RU130657U1 - EXPLOSION PROTECTION DEVICE WITH EXPLOSIVE MEMBRANE - Google Patents

Abstract

1. Explosion-proof device with a bursting disc containing a valve body, a shutter and a bursting element, characterized in that it further comprises a lined cargo gate, movably connected to the valve body by at least three flexible connections, for example in the form of chains, one end of which is pivotally connected to the valve body, and the other is pivotally connected to the cargo lock, while the valve body is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and in the lower cylindrical part Situated lined cargo gate overlying the opening in the housing of the protected object, and in the upper cylindrical portion of the valve body situated fastening part of the bursting disc, the valve settings are in the following ranges of optimal values: a = D / Dy = 1,5 ÷ 2,0; where Dy is the diameter of the upper cylindrical part of the valve body equal to the maximum size of the opening of the body of the protected object; D is the diameter of the lower cylindrical part of the valve body. 2. The explosion-proof device according to claim 1, characterized in that the bursting disc between the rings is clamped without using any gaskets, and the sealing surfaces of the rings are made of the correct geometric shape and high purity of processing, and when assembling the membrane assembly in the flange connection, the rings are fastened to one another diametrically spaced strips and screws, and one of the holes for the screws in the plank has an oblong shape, while the shapes of the surfaces of the rings in contact with the flanges fully correspond to the shape e the sealing surfaces of flanges, the membrane parameters kt

Description

The utility model relates to explosion-proof devices and can be used for explosion protection of technological equipment in the event of an emergency.

The closest technical solution to the claimed object is an explosion-proof device according to the application No. 2008148151, F16D 3/04, published in BI No. 35 of 12.20.10 (prototype), containing a valve body, a shutter, heat insulating and explosive elements.

A disadvantage of the known solution is the relatively low reliability of operation of the bursting disc.

EFFECT: increased efficiency of protection of technological equipment from explosions in the event of an emergency (ES) by increasing the speed and reliability of the operation of explosive elements.

This is achieved by the fact that in an explosion-proof device with a bursting disc containing a valve body, a shutter and a bursting element, an additional lined cargo gate is movably connected to the valve body by means of at least three flexible connections, for example, in the form of chains, one end of which is pivotally connected to the valve body, and the other is pivotally connected to the cargo lock, while the valve body is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and in the lower cylindrical the lined part contains a lined cargo lock that covers the hole in the body of the protected object, and a bursting disc attachment unit is located in the upper cylindrical part of the valve body, and the valve parameters are in the following optimal ranges of values: a = D / Dy = 1.5 ÷ 2.0 ; where Dy is the diameter of the upper cylindrical part of the valve body equal to the maximum hole size of the body of the protected object; D is the diameter of the lower cylindrical part of the valve body.

In Fig.1 shows a General view of an explosion-proof device with a bursting disc, in Fig.2 - the mounting unit of the membrane safety device, in Fig.3 - an embodiment of a bursting disc with radial risks, in Fig.4 - an embodiment of a bursting disc with a circular risk, figure 5 is an embodiment of a bursting disc with slots, figure 6 is an embodiment of a bursting disc with holes.

The explosion-proof device (Fig. 1) with a bursting disc 7 is mounted on the housing 1 of the protected object and contains a lined cargo closure 2, movably connected to the valve housing 3 by at least three flexible connections, for example in the form of chains 9, one end of which is pivotally connected to the housing 3 valves, and the other is pivotally connected to the cargo valve 2 valve. The valve body is made in the form of a lower cylindrical part 3, a middle conical part 4, and an upper cylindrical part 5, and a lined cargo lock 2 is placed in the lower cylindrical part, covering the hole with a diameter Dy in the body 1 of the protected object. A node 6 of the bursting disc 7 is fastened to the upper cylindrical part 5 of the valve body by means of fasteners 8. The shutter 2 does not provide a tight seal for the discharge opening of the protected apparatus 1, it lies freely on it, and slightly loosened chains 9 serve only to center the shutter 2, t. e. to prevent its large displacements relative to the discharge opening, and the lined cargo lock 2 protects the valve body from burning in case of high temperature in the protected device. To obtain the highest explosion protection efficiency of production equipment, the explosion protection valve has parameters that are in the following optimal ranges of values: a = D / Dy = 1.5 ÷ 2.0; where Dy is the diameter of the upper cylindrical part 5 of the valve body, equal to the maximum size of the hole of the body 1 of the protected object; D is the diameter of the lower cylindrical part 3 of the valve body.

The explosion-proof device can be equipped with a membrane safety device 6 of the type of flange connection, which contains a membrane unit (figure 2), which consists of a membrane 7 and a pair of clamping rings 10 and 11. The membrane 7 between the rings is clamped without the use of any gaskets, which leads to very stringent requirements for the quality of the sealing surfaces of the rings, such as the correct geometric shape and high purity of processing. For ease of assembly of the membrane assembly in the flange connection, the rings are fastened one to the other by two diametrically arranged strips 12 and screws 13. One of the holes for the screws in the stripe has an oblong shape so that the presence of the strips does not prevent the membrane from being clamped evenly and tightly between the clamping rings when tightened flange connection. Moreover, the shapes of the surfaces of the rings in contact with the flanges must fully correspond to the shape of the sealing surfaces of the flanges; the design of the membrane assembly is intended for installation in flanges with a thorn-groove-type sealing surface.

Bursting membranes are usually made from thin-sheet rolled metal of ductile metals such as aluminum, nickel, stainless steel, brass, copper, titanium, monel, etc. There are known cases of the use of non-metallic membranes from polyethylene and fluoroplastic films, from paper, cardboard, paronite, asbestos, and even from plywood. However, these materials are characterized by very unstable mechanical properties, membranes from them have a large variation in response pressure and are not recommended for widespread use, although in some cases their use is the only possible one. Typically, these are membranes of large sizes (with a diameter of about a meter or more), sometimes square or rectangular in shape and with very low response pressure, i.e. designed for explosion protection of low-strength equipment. The use of asbestos is justified by the high temperature inside the equipment, i.e. in case of explosion protection of furnaces, furnaces and other high temperature reactors.

To obtain the highest explosion protection efficiency of industrial equipment, the membrane unit has parameters that are in the following optimal ranges of values: a = D ₁ / D = 1.1 ÷ 2.0; b = D ₂ / D = 1,11 ÷ 2,4; c = D ₂ / D ₁ = 1.01 ÷ 1.3;

where D is the diameter of the bore of the membrane unit, equal to the inner diameter of the rings in contact with the flanges and the membrane, D ₁ is the outer diameter of the bursting membrane, D ₂ is the outer diameter of the rings in contact with the flanges.

Designs of bursting membranes can be performed with radial (figure 3), circular (figure 4) risks. Radial risks are easier to manufacture, however, such a membrane often breaks when triggered by one or two risks and does not provide full disclosure of the bore. The membrane with a circumferential risk (figure 4), as a rule, is fully disclosed. To prevent separation, the risk is applied along an open circular contour, while on the side opposite to the pressure source, a segment stop 7 is installed at the ends of the risks, the chord of which tightens a larger circular arc than the chord connecting the ends of the risks, as shown in Fig. 4. Also effective are membranes with slots (Fig. 5) and holes (Fig. 6). They are always two-layer, since they additionally contain a sealing substrate of corrosion-resistant and low-strength material.

Explosion-proof device with a bursting disc operates as follows.

The pressure in the protected device acts on the shutter 2, which shuts off the inlet aperture and with a rapid increase in pressure, it can rise up as far as the length of the chains holding it 9. The membrane 7 experiences large plastic deformations and acquires a pronounced dome, in shape very close to the spherical segment. Most often, the membrane is given a domed shape in advance during manufacture, subjecting it to loading with a pressure of about 90% of the bursting. In this case, almost the entire stock of plastic deformations of the material is practically exhausted, therefore, the membrane’s performance is further increased. At explosive pressure, the membrane experiences rupture deformations and ruptures, thereby ensuring full disclosure of the bore of the safety device to exit the shock wave and preserve equipment integrity.

Bursting membranes are usually made from thin-sheet rolled metal of ductile metals such as aluminum, nickel, stainless steel, brass, copper, titanium, monel, etc. There are known cases of the use of non-metallic membranes from polyethylene and fluoroplastic films, from paper, cardboard, paronite, asbestos, and even from plywood. However, these materials are characterized by very unstable mechanical properties, membranes from them have a large variation in response pressure and are not recommended for widespread use, although in some cases their use is the only possible one. Typically, these are membranes of large sizes (with a diameter of about a meter or more), sometimes square or rectangular in shape and with very low response pressure, i.e. designed for explosion protection of low-strength equipment. The use of asbestos is justified by the high temperature inside the equipment, i.e. in case of explosion protection of furnaces, furnaces and other high temperature reactors.

For chemical and other related industries, the products of which are valuable and extremely harmful to the environment, the condition of complete tightness should be considered as a priority, largely determining the area of their possible application.

Claims (9)

1. Explosion-proof device with a bursting disc containing a valve body, a shutter and a bursting element, characterized in that it further comprises a lined cargo gate, movably connected to the valve body by at least three flexible connections, for example in the form of chains, one end of which is pivotally connected to the valve body, and the other is pivotally connected to the cargo lock, while the valve body is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and in the lower cylindrical part Situated lined cargo gate overlying the opening in the housing of the protected object, and in the upper cylindrical portion of the valve body situated fastening part of the bursting disc, the valve settings are in the following ranges of optimal values: a = D / Dy = 1,5 ÷ 2,0; where Dy is the diameter of the upper cylindrical part of the valve body equal to the maximum size of the opening of the body of the protected object; D is the diameter of the lower cylindrical part of the valve body. 2. The explosion-proof device according to claim 1, characterized in that the rupture disk between the rings is clamped without the use of any gaskets, and the sealing surfaces of the rings are made of the correct geometric shape and high purity of processing, and when assembling the membrane unit in the flange connection, they fasten one with the other two diametrically spaced strips and screws, and one of the holes for the screws in the bar has an oblong shape, while the shapes of the surfaces of the rings in contact with the flanges fully correspond to the sealing surfaces of the flanges, while the parameters of the membrane assembly are in the following optimal ranges of values: a = D ₁ / D = 1.1 ÷ 2.0; b = D ₂ / D = 1,11 ÷ 2,4; c = D ₂ / D ₁ = 1.01 ÷ 1.3; where D is the diameter of the bore of the membrane unit, equal to the inner diameter of the rings in contact with the flanges and the membrane, D ₁ is the outer diameter of the bursting membrane, D ₂ is the outer diameter of the rings in contact with the flanges. 3. The explosion-proof device according to claim 1, characterized in that the membrane is made of sheet metal rolled ductile metals such as aluminum, nickel, stainless steel, brass, copper, titanium, monel. 4. The explosion-proof device according to claim 1, characterized in that the membrane is made of polyethylene and fluoroplastic films, of paper, cardboard, paronite, asbestos. 5. The explosion-proof device according to claim 1, characterized in that the membrane is made with radial risks. 6. The explosion-proof device according to claim 1, characterized in that the membrane is made with circular risks. 7. The explosion-proof device according to claim 1, characterized in that the membrane is made with slots. 8. The explosion-proof device according to claim 1, characterized in that the membrane is made with holes. 9. The explosion-proof device according to claim 1, characterized in that the membrane is made of two layers and additionally contains a sealing substrate of a corrosion-resistant and low-strength material.

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