RU229506U1 - Excess pressure relief valve - Google Patents

Abstract

The excess pressure relief valve (EPRV) is designed to protect premises and equipment from excess gas pressure generated during the release of a gas fire extinguishing agent (GFEA) into the premises from gas fire extinguishing systems. The excess pressure relief valve includes a housing, a shutter made of sheet steel, an inlet with a sealant laid along the perimeter. The sealant is laid along the edge of the inlet. The housing is equipped with vertical posts made on opposite sides of the inlet in front of the side walls of the housing. The housing can be equipped with two vertical posts, or four vertical posts, a pair on each side, or six vertical posts, three on each side. The most optimal number of posts is four, a pair on each side of the inlet. The vertical posts act as guides for the shutter. The shutter is made of a steel sheet up to 12 mm thick. On opposite ends of the shutter there are symmetrically located lugs with holes. The number of lugs and their location correspond to the number and location of the vertical posts. By means of the said lugs, the valve is movably connected to the posts with the possibility of free movement along the posts in the up-down direction to open and close the inlet. In the upper part, the vertical posts have valve lift limiters that prevent the valve from being dropped from the vertical posts. The technical result is an increase in the reliability of the excess pressure relief valve.

Description

The excess pressure relief valve (EPRV) is designed to protect premises and equipment from excess gas pressure generated during the release of gaseous fire extinguishing agent (GFEA) from gas fire extinguishing systems into the premises.

A flap valve is known, adapted for use in high-temperature installations, for example, at the outlet of a high-temperature cyclone separator. The valve includes a shaft mounted with the possibility of rotation in a device correctly located relative to the pipeline to be closed. The shaft includes a polygonal central section and a flap with an upper surface adapted to close the open end of the pipeline, wherein one end of the flap lies above the polygonal section of the shaft. The rear part of the flap is bent perpendicularly to the upper surface to hang over the shaft. A pawl, having a polygonal opening of a similar shape, slides along the central part of the rod and has a leg that lies on the upper surface of the flap. This pawl serves to transmit rotational forces between the shaft and the flap, while ensuring relative movement of the shaft on the flap in a direction parallel to the shaft axis in order to provide relative thermal expansion. A typical counterweight is connected to the shaft to apply a rotational force to the shaft tending to rotate the valve to the closed position (see patent US4494564(A), IPC F16K15/03, 1985).

An automatic air valve is known, comprising a housing with an inlet cavity in the lower part, a float, the outer surface of which forms an annular channel with the inner surface of the housing, and a working element located in the upper part, including a control valve connected to the float, a shutter and a shutter seat, the opening of which is communicated with the atmosphere, characterized in that the control valve seat is made in the shutter, and the shutter itself is made in the form of a cup, while the shutter seat is made in a component part of the housing with a perforated wall in the half adjacent to it, and in the other half the surface of the opening and the surface of the shutter adjacent to it are made conjugate in diameter, which is larger than the diameter of the opening of the shutter seat (analog - Russian Federation Patent No. 2227855 dated 21.05.2002).

The disadvantage of the above known solutions is low throughput and complexity of the design.

A pressure relief valve is known, comprising a flap rotating about an axis parallel to the plane of the flap. A holder holds the flap in a closed position, which exerts a given force opposite to the force exerted by the pressure on the sealing side. The sealing side of the flap has a skirt, which extends to the valve seat and interacts with the periphery of the seat. The skirt is at a given height, so that the valve moves from its initial position by a given amount, while maintaining the seal. The holder has a mass movable relative to the flap. The mass moves from the initial position to the inactive position, when the flap moves from the closed position to the open position, in order to change the center of gravity of the flap and thereby reduce the force exerted by the holder (analog - US6085781, IPC F16K15/03, 2000).

The disadvantage of the known solution is its large weight and complexity of design.

The excess pressure relief valve (EPR) is widely known.

The KSID consists of a body and a shutter, on which a load is fixed by welding. Rotation of the shutter relative to the body is carried out by means of an axis and a bushing. The shutter is pressed against the valve seat under the action of its own weight and the weight of the load located on it. Weight of the load is calculated in accordance with the value of excess opening pressure of the valve. Sealing of the valve seat is ensured by a self-adhesive seal (see Internet publications: https://isp-holding.one/ksid, https://oskshop.ru/product/ksid-600-1-2/https://firehub.ru/upload/uf/61c/bj3xn0uxif8jtxpf4k1klxvcrgylrl0d/_%D0%A0%D0%AD%20%D0%9F%D0%A1%20%D0%9A%D0%A1%D0%98%D0%94-%D0%9F%20%D0%9F%D0%9C%D0%A1%D0%90%20(4).pdf).

This decision was adopted as a prototype.

The disadvantages of the known design are that the shutter opens by rotating the shutter around an axis fixed in the body. An additional load is usually attached to the edge of the shutter opposite the axis of rotation. When excessive air pressure is applied to the shutter, the shutter fails to open, since the side of the shutter on which the load is not installed bends first, a gap appears there and air escapes before the shutter opens. This leads to the fact that the shutter opening time increases until the pressure reaches the value required to fully open the shutter. The shutter may jam when triggered if the shutter rotation axes are displaced. In addition, the position of the rotation axis does not allow for uniform sealing of the shutter over the entire contact surface with the seal.

The technical problem solved by the utility model is the elimination of the indicated shortcomings of the prototype.

The technical result is an increase in the reliability of the operation of the excess pressure relief valve.

The stated technical result is achieved due to the fact that in the excess pressure relief valve, which includes a housing with an inlet provided with a seal, and a shutter pressed against the inlet under its own weight, according to the utility model, the housing is provided with vertical posts made on opposite sides of the inlet in front of the side walls of the housing and having limiters for lifting the shutter, made from a steel sheet and provided with lugs with holes, by means of which the shutter is connected to the vertical posts with the possibility of moving along them.

The body is equipped with two vertical posts.

The body is equipped with four vertical posts, a pair on each side.

The body is equipped with six vertical posts, three on each side.

The shutter is made of steel sheet up to 12 mm thick.

The bolt is equipped with two lugs located on the ends facing the side walls of the body.

The bolt is equipped with four lugs located on the ends facing the side walls of the body.

The bolt is equipped with six lugs located on the ends facing the side walls of the body.

The implementation of the excess pressure relief valve with a housing equipped with vertical posts made on opposite sides of the inlet in front of the side walls of the housing and having limiters for lifting the shutter made of a steel sheet and equipped with lugs with holes by means of which the shutter is connected to the vertical posts with the possibility of moving along them, allows for increased reliability of the excess pressure relief valve operation. Reliability of the valve operation is necessary to prevent any destruction in the protected room at elevated pressure, since the operation occurs when the pressure increases above a certain level.

The shutter, made in the form of a steel sheet, has a greater thickness, and therefore greater rigidity and, as a consequence, constant flatness, which allows for uniform adherence of the shutter over the entire contact surface with the seal and prevents it from warping when rising along the vertical posts during valve operation, which increases the reliability of the overpressure relief valve.

The presence of vertical posts in the valve, made on opposite sides of the inlet in front of the side walls of the body and having limiters for lifting the shutter, allows eliminating the shortcomings of the prototype, namely preventing the shutter from jamming when triggered, which increases the reliability of the operation of the excess pressure relief valve.

When exposed to excess pressure, the valve is lifted along the guides along the vertical posts above the valve inlet. This eliminates the need to use an axis, thus eliminating the deflection of the valve edge and the tilt of the valve above the inlet, which allows for increased reliability of the overpressure relief valve.

Fig. 1 - KSID in closed state with two racks;

Fig. 2 - KSID in a closed state with four racks (half of the device is shown);

Fig. 3 - KSID in the open state with four posts (the second side wall is not shown and one of the vertical posts 5 is cut off at the top).

The excess pressure relief valve includes a housing 1, a gate 2 made of sheet steel, an inlet 3, along the perimeter of which a seal 4 is placed. The seal 4 is placed along the edge of the inlet 3 (see Figs. 1, 2). The housing 1 is provided with vertical posts 5 made on opposite sides of the inlet 3 in front of the side walls 6 of the housing (see Figs. 1, 3). The housing can be provided with two vertical posts 5 (see Fig. 1), or four vertical posts 5, a pair on each side (see Figs. 2, 3), or six vertical posts 5, three on each side. The most optimal number of posts is four, a pair on each side of the inlet 3. The vertical posts 5 are guides for the gate 2. The gate is made of a steel sheet up to 12 mm thick.

On the opposite ends of the bolt 2 there are symmetrically located lugs 7 with openings 8 (see Fig. 2). The number of lugs 7 and their location corresponds to the number and location of the vertical posts 5. By means of the said lugs 7 the bolt 2 is movably connected to the posts 5 with the possibility of free movement along the posts in the up-down direction for opening and closing the inlet opening 3. In the upper part the vertical posts 5 have limiters 9 for lifting the bolt 2, preventing the bolt from being thrown off the vertical posts.

The shutter 2 made of steel sheet lies under its own weight on the seal 4, closing the inlet opening 3 of the housing 1 of the KSID. Uniform fit of the shutter 2 in this case allows achieving class A tightness. When excess pressure is applied to the shutter 2 made of steel sheet, it rises along the vertical posts 5 until it stops against the limiters 9, uniformly opening the inlet opening 3. When the pressure drops below the opening value, the shutter 2 is uniformly lowered along the posts 5 onto the seal 4, closing the inlet opening 3 and ensuring tightness for long-term maintenance of the required concentration of the fire extinguishing agent GOTV (gas fire extinguishing agent) in the protected room.

The need to use a KSID as part of a gas fire extinguishing system is determined by the “Methodology for calculating the area of an opening for relieving excess pressure in rooms protected by gas fire extinguishing systems.”

The KSID is a device whose shutter opens when the excess pressure of the GFTS in the room is reached, corresponding to the opening pressure, and the environment is discharged from the protected room into the atmosphere.

After the medium has been released to the set pressure, the valve 2 is seated on the inlet 3 with the specified valve tightness, which ensures longer preservation of the fire extinguishing concentration of the GFTS in the protected room.

The KSID is mounted on vertical enclosing structures (walls) inside the protected object in accordance with the requirements of the project for an automatic gas fire extinguishing system.

The KSID can have a special heat-insulating coating on the body and shutter, preventing moisture condensation on the internal surfaces of the valve, which allows the valve to be installed on the wall of the enclosing structure that is in direct contact with the external environment.

Before starting installation work on the KSID, it is necessary to make an opening in the enclosing structures of the room and mark the location of the holes for mounting the valve.

Install the KSID in a horizontal position with the inlet opening down and secure the outlet opening flange to the enclosing structures through a rubber gasket using fasteners (bolt, screw, wood screw).

Check the proper operation of the valve shut-off element by forcibly pressing the valve shutter from below with your hand. Apply force to the center of the shutter. The shutter should move without jamming until it contacts the travel limiters 9 of the posts 5.

The working environment coming out of the valve should be discharged into the atmosphere or a safe place. It is not allowed to move the gas environment with an increased concentration of GFTS from the protected room to another place where people may be.

The test results showed an increase in the reliability of the excess pressure relief valve.

The claimed excess pressure valve can be manufactured on existing equipment from known materials (steel, seal - rubber).

The claimed utility model can be used in the field of fire extinguishing to protect premises and equipment from excess gas pressure generated during the release of a gas fire extinguishing agent (GFEA) into a room from gas fire extinguishing installations.

Claims (8)

1. An excess pressure relief valve comprising a housing with an inlet provided with a seal and a shutter pressed against the inlet under its own weight, characterized in that the housing is provided with vertical posts made on opposite sides of the inlet in front of the side walls of the housing and having limiters for lifting the shutter, made of a steel sheet and provided with lugs with holes by means of which the shutter is connected to the vertical posts with the possibility of moving along them. 2. The valve according to item 1, characterized in that the body is equipped with two vertical posts. 3. The valve according to item 1, characterized in that the body is equipped with four vertical posts, a pair on each side. 4. The valve according to item 1, characterized in that the body is equipped with six vertical posts, three on each side. 5. The valve according to item 1, characterized in that the shutter is made of a steel sheet up to 12 mm thick. 6. The valve according to item 1, characterized in that the shutter is provided with two lugs located on the ends facing the side walls of the body. 7. The valve according to item 1, characterized in that the shutter is provided with four lugs located on the ends facing the side walls of the body. 8. The valve according to item 1, characterized in that the shutter is provided with six lugs located on the ends facing the side walls of the body.