KR20020061791A - Apparatus for preventing overpressure - Google Patents

Abstract

PURPOSE: A device for preventing overpressure is provided to easily repair the trouble, to make the device used in material having softer quality, and to make more fluid discharged quickly. CONSTITUTION: A device fro preventing overpressure includes a body(7), a stem(5), an O-ring(6), a spring(4), a ring nut(1), and a support(3). In the body, a flow hole(7a) is formed at the base for flow of fluid and a mounted member is put to the upper part to fix the mounted member. The stem is installed within the body for the opening and shutting of the inflow hole. The O-ring is installed between the base of the stem and the top of the flow hole, to keep the exact sealing of the flow hole. The spring supports the stem with pushing the stem to supply regular strength to the stem. The ring nut is coupled to the upper part of the body for fixing of the mounted member. The support supports the upper part of the spring. The discharge capacity is increased to discharge more fluid all at once.

Description

Apparatus for preventing overpressure

The present invention relates to an overpressure preventing device for preventing a container from being damaged due to the pressure of a fluid, and more particularly, is provided in a structural device using a buoyancy device such as an air sac used in water to safely collect a structure. The present invention relates to an overpressure preventing device that not only prevents overpressure of the bladder, but also enables the safe collection of the structure from underwater.

As a device for controlling the flow of fluid by using a difference in pressure, a differential pressure valve that can be used in a pipe to control the flow of a fluid has been conventionally proposed.

1 is a schematic cross-sectional view of a conventional differential pressure valve.

Referring to FIG. 1, a conventional differential pressure valve is positioned between two pipes having different pressures to control the flow of a fluid. Hereinafter, the configuration of the differential pressure valve will be described in detail.

The first conduit 11 on which the high pressure fluid is placed, the second conduit 12 on which the low pressure fluid is placed in comparison with the first conduit 11, and the body 13 for supporting the configuration of the differential pressure valve from the outside. And a flow port 18 formed at the front of the differential pressure valve to control the flow of the fluid, a stem 14 to block the flow port 18 according to the pressure difference, and the stem 14 The pressure difference between the O-ring 15 and the first conduit 11 and the second conduit 12 is provided at an interval between the inlets 18 so that the inlet 18 is completely sealed. When it reaches below a certain degree, the spring 14 for allowing the stem 14 to fall out of the flow port 18 so that the fluid flows, and the spring 16 is supported so that a constant restoring force continues toward the stem 14 It consists roughly of support angles 17 for acting.

Referring to the operation of the differential pressure valve made of such a configuration as follows.

If the pressure in the first conduit 11 and the pressure in the second conduit 12 are the same, the forces exerted on the stem 14 add up only to the restoring force of the spring 16, so that the stem 14 has an O-ring 15. By blocking the flow port 18 with the gap therebetween, there is no flow of the fluid through the first conduit 11.

However, the force applied to cause the pressure in the first conduit 11 to rise to open the stem 14 gradually prevents the stem 14 and the spring 16 due to the pressure in the second conduit 12. At a moment greater than the sum of the restoring forces of the stem, the stem 14 overcomes the restoring force of the spring 16 and is displaced to the left.

When the stem 14 is displaced to the left, the flow opening 18 opens and the fluid exits the second conduit 12 through the flow opening 18. Eventually the fluid will flow through the differential pressure valve.

In this configuration of the differential pressure valve, the question of how much the fluid flows when the pressure of the first conduit 11 and the second conduit 12 reaches is a problem related to the design of the differential pressure valve. It depends on how much the restoring force of the spring 16 is.

However, the conventional differential pressure valve as described above has a problem in that the entire differential pressure valve needs to be replaced when a failure occurs in one part as a single unit supplied integrally, and the amount of fluid discharged through the differential pressure valve used is a differential pressure valve. Due to the reason that the outer wall is thick to overcome the fluid pressure therein, there is a problem that the valve diameter is small and limited to a predetermined level or less.

In addition, due to the problem that the metallic material is used, such a shutoff valve also has a problem that can be used only for metal parts.

The present invention has been created to solve this problem, it is easy to repair in the event of a failure in a part in the device, to be used in a softer material, more fluid can be discharged in a short time It is an object of the present invention to provide a proposed overpressure preventing device.

1 is a schematic cross-sectional view of a conventional differential pressure valve.

2 is an exploded perspective view illustrating the overpressure preventing device according to the present invention.

Figure 3a is a view explaining the absence of flow in the overpressure prevention device according to the present invention.

Figure 3b is a view for explaining how the flow occurs in the overpressure preventing device according to the present invention.

4A and 4B are free body diagrams illustrating the states of FIGS. 3A and 3B, respectively.

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

1 ....... ring nut 2 ......... stop ring

3 ....... Support 4, 16 ..... Spring

5, 14 ... Stem 6, 15 ... O-ring

7, 13 ... body 7a, 18 ...

7b ...... Screw 8 ......... Rubber Shield

11 ...... 1st pipeline 12 ............ 2nd pipeline

14 ...... Stem 17 ............. Support Angle

In order to achieve the above object, the overpressure preventing device according to the present invention has a flow hole formed on a lower surface for fluid to flow, and the body to be placed on the upper side in order to fix the snow material, and is coupled to the upper side of the body. A ring nut for fixing the snow rod, a stem provided inside the body for opening and closing the flow hole, a spring for pushing the stem to provide a constant force to the stem, and the spring Characterized in that the upper side of the support made to be supported.

The overpressure preventing device according to the present invention as shown above is configured to be suitable for the case where a large amount of fluid should be discharged in a short time and where the overpressure preventing device is installed, where a soft material is used. It can be used more suitably for air sacs that allow an object to be rescued.

Hereinafter, with reference to the drawings to introduce a specific embodiment according to the present invention.

2 is an exploded perspective view illustrating the overpressure preventing device according to the present invention.

Referring to Figure 2, the body 7 for laying the device according to the present invention in a dropping material such as air sacs are formed on the lower surface to allow the fluid flow (7a) ), A stem 5 for blocking the inner surface of the flow port 7a so as to open and close the flow of fluid, and a bottom surface of the stem 5 and an upper surface of the flow port 7a so as to seal the flow port 7a. O-ring (6) for more accurate retention, and one side of the stem to ensure that the flow opening (7a) is always closed when no pressure is applied from the outside of the stem (5) to the stem (5). 5) and a ring nut (1) for fixing the cut material to be placed on the upper surface of the body (7) and the main body 7 is mainly included.

In addition, when the overpressure preventing device according to the present invention is installed during or after being installed on the snow-covered material, a rubber shield 8 is provided to protect the body 7 from the outside so as not to damage the snow-covered material. On the upper side of the body 7, a threaded portion 7b for fixing with the ring nut 1 is machined in order to fix the material.

On the other hand, the stem (5), the support (3) for supporting the other side of the spring (5) in order to ensure that the spring (4) is accurately supported without swinging, and the stop ring for preventing the support (3) from swinging or falling out ( 2) is further included.

The stop ring 2 as described above also has a structure that is cut at a predetermined position, making insertion and removal of the stop ring 2 itself easier.

3A and 3B are cross-sectional views of a state in which the fastening of the overpressure preventing device according to the present invention is completed, and the former shows a state in which no pressure is applied to the overpressure preventing device or there is no flow of fluid, and the latter is provided to the overpressure preventing device. It is a figure explaining the case where a fluid flow is generated because the pressure applied is larger than the restoring force of a spring.

Referring to FIG. 3A, this is a state where the restoring force of the spring 4 is greater than the force due to the pressure exerted on the bottom of the stem 5 so that the spring 4 is fixed without movement and there is no fluid flow.

However, referring to FIG. 3B, this is a state in which the force due to the pressure applied to the bottom of the stem 5 is greater than the restoring force of the spring 4 so that the stem 5 rises and the fluid flows into the flow opening (see 7A of FIG. 2). ) Describes the state of fluid outflow.

On the other hand, it can be seen that the material to be installed 9, in which the overpressure preventing device according to the present invention is installed, is firmly fixed to the upper surface of the body 7 and the lower surface of the ring nut 1.

As described above, a state in which the fluid is discharged through the flow port will be described with reference to FIGS. 4A and 4B showing a free body diagram based on the stem.

FIG. 4A shows the state of FIG. 3A, which is a force F2 due to the pressure exerted on the outside, that is, above the stem 5, a force F1 due to the restoring force of the spring 5, and a snowpile 9. The force F3 due to the pressure exerted inside the stem, i.e., under the stem 5, is shown.In the situation shown in the figure, the force F1 + F2 applied from the top of the stem 5 is applied from the bottom. In a state larger than F3, there is no movement of the stamp 5.

However, FIG. 4B shows the state of FIG. 3B, and the force F1 due to the external pressure applied to the stem 5, the force F2 due to the restoring force of the spring 5, and the snow-bearing material 9. Each of the forces F3 due to the pressure in the inner circle) is shown. In the situation as shown in FIG. 4B, the force F1 + F2 applied on the upper side of the stamp 5 is smaller than the force F3 applied on the lower side. The stem 5 is lifted so that the flow opening (see 7a in FIG. 2) is opened so that the fluid inside the snow-bearing material exits.

However, in this free body diagram, the point of action of the force is shown for convenience, and it should be understood that the moment of rotation does not occur since it actually acts perpendicular to all the faces of the stem 5.

Referring to the operation of the overpressure preventing device having such a configuration, the fluid (F3) applied from the lower side of the stem (5) is exceeded a certain pressure of the fluid filled in the interior of the bladder material (9) When the upper side of the stem 5, that is, the force F1 due to the external fluid and the force F1 due to the spring 4, is greater than the stem 5, the stem 5 is lifted up and the The fluid sealed inside flows out through the flow port 7a.

However, if it is small, there will be no movement of the stem 5, and the fluid opening 7a will not open, and the fluid will not fall out.

If the overpressure preventing device as described above is described in more detail the method used to rescue the structure in the water as follows.

After the overpressure preventing device according to the present invention is installed in the bladder, that is, the snowpile 9, and after being fixed to the structure, a gas generator is used to generate a pressure in the bladder so that pressure is generated. Due to the pressure of

The gas expanded in the air sac floats due to the buoyancy and the blood structure also rises. By the way, in the depth of the depth of the bladder does not expand a lot due to the external pressure, but when the structure is floating, the water pressure is lowered as the depth moves to the shallow place, the pressure applied from the outside of the bladder In contrast to this, the pressure of the gas stored inside the bladder remains the same, and the bladder continues to expand. If this condition persists, eventually the expansion of the bladder will explode beyond the permissible stress of the material of the bladder, and the structure will sink again.

In order to prevent such a situation, an overpressure prevention device is used. By appropriately adjusting the restoring force of the spring 4, the bladder contains gas only within a range of pressure allowable by the material of the bladder. The force F3 due to the pressure remains the same, but the force F2 due to the external hydraulic pressure becomes smaller due to the rise of the air sac, so that this force difference F2-F3 is restored to the restoring force F1 of the spring 4. Compensation is made up to the limit already set, if the force difference (F2-F3) exceeds the allowable limit of the bladder, the stem (5) is opened, and the force (F3) due to the pressure inside the bladder is small again due to the outflow of gas. By allowing the ground stem 5 to close, the difference between the pressure inside the bladder and the external hydraulic pressure can be kept constant.

In other words, by calculating the difference between the pressure inside the bladder and the hydraulic pressure, and by installing a spring (4) in the overpressure prevention device to the extent that the difference is offset, the gas in the bladder does not expand to a certain degree or more to the structure You can safely rescue.

In order to be used in the structure of the submerged structure in this way, the overpressure preventing device according to the present invention is a ring nut (see 1 in FIG. 2) designed specifically to be installed on the structure and the thread is processed on the upper side A body (see 7 of FIG. 2) is provided, and a rubber shield (see 8 of FIG. 2) is provided at a contact portion to be used in a soft material having a certain degree of elasticity.

The embodiment of the present invention as described above is not limited thereto, but another embodiment can be easily made by adding or changing components wherever pressure is required to be maintained.

The overpressure preventing device according to the present invention has a large fluid discharge capacity so that a large amount of fluid can be pulled out in a certain space at a time, and can be used more conveniently by being made of a soft material so as to be installed in a soft snow material.

In addition, it is easy to assemble and disassemble, so that only the measurement part can be replaced when a failure occurs in the part, thereby increasing the life of the whole product.

Claims (3)

A flow hole is formed on the lower surface for the fluid to flow, and the body on which the tongue is placed on the upper side to fix the tongue, A ring nut coupled to an upper side of the body to fix the snow rod; A stem provided inside the body to open and close the flow port; A spring for pushing the stem to provide a constant force to the stem, An overpressure preventing device, characterized in that consisting of a support for the upper side of the spring is supported. The method of claim 1, And an o-ring between the lower surface of the stem and the flow port to completely seal the flow port. The method of claim 1, A shield which is added to the lower side of the body to prevent the body from being damaged due to the body; And a stop ring disposed between an upper side of the support and a lower surface of the ring nut to prevent rocking or slipping of the support.