portion 242b at the center of the flow path 120 and to which a lower end portion of the guide shaft 244 is fastened.

That is, the fastening portion of the fixing bracket 242 is formed with a thread on the circumferential surface, and a screw thread corresponding to the thread of the fastening portion is formed on the lower side of the flow passage 120 so that the fastening portion is screwed to the flow- Can be fixed. The fastening portion is provided with a rib portion extending along the inner circumference and extending toward the center of the flow path 120, and a boss portion for fastening the guide shaft 244 on the center of the flow path 120, do. As a result, the fluid can pass between the rib portions spaced apart from each other in the fastening portion, and the guide shaft 244 is fastened to the boss portion coupled to the rib portion, As shown in FIG.

The lower end of the guide shaft 244 may be threaded and the inner circumferential surface of the boss may be threaded so that the guide shaft 244 may be threadedly engaged. When the lower end of the guide shaft 244 is screwed to the boss The position of the guide shaft 244 can be fixed through a separate nut.

2, a support end 245 is protruded in the circumferential direction at the upper end of the guide shaft 244 and a through hole 222 through which the guide shaft 244 is passed is formed in the valve member 220, And a support groove 223 into which the support end 245 is inserted is formed on the upper side of the through hole 222. The elastic portion 260 may be provided on the support groove 223 and supported on the support end 245. [

The valve member 220 is formed with a through hole 222 through which the guide shaft 244 passes and a support groove 223 through which the support end 245 is inserted, And can be moved up and down along the inserted guide shaft 244. The elastic member 260 is provided between the support end 245 formed at the upper end of the guide shaft 244 and the support groove 223 formed in the through hole 222 of the valve member 220, The valve member 220 can be moved by receiving the elastic force of the elastic portion 260 when the valve member 220 is moved downward.

A separate sealing ring may be provided between the through hole 222 and the guide shaft 244 of the valve member 220. The elastic member 260 may be a spring to provide an elastic force to the valve member 220 can do. The vertical length of the support groove 223 formed in the valve member 220 may be set to a length corresponding to the maximum distance through which the valve member 220 is moved upward. That is, the maximum travel distance of the valve member 220 can be determined according to the vertical length of the support groove 223.

1, a guide groove 225 is formed in the upper end of the valve member 220 toward the guide shaft 244. A guide groove 225 is formed in the upper end of the guide shaft 244, The distance that the valve member 220 is moved upward and downward can be limited by protruding the fixing pin 244a inserted into the valve body 220. [ That is, the maximum distance that the valve member 220 is moved upward or downward can be determined according to the vertical length of the guide groove 225. As a result, when the valve member 220 is moved upward by the fluid, the guide groove 225 formed in the valve member 220 is restricted from moving to the position where it is caught by the fixing pin 244a provided on the guide shaft 244 Even if the valve member 220 is moved upward, the fluid can be moved through the flow path 120 and the valve member 220 can be moved along the guide shaft 244 As shown in Fig.

On the other hand, in the event of a problem on the flow path on which the check valve is installed or a problem due to a mechanical defect, the water staying in the flow path 12 may be discharged to the lower side of the check valve.

4, the bypass valve 300 may be further inserted at the side of the valve housing 100 so as to be movable from the outside to the flow passage 120 side. The bypass valve 300 is forcibly moved by the bypass valve 300 and not by the force generated by the movement of the valve member 220 when the valve member 220 is in contact with the valve member 220 provided in the flow path 120, Can be passed.

A bypass valve 140 is formed at a side of the valve housing 100. The bypass valve 300 includes a body 320 inserted into the bypass hole 140 and extending toward the valve member 220 And a head 340 coupled to the body 320 and exposed to the outside of the valve housing 100. The body 320 of the bypass valve 300 is inserted into the bypass hole 140 and inserted into the flow passage 120 to be in contact with the valve member 220 Is moved upward. The head 340 coupled to the body 320 is exposed to the outside of the valve housing 100 so that the operator can adjust the position of the body 320 by grasping the head 340.

The body 320 of the bypass valve 300 and the bypass hole 140 of the valve housing 100 are screwed together so that the body 320 of the bypass valve 300 is moved in the bypass hole 140 . A separate spring may be provided between the head 340 and the valve housing 100 so that the body 320 is moved toward the valve member 220 and then automatically retracted by the force of the spring. As a result, the operational convenience of the bypass valve 300 can be improved.

4, the trunk portion 320 of the bypass valve 300 is bent at its end, and the outer circumferential surface of the valve member 220 is closed by the valve member 220 closing the flow passage 120 The portion corresponding to the bypass valve 300 is depressed or inclined so that the bypass valve 300 can be pushed upward when the bypass valve 300 is contacted.

That is, when the bypass valve 300 is moved toward the valve member 220 and contacts the valve member 220, the end of the body portion 320 contacts the inclined portion or the jaw formed on the outer peripheral surface of the valve member 220 The valve member 220 is moved upwards on the curved inclined surface of the body 320.

5, the valve housing 100 is connected at its one end to the flow path 120 and is opened when the inside of the flow path 120 is at a set pressure or higher, And an overpressure prevention valve 400 for allowing the fluid to be discharged.

The overpressure prevention valve 400 prevents the excessive pressure from being generated in the valve housing 100 when the fluid flows backward due to a problem in the flow path or a problem due to a mechanical defect. That is, when an emergency situation occurs due to a mechanical failure, or when a reverse flow of the fluid occurs due to the stoppage of the pump, a water shock may be generated inside the valve housing 100. An overpressure prevention valve 400 is installed in the valve housing 100 The overpressure prevention valve 400 is opened so that the pressure inside the valve housing 100 decreases as the fluid in the flow passage 120 is discharged to the outside when the pressure inside the flow passage 120 is equal to or higher than the set pressure. can do.

The overpressure prevention valve 400 includes a valve body 420 having an inlet 421 connected to the communication passage 120 and an outlet 422 through which fluid is discharged to the outside. A valve disc 440 installed inside the valve body 420 to open and close the outlet 422; The valve disc 440 is elastically supported in the valve body 420 toward the outlet 422 and the valve disc 440 opens and closes the outlet 422 in accordance with the pressure input to the inlet 421. [ (460).

Here, the elastic force of the spring portion 460 is set such that the valve disc 440 is not moved during a pressure action caused by the fluid flowing through the flow passage 120 of the valve housing 100, The valve disc 440 may be set to open the outlet 422 when pressure is applied due to the water impact. In addition, in the case of the valve disc 440, the valve disc 440 may be formed so as to be recessed upward so as to allow the fluid to flow.

The valve disc 440 is elastically supported by the spring portion 460 in the valve body 420 so that the valve disc 440 is closed inside the valve housing 100 by the backward flow by the mechanical coupling while the outlet port 421 is closed. The valve disc 440 which closes the outlet 422 is moved while pressing the spring portion 460 to open the outlet 422. As a result, The fluid inside the flow path 120 flows into the inlet port 421 of the valve body 420 and is discharged to the outlet port 422 so that the pressure inside the valve housing 100 can be lowered. As a result, the water impact due to the back flow of the fluid can be mitigated, and the vibration and damage of the overall system and the check valve can be prevented.

The operation according to the present invention will be briefly described below.

As shown in FIG. 2, when the entire system is operated normally, the valve member 220 provided inside the valve housing 100 is maintained to be moved upward by the movement of the fluid.

5, the valve member 220 closes the flow passage 120 to shut off the flow of the fluid, so that the pressure inside the valve housing 100 is increased. As a result, The overpressure prevention valve 400 is opened so that the pressure inside the valve housing 100 is lowered so that the water impact can be mitigated.

4, when the fluid is to be discharged to the outside in order to solve the problem caused by the flow path or a mechanical defect, when the bypass valve 300 is operated, the valve member 220 is forced upward The fluid can flow back toward the discharge portion 126 side of the flow path 120 and be discharged to the inflow portion 122 side.

According to the check valve apparatus having the above-described structure, the shape of the valve member 220, which permits or blocks the fluid communication with the valve housing 100 through which the fluid passes, is formed to gently bend, The vortex generation is prevented, and the pressure loss is thereby minimized. In addition, as the venturi effect is generated between the valve housing 100 and the valve member 220, the flow of the fluid becomes more smooth, thereby improving the energy efficiency due to the minimization of the pressure loss.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

100: valve housing 120:
122: inlet portion 124:
126: discharging part 140: bypass hole
200: valve mechanism 220: valve member
222: Through hole 223: Support groove
225: guide groove 220a: sealing member
240: Guide part 242: Fixing bracket
244: Guide shaft 244a: Fixing pin
245: Support end 260:
300: bypass valve 320: body portion
340: head part 400: overpressure prevention valve
420: valve body 421: inlet
422: outlet 440: valve disc
460: spring portion

Claims (18)

A valve housing having an upper end and a lower end opened to form a flow passage through which the fluid flows, the flow passage being formed to gently round the valve housing; And
And a valve mechanism provided in the flow passage of the valve housing to open the flow passage when it is moved upward and to close the flow passage when moving downward, and the valve member has a valve mechanism formed to gently round the outer circumferential surface Valve device. The method according to claim 1,
Wherein the flow path comprises an inflow portion through which the fluid flows, a space portion through which the fluid introduced through the inflow portion passes, a valve portion provided with the valve portion, and a discharge portion through which the fluid flows in the space portion. The method of claim 2,
Wherein the width of the space portion is formed to be larger than the width of the inlet portion and the outlet portion, and the width of the inlet portion is formed to be smaller than the width of the outlet portion. The method of claim 2,
And the width of the inflow portion is gradually reduced toward the upper side. The method of claim 2,
Wherein the valve member is formed such that a lower end portion thereof is in close contact with the inlet portion and the upper end portion is formed to be smaller than the width of the discharge portion and the intermediate portion is protruded toward the space portion and smaller than the width of the space portion. The method of claim 5,
Wherein the distance between the intermediate portion and the space portion of the valve member is smaller than the distance between the upper end portion of the valve member and the discharge portion, with the valve member positioned to open the flow passage. The method of claim 5,
Wherein a distance between a lower end portion of the valve member and the inflow portion is formed to be smaller than a distance between the intermediate portion and the space portion of the valve member, with the valve member positioned to open the flow passage. The method of claim 5,
Wherein a lower end portion of the valve member is formed to protrude so as to be inserted into the passage of the inlet portion and is provided with a sealing member which is in contact with the inlet portion. The method according to claim 1,
The valve mechanism includes: a guide portion fixed to the flow passage and provided so as to be guided and moved in the vertical direction; And
And an elastic portion provided in the guide portion and elastically supporting the valve member in a downward direction. The method of claim 9,
Wherein the guide portion comprises a fixing bracket fixed to the flow passage and fixed to the fixing bracket, and a guide shaft vertically extending from the fixing bracket and connected to the valve member so as to be movable in the vertical direction. The method of claim 10,
The fixing bracket includes a fastening portion screwed to the flow passage, a rib portion disposed to be spaced apart from the periphery of the fastening portion and extending toward the center of the flow passage, a boss fastened to the rib portion at the center of the flow passage, And a check valve unit. The method of claim 10,
A support end portion is protruded from the upper end of the guide shaft in the circumferential direction,
The valve member is provided with a through hole through which the guide shaft passes and a support groove into which the support end is inserted upwardly of the through hole,
And the resilient portion is provided in the support groove and is supported on the support end. The method of claim 10,
A guide groove recessed toward the guide shaft is formed at the upper end of the valve member,
And a fixing pin inserted into the guide groove protrudes from the upper end of the guide shaft. The method according to claim 1,
Wherein the bypass valve is movably inserted into the valve housing from the outside to the flow passage side so that the valve member is moved upward when the bypass valve is brought into contact with the valve member provided in the flow passage. . 15. The method of claim 14,
A bypass hole is formed at a side end of the valve housing,
Wherein the bypass valve comprises a body portion inserted into the bypass hole and extending to the valve member side, and a head portion coupled to the body portion and exposed to the outside of the valve housing. 15. The method of claim 14,
The body portion of the bypass valve is formed with a bent end,
The outer peripheral surface of the valve member is formed such that the portion corresponding to the bypass valve is depressed or inclined in a state where the valve member is positioned to close the flow passage so that the valve member is pushed upward when the bypass valve is contacted Check valve device. The method according to claim 1,
And an overpressure prevention valve connected to the side of the valve housing so as to communicate with the flow passage and being opened when the inside of the flow passage is higher than a set pressure to discharge the fluid inside the flow passage. 18. The method of claim 17,
The overpressure prevention valve includes a valve body having an inlet communicating with the flow passage and an outlet through which the fluid is discharged to the outside;
A valve disc installed inside the valve body to open and close the inlet; And
And a spring portion elastically supporting the valve disc in the valve body in the valve body so as to open and close the outlet of the valve disc in accordance with a pressure inputted to the inlet side.

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