RU48641U1 - SYSTEM OF INDIVIDUAL CONTROL AND METERING OF ELECTRIC ENERGY - Google Patents

Abstract

The utility model relates to the field of electrical engineering and is intended primarily to provide remote control in individual metering systems for consumption and payment of electric energy.

The system comprises a branch assembly 4 from an overhead line (VL) support 2 power lines with insulated conductors 5 and an input unit 16 into the building in the form of insulated wires (or cable) 19 and an input device with a meter (electric meter 21) connected to the internal wiring. The input device is designed for external installation in the form of a metal or plastic sealed electrical cabinet 11. The cabinet 11 is mounted remotely from the energy consumer on the overhead power transmission line 2 or on the console 9 or on the external wall 12 of the building 13. The conductors 5 of the branch node 4 are laid from insulators 3 on the overhead line 2 of power transmission to the meter 21 of the input device 11 and passed through a flexible metal sleeve 6, which is inserted into the input-output holes of the housing 17 of the cabinet 11 through the sealing glands ki 26. The metal sleeve 6 with the conductors 5 enclosed in further metal tube 7, which is fixed on a support overhead power transmission 2 or the accessory 9.

Description

The utility model relates to the field of electrical engineering and is intended primarily to provide remote control in individual metering systems for consumption and payment of electric energy.

Known systems for automated control and metering of electricity (1, 2). The constructive solution contains measuring equipment, which is placed in a housing formed by conductive walls in the form of a Faraday cage. The technical result of the invention is to simplify the design and testing processes of devices - current and voltage transformers and improve the accuracy of control and metering of electricity. However, such a constructive implementation of the control and accounting system does not provide the possibility of accounting for energy consumption by individual consumers, which narrows the scope of its use.

A device (3) is proposed, which is advisable to use in automated systems for monitoring and accounting for electricity. It contains a reference pulse generator, sensors for current values of voltage, current, frequency, phase difference, the number of voltage deviations per tolerance field per unit time, a pulse counter, four decoders, an adder, a pulse distributor, and a number of other circuit elements. The technical result of the invention is the extension of functionality

due to the introduction of penalties against consumers - sources of deterioration of electricity in general-purpose networks.

However, the device does not provide reliable prevention of unauthorized extraction of electricity (theft) from distribution networks in the systems for supplying electric energy to residential buildings for individual consumers.

Also known is a metering device for electricity consumption in the form of a distribution electrical cabinet (4). The design contains a closed box with a lid. In the case of the box there are holes for fastening and holes for input (output) of power wires, which are passed through a flexible metal sleeve and placed at least 3 meters from the wall of the building. The box has a circuit breaker, a fuse and an electric meter. The meter is placed in a window in the lid so that half of its body is exposed to the outside of the lid. The window in the lid is designed so that the numerical drums of the electric meter are located opposite it. The window is closed from the inside with clear glass that is seated firmly on the glue. The lid is fixed to the box with locking fasteners - screws with a cylindrical head, which is placed in the sleeve with the possibility of rotation of the latter around the head. The sleeve is coupled to the screw head by means of a recess, and a blind hole is made on the end head, which is offset from its axis by a certain distance. The height of the sleeve is greater than the height of the screw head and thus the latter is placed “flush”. The lid is fixed to the box with screws through blind threaded holes made in the nuts attached to the box by welding. Sealable material, for example, sealing wax, is sealed in the space between the end face of the head of the fixing screw and the inner surface of the sleeve and sealed in the form of an impression of the owner of the electric power after screwing this screw.

The design disadvantage is the low degree of protection of electrical equipment from adverse environmental conditions (humidity, dust

etc.), which does not allow it to be placed outside of enclosed spaces and used for the installation of remote control systems for electric energy.

There is a known system for introducing power lines into industrial, administrative, domestic and residential premises and the design of branch nodes from air lines (VL) to the inputs to buildings, which is chosen as a prototype (5, 6). The system includes a branch assembly, the conductors of which are laid from the overhead line in the form of a section for the electrical wiring from insulators on the overhead line support to insulators on the wall or roof of the building, an input node to the building in the form of a section of electrical wiring from insulators on the outer wall or roof of the building to the input device (for example , electrical cabinet) connecting the external electrical network to the internal wiring. An electrical cabinet is installed indoors and is equipped with a meter - an electric meter. The conductors of the branch node from the overhead line to the building entrance are made of uninsulated aluminum wires with a cross section of at least 16 mm ² or insulated aluminum wires of the AVT-1 or AVT-2 brand with a vinyl coating and a supporting cable or AVP-1 and AVP-2. Entrance to the building is made by an insulated wire (or cable). Each input wire is connected to the branch assembly on the overhead line support with a clamp such as ОАС-1, ОАС-2 or clamps of the type ЩКД-2Б, ЩКД-2, which provide good electrical contact, high mechanical strength and tightness of the connection. The input is made, as a rule, two-wire through an opening in the wall or by means of a pipe-mount mounted on the wall or roof of the building. Tubing is made of a piece of steel thin-walled pipe with a nominal bore of 15 mm or a water-gas pipe with a diameter of 1/2 inch. To reduce the risk of electric shock, the pipe stand is nullified. Accounting and control of electrical energy consumption in the system is carried out by taking readings of the meter. To do this, an employee of the Energy Supervision Service periodically visually inspects the condition of the input device and inputs to the building in order to identify and suppress unauthorized connections to the system

bypassing the electric meter, as well as violation of the integrity of the conductors of the branch node and the input device itself - an electric cabinet and an electric meter. This mode of control and accounting is not very effective, because it is often difficult or even not possible to identify an illegal connection to the power supply, which, as a rule, is done secretly and, in addition, it is sometimes difficult to get into a guarded building for conducting a visual inspection of the input device.

The disadvantage of the prototype is the poorly protected execution of the branch node made by non-insulated conductors or conductors in vinyl insulation, which makes the system very vulnerable to unauthorized connections bypassing the input device with an electric meter and potentially creates conditions for the theft of electricity. In addition, the input device is mounted indoors and is not suitable for remote control, which makes it difficult to access and independent of the consumer control and accounting of electrical energy.

The objective of the utility model is to eliminate these shortcomings and create a system for remote metering of electricity with effective protection against unauthorized selection of electric energy.

The technical result of the utility model is, firstly, the increased reliability of the execution of the overhead branch node and the protection against unauthorized connections bypassing the electric meter. Secondly, independent from the consumer control by the Energy Supervision Service over the consumption and accounting of electric energy.

This goal is achieved by the fact that the system of individual control and metering of electric energy, comprising a branch unit from insulators on an overhead power line (VL) support and an input unit to the building in the form of insulated wires or cable, an input device with a metering device (electric meter) connected with internal wiring, according to a utility model, the input device is made with the possibility of external installation in the form of metal or plastic

a sealed electrical cabinet, which is equipped with a fastener and mounted remotely from the energy consumer on the power transmission line support or on the console or on the external wall of the building, and the branch assembly conductors are laid from insulators on the power transmission line support to the metering device of the input device and passed through a flexible metal sleeve, which is additionally enclosed in a protective metal pipe mounted on a power transmission line support or on a set-top box, or on the external wall of a building, while the metal pointing with conductors brought into the input-output openings of the cabinet body through the sealing glands.

The cabinet fastening means on the lighting support or console is made in the form of mounting brackets, the ends of which are equipped with a threaded connection under the nut with the possibility of mounting the cabinet with a gap between its rear wall and the support.

The cabinet fastening means on the external wall of the building are made in the form of anchor bolts or dowels.

The metal pipe is fixed by welding to the mount, which is mounted on the support of the overhead power lines by means of a steel clamp.

The branch assembly from the overhead power line (VL) power transmission support is made of a single-phase or three-phase insulated wire or a coaxial cable or cable on a cable.

The input unit to the building is made through a pipe pipe with an insulated wire, cable or coaxial cable, which is wound in a metal sleeve.

As follows from the technical level, the proposed technical solution meets the criterion of novelty, which consists, firstly, in the design of the branch assembly of the system, namely: the conductors of the assembly are made with increased protection against unauthorized connection bypassing the input device, for which they are passed through a flexible metal

a sleeve, which is additionally enclosed in a protective metal pipe and mounted on a VL support, an attachment, or an external wall of a building.

Secondly, the layout solution of the system as a whole is new — the branch node is directly electrically connected to the input device, which is further connected to the conductors of the input unit to the building, and the conductors of the latter are electrically connected to the building’s internal wiring.

Thirdly, the input device - an electrical cabinet with a metering device is located outside the building remotely from the consumer of electricity, which provides independent control from the consumer by the Energy Supervision Authority, both over the physical condition of individual components of the system and the metering of electrical energy at any convenient time in accordance with established regulations. For these purposes, the electrical cabinet is made with IP-54 degree of dust and moisture protection (solid housing, sealed with special seals at the points of input-output of conductors, mounting fittings, connector along the door-housing line, etc.). The design of the cabinet meets the requirements of counteracting domestic vandalism (a robust case, built-in door hinges inaccessible for breaking, locks with locking bolts for a secret key) and at the same time provides the ability to visually control the meter readings through a sealed inspection window, which also has a cover for anti-vandal protection.

These distinguishing features are new and provide high security against unauthorized connections and effective control of the electric energy metering system.

The essence of the utility model is illustrated by the drawings shown in figures 1-10.

Figure 1 presents the principal block diagram of a system of individual metering and control of electricity, including (a) - input from a support without a prefix, (b) - input from a support with a prefix.

Figure 2 is a diagram of a single-phase air inlet with an electrical cabinet placed on the overhead line support or prefix (a) and through a pipe on the wall of the building (b).

Figure 3 is a diagram of a three-phase air inlet with an electrical cabinet placed on the overhead line support or prefix (a) and on the wall of the building (b).

Figure 4 - diagram of the mounting of the electrical cabinet on the support of the overhead line or console (a) and on the wall of the building (b).

In Fig.5 - the mount of the metal pipe on the support of the overhead line, (a) is a side view, (b) is a top view section.

Fig.6,7 - electrical connection diagrams for single-phase input insulated wire and cable, respectively.

On Fig, 9 - electrical connection diagrams for three-phase input insulated wire and cable, respectively.

Figure 10 is a General view of an electric remote cabinet.

The system includes an overhead power transmission line 1, a VL 2 support with insulators 3. A branch assembly 4 with an input section of insulated conductors 5 passed through a metal sleeve 6 enclosed in a metal pipe 7; the pipe 7 by the mounting unit 8 is mounted on the VL 2 support or on the prefix 9 by means of a clamp 10. An input device is an external electrical cabinet 11, which is mounted respectively on the VL 2 support or the prefix 9, or on the outer wall 12 of the building 13 by means of appropriate mounting means: mounting brackets 14 or anchor bolts (or dowels) 15. Node 16 entering the building 13 through the pipe 17 or directly through the hole 18 in the wall 12 with conductors 19, which are made of insulated wire or cable 20 and connected to the internal electrical wire ke in building 13 (not shown in the drawing). The electric cabinet 11 contains a metering device (electric meter) 21 connected to the corresponding electrical circuit for single-phase and three-phase input (Fig.6-9). On the front side of the housing 22 around the perimeter contains a sealing element 23. Mounting holes 24 and holes

input (output) 25 are equipped with sealing washers 33 and seals 26, respectively. The door 27 contains a viewing window 28 made of glass, sealed with a sealing profile 29. The window 28 is provided on the outside with a protective hinged lid 30 made of impact-resistant material. The door 27 contains two locks in the form of locking clamping bolts 31, which are mated with a threaded connection with the housing 22. The heads of the bolts 31 are made under a special key (not shown in the drawing) and placed in the door 27 “flush” with anti-vandal protection of the locks by mechanical locking from unauthorized entry.

The system is mounted in accordance with the Electrical Installation Rules (7). From the main transmission line 1 from the VL 2 support from the insulators 3, a branch assembly 4 with an input section of insulated conductors 5 is made. As conductors 5 for single-phase input, use an AVVG cable, an AVK coaxial cable or an insulated wire (SIP input). With three-phase input, an insulated reclosure wire is used, a self-supporting insulated wire SIP-2A. In this case, the conductors 5 are led into a flexible metal sleeve 6, which is then passed through a metal pipe 7, which is previously fixed by a welding joint to the attachment unit 8. The latter, in advance, by means of a clamp 10, is fixed on the VL 2 support, and the pipe 7 is brought to the remote electrical cabinet 11. The housing 22 of the latter is made of metal all-welded or plastic, for example, polystyrene with a degree of protection of at least IP-54 and is resistant to mechanical stress, as well as to unauthorized entry. Depending on the specific project, the electric cabinet 11 for outdoor installation is also mounted on the VL 2 support on the console 9 or on the external wall 12 of the building 13. In the latter case, the input unit 16 into the building 13 is made through a pipe 17 or directly through the hole 18 in the wall 12 with conductors 19, which are made with an insulated wire of АПВ type (or a cable of the AVK brand) 20 and connected to the internal wiring in building 13 through a local distribution

shield (not shown in the drawing). Conductors 19 also lead into a metal sleeve similar to sleeve 6. The pipe 17 and the metal sleeve are mounted on the outer wall 12 with brackets 32.

A sealed electrical cabinet 11, depending on the version of the system project being implemented, is installed on the VL 2 support, either on the prefix 9, or on the wall 12 of the building 13. The cabinet 22 of the cabinet 11 on the VL 2 support or the prefix 9 is fixed with mounting brackets 14, which are passed through mounting holes 24. At the same time, a technological gap is left between the rear wall of the housing 22 and the mounted plane of the VL 2 support, to allow the electrician-installer to climb onto the support using special “claws” that must pass freely through the lumen of the gap. When installing the mounting brackets 14 in the housing 22 through the mounting holes 24, the latter are sealed with sealing washers 33. When installing the electrical cabinet 11 on the external wall 12, it is fixed with anchor bolts 15. After installation, an electrical meter 21 is installed in the electrical cabinet 11, and in the input holes the output through the gaskets 26 lead a metal sleeve b with conductors 5 from the branch node 4 and also output a metal sleeve with conductors 19 of the input node 16 into the building 13. Next, in accordance with the adopted project, connect via fighter an in building 13 on a single phase (6, 7) or three-phase (8, 9) scheme. As metering devices, for single-phase input, electric meters of active energy of the type CE 6807 В IT or СET1-1 are used, and for three-phase input, electric meters of type CE 6803 В IT or СЭТЗа-02-05 are used. Through the electric meter 21, copper buses 37 and 38 mounted in a remote cabinet 11, in accordance with the electrical circuits (Figs. 6-9), through a switch-disconnector 34 and an automatic switch 35, the branch unit 4 is connected to the input unit 16 for supplying electricity to building 13 to the internal distribution board (not shown in the drawing). After installation of the entire system include a switch-disconnector 34, the door 27 of the electric

cabinet 11 by means of a sealing element 23 is hermetically closed and locked with a bolt connection 31. A visual review of the readings of the electric meter 21 is carried out through the viewing window 28. In the stationary mode of operation of the system, the glazed window 28 is in the closed position by a protective cover 30, which protects it from accidental or intentional damage.

The system operates as follows. After mounting and turning on the switch-disconnector 34 from the main transmission line 1 through the branch unit 4 and the input device is an electric cabinet 11 for outdoor installation and then through the input unit 16 to the building 13, the electric power is automatically supplied to the individual consumer. The Energy Supervision Service periodically, in accordance with the regulations, conducts a visual inspection of the state of the system and checks for the readings of the meter - electric meter 21. To do this, the controller manually pushes the protective cover 30 of the inspection window 28 of the electrical cabinet 11 to the side, records the readings of the electric meter 21 and releases the cover 30 , which then, under its own weight, takes its working position and closes window 28. At the same time, the branch assembly 4 and the integrity of the conductors of the input section from the mag of the power line 1 to the input opening and the condition of the electrical cabinet 11. If a mechanical damage is detected or an unauthorized attempt is made to take electricity to the electricity meter 21, the system is turned off by a switch-disconnector 34 after the locks 31 are unlocked and the door 27 of the electrical cabinet is opened 11. The consumer is disconnected in the building 13 from the main transmission line 1 can be produced automatically by the system by the switch 35 in case of emergency or unsanction onirovannogo selection electricity.

As follows from the above description of the system, the developed technical solution meets the criterion of "industrial applicability".

The proposed utility model was used in the design solution: “Electric energy metering units in outdoor cabinets”, 15.200- ES developed at Zapadselenergoproekt Institute OJSC (Smolensky OKP) and passed pilot industrial tests in the power supply system of the Smolensk region in Russia.

The test results showed the high efficiency and cost-effectiveness of the new approach to the organization of control and metering of electric energy consumption by individual consumers. At the same time, non-production energy losses during the six months of using the utility model were reduced by more than 400,000 (four hundred) thousand US dollars, which was made possible due to the layout layout of the system and the high reliability of branch 4, which is difficult for unauthorized persons to access and thereby reduced the possibility of theft, especially in remote areas of the countryside. In addition, the use of an outdoor installation in the system of an electrical cabinet with an IP-54 degree of protection and high anti-vandal properties significantly simplified the process of visual control and metering of electricity consumption, due to the availability and ease of maintenance of the system for employees of the Energy Supervision Service.

Sources of information:

1. Patent RU No. 2224260 C1, IPC ⁷ G 01 R 11/48, (22) 2002.06.28., (46) 2004.02.20. "Automated system for monitoring and accounting for electricity."

2. Patent RU No. 2229724 C2, IPC ⁷ G 01 R 11/48, (22) 2002.06.28., (43) 2004.01.27. "Automated system for monitoring and accounting for electricity."

3. Patent RU No. 2125269 C1, IPC ⁶ G 01 R 21/133. (22) 1997.08.28., (46) 1999. 01.20. "Device for metering electricity."

4. Application RU No. 99122445 A, IPC ⁷ H 02 G 7/00, (22) 1999.10.26. (43) 2001.09.20. “Electricity consumption metering device”, (71) (72) Pashchenko V.Ya.

5. Kadykov Yu.M., Kharechko VN. JSC ROSEP. Typical building structures, products and units. Series 5.407-155.94; “Inputs of power lines up to 1 kV into industrial, domestic and residential premises in rural areas”. Issue 1, parts and assemblies, working drawings. Entered into force on 01.03.95. Order of December 21, 94 No. 2-P .; Content Sheets 1-3; Explanatory note, sheets 1-3; Drawings 5.407-15 5.94.1-sheets 3-30.

6. Makarov EF, "Handbook of electric networks 0, -35 kV and 110-1150 kV", Volume 2. Training and production publication. Ed. Goryuno-va I.T., Lyubimova A.A., Moscow, ed. Papyrus PRO, 2003, p. 93 - 138 (prototype).

7. Rules for the installation of electrical installations. Section 4. "Switchgears and substations." Chapter 4.1, 4.2-7th ed. - M.: Publishing House NTs ENAS, 2003.-104 p.

Claims (7)

1. The system of individual control and metering of electric energy, comprising a branch unit from insulators on an overhead power line (VL) power transmission tower and an input unit to the building in the form of insulated wires or cable, an input device with a metering device (electric meter) connected to internal wiring, characterized in that the input device is made with the possibility of external installation in the form of a metal or plastic sealed electrical cabinet, which is equipped with a fastening means and mounted remotely from the energy consumer on the overhead power transmission tower or on the console or on the external wall of the building, and the conductors of the branch node are laid from insulators on the overhead power transmission tower to the metering device of the input device and passed through a flexible metal sleeve, which is additionally enclosed in a protective metal pipe fixed to the power transmission line overhead either on the console or on the external wall of the building, while a metal sleeve with conductors is inserted into the input-output openings of the cabinet body through the sealing lips nicks. 2. The system according to claim 1, characterized in that the means of attaching the cabinet to the lighting support or console is made in the form of mounting brackets, the ends of which are provided with a threaded connection under the nut with the possibility of mounting the cabinet with a gap between its rear wall and the support. 3. The system according to claim 1, characterized in that the means for mounting the cabinet on the outer wall of the building is made in the form of anchor bolts or dowels. 4. The system according to claim 1, characterized in that the metal pipe is fixed by welding to the mount, which is mounted on the support of overhead power lines by means of a steel clamp. 5. The system according to claim 1, characterized in that the node branch from the support of the overhead line (VL) power transmission is made of a single-phase or three-phase insulated wire or coaxial cable or cable on a cable. 6. The system according to claim 1, characterized in that the input node into the building is made through a pipe stand with an insulated wire, cable or coaxial cable, which is wound in a metal sleeve. 7. The system according to claim 6, characterized in that the input node into the building is made with a cable, which is wound in a metal sleeve.