RU145278U1 - CABINET TYPE CABINET - Google Patents

Abstract

1. Capsule-type instrument cabinet for protecting technological equipment on the pipeline, including a dust-tight housing and a cover made with a tight fit to the housing, having an internal cavity for accommodating technological equipment, made in the housing and the lid providing dustproof moisture proof openings for the pipeline to pass through and placed in the inner cavity, the fastening elements of the device body to the pipeline, as well as at least one thermoregulable a heating element connected to an external power source via an electric cable through a cable entry, the housing and the cover being multilayer with a layer of explosion and fireproof non-combustible heat-insulating material and the outer and inner layers of a durable non-combustible antistatic corrosion-resistant explosion-proof material and pivotally interconnected one edge, while access to the internal cavity is limited by locking elements placed on the lid and the housing, characterized in that the cabinet body is made with a double wall, while the inner wall is made of the same material as the outer. 2. The cabinet according to claim 1, characterized in that the outer and inner layers of the housing and the cover are made of fiberglass reinforced with fiberglass, or plastic. A cabinet according to claim 1, characterized in that the layer of heat-insulating material of the housing and the cover is made of structural polyurethane foam, needle-punched fiberglass or mineral wool. The cabinet according to claim 1, characterized in that the housing and the cover are provided with an additional layer of heat

Description

The utility model relates to the field of protection of technological control and measuring and other equipment from environmental influences and the exclusion of its various possible damages, namely, devices for heating and / or preventing freezing of pipe valves and / or technological equipment installed on the pipeline, for example , measuring instruments such as sensors, flow meters, manometers, etc., and can also be used as removable thermal insulation of reusable use in various industries slyah industry to expand the temperature range of the various types of equipment.

A prior art device is known for protecting technological equipment on a pipeline, having an internal cavity for accommodating technological equipment, formed by a housing and a cover, openings for passing the pipe, a heating element configured to thermoregulate, the cover being provided with a heat-insulating layer, and access to the internal cavity is limited locking elements placed on the cover and housing (RU 89200, publ. 11/27/2009).

A disadvantage of the known technical solution is the lack of strength, since in the previously known device, the housing and the cover consist of an outer layer made of a durable non-combustible antistatic corrosion-resistant explosion-proof material and a warming layer made of explosion-proof and fireproof non-combustible heat-insulating material. This design does not provide sufficient strength, because with significant dimensions of the product, the entire load to preserve the geometric shape of the product falls on the outer layer. In the case of its manufacture from plastic or fiberglass reinforced with fiberglass, deformation of the lid is inevitable when opening the product. If the insulation layer is made of inelastic materials (for example, polyurethane foam), it will break and crumble. Also, when servicing devices placed inside the product, there is a risk of damage to the fragile thermal insulation layer by tools.

The technical result is the creation of a durable explosion-proof fireproof device, ensuring effective heat saving with low power consumption, as well as providing climatic and additional physical protection of the pipeline processing equipment, increasing the service life of the device and equipment placed in it.

The technical result is achieved through a capsule-type instrument cabinet to protect the process equipment on the pipeline. The cabinet includes a dust-proof, moisture-proof housing and a cover made with a tight fit to the housing, having an internal cavity for accommodating processing equipment, made in the housing and the lid to provide dust-, moisture-proof openings for the pipeline to pass through, and fastening elements of the device’s housing located in the inner cavity to the pipeline, as well as at least one thermoregulable heating element connected to an external power source by means of an electric cable through the cable entry, and the housing and the cover are multilayer with a layer of explosion and fireproof non-combustible heat-insulating material, for example, polyurethane foam or mineral fiber and the outer and inner layers of a durable non-combustible antistatic corrosion-resistant explosion-proof material, for example fiberglass reinforced with fiberglass or plastic (polystyrene or mixtures of ABS and polycarbonate) and are interconnected hinged along one edge, while access to the internal cavity is limited n locking elements located on the lid and housing. The cabinet body is made with a double wall, while the inner wall is made of the same material as the outer one, for example fiberglass reinforced with fiberglass or plastic (polypropylene or a mixture of ABS with polycarbonate).

The outer and inner layers of the body and cover can be made of plastic (polypropylene or a mixture of ABS and polycarbonate), fiberglass reinforced fiberglass. The outer and inner layers of the body and lid are glued together, which allows you to get a very durable and resistant to deformation design. The presence of an inner durable layer allows you to attach to it placed inside the cabinet instrumentation and various structural elements.

The layer of heat-insulating material of the body and the cover can be made of structural polyurethane foam, needle-punched fiberglass or mineral wool.

The inner layer of the housing and the cover can also be equipped with an additional layer of thermal insulation made of foamed rubber with aluminum coating. This layer can be applied to the inside of the cabinet and lid and facing with a shiny aluminum coating inside the cabinet. The shiny surface will reflect heat rays and provide additional heat savings.

The fastening elements of the housing of the device to the pipeline can be made in the form of detachable mounting clamps located on the walls of the housing.

Condensate drain holes may be provided in the housing, provided with plugs placed in the internal cavity of the device.

The device can be equipped with at least one earth outlet, as well as additional cable entries for connecting to the external power source of the pipeline processing equipment, and the cable entries can be made explosion-proof.

To ensure connection to an external power source, the device can be equipped with a sealed junction box mounted on a mounting plate placed on the outside of the case or inside it.

The cover and / or the housing in place of tight fit to each other can be equipped with a seal made of double-strand silicone or neoprene.

The housing and the cover can be made semi-cylindrical with flanging around the perimeter of their abutment to each other.

The housing and the cover can be interconnected via a loop connection, for example, in the form of a piano loop.

The device may contain at least one, and preferably two hydraulic stops, each of which is attached with one end to the housing and the other to the lid.

The device may be equipped with a junction box for connecting the heating element to an external power source.

Openings for the passage of the pipeline can be equipped with seals to seal the places of entry and exit of the pipeline.

The device may be equipped with at least one electronic temperature controller located in the internal cavity of the device and connected to the heating element.

The heating element can be made in the form of separate insulated plates or elements representing a heating fabric made of electrically conductive carbon-containing fibers, creating a continuous heating layer when voltage is applied to them and equipped with a temperature sensor and a thermostat to provide the required temperature range in the internal cavity of the device.

In another embodiment, the heating element can be made convection explosion-proof in the form of a filled compound and enclosed between two mechanically tightened radiators of the heating element and equipped with an electronic temperature regulator.

In addition, the heating element can be made in the form of a self-regulating cable, which is two conductive conductors isolated from each other, placed in a semiconductor carbon matrix enclosed in a plastic sheath, a copper braid and a polyolefin or fluoroplastic sheath placed on the mounting elements or frame in the form lattice.

The technical result provided by the above set of features is to create a durable explosion-proof and fireproof device due to the implementation of the device dustproof, equipped with a housing and a cover, made multilayer with a layer of explosion and fireproof non-combustible heat-insulating material and the outer and inner layers of durable non-combustible antistatic corrosion explosion-proof material, providing explosion protection and effective heat saving with little m energy consumption of the heating element, made with the possibility of thermoregulation, as well as providing climate protection for the technological equipment of the pipeline due to dust and moisture protection of the openings for the passage of the pipeline and the snug fit of the cover to the body; to provide additional physical protection for the equipment installed in the device due to the implementation of the locking elements on the lid and the housing, as well as the placement of the fastening elements of the device to the pipeline in the internal cavity with a high degree of vandal protection, which increases the service life of the device and equipment placed in it, the maintenance of which is facilitated due to the implementation of the fastening elements of the housing of the device to the pipeline, placed in the internal cavity of the device, and performing a hinge connections along one edge of the case and the device cover

The invention is illustrated by drawings, which depict:

figure 1 is a General view of the cabinet of the instrument capsule type of waxonometry;

figure 2 - cabinet instrument capsule type, top view;

figure 3 - wall of the capsule in section.

The capsule-type instrument cabinet for protecting technological equipment on the pipeline 1 includes an internal cavity for accommodating the technological equipment 2, a dust and moisture-proof housing 3 and a cover 4. The cover 4 is made with the possibility of tight fit to the housing 3. In the housing 3 and the cover 4, openings 5 are made for pipelines with dust and moisture protection, for which the openings 5 for piping 1 are equipped with seals to seal the places of entry and exit of the pipeline. In the internal cavity of the device, fastening elements 6 of the cabinet body 3 to the pipeline are placed. The fastening elements 6 of the enclosure 3 of the cabinet to the pipeline 1 can be made in the form of detachable mounting clamps located on the walls of the enclosure, which ensures ease of installation and dismantling at the installation site, as well as additional physical protection to prevent unauthorized dismantling of the device due to their installation in the internal device cavities. Also, in the inner cavity of the cabinet, preferably in its housing 3, is located at least one thermoregulable heating element 7. The heating element 7 is connected to an external power source via an electric cable 8 through a cable entry 9. The housing 3 and the cover 4 are made multilayer with a layer of explosion and fireproof non-combustible heat-insulating material 20, for example, structural polyurethane foam or mineral fiber, and an outer layer 18 and an inner layer 19 of durable non-corrosive which antistatic corrosion-explosive material, e.g., fiberglass, reinforced fiberglass or plastic (polypropylene or a mixture of ABS and polycarbonate). The housing 3 and the cover 4 are interconnected pivotally on one edge. In addition, the inner layer of the housing 3 and the cover 4 can be provided with an additional layer of thermal insulation made of foamed rubber with aluminum coating. Access to the internal cavity is limited by locking elements 10 located on the lid 4 and the housing 3.

In the bottom of the housing 3 holes are made for drainage of condensate (not shown in the drawings), equipped with plugs placed in the internal cavity of the device.

The device is equipped with at least one earth outlet 11, as well as additional cable entries 12 for connecting to an external power source of technological equipment 2 of the pipeline 1. Cable entries 9, 12 are made explosion-proof. To ensure that the heating element 7 and the process equipment 2 are connected to an external power supply, the device is equipped with a sealed junction box 13, which is mounted on a mounting plate 14 located on the outside of the housing 3. To ensure dust and moisture protection of the connection of the cover 4 and the housing 3, they (or one of them) is equipped with a two-handed seal 15 in place of their tight fit to each other. Double-handed seal 15 may be made of silicone or neoprene. To enhance protection against ingress of dust, moisture and precipitation, the housing 3 and the cover 4 can be flanged (shown in Fig. 3) along the perimeter of their abutting to each other, and to achieve optimal conditions for condensate drainage, the housing 3 and the cover 4 are made semi-cylindrical forms. For ease of maintenance, the housing 3 and the cover 4 can be pivotally interconnected along one edge, preferably by means of a loop connection, for example, in the form of a piano loop 16. In this case, the device may contain at least one, and preferably two hydraulic stops 17. Each hydraulic emphasis 17 is fixed with one end to the housing 3, and the other to the cover 4.

The heating element 7 in different types of execution of the device can be selected from the following.

The heating element 7 can be made in the form of separate insulated plates or elements representing a heating fabric of electrically conductive carbon-containing fibers, creating a continuous heating layer when an electrical voltage is applied to them and equipped with a temperature sensor and an electronic temperature controller to provide the required temperature range in the internal cavity of the device, which is determined by the corresponding temperature setting (for example, at + 50C), which is set in the factory x.

In another embodiment, the heating element 7 can be made of convection explosion-proof in the form of a cast compound and enclosed between two mechanically tightened radiators of the heating element and equipped with an electronic temperature controller. The principle of operation of the heating element 7 is to generate heat during the passage of electric current through the heating element and maintain it at a predetermined temperature by means of an electronic temperature controller. Explosion protection is ensured by sealing the insulated active part of the heater and fuses embedded between the fins of the radiator, and by mechanical protection with metal profile plates.

In addition, the heating element 7 can be made in the form of a self-regulating cable, which is two conductive conductors (parallel busbars) isolated from each other, placed in a semiconductor carbon matrix enclosed in a plastic sheath, a copper braid and a polyolefin or fluoroplastic sheath placed on mounting elements or frame in the form of a lattice. Parallel busbars provide voltage along the entire cable length. The semiconductor carbon matrix is a continuous heating element, thus allowing you to cut the cable anywhere, eliminating the appearance of dead and cold zones. A cable acquires its self-regulating properties due to the properties of a semiconductor carbon matrix. As the temperature of the material of the semiconductor carbon matrix increases, the number of local conductive bonds in it decreases, automatically reducing heat generation. With decreasing temperature, the number of local conductive bonds increases, leading to an increase in heat release. This happens at every point along the length of the cable, so the output power depends on the environmental conditions along the length of the pipeline. The ability of self-regulation makes it possible to overlap the cable, while this does not form hot spots and zonal local overheating. Since the cable independently controls the heat output, this limits the maximum temperature inside the device, and at the same time provides the necessary power to maintain the temperature in it.

The heating element 7 is placed in the inner part of the device. An electric power cable 8 from the heating element 7 is led out of the device body 3 via an explosion-proof cable entry 9. Then, it is connected externally via an explosion-proof junction box 13 to an external power source.

The device operates as follows. The capsule type instrument cabinet is placed on the pipeline to protect its technological equipment. When installing the housing 3 of the device using the fastening elements 6 is fixed to the pipeline 1. Technological equipment 2 is placed in the inner cavity of the dust-moisture-proof housing 3 and cover 4. The cover 4 is tightly attached to the housing 3, and the openings 5 for the passage of the pipeline 1 provide dust moisture resistance. The thermoregulation element 7 is connected to an external power source by means of an electric cable 8 through a cable entry 9. An electric current is supplied, resulting in an increase in temperature in the internal cavity of the device due to the operation of the heating element (principle of operation of heating elements that can be used in the claimed technical solution, described above). At the same time, effective heat saving is ensured due to the case and cover being multilayer, with a layer of explosion and fireproof non-combustible heat-insulating material and outer and inner layers of durable non-combustible antistatic corrosion-resistant explosion-proof material. The maintenance of technological equipment 2 installed on the pipeline 1 is facilitated by connecting the cover 4 and the housing 3 with a hinge along one edge, while opening the cover the housing remains fixed on the pipeline 1. Access to the internal cavity is limited by the locking elements 10 located on cover 4 and housing 3.

Thus, the claimed utility model allows you to create a solid explosion-proof and fireproof device that provides effective heat saving with low energy consumption, as well as a high degree of vandal resistance, climate and additional physical protection of the pipeline’s process equipment, increasing the service life of the device and equipment placed in it, when using it outdoors (ambient temperature range from minus 70 to plus 60 ° C), when exposed to direct sunlight light, precipitation (rain, snow), condensation, icing, under wind loads, including during the cold season, as well as the harmful effects of dust.

Claims (18)

1. Capsule-type instrument cabinet for protecting technological equipment on the pipeline, including a dust-tight housing and a cover made with a tight fit to the housing, having an internal cavity for accommodating technological equipment, made in the housing and the lid providing dustproof moisture proof openings for the pipeline to pass through and placed in the inner cavity, the fastening elements of the device body to the pipeline, as well as at least one thermoregulable a heating element connected to an external power source via an electric cable through a cable entry, the housing and the cover being multilayer with a layer of explosion and fireproof non-combustible heat-insulating material and the outer and inner layers of a durable non-combustible antistatic corrosion-resistant explosion-proof material and pivotally interconnected one edge, while access to the internal cavity is limited by locking elements placed on the lid and the housing, characterized in that the cabinet body is made with a double wall, while the inner wall is made of the same material as the outer one. 2. The cabinet according to claim 1, characterized in that the outer and inner layers of the housing and the cover are made of fiberglass reinforced with fiberglass, or plastic. 3. The cabinet according to claim 1, characterized in that the layer of heat-insulating material of the housing and the cover is made of structural polyurethane foam, needle-punched fiberglass or mineral wool. 4. The cabinet according to claim 1, characterized in that the housing and the cover are provided with an additional layer of thermal insulation made of foamed rubber with an aluminum coating. 5. The cabinet according to claim 1, characterized in that the fastening elements of the housing of the device to the pipeline are made in the form of detachable mounting clamps located on the walls of the housing. 6. The cabinet according to claim 1, characterized in that the housing has openings for draining the condensate, equipped with plugs located in the internal cavity of the device. 7. The cabinet according to claim 1, characterized in that it is equipped with at least one earth outlet, as well as additional cable entries for connecting to the external power source of the pipeline processing equipment, the cable entries being made explosion-proof. 8. The cabinet according to claim 1, characterized in that to ensure connection to an external power source, it is equipped with a sealed junction box mounted on a mounting plate placed on the outside of the housing. 9. The cabinet according to claim 1, characterized in that the lid and / or housing in place of a snug fit to each other are equipped with a seal made of double-strand silicone or neoprene. 10. The cabinet according to claim 1, characterized in that the housing and the cover are made semi-cylindrical with flanging around the perimeter of their abutment to each other. 11. The cabinet according to claim 1, characterized in that the housing and the cover are interconnected by means of a loop connection, for example, in the form of a piano loop. 12. The cabinet according to claim 1, characterized in that it contains at least one, and preferably two hydraulic stops, each of which is attached at one end to the housing and the other to the lid. 13. The cabinet according to claim 1, characterized in that it is equipped with a junction box for connecting the heating element to an external power source. 14. The cabinet according to claim 1, characterized in that the openings for the passage of the pipeline are equipped with seals for sealing the places of entry and exit of the pipeline. 15. The cabinet according to claim 1, characterized in that it is equipped with at least one electronic temperature controller located in the internal cavity of the device and connected to the heating element. 16. The cabinet according to claim 1, characterized in that the heating element is made in the form of separate insulated plates or elements representing a heating fabric of electrically conductive carbon-containing fibers, creating a continuous heating layer when an electrical voltage is applied to them and equipped with a temperature sensor and a thermostat to ensure the required temperature range in the internal cavity of the device. 17. The cabinet according to claim 1, characterized in that the heating element is made of convection explosion-proof in the form of a cast compound and enclosed between two mechanically tightened radiators of the heating element and is equipped with an electronic temperature controller. 18. The cabinet according to claim 1, characterized in that the heating element is made in the form of a self-regulating cable, which is two conductive conductors isolated from each other, placed in a semiconductor carbon matrix enclosed in a plastic sheath, a copper braid and a polyolefin or fluoroplastic sheath, placed on mounting elements or lattice frame.