RU2240638C1 - Method for power supply to structure or complex thereof being erected or reconstructed; method for power supply to settlement, location, district of town, industrial or agroindustrial complex, or city; power network of erected or reconstructed structure or complex of structures; power supply to settlement, location, district of town, industrial or agroindustrial complex, or city - Google Patents

Abstract

FIELD: electrical engineering; power supply to various projects.

SUBSTANCE: proposed method for power supply to erected or reconstructed structure or complex of structures includes separate laying of power cable lines from at least two independent geographically spaced apart power supplies, installation of modular distribution center in the form of at least one transportable precipitation-proof heated module or three-dimensional prefabricated unit on pre-erected foundation, lengths of opposing external wall pairs of this unit being in definite proportion, and at least two cubicle sections accommodating switching and protective devices for uniform load distribution among users being provided in unit. Equipment is mounted upon installation of three-dimensional unit on foundation for reuse by provision for its removal from foundation, displacement, and connection in power systems of other projects, including those newly erected or reconstructed, or by replacement in emergency situations with similar three-dimensional unit. Method includes laying of new power lines including those at least partially replacing existing ones, or additional power lines, or power supply and distribution networks. Power network has power lines for connecting loads from at least two geographically spaced apart independent power supplies. Optimal arrangement of pieces of equipment, considering their functional applications, facilitates maintenance of power network.

EFFECT: enhanced economic efficiency and service life, facilitated maintenance of power network.

24 cl, 15 dwg

Description

The invention relates to the field of electrical engineering, namely to the power supply of objects for various purposes.

A known method of power supply for various purposes, involving the open construction of stationary complete switchgears, which are designed for one-way maintenance. The cameras are divided into three compartments. In the upper compartment of the chamber, busbars and a bus disconnector are openly placed, in the middle compartment there is a VMG type switch or load switch, or fuses and disconnectors, in the lower compartment there is a linear disconnector, cable funnel and current transformers of the TZ type. The upper and lower doors are located on the facade of the chamber (see, for example, Konyukhova EA, Power supply of objects. M: Mastery, 2002, p. 102).

The closest to the invention for all objects in essence and the achieved result is a method of power supply to the object and a power supply network, including the construction of a distribution substation, attached to an existing industrial building, or placed in a separate room inside an existing object, for example, between columns in the workshop, or performed freestanding with switchgear chambers (see ibid., pp. 114-116, Fig. 7.11b).

The objective of the present invention for all objects is to increase the cost-effectiveness of power supply to a constructed or reconstructed structure, a complex of structures, a settlement, a microdistrict, a city district, an industrial, agro-industrial complex, and a megalopolis while ensuring high reliability, reducing accident rate and ensuring uninterrupted operation of all power supply sections, and also reducing the complexity of installation and operation of the power supply network of a constructed or reconstructed structure a complex, a complex of buildings, a settlement, a microdistrict, a city district, an industrial, agro-industrial complex, megalopolis, while ensuring reliability and durability, improving service conditions and making it possible to optimally use the area for erecting distribution points of various sizes and connecting others to power systems, including constructed or reconstructed facilities or replacement in emergency situations with the same volume unit.

The task in terms of the method of power supply of the erected or reconstructed structure, the complex of structures is solved due to the fact that the method provides for the separate laying of power cable lines from at least two independent power sources spaced apart, installation of a block distribution point on a previously prepared foundation in the form at least one insulated transportable module protected from atmospheric precipitation in the form of a factory-ready volume block with a ratio of the lengths of pairs of opposite external walls of 1.0-1.45, with at least two sections of cells mounted in it with a uniform load distribution of consumers across sections of switching equipment and protection devices, or at least part the specified equipment is mounted after installing the volume unit on the foundation, and the volume unit is mounted with the possibility of subsequent reuse by removing from the foundation, moving and connecting to power systems other, including constructed or reconstructed facilities or replacement in emergency situations with the same building block.

A block distribution point can be connected to at least two sources of constant power supply through corresponding cable lines and configured to connect to at least two additional sources of electricity from standby power centers also through corresponding cable lines and the ability to connect at least , four outlet cable lines, in each section four output cells are mounted in series, at least two input cells, a cell for the transformer auxiliary needs 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 the output and input cells are equipped with current transformers for measuring phase current and for measuring the earth fault current, input, output cells and cells under transformers they provide maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as protection against earth faults with no depending on the time delay with the effect on the signal, while the above cells of the same functional purpose in different sections perform the same type in pairs and place the same type of cells in the volume unit mirror symmetrically with respect to one of the two middle vertical planes of the volume unit, in addition, in one of of sections, place the cell of the sectional switch, and in another section symmetrically to this cell relative to the same plane of the volumetric block, set the cell of the sectional disconnector, which are trically connected to the cell of the sectional switch, and the cells are installed in the volumetric block with the formation of passages predominantly symmetrical with respect to the same average vertical plane along the external walls of the volumetric block facing these cells, while the cell of the sectional switch is made with the device of maximum current protection against interphase a short circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device, which contains t elements of disconnecting the power supply input 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 in this section below a certain level in one, two or three phases, a blocking system when the device for maximum current protection of the cable power input is working power lines 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 cable power input power transmission line to the emergency section, manual reset devices after automatic operation, as well as control keys for two positions of automatic input of the backup power supply “input” - “output”, which are installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch when any position of the trolley of the disconnected input switch, and the block distribution point is equipped with telemechanization systems, including telecontrol systems, signaling and telemetry: the positions of the cable line switches, power transformers and the sectional circuit breaker for ground faults, the connection of higher voltage cable lines, the presence of voltage on the buses of each section, the malfunction in operational circuits, with the possibility of executing remote control commands of the power switch in each section , including TV and TV shutdowns and TV measurement systems for load currents of cable lines, power transformers and a sectional voltage switch and the sections.

As auxiliary transformers for a down-conversion of higher-voltage energy, mainly 10 kV, into lower-voltage electricity, mainly 0.4 kV, they can use mainly dry transformers with a capacity of 40 kV · A, each with a voltage of 10 ± 2 × 2 , 5% / 0.4 kV.

A block distribution point can be made of two or more transportable modules, each of which is made in the form of a volume block, the base being prepared for all transportable modules forming a block distribution point, while each volume block is made mainly of a metal frame, insulated external walls , an insulated ceiling, floor, roof, and at least one safe metal door, and the foundation for each volume unit is formed by making n of the volumetric block and at least between one pair of opposite external walls of its trenches expanding upwards, performing in the trenches a compacted sand cushion on which reinforced concrete belts bearing the armor belt are concreted, followed by installation of the foundation blocks with the required strength of less than the concrete the width of reinforced concrete tapes with the location of the upper surface of the foundation blocks at zero ground level, backfilling the trench and performing reinforcement on the top of the foundation blocks a cement-sand screed, after the strength has been set, a volume block is installed based on the screed, and one of the reinforced concrete tapes forming an arm belt, parallel to one pair of opposite external walls of the volume block, is placed along one of the two middle vertical planes of the volume block, and the rest tapes parallel to this plane - at equal distances from each other, in the floor of each volume unit form at least two technological openings for passing the corresponding cable x lines and between the foundation blocks - underground, limited its walls.

The outer walls of the volumetric block can be 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 profiled metal sheets are interconnected by combined rivets.

As regards the method of power supply to a settlement, microdistrict, city district, industrial, agro-industrial complex, megalopolis, the problem is solved due to the fact that it involves laying new, including at least partially replacing existing, or additional power supply lines or power lines and distribution networks of power supply for a settlement, microdistrict, city district, industrial, agricultural complex, metropolis with the construction of a block of the distribution point from the transportable module in the form of at least one volume unit with a length ratio of one and the other pairs of opposite external walls of 1.0-1.45, with at least two cell sections mounted in it with uniform distribution of the load of consumers across sections with switching equipment and protection devices, or at least part of the specified equipment is mounted after the unit is installed on the foundation, and the volumetric unit is mounted with the possibility of subsequent repeated use by removing from the foundation, moving and connecting others in the power supply systems, including as part of new or partially replacing existing or additional power supply lines or power and distribution power supply networks of a settlement, microdistrict, city district, industrial or agro-industrial complex, metropolis.

A block distribution point can be connected to at least two sources of constant power supply through corresponding cable lines and configured to connect to at least two additional sources of electricity from standby power centers also through corresponding cable lines and the ability to connect at least , four outlet cable lines, in each section four output cells are mounted in series, at least two input cells, a cell for the transformer auxiliary needs 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 the output and input cells are equipped with current transformers for measuring phase current and for measuring the earth fault current, input, output cells and cells under transformers they provide maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as protection against earth faults with no depending on the time delay with the effect on the signal, while the above cells of the same functional purpose in different sections perform the same type in pairs and place the same type of cells in the volume unit mirror symmetrically with respect to one of the two middle vertical planes of the volume unit, in addition, in one of of sections, place the cell of the sectional switch, and in another section symmetrically to this cell relative to the same plane of the volumetric block, set the cell of the sectional disconnector, which are trically connected to the cell of the sectional switch, and the cells are installed in the volumetric block with the formation of passages predominantly symmetrical with respect to the same average vertical plane along the external walls of the volumetric block facing these cells, while the cell of the sectional switch is made with the device of maximum current protection against interphase a short circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device, which contains t elements of disconnecting the power supply input 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 in this section below a certain level in one, two or three phases, a blocking system when the device for maximum current protection of the cable power input is working power lines to the emergency section, the system for automatically turning on the sectional switch from the block contacts of the input switch without time delay after disconnecting the power input cable power transmission line to the emergency section, manual reset devices after automatic operation, as well as control keys for two positions of automatic input of the backup power supply “input” - “output”, which are installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch when any position of the trolley of the disconnected input switch, and the block distribution point is equipped with telemechanization systems, including telecontrol systems, signaling and telemetry: the positions of the cable line switches, power transformers and the sectional circuit breaker for ground faults, the connection of higher voltage cable lines, the presence of voltage on the buses of each section, the malfunction in operational circuits, with the possibility of executing remote control commands of the power switch in each section , including TV and TV shutdowns and TV measurement systems for load currents of cable lines, power transformers and a sectional voltage switch and the sections.

As auxiliary transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly 0.4 kV, they can mainly use dry transformers with a capacity of 40 kV · A, each with a voltage of 10 ± 2 × 2.5 % / 0.4 kV.

A block distribution point can be made of two or more transportable modules, each of which is made in the form of a volume block, the base being prepared for all transportable modules forming a block distribution point, while each volume block is made mainly of a metal frame, insulated external walls , an insulated ceiling, floor, roof, and at least one safe metal door, and the foundation for each volume unit is formed by making n of the volumetric block and at least between one pair of opposite external walls of its trenches expanding upwards, performing in the trenches a compacted sand cushion on which reinforced concrete belts bearing the armor belt are concreted, followed by installation of the foundation blocks with the required strength of less than the concrete the width of reinforced concrete tapes with the location of the upper surface of the foundation blocks at zero ground level, backfilling the trench and performing reinforcement on the top of the foundation blocks a cement-sand screed, after the strength has been set, a volume block is installed based on the screed, and one of the reinforced concrete tapes forming an arm belt, parallel to one pair of opposite external walls of the volume block, is placed along one of the two middle vertical planes of the volume block, and the rest tapes parallel to this plane - at equal distances from each other, in the floor of each volume unit form at least two technological openings for passing the corresponding cable x lines and between the foundation blocks - underground, limited its walls.

The outer walls of the volumetric block can be 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 profiled metal sheets are interconnected by combined rivets.

The task in the power supply network of a constructed or reconstructed structure, a complex of structures is solved due to the fact that it contains supply lines for connecting at least two independent power sources geographically separated, at least one block distribution point installed on the foundation - a transportable module in the form volume unit, one pair of opposite outer walls of which has a length of 1.0-1.45 the length of the opposite outer walls of another pair, with mounted in it, by at least two sections of cells with a uniform load distribution of consumers across sections of switching equipment and protection devices, some of which in different sections are made in pairs of the same type for functional purpose and placed mirror symmetrically with respect to one of the two middle vertical planes of the volume unit, sections of cells are mounted with the formation, mainly symmetrical with respect to the same plane of the volumetric block of passages along the outward facing them walls of the volumetric block.

The network can be configured to connect to at least two additional sources of electricity from standby power centers also through the corresponding cable lines and connect at least four cable outlet lines, with four output cells connected in series to each section, at least at least two input cells, a cell for an auxiliary transformer and a cell for a voltage transformer to control and measure the voltage on the sections and ensure the operation of automatic and 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, and, in addition, in one section there is a section switch cell, and in the other section symmetrically to a section switch cell relative to one of two middle vertical planes there is a cell of a sectional disconnector electrically connected to the cell of the sectional switch, while the input, output cells and cells for transformers are equipped with With maximum current protection against interphase short circuit with an independent time delay with a trip action, as well as protection against earth faults with an independent time delay with an action on a signal, the section switch cell is designed with a 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 that contains elements for disconnecting the power input of a cable power line Achi 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 when the device is used for overcurrent protection of the power input of the cable power line to the emergency section, system automatic inclusion of the sectional switch from the block contacts of the input switch without time delay after disconnecting the power input of the cable power line to the emergency section, manual devices return to the initial position after automatic operation, as well as control keys for two positions of automatic input of the backup power supply “input” - “output” installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch for any position of the truck disconnected input switch, and block distribution the station is equipped with telemechanization systems, including telecontrol, tele-alarm and telemetry systems: positions of the cable line switches, power output transformers and a sectional switch, ground faults, on connecting cable lines of higher voltage, voltage on the buses of each section, malfunctions in operational circuits with the possibility of executing telecontrol commands by a power switch in each section, including television switching and TV disconnecting and systems Telemeasurement of load currents of cable lines, power transformers and sectional voltage switch on sections.

As transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kV · A each with a voltage of 10 ± 2 × 2.5% / can be used 0.4 kV.

The power supply network can be made on the basis of two or more transportable modules, each of which is made in the form of a volume unit.

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 “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 profiled metal sheets are interconnected by combined rivets.

The foundation on which the volumetric block is mounted can be made in the form of a buried in soil, located in a trench expanding upward on a compacted sand cushion of a supporting armopoiet, 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 of which, as well as foundation blocks installed on the armored belt, also buried in the ground, with a width smaller than the armored belt width, and made on top of the foundation blocks at the day mark the surface of the reinforced cement-sand screed, and in the trench over the sand cushion there is a soil backfill to the bottom of the foundation blocks, and underground walls are formed between the foundation blocks, one of the reinforced concrete tapes forming an armored belt parallel to one pair of opposing walls of the volume block along one of the two middle vertical planes of the volumetric block, and the remaining tapes parallel to this plane - at equal distances from each other.

As regards the power supply network of a settlement, microdistrict, city district, industrial, agro-industrial complex, megalopolis, the problem is solved due to the fact that it contains supply lines for connecting loads from at least two independent power supplies, at least one independent a block distribution point installed on the foundation - a factory-ready transportable module in the form of at least one volume unit with the ratio of the lengths of pairs of opposite external walls, comprising 1.0-1.45, with at least two sections of cells mounted in it, providing uniform distribution of consumer load across sections of switching equipment and protection devices, some of which in different sections can be made in pairs of the same type for functional purpose and can be placed mirror symmetrically with respect to one of the two middle vertical planes of the volumetric block, and cell sections can be mounted with the formation, mainly, symmetric flax of the same plane of the volumetric block of passages along the outer walls of the volumetric block facing them.

The power supply network can be configured to connect to at least two additional sources of electricity from the backup power centers via the corresponding cable lines and connect at least four cable outlet lines, with four output cells connected in series to each section at least two input cells, a cell for an auxiliary transformer and a cell for a voltage transformer to control and measure the voltage on the sections and ensure the operation of 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, and, in addition, a section switch cell is located in one section and symmetrically relative to the section switch cell in the other section one of the two middle vertical planes contains a cell of a sectional disconnector, electrically connected to the cell of the sectional switch, while input, output cells and cells for trans the formators are equipped with maximum current protection against interphase short circuit with an independent delay time with a trip action, as well as protection against earth faults with an independent time delay with an action on a signal, the section switch cell is made with a device for maximum current protection against interphase short circuit with an independent exposure time with a shutdown action, as well as with an automatic backup power input device that contains elements for disconnecting the power input of cable l power transmission lines to the emergency section with adjustable time delay from 0 to 20 s when the voltage in this section disappears or decreases below a certain level in one, two or three phases, a blocking system during operation of the overcurrent protection device for inputting power to 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 of the cable power line to the emergency section, manual reset to the initial position after automatic operation, as well as control keys for two positions of automatic input of the backup power supply “input” - “output” installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch for any position of the truck disconnected input switch, and the block distribution point is equipped with telemechanization systems, including remote control systems, telealarm systems and telemetry: the position of the circuit breakers white lines, power transformers and a sectional switch, ground faults, on connecting cable lines of higher voltage, voltage on the buses of each section, malfunctions in operational circuits with the possibility of executing telecontrol commands for the power switch in each section, including TV and tele-shutdowns and telemetry systems for load currents of cable lines, power transformers and sectional voltage circuit breakers in sections.

As transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kV · A each with a voltage of 10 ± 2 × 2.5% / can be used 0.4 kV.

The power supply network can be made on the basis of two or more transportable modules, each of which is made in the form of a volume unit.

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 “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 profiled metal sheets are interconnected by combined rivets.

The foundation on which the volumetric block is mounted can be made in the form of a buried in soil, located in a trench expanding upward on a compacted sand cushion of a supporting armopoiet, 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 of which, as well as foundation blocks installed on the armored belt, also buried in the ground, with a width smaller than the armored belt width, and made on top of the foundation blocks at the day mark the surface of the reinforced cement-sand screed, and in the trench over the sand cushion there is a soil backfill to the bottom of the foundation blocks, and underground walls are formed between the foundation blocks, one of the reinforced concrete tapes forming an armored belt parallel to one pair of opposing walls of the volume block along one of the two middle vertical planes of the volumetric block, and the remaining tapes parallel to this plane - at equal distances from each other.

The technical result provided by all objects of the invention is to increase 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 placement of equipment in them, taking into account their functional purpose, adopted system and mounting sequence, as well as the sequence and relative position of cells in the volume units, compactness p spredelitelnogo point and accelerate its commissioning by reducing the amount of work produced on the site of the construction, including by optimizing the design of the foundation on which the room unit is set.

The invention is illustrated by drawings, where figure 1 shows a block distribution point in the plan;

figure 2 is the same, a view along aa in figure 1;

figure 3 is the same, a view along BB in figure 1;

figure 4 is the same circuit diagram of the power supply;

figure 5 is the same, the layout of the cables;

figure 6 is the same, grounding;

Fig.7 is the same, the layout of the foundation in the plan;

in Fig.8 is a section along bb in Fig.7;

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

figure 10 - node D in figure 8 and figure 9;

figure 11 - layout of the armo-belt in the plan;

on Fig - section E-E in Fig.11;

on Fig - arrangement of the foundation blocks in the plan;

on Fig - layout in terms of reinforced cement-sand screed;

on Fig - section FJ in Fig. 14.

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

One pair of opposing outer walls 2 of the volume unit 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.

At least in one 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, cells 12, 13 and 21, 22 for transformers located in cells 4 and 5, respectively. 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 the same type and placed mirror symmetrically with respect 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, 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 with respect 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 the section 4 of the end face 25 of the volume unit, a telemechanics terminal box 29, a lighting, heating and ventilation panel 30, auxiliary supply cabinet 31, alarm circuits and a device for finding the “earth” 32 are mounted, and a telemechanization device 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 supply 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, 11 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 automatic input operation 42 backup power between sections 4 and 5 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, 11 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 earth faults with an independent time delay with an 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 42 backup power supply.

The automatic backup power input device 42 contains elements (not shown) for disconnecting the power input 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 input 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, devices (not shown) manual reset to the initial position after automatic operation, as well as control keys (not shown) for two positions of automatic input of backup power “entered” - “displayed”, installed e on the input cells 10, 11 and 19, 20 to ensure the principle of continuity of the control circuit of the section 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.

The telealarm system provides the positions of the cable line switches, power transformers and the section switch, ground faults, the connection of higher voltage cable lines, the presence of 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, each with a voltage of 10 ± 2 × 2.5% / 0, are 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 load-bearing arm belt 48 formed by reinforced concrete tapes 49 located along the perimeter of the outer walls 2, 3 of volumetric block 1 and in parallel of at least one pair of 3 opposite of them, as well as of foundation blocks 50, which are also buried in the ground, and are also buried in the ground foundation blocks 50 with a width smaller than the width of armopoyas 48 and made on top of the foundation blocks 50 etke day surface of 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 underground 53 with the 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 along 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 mainly 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 external walls are made of three-layer metal panels of the “sandwich” type 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 method of power supply of a constructed or reconstructed structure, a complex of structures, is as follows:

Separately lay supply cable lines 38 from geographically spaced at least two independent power sources 37. They are installed on a previously prepared foundation 45 of a block distribution point in the form of at least one insulated transportable module protected from atmospheric precipitation in the form of a prefabricated volume unit 1 with a parity of lengths of pairs of opposite external walls 2 and 3 of 1.0 -1.45 . In the volume unit 1, at least two sections of 4 and 5 cells are mounted with a uniform load distribution of consumers across sections of switching equipment and protection devices. Or, at least part of the specified equipment is mounted after installing the volume unit 1 on the foundation 45.

The volume unit 1 is mounted with the possibility of subsequent reuse by removing it from the foundation 45, moving and connecting others, including constructed or reconstructed objects in power supply systems, or replacing it in emergency situations with the same volume unit 1.

The block distribution point is connected to at least two sources of constant power supply 37 through the corresponding cable lines 38 and is configured to connect to at least two additional sources of electric power 40 from the backup power centers also through the corresponding cable lines 41 and the possibility of connection, at least four outlet cable lines 39.

In each section 4 and 5, four output cells 6–9 and 15–18 are successively mounted, respectively, at least two input cells, respectively 10, 11 and 19, 20, cell 12 and 21 for the auxiliary transformer and cell 13 and 23 under voltage transformer for monitoring and measuring voltage on sections 4 or 5 and ensuring the operation of automatic input 42 backup power between sections 4 and 5.

Output 6-9 and 15-18 and input 10, 11 and 19, 20 cells are equipped with current transformers 43 for measuring phase current and for measuring the earth fault current. Input 10, 11 and 19, 20, output 6-9 and 15-18 cells and cells 12, 21 and 13, 23 for transformers provide maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as protection against earth faults with an independent time delay with action on the signal (not shown).

The above-mentioned cells of the same functional purpose in different sections 4 and 5 are performed in pairs of the same type and place the same type of cells in the volumetric block mirror symmetrically with respect to one of the two middle vertical planes 26 of the volumetric block 1.

In one of the sections, the cell 14 of the sectional switch 44 is placed, and in the other section symmetrically to this cell relative to the same plane of the volumetric block, the cell 23 of the sectionalizer is installed, which is electrically connected to the cell 14 of the sectional switch 44.

Cells 6-23 are installed in the volumetric block 1 with the formation, mainly symmetrical with respect to the same average vertical plane 26 of its passages 28 along the outer walls 2 of the volumetric block 1 facing these cells.

The cell 14 of the sectional switch 44 is performed with a device of maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as with a device for automatically entering backup power. The automatic backup power input device contains elements (not shown) for disconnecting the power input of the cable power line to the emergency section 4 and 5 with adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section 4 and 5 below a certain level in one, two or three phases. The backup power input automatic input device also includes a blocking system (not shown) during operation of the overcurrent protection device of the cable power line input for the emergency section 4 and 5, a system for automatically turning on the section switch 44 from the input contacts of the input switch without delaying after the power input is turned off cable power lines to emergency section 4 and 5. There are also devices (not shown) for manual reset to the initial position after automatic triggering key, as well as control keys (not shown) for two positions of automatic input of backup power supply “input” - “output”, which are installed on the input cells 10, 11 and 19, 20 to ensure the principle of continuity of the control circuit of the section switch 44 at any position of the trolley disconnected input switch.

The block distribution point is equipped with telemechanization systems, including remote control, tele-signaling and telemetry systems: the positions of the cable line switches, power transformers and the sectional ground circuit breaker, the connection of higher voltage cable lines, the voltage on the buses of each section 4 and 5, malfunctions in operational circuits. It is possible to execute telecontrol commands by 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 sections.

As auxiliary transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kV · A, each with a voltage of 10 ± 2 × 2.5%, are used / 0.4 kV.

A block distribution point is made of two or more transportable modules, each of which is made in the form of a volume unit 1, the base being prepared for all transportable modules forming a block distribution point, while each volume block 1 is made mainly of a metal frame (not shown ), insulated external walls 2 and 3, insulated ceiling 56, floor 57, roof 58 and at least one safe metal door 59. The foundation 45 for each volume unit is formed by performing in run along the contour of walls 2 and 3 of the volumetric block 1 and at least between one pair of opposite external walls 3 of its trenches expanding upwards, performing in the trenches a compacted sand cushion 47 on which reinforced concrete belts 49 forming the armor belt 48 are concreted. After concrete casting of required strength, foundation blocks 50 are installed on them with a width smaller than the width of reinforced concrete tapes with the location of the upper surface of the foundation blocks 50 at zero ground level. Then, backfill 52 of the trench 46 is carried out and reinforced cement-sand screed 51 is installed on the top of the foundation blocks 50. After the cement-sand screed 51 has set strength, a volume block 1 is mounted on it. One of the reinforced concrete tapes 49 forming an armored belt 48 located in parallel one pair of opposing outer walls 3 of the volume unit 1, is placed along one of the two middle vertical planes 55 of the volume unit 1. The remaining tapes 49, parallel to this plane 55, are at equal distances from each other. At least two technological openings 60 are formed in the floor of each volume unit 1 for passing through the corresponding cable lines. Between the foundation blocks 50 form an underground limited by the walls 2 and 3 of the volume block 1.

The outer walls 2 and 3 of the volume unit 1 are made of three-layer metal panels of the “sandwich” type with a heater (not shown), preferably polyurethane foam, with environmentally friendly two-sided painting. The roof 58 is preferably made of profiled metal sheets with zinc or aluminum-zinc coating and a layer of non-combustible insulation (not shown in the drawings). Moreover, the profiled metal sheets are interconnected by combined rivets (not shown).

The method of power supply of a settlement, microdistrict, city district, industrial, agro-industrial complex, metropolis, is carried out as follows:

When laying new, including at least partially replacing existing, or additional supply lines, or supply and distribution networks for power supply of a settlement, microdistrict, city district, industrial, agro-industrial complex, metropolis, 45 block distribution points are erected on a previously prepared foundation from a transportable module in the form of at least one volume unit 1.

The volumetric block 1 has a ratio of the lengths of one 2 and the other pairs 3 of opposite external walls, which is 1.0-1.45, respectively. The volumetric block 1 is installed with at least two sections 4 and 5 of cells 6-23 mounted in it, ensuring uniform distribution of the load of consumers over sections 4 and 5 of switching equipment and protection devices. Or, at least part of the specified equipment is mounted after installing block 1 on the foundation 45.

The volume unit 1 is mounted with the possibility of subsequent reuse by removing from the foundation 45, moving and connecting others in the power supply systems, including as part of new or partially replacing existing or additional power supply lines or power and distribution power supply networks of a settlement, microdistrict, district city, industrial or agricultural complex, megalopolis.

The block distribution point is connected to at least two sources of constant power supply 37 through the corresponding cable lines 38 and is configured to connect to at least two additional sources of electric power 40 from the backup power centers also through the corresponding cable lines 41 and the possibility of connection, at least four outlet cable lines 39.

In each section 4 and 5, four output cells 6–9 and 15–18 are successively mounted, respectively, at least two input cells, respectively 10, 11 and 19, 20, cell 12 and 21 for the auxiliary transformer and cell 13 and 23 under voltage transformer for monitoring and measuring voltage on sections 4 or 5 and ensuring the operation of automatic input 42 backup power between sections 4 and 5.

Output 6-9 and 15-18 and input 10, 11 and 19, 20 cells are equipped with current transformers 43 for measuring phase current and for measuring the earth fault current. Input 10, 11 and 19, 20, output 6 -9 and 15 -18 cells and cells 12, 21 and 13, 23 for transformers provide maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as protection against earth faults with an independent time delay with action on the signal (not shown).

The above-mentioned cells of the same functional purpose in different sections 4 and 5 are performed in pairs of the same type and place the same type of cells in the volumetric block mirror symmetrically with respect to one of the two middle vertical planes 26 of the volumetric block 1.

In one of the sections, the cell 14 of the sectional switch 44 is placed, and in the other section symmetrically to this cell relative to the same plane of the volumetric block, the cell 23 of the sectionalizer is installed, which is electrically connected to the cell 14 of the sectional switch 44.

Cells 6-23 are installed in the volumetric block 1 with the formation, mainly symmetrical with respect to the same average vertical plane 26 of its passages 28 along the outer walls 2 of the volumetric block 1 facing these cells.

The cell 14 of the sectional switch 44 is performed with a device of maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as with a device for automatically entering backup power. The automatic backup power input device contains elements (not shown) for disconnecting the power input of the cable power line to the emergency section 4 and 5 with adjustable time delay from 0 to 20 s when the voltage disappears or decreases in this section 4 and 5 below a certain level in one, two or three phases. The backup power input automatic input device also includes a blocking system (not shown) during operation of the overcurrent protection device of the cable power line input for the emergency section 4 and 5, a system for automatically turning on the section switch 44 from the input contacts of the input switch without delaying after the power input is turned off cable power lines to emergency section 4 and 5. There are also devices (not shown) for manual reset to the initial position after automatic triggering key, as well as control keys (not shown) for two positions of automatic input of backup power supply “input” - “output”, which are installed on the input cells 10, 11 and 19, 20 to ensure the principle of continuity of the control circuit of the section switch 44 at any position of the trolley disconnected input switch.

The block distribution point is equipped with telemechanization systems, including remote control, tele-signaling and telemetry systems: the positions of the cable line switches, power transformers and the sectional ground circuit breaker, the connection of higher voltage cable lines, the voltage on the buses of each section 4 and 5, malfunctions in operational circuits. It is possible to execute telecontrol commands by 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 sections.

As auxiliary transformers for down-converting high-voltage energy, mainly 10 kV, into low-voltage electricity, mainly 0.4 kV, mainly dry transformers with a capacity of 40 kV · A, each with a voltage of 10 ± 2 × 2.5%, are used / 0.4 kV.

A block distribution point is made of two or more transportable modules, each of which is made in the form of a volume unit 1, the base being prepared for all transportable modules forming a block distribution point, while each volume block 1 is made mainly of a metal frame (not shown ), insulated external walls 2 and 3, insulated ceiling 56, floor 57, roof 58 and at least one safe metal door 59. The foundation 45 for each volume unit is formed by performing in run along the contour of walls 2 and 3 of the volumetric block 1 and at least between one pair of opposite external walls 3 of its trenches expanding upwards, performing in the trenches a compacted sand cushion 47 on which reinforced concrete belts 49 forming the armor belt 48 are concreted. After concrete casting of required strength, foundation blocks 50 are installed on them with a width smaller than the width of reinforced concrete tapes with the location of the upper surface of the foundation blocks 50 at zero ground level. Then, backfill 52 of the trench 46 is carried out and reinforced cement-sand screed 51 is installed on the top of the foundation blocks 50. After the cement-sand screed 51 has set strength, a volume block 1 is mounted on it. One of the reinforced concrete tapes 49 forming an armored belt 48 located in parallel one pair of opposing outer walls 3 of the volume unit 1, is placed along one of the two middle vertical planes 55 of the volume unit 1. The remaining tapes 49, parallel to this plane 55, are at equal distances from each other. At least two technological openings 60 are formed in the floor of each volume unit 1 for passing through the corresponding cable lines. Between the foundation blocks 50 form an underground limited by the walls 2 and 3 of the volume block 1.

The outer walls 2 and 3 of the volume unit 1 are made of three-layer metal panels of the “sandwich” type with a heater (not shown), preferably polyurethane foam, with environmentally friendly two-sided painting. The roof 58 is preferably made of profiled metal sheets with zinc or aluminum-zinc coating and a layer of non-combustible insulation (not shown in the drawings). Moreover, the profiled metal sheets are interconnected by combined rivets (not shown).

The power supply network of a constructed or reconstructed structure, complex of structures contains supply lines for connecting at least two independent power sources 37, at least one block distribution point installed on the foundation 45 - a transportable module in the form of a volume unit 1. One pair of opposite external the walls 2 of the volume unit 1 has a length of 1.0 -1.45 the length of the opposite outer walls 3 of another pair. At least two sections 4 and 5 of cells 6-23 are mounted in the volumetric block, ensuring uniform load distribution of consumers among sections 4 and 5 of switching equipment and protection devices. Part of the equipment in different sections 4 and 5 is made in pairs of the same type for functional purpose and placed mirror symmetrically with respect to one of the two middle vertical planes 26 of the volume unit 1. Sections 4 and 5 of cells 6-23 are mounted with the formation, mainly symmetrical with respect to the same plane 26 of the volume block 1 of the passages 28 along the outer walls 2 of the volume block 1 facing them.

The power supply network is configured to connect to at least two additional sources of electricity 40 from the standby power centers also through the corresponding cable lines 41 and connect at least four outgoing cable lines 39.

In each section 4 and 5, four output cells 6-9 and 15-18 are mounted in series, at least two input cells 10, 11 and 19, 20, a cell 12 and 21 for an auxiliary transformer and a cell 13 and 22 for a voltage transformer for monitoring and measuring voltage on sections 4 and 5 and ensuring the operation of automatic input 42 backup power between sections 4 and 5.

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.

In one section 4, the cell 14 of the sectional switch 44 is located, and in the other section 5, symmetrically to the cell 14 of the sectional switch 44 relative to one of the two middle vertical planes 26, the cell 23 of the sectionalizer is electrically connected to the cell 14 of the sectional switch 44.

Input 10, 11 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 earth faults with an independent time delay with an 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 42 backup power supply.

The automatic backup power input device 42 contains elements (not shown) for disconnecting the power input 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 input 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, devices (not shown) manual reset to the initial position after automatic operation, as well as control keys (not shown) for two positions of automatic input of backup power “entered” - “displayed”, installed located on the input cells 10, 11 and 19, 20 to ensure the principle of continuity of the control circuit of the section switch 44 at any position of the trolley of the disconnected input switch (not shown).

The block distribution point is equipped with telemechanization systems 33, including remote control systems, tele-signaling and telemetry.

The telealarm system provides the positions of the cable line switches, power transformers and the section switch, ground faults, the connection of higher voltage cable lines, the presence of 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, each with a voltage of 10 ± 2 × 2.5% / 0, are used , 4 kV.

The power supply network is based on two or more transportable modules, each of which is made in the form of a volume unit 1.

Each volume unit 1 consists mainly 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 external walls are made of three-layer metal panels of the “sandwich” type 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 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 load-bearing arm belt 48 formed by reinforced concrete tapes 49 located along the perimeter of the outer walls 2, 3 of volumetric block 1 and in parallel of at least one pair of 3 opposite of them, as well as of foundation blocks 50, which are also buried in the ground, and are also buried in the ground foundation blocks 50 with a width smaller than the width of armopoyas 48 and made on top of the foundation blocks 50 etke day surface of 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 underground 53 with the 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 along 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.

The power supply network of a settlement, microdistrict, city district, industrial, agro-industrial complex, megalopolis contains supply lines for connecting loads from at least two independent power sources 37, at least one block distribution point installed on the foundation 45 - a transportable module prefabrication in the form of at least one building block 1 with the ratio of the lengths of pairs of opposite external walls 2 and 3, respectively 1.0-1.45. At least two sections 4 and 5 of cells 6-23 are mounted in volume unit 1 with a uniform load distribution of consumers across sections 4 and 5 of switching equipment and protection devices, some of which in different sections 4 and 5 are made in pairs of the same functional purpose for mutual reservation of sections 4 and 5.

The power supply network is configured to connect to at least two additional sources of electricity 40 from the standby power centers also through the corresponding cable lines 41 and connect at least four outgoing cable lines 39.

In each section 4 and 5, four output cells 6–9 and 15–18 are mounted in series, at least two input cells 10, 11 and 19, 20, a cell 12 and 21 for an auxiliary transformer, and a cell 13 and 22 for a voltage transformer to control and measure the voltage on sections 4 and 5 and to ensure the operation of automatic input 42 backup power between sections 4 and 5.

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.

In one section 4, the cell 14 of the sectional switch 44 is located, and in the other section 5, symmetrically to the cell 14 of the sectional switch 44 relative to one of the two middle vertical planes 26, the cell 23 of the sectionalizer is electrically connected to the cell 14 of the sectional switch 44.

Input 10, 11 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 earth faults with an independent time delay with an 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 42 backup power supply.

The automatic backup power input device 42 contains elements (not shown) for disconnecting the power input 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 input 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, devices (not shown) manual reset to the initial position after automatic operation, as well as control keys (not shown) for two positions of automatic input of backup power “entered” - “displayed”, installed cells on input 10, 11 and 19, 20 for ensuring the continuity at any position of the principle of the control circuit section switch trolley 44 disconnected input switch (not shown).

The block distribution point is equipped with telemechanization systems 33, including remote control systems, tele-signaling and telemetry.

The telealarm system provides the positions of the cable line switches, power transformers and the section switch, ground faults, the connection of higher voltage cable lines, the presence of 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, each with a voltage of 10 ± 2 × 2.5% / 0, are used , 4 kV.

The power supply network is based on two or more transportable modules, each of which is made in the form of a volume unit 1.

Each volume unit 1 consists mainly 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 external walls are made of three-layer metal panels of the “sandwich” type 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 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 load-bearing arm belt 48 formed by reinforced concrete tapes 49 located along the perimeter of the outer walls 2, 3 of volumetric block 1 and in parallel of at least one pair of 3 opposite of them, as well as of foundation blocks 50, which are also buried in the ground, and are also buried in the ground foundation blocks 50 with a width smaller than the width of armopoyas 48 and made on top of the foundation blocks 50 etke day surface of 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 underground 53 with the 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 opposite walls 3 of the volume unit 1 is placed along one of the two middle vertical planes 55 of the volume unit 1, and the remaining tapes 49 parallel to this plane 55 are equally spaced from friend.

Claims (24)

1. The method of power supply of the erected or reconstructed structure, the complex of structures, characterized in that it provides for separate laying of power cable lines from at least two independent power sources spaced apart, installation of at least one block distribution point on a previously prepared foundation insulated transportable module protected from atmospheric precipitation in the form of a prefabricated volume block with the ratio of the lengths of the pairs against adjacent outer walls, comprising 1.0-1.45, with at least two sections of cells mounted in it, providing uniform distribution of consumer load across sections, switching equipment and protection devices, while part of the specified equipment is mounted after the installation of the volume unit on the foundation, and the volume unit is mounted with the possibility of subsequent reuse by removing from the foundation, moving and connecting others to the power supply systems, including those being built or reconstructed objects or replacements in emergency situations with the same volumetric unit. 2. The method according to claim 1, characterized in that the block distribution point is connected to at least two sources of constant power supply through the corresponding cable lines and is configured to connect to at least two additional sources of electricity from standby power centers through the appropriate cable lines and the ability to connect at least four outlet cable lines, in each section, four output cells, at least two input cells, are sequentially mounted cells, a cell for an auxiliary transformer and a cell for a voltage transformer to control and measure the voltage on the sections and ensure the operation of automatic input of backup power between the sections, and the output and input cells are equipped with current transformers for measuring the phase current and for measuring the earth fault current, , output cells and cells for transformers provide maximum current protection against interphase short circuit with an independent time delay with a trip effect, as well as protection from earth faults with an independent time delay with an action on the signal, while the above cells of the same functional purpose in different sections are performed in pairs of the same type and placed the same type of cells in the volumetric unit are mirror symmetrically relative to one of the two middle vertical planes of the volumetric unit, in addition, in one of the sections the cell of the sectional switch is placed, and in the other section symmetrically to this cell relative to the same plane of the volumetric block, the cell is installed in the section of the disconnector, which is electrically connected to the cell of the sectional switch, and the cells are installed in the volumetric block with the formation of passages mainly symmetrical with respect to the same average vertical plane along the outer walls of the volumetric block facing these cells, while the cell of the sectional switch is made with the maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as with a device for automatic input of cut power supply, which contains the 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 below a certain level in one, two or three phases, the system locks when the device operates at maximum current protection of the power input of the cable power line to the emergency section, the system for automatically turning on the sectional switch from the block contacts of the input switch without delaying after switching off 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 of the backup power supply “input” - “output”, which are installed on the input cells to ensure the principle of continuity of the control circuit section switch at any position of the trolley of the disconnected input switch, and the block distribution point is equipped with telemechanization systems, including system topics of remote control, remote signaling and telemetry: the position of the cable line switches, power transformers and the sectional ground circuit breaker, the connection of higher voltage cable lines, the presence of voltage on the buses of each section, malfunctions in operational circuits, with the possibility of executing remote control commands of the power switch in each section, including TV and TV shutdowns and TV measurement systems for load currents of cable lines, power transformers and sectional section voltage switches. 3. The method according to claim 2, characterized in that dry transformers with a capacity of 40 kVA, each with a voltage of (10 ± 2) · 2, are used as auxiliary transformers for down-converting high-voltage energy of 10 kV to low-voltage electricity of 0.4 kV , 5% / 0.4 kV. 4. The method according to claim 1, characterized in that the block distribution point is made of two or more transportable modules, each of which is made in the form of a volume unit, the base being prepared for all transportable modules forming a block distribution point, each volume block mainly made of metal frame, insulated external walls, insulated ceiling, floor, roof and at least one safe metal door, and the foundation for each volume unit is formed by fillings in the soil along the contour of the walls of the volumetric block and at least between one pair of opposite external walls of its trenches expanding upwards, performing in the trenches a compacted sand cushion on which reinforced concrete belts forming the bearing armoponton are concreted with subsequent installation of the required strength on them after concrete has been set foundation blocks with a width smaller than the width of reinforced concrete tapes with the location of the upper surface of the foundation blocks at zero ground level, backfilling the trench and performing xy of the foundation blocks of a reinforced cement-sand screed, after gaining strength, a volume block is installed based on the screed, and 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, in the floor of each volume unit form at least two technological openings for prop ska respective cable lines, and between the foundation blocks - underground, limited its walls. 5. The method according to claim 4, characterized in that the outer walls of the volumetric block are made of three-layer metal panels of the sandwich type with a heater, preferably made of polyurethane foam, with environmentally friendly two-sided coloring, 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. 6. The method of power supply of a settlement, microdistrict, city district, industrial, agro-industrial complex, megalopolis, characterized in that it includes the laying of new, including at least partially replacing existing, or additional lines of the supply network or supply and distribution networks power supply of a settlement, microdistrict, city district, industrial, agro-industrial complex, metropolis with the construction of a preliminary distribution block block distribution nta from a transportable module in the form of at least one volume unit with a length ratio of one and the other pairs of opposite external walls of 1.0-1.45, with at least two cell sections mounted in it, ensuring uniform distribution loads of consumers in sections with switching equipment and protection devices, or at least part of the specified equipment are mounted after the unit is installed on the foundation, and the volumetric unit is mounted with the possibility of subsequent reuse by removing from the foundation, moving and connecting others in the power supply systems, including as part of new or partially replacing existing or additional power supply lines or supply and distribution power supply networks of a settlement, microdistrict, city district, industrial or agricultural complex, megalopolis. 7. The method according to claim 6, characterized in that the block distribution point is connected to at least two sources of constant power supply through corresponding cable lines and is configured to connect to at least two additional sources of electricity from standby power centers through the appropriate cable lines and with the possibility of connecting at least four outlet cable lines, in each section four output cells, at least two input cables are sequentially mounted cells, a cell for an auxiliary transformer and a cell for a voltage transformer to control and measure the voltage on the sections and ensure the operation of automatic input of backup power between the sections, and the output and input cells are equipped with current transformers for measuring the phase current and for measuring the earth fault current, , output cells and cells for transformers provide maximum current protection against interphase short circuit with independent time delay with shutdown action, as well as for shield from earth faults with an independent time delay with an effect on the signal, while the above cells of the same functional purpose in different sections are performed in the same type in pairs and place the same type of cells in the volumetric block mirror symmetrically with respect to one of the two middle vertical planes of the volumetric block, in addition, in one of the sections the cell of the sectional switch is placed, and in the other section symmetrically to this cell relative to the same plane of the volume unit, the cell of the sectional is installed of the disconnector, which is electrically connected to the cell of the sectional switch, and the cells are installed in the volumetric block with the formation of passages mainly symmetrical with respect to the same average vertical plane along the outer walls of the volumetric block facing these cells, while the cell of the sectional switch is made with the maximum current protection against interphase short circuit with an independent time delay with a shutdown action, as well as with an automatic input device the backup power supply, which contains the elements for disconnecting the power input 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 locks when the device operates at maximum current protect the power input of the cable power line to the emergency section, the system for automatically turning on the sectional switch from the contact block of the input switch without delay after switching off 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 of the backup power supply “input” - “output”, which are installed on the input cells to ensure the principle of continuity of the control circuit section switch at any position of the trolley of the disconnected input switch, and the block distribution point is equipped with telemechanization systems, including telecontrol, tele-alarm and telemetry systems: positions of cable line switches, power transformers and a sectional ground-fault circuit breaker, for connecting high-voltage cable lines, the presence of voltage on the buses of each section, malfunctions in operational circuits, with the possibility of executing telecontrol commands for the power switch in each section, including TV and TV shutdowns and TV measurement systems for load currents of cable lines, power transformers and sectional a voltage switch on the sections. 8. The method according to claim 7, characterized in that dry transformers with a capacity of 40 kVA, each with a voltage of (10 ± 2) · 2, are used as auxiliary transformers for down-converting high-voltage energy of 10 kV to low-voltage electricity of 0.4 kV , 5% / 0.4 kV. 9. The method according to claim 6, characterized in that the block distribution point is made of two or more transportable modules, each of which is made in the form of a volume block, the base being prepared for all transportable modules forming a block distribution point, each volume block mainly made of metal frame, insulated external walls, insulated ceiling, floor, roof and at least one safe metal door, and the foundation for each volume unit is formed by fillings in the soil along the contour of the walls of the volumetric block and at least between one pair of opposite external walls of its trenches expanding upwards, performing in the trenches a compacted sand cushion on which reinforced concrete belts forming the bearing armoponton are concreted with subsequent installation of the required strength on them after concrete has been set foundation blocks with a width smaller than the width of reinforced concrete strips, with the top surface of the foundation blocks at zero ground, backfilling the trench and performing rkhu of foundation blocks of a reinforced cement-sand screed, after gaining strength, a volume block is installed based on the screed, and one of the reinforced concrete tapes forming an arm belt, parallel to one pair of opposite external 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, in the floor of each volume unit form at least two technological openings for prop the wire of the corresponding cable lines, and between the foundation blocks there is an underground limited by its walls. 10. The method according to claim 9, characterized in that the outer walls of the volumetric block are made of three-layer metal panels of the "sandwich" type with a heater, preferably made of polyurethane foam, with environmentally friendly two-sided coloring, 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. 11. The power supply network of a constructed or reconstructed structure, a complex of structures, characterized in that it contains supply lines for connecting at least two independent power sources geographically separated, at least one block distribution point installed on the foundation - a transportable module in the form of a volume unit , one pair of opposite outer walls of which has a length of 1.0-1.45 of the length of the opposite outer walls of the other pair, with at least at least two sections of cells with a uniform load distribution of consumers across sections of switching equipment and protection devices, some of which in different sections are made in pairs of the same type for functional purpose and placed mirror symmetrically with respect to one of the two middle vertical planes of the volume unit, and the cell sections are mounted to form predominantly symmetrical about the same plane of the volumetric block of passages along the outer walls of the volumetric block facing them about the block. 12. The power supply network according to claim 11, characterized in that it is configured to connect to at least two additional sources of electricity from the backup power centers also through the corresponding cable lines and connecting at least four outlet cable lines, in each section, four output cells, at least 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 are successively mounted ensuring the operation of 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, in addition, a section switch cell is located in one section and a section switch cell is symmetrical in one section of two middle vertical planes there is a cell of a sectional disconnector, electrically connected to the cell of the sectional switch, with input, output cells and the cells for the transformers are equipped with maximum current protection against interphase short circuit with an independent delay time with a trip effect, as well as protection against earth faults with an independent time delay with a signal action, the cell section switch is made with a maximum current protection against interphase short circuit short-circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device that contains input shutdown elements power supply of the cable power line to the emergency section with 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 locks when the device is used for overcurrent protection of the power input of the cable power line to the emergency section, the system for automatically turning on the sectional switch from the block contacts of the input switch without time delay after disconnecting the power input of the cable power line to emergency section, manual reset devices after automatic actuation, as well as control keys for two positions of automatic input of backup power supply “input” - “output” installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch for any position of the truck circuit breaker input, and the block distribution point is equipped with telemechanization systems, including remote control systems, tele-signaling and telemetry: provisions circuit breakers for cable lines, power transformers and a sectional switch, ground faults, for connecting cable lines of higher voltage, voltage on the tires of each section, malfunctions in operational circuits with the possibility of executing telecontrol commands for the power switch in each section, including TV switching and tele-shutdowns and telemetry systems for load currents of cable lines, power transformers and a sectional voltage switch on the sections. 13. The power supply network according to claim 12, characterized in that dry transformers with a capacity of 40 kVA each with a voltage of (10 ± 2) · 2.5 are used as transformers for down-converting high-voltage energy of 10 kV to low-voltage electricity of 0.4 kV % / 0.4 kV. 14. The power supply network according to any one of paragraphs.11, 12, 13, characterized in that it is made on the basis of two or more transportable modules, each of which is made in the form of a volume unit. 15. The power supply network according to claim 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. 16. The power supply network according to clause 15, wherein 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 the profiled metal sheets are interconnected by combined rivets. 17. The power supply network according to claim 11, characterized in that the foundation on which the volumetric block is mounted is 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 of the exterior walls of the volumetric block and in parallel with at least one pair of opposing ones, as well as foundation blocks installed in the ground also buried in the ground with a width less than the width of the arm belt, and executed in at the foundation blocks at the mark of the surface of the reinforced cement-sand screed, 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 with walls is formed between the foundation blocks, one of the reinforced concrete tapes forming an armored belt parallel to one pair opposite walls of the volumetric block, placed along one of the two middle vertical planes of the volumetric block, and the remaining tapes parallel to this plane, at equal distances x apart. 18. The power supply network of a settlement, microdistrict, city district, industrial, agricultural complex, megalopolis, characterized in that it contains power lines for connecting loads from at least two independent power sources, at least one block installed on the foundation distribution point - a factory-ready transportable module in the form of at least one volume unit with a parity of lengths of pairs of opposite external walls of 1.0-1.45, with at least two cell sections mounted in it with a uniform distribution of consumer load across sections of switching equipment and protection devices, some of which in different sections are made in pairs of the same type for functional purpose and placed mirror symmetrically with respect to one of the two middle vertical planes of the volume unit moreover, cell sections are mounted with the formation of passages predominantly symmetrical about the same plane of the volumetric block along the ar The external walls of the volume unit attached to them. 19. The power supply network according to p. 18, characterized in that it is configured to connect to at least two additional sources of electricity from the backup power centers also through the corresponding cable lines and connecting at least four outlet cable lines, in each section, four output cells, at least 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 are successively mounted ensuring the operation of 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, in addition, a section switch cell is located in one section and a section switch cell is symmetrical in one section of two middle vertical planes there is a cell of a sectional disconnector, electrically connected to the cell of the sectional switch, with input, output cells and the cells for the transformers are equipped with maximum current protection against interphase short circuit with an independent delay time with a trip effect, as well as protection against earth faults with an independent time delay with a signal action, the cell section switch is made with a maximum current protection against interphase short circuit short-circuit with an independent time delay with a shutdown action, as well as with an automatic backup power input device that contains input shutdown elements 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 locks when the device is used for overcurrent protection of the power line input of the cable power line to the emergency section, the system for automatically turning on the sectional switch from the block contacts of the input switch without time delay after disconnecting the power input of the cable power line to emergency section, manual reset devices after automatic actuation, as well as control keys for two positions of automatic input of backup power supply “input” - “output” installed on the input cells to ensure the principle of continuity of the control circuit of the sectional switch for any position of the truck circuit breaker input, and the block distribution point is equipped with telemechanization systems, including remote control systems, tele-signaling and telemetry: provisions circuit breakers for cable lines, power transformers and a sectional switch, ground faults, for connecting cable lines of higher voltage, voltage on the tires of each section, malfunctions in operational circuits with the possibility of executing telecontrol commands for the power switch in each section, including TV switching and tele-shutdowns, and telemetry systems for load currents of cable lines, power transformers and a sectional voltage switch on the sections. 20. The power supply network according to claim 19, characterized in that dry transformers with a capacity of 40 kVA each with a voltage of (10 ± 2) · 2.5 are used as transformers for down-converting high-voltage energy of 10 kV to low-voltage electricity of 0.4 kV % / 0.4 kV. 21. The power supply network according to any one of claims 18 to 20, characterized in that it is made on the basis of two or more transportable modules, each of which is made in the form of a volume unit. 22. The power supply network according to p. 18, characterized in that each volume unit consists of a metal frame, insulated outer walls, insulated ceiling, floor, roof and at least one safe metal door. 23. The power supply network according to item 22, wherein the outer walls are made of three-layer metal panels of the type "sandwich" 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 the profiled metal sheets are interconnected by combined rivets. 24. The power supply network according to claim 18, characterized in that the foundation on which the volumetric block is mounted is 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 around the perimeter of the exterior walls of the volumetric block and in parallel with at least one pair of opposing ones, as well as foundation blocks installed in the ground also buried in the ground with a width less than the width of the arm belt, and executed in at the foundation blocks at the mark of the surface of the reinforced cement-sand screed, 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 with walls is formed between the foundation blocks, one of the reinforced concrete tapes forming an armored belt parallel to one pair opposite walls of the volumetric block, placed along one of the two middle vertical planes of the volumetric block, and the remaining tapes parallel to this plane, at equal distances x apart.

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