RU2519984C1 - Means of volumetric thermal and fire protection of drive of shutoff and control valves of pipeline in case of fire - Google Patents

Abstract

FIELD: fire safety.SUBSTANCE: means of volumetric thermal and fire protection of drive of shutoff and control valves of pipeline in case of fire comprises a rigid box made in the form of an open vessel, which internal volume is equipped with a coating of fire retardant material. At that the securable object is made in the form shutoff and control valves with the housing and the main shaft connected to the locking element, the servo-actuator and the control unit. At that the bottom of this box is made of a rigid magnesite plate and the box is made in the form of a rigid volumetric frame with the walls of the sandwich panels. At that under the bottom of the means the bearing assembly is placed consisting of a support platform, and a lower sleeve is located in it in which the additional hollow shaft of the servo-actuator is mounted, connected to the main shaft of the locking element. At that in the contact between the panel of the bottom and the panels of the box the seal of soft fire retardant material is placed, glued by heat-resistant adhesive to the sandwich panels of the box, latticed with steel amplifier of its mechanical strength and provided with handles with the ability of its removal, the additional shaft of servo-actuator is kinematically connected to the joint lever rotation of the indicator of position of the locking element, and the electrical cable of the control unit and the working power supply connections of the servo-actuator are passed through the holes in the bottom of the means and are sealed in it.EFFECT: improvement of operational capabilities and reliability of operation.16 cl, 16 dwg

Description

The invention relates to fire fighting equipment, and in particular to methods and devices for preventing fire or containing fire, in particular to physical fire barriers and barriers.

The invention can be used for fire protection in pipelines, tanks and other equipment of gas and gas collection points, gas processing plants, underground gas storages, linear parts of gas pipelines, technological piping of compressor, booster, gas distribution stations.

Known means volumetric thermal and fire protection drive shutoff and control valves in a fire, containing a rigid box made in the form of an open container, the internal volume of which is equipped with a coating of flame retardant material, and a protected object placed inside the box (patent RU2302271, IPC A62C 2 / July 6, 2005).

This technical solution is the closest to the invention, therefore, taken as a prototype.

The disadvantages of the prototype are the complex design, the assembly and maintenance technology, as well as the inability to ensure reliable operation of the shut-off and control valves in a fire due to unreliable protection of pipelines, their joints, protruding shut-off valves due to imperfection of their closing elements, damage during fire, as well as the complexity and material consumption of works related to fire and thermal protection of fire hazardous facilities.

The technical result from the use of the claimed technical solution is to increase operational capabilities by simplifying the design, assembly and maintenance technology, as well as ensuring the failure-free operation of the pipeline shut-off and control valves in case of fire.

The following are general and particular essential features characterizing the causal relationship of the essential features of the invention with the specified technical result.

The means of volumetric thermal and fire protection of the actuator of the pipeline shut-off and control valves in case of fire contains a rigid box made in the form of an open container, the internal volume of which is equipped with a coating of fire-retardant material, and a protected object located inside the box. The specified protected object is made in the form of shut-off and control valves with a housing and a main shaft associated with a shut-off element, a servo-drive and a control unit. In this case, the tool is provided with a bottom of the box made of a hard magnesite plate covered with a multilayer panel, and the said box is made in the form of a rigid volumetric frame with walls of multilayer panels placed indented above its open part, making it possible to place a multilayer panel located on the specified bottom panels. The multilayer panels of the box and the bottom are glued from three layers of plates based on magnesite materials, the middle of which is made of foamed magnesite, and these magnesite plates have the following thicknesses on the layers: inner layer 3-20 mm; the middle layer is 10-120 mm and the outer layer is 5-25 mm, while the last, outer layer is lined with an aluminum coating 0.25-3 mm thick and painted with fire-retardant paint. Under the bottom of the means there is a bearing assembly consisting of a support platform fixed to the housing on which a hard magnesite plate is installed, both have a central hole and a lower sleeve is placed in it, in which an additional hollow servo drive shaft is installed, connected to the main shaft of the shut-off element. The specified lower sleeve is hermetically placed in the holes conjugated with each other in the support area, magnesite plate and in the lower mounting element mounted on the latter, and interconnected with the lower sleeve by means of fixation. On the lower mounting element, the bottom of the tool is installed on the bottom plane, made of a hard magnesite plate, paired with the upper plane and the upper mounting element installed above it, inside of which a rigid fire-retardant plate is placed above the interface, detachably connected to the lower upper mounting element, the bottom of the tool and the lower mounting an element. In these connected parts, through coaxial holes are made with the possibility of free placement of the mentioned additional shaft in them, and an opening is made in the upper part of the upper mounting element in which the upper sleeve of the additional shaft is placed. The space around the lower mounting element between the magnesite base plate and the bottom of the tool is filled with soft fire-resistant material based on stone wool with aluminum foil on the outside. In the contact between the bottom panel and the duct panels, a seal is made of soft fire-resistant material based on stone wool glued with heat-resistant adhesive to the multilayer panels of the duct, sheathed with a steel amplifier of its mechanical strength and equipped with handles with the possibility of removing it if necessary for operational maintenance or valve control. Labels are applied to the upper surface of the box for the indicator of the position of the locking element of the valve, the additional servo shaft is kinematically connected to the cranked lever of rotation of the indicator of the position of the locking element. The electric cable of the control unit and the working supply connections of the servo drive are passed through the holes in the bottom of the tool and sealed in it with fireproof mastic. The supporting platform may be made of steel sheet or in the form of a lattice. The specified servo is made using electric traction or in the form of an actuator of a pneumatic type. These lower and upper mounting elements may have a C-shaped cross section or have the form of a volumetric lattice with supports for the lower and upper bushings or have the form of a parallelepiped or cube with cutouts on the walls. The bottom and the box can be interconnected by safety cables. The air intake pipe of the pneumatic type servo can be equipped with a flame arrester and a gasket. The bottom of the tool may have a frame structure in which a rigid magnesite plate is fixed. The box can be made in the form of a parallelepiped or in the form of a truncated cone with a cylindrical lower part, or is made of a cylindrical shape or in the form of a hemisphere. The box and the bottom can be impregnated on the outside on the surface of the fire exposure with a composition that reflects thermal radiation.

The invention is illustrated by drawings, where: in Fig.1 shows a cross section of a device of a spherical shape; figure 2 presents a General view of the device conical shape; figure 3 presents a General view of the device in a cylindrical shape; figure 4 presents a General view of the device in the form of a parallelepiped; figure 5 is a longitudinal section of the device of figure 4; figure 6 is a top view of figure 5; Fig.7 is a transverse section of the box; in Fig.8 is a view of I in Fig.5; Fig.9 is a view aa in Fig.7; figure 10 is a view II of figure 5; figure 11 is a view B of figure 7, the panel 8 of the bottom is conditionally combined with the box; in Fig.12 is a view of G in Fig.7; on Fig - view bb in Fig; in Fig.14 - EE in Fig.11; on Fig - view FJ in Fig.11; in Fig.16 - device with safety cables.

The means of volumetric thermal and fire protection of the actuator of the pipeline shut-off and control valves in case of fire contains a rigid box 1 made in the form of an open container, the internal volume of which is equipped with a coating of fire-retardant material, and a protected object 2 located inside the box 1.

The protected object 2 is made in the form of shut-off and control valves with a housing 3 and a main shaft 4 connected to a locking element (not shown), a servo-drive 5 and a control unit 6.

The tool is equipped with a bottom 7 of the box 1, made of a hard magnesite plate covered with a multilayer panel 8, and the said box 1 is made in the form of a rigid volumetric frame with walls 9 of multilayer panels placed above its open part with an indent L, which makes it possible to place it located on the specified bottom of the multilayer panel 8.

Multilayer panels 9 of the box 1 and the bottom 7 are glued from three layers of 10, 11 and 12 plates based on magnesite materials, the middle of which 12 is made of foamed magnesite.

Magnesite plates have the following thicknesses in layers: inner 10 layer 3-20 mm; the middle 11 layer of 10-120 mm and the outer 12 layer of 5-25 mm, while the last, outer 12 layer is lined with aluminum coating 13 with a thickness of 0.25-3 mm and painted with fire-retardant paint 14.

Box panels can be permanently connected to each other (for example, by gluing) with cut planes at an angle of 45 degrees of mating surfaces or with one-piece connection of the inner surfaces of the aluminum coverings of the side panels with the ends of the aluminum coating of the upper panel placed flush in the indicated outlets of the side panels (not shown), when this joint between the indicated panels can be closed by a corner or plate tightly attached to the panels of the box.

Under the bottom 7 of the means there is a bearing assembly consisting of a support platform 15 fixed to the housing 3, on which a hard magnesite plate 16 is installed, both of which have a central hole and a lower sleeve 17 is placed in it, in which an additional hollow shaft 18 of the servo drive 2 is installed, connected to the main shaft 4 of the locking element (not shown).

The lower sleeve 17 is hermetically placed in the holes conjugated with each other in the support area 15, the magnesite plate 16 and in the lower mounting element 19 (Fig. 5) mounted on the latter, and connected with each other and the lower sleeve 17 by the fixing means 20.

On the lower mounting element 19, the bottom 7 of the means is installed with the lower plane, made of a hard magnesite plate, conjugated by the upper plane with the upper mounting element 21 mounted above it, inside of which a rigid fire-retardant plate 22 is placed above the interface, detachably connected to the lower upper mounting element 21, the bottom of the tool 7 and the lower mounting element 19.

In these connected parts, through coaxial holes are made with the possibility of free placement of the mentioned additional shaft 18 in them, and an opening is made in the upper part of the upper mounting element 21 in which the upper sleeve 23 of the additional shaft 18 is placed.

The space around the lower mounting element 19 between the magnesite plate 16 of the support platform 15 and the bottom 7 of the tool is filled with soft fire-retardant material 24 made of stone wool with aluminum foil 25 from the outside.

In contact between the bottom panel 7 and the panels 9 of the duct 1, a seal 26 is installed of soft fire-resistant material of their stone wool, which is glued with heat-resistant adhesive to the panels of the duct 9.

The box 1 is sheathed by a steel amplifier 27 of its mechanical strength and is equipped with handles 28 with the possibility of removing it if necessary, operational maintenance or control valves.

On the upper surface of the box 1 marked 29 for the position indicator of the locking element of the valve.

The additional shaft 18 of the servo drive 2 is kinematically connected to the crankshaft 30 for turning the position indicator 31 of the locking element.

The electric cable 32 of the control unit 6 and the working supply connection 33 (Fig. 5) of the servo drive 2 are passed through the holes in the bottom of the tool 7 and sealed in it with fireproof mastic.

The specified supporting platform 15 may be made of steel sheet or in the form of a lattice.

The servo is made using electric traction (figure 1) or in the form of an actuator of a pneumatic type (figure 5).

The lower 19 and upper 21 mounting elements can have a C-shaped cross-section, or have the form of a volumetric lattice with supports for the lower 17 and upper 23 bushings, or have the form of a parallelepiped or cube with cutouts on the walls.

The bottom 7 and the box 1 can be interconnected by safety cables 34 (Fig. 16).

The air intake pipe 35 of the pneumatic type servo is equipped with a flame arrester and a seal 37.

The bottom 7 of the tool may have a frame structure in which a rigid magnesite plate is fixed.

Box 1 can be made in the form of a parallelepiped (Fig. 5) or in the form of a truncated cone with a cylindrical lower part (Fig. 2), or made of a cylindrical shape (Fig. 3), or the box 1 is made in the form of a hemisphere (Fig. 1) .

The box 1 and the bottom 7 can be impregnated externally on the surface of the fire exposure with a composition reflecting thermal radiation.

Comparison of the claimed technical solution with the prior art known from the scientific, technical and patent documentation as of the priority date in the main and related sections did not reveal a tool that has features identical to all the features contained in the claims proposed by the applicant, including the purpose of the application. Those. the set of essential features of the claimed solution was not previously known and is not identical to any known technical solutions, therefore, it meets the condition of patentability "novelty".

This technical solution is industrially applicable, since its purpose is indicated in the description of the application and the title of the invention, it can be manufactured industrially and used to ensure trouble-free operation of the pipeline shut-off and control valves in case of fire.

The technical solution is workable, feasible and reproducible, and the distinguishing features of the device allow you to get the desired technical result - increasing operational capabilities by simplifying the design, assembly and maintenance technology, as well as ensuring the failure-free operation of the pipeline shut-off and control valves in case of fire, i.e. are significant.

The invention, in the form as described in each of the claims, can be carried out using the tools and methods described in the prototype, which became public until the priority date of the invention.

Therefore, the claimed technical solution meets the condition of patentability "industrial applicability".

An analysis of the known technical solutions in the art showed that the proposed technical solution does not follow explicitly from the prior art for the specialist, since no solutions having features matching the distinguishing features of the invention have been identified and the influence of the distinctive features on the technical indicated in the application materials has not been confirmed. result. Those. the claimed solution has features that are absent in the known technical solutions, and the use of these features in the claimed combination of essential features makes it possible to obtain a new technical result, therefore, the proposed technical solution could be obtained only through a creative approach and is not obvious to the average person skilled in the art, t .e. has an inventive step in comparison with the existing level of technology.

The device is implemented as follows.

Volumetric thermal and fire protection means are used in conjunction with an electric or pneumatic drive of the type: GBVA / DAPS, GBVA / DFPB; with a control system, designed for use on pipelines, tanks and other equipment of gas and gas collection points, gas processing plants, underground gas storages, linear parts of main gas pipelines, technological piping of compressor, booster, and gas distribution stations of OAO Gazprom. The device is intended for use in the following environmental conditions:

- climatic conditions: UHL1;

- ambient temperature: -60 ... + 40 ° C;

- relative humidity: up to 100%, with condensation;

- place of installation: open area (land);

- protection against solar radiation (ultraviolet): not required;

- Weather protection: not required.

The manufacture of the device is as follows:

The upper part is assembled from the multilayer panels made to the size of the required fireproof box with the help of aluminum corners and fasteners. According to the position and marking, a hole is drilled in the upper panel for outputting the shaft of the valve position indicator. Next, the upper part of the protective metal frame is put on the resulting structure. The lower part of the protective metal frame is attached to the upper part of the protective metal frame so that the multilayer panel structure is rigidly fixed between the internal and external protective metal frames.

A soft sealing material based on stone wool is attached to the bottom panel, which has the necessary holes for mounting and outputting electric cables and the air duct of the pneumatic drive, in place of contact with the upper part of the duct using heat-resistant glue.

The assembly of the device is as follows:

A magnesite panel is installed between the mounting elements for mounting the actuator to the valve.

An additional shaft is installed that transmits torque from the actuator to the valve.

A multilayer panel is installed between the mounting elements for mounting the actuator to the valve - the lower part of the duct.

Between the magnesite panel and the lower part of the fireproof casing, the mounting elements for fastening the actuator to the valve are covered with stone wool material with an aluminum top layer.

Through the provided holes in the multilayer panel - the lower part of the fireproof casing - the electric cables and the air duct of the pneumatic drive are connected and the entry point is sealed with fireproof mastic.

After tightening all the mechanical connections with the required torque, the upper part of the fireproof box is put on top of the drive so that the upper part rests on the multilayer bottom panel in a place glued with soft sealing material based on stone wool.

The upper part of the casing can be attached to the lower part with safety cables.

Through the provided hole in the upper panel, the shaft of the valve of the position indicator of the valve with the position indicator is installed.

This device has the following advantages over the known:

- the use of a removable upper part of the box, maintenance personnel have full access to repair, maintenance and equipment management from all sides;

- due to the use of heat-insulating spacers and a special shaft design, a decrease in the heat flux from the valve to the actuator is achieved, which allows you to fully maintain the performance of the system;

- the use of multilayer panels allows to achieve minimal thermal conductivity from the environment to the equipment;

- the presence of handles on the removable part of the casing allows you to access the protected equipment without additional tools;

- the presence of the position indicator of the locking element allows you to determine the position of the valve without removing the protective box, even when inspecting the object from the air (by helicopter);

- thanks to the hollow shaft of the pointer, the heat flow from the pointer to the drive is reduced. The valve position indicator allows you to determine the position of the valve;

- the use of a rigid frame protects the fireproof box from damage during mechanical impact on the box. The steel frame is painted with fire-retardant enamel, which allows you to save the properties of the material of the frame without deformation and critical decreases in the strength of the metal;

- the outer aluminum coating of the multilayer panels prevents the destruction of their material during mechanical impact on them. In addition, aluminum allows reflecting thermal radiation at the initial stage of a fire, which positively affects the general fire-retardant properties of the casing;

- protective enamel prevents the negative effects of the environment, such as ultraviolet radiation, precipitation, on the materials of multilayer panels.

Thanks to the protective enamel, the device retains its functional properties and aesthetic appearance throughout its entire service life.

The use of the invention improves the reliability and reliability of the equipment in case of emergency, and safety, since even in the event of a fire it is possible to block the flow of combustible substances into the combustion zone. And also increase operational capabilities by simplifying the design, assembly technology and maintenance.

Claims (16)

1. A means of volumetric thermal and fire protection of the actuator of the shut-off and control valves of the pipeline in case of fire, comprising a rigid box made in the form of an open container, the internal volume of which is equipped with a coating of fire-retardant material, and a protected object placed inside the box, characterized in that the protected object is made in the form of shut-off and control valves with a housing and a main shaft connected with a shut-off element, a servo-drive and a control unit, while the tool is equipped with a bottom of the box made of rigid of magnesite plate covered with a multilayer panel, and the said box is made in the form of a rigid volumetric frame with walls of multilayer panels placed indented above its open part, providing the possibility of placing a multilayer panel located on the indicated bottom, while the multilayer panels of the box and the bottom glued from three layers of plates based on magnesite materials, the middle of which is made of foamed magnesite, and these magnesite plates have the following thicknesses in layers: internally layer about 3-20 mm; the middle layer is 10-120 mm and the outer layer is 5-25 mm, while the last, outer layer is lined with an aluminum coating with a thickness of 0.25-3 mm and painted with fire-retardant paint, and under the bottom of the means there is a bearing assembly consisting of a supporting platform fixed to the housing on which a rigid magnesite plate is installed, a central hole is made in both of them and a lower sleeve is placed in it, in which an additional hollow servo drive shaft is connected, connected to the main shaft of the locking element, while the lower sleeve is sealed but it is located in the holes conjugated with each other in the support platform, magnesite plate and in the lower mounting element mounted on the latter, and interconnected with the lower sleeve by means of fixation, while on the lower mounting element the bottom surface of the means is made of rigid magnesite plate, conjugated by the upper plane with the upper mounting element installed above it, inside of which a rigid fire-retardant plate is placed above the specified interface, detachably connected to the underlying the upper mounting element, the bottom of the tool and the lower mounting element, while in these connected parts are made through coaxial holes with the possibility of free placement of the mentioned additional shaft, and in the upper part of the upper mounting element there is a hole in which the upper sleeve of the additional shaft is placed, the space around the lower mounting element between the magnesite plate, the support platform and the bottom of the tool is filled with a soft fire-resistant material based on stone in Atoms with aluminum foil on the outside, and in contact between the bottom panel and the duct panels, a seal is made of soft fire-resistant material based on stone wool glued with heat-resistant adhesive to the multilayer panels of the duct, sheathed with a steel amplifier of its mechanical strength and equipped with handles with the possibility of removal the need for operational maintenance or control of the fittings, labels are placed on the upper surface of the box for the position indicator of the locking element of the reinforcement, additional the servo drive shaft is kinematically connected to the cranked lever of rotation of the indicator of the position of the locking element, and the electric cable of the control unit and the working supply connections of the servo drive are passed through the holes in the bottom of the tool and sealed in it with fireproof mastic. 2. The tool according to claim 1, characterized in that the said supporting platform is made of steel sheet. 3. The tool according to claim 1, characterized in that the said supporting platform is made in the form of a lattice. 4. The tool according to claim 1, characterized in that said servo drive is made using electric traction. 5. The tool according to claim 1, characterized in that said servo drive is made in the form of an actuator of a pneumatic type. 6. The tool according to claim 1, characterized in that the said lower and upper mounting elements have a C-shaped cross section. 7. The tool according to claim 1, characterized in that the said lower and upper mounting elements are in the form of a volumetric lattice with supports for the lower and upper bushings. 8. The tool according to claim 1, characterized in that the said lower and upper mounting elements are in the form of a parallelepiped or cube with cutouts on the walls. 9. The tool according to claim 1, characterized in that the supporting platform and the box are interconnected by safety cables. 10. The tool according to claim 3, characterized in that the air intake pipe of the pneumatic type servo drive is equipped with a flame arrester and a sealant. 11. The tool according to claim 1, characterized in that the bottom of the tool has a frame structure in which a rigid magnesite plate is fixed. 12. The tool according to claim 1, characterized in that the box is made in the form of a parallelepiped. 13. The tool according to claim 1, characterized in that the box is made in the form of a truncated cone with a cylindrical lower part. 14. The tool according to claim 1, characterized in that the box is made of cylindrical shape. 15. The tool according to claim 1, characterized in that the box is made in the form of a hemisphere. 16. The tool according to claim 1, characterized in that the box and the bottom are impregnated on the outside on the surface of the fire exposure with a composition that reflects thermal radiation.

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