RU164421U1 - SUPPORT ELEMENT - Google Patents

Abstract

1. A support element made of metal, comprising two walls oriented mainly vertically and interconnected by walls oriented mainly horizontally, characterized in that from the end of the support element there are additional extensions of these two walls oriented mainly vertically. 2. The supporting element according to claim 1, characterized in that said extensions from the end of the supporting element are additionally provided with fastening elements, wherein the fastening elements are located at end portions of said extensions. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of protrusions. 4. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of holes or grooves. 5. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of bends at the ends of the indicated extensions. The supporting element according to claim 5, characterized in that holes or grooves are additionally made in said bends. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of additionally welded heels. The supporting element according to claim 7, characterized in that holes or grooves are additionally made in said heels. The supporting element according to claim 1, characterized in that said extensions are made from each end of the supporting element. The support element according to claim 9, characterized in that said extensions are further provided with fastening elements at each end of the supporting element, wherein the fastening elements are located at end portions of said extensions. The supporting element according to claim 10, characterized in that the fastening elements

Description

The proposed utility model relates to electrical engineering, namely, to the laying of cable lines for electric power transmission, mainly intended for placement of high voltage cables in polyethylene insulation with high mechanical and electrical characteristics, the so-called cross-linked polyethylene.

A cable structure in the present description for brevity refers to one of the set of supporting structures of a cable structure or industrial premises intended for placement of cables on them, for example, cable rack structures or cable gallery structures, or cable tunnel, or industrial premises. The cable structure includes basic building structures and building foundations, for example, columns, beams, walls (including the actual walls, ceilings and floors), and also includes cable structures (including, for example, wall structures, ceiling structures, floor structures) . The cable structure may also include other equipment that is not considered in the present description. The cable structure includes at least one base, for example, a rack fixed with brackets on a building structure (in the present description, for the sake of brevity, vertical profiles of suspensions, calipers, cable shelves are assigned to the racks), and supporting elements located horizontally and fixed on the bases cable structures. Cable trays are fixed, as a rule, on horizontal supporting elements of cable structures or, less commonly, directly on building structures. A support element in the present description and in the formula is called such an element oriented horizontally and transversely to the direction of the cable, such as a console or shelf of a cable overpass (i.e., a support element fixed at one end to a rack) or, for example, a wall bracket (i.e. e. a supporting element fixed at one end to the wall), or, for example, the crossbar of the cable ladder, i.e. a support element fixed by two ends to the longitudinal elements (also called sides, spars) of the cable tray, or, for example, a horizontal support element of a floor support or ceiling suspension. Cables can be attached to the supporting elements of the cable structure or to the supporting elements of the cable tray using well-known means — cable ties, cable ties, cable ties, clamps, etc. Also, cable tray can be attached to the supporting elements of the cable structure.

It is known that short circuits in the cable line of high voltage and high power cause the sudden occurrence of high forces of interaction between the cables and the mechanical transmission of the effects of these forces on cable fasteners, for example, clamps, and then on supporting structures. The propagation of such forces can cause destruction in structures in places of concentration of mechanical stresses, for example, in the nodes of fastening parts to each other. To prevent or mitigate the destructive effect of such mechanical loads, it was proposed to include elastic liners and springs in the clamps (see, for example, patent document CN 204333865), however, this leads to a complication of their design, and their efficiency is low, because elastic elements only slightly slow down the propagation of a wave of mechanical deformation from cables along cable support structures, but they are not able to quickly absorb a large amount of mechanical energy irreversibly. In practice, the existence of the probability of short circuits in cable lines of high transmitted power leads to the use of support structures with excessive strength and to an increase in the consumption of materials, to complicate the construction of cable structures, the manufacture of cable structures, their racks and shelves, and the manufacture of cable trays, their spars and crossbars. From other areas of technology (for example, from areas that include earthquake-resistant structures, automotive load-bearing structures, road fences), it is known that in order to prevent structural damage due to the propagation of high mechanical stresses, metal structures are supplied with areas characterized by a reduced threshold of plastic deformation. Plastic deformation provides an irreversible absorption of a significant portion of the mechanical energy of the propagating mechanical stress and reduces the likelihood of destruction of the remaining sections of the structure. However, the use of structural sections made with a deliberately reduced threshold for plastic deformation is unknown in the field of cable support structures and cable structures. Direct, formal transfer of the experience of other areas of technology to the field of cable support structures and cable structures is not applicable, since it can lead to negative consequences.

From other areas of technology there are known distant analogues of the proposed support element, including sections in which it is possible to assume a change in the level of torsion resistance as an accompanying result of a technical solution, however, in the sources of information describing these analogues, there is no indication of such a technical result as partial absorption of sudden energy mechanical stresses in the process of irreversible plastic deformation and, as a consequence, prevention of destruction of the support element and other parts alley. For example, a metal crossbeam (horizontal) or a spacer (tilted) for a rack is known, disclosed in patent document DE 3307645 (IPC: AV 55/00; publ. 1984.09.06). The horizontal crossbar includes two vertical walls, interconnected by one horizontal wall. A slot is made at each end of the crossbar in the horizontal wall, the vertical walls are separated in different directions and welded to the walls of the rack rack. DE 3307645 claims that the weakening of the stiffness of the crossbar due to the presence of a slot is fully compensated by the increase in stiffness due to the expansion of the crossbar in the areas of its ends. For example, a cross-arm for power transmission towers is known, disclosed in patent document SU 652292 (IPC: E04C 3/32; publ. 1979.03.15). The traverse body is made in the form of a channel with a longitudinal cut in the channel wall and the channel shelves divorced along the length of the cut. It is expected to increase the service life and reliability during operation. Support elements according to DE 3307645 or SU 652292 cannot provide a reduction in resistance to horizontal bending, because their horizontal wall in the area of the slot (cut) is stored in the form of two parts located on both sides of the slot (cut) and connected to the vertical walls.

Known support element disclosed in patent document EP 0798505 (IPC: H02G 3/26; publ. 1997.10.01). This support element includes six vertical walls and seven horizontal walls (in the working position of the support element). Two of its vertical walls are interconnected by one horizontal wall. Under operating conditions, in the event of a short circuit accompanied by the occurrence of high dynamic loads between cables fixed to such a support element, there is a high probability of damage or destruction of cable clamps or clamps, clamp fastenings to the support element, fasteners of the support element to the cable structure rack or to the longitudinal load-bearing cable tray elements. This is due to the excessive rigidity of the support element, the absence of areas near its ends that are characterized (in comparison with the middle section of the support element) by a reduced threshold of plastic deformation.

From the field of laying cable lines, a support element is known - a cable console disclosed in patent document EP 2180567 (IPC: H02G 3/30; publ. 2010.04.28). This supporting element includes two vertical walls not parallel to each other, interconnected by one horizontal wall. The support element also includes two wedge-shaped in plan mainly horizontal walls, flanged from the lower edges of the vertical walls. The supporting element is additionally equipped with a heel with mounting holes welded from one end of the supporting element to the ends of its walls. This supporting element is characterized by the disadvantages of the above analogue of EP 0798505. This is due to the excessive rigidity of the supporting element in its portion adjacent to the heel.

Known support element is a cable console with a U-shaped profile, disclosed in patent document SU 1297151 (IPC: H02G 3/30; H02G 3/02; publ. 1987.03.15). This supporting element includes two vertical walls, interconnected by one horizontal wall. From one end (from the landing end, which is intended for fastening to the rack) of the supporting element, the horizontal wall ends with a T-shaped element. The length of the vertical walls and the horizontal wall is the same. A rigid fastening of a support element on the basis of a cable structure — a rack is disclosed. The vertical walls and the horizontal wall in the operating conditions of the support element are located in the groove of the rack without forming a gap between the rack and the horizontal wall. The disadvantage of this supporting element is excessive rigidity, in the absence on the landing end of the supporting element of the section, characterized by a reduced threshold of plastic deformation relative to torsion and horizontal bending. This disadvantage is due to the fact that the vertical walls have a length equal to the length of the horizontal wall. Therefore, it is not possible to fix this support element with the formation of a gap between the rack (the base of the cable structure) and the horizontal wall of the support element. Under operating conditions, in the event of a short circuit accompanied by the occurrence of high dynamic loads between the cables fixed on such a cable console, there is a high probability of damage or destruction of cable clamps or clamps, clamp fastenings to such a cable console, fasteners of such a cable console to the rack, rack mount nodes to building structures.

Known support element is a cable console disclosed in patent document SU 1534592 (IPC: H02G 3/30; H02G 3/02; publ. 1990.01.07). This supporting element includes two vertical walls, interconnected by one horizontal wall. At one end of the support element, the horizontal wall ends with a T-shaped element. The length of the vertical walls does not exceed the length of the horizontal wall. The fastening of the support element on the basis of the cable structure - the rack is disclosed. The vertical walls and the horizontal wall in the operating conditions of the support element are mounted on the rack without forming a gap between the rack and the horizontal wall. The disadvantage of this support element is identical to the disadvantage of the above counterpart in the document SU 1297151.

Known support element is the transverse profile of the cable tray disclosed in the directory "Electrical equipment, busbars, wiring products, tools and mechanisms. 6th ed.", M., 2009, JSC Company "Electric installation", on p. 369-370, fig. 3.3.16-3.3.17. The transverse profile on the middle part of its length includes two vertical walls and at least one horizontal wall connecting these vertical walls. The ends of the transverse profiles are flattened so that in the end regions the transverse profiles contain only horizontally oriented parts of the walls. It is not possible to fix this transverse profile with the formation of a gap between the bearing longitudinal profiles of the cable tray and the horizontal wall of the transverse profile. As a result, the resistance of the transverse profile to the vertical static load (cable weight) is reduced. Resistance to horizontal dynamic load, when it increases to a certain value, is preserved and causes only elastic deformation, which prevents the absorption of dynamic load energy.

A support element is known - a connecting strip of a cable-carrying ladder-type tray disclosed in FIG. 2 attached to the patent document RU 49383 (IPC: H02G 3/04; publ. 2005.11.10). The connecting strip is made in the form of a hollow cylinder of oval cross-section. Conventionally, it can be considered that said connecting strip contains two walls oriented predominantly vertically (i.e., two convex lateral regions of an oval hollow cylinder with horizontal orientation of the cylinder axis) and interconnected by two walls oriented mainly horizontally (i.e. connected by the upper and lower convex regions of the oval hollow cylinder, with the horizontal axis of the cylinder). The disadvantage of this support element is excessive rigidity, in the absence at its ends of sections characterized by a reduced threshold of plastic deformation relative to torsion and horizontal bending. This disadvantage is due to the fact that the conditionally considered four walls of the oval cylinder have the same length. It is not possible to fix this support element with the formation of a gap between the longitudinal support elements of the cable tray and the horizontal wall of the support element. High dynamic loads during a short circuit can lead to damage or destruction of cable clamps or clamps, clamp fasteners to such a cable tray connecting plate, attachment points of such a connecting plate to the longitudinal support elements of the cable tray.

Known support element is the transverse profiled element of the cable tray disclosed in patent document RU 522833 (IPC: H02G 3/02; publ. 1976.07.25), which can be considered as the closest analogue of the proposed support element. The transverse profiled element has a C-shaped profile, includes two vertical walls interconnected by one horizontal wall, and two additional horizontal walls flanged from the vertical walls. The disadvantage of this support element is excessive rigidity, in the absence at its ends of sections characterized by a reduced threshold of plastic deformation relative to torsion and horizontal bending. This disadvantage is due to the fact that the vertical walls have a length equal to the length of the horizontal walls. Therefore, it is not possible to fix this support element with the formation of a gap between the longitudinal support elements of the cable tray and the horizontal wall of the support element. Under operating conditions, in the event of a short circuit accompanied by the occurrence of high dynamic loads between cables fixed to such a transverse profiled element of a cable tray, there is a high probability of damage or destruction of cable clamps or clamps, fastenings of clamps to such a transverse profiled element of a cable tray, attachment points of such a transverse profiled element to the longitudinal bearing elements of the cable tray, fastening nodes of the longitudinal bearing elements cable th tray to the building structure.

The problem to which the proposed utility model is aimed is to increase the stability of the supporting elements of cable structures, cable structures, cable trays to the action of sudden high mechanical stresses from the side of the high voltage cables fixed to the horizontally oriented supporting elements in the event of short circuits, as well as to the action of high mechanical stresses due to other factors, for example, seismic activity or, for example, anthropogenic impact, and cooked. The solution to this problem is achieved as a result of using in the proposed support element sections characterized by (under conditions of its operation as part of a cable structure or cable tray) a reduced external load threshold at which plastic deformation occurs. Further, for brevity, such areas are also called damping areas.

The specified problem is solved in the proposed support element in that the support element made of metal contains two walls oriented mainly vertically and interconnected by walls oriented mainly horizontally, while from the end of the support element there are additional extensions of these two walls oriented mainly vertically. The terms “vertically” and “horizontally” refer to the operating position of the support member in which it is oriented horizontally and transversely to the direction of cables arranged horizontally. The wall of the supporting element is conditionally considered to be oriented mainly vertically if the area of its projection onto the (imaginary) vertical plane located along the supporting element exceeds the area of its projection onto the horizontal plane, and, accordingly, the wall is conventionally considered oriented mainly horizontally if its projection area is horizontal the plane exceeds the area of its projection onto a vertical plane located along the supporting element. The walls of the support element can be flat or formed of flat sections, but can also have a curved section, for example, the walls can be in the form of part of a cylindrical surface or in the form of part of a conical surface.

The proposed support element is similar to the closest analogue in that it is made of metal and contains two walls oriented mainly vertically and interconnected by walls oriented mainly horizontally.

The proposed support element in the General case differs from the closest analogue in that from its end there are additionally made extensions of these two walls, oriented mainly vertically.

In the first particular case, the proposed support element further differs from the general case in that the said extensions from the end of the support element are additionally provided with fastening elements, while the fastening elements are located at the end sections of these extensions.

In the first refinement of the first particular case, the proposed support element further differs from the first particular case in that the fastening elements are made in the form of protrusions.

In the second refinement of the first particular case, the proposed support element further differs from the first particular case in that the fastening elements are made in the form of holes or grooves.

In the third refinement of the first particular case, the proposed support element further differs from the first particular case in that the fastening elements are made in the form of bends at the ends of the indicated extensions.

In development of the third refinement of the first particular case, the proposed support element is additionally characterized in that holes or grooves are additionally made in said bends.

In the fourth refinement of the first particular case, the proposed support element further differs from the first particular case in that the fastening elements are made in the form of additionally welded heels.

In development of the fourth refinement of the first particular case, the proposed support element is additionally characterized in that holes or grooves are additionally made in said heels.

In the second particular case, the proposed support element further differs from the general case in that the said extensions are made from each of the ends of the support element.

In clarifying the second particular case, the proposed support element further differs from the second special case in that the said extensions are further provided with fastening elements at each end of the supporting element, while the fastening elements are located at the end sections of these extensions.

In one implementation of the specified second particular case, the proposed support element is additionally characterized in that the fastening elements are made in the form of protrusions.

In another implementation of the specified second particular case, the proposed support element is additionally characterized in that the fastening elements are made in the form of holes or grooves.

In the third implementation of the specified second special case, the proposed support element is additionally characterized in that the fastening elements are made in the form of bends at the ends of these extensions.

In development of the third implementation of the specified second particular case, the proposed support element is additionally characterized in that holes or grooves are made in the said bends.

In the fourth implementation of the specified second particular case, the proposed support element is additionally characterized in that the fastening elements are made in the form of bent protrusions on the lower edges of these extensions.

In development of the fourth implementation of the specified second particular case, the proposed support element is additionally characterized in that in said bent protrusions, holes or grooves are additionally made.

In the fifth implementation of the specified second special case, the proposed support element is additionally characterized in that the fastening elements are made in the form of additionally welded heels.

In development of the fifth implementation of the specified second particular case, the proposed support element is additionally characterized in that holes or grooves are additionally made in said heels.

When describing the use of the proposed support element, the term "base" is applied not only to the bases in the cable structures, but also to the building structures, and to the longitudinal support elements of the cable trays.

The implementation of the support element of metal and the presence of two walls oriented mainly vertically and interconnected by walls oriented mainly horizontally, provides the purpose of the support element, because provides stability of the support element to vertical static loads, for example, loads created by the weight of cables or cable trays, or foreign objects (snow, ice, etc.).

The presence of walls oriented mainly horizontally ensures stability in the middle part of the support element, which under operating conditions accounts for most of this vertical load. Maintaining the shape of the middle part of the support element prevents cable clamps and fasteners installed on the middle part of the support element from destruction or deformation. One skilled in the art will appreciate that the number of walls oriented predominantly horizontally and connecting these two walls oriented predominantly vertically can be different: usually this is one wall, for example, in the case of a U-shaped profile of the middle part of the support element; but two walls are possible, for example, in the case of an M-shaped profile and in the case of a pipe rectangular profile, as well as four walls, for example, in the case of a pipe hexagonal profile, etc. Essential for the implementation of the purpose of the support element is the presence of such connecting walls, and not their number. It will also be appreciated by those skilled in the art that the support member may include additional walls involved in providing resistance of the support member to loads.

Performing from the end of the support element the extensions of two walls oriented mainly vertically, provides (when using the support element fixed by this end on the basis of the cable structure or on the building structure) to reduce its resistance to torsion and horizontal bending in the region of the indicated extensions. The presence of these extensions is determined in comparison with the predominantly horizontally oriented walls, i.e. the final portion of the supporting element contains sections of two walls oriented mainly vertically, but does not contain sections of these walls connecting them to each other, oriented mainly horizontally. Based on the foregoing, the specialist understands that when using the support element for fixing, it is necessary to use the indicated extensions not completely, so that a gap is formed between the indicated walls, oriented mainly horizontally, and the base on which the support element is fixed. With this use, the threshold of plastic deformation of the support element in the region of the specified gap is reduced (compared with the middle region of the support element), the damping properties of the support element under dynamic loads acting on the support element from the cable side in emergency situations are increased. A portion of the support member at the indicated gap may be called a “damping portion”. The stability of the support element to

vertical load, if the continuation of both of these specified mainly vertically oriented walls from the fixed end of the support element is attached to the base. As is known to the specialist, it is vertically oriented wall sections that provide the greatest resistance to vertical loading. In addition, in the specified interval due to the absence of horizontal sections of the walls, the elastic resistance of horizontal bending and torsion is reduced. This leads to a decrease in the average natural frequencies of torsion and bending of the supporting element in the horizontal plane. As a result, the propagation of the mechanical energy of vibrations from the installed cables through the support element to the base of the cable structure or to the longitudinal support element of the cable tray slows down also under such loads that do not exceed the plastic deformation threshold of the support element at the indicated interval, which also contributes to the safety of cable structure details or details cable tray, and the safety of cable fasteners, cable sheaths, fasteners, etc.

The proposed support element, when used, can be fixed on the base with one of its ends (for example, if the support element is used as a cable shelf of a cable structure or as a single cable console fixed to the wall of a building structure) or its two ends (for example, if the support element is used as the crossbar of the cable tray or as the crossbar of the U-shaped cable structure, or as the floor support for the cable tray). If the said extensions of the predominantly vertically oriented walls are made from only one end of the support element, it is preferable to use only this end of the support element to fix the support element, i.e. it is preferable to use the support element as, for example, a cable structure console. If these extensions of the predominantly vertically oriented walls are made at both ends of the support element, it is preferable to use both ends of the support element, i.e. it is preferable to use the support element as, for example, the crossbar of the cable tray. If the indicated extensions do not have fastening elements, the fastening of the supporting element on the base can be performed, for example, by welding the ends of the indicated extensions to the metal rack of the cable structure or to the metal embedded part of the building structure, or to the metal longitudinal support element of the cable tray. You can also, for example,

additionally drill holes for bolted joints at the end sections of the indicated extensions.

The supply of these extensions from the end of the proposed support element fasteners located on the end sections of these extensions, facilitates the installation of the proposed support element as a cable console, shelf or bracket, if the fasteners are made in advance at the stage of production of the support element according to the individual task of the consumer or, for example, according to a pre-developed standard design of the unit for fastening the support element to the base. The fastening elements can be made in accordance with those well-known technical solutions in which the fastening elements are located only at the ends of the vertical walls of the known cable consoles, shelves or brackets (i.e., in the form, for example, of bolt holes or, for example, in the form of -shaped protrusions for engagement in the openings of the rack of the cable structure). The location of the fastening elements at the end sections of these extensions allows the formation of the aforementioned gap between these walls, oriented mainly horizontally, and the base on which the supporting element is fixed.

The implementation of these extensions from each end of the support element ensures that it is secured on two bases under operating conditions (for example, when using it as a pressed-in crossbar of a cable tray or, for example, as a welded cross-beam of a U-shaped frame of a cable structure) attenuation of high sudden dynamic the load transferred to each of the bases, by irreversible absorption of mechanical energy at the indicated intervals of the support element, or by slowing down the spread wounds that load fluctuations reduced frequency due to the presence of said gaps. Thus, in an emergency short circuit, the attachment points of both ends of the support element and both bases are protected from damage.

Providing these extensions with fastening elements from each end of the support element facilitates the installation of the proposed support element as, for example, the crossbar of the cable tray or, for example, as the crossbar of the U-shaped frame of the cable structure, if the fastening elements are made in advance at the stage of production of the support element. Moreover, the location of the fastening elements at the end sections of these extensions provides the possibility of education

the aforementioned gaps between the indicated walls of the support element, oriented mainly horizontally, and each of the two bases on which the support element is fixed. In addition, with the symmetrical execution of these extensions and the symmetrical arrangement of the fastening elements at both ends of the support element, the distribution of dynamic loads on both bases is symmetrical in an emergency, which contributes to the safety of, for example, the cable structure or cable tray as a whole.

The implementation of the fastening elements in the form of protrusions (shaped protrusions, including those known in the industry, as one skilled in the art) provides quick installation of the support element on the base if the base (for example, a cable structure rack) is provided with mating holes for the protrusion shape used (similar units) mounts, for example, the so-called bayonet mounts, are well known in the art).

The implementation of the fastening elements in the form of holes or grooves makes it easy to mount the support element on the base with bolt connections, if the base is equipped with mating holes or grooves, since bolts and nuts are standard fasteners and are available at most industrial enterprises and in the range of fasteners of most suppliers .

The implementation of the fastening elements in the form of bends at the ends of the indicated extensions facilitates the fastening of the support element at an angle to the surface of the base (for example, to the front surface of the cable structure upright or to the inner surface of the cable tray side). The presence of bends increases the available perimeter for the fastening points of the support element and, thus, ensures the dispersion of dynamic loads in an emergency and reduces the likelihood of damage to the cable structure or cable tray.

The implementation of the fastening elements in the form of bent protrusions on the lower edges of these extensions facilitates the installation of the proposed support element, provided with the indicated extensions from each of its ends, on a horizontal surface (for example, on the floor or on the bottom of a sheet cable tray and increases the strength of such a installation of the support element, because fasteners (for example, bolted or, for example, welded fasteners) are dispersed along a larger perimeter. In addition, it is possible to use such a supporting element as e rungs

cable tray or, for example, as a support element of a U-shaped cable structure.

The implementation of the fastening elements in the form of additionally welded heels provides increased reliability and ease of fixing the ends of the proposed supporting elements by welding on the bases, for example, on racks of cable structures, on embedded parts of walls, on construction columns, on longitudinal load-bearing elements of cable trays.

The additional holes or grooves in the bends at the ends of the indicated extensions or in the bent protrusions on the lower edges of the indicated extensions, or in the indicated heels, make it easy to mount the support element on the base with bolts and / or nuts if the base is provided with mating holes or grooves, or, for example, mating threaded rods embedded in the base, as bolts and nuts are standard fasteners.

The essence of the proposed support element is illustrated by the embodiments presented in the following images.

FIG. 1: (a), (b), (c) - supporting elements in the form of a U-shaped profile; (e) - supporting element in the composition of the welded cable bracket; (e) - supporting element in the prefabricated wall cable structure; (g) - supporting element in the prefabricated ceiling cable structure; (d) - supporting elements in the composition of the cable tray ladder type.

FIG. 2. Support element in the prefabricated ceiling cable structure.

FIG. 3. Support element in the prefabricated wall cable structure.

FIG. 4. Support element in the welded cable bracket.

FIG. 5. Support element in the form of a U-shaped profile.

FIG. 6. Support element in the form of a round pipe as part of a welded cable bracket.

FIG. 7. Support element in the form of a hexagonal tube as part of a welded cable bracket.

FIG. 8. Support element in the form of an omega-shaped profile as part of a welded cable bracket.

FIG. 9. Support element in the frame cable structure.

FIG. 10. A support element provided with fastening elements in the form of bends at the ends of the extensions of its vertical walls, and a support element provided

fastening elements in the form of bent protrusions on the lower edges of the extensions of its vertical walls, as part of the cable ladder type.

FIG. 11. Support element in the form of a U-shaped profile.

FIG. 12. Support element in the form of a Z-shaped profile.

FIG. 13. The supporting element in the form of a U-shaped profile, the continuation of the vertical walls of which are provided with bends.

FIG. 14. The supporting element in the form of a U-shaped profile, equipped with bent protrusions on the lower edges of the extensions of the vertical walls.

FIG. 15. Support element with welded heels.

Each of the presented support elements 1 contains two predominantly vertically oriented walls 4, interconnected by a predominantly horizontally oriented wall 5. At the ends of the walls 4, extensions are made (compared to the length of the wall 5) 7, by which the support elements can be fixed on the bases 3 or 10 .

Examples of fixing the support elements on the bases by welding are shown in FIG. 1 (e), FIG. 4, FIG. 6 - FIG. 8.

In the bases, holes 8 can be made for a bolt or stud. In the images presented, the wall brackets include a flat base 3, the wall prefabricated structure and the ceiling prefabricated structure include a base 3 in the form of a rack, the frame structure includes two bases 3 in the form of racks, cable tray 9 includes two bases - two longitudinal support elements 10. Cable tray 9 includes two support elements 1. One skilled in the art will recognize that the longitudinal support elements of the cable tray, to which the support element can be attached, can be made in the form of sides of a cable tray sheet CSOs, including two-layer boards disclosed in the utility model RU 85269 (IPC: H02G 3/04; H02G 3/14; publ. 07.27.2009). The frame cable structure of FIG. 9 can be used as a floor cable structure (for example, racks 3 can be welded to embedded parts of the floor or additionally equipped with heels with holes for bolts or studs).

Examples of securing the support elements on the bases with bolts 2 are shown in FIG. 1 (d), (e), (g), FIG. 2, FIG. 3, FIG. 9, FIG. 10.

The fastening elements in the form of holes 13 in extensions 7 are shown in FIG. 3, FIG. 5. When bolted, holes 15 are used in the bases 3. Fastening elements in the form of bends 11 at the ends of the extensions 7 are shown in FIG. 13; in the bends 11 holes are made 17. The supporting element with bends 11 is contained in the cable

tray 9 shown in FIG. 1 (g), FIG. 10 (on the right side of the figure). The fastening elements in the form of bent protrusions 12 at the lower edges of the extensions 7 are shown in FIG. fourteen; holes 18 are formed in the bent projections 12. The support element with the bent projections 12 is contained in the cable tray 9 shown in FIG. 1 (g), FIG. 10 (on the left side of the figure). The fastening elements in the form of welded heels 19 are shown in FIG. fifteen; holes 20 are made in the heels 19. In the wall 5, holes 14 for installation of equipment can be made.

FIG. 3 illustrates the mounting of the support element 1 on the rack 3 by bolts 2 using holes 13 in the extensions 7 (having a length δ1) of the walls 4 and holes 15 in the shelves of the rack 3. The indentation δ2 between the holes 13 and the wall 5 provides a gap δ equal to δ2 minus δ3, where δ3 is the distance of the holes 15 from the edge of the rack 3. You can use the spacer sleeve or, for example, the spacer insert 16 to prevent deformation of the support element and rack when assembling the cable structure.

Under operating conditions, a decrease in the resistance to torsion and horizontal bending of the support elements 1 is ensured by continuations 7 of predominantly vertically oriented walls 4 and the presence of a gap δ between the base 3 or 10 and the predominantly horizontally oriented wall 5. The damping sections "d" are conditionally indicated with braces. FIG. 8 illustrates the plastic deformation of the support element by the example of the support element 1 in the form of an omega-shaped profile containing two vertical walls 4 connected between the failure by a horizontal wall 5 and two horizontal walls 6. The image of FIG. 8 (a) shows the cable structure before exposure to high mechanical stress, and the image of FIG. 8 (b) shows the cable structure after exposure to high mechanical stress.

The presented supporting elements are made of high-quality sheet steel.

The proposed support element can be manufactured at existing enterprises manufacturing electrical products from materials used in the industry.

Claims (18)

1. A support element made of metal, comprising two walls oriented predominantly vertically and interconnected by walls oriented mainly horizontally, characterized in that from the end of the support element there are additionally made extensions of these two walls oriented mainly vertically. 2. The supporting element according to claim 1, characterized in that said extensions from the end of the supporting element are additionally provided with fastening elements, wherein the fastening elements are located at end portions of said extensions. 3. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of protrusions. 4. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of holes or grooves. 5. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of bends at the ends of these extensions. 6. The supporting element according to claim 5, characterized in that in said bends are additionally made holes or grooves. 7. The supporting element according to claim 2, characterized in that the fastening elements are made in the form of additionally welded heels. 8. The supporting element according to claim 7, characterized in that holes or grooves are additionally made in said heels. 9. The support element according to claim 1, characterized in that said extensions are made from each of the ends of the support element. 10. The supporting element according to claim 9, characterized in that said extensions are further provided with fastening elements from each of the ends of the supporting element, wherein the fastening elements are located at end portions of said extensions. 11. The supporting element according to claim 10, characterized in that the fastening elements are made in the form of protrusions. 12. The supporting element according to claim 10, characterized in that the fastening elements are made in the form of holes or grooves. 13. The supporting element according to claim 10, characterized in that the fastening elements are made in the form of bends at the ends of these extensions. 14. The supporting element according to claim 13, characterized in that in said bends are additionally made holes or grooves. 15. The supporting element according to claim 10, characterized in that the fastening elements are made in the form of bent protrusions on the lower edges of these extensions. 16. The supporting element according to claim 15, characterized in that in said bent protrusions holes or grooves are additionally made. 17. The supporting element according to claim 10, characterized in that the fastening elements are made in the form of additionally welded heels. 18. The supporting element according to claim 17, characterized in that holes or grooves are additionally made in said heels.

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