RU141682U1 - VARIABLE DEVICE FOR HUNGER MELTING - Google Patents

Abstract

1. Device for melting ice with alternating current, containing phase wires of heated power lines outgoing from the supply substation, connected from the receiving substations with the contacts of shorting disconnectors, the second contacts of which are interconnected and grounded, as well as a power source for melting the ice located on the supply substation , which uses windings of a lower voltage than the voltage of heated power lines, while the power source for melting ice connected to the bus bypass system through the first disconnector, circuit breaker, second disconnector connected in series, and the bus bypass system is connected to the phase conductors of each of the heated power lines through the respective line disconnectors, and three phase capacitor units are placed at the power substation between the switch and the second disconnector, each of which consists of series-connected capacitor blocks with output terminals, while the corresponding terminals of the con the capacitors of the phase capacitor units are connected to the contacts of the individual disconnectors, the second contacts of which are connected to the bypass bus system, characterized in that the third, fourth and fifth disconnectors are installed in the device, which are located on the power substation, while the third disconnector is longitudinally connected between the switch and the phase capacitor installations, the contacts of the fourth disconnector are connected to the phases of the three-phase circuit between the third disconnector and the phase capacitor units, and the second contacts

Description

The utility model relates to the field of electric power and can be used to protect the wires of power lines from ice in a cyclone of autumn-winter weather.

A device is known for melting ice with alternating current, containing phase wires of heated power lines outgoing from the supply substation, connected from the receiving substations with the contacts of shorting disconnectors, the second contacts of which are interconnected and grounded, and a power source for melting the ice located on the supply substation which uses windings of a lower voltage than the voltage of heated power lines, while the power source for melting iced ice is connected to the bus bypass system through the first disconnector, circuit breaker, second disconnector connected in series, and the bus bypass system is connected to the phase conductors of each of the heated power lines through the corresponding linear disconnectors (Guidelines for melting ice with alternating current. RD 34.20.511, MU 34 -70-027-82. M .: Soyuztekhenergo, 1983).

The main disadvantage of the known device is that the voltage of the power source for melting ice is often insufficient to create the required currents for melting ice. This problem is connected with the fact that on power lines with voltage of 110 kV and higher, the longitudinal inductive resistance of the phase wire of the heated section of the power line significantly and substantially limits the value of the ice melting current at an industrial frequency. An alternating current of ice melting of the required size in the known device can be created by reducing the distance from the supply transformer substation to the installation location of the short-circuit disconnector, by placing it in the area between the supply and receiving substations, for example, on one of the supports along the transmission line. However, this leads to a decrease in the possibility of covering an ice-hazardous area and an increase in the time required to carry out the necessary switching with the departure to the installation site of a short-circuit disconnector.

The closest in technical essence to the claimed utility model is a device for melting ice with alternating current, containing phase wires of heated power lines outgoing from the supply substation, connected from the receiving substations with the contacts of shorting disconnectors, the second contacts of which are interconnected and grounded, as well as at the power substation, a power source for melting ice, which uses windings of lower voltage than the voltage around heated power lines, while the power source for melting ice is connected to the bypass bus system through the first disconnector, switch, second disconnector connected in series, and the bypass bus system is connected to the phase conductors of each heated power line through the corresponding linear disconnectors, and at the power substation between three phase capacitor units, each of which consists of consecutively connected blocks of of capacitors with connected terminals, while the corresponding terminals of the capacitor banks of the phase capacitor units are connected to the contacts of the individual disconnectors, the second contacts of which are connected to the bypass bus system (RF Patent for Utility Model No. 119951 “Ice Melting Device”, H02G 7/16, publ. in BI 08.28.2012).

The main disadvantage of the known device is that in it the maximum current value for melting ice is limited by the ratio of the phase voltage of the power source for melting ice to the active resistance of the phase wire of the heated section of the power line. As a result, in a number of cases, the ice melting current, for example, generated at a common voltage of a power source of 6-10 kV, may turn out to be insufficient for melting ice on relatively long sections of heated transmission lines of 110 kV and higher, despite the effect achieved in a known utility model, comparable to the effect of melting ice with direct current, due to the full compensation of the inductive resistance of the wire by the capacitive resistance of the capacitor unit.

This utility model is aimed at solving the technical problem of creating the required industrial frequency currents using relatively inexpensive switching devices, consisting of single-pole disconnectors, using which, instead of the phase voltage, the linear voltage of a three-phase power source for icing is applied to the wire of the heated transmission line section.

The technical result achieved in this case is to increase the efficiency of the device by solving the above problem.

The specified technical result is achieved by improving the device for melting ice with alternating current, containing phase wires of heated power lines extending from the supply substation, connected from the receiving substations with the contacts of shorting disconnectors, the second contacts of which are interconnected and grounded, and also located on the supply substations a power source for melting ice, which uses windings of lower voltage than the voltage power transmission lines, wherein the power source for melting ice is connected to the bypass system of buses through the first disconnector, switch, second disconnector connected in series, and the bypass system of buses is connected to the phase wires of each of the heated power lines through the corresponding linear disconnectors, and at the power substation between three phase capacitor units are placed by a switch and a second disconnector, each of which consists of series-connected condensate blocks a ditch with the extracted terminals, while the corresponding terminals of the capacitor banks of the phase capacitor units are connected to the contacts of the individual disconnectors, the second contacts of which are connected to the bypass bus system, into which the third, fourth and fifth disconnectors are inserted, which are located on the power substation, while the third disconnector is longitudinal connected between the switch and the phase capacitor units, the contacts of the fourth disconnector are connected to the phases of the three-phase circuit between the third disconnector and the phase capacitor installations, and the second contacts of the fourth disconnector are connected to each other, and the contacts of the fifth disconnector are connected to the phases of the three-phase circuit between the switch and the third disconnector, and the second contacts of the fifth disconnector are interconnected and grounded, with each phase of the first, third, fourth and fifth disconnectors made in the form of a separately switched unipolar disconnector.

This set of features allows you to solve the problem.

Figure 1 shows, by way of example, a block diagram of an apparatus for melting ice with alternating current, intended for melting ice on phase wires A, B, C of three outgoing power lines 1-3, using a capacitor unit, each phase of which consists of three blocks of capacitors 4 -6. For convenience, the figure simplifies only the elements of a device for melting ice with alternating current without the image of system buses, the main switching and other equipment of the transformer substation.

When it becomes necessary to melt ice, phase wires of the corresponding power line, for example, power line 1, after disconnecting from the network, are transferred to the ice melting mode. To do this, along this power line 1 from the receiving transformer substation side, a short-circuit disconnector 7 is turned on, the second contacts of which are interconnected and grounded, and on the supply transformer substation are switched on: separately switched single-pole disconnectors of phases A and B as part of the first disconnector 8, single-pole phase disconnector A as part of the third disconnector 9, a single-pole phase B disconnector as part of the fifth disconnector 10, as well as the second disconnector 11 and the linear disconnector 1 2.

As a result of the switchings, the phase B of the power source for melting ice 13 at the supply substation is shorted to ground, and the linear voltage between phases A and B of this source is applied to the wire-to-ground circuit on the heated section of the power line 1 with phase A wire through three blocks of capacitors 4-6 and a bypass system of tires 14. In this case, ice is melted and completed using an automatic switch 15. On the wires of other phases, ice is melted in a similar manner. If the power supply is sufficient for melting the ice 13, the ice in the claimed utility model can be produced in one step, with the inclusion of the fourth disconnector 16, as a result of which the melting currents flow simultaneously in all three phases.

The current value of the ice melting current in the considered circuit is determined by the formula, neglecting the significantly low resistance of grounding conductors and other circuit elements:

,

,

where Ul and Uf are the effective values of the linear and phase voltages of the power source for melting ice 13; R is the resistance of the phase wire and earth on the heated section of the power line 1; Xpr - the inductive resistance of the phase wire in the heated section of the power line 1; Xс - resistance of the used part of the phase capacitor unit with capacitor banks 4-6.

The ground resistivity of 0.05 Ohm / km is much lower than the specific resistance of the wire, for example, the specific resistance of the AC-70/72 wire on a 110 kV overhead line at a wire temperature of 80 ° C is an order of magnitude higher than the ground resistance and is 0.513 Ohm / km (see. Guidelines for melting ice with alternating current. RD 34.20.511, MU 34-70-027-82. M .: Soyuztekhenergo, 1983). In this regard, in the considered circuit, the resistance value K is approximately equal to the active resistance of the heated section of the wire.

раз больше, чем значение тока плавки гололеда в известном устройстве, при прочих равных условиях. Как было указано выше, при достаточности мощности источника, плавка гололеда в данном устройстве может быть произведена в один этап по схеме «три провода-земля», где величина тока плавки гололеда в каждом проводе будет приблизительно равна току плавки гололеда по схеме «провод-земля».Given this fact, the value of the current melting ice in the inventive utility model to

times greater than the value of the current melting ice in the known device, ceteris paribus. As mentioned above, if the power of the source is sufficient, the ice in this device can be melted in one step according to the “three wire-to-ground” scheme, where the current of ice melting in each wire will be approximately equal to the current of melting ice in the “wire-to-ground” scheme ".

On power lines 2 and 3, ice is smelted in the same way, where at the receiving substations the wires are interconnected and grounded using short-circuit disconnectors 17 and 18, and the phase wires of these power lines to the bypass bus system 14 are connected through line disconnectors 19 and 20, respectively. Separate disconnectors 21 and 22 connecting the output terminals of the capacitor units of the phase capacitor units to the bus bypass system are used to control the magnitude of the ice melting currents, while simultaneously connecting the capacitor units 4, 5 or 4, respectively.

The wire-to-ground ice melting schemes are known and are widely used in practice, where a wire is usually grounded at the receiving substation and a neutral of the secondary windings of the power transformer connected to the star is grounded at the supply substation. However, in this case, the melting currents are created under the action of only the phase voltage of the source, and are also limited due to the negative influence of the inductive resistance of the wire.

In the claimed utility model, the ice melting circuit consists of a series-connected phase capacitor unit, a phase wire of a heated section of the power line and earth, where the linear voltage of the power source for melting the ice is applied to the ice melting circuit, by grounding the wire at the receiving substation and shorting to ground one of source phases at the power substation.

The combination of the above features, namely, providing a single-phase earth fault and applying a linear voltage of the source to the ice melting circuit, in which the inductive resistance of the wire is compensated by the capacitive resistance of the capacitor unit, allows us to solve the problem and create the required ice melting currents with alternating current.

раз по сравнению с током плавки в известном устройстве.In addition, the considered device for melting ice with alternating current allows the ice to be melted in two stages according to the schemes: using two-wire-ground earth and with a third wire-to-ground wire, without using two-wire-wire ground and with the last two wires "wire-to-wire", as well as according to other schemes by switching three-phase and separately switched single-pole switching devices, at the linear voltage of the source with compensation of the reactance of the wire. Calculations show that when melting ice without using land according to the "wire-two wires" scheme, the alternating current of melting ice in the inventive utility model increases to

times compared with the melting current in the known device.

Claims (1)

1. Device for melting ice with alternating current, containing phase wires of heated power lines outgoing from the supply substation, connected from the receiving substations with the contacts of shorting disconnectors, the second contacts of which are interconnected and grounded, as well as a power source for melting the ice located on the supply substation , which uses windings of a lower voltage than the voltage of heated power lines, while the power source for melting ice connected to the bus bypass system through the first disconnector, circuit breaker, second disconnector connected in series, and the bus bypass system is connected to the phase conductors of each of the heated power lines through the respective line disconnectors, and three phase capacitor units are placed at the power substation between the switch and the second disconnector, each of which consists of series-connected capacitor blocks with output terminals, while the corresponding terminals of the con the capacitors of the phase capacitor units are connected to the contacts of the individual disconnectors, the second contacts of which are connected to the bypass bus system, characterized in that the third, fourth and fifth disconnectors are installed in the device, which are located on the power substation, while the third disconnector is longitudinally connected between the switch and the phase capacitor installations, the contacts of the fourth disconnector are connected to the phases of the three-phase circuit between the third disconnector and the phase capacitor units, and the second contacts The fourth disconnector is connected to each other, and the contacts of the fifth disconnector are connected to the phases of the three-phase circuit between the switch and the third disconnector, and the second contacts of the fifth disconnector are interconnected and grounded, each phase of the first, third, fourth and fifth disconnectors is made as separately switched single pole disconnector.

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