RU2612519C1 - Kochetov's explosion-proof valve with alert emergency system - Google Patents

Abstract

FIELD: machine engineering.

SUBSTANCE: explosion-proof valve comprises a valve body and a thermally insulating discontinuous elements lined cargo shutter movably connected to the valve body. Movable cargo compound is lined with a base shutter valve body is in the form of three rods vertically installed in the holes formed in the peripheral part of the housing shutter lined cargo. Lower part rods are fixed at the base of the valve body and the top have a damping device. A damping device made of vibration damping material such as hard "Agat". The base unit is connected to the damping of the elastomer sleeve and has a central hole through which the rod passes. The sleeve has at least three openings, coaxial with the bar, in which there are elastic elements, such as coil springs, the upper-end face of which, by means of fastening elements, are connected with the base, and the bottom is in unpressed condition and stands for the lower sleeve plane to the distance, determined by the forces developed by the shock wave. Inside the elastic elements coaxially to them, there are additional elastic elements. Their upper end is connected to the base of the damping device, and the bottom - in a free state and acts as the lower plane of the elastic elements on the distance determined forces developed by the blast shock. To the base of the dampener, the sleeve, made of the fast-destroying material, is attached. The security indicator is attached to the outer surface of the sleeve is responsive to the occurrence of an emergency. The indicator is designed as a sensor that responds to a deformation, such as strain gage, whose output is connected to a signal amplifier strain amplifier. Yield strain amplifier is connected to the input device in the system notification of an emergency.

EFFECT: increase the efficiency of the protection of technological equipment from explosions by increasing the damping lined cargo gate.

3 dwg

Description

The invention relates to mechanical engineering and can be used for explosion protection of technological equipment.

The closest technical solution to the claimed object is an explosion-proof valve according to the patent of Russian Federation No. 2379569, F16D 3/04, (prototype), comprising 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 lined cargo bolt during the propagation of a shock wave.

The technical result is an increase in the efficiency of protection of technological equipment from explosions by increasing the damping of the lined cargo bolt.

This is achieved by the fact that in the explosion-proof valve containing the valve body, heat insulating and bursting elements, a lined cargo gate, movably connected to the valve body, the valve body is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and in the lower cylindrical part a lined cargo lock is placed, covering the hole in the body of the protected object, and a heat-insulating element and a sealing element are placed in the upper cylindrical part of the valve body a membrane pressed to the valve body by means of a cover pivotally connected to a lever interacting with the chipper, and the fastening element of the discontinuous element is fixed with its upper part on the lever and the lower one to the upper cylindrical part of the valve body, and consists of a wire, a locking bolt, a fork, the lever of the valve cover, the nut, two drums located respectively in the fork of the lever of the valve cover and in the fork of the upper cylindrical part of the valve body, while the ends of the wire are inserted into the holes of the drums and then yvayutsya on them, and the gap h between the forks of the order of (1,5 ÷ 3) on the wire diameter, and the valve settings are in the following ranges of optimal values:

а = D / Dу = 1,5 ÷ 2,0; b = H / L = 1.3 ÷ 1.8; s = H / Dy = 2.5 ÷ 3.0,

where Du - the diameter of the upper cylindrical part of the valve body 3, equal to the maximum hole size of the body 1 of the protected object; D is the diameter of the lower cylindrical part of the valve body 3; H is the height of the valve assembly; L is the maximum overall dimension of the valve in plan, the movable connection of the lined cargo bolt with the base of the valve body is made in the form of three vertically mounted rods in the holes made in the peripheral part of the body of the lined cargo bolt.

In FIG. 1 shows a front section of an explosion-proof valve; FIG. 2 - attachment of the bursting element, in FIG. 3 is a diagram of a damping device.

The explosion-proof valve is installed on the housing 19 of the protected object by means of fasteners 20 and contains a lined cargo gate 2, movably connected to the base 1 of the valve body 3.

The movable connection of the lined cargo bolt 2 with the base 1 of the valve body is made in the form of three vertically mounted rods 10 in the holes made in the peripheral part of the body of the lined cargo bolt 2. The lower part of the rods 10 are fixed in the base 1 of the valve body, and in the upper part a damping device 11, mounted on horizontal bridges 12 of the rods 10 and facing the load gate 2.

Each of the three damping devices 11 (Fig. 3) is mounted on a horizontal jumper 12, rigidly connected to the rod 10 and made in the form of a circular disk, on which the base 21 of the damping device made of a hard vibration-damping material of the Agat type is fixed by screws 22, which is connected to a sleeve 23 of an elastomer having a central hole through which the rod 10 passes. The sleeve has at least three holes 24 coaxial with the rod 10 in which elastic elements 25 are located, for example, indricheskie coil springs, whose upper end by fasteners 26 connected to the base 21 of the damping device, and the bottom - is in the (nepodzhatom) state and protrudes beyond the bottom plane of the sleeve 23 on the distance determined forces developed explosive shock wave.

A variant is possible when, in the damping device 11, coaxially covering the elastic spring elements 25 and 27 and not protruding beyond their lower surface, a sleeve 23 made of rapidly decaying material is attached to the base 21 of the damping device made of rigid vibration damping material such as “Agate” for example, triplex glass. A safety indicator 28 is attached to the outer surface of this sleeve 23, responding to an emergency, made, for example, in the form of a sensor that responds to deformation, such as a strain gauge (strain gauge), the output of which is connected to a signal amplifier, such as a strain gauge 29, and the output of a strain gauge 29 is connected to the input of the emergency warning device 30.

It is possible that inside the elastic elements 25, coaxially with them, additional elastic elements 27 are located, for example, made in the form of coil springs, while their upper end is connected to the base 21 of the damping device, and the lower end is in a free (unpressed) state and stands for the lower plane of the elastic elements 25 at a distance determined by the force developed by the shock wave. This allows you to more evenly absorb the energy of the shock wave.

The valve body 3 is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and a lined cargo lock 2 is placed in the lower cylindrical part, covering the hole with a diameter of Du in the housing 1 of the protected object. In the upper cylindrical part of the valve body 3 there is a heat-insulating element 4 and a sealing membrane 5 pressed to the valve body by means of a cover 6, pivotally connected to the lever 8 interacting with the chipper 7. The fastening element 9 of the bursting element (wire 18) is mounted with its upper part on the lever 8, and the bottom to the upper cylindrical part of the valve body 3. The fastening element of the bursting element consists of a wire 18, a locking bolt 13, a plug 14, a lever 15 of the valve cover, a nut 16, and two drums 17 located respectively in the fork 14 of the lever 15 of the valve cover and in the fork of the upper cylindrical part of the valve body 3. The ends of the wire 18 are inserted into the holes of the drums and then wound on them when they are rotated with a conventional wrench. After sufficient wire tension, the drums 17 are fixed with locking bolts 13. It is important to note that the valve operating pressure depends only on the strength of the wire 18 and does not depend on its tension. So that valve actuation is not preceded by large plastic deformations of the wire, its length and, consequently, the clearance h should be minimal. The gap h should be of the order of (1.5 ÷ 3) d, where d is the diameter of the wire. So that the fastening of the ends of the wire is reliable and does not allow them to be pulled out of the holes in the drum, at least three turns must be wound on it. The hinged lid 6 through the lever 8 is held in a closed position with a bursting element 9, the role of which is performed by a calibrated section wire. For complete valve sealing, a membrane 5 made of aluminum foil or of a polymeric material is used. Under the action of pressure in the protected device, the membrane is pressed against the cover and thus through the lever 8 all the pressure is transferred to the lever hinge and the bursting wire 18. The membrane itself is almost completely unloaded and the valve operating pressure (wire break 18) has a significant effect does not render. In this sense, the membrane is not a design element: the design of the explosive valve.

If technological processes take place in the protected device 1 at high temperatures, then two levels of thermal insulation are provided for thermal protection of the membrane 5 and other valve parts. The first of them is a cargo lock 2, lined with refractory material, and the second is mineral wool, asbestos chips or other heat-resistant porous material 4, laid in a basket of metal rods or strips. The shutter 2 does not provide a tight shutoff of the discharge opening of the protected apparatus 1, it lies freely on it, and slightly loosened chains 10 serve only to center the shutter 2, i.e. to prevent large displacements relative to the outlet.

The lined cargo lock 2 protects the valve body 3 from burning out in case of high temperature in the protected device, and filling 4 further reduces the temperature in the area of the membrane 5. To obtain the most efficient explosion protection of production equipment, the explosion-proof valve has parameters that are in the following optimal ranges of values : a = D / Dy = 1.5 ÷ 2.0; b = H / L = 1.3 ÷ 1.8; s = H / Dy = 2.5 ÷ 3.0,

where Dy is the diameter of the upper cylindrical part of the valve body 3, equal to the maximum hole size of the body 1 of the protected object; D is the diameter of the lower cylindrical part of the valve body 3; H is the height of the valve assembly; L is the maximum overall dimension of the valve in the plan (in the top view).

Explosion proof valve operates as follows.

The pressure in the device to be protected acts on the cover 6, since the shutter 2 closes the inlet and is leaky and can rapidly rise with a rapid increase in pressure, and the insulating layer 4 is porous. When the valve is activated, the cover 6 is thrown as far as it will go into the bumpers 7, the backfill 4 is ejected from the valve cavity by the gas flow, and the shutter 2 is lifted up as far as the length of the holding rods 10 allows, while the partial absorption of explosive energy falls on damping devices 11 mounted on horizontal jumpers 12. In this case, elastic elements 25 are first compressed, for example, cylindrical coil springs, the lower ends of which are in a free (unpressed) state, and then the hubs extinguish the explosion energy 23 from an elastomer, for example injection molded polyurethane together with elastic elements 25, in addition to damping in the material of the bushings 23, there is also a dry friction of the elastic elements 25 against the side surfaces of the holes 24 located in the bushings 23 of the elastomer.

The introduction of additional elastic elements 27, for example, made in the form of cylindrical coil springs, allows more evenly absorb the energy of the shock wave.

After the discharge of gases, the shutter 2 and the cover 7 are lowered and close the valve outlet. In this case, the valve tightness is not completely restored, however, an intensive intake of air from the atmosphere into the cavity of the protected device, which can cause a secondary explosion in the equipment, is eliminated.

After the valve is activated and the causes of the explosion in the equipment are eliminated, the valve must be restored, i.e. it is necessary to lay the insulating layer in the basket.

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 (3)

An explosion-proof valve comprising a valve body, heat insulating and bursting elements, a lined cargo gate, movably connected to the valve body, while the valve body is made in the form of a lower cylindrical, middle conical and upper cylindrical parts, and a lined cargo gate is located in the lower cylindrical part, overlapping a hole in the body of the protected object, and in the upper cylindrical part of the valve body there is a heat-insulating element and a sealing membrane pressed against the body the valve mustache by means of a cover pivotally connected to the lever interacting with the chipper, and the fastening element of the discontinuous element is fastened with its upper part to the lever and the lower to the upper cylindrical part of the valve body, while the fastening element of the discontinuous element consists of a wire, a locking bolt, a fork , valve cover lever, nut, two drums located respectively in the valve cover lever fork and in the fork of the upper cylindrical part of the valve body, while the ends of the wire are inserted into the holes of the drum in and then wound on them, and the gap h between the forks is of the order of (1.5 ÷ 3) of the wire diameter, and the valve parameters are in the following optimal ranges of values: a = D / Dy = 1.5 ÷ 2.0; b = H / L = 1.3 ÷ 1.8; c = H / Dy = 2.5 ÷ 3.0, where Dy is the diameter of the upper cylindrical part of the valve body 3, equal to the maximum hole size of the body 1 of the protected object; D is the diameter of the lower cylindrical part of the valve body 3; H is the height of the valve assembly; L is the maximum overall dimension of the valve in plan, and the movable connection of the lined cargo bolt with the base of the valve body is made in the form of three vertically mounted rods in holes made in the peripheral part of the body of the lined cargo bolt, with the lower part of the rods fixed to the base of the valve body, and in the upper part they have a damping device fixed to the horizontal lintels of the rods and facing the load gate, each of the three damping devices is fixed leno on a horizontal jumper, rigidly connected to the rod and made in the form of a circular disk, on which the base of a damping device made of a hard vibro-damping material of the type "Agate" is fixed by screws, which is connected to an elastomer sleeve having a central hole through which the rod passes and the sleeve has at least three holes coaxial with the rod, in which elastic elements are located, for example cylindrical coil springs, the upper end of which is of mantle elements is connected to the base of the damping device, and the lower one is in a free state and protrudes beyond the lower plane of the sleeve at a distance determined by the force developed by the shock wave, characterized in that additional elastic elements are arranged inside the elastic elements coaxially with them in the form of cylindrical coil springs, while their upper end is connected to the base of the damping device, and the lower one is in a free, non-pressed state and protrudes beyond the lower plane of the elastic elements at a distance determined by the force developed by the shock wave, while in the damping device, coaxially covering the elastic spring elements and not protruding beyond their lower surface, a sleeve made made of quick-breaking material in the form of glass of the “triplex” type, and a safety indicator responding to an emergency situation is attached to the outer surface of this sleeve space filled with a sensor responsive to the strain gage type, whose output is connected with a signal amplifier, strain amplifier, and the strain amplifier output coupled to an input device of the system notification of an emergency.

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