RU227419U1 - HEAT PROTECTIVE CASE - Google Patents

Abstract

The utility model relates to the field of protecting technological instrumentation and other equipment from the influence of aggressive environmental influences and eliminating various possible damages, namely a thermal protective cover. The technical result is achieved by a thermal protective cover containing a housing with a heat-insulating layer and heating elements placed inside it, designed to accommodate insulated equipment and formed by parts equipped with quick-release fasteners, while the housing is made with a sealed lead-in for the power cable containing positioning disks located on the inside and the outer side of the housing wall and tightened with fasteners. The technical result achieved by the utility model is effective thermal insulation of equipment under various environmental conditions.

Description

The utility model relates to the field of protecting technological instrumentation and other equipment from the influence of aggressive environmental influences and eliminating various possible damages, namely a thermal protective cover.

A protective case is known from the prior art (Russian utility model patent No. 138635, IPC G01D 11/24), made antistatic and containing heating devices and a housing formed by walls equipped with quick-release fasteners with shells placed one inside the other in such a way that each of the walls includes at least three layers, wherein the outer layer is made of chemical wear-resistant with oil- and water-repellent properties, and the inner layer is made of heat-resistant and heat-reflecting material, while between the inner and outer layers a vibration-resistant insulating layer made of either multi-layer insulation, equipped with a double-sided adhesive connection of layers, and the layers are connected to each other with adhesive tape, or homogeneous, and the connections of the walls and quick-release fasteners are made using heat-resistant means from non-flammable and/or non-combustible materials, characterized in that the cover contains cooling devices with thermostats.

The disadvantages of the utility model are: the lack of the possibility of hermetically and reliably fixing the power cable, the lack of the possibility of fixing the terminal junction box on the wall of the protective cover, which complicates the process of installation and maintenance of the equipment, as well as the lack of shut-off valves at the cut points of the protective cover, which reduces the dust-moisture-proof and heat-insulating properties protective cover.

The problem that the utility model is aimed at solving is to create a reliable thermal protective cover to ensure thermal insulation of equipment under various environmental conditions.

The technical result achieved by the utility model is effective thermal insulation of equipment under various environmental conditions.

The technical result is achieved by a thermal protective cover containing a housing with a heat-insulating layer and heating elements placed inside it, designed to accommodate insulated equipment and formed by parts equipped with quick-release fasteners, while the housing is made with a sealed lead-in for the power cable containing positioning disks located on the inside and the outer side of the housing wall and tightened with fasteners.

The utility model is further illustrated by the following figures:

Fig. 1. General view of the thermal cover.

Fig. 2. General view of the sealed lead-in for the thermal cover.

The thermal cover is designed to protect and heat instrumentation and automation (instrumentation and automation) and other equipment operated in open spaces and unheated rooms, and is a protective module with optional elements placed inside and around it.

The thermal cover is made of antistatic materials and contains a housing 1 with a sealed lead-in 2, designed to accommodate equipment. The walls of the housing are formed of a multilayer material, a heat-insulating layer and protective layers on both sides of it, the inner layer is made of foil fiberglass with a special coating that has chemical wear resistance with oil and water-repellent properties, the middle insulation layer is made of foam rubber with a thickness of 10 to 100 mm, and the outer layer is made of fiberglass with a polyurethane coating, which has chemical wear resistance with oil and water repellent properties.

The outer and inner layers of the thermal cover are glued to the foam rubber for reliable fixation of the fabric and, accordingly, the equipment placed on the fabric (for example, a terminal box, loops for a self-regulating heating cable, etc.)

In a particular case, instead of foam rubber, MBOR (rolled basalt fire-retardant material), which is basalt ultra-thin fibers fastened together by natural friction forces (woven into each other), can be used as insulation instead of foam rubber. It is also stitched, which improves the physical and mechanical properties and allows the thermal cover not to crumble and maintain its shape throughout its entire service life.

In a particular case, instead of foamed rubber, basalt canvas can be used as insulation, which is ultra-thin basalt fibers fastened together by natural friction forces (woven into each other).

The insulation thickness ranges from 20 mm to 100 mm or more. The insulation thickness is selected by calculating heat loss and corresponds to calculations in accordance with current GOST and SNiP standards.

The wall of the thermal cover (fabric-insulation-fabric) is pierced with “buttons” made of stainless steel. Buttons are 2 washers on both sides of the insulation, tightened either with wire or other stainless steel fasteners. And it is pulled together to ensure the formation of the geometry of the thermal cover.

The housing is made of individual elements connected by seams and equipped with fasteners for fixing around the equipment being insulated.

The body 1 of the thermal cover is designed to be wrapped around and/or placed around the insulated equipment directly at the site of operation.

Inside housing 1 there are heating and cooling devices with thermostats.

In a particular case, the design of the thermal cover provides an inspection window 3 equipped with a heat-insulating layer, providing access to the control panel of the insulated equipment for readings and/or maintenance.

In a particular case, the viewing window can be made through-insulated.

In a particular case, the viewing window can be made insulated and blind (a transparent window is installed behind the folding insulated one).

In a particular case, the viewing window can be made without insulation.

In a particular case, the thermal cover may contain mounting channels for the passage of equipment piping elements, for example, pipes, pipeline elements and/or fittings. These channels for passing pipes, pipeline elements and/or fittings can additionally be equipped with external protective non-insulated sleeves 4 made of the same material as the outer layer of the protective cover. These non-insulated hoses 4 are made in the form of cylinder-shaped cups sewn to the body, equipped with a cord made of heat-resistant and fire-resistant material (for example, basalt allows it to be used in contact with surfaces heated to 700°C) and fixed around the pipe with quick-release fasteners, for example Velcro type .

The tension sleeves can be located both on the valves and on the body of the thermal cover, which increases dust and moisture protection and improves the thermal insulation properties of the thermal cover. They also provide a more reliable fixation to the thermal cover.

Inside the thermally insulated body of the thermal cover there is a heating element connected to a power cable 5 passing through a sealed lead-in 2 located in the through hole of the body and surrounded by a sleeve 6 on the outside of the thermal cover to prevent heat loss. The sealed lead-in 2 prevents the cable from coming off and the fabric from tearing at the entry point, as well as the inadvertent removal of the power cable 5, which helps maintain the functionality of the thermal cover and, as a result, maintain the operating temperature of the equipment. The design of the sealed lead-in 2 also prevents moisture from entering the thermal cover.

The outer sleeve 6 is made in the shape of a glass, the outer open end of which is equipped with a cord 7 made of heat-resistant and fire-resistant material, to allow the sleeve to be tightened along the diameter of the power cable, and the other end of the sleeve 6 is sewn by means of edges to the body and a disk is placed at the place where the glass is attached to the wall of the thermal cover positional 8 of the sealed lead-in 2, containing at least three mounting holes. There is a cut along the entire height of the glass with a quick-release Velcro fastening for tight fixation on the cable, preventing heat loss.

The power cable is connected to the terminal box 9, which provides a sealed connection and switching of wires and cables for supplying electrical power to the heating elements of the thermal cover.

The explosion-proof terminal box 9 is secured to the thermal cover by means of a technical pocket 10, which ensures safe and reliable operation, ease of installation of the structure, storage and operation of the terminal box itself, as well as reducing the dimensions of the product.

The technical pocket is made of the same material as the thermal cover itself and is tightened around the terminal box 8 using sewn elements designed to overlap the terminal box 8 and be fixed using Velcro quick-release fastening elements. This prevents accidental disconnection of the terminal box and power cable during operation.

The body 1 of the thermal cover is equipped with an external grounding element 9.

The thermal cover is equipped with an installation cut for installation on stationary equipment at the site of operation.

The thermal cover is equipped with valves that cover the mounting cuts of the thermal cover to ensure dust and moisture protection and improve the thermal insulation properties of the thermal cover.

The installation section is covered with valves with Velcro, which provide the necessary dust and moisture protection and minimize heat loss. The valves around the perimeter are attached with Velcro.

In a particular case, the thermal cover can be made like a book: the mounting section includes two parts connected by a common base, made with the possibility of opening and grasping the insulated equipment, followed by fixing the position with quick-release fasteners, for example, using Velcro tapes sewn across the entire contact area of these parts.

In a particular case, the thermal cover can be made in the shape of a cylinder and, when installed on equipment, can also be fixed around the entire equipment using Velcro fasteners.

The sealed lead-in 2 consists of a cable entry for an unarmored cable with a metal hose in the form of a tube and a position disk installed in series on it, installed at the point where the cup is attached to the wall of the thermal cover, and a counter position disk installed in the wall of the thermal cover from the inside. The position disks contain at least three mounting holes, in each of which fasteners are installed, for example, screws, secured to the walls of the thermal case with washers and nuts on both sides of the thermal case, tightening and holding the position disks together. To seal the gaps formed between the movable cable and the fixed elements, the pressure gland contains a gland that tightens the elements and is installed on the inside of the thermal cover.

In particular cases, other fasteners, such as studs, can be used instead of screws.

In a particular case, the sealed lead-in 2 can be additionally protected by a cuff on the inside.

The protective case according to claim 1, characterized in that it is equipped with marking plates made of stainless steel with laser engraving and with fasteners made of stainless steel (rivets) to identify the installation locations of the equipment.

Possibility to fix the terminal junction box on the wall of the thermal cover. This ensures ease of installation and maintenance of equipment.

Description of the device operation

The thermal cover is installed on the necessary equipment. To do this, the thermal cover is opened, encircling the insulated equipment, and the heating elements inside the thermal cover are connected to a power cable connected to the terminal box, while the cable is laid through a sealed lead-in. From the outside, the pressure inlet is reliably protected by a sleeve secured with a basalt cord.

After installing and connecting all the elements, the thermal protective cover is closed using Velcro fasteners, which prevent the ingress of moisture and oil and heat loss.

The advantages of the claimed utility model are the increased reliability of the thermal cover due to the use of a sealed lead-in, which prevents the cable from coming off and tearing the fabric at the entry point, as well as involuntary removal of the power cable, which helps maintain the functionality of the thermal cover and, as a result, maintain the operating temperature of the equipment.

Claims (6)

1. A thermal protective cover containing a housing with a heat-insulating layer and heating elements placed inside it, designed to accommodate insulated equipment and formed by parts equipped with quick-release fasteners, characterized in that the housing is made with a sealed lead-in for the power cable containing positioning disks located with the inner and outer sides of the housing wall and tightened with fasteners. 2. Thermal protective cover according to claim 1, characterized in that the pressure gland includes a cable gland fixed in the wall of the thermal cover using positioning disks located on the inner and outer sides of the wall of the thermal cover and equipped with mounting holes with fasteners and tightened with an gland. 3. Thermal protective cover according to claim 1, characterized in that the walls of the housing are formed by a multilayer material, including a heat-insulating layer and protective layers on both sides of it. 4. Thermal protective cover according to claim 1 or 3, characterized in that on the wall of the housing there is a folding element equipped with a heat-insulating layer, configured to form an inspection window. 5. Thermal protective cover according to claim 1, characterized in that the housing is made with a sleeve surrounding the sealed lead on the outside of the housing. 6. Thermal protective cover according to claim 1, characterized in that it contains a pocket formed by sewn elements with quick-release fasteners for placing a terminal box connected to the power cable.