RU2267843C1 - Modular electric plant and its receiving assembly - Google Patents

Abstract

FIELD: power engineering, possible use for construction of supporting structures of sub-stations, distributing devices and other electric plants, meant for receiving, transforming and distributing electric energy of three-phase electric current of industrial frequency 50 Hz in networks with voltages range 35, 110, 150, 220 kV.

SUBSTANCE: modular electric plant consists of electric equipment, receiving assembly and bearing structure, formed of at least one module mounted on foundation , consisting of at least two rows of bearing posts of tubular shape, with at least two of them in each row with forming of flights in longitudinal and transverse directions; bearing beams, supported by bearing posts in each flight of longitudinal direction and mounted in pairs. Modules are constructed so, that bearing beams of separate modules are mutually parallel and/or mutually perpendicular, and electric equipment is mounted on foundation. Receiving assembly consists of at least one current-conducting wire, connected to at least one support, mounted on bearing structure of modular electric plant, while support consists of two polymer isolators, connected along height with forming of rigidity point, and current conducting wire is connected to support by holding assembly. The best variants of inventions from the group are realized with bolt connection of bearing structure elements and polymer isolators.

EFFECT: higher operational reliability of electric plant structures in case of upholding of unification and standardization principles due to development of modules, rational occupation of area occupied by distributing device, possible further expansion of operating electric plants, decreased metal capacity of bearing structure, decreased net costs of mounting operations and operation of electric plant, higher operational reliability of receiving assembly of modular electric plant due to support being capable of receiving static and dynamic loads, increased reliability of receiving assembly of modular electric plant due to development of modules.

2 cl, 4 dwg

Description

The invention relates to energy and can be used in the construction of supporting structures of substations, switchgears and other electrical installations designed to receive, convert and distribute electrical energy of three-phase alternating current of industrial frequency 50 Hz in networks in the voltage range of 35, 110, 150, 220 kV.

The rules for installing electrical equipment (PUE) in Russia are the main regulatory document governing all aspects of the planning, installation and operation of systems consisting of elements whose purpose is transport and conversion of electrical energy.

In accordance with the PUE, electrical installations on load-bearing structures are subject to the requirement of strength and stability of structures as a whole from the action of static and dynamic loads, which include wind loads operating in various power planes, or in accordance with Clause 1.1.22 of the PUE “Electrical Installations and Related with them, structures must be resistant to environmental influences. ”

Known combined kiosk transformer substation (application RU 93033437 A), consisting of a three-dimensional supporting structure in the form of a box-shaped housing mounted on a reinforced concrete base and secured to the latter by means of a bolted connection. It is known that the receiving unit is made standard in the form of a support-rod insulator installed directly on the transformer substation.

Known complete transformer block modernized substation (KTBMP) from the Technical Information TI-064 1999 of the Samara plant "Electroshield". KTBMP consists of electrical equipment and a supporting structure. The supporting structure consists of at least one unit or, in other words, a module. Each module is formed by at least two parallel beams of the foundation; installed on the foundation beams with at least four support legs, on which the transverse beams are supported in pairs with the electrical equipment installed on them. In this case, the transverse beams and the foundation beams are mutually perpendicular. The modules are arranged so that the transverse beams are mutually parallel and / or mutually perpendicular. The listed structural elements are connected by welding.

As the closest analogue to the claimed modular electrical installation, the selected transformer substation of high voltage from the description of patent WO 9114305. The substation consists of electrical equipment, a receiving unit and a supporting structure. The supporting structure consists of at least one module. Each module is formed by at least two parallel beams of the foundation; installed on the foundation beams with at least four support legs, on which the transverse beams are supported in pairs with the electrical equipment installed on them. In this case, the transverse beams and the foundation beams are mutually perpendicular. The modules are arranged so that the transverse beams are mutually parallel and / or mutually perpendicular. Rigid connection of support pillars and base bearing beams is made detachable by means of bolted connections; the transverse beams are attached to the support posts by welding. The foundation beams are made reinforced, consisting of reinforced concrete and metal parts, welded together along the length. It is known that structural elements are made of profiles.

When operating electrical installations like the above, one of the problems is low operational reliability due to the possible exhaustion of the margin of safety of the elements of the supporting structure and its insufficient rigidity. The impact of wind loads - peak and cyclic leads to a break in the support posts of metal profiles. Such an undesirable phenomenon is predetermined by the cross-sectional shape of profiles having a sharp change in width and, as a result, having low resistance to multidirectional loads. The choice of profiles with sufficient strength characteristics, or the strengthening of the supporting structure with additional elements from the profiles, leads to an increase in metal consumption, which results in increased requirements for the operational reliability of the foundation of the structure as a whole, and ultimately affects the overall operating costs of the facility.

In addition, the supporting structures of the above analogues do not have sufficient stability, because under the influence of the wind load, a tipping moment may occur that exceeds the threshold value.

As for the rigidity of the modules described in the closest analogue of WO 9114305 and the analogue of TI-064, it is insufficient due to the implementation of the supporting structure in the form of a U-shaped frame.

It should be noted that the presence of welded joints also reduces the operational reliability of the supporting structure, because the most unfavorable for them are dynamic loads, leading to the destruction of the connection. Therefore, when using welded joints, an additional requirement for operating plants is the mandatory testing of vibration resistance of the supporting structure. This fact also leads to an increase in overall operating costs.

The electrical equipment used in the industry provides for the creation of electrical connection schemes, both in a standard version and non-standard. In this regard, there is a need for a rational layout of electrical installations.

So, analyzing the layout of the modules of the mentioned analogs of the electrical installation (TI-064 and WO 9114305), the following negative features are revealed.

Firstly, the rational arrangement of the modules from the point of view of the area occupied by the electrical installation is not always possible.

Secondly, in the case of a large amount of equipment, it is required to develop electrical connection schemes.

Thirdly, for the installation of electrical equipment at various elevations, it is necessary to use the nomenclature of the support posts;

And the last, due to the presence of welded joints, the installation of modules of the supporting structure (and electrical equipment) is a labor-intensive and material-intensive process.

In relation to a modular electrical installation, the technical task to be solved is as follows:

- to increase the operational reliability of electrical installations, subject to the principles of unification and standardization through the development of modules;

- in the rational use of the occupied area by a switchgear;

- the possibility of further expansion of existing electrical installations;

- in reducing the metal consumption of the supporting structure;

- to reduce the total cost of installation and operation of the electrical installation.

The technical problem posed in relation to a modular electrical installation is solved in that it consists of electrical equipment, a receiving unit and a supporting structure formed of at least one module installed on the foundation, consisting of at least two rows of tubular-shaped support posts, according to at least two in each row with the formation of spans in the transverse and longitudinal directions; load-bearing beams resting on supporting posts in each span of the longitudinal direction, and a base made in the form of a set of transverse beams resting on load-bearing beams in each span of the transverse direction and installed in pairs, the modules being arranged so that the load-bearing beams of the individual modules are mutually parallel and / or mutually perpendicular, and electrical equipment installed on the base.

The best options for using the inventive modular electrical installation are possible with the following design features.

It is advisable that one channel rests on each support post and is attached to the support posts using welds.

It is advisable that the load-bearing beams are attached to the channel, supported by supporting posts, using bolted connections;

It is also advisable that the transverse beams are attached to the supporting beams using bolted connections.

Preferably, at least one span of the longitudinal and / or transverse direction was provided with an arched structure.

It is possible that the modular electrical installation contains at least two additional load-bearing beams installed in the form of consoles on the extreme support posts, while the transverse beams installed in pairs are supported on the console.

The advantage is that the modular electrical installation can be equipped with at least two additional support columns installed in the span of the transverse direction on the carrier beams coaxially with the support columns, while additional transverse columns are supported by transverse beams installed in pairs with electrical equipment installed on them.

Preferably, at least the supporting structure is zinc coated.

The authors propose a receiving unit for a modular electrical installation, previously referring to the closest analogue.

A transformer substation of high voltage with a non-abortive receiving unit is known from the description of the patent WO 9114305. The non-aborting receiving unit consists of supports made in the form of insulators with a current-carrying element attached to them in the form of a bus; supports are mounted on a supporting structure. The supporting structure consists of one module. The module is formed by at least two parallel beams of the foundation; at least four support posts installed on the foundation beams, on which two transverse beams are supported in pairs with electrical equipment installed on them, including support insulators. In this case, the transverse beams and the foundation beams are mutually perpendicular. Rigid connection of support pillars and base bearing beams is made detachable by means of bolted connections; the transverse beams are attached to the support posts by welding. It is known that the elements of the supporting structure are made of profiles, and the supports are made of supporting rod porcelain insulators.

When operating a known non-mortal node, the following disadvantages are identified.

The supporting structure, consisting of a module, does not have sufficient strength and rigidity. A possible exhaustion of the margin of safety leads to a break in the support posts due to the fact that the latter are made of metal profiles. For metal profiles having a cross section with a sharp change in width, low resistance to multidirectional loads is characteristic. It is the influence of multidirectional static and dynamic loads that the load-bearing structure of the receiving unit, in particular the support posts of a metal profile, is subjected. The choice of profiles with sufficient strength characteristics, or the strengthening of the supporting structure with additional elements from the profiles, leads to an increase in metal consumption, which results in increased requirements for the operational reliability of the foundation of the structure as a whole, and ultimately affects the overall operating costs of the facility.

The bearing structure of the receiving unit perceives significant vertical loads from the weight of the busbar. Having good resistance to the effect of vertical load on the weight of insulators and busbars, the module does not have sufficient rigidity, because spatial design has a U-shape.

In addition, the bearing structure in question does not have sufficient stability, since under the influence of the wind load, a tipping moment may occur that exceeds the threshold value.

The disadvantage of the support is significant material consumption, large dimensions and weight of porcelain elements, low moisture discharge characteristics and mechanical reliability of these insulators.

In addition, the support from the porcelain insulator is exposed to the vertical load from the busbar and is not able to absorb the bending force from the effect of the horizontal load. Under the influence of a bending force, a kink is possible at the base of the insulator, where the value of the bending moment is maximum.

In relation to the receiving node, the technical task to be solved is as follows:

- to increase the operational reliability of the receiving unit of a modular electrical installation due to the ability of the support to perceive static and dynamic loads;

- to increase the operational reliability of the receiving unit of a modular electrical installation due to the development of modules;

The stated technical problem is solved in that the receiving unit contains at least one current-carrying wire, at least one support mounted on a supporting structure identical to the supporting structure of a modular electrical installation, while the support consists of two polymer insulators connected in height, and the current-carrying wire is attached to the support.

The best options for using the inventive receiving unit are possible with the following design features.

Preferably, the polymer insulators are connected in height to form a stiffener assembly.

It is also preferable that the stiffening unit be made in the form of a connection of the flanges of polymer insulators.

It is advisable to connect the flanges of the polymer insulators with a bolted connection.

It is also advisable that the support contains flanges at the ends.

It is possible to attach the current-carrying wire to the upper flange of the support by means of a fastening unit.

It is also possible to attach the support to the supporting structure using a bolted connection.

The inventive design of the devices of the modular electrical installation and the receiving node are a group of inventions, one of which is the "receiving node" is intended for use in another. The unified concept of inventions is confirmed by a common technical task and function.

A modular electrical installation is combined in one application with a receiving unit on the grounds that the latter ensures the most efficient operation of the entire structure.

The inventive receiving unit can be used as an independent technical solution in the general structural scheme of the electrical installation with the corresponding equipment.

New in the inventive modular electrical installation is the implementation of supporting struts of a tubular shape. This makes it possible to withstand static and dynamic multidirectional loads. From the course of resistance of materials it is known that an element with an annular cross section is equally strong, because its moment of resistance does not depend on the direction of the load.

It is known from the prior art to use tubular shaped elements as a pile shaft (RU 2171337 C1). In this technical solution, a pair of tubular piles with a hinged joint is pressed into the ground from above; the piles diverge. Being in the ground, piles perceive pressing and pulling forces, and from this point of view it is advisable to use this type of piles. When calculating piles, the stress-strain state “pile-soil” is taken into account. Thus, the influence of lateral compression of the soil causes a possible deformation of the hollow annular section of the pile and the loss of stability of the foundation-structure system. From this point of view, the use of tubular piles is not justified. Thus, due to various kinds of influences on identical elements, the properties of the tubular piles, manifested in the known technical solution, do not coincide with the properties of the support column in the claimed invention.

The module of the supporting structure consists of at least four tubular-shaped support pillars, supporting beams supported in pairs on the support pillars, and a set of transverse beams supported on the longitudinal beams. Thus, the formation of modules, starting with the above basic unit and ending with a technologically justified set of the listed elements and the order of this set, ensures the strength of the supporting structure as independent of the position of the force plane of the wind load.

New is the fact that the bearing longitudinal beams are supported by supporting posts, which, in turn, determines the ability to install electrical equipment on a base consisting of a set of pairwise transverse beams. The module formed in this way as a single frame, starting from the base module, provides a rigid structure due to the introduction of additional ties - load-bearing beams and longitudinal beams in each of the corresponding spans.

Moreover, the presence of the corresponding beams (load-bearing and transverse) in each span of the longitudinal and transverse directions in the span forms a symmetrical structure. From the course of resistance of materials it is also known that the stiffnesses of symmetrically located parts are equal to each other. The symmetry of the stiffness of the supporting structure of the inventive electrical installation provides operational reliability of the structure and meets the objective of the invention.

In addition, due to the introduction of additional ties - load-bearing beams, the module of the load-bearing structure eliminates the occurrence of a moment tilting the support post from the influence of wind load.

By attaching the corresponding module elements with bolted connections, it became possible to simplify the installation of the supporting structure. In addition, bonds made with bolts have a positive effect on the strength of the structure as a whole, as dynamic loads do not affect this type of connection. Another advantage of the bolted connection of the elements of the supporting structure is the possibility of dismantling the structure or its fragment.

The decrease in metal consumption of the supporting structure is explained by the possibility of using the supporting structure with lightweight elements in geographical areas with favorable climatic conditions.

As a supporting structure, the module allows you to reuse and develop typical circuits of electrical connections of electrical equipment and develop non-standard circuits, which meets the principle of standardization.

The principle of unification, formulated as a reduction to a single form or system, is also respected when using the claimed invention. So, the base of the module, consisting of a set of transverse beams installed in each span of the transverse direction, allows you to set the largest number of elements of electrical equipment in the form of a single system in accordance with the PUE.

Among the technical results achieved, the rational layout of the modules is indicated. This statement follows from the very principle of the formation of a module as a single framework using each span of the longitudinal and transverse directions to form bonds.

The channel, based on each support post, is a necessary structural element, providing the possibility of placing the carrier beams of the module.

To enhance the rigidity and stability of the supporting structure, it is justified to use an arched structure installed in the span of the longitudinal or transverse directions.

Additional load-bearing beams with a slant installed on the support racks in the form of consoles allow avoiding the increase in the size of the area occupied by the electrical installation.

Additional support posts with paired beams installed on the supporting beams serve to accommodate electrical equipment if necessary to increase the insulation distance, as well as to form technological passageways under current-carrying wires extending from the electrical equipment.

The implementation of the module with zinc coating ensures the operational reliability of the electrical installation. The choice of this type of coating is explained by the anticorrosive properties of the zinc coating and its hardness. In addition, the zinc coating accurately reproduces the surface profile of the elements of the supporting structure, thread, holes, internal cavities of the support posts.

New in the inventive receiving node of a modular electrical installation is a support composed of polymer insulators.

It is known that support insulators made of polymeric material are widely used in the energy sector, for example, as busbar supports, slewing columns in the disconnector as an alternative to porcelain insulators.

The advantage of polymer insulators compared to porcelain is the following features:

- resistance to high mechanical loads - static and dynamic;

- in resistance to destruction, vibration, mechanical damage and to acts of vandalism, and also has a significantly lower weight.

Known and patented technical solutions for supporting insulation structures: RU 2194324 C2 and RU 2173902 C1. The mentioned structures are used as supporting insulation for high-voltage devices of circuit breakers, disconnectors, busbars. In this case, the supporting insulators perceive the vertical load and its range, depending on the typical variant of the insulator, includes values from 10 to 30 kN.

The applicant has not found information regarding the use of polymer insulators as supports capable of withstanding significant bending loads, for example, from the tension of current-carrying wires.

According to the claimed invention from the group, the support, consisting of polymer insulators connected in height, realizes the possibility of using polymer insulators in a different quality and, therefore, exhibits new properties.

So, the results of tests conducted by the applicant to predict the minimum breaking strength of the bend support insulator (R _min ) show R _min = 27 kN.

However, the bearing capacity of the support made of polymer insulators increases due to the fact that the polymer insulators are connected in height to form a stiffener. Having performed the support of the composite, the upper polymer insulator is mainly exposed to the bending load, and the stiffening unit acts as a damper.

The feasibility of performing flanges at the ends of the support is explained by the widespread use of this type of connecting parts in the technique. In addition, an increase in the strength of the supports at the locations of the flanges is provided.

The connection of the flanges of polymer insulators using bolts is the most technologically advanced in terms of installation, maintainability and ease of use.

For the same reasons, the support is attached to the supporting structure of the receiving unit using a bolted connection.

The attachment point of the current-carrying wire to the composite support is a technologically necessary intermediate element.

Attaching a current-carrying wire support to the upper flange is traditionally used in the art.

In addition, the implementation of the composite support gives the advantage of increasing the insulating distance between the current-carrying wire and the ground, as well as observing the technological level of the location of the current-carrying wires of the electrical installation above the ground.

The possibility of using polymer insulators capable of perceiving the influence of a bending load is realized due to the fact that the support with an attached current-carrying wire is mounted on a supporting structure made identical to the supporting structure of the invention “Modular electrical installation”.

The supporting structure, consisting of at least one module, exhibits the following properties that predetermine the achievement of the technical result by the invention of the "receiving unit".

As indicated above, the implementation of the tubular-shaped support legs makes it possible to withstand static and dynamic multidirectional loads, since the annular section is equally strong, because its moment of resistance does not depend on the direction of the load. The formation of the module, starting with the necessary and sufficient set of elements, ensures the strength of the supporting structure as independent of the position of the force plane of the wind load.

The supporting structure has a significant degree of rigidity, explained by the introduction of additional bonds - load-bearing beams in each span of the longitudinal direction and transverse beams also installed in each span of the transverse direction. The formed symmetric module has the property of symmetry of stiffness, indicating the operational reliability of the receiving unit.

An analysis of the known technical solutions relating to the modular electrical installation and the receiving unit, as well as an analysis of the essential features of the proposed technical solutions from the group, allows us to conclude that the invention meets the criterion of "novelty."

The claimed essential features of the invention, predetermining the receipt of a technical result, do not explicitly follow from the prior art, which allows us to conclude that the invention meets the criterion of "inventive step".

The invention is explained in more detail on the example of its implementation, illustrated by the drawings:

figure 1 is a main view of the module of the supporting structure with electrical equipment;

figure 2 is a top view of the module;

figure 3 is a main view of a modular electrical installation with a receiving node;

figure 4 is a top view of a modular electrical installation with a receiving node.

The inventive device depicted in figures 1 and 2, is an electrical equipment 1 mounted on a supporting structure - module 2. Module 2 consists of four support posts 3 of tubular section mounted on a shallow foundation 4 of the type "lying" and attached to the latter with bolted connection (not shown in the drawings). To the support column 3 in its upper part with the help of a weld, a channel 5 is attached, facing downwards with the shelves.

On supporting posts 3 with a channel 5 (hereinafter referred to as supporting column (s) 3), supporting beams of a metal profile - I-beams 6; the latter are attached to the channel 5 using a botton connection (not shown in the drawings).

The supporting beams from the I-beam 6 are supported by transverse beams from the channel 7, installed in pairs and attached to the said beams 6 by means of a bolted connection (not shown in the drawings).

The pairwise installed beams from the channel 7 form the basis for the installation of electrical equipment 1. The number of pairwise installed beams from the channels 7 within the transverse span is selected taking into account the type of electrical equipment 1 and the permissible distance between its individual elements.

In figure 1, 2 support racks 3 form spans of longitudinal and transverse directions, comprising 6 m and 3 m, respectively, electrical equipment 1 is installed at 2860 mm.

Figures 3 and 4 illustrate the details of the electrical installation consisting of the assembled modules. The electrical installation is a 110 kV open switchgear (switchgear), consisting of a receiving unit 8, supporting structure, consisting of two identical modules 9 and module 10, arranged on site in accordance with the standard circuit diagram of the electrical switchgear. Modules 9, 10 consist of elements identical to those indicated in Figs. 1 and 2, namely: support posts 3, load-bearing beams of I-beams 6, transverse beams from channel channels 7. In addition, additional support beams are installed on the extreme support posts 3 - consoles 11, the latter are made in the form of an I-beam (11) connected to the brace 12. Two transverse pairwise beams 7 of channels are supported on the console 11. Support struts 3 are installed in two parallel rows with the formation of transverse spans of 3 m and spans of longitudinal direction of 6 m. Module 10 has the same values of longitudinal and transverse spans, while the distance between the axes of the support struts 3 of adjacent modules 9, 10 is determined by the permissible the distance between the elements of electrical equipment (in accordance with the PUE) is 3 m. In addition, each of the modules 9 contains an arched structure 13 of metal profiles, for example, corners connected by a weld E. Arched structure 13 is installed in the middle span of the longitudinal direction and in the first span of the transverse direction (view of drawings 3, 4 does not display the arched structure of the transverse direction). In addition, on the supporting beams of the I-beams 6, resting on the extreme support legs 3 of identical modules 9 coaxially with the support legs 3, additional support legs 3 are installed with pairwise transverse beams in the form of channels 6.

The receiving node 8 outdoor switchgear contains a supporting structure consisting of identical modules 9, and composite supports 14 made of two polymer insulators with flanges at the ends (not shown in the drawings); the support 14 is mounted on pairwise beams 7, the latter are supported on the beam-console 11.

The connection node 15 of the polymer insulators of the support 14 is a bolted connection of the flanges of the polymer insulators (not shown in the drawings).

The attachment point of the current-carrying wire 16 to the upper flange of the support 14 is made standard and consists of the following elements: brackets, tension clamp and hardware clamp (not shown in the drawing).

On the support 14, an element of electrical equipment 1 is installed - a choke.

For support 14 of the receiving unit 8, typical polymer support insulators with a height of 1050 mm are used: IOSK-30-110 / 480-I UHL1 as the lower insulator, IOSK-20-110 / 480-I UHL1 as the upper insulator, representing a pipe made of insulating material, for example fiberglass, which is a power element for the perception of mechanical stress; steel metal flanges at the ends of the insulator, the outer and inner polymer insulation. As indicated above, the minimum mechanical breaking strength in bending at the end of a 30 year life is 27 kN.

In relation to the supporting posts of the tubular section 3, the calculation of strength, rigidity and stability allows the use of a pipe 159 × 8 GOST 8732-78.

With regard to the supporting beams and transverse beams, the calculation of strength and stiffness shows that the I-beam 20Sh1 GOST 2602-83 is used as the supporting beams 6, and the channel No. 16P GOST 8240-97 is used as the transverse beams 7.

An outdoor switchgear (switchgear) is constructed on site as follows.

An unfilled foundation 4 of the “lying” type is laid on the platform, support racks 3 are installed on it, load-bearing beams 6 are attached to them, on which, in turn, are installed pairwise transverse beams 7. Electrical equipment 1 is installed on pairwise transverse beams 7.

The support 14 of the receiving unit 8 is installed by attaching the corresponding flange of the lower polymer insulator to the supporting structure - modules 9, then the upper polymer insulator is installed and the current-carrying wire 15 is connected to the upper flange of the formed composite support 14 using the mounting unit (not shown in Figs. 3, 4) .

Claims (15)

1. A modular electrical installation consists of electrical equipment, a receiving unit and a supporting structure formed of at least one module installed on the foundation, consisting of at least two rows of tubular-shaped support posts, at least two in each row, with the formation of spans in the transverse and longitudinal directions, bearing beams, resting on supporting struts in each span of the longitudinal direction, and a base made in the form of a set of transverse beams, resting on bearing beams in each span transverse direction and installed in pairs, and the modules are arranged so that the supporting beams of the individual modules are mutually parallel and / or mutually perpendicular, and the electrical equipment is installed on the base. 2. The modular electrical installation according to claim 1, characterized in that one channel is supported on each support post, which is attached to the support post using welds. 3. The modular electrical installation according to claim 2, characterized in that the supporting beams are attached to the channel with bolted connections. 4. The modular electrical installation according to claim 1, characterized in that the transverse beams are attached to the supporting beams using bolted connections. 5. The modular electrical installation according to claim 1, characterized in that at least one span of the longitudinal and / or transverse direction is provided with an arched structure. 6. The modular electrical installation according to claim 1, characterized in that the supporting structure comprises at least two additional load-bearing beams installed in the form of consoles on the extreme support legs, while the transverse beams installed in pairs are supported on the console. 7. The modular electrical installation according to claim 1, characterized in that the supporting structure comprises at least two additional support legs installed in the span of the transverse direction on the support beams coaxially with the support legs, while the additional installed support legs are supported by pairs of transverse beams with electrical equipment installed on them. 8. The modular electrical installation according to claim 1, characterized in that the supporting structure is made with zinc coating. 9. The receiving unit contains at least one current-carrying wire, at least one support mounted on a supporting structure of a modular electrical installation according to claim 1, wherein the support consists of two polymer insulators connected in height and the current-carrying wire is attached to support through the mount. 10. The receiving unit according to claim 9, characterized in that the insulators are connected in height to form a stiffening unit. 11. The receiving unit according to claim 10, characterized in that the stiffening unit is made in the form of a connection of the flanges of polymer insulators. 12. The receiving unit according to claim 11, characterized in that the flanges are connected using a bolted connection. 13. The receiving unit according to claim 9, characterized in that the support contains flanges at the ends. 14. The receiving unit according to claim 9, characterized in that the current-carrying wire is attached to the upper flange of the support by means of a stiffening unit. 15. The receiving unit according to claim 9, characterized in that the support is attached to the supporting structure using a bolted connection.

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