SU1339717A1 - Arrangement for melting ice deposit - Google Patents

Abstract

The invention relates to electrical engineering and can be used when cleaning wires from snow and ice. The goal is to expand the field of use of the device for melting ice by creating the possibility of melting ice on single-circuit transmission lines (LEP) and increasing the efficiency of melting ice. The ice melting device contains three-phase three-core transformers 1 and 2, the beginnings of the primary windings 3 of which are connected to the phase conductors of 4 power lines, and the secondary windings 5 are connected in delta and connected to the load 6. An adjustable DC source 7 is connected to the ends of the primary windings 3, located on the extreme rods of transformers 1 and 2 and with one of the terminals of the resistors 8. The second terminals of the resistors 8 are interconnected by a jumper 10 and connected to the ends of the primary windings 3 located on the middle rod X transformers. The goal is achieved by introducing a direct current source and two resistors, as well as their inclusion. 3 il. from sl 00 oo

Description

The invention relates to: electrical engineering and can be used in devices for melting ice on the wires of overhead power lines without disconnecting consumers.

The purpose of the invention is to expand the field of use by creating the possibility of melting ice on single-chain power lines and increasing the efficiency of melting ice on double-chain lines and in coil systems.

Fig, 1 shows the scheme set20

25

thirty

35

melts for melting ice; in FIGS. 2-5 by a neutral earth, when the jumper is a device usage diagram at. melting the ice on the double-delineated line at FIG. 3 - the same for melting ice in the ring network.

The device contains three-phase three-core transformers 1 and 2, the beginnings of the primary windings 3 of which are connected to the phase conductors of the power transmission line 4, and the secondary windings 5 are connected in delta and connected to the load 6c. The outputs of the regulated DC source 7 are connected to extreme rods of transformers 1 and 2 and with one of the terminals of the resistors 8, in parallel with which the switching devices 9 are installed. The second terminals of the resistors 8 are interconnected by a jumper 10 and connect s to the ends of the primary winding 3 disposed on the middle rod transformers 1 and 2. Jumper 10 may be connected to ground either directly through a ground wire broken 11 or through a resistor 12, shunt 13, arrester of

The device works in the following way.

When melting the ice, the switching devices 9 are disconnected and a voltage is applied to the regulated direct current source 7. In this case, along with the windings 3 located on the extreme rods, along with the alternating current, constant bias currents 1 flow, the direction of which is shown in Fig. 1 by arrows, and the constant magnetic fluxes of the outer rods excited by them are closed through the middle rods.

With an increase in the current under the connection, the saturation of the magnetic system of transformers increases, which

10 is grounded by wire 11, conditions are created for the passage of odd harmonics of the current, a short three, in the circuit of the line - the primary windings of the transformers - ground. However, due to the shunting effect of secondary windings 5 connected in a triangle, their connection will be significantly reduced.

A more significant reduction in the level of harmonics, a multiple of three, in the line occurs when the neutrals of the transformers are earthed through a resistor 12, as well as when the transformers are operated with a grounded neutral. The presence of delta-connected windings provides almost complete suppression of odd harmonic multiples of three in the curves of the magnetic flux and phase EMF of transformers

The operation of device transformers in a network with an insulated neutral is similar to the work with a grounded neutral. In such networks of neutrals, the coil of transformers and their terminals usually have full insulation and their protection by dischargers is not required. However, the installation of the arrester 13 may be advisable to protect the DC source.

It is also possible to operate the device while supplying transformers from the side of a triangle, and loads from the side of a star.

The magnitude of the active resistance

45

50

55

- resistors 8 it is advisable to take equal to (1-2) Gf5 where Gf is the active resistance of the phase of the primary winding; which practically does not lead to distortion of the star of the phase voltages.

The possibility of practical use of the proposed device for ice crushing is determined by the fact that, according to the existing practice

3397172

leads to an increase in the magnetizing current consumed by transformers from the network, and consequently, the magnitude of the resulting current in the supply transformer line 4.

The use of a DC source with a smooth adjustment of the output voltage allows the value of the resulting line current to be varied, which ensures optimal ice melting under various weather conditions,

When working transformers with zai

ten

0

five

0

five

5 ground neutral when jumper

10 is grounded by wire 11, conditions are created for the passage of odd harmonics of the current, a short three, in the circuit of the line - the primary windings of the transformers - ground. However, due to the shunting effect of secondary windings 5 connected in a triangle, their connection will be significantly reduced.

A more significant reduction in the level of harmonics, a multiple of three, in the line occurs when the neutrals of the transformers are earthed through a resistor 12, as well as when the transformers are operated with a grounded neutral. The presence of delta-connected windings provides almost complete suppression of odd harmonic multiples of three in the curves of the magnetic flux and phase EMF of transformers

The operation of device transformers in a network with an insulated neutral is similar to the work with a grounded neutral. In such networks of neutrals, the coil of transformers and their terminals usually have full insulation and their protection by dischargers is not required. However, the installation of the arrester 13 may be advisable to protect the DC source.

It is also possible to operate the device while supplying transformers from the side of a triangle, and loads from the side of a star.

The magnitude of the active resistance

five

0

five

- resistors 8 it is advisable to take equal to (1-2) Gf5 where Gf is the active resistance of the phase of the primary winding; which practically does not lead to distortion of the star of the phase voltages.

The possibility of practical use of the proposed device for ice crushing is determined by the fact that, according to the existing practice

31

and the standards for technological design of substations in substations of all categories are, as a rule, installed two transformers (autotransformer). Usually both transformers are simultaneously operating with a load of the order (0.6-07) of nominal.

Figure 2 shows an example of the use of the proposed device when powering a two-transformer substation along two parallel lines 4 and 14. Switching device 15 is turned on in dissecting line 14.

If in normal mode both transformers and both lines are in operation, then the ice melting on the lines can be conducted sequentially, first on one and then on the other line.

For example, when melting ice on line 4, line 14 is switched off by switching device 15 and both transformers are switched to work from line 4, which allows it to increase the current in it about two times. A further increase in the current load of the heated line is accomplished by biasing the transformer magnetic system. The maximum possible melting current is determined by the overload capacity of the transformers.

Fig. 3 shows an example of using a device in a ring network with two-transformer substations A and B. Busbar systems of 16 substations receive power through the lines 17 and 18 of the ring. Switchgear 15 is switched on rassechku line 18. Ice melting is conducted on line 17 by magnetizing transformers of substations A and B. At substation B, the ring is opened by switching device 15. Similarly, by corresponding switchings, ice can be melted in other parts of the ring.

39717 Thus, the biasing of the transformers allows an increase in the current in the line and leads to the melting of the ice on the single-circuit power lines, which expands the field of application of the device.

In addition, the magnetization of trans-1Q formers allows an increase in the current in the heated line when melting ice on double-circuit transmissions and ring systems by the method of load redistribution, which increases the melting efficiency by 1g.

Claims (1)

Invention Formula A device for melting icing 2Q on power lines without disconnecting consumers, containing two three-phase three-rod transformers connected between a power line and a load, in which 25 windings of one of the sides of the same name are connected in a triangle, the beginning of the second side of the like windings are combined to form conclusions The ends of the windings on the second side of the second side of each transformer located on the extreme rods of each transformer are interconnected, characterized in that the possibility of melting ice on single-circuit transmission lines and increasing the efficiency of melting ice, it additionally introduces a DC source and two resistors shunted by switching devices, each of which is connected to the ends of the second side windings of the transformers by one of its terminals the other, with the point of connection of the ends of the windings of the second side of one of the transformers located on the extreme rods and with one of the terminals of the DC source. 35 40 45 Phage2 L p / st.A Editor A. Kozoriz P1st.B FIG. Compiled by V. Topelberg Tehred M.Hodanich Proofreader V.Girn to Order 4235/47 Circulation 617 Subscription VNISh State Committee of the USSR for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, Projecto st., 4