RU33467U1 - Block distribution point and block distribution point module - Google Patents

Description

h Block distribution point n module of the block distribution point. The utility model relates to the field of electrical engineering, namely to the power supply of objects for various purposes. Known stationary complete switchgears (cameras type KCO), having an open design and intended for one-way service. The cameras are divided into three compartments. In the upper compartment of the chamber, prefabricated busbars and a bus disconnector are openly located, in the middle compartment there is a VMG type switch or a load switch, or fuses and disconnectors, in the lower compartment there is a linear disconnector, cable funnel and current transformers of the TZ type. On the facade of the cell there are upper and lower doors (see, for example, EA KONYUHOVA, Power supply facilities, Moscow, Mastery Publishing House, 2002, p. 102). The closest to the claimed utility model in its essence and the achieved result is a distribution substation that is attached to an existing industrial building, or placed in a separate room inside an existing industrial facility, for example, between columns in a workshop, or made separately with complete switchgear cameras (see ibid., pp. 114 - 116, Fig. 7.11 b). The objective of this utility model, both in terms of a block distribution point and in terms of the module of such a block distribution point, is to increase the cost-effectiveness and reduce the complexity of installation and operation of a block distribution point while ensuring reliability and durability, improving service conditions and ensuring optimal use of the area for the construction of distribution points of various sizes and power supply of a different number of consumers th.

walls, floor and roof, and the electrotechnical and auxiliary equipment of a block distribution point mounted in it, characterized in that it is made in the form of at least one transportable module - a volume unit of full factory readiness with a ratio of lengths of pairs of opposite external walls of 1 , 0 - 1, 45, and the electrical and auxiliary equipment is located in at least two partially mutually redundant sections, part of the cells of which in different sections are made duplicating each other.

A block distribution point may be connected to at least two sources of constant power supply via appropriate cable lines and may be configured to connect at least four cable outlet lines.

The block distribution point can be configured to connect to at least two additional sources of electricity from the backup power centers through the corresponding cable lines.

A block distribution point can be made on the basis of two or more transportable modules, each of which can be made in the form of a volume unit.

In each section, four output cells, two input cells, a cell for an auxiliary transformer and a cell for a voltage transformer for monitoring and measuring the voltage on the sections and ensuring the operation of the automatic input of backup power between the sections can be mounted in series, and the output and input cells can be equipped current transformers for measuring the phase current and for measuring the earth fault current, while in one section a cell of a sectional switch can be placed, and in another with section - symmetrically to the cell of the sectional switch relative to the same plane, the cell of the sectional disconnector can be placed electrically connected to the cell of the sectional switch, and the cell sections can be mounted with the formation of passages mainly symmetrical with respect to the same plane of the volumetric block along the outer walls of the volumetric block .

Input, output cells and iodine-transformer cells can be equipped with maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as earth fault protection with an independent time delay with a signal action.

The sectional switch cell can be configured with an overcurrent short-circuit protection device with an independent time delay with a shutdown action, as well as with an automatic backup thread input device, which may contain elements for disconnecting the cable transmission line power input to the emergency section with an adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section below a certain level in one, two or three phases, the blocking system During operation of the overcurrent protection device for inputting power supply of the cable power line to the emergency section, a system for automatically turning on the sectional switch from the contact block of the input switch without time delay after disconnecting the power input for the cable power line to the emergency section, manual reset devices after automatic operation, as well as control keys for two positions of automatic input of backup power “input -“ output, installed on the input cells Trics for ensuring the continuity of the principle of the control circuit section switch at any position of the trolley disconnected input switch.

A block distribution point can be equipped with telemechanization systems, including telecontrol, tele-alarm and telemetry systems: the positions of cable line switches, power transformers and a section switch, ground faults, cable connections of higher voltage, voltage on the buses of each section, operational faults circuits with the ability to execute telecontrol commands by a circuit breaker in each section, including TV and TV disconnections and with Stem Telemetry load currents of cable lines, power transformers and voltage sections sectioned on the switch.

voltage, mainly 0.4 kV, can be used mainly dry transformers with a capacity of 40 kVA each voltage of 10 + 2 x 2.5% / 0.4 kV.

The volumetric block can be mounted on a foundation made in the form of a buried in the ground, located in a trench expanding upwards on a compacted sand cushion of a supporting armopoyode, formed by reinforced concrete tapes located along the perimeter of the outer walls of the volumetric block and in parallel with at least one pair of opposite ones , as well as foundation blocks installed on the armored belt, also buried in the ground, with a width shorter than the armored belt, and made on the top of the foundation blocks at the level of the daily ited reinforced cement screed, wherein the sand in the trench top cushion may be arranged to dirt filling level of the bottom of the base blocks, and between the base blocks may be formed from underground walls.

One of the reinforced concrete tapes forming an armored belt located parallel to one pair of opposing walls of the volume block can be placed along one of the two middle vertical planes of the volume block, and the remaining tapes parallel to this plane - at equal distances from each other.

Each volume unit may consist mainly of a metal frame, insulated external walls, insulated ceiling, floor, roof and at least one safe metal door.

The external walls can be made of three-layer metal panels of the type “sandwich with insulation, preferably polyurethane foam, with environmentally friendly two-sided painting, and the roof can be made preferably of profiled metal sheets with zinc or aluminum-zinc coating and a layer of non-combustible insulation, and profiled metal sheets can be interconnected by combined rivets.

The problem in terms of the module block distribution point is solved due to the fact that the proposed module block distribution point, weatherproof, insulated, factory

manufacture, containing enclosing structures, including external walls, NOL and roof, and mounted in it electrical and auxiliary equipment of a block distribution point, characterized in that it is made in the form of a portable volumetric block with a length ratio of pairs of opposite external walls of 1, 0 1.45, and the electrical and auxiliary equipment is located in two, at least partially mutually redundant sections, part of the cells of which in different sections are made duplicate yn friend.

The module of a block distribution point can be connected to at least two sources of electric energy of constant power supply through the corresponding cable lines and can be made with the possibility of connecting at least four outlet cable lines and with the possibility of connecting at least two additional power sources from standby power centers through appropriate cable lines.

In each section, in series, starting from the ends of the sections facing the same end of the volume unit, four output cells, two input cells, a cell for auxiliary transformer and a cell for voltage transformer can be mounted to control and measure the voltage on the sections and ensure the automatic input of backup power between sections, moreover, these cells can be performed in different sections in pairs of the same type for functional purpose, and in the zone facing the opposite end at the volume unit, in one section the cell of the sectional switch can be placed, and in the other section symmetrically to the cell of the sectional switch relative to one of the two middle vertical planes of the volumetric block, the cell of the sectional switch can be placed electrically connected to the cell of the sectional switch.

Input, output cells and cells for transformers can be equipped with maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as protection against earth faults with an independent time delay with a signal action.

The sectional switch cell can be made with an overcurrent short circuit protection device with an independent time delay with a shutdown action, as well as with an automatic backup thread input device, which may contain elements for disconnecting the power line cable input to the emergency section with an adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section below a certain level in one, two or three phases, the blocking system During operation of the overcurrent protection device for inputting power supply of the cable power line to the emergency section, a system for automatically turning on the sectional switch from the contact block of the input switch without time delay after disconnecting the power input for the cable power line to the emergency section, manual reset devices after automatic operation, as well as control keys for two positions of automatic input of backup power “input -“ output, installed on the input cells Trics for ensuring the continuity of the principle of the control circuit section switch at any position of the trolley disconnected input switch.

The module of a block distribution point can be equipped with telemechanization systems, including telecontrol systems, telemetry signaling systems: positions of cable line switches, power transformers and a section switch, ground faults, cable connections of higher voltage, voltage on the buses of each section, operational faults circuits with the possibility of executing telecontrol commands by a circuit breaker in each section, including TV switching and TV disconnect eniya and telemetry systems load currents of cable lines, power transformers and voltage sections sectioned on the switch.

As transformers for step-down energy conversion of higher voltage, predominantly 10 kV ,. for electricity of low voltage, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kVA each with a voltage of 10 ± 2 x 2.5% / 0.4 kV can be used.

The volumetric block can be mounted on a foundation made in the form of a buried in soil, located in a trench expanding upwards on a consolidated sand cushion of a supporting armonoyas formed by reinforced concrete tapes located along the perimeter of the outer walls of the volumetric block and parallel to at least one pair of opposite ones , as well as foundation blocks installed on the armored belt, also buried in the ground, with a width shorter than the armored belt, and made on the top of the foundation blocks at the level of the daily ited reinforced cement screed, wherein the sand in the trench top cushion may be arranged to dirt filling level of the bottom of the base blocks, and between the base blocks may be formed from underground walls.

One of the reinforced concrete tapes forming an armored belt located parallel to one pair of opposite external walls of the volume block can be placed along one of the two middle vertical planes of the volume block, and the remaining tapes parallel to this plane can be placed at equal distances from each other.

Each volume unit may consist of a predominantly metal frame, insulated external walls, insulated ceiling, floor, roof and at least one safe metal door.

The external walls can be made of three-layer metal panels of the type “sandwich with insulation, preferably polyurethane foam, with environmentally friendly two-sided painting, and the roof can be made preferably of profiled metal sheets with a pink or aluminum zinc coating and a layer of non-combustible insulation, and the profiled metal the sheets can be joined together by combined rivets.

The technical result provided by both objects of the utility model consists in increasing the efficiency of energy supply while ensuring reliability and durability and simplifying maintenance due to the optimal design of volume units, the optimal ratio of their parameters and the optimal

the adopted system and installation sequence, as well as the sequence and relative position of the cells in the volume units, the compactness of the distribution point and the acceleration of its commissioning by reducing the amount of work carried out at the construction site, including by optimizing the construction of the foundation for which the volume the block is installed.

The essence of the utility model is illustrated by drawings, where

in FIG. 1 - shows a block distribution point in the plan;

in FIG. 2 is the same, view along A - A in FIG. 1;

in FIG. 3 is the same, a view along B - B in FIG. 1;

in FIG. 4 is the same schematic diagram of power supply;

in FIG. 5 - the same layout of cabling;

in FIG. 6 - the same, grounding;

in FIG. 7 - the same, the layout of the foundation in the plan;

in FIG. 8 is a section along B - B in FIG. 7;

in FIG. 9 is a section along D - G in Fig 8;

in FIG. 10 - node D in FIG. 8 and FIG. 9;

in FIG. 11 is a plan of the location of the armo-belt in the plan;

in FIG. 12 is a section E - E in FIG. eleven;

in FIG. 13 is a plan of arrangement of foundation blocks in a plan;

in FIG. 14 - arrangement of the plan in the reinforced cement-sand

screeds;

in FIG. 15 - section F - W in Fig. 14.

The block distribution point is made on the basis of one transportable module in the form of a volume unit 1.

One pair of opposing outer walls 2 of the volume block 1 within this block has a length of 1.0 - 1.45 of the length of the opposing outer walls 3 of the other pair.

L -, // 232 L

The specified equipment includes output 6-9 and 15-18 and input 10, 11 and 19, 20 cells of sections 4 and 5 and cells 12, 13, and 21, 22 for transformers. These cells are sequentially grouped in each section 4 and 5 unidirectionally, starting from the ends of 24 sections 4 and 5, facing the same end face 25 of the volume unit 1.

The above cells of the same functional purpose are made in different sections 4 and 5 in the same type and placed mirror symmetrically relative to one of the two middle vertical planes 26 of the volume unit 1.

In the area facing the opposite end 27 of the volume unit 1, in one section 4 there is a cell 14 of a sectional switch.

In another section 5, symmetrically to the cell 14 of the sectional switch relative to the same plane 26, a cell 23 of the sectionalizer is electrically connected to the cell 14 of the sectional switch.

Cell sections are mounted with the formation, mainly symmetrical relative to the same plane of the volume block 1 of the passages 28 along the outer walls 2 of the volume block 1 facing them.

In section 4, at the end face 25 of the volume unit, a telemechanics terminal box 29, a lighting, heating and ventilation panel 30, auxiliary power supply panel 31, alarm circuits and a device for finding “land 32” are mounted, and telemechanization systems 33 and telephone set 34.

In section 5, at the end face 25 of the volume unit 1, metering cabinets 35 are installed.

Cells 6-23 are made with cable consoles 36.

The block distribution point is connected to at least two sources of energy 37 constant power through the corresponding cable lines 38 and is configured to connect at least four outlet cable lines 39.

The block distribution point is configured to connect to at least two additional sources of electricity 40 from the backup power centers through the corresponding cable lines 41.

SG

A block distribution point can be made on the basis of two or more transportable modules, each of which is made in the form of a volume unit 1.

The output cells are 6–9 and 15–18, respectively, the input cells are 10, I and 19, 20, respectively, cells 12 and 21 for the auxiliary transformer and cells 13 and 22 under the voltage transformer for monitoring and measuring voltage on sections 4 and 5 and providing the operation of automatic input 42 backup power between sections 4 and 5, respectively, are mounted in sections in series.

Output 6-9 and 15-18 and input cells 10, 11 and 19, 20 are equipped with current transformers 43 for measuring phase current and for measuring the earth fault current.

Input 10, And and 19, 20, output 6-9 and 15 - 18 cells and cells 12, 13 and 21, 22 for transformers are equipped with maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as protection against short circuits on Independently delayed ground with signal action (not shown).

The cell 14 of the sectional switch is made with a device (not shown) for maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as with an automatic input device 42 for backup power.

The automatic backup power input device 42 contains elements (not shown) for disconnecting the power supply of the cable power line to the emergency section with an adjustable time delay from 0 to 20 s when the voltage disappears or decreases below a certain level in one, two or three phases, the system blocking (not shown) during operation of the overcurrent protection device for power input of the cable power line to the emergency section. Also, the automatic input device 42 of the backup power supply includes a system (not shown) for automatically turning on the sectional switch 44 from the contact contacts of the input switch (not shown) without delay after disconnecting the power input of the cable power line to the emergency section 4 or 5, automatic operation, and also control keys (not shown) to the two positions of the automatic input of the backup power “entered -“ displayed, installed on the input cells 10, And and 19, 20 to ensure the principle of continuity pi control section switch 44 at any position of the carriage disconnected input switch (not shown). Telemechanization systems 33 include telecontrol, tele-alarm and telemetry systems. The telealarm system provides the positions of cable line switches, power transformers and a sectional switch, ground faults, cable connections of higher voltage, voltage on the buses of each section, and malfunctions in operational circuits. Telecontrol provides the ability to execute commands with a power switch in each section, including TV and TV shutdowns, and telemetry systems for load currents of cable lines, power transformers and a sectional voltage switch on the sections. As transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly, 0.4 kV, dry transformers with a power of 40 kVA each, voltage of 10 ± 2 x 2.5% / 0, are mainly used. 4 kV. The volumetric block 1 is mounted on the foundation 45. The foundation 45 is made in the form of a buried in the ground, located in the trench 46 expanding upward on a compacted sand cushion 47 of the load-bearing arm belt 48, formed by reinforced concrete tapes 49 located along the perimeter of the outer walls 2, 3 of the volumetric block 1 and in parallel of at least one pair of 3 opposite of them, as well as of foundation blocks 50 buried in the ground, also installed on armopoyas 48, with a width smaller than armopoyas 48, and made on top of foundation blocks 50 etke the surface of reinforced cement-sand screed 51. The trench 46 on top of the sand cushion 47 is a dirt filling level of the bottom 52 to the foundation blocks 50 and between the adjoining blocks 50 is formed by the underground 53 with walls 54.

One of the reinforced concrete tapes 49, forming armopoyas 48, located parallel to one pair of opposing walls 3 of the volume unit 1, is placed on one of the two middle vertical planes 55 of the volume unit 1, and the remaining tapes 49 parallel to this plane 55 are at equal distances from each other.

Each volume unit 1 consists of a metal frame (not shown), insulated outer walls 2 and 3, insulated ceiling 56, floor 57, roof 58 and at least one safe metal door 59.

External walls are made of three-layer metal panels of the type “sandwich with insulation (not shown), preferably polyurethane foam, with environmentally friendly two-sided painting.

The roof is preferably made of profiled metal sheets (not shown) with a zinc or aluminum-zinc coating and a layer of non-combustible insulation (not shown).

Profiled metal sheets are interconnected by combined rivets (not shown).

The module of the block distribution point is made in the form of a volume unit 1.

One pair of opposing outer walls 2 of the volume block 1 within this block has a length of 1.0 - 1.45 of the length of the opposing outer walls 3 of the other pair.

In the volume unit 1, at least two sections 4 and 5 of cells 6 - 23 are mounted with switching equipment and protection devices.

The specified equipment includes output 6-9 and 15-18 and input 10, 11 and 19, 20 cells of sections 4 and 5 and cells 12, 13, and 21, 22 for transformers. These cells are sequentially grouped in each section 4 and 5 unidirectionally, starting from the ends of 24 sections 4 and 5, facing the same end 25 of the volume unit 1.

The above cells of the same functional purpose are made in different sections 4 and 5 in pairs of the same type and placed mirror symmetrically with respect to one of the two middle vertical planes 26

in the area facing the opposite end 27 of the volume unit 1, in one section 4 there is a cell 14 of the sectional switch.

In another section 5, symmetrically to the cell 14 of the sectional switch with respect to the same speed 26, the cell 23 of the sectionalizer is electrically connected to the cell 14 of the sectional switch.

Cell sections are mounted with the formation, mainly symmetrical relative to the same plane of the volume block 1 of the passages 28 along the outer walls 2 of the volume block 1 facing them.

In section 4, at the end face 25 of the volume unit, a telemechanics terminal box 29, a lighting, heating and ventilation panel 30, auxiliary power cabinet 31, alarm circuits and a device for finding “land 32” are mounted, and telemechanization systems 33 and telephone set 34.

In section 5, at the end face 25 of the volume unit 1, metering cabinets 35 are installed.

Cells 6-23 are made with cable consoles 36.

The block distribution point is connected to at least two sources of energy 37 constant power through the corresponding cable lines 38 and is configured to connect at least four outlet cable lines 39.

The block distribution point is configured to connect to at least two additional sources of electricity 40 from the backup power centers through the corresponding cable lines 41.

A block distribution point can be made on the basis of two or more transportable modules, each of which is made in the form of a volume unit 1.

The output cells are 6-9 and 15-18, respectively, the input cells are 10, And and 19, 20, respectively, cells 12 and 21 for the auxiliary transformer and cells 13 and 22 for the voltage transformer to control and measure the voltage on sections 4 and 5 and ensure automatic operation input 42 backup power between sections 4 and 5, respectively, are mounted in sections in series.

Output 6-9 and 15-18 and input cells 10, I and 19, 20 are equipped with current transformers 43 for measuring phase current and for measuring the earth fault current.

Input 10, And and 19, 20, output 6 - 9 and 15 - 18 cells and cells 12, 13 and 21, 22 under the transformers are equipped with maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as protection against earth faults with independent time delay with action on the signal (not shown).

The cell 14 of the sectional switch is made with a device (not shown) for maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as with an automatic input device 42 for backup power.

The automatic backup power input device 42 contains elements (not shown) for disconnecting the power supply of the cable power line to the emergency section with an adjustable time delay from 0 to 20 s when the voltage disappears or decreases below a certain level in one, two or three phases, the system blocking (not shown) during operation of the overcurrent protection device for power input of the cable power line to the emergency section. Also, the automatic input device 42 of the backup power supply includes a system (not shown) for automatically turning on the sectional switch 44 from the contact contacts of the input switch (not shown) without delay after disconnecting the power input of the cable power line to emergency section 4 or 5, devices (not shown) return to initial position after automatic operation, as well as control keys (not shown) for two positions of automatic input of backup power “entered -“ displayed, installed on the input cells 10, 11 and 19, 20 to ensure the principle of continuity of the control circuit of the sectional switch 44 at any position of the trolley of the disconnected input switch (not shown).

Telemechanization systems 33 include telecontrol, tele-alarm and telemetry systems.

connection of cable lines of higher voltage, the presence of voltage on the tires of each section, malfunctions in operational circuits.

Telecontrol provides the ability to execute commands with a power switch in each section, including TV and cable, and telemetry systems for load currents of cable lines, power transformers and a sectional voltage switch on the sections.

As transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly, 0.4 kV, dry transformers with a power of 40 kVA each, voltage of 10 ± 2 x 2.5% / 0, are mainly used. 4 kV.

The volumetric block 1 is mounted on the foundation 45. The foundation 45 is made in the form of a buried in soil, located in a trench 46 expanding upward on a compacted sand cushion 47 of a supporting armopoy 48, formed by reinforced concrete tapes 49 located along the perimeter of the outer walls 2, 3 of the volumetric block 1 and parallel to at least one pair of 3 opposite of them, and also installed on armopoyas 48, also the foundation blocks 50 buried in rpyin, of a smaller width armopoyas 48, and made on top of the foundation blocks 50 on the top day surface ke reinforced cement-sand screed 51.

In a trench 46, a soil backfill 52 is located on top of the sand cushion 47 to the bottom of the foundation blocks 50, and an underground 53 with walls 54 is formed between the foundation blocks 50.

One of the reinforced concrete tapes 49, forming armopoyas 48, located parallel to one pair of opposing walls 3 of the volume unit 1, is placed on one of the two middle vertical planes 55 of the volume unit 1, and the remaining tapes 49 parallel to this plane 55 are at equal distances from each other.

Each volume unit 1 consists of a metal frame (not shown), insulated outer walls 2 and 3, insulated ceiling 56, floor 57, roof 58 and at least one safe metal door 59.

The outer walls are made of three-layer metal panels of the type “sandwich with insulation (not shown), preferably polyurethane foam, with environmentally friendly two-sided painting.

The roof is preferably made of profiled metal sheets (not shown) with a zinc or aluminum-zinc coating and a layer of non-combustible insulation (not shown).

Profiled metal sheets are interconnected by combined rivets (not shown).

Claims (24)

1. A block distribution point mounted on a foundation, including enclosing structures, including external walls, floor and roof, and electrical and auxiliary equipment of a block distribution point mounted in it, characterized in that it is made in the form of at least one transportable module - a volume unit of full factory readiness with a parity of lengths of pairs of opposite external walls of 1.0-1.45, and electrical and auxiliary equipment is located at least re, in two partially mutually redundant sections, part of the cells of which in different sections are made duplicating each other. 2. The block distribution point according to claim 1, characterized in that it is connected to at least two sources of energy of constant power supply through the corresponding cable lines and is configured to connect at least four outlet cable lines. 3. The block distribution point according to claim 2, characterized in that it is configured to connect to at least two additional sources of electricity from the backup power centers through the corresponding cable lines. 4. Block distribution point according to any one of claims 1 to 3, characterized in that it is based on two or more transportable modules, each of which is made in the form of a volume unit. 5. Block distribution point according to any one of claims 1 to 4, characterized in that in each section four output cells, two input cells, a cell for auxiliary transformer and a cell for voltage transformer for monitoring and measuring the voltage on the sections and providing automatic input of backup power between the sections, the output and input cells are equipped with current transformers for measuring the phase current and for measuring the earth fault current, while in one section there is a cell section switch, and in the other section, symmetrically to the section switch cell relative to the same plane, the section disconnector cell is electrically connected to the section switch cell, and the sections of the cells are mounted with the formation of passages, mainly symmetrical with respect to the same plane of the volumetric block, along the outer passages walls of the volume block. 6. Block distribution point according to any one of claims 1 to 5, characterized in that the input, output and transformer cells are equipped with maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as earth fault protection with an independent delay of time with action on a signal. 7. The block distribution point according to any one of claims 1 to 6, characterized in that the cell of the sectional switch is made with a device for maximum current protection against interphase short circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device, which contains elements for disconnecting the power input of the cable power line to the emergency section with adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section below a certain level in one, two or three phases, a blocking system during operation of the overcurrent protection device for inputting power supply of the cable power line to the emergency section, a system for automatically turning on the sectional switch from the contact contacts of the power switch without time delay after disconnecting the power supply of the cable power line to the emergency section, devices manual return to the initial position after automatic operation, as well as control keys for two positions of automatic backup input Ethan "put" - "displayed", installed on the input cells to ensure the continuity of the principle of the control circuit section switch at any position of the trolley disconnected input switch. 8. The block distribution point according to claim 1, characterized in that it is equipped with telemechanization systems, including remote control systems, telealarm systems and telemetry: the position of the cable line switches, power transformers and sectional switch, ground fault, to connect cable high voltage , the presence of voltage on the tires of each section, malfunctions in the operational circuits with the possibility of executing telecontrol commands by a power switch in each section, including television switching and tele-shutdowns and telemetry systems for load currents of cable lines, power transformers and a sectional voltage switch in sections. 9. The block distribution point according to claim 1, characterized in that as transformers for down-converting high-voltage energy, preferably 10 kV, into low-voltage electricity, mainly 0.4 kV, dry transformers with a capacity of 40 kVA each with a voltage of 10 are used ± 2x2.5% / 0.4 kV. 10. Block distribution point according to any one of claims 1 to 9, characterized in that the volumetric block is mounted on a foundation made in the form of a recessed in soil located in a trench expanding upwards on a compacted sand cushion of a load-bearing arm belt formed by reinforced concrete tapes located around the perimeter the outer walls of the volumetric block and in parallel with at least one pair of opposing ones, as well as those installed on the armo-belt, also foundation blocks with a width shorter than the armo-belt, buried in the ground, and A reinforced cement-sand screed made at the top of the foundation blocks at the level of the surface of the day, and in the trench over the sand cushion there is a soil backfill to the level of the bottom of the foundation blocks, and an underground wall is formed between the foundation blocks. 11. The block distribution point according to claim 10, characterized in that one of the reinforced concrete tapes forming an arm belt, parallel to one pair of opposing walls of the volume block, is placed along one of the two middle vertical planes of the volume block, and the remaining tapes parallel to this plane at equal distances from each other. 12. Block distribution point according to any one of claims 1 to 11, characterized in that each volume unit consists mainly of a metal frame, insulated external walls, insulated ceiling, floor, roof and at least one safe metal door. 13. The block distribution point according to claim 12, characterized in that the outer walls are made of three-layer metal panels of the sandwich type with a heater, preferably polyurethane foam, with environmentally friendly two-sided painting, and the roof is preferably made of profiled metal sheets with zinc or aluminum-zinc coating and a layer of non-combustible insulation, and profiled metal sheets are interconnected by combined rivets. 14. The module of the block distribution point, weatherproof, insulated, factory-made, containing enclosing structures, including external walls, floor and roof, and the electrical and auxiliary equipment of the block distribution point mounted in it, characterized in that it is made in a transportable volumetric block with a ratio of the lengths of pairs of opposite external walls of 1.0-1.45, and electrical and auxiliary equipment is located in two, at least at least partially mutually redundant sections, part of the cells of which in different sections are made duplicating each other. 15. The module of a block distribution point according to claim 14, characterized in that it is connected to at least two sources of electric energy of constant power supply through corresponding cable lines and is configured to connect at least four outlet cable lines and to be connected at least two additional sources of electricity from the backup power centers through the corresponding cable lines. 16. The module of the block distribution point according to any one of paragraphs.14 and 15, characterized in that in each section in series, from the ends of the sections facing the same end of the volume unit, four output cells, two input cells, a cell under auxiliary transformer and a cell for a voltage transformer for monitoring and measuring the voltage on the sections and ensuring the operation of automatic input of backup power between the sections, and these cells are made in different sections in pairs of the same type in function ionic purpose, and in the area facing the opposite end of the volume unit, a sectional switch cell is located in one section, and the sectional switch cell is symmetrical to the sectional switch cell relative to one of the two middle vertical planes of the volumetric block, the sectionalizer cell is electrically connected to the sectional switch cell. 17. The module of the block distribution point according to clause 16, characterized in that the input, output and transformer cells are equipped with maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as earth fault protection with an independent delay time with the action on the signal. 18. The module of the block distribution point according to paragraphs 16 and 17, characterized in that the cell of the sectional switch is made with a device for maximum current protection against interphase short circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device, which contains elements for disconnecting the power input of the cable power line to the emergency section with adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section below certain level in one, two or three phases, a blocking system during operation of the overcurrent protection device for inputting power supply of the cable power line to the emergency section, a system for automatically turning on the sectional switch from the contact contacts of the power switch without time delay after disconnecting the power input of the cable power line to the emergency section, manual reset devices after automatic operation, as well as control keys for two positions of automatic input th power "is entered," - "displayed", installed on the input cells to ensure the continuity of the principle of the control circuit section switch at any position of the trolley disconnected input switch. 19. The module of a block distribution point according to any one of paragraphs.14-18, characterized in that it is equipped with telemechanization systems, including telecontrol systems, tele-signaling telemetry systems: positions of cable line switches, power transformers and a section switch, ground fault, to connections cable lines of higher voltage, the presence of voltage on the tires of each section, malfunctions in operational circuits with the possibility of executing remote control commands by a power switch in each section, in t m including televklyucheniya and transfer trip and telemetry systems load currents of cable lines, power transformers and voltage sections sectioned on the switch. 20. The module of the block distribution point according to clause 16, characterized in that, as transformers for the down-conversion of higher voltage energy, preferably 10 kV, to low voltage electricity, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kVA are used each voltage of 10 ± 2x2.5% / 0.4 kV. 21. The module of a block distribution point according to any one of claims 14 to 20, characterized in that the volumetric block is mounted on a foundation made in the form of a buried in soil located in a trench expanding upwards on a compacted sand cushion of a load-bearing arm belt formed by reinforced concrete tapes located along the perimeter of the outer walls of the volumetric block and in parallel with at least one pair of opposite ones, as well as those installed on the armored belt, also foundation blocks with a width smaller than the width ap mopoyas, and reinforced cement-sand screed made at the top of the foundation blocks at the level of the surface of the day, and in the trench above the sand cushion there is a soil backfill to the level of the bottom of the foundation blocks, and an underground with walls is formed between the foundation blocks. 22. The module of a block distribution point according to claim 21, characterized in that one of the reinforced concrete tapes forming an arm belt, parallel to one pair of opposing outer walls of the volume block, is placed along one of the two middle vertical planes of the volume block, and the remaining tapes parallel to this plane, - at equal distances from each other. 23. The module distribution block according to any one of paragraphs.14-22, characterized in that each volume unit consists mainly of a metal frame, insulated outer walls, insulated ceiling, floor, roof and at least one safe metal door. 24. The module of the block distribution point according to claim 23, wherein the outer walls are made of three-layer metal panels of the sandwich type with insulation, preferably polyurethane foam, with environmentally friendly two-sided painting, and the roof is preferably made of profiled metal sheets with zinc or aluminum-zinc coating and a layer of non-combustible insulation, and the profiled metal sheets are interconnected by combined rivets.