RU118479U1 - HIGH VOLTAGE NETWORK - Google Patents

Abstract

1. A high-voltage network containing a transformer substation with two-circuit overhead power transmission lines outgoing from it, the transformer substation of which, in addition to the busbar systems, has sections of the bypass bus system, each of which connects one of the overhead line circuits to the melting current source of the overhead line sticking to the wires ice and snow, characterized in that one section of the bypass bus system has a phasing of the A1B2C1 buses, the other section of the bypass system has a phasing of the C2B1A2 buses, and each section of the bypass bus system is connected to the low voltage buses of the transformer station. ! 2. Network according to claim 1, characterized in that the second section of the bypass bus system has a short-circuit.

Description

The utility model relates to the field of large electric power industry, more specifically to high-voltage power lines equipped with devices for removing icy deposits from power wires.

A high-voltage network is known, equipped with a device for removing icy deposits from power wires in the form of a series-connected converter, an oscillating speed transformer and a holder in the form of a guiding cup, at the output end of which there is an axially displaceable tool, the tool being made in the form of a clamp, consisting of two half-shells mounted on an axis and connected by a threaded connection, while the inner surface of the clamp half-shells is roughened oh [RF Patent 98848 for utility model dated 03.06.2010, IPC H02G 7/16]. The disadvantage of this arrangement is the use of a mechanical clamp - acting as a scraper tool with axial movement of the device along the wire / cable of the overhead power line.

A high-voltage network is known, equipped for ice melting with a direct current rectifier on power lines, consisting of an uncontrolled three-phase bridge rectifier, voltage limiters installed parallel to each arm of the rectifier bridge, RC circuits, resistive voltage dividers, diode breakdown signaling devices, and a control cabinet, as signal elements about the presence of punctured diodes, indicator relays are used, located at the potential of the monitored diodes and included in diagonals between series-connected diodes and resistive voltage dividers. [RF patent 105084 for utility model dated 12/15/2010, IPC H02G 7/16]. The disadvantage of this arrangement is the need to equip the high-voltage line with additional rectifiers and electrical circuits for controlling the ice removal unit.

The prototype is a high-voltage network containing a transformer substation (with software), with two-circuit overhead power lines departing from it, in the transformer substation of which, in addition to working bus systems, there are two sections of the bus bypass system, each of which connects one of the air line circuits power lines with a current source for melting ice and snow sticking to overhead line wires [Levchenko II, Zasypkin AS, Alliluyev AA, Satsuk E.I. Diagnostics, reconstruction and operation of overhead power lines in icy areas. - M.: Publishing. House MPEI. - 2007]. In the indicated high-voltage network, a substation rectifier installation is used as a source of current for melting ice on wires of a high-voltage power line departing from a transformer substation. A change in the type of melting current compared to the operating current of the high-voltage network is dictated by the fact that the direct current of the rectifier installation is insensitive to the large inductive term jx ₀ in the linear resistance r ₀ + jx ₀ of the overhead power line circuits. At the same time, the consequence of the same betrayal is a number of other technical shortcomings, the main of which / are:

- significant costs for the construction and operation of a substation rectifier installation with a short time of its use, in a year;

- a significant duration of the alternate melting of already adhering ice at the same time only on two (out of six) wires of a double-circuit overhead line. During this time, the wires of the neighboring overhead line are overloaded and torn under the weight of the ice load, its supports break down by glaciation. The emergency recovery of overhead power lines in harsh winter conditions lasts for weeks, which forces a technologically advanced network subscriber to acquire a backup diesel power station.

The proposed technical arrangement of the high-voltage network is aimed at eliminating technical shortcomings (contradictions), while the rectifier installation is not required.

The technical result is to protect high-voltage power lines from sticking wet snow and ice.

The essence of the proposed technical solution for the high-voltage network device is that on one section of the bus bypass system, the phasing of tires A ₁ B ₂ C _{1 is set} , on the other section of the bypass system of buses, the phasing of buses C ₂ B ₁ A _{2 is set} , with each section of the bypass bus system connected to the low voltage busbars of the transformer substation, the second section of the bus bypass system having a short circuit.

The technical solution of the device is illustrated by examples of the structural and functional design diagram shown in Fig 1-3. Figure 1 presents a single-line electrical diagram of a high-voltage network, figure 2 presents a three-line electrical diagram of a high-voltage network, figure 3 shows the phasing of six wires on a support of a double-circuit overhead power line. The structure of the device includes: transformer substation 1, the first circuit 2 of a double-circuit overhead power line, the second circuit 3 of a double-circuit overhead power line, the first section 4 of the bypass bus system, the second section 5 of the bypass bus system, the first switch 6, the second switch 7, short circuit 8, low voltage busbars 9 of a transformer substation, strut supports 10 of a double-circuit overhead power line, where (see FIG. 3) A ₁ V ₂ C ₁ and C ₂ B ₁ A ₂ is the temporary phasing of six bus sections of the bypass system of the bus transformer substation and wires of both overhead line circuits on both sides of the common strut of the overhead line support of the high voltage network.

The device of the high-voltage network for removing ice works as follows.

At the transformer substation 1, a remote assembly program for the preventive melting scheme of ice and snow, which adheres to the wires of the first overhead power line, is launched. At the same time, the first circuit 2 of the double-circuit overhead line and the second circuit 3 of the double-circuit overhead power line are temporarily taken out of the normal operation by their linear devices (they are darkened in Fig. 1) and connected to each other by the terminal transformer substation devices (see dashes there). Next, the tires of the first section 4 of the bypass bus system are connected to the wires of the circuit 2, and the tires of the second section 5 of the bypass bus system are connected to the wires of the circuit 3. Then, by switching on the pairs, the second switch 7 - the first switch 6 or the second switch 7 - short circuit 8 through both series-connected circuits 2 and 3 of this overhead line, an opposition current or artificial short circuit current I of bus 9 of the low voltage of the transformer substation is passed, which is the current of melting ice sticking to all six wires air line i.e. Joule heat generated by the current I of the wire itself. Upon completion of the ice melting using the substation computer software, the preventive melting circuit of this overhead line is disassembled with the restoration of the normal operation of both its circuits 2 and 3. Then, they sequentially proceed to similar ice melting on the wires of another overhead power transmission line, etc.

The feature of this high-voltage network device is that due to the changed (against the busbars of the transformer substation) bus phasing of sections 4 and 5 of the bypass bus system, the phasing of the wires of chains 2 and 3 on the rack 10 of the support of each overhead line also changes: for example (Fig. 3 ), to the left of the strut of the supports 10, the phasing A ₁ B ₂ C _{1 is set} , to the right - C ₂ B ₁ A ₂ . In this case, the direct current magnetic field I in circuit 2, determined by the area of triangle A ₁ B ₁ C ₁ , is 75% overlapped by the same reverse current field I of second circuit 3 (see Fig. 3, triangle A ₂ B ₂ C ₂ ) and vice versa. Therefore, in the linear inductive resistance of each circuit 2 and 3, the difference j (x ₀ -x _M ) works, where x _M is the mutual inductance of the circuits. Typically, if nothing is changed in the phasing of the wires of circuits 2 and 3 against normal, then the mutual inductance of the circuits is x _M ≈ 0, while in the proposed device x _M ≈ 0.75 x ₀ . Those. the same thing happens as in the prototype — the exclusion from the melting current circuit I of the large and harmful term jx ₀ , but without a rectifier device and simultaneously on all six wires.

An example implementation of the device. Several double-circuit overhead transmission lines VL-220 kV with lengths depart from the substation 500 / 220-35 kV 3 × 167 MVA _VL ≤100 km and with wires AC-240/32. The linear resistance of the circuits r ₀ + j (x ₀ -x _M ) = 0.12 + j0.112 Ω / km. The current strength in both circuits of the overhead lines after turning on the pairs, the second switch 7 - the first switch 6 or the second switch 7 - short circuit 8 (see Figs. 1 and 3) to the low voltage busbars 9 of the 35 kV transformer substation will be 1080 and 620 A, respectively. At the same time, the melting time is from 3 min at 1080 A to 6 min at 620 A. After this time, reverse switching is carried out with the restoration of normal operation of these overhead lines VL-220 kV. Next, a similar melting circuit is assembled on the wires of another double-circuit overhead line of the high voltage network.

At the same time, the main advantages are realized:

- a substation rectifier installation and a standby diesel power station are not required; accordingly, there are no costs for the owner of the high-voltage network and subscriber for their arrangement and operation;

- significantly (20 times or more) the total duration of alternating ice melting on all overhead lines departing from a given transformer substation is reduced;

- the lack of time to cover the entire totality of these air lines with timely melting of ice will disappear;

- simplifies the operation of the high-voltage network in view of the absence of the need for a rectifier installation.

Claims (2)

1. A high-voltage network containing a transformer substation with dual-circuit overhead power lines extending from it, the transformer substation of which, in addition to the busbar systems, has sections of the bus bypass system, each of which connects one of the circuit of the overhead line with a current source of melting adhering to the overhead line wires ice and snow, characterized in that one section of the bypass bus system has bus phasing a ₁ B ₂ C _1, the other section of the bypass system has phasing tire C ₂ B ₁ a _2, and each section of the bypass system w n is connected to the low voltage busbars transformer substation. 2. The network according to claim 1, characterized in that the second section of the bus bypass system has a short circuit.