RU169322U1 - THERMAL INSULATING CASE TO INCREASE THE RELIABILITY OF SECURITY VALVES - Google Patents

Abstract

The utility model relates to devices containing structural elements of vessels, as well as their filling and releasing devices, and is intended to prevent freezing of safety valves of pipeline valves used in the oil and gas industry. The technical task aimed at solving this utility model is to increase the manufacturability of a thermally insulating casing, increasing the reliability of its operation in conditions of extremely low temperatures and as a result ensuring reliable operation of the fuse valves of pipeline valves. The stated problem is solved in that the thermally insulating casing for increasing the reliability of safety valves contains at least two sections made with the possibility of their mechanical connection, while each of these sections contains a sealed cavity formed by internal and external walls. The inlet and outlet fittings are installed on the outer wall of each section, connecting the sealed cavity with the external environment, and the inner wall is made of a material having a thermal conductivity greater than the thermal conductivity of the material of the outer wall. Said sealed cavity is filled with liquid or gaseous coolant. Heating elements and temperature sensors can be additionally installed on the surface of the inner wall of the sections, electrically connected to a control unit made, for example, based on an industrial controller.

Description

The utility model relates to devices containing structural elements of vessels, as well as their filling and releasing devices, and is intended to provide a thermostatic mode of operation of safety valves of pipeline valves used in the oil and gas and defense industries, as well as construction and public utilities.

The task of thermal insulation in technology, in particular the storage of liquid gases, is solved by using Dewar vessels containing external and internal insulated vessels, between which there is a vacuum. Among the technical solutions related to the mentioned devices, it is possible to distinguish, for example, the thermally insulating casing of the cryogenic device (RU 2102650C1, IPC F17C 3/08, publ. 20.01.1998), having an inner wall and an outer wall with an inner space between the said walls, completely or partially filled insulating material.

The disadvantage of this device is the complexity of its design due to the need to use materials to maintain a deep vacuum between the walls of the vessel, which makes it unsuitable to use such a casing for thermal insulation of pipe fittings and hydrodynamic life support systems.

As the closest technical solution to the claimed utility model, a device for thermal protection of objects (SU 1033835A, IPC F28D 15/00, F17C 3/02, publ. 07.08.83) containing the inner and outer walls that form the cavity in equidistant which is a container with boiling liquid. Moreover, the said tank is additionally equipped with a heater.

The disadvantage of this device is its low manufacturability, associated with the complexity of the design and installation associated with the use of a low-boiling liquid, mainly freon, as a coolant, which requires the storage of its capacity from expensive heat-conducting material, namely bronze.

The technical problem to which the utility model is aimed is to increase the manufacturability of the thermally insulating casing and ensure the stability of its operation at extremely low temperatures, which in turn will increase the reliability of the safety valves of pipeline valves equipped with it.

This problem is solved in that the insulating casing to increase the reliability of the safety valves contains at least two sections made with the possibility of their mechanical connection, while each of the said sections contains a sealed cavity formed by the inner and outer walls. The inlet and outlet fittings are installed on the outer wall of each section, connecting the sealed cavity with the external environment, and the inner wall is made of a material having a thermal conductivity significantly greater than the thermal conductivity of the material of the outer wall. Said sealed cavity is filled with liquid or gaseous coolant. Heating elements and temperature sensors can be additionally installed on the surface of the inner wall of the sections, electrically connected to a control unit made, for example, based on an industrial controller.

A positive technical result provided by the set of design features disclosed above is an increase in the manufacturability of the casing due to the implementation of the walls of the sections from materials of different thermal conductivity, as well as fittings that make it possible to connect an injection system, for example, a pump, that circulates the coolant inside sealed cavities. The heating elements and temperature sensors connected to the control unit are essentially a programmable automatic controller and allow you to implement any required algorithm for controlling the temperature inside the casing.

The utility model is illustrated by drawings, where in FIG. 1, a heat insulating casing is shown in section; in FIG. Figures 2 and 3 show a variant of sealing the ends of the casing and illustrates the method of its installation on the safety valve.

The heat-insulating casing for increasing the reliability of the safety valves contains at least two sections made with the possibility of their mechanical connection (figure 1 shows a variant of the casing consisting of two sections 1 and 2), each of these sections contains a sealed cavity 3 formed by an inner and external walls 4 and 5, made equidistant to each other. The inlet and outlet fittings 6 and 7 are installed on the outer wall of each section, connecting the sealed cavity with the external environment, and the inner wall is made of a material having a thermal conductivity greater than the thermal conductivity of the material of the outer wall. Said sealed cavity is filled with liquid or gaseous heat carrier 8, for which, for example, heated water or steam can be used. Heating elements and temperature sensors can be additionally installed on the surface of the inner wall of the sections, electrically connected to a control unit made, for example, based on an industrial controller. The heating elements are made in the form of conductive spirals fixed to the inner walls of the sections, for example, by gluing, and temperature sensors can be either resistive or thermocouples buried in the section housing for a certain distance.

The device operates as follows. Previously, the casing is fixed on the safety valve and the ends are sealed by means of specialized end frames 9 through the sealing gasket 10 using bolt connections 11. Next, the tees 12 are connected to the fittings 6 and 7, connected to the discharge system with flexible hoses 13, after which the sealed cavities of the casing are filled with coolant. Using the data input module of the control unit, the desired temperature is adjusted to maintain it constant inside the casing and the said unit is switched to automatic operation.

Information sources

1. Pat. 2102650 Russian Federation, IPC ⁶ F17C 3/08. Thermal insulating casing of the cryogenic device / Claudio Boffito [IT], Antonio Schiabel [IT], Alessandro Gallitoniotta [IT], applicant and patentee Saes Getter S.p.A. (IT). - No. 94042981/25. Claim 02/01/1993, publ. 01/20/1998.

2. A.S. 1033835 USSR, IPC ⁶ F28D 15/02, F17C 3/02. Device for thermal protection of objects / Rosenblit R.A. (SU), Rogov V.I. (SU), the applicant Enterprise PO Box B-2203 (SU). - No. 3396373. Claim 02/08/1982, publ. 08/07/1983. - Bull. No. 29. - 3 p.: Ill.

Claims (7)

1. A thermally insulating casing to increase the reliability of safety valves, comprising at least two sections made with the possibility of mechanical connection, each of these sections contains a sealed cavity formed by internal and external walls, characterized in that on the outer wall of each of the sections are installed inlet and outlet fittings connecting the sealed cavity with the external environment, and the inner wall is made of a material having a thermal conductivity significantly greater than the thermal conductivity s outer wall material. 2. Thermal insulating casing to increase the reliability of safety valves according to claim 1, characterized in that the sealed cavity is filled with a liquid coolant. 3. A thermally insulating casing to increase the reliability of safety valves according to claim 1, characterized in that the sealed cavity is filled with gaseous coolant. 4. Thermal insulating casing to increase the reliability of the safety valves according to claim 1, characterized in that heating elements are installed on the surface of the inner wall of the sections. 5. Thermal insulating casing to increase the reliability of safety valves according to claim 4, characterized in that temperature sensors are installed on the surface of the inner wall of the sections. 6. A thermally insulating casing for increasing the reliability of safety valves according to claim 5, characterized in that the heating elements and temperature sensors are electrically connected to the control unit. 7. Thermal insulating casing to increase the reliability of safety valves according to claim 6, characterized in that the control unit is based on an industrial controller.

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