SU1092594A1 - High-voltage fuse - Google Patents

Abstract

A HIGH-VOLTAGE FUSED FUSE, containing a vertically mounted cartridge made of solid gas-insulating material, an internal and detectable electrodes connected to a fusible insert consisting of a hollow cylindrical dielectric holder with a liquid non-conductive filler, an upper and lower sealing lip, and a nozzle holder and a liquid non-conductive filler, an upper and lower sealing lip, and an upper and lower sealant nozzles and a liquid dielectric holder with a liquid non-conducting filler, an upper and lower sealing lip, and an upper and lower sealant nozzles and a liquid dielectric holder with a liquid non-conducting filler, an upper and lower sealing lip and nozzles. of a fusible element having a high-resistance part from below, which are t and chats, so that, in order to expand its functionality and speed overload currents, the upper sealing tip is equipped with an alloy element with an additional dielectric bushing, the internal cavity of which is connected to the bottom of the i cavity of the holder, and the high-resistance part of the fusible element to the whole high (L that is immersed in the liquid filler.

Description

The invention relates to a high-voltage electrical apparatus, namely, shooting fuses producing electric arc extinguishing in a gas stream generated by the cartridge of the fuse itself under the influence of a high electric arc temperature, and can be used to protect low-power power-down transformers at substations 35 / 0.4-10 kV and 110 / 0.410 kV from the side of their higher voltage. It is known that the main drawbacks of modern 35/110 kV fuses are their low sensitivity to overload currents and the delay in disconnecting damage at short circuit currents of small magnitude. The fuse-links of these fuses are made of inertialess well-conducting material, such as copper or silver, and cannot damp the starting currents of the motors behind the transformer and the currents of external short circuits on the lines 0.4-10 kV. Therefore, in order to rebuild them from the indicated currents, it is necessary to choose vkie insert the rated current exceeding the rated current yuschy protected transformer in at least two or more -raz, for these purposes would come up inertia onnye fusible inserts made from tin or lead. Such inserts could be selected by the nominal current of the transformer. Then they would be able to ensure the sensitivity of the fuses to small overloads of transformers and would allow them to be rebuilt due to their massiveness from the starting currents of the motors fed by the transformer and external short-circuit currents on the lines 0.4-10 kV. Such fuses allow Would it not be possible to damp, not a burst, short-term bursts of heating from starting motor circuits and short-circuit currents with external damages of 0.4-10 kV lines. However, fuses with such fuse-links would have a very small response time when short circuits in transformers from the 35 and 110 kV side. This is due to the fact that it would take a long time to heat and evaporate the body with a massive fusible insert. On the other hand, such fuses would have low switching capacity. The latter is explained by the large amount of metal vapors from the fusible insert, which are inserted into the electric arc channel inside the cartridge. They would be able to conduct the conductivity of the E channel of the arc, and therefore more difficult to extinguish it. Therefore, they are of great technical interest in the solution; providing the choice of instantaneous fusible plugs to protect step-down transformers that are able to sense small transformer overloads, work quickly with large short-circuit currents, operate relatively quickly with overload currents and simultaneously provide damping (pulling in operation) when the engine starts: short and external short closures of x, switched off by automatic switches and switches of 0.4 and 10 kV. Fuses are known in which fuse-links are made of inertia-free material, for example, copper, but they are sensitive to overload currents of small magnitude. The characteristics of these fusible copper and silver inserts (melting point is respectively 1080 and) can be improved by high-temperature soldering of tin or lead, the melting temperature of which is much lower (100 and 327 ° C, respectively). When the soldering metal melts, the latter dissolves refractory copper or silver in itself, as a result of which the insert quickly collapses at a temperature much lower than the melting point of the core material of the insert 1.1. However, with short circuits of any size, the fusion insert burns out in places where there is no overlap of tin or lead. This is due to the fact that with these damages, the fuses blow out quickly. Consequently, in order to detach from external short circuits on 0.410 kV lines, it will still be necessary to increase the cross sections of the copper (silver) part of the insert. This will also require the starting currents of the motors and the tokhs of magnetization of the transformers that arise when the transformers are turned on. As you know, they are 8-10; times the rated current of the transformer, however, for no more than a second or tenth of it. Therefore, the float of tin or lead will not provide damping of these currents and will need to be removed from them by means of making the body section of the fusible insert itself. At the same time, this could have been avoided if, by activating, the removal of heat from the body of the fusible insert to the ioment, the occurrence of these currents .. The heat sink could, with inrush currents and currents of external short circuits having a relatively small amount, dampen them, ensuring

required rapid cooling insert. With short circuits on the high-voltage input of a power transformer, when the currents reach very high values, the process of heat accumulation by a fusible insert is, as a rule, adiabatically without returning heat to the surrounding space, and then the melting time and the amount of metal vapor in the electrical channel the arcs would be determined only by the section of the fuse-link. In the construction of the known device, the heat sink at low currents is insufficient, therefore an increase in the cross section of the insert is required. And this, in turn, will reduce the switching capacity of the fuse and complicate its operation at low currents. On the other hand, the presence of tin or lead float can lead to false and non-selective operation of the fuses. The fact is that during external short circuits, fuse-insert heat-ups will be observed, which will lead to a gradual rolling of the float ball from the insert body, and this will lead to its insensitivity to overload currents that will occur after the rolling-up float. At the same time, on the contrary, conditions may arise when the insert will work falsely - with inrush currents and currents of external short circuits. The latter is explained by the fact that the most heated layer in the deposit is its part adjacent to the body of the fusible insert. Thus, being softened at a number of external damages, the solder will begin to penetrate into the body of the fuse-link even when the insertion of the insert is not required, i.e. it begins to accumulate the so-called aftereffect from external short circuits, residual phenomena. Gradually, they will lead to premature fusible plug activation when the damage should be switched off by a switch or circuit breaker on the 10 or 0.4 kV side. It is known that up to eight 10 kV lines can depart from each of the considered substations on the low-voltage side. So premature operation will lead to incomplete-phase modes, emergency undersupply of energy to the substation, and full repayment of the substation when the falsely triggered insert is replaced. All this creates great national economic losses.

Closest to the invention is a high-voltage fuse-junction fuse containing an installed vertically gas generating cartridge, made of solid insulating gas generating material, internal and external

electrodes interconnected by a fusible insert consisting of a hollow cylindrical dielectric holder with a liquid non-conductive filler of the upper and lower sealing tips and a composite fusible element having a high-resistance part of the bottom G2.

The disadvantages of the known device are the insensitivity to overload currents of small magnitude, due to the fact that during such overloads the heat sink of the filler occurs very quickly and the insert cannot accumulate enough heat to melt; low speed at medium values of overload currents and damage at the output of the transformer from the lower voltage side, which can also be explained by a fast heat sink from the fusible insert from the liquid filler side. It is known that oil in power transformers removes heat from windings 16 times faster than air can do.

The aim of the invention is to extend the functionality and speed at overload currents.

The goal is achieved by the fact that in a high-voltage fuse containing a cartridge mounted vertically and made of a solid insulating gas-generating material, the inner and outer electrodes connected by means of a fusible insert consisting of; From a hollow cylindrical dielectric holder with a liquid non-conductive filler, upper and lower sealing tips and a composite fusible element having a high-resistance part underneath, the upper sealing tip with a fusible element is provided with an additional dielectric bushing, the internal cavity of which from the bottom communicates with the hollow of the holder and the high-resistance part element to the full height immersed in a liquid filler.

In the drawing, the fuse design is given (as a cut-out in the area of the fuse-link).

The device consists of a cartridge 1, filled with an insulating solid gas-generating material, installed in a normal working position vertically or close to the vertical, as indicated in the drawing. The inner 3 and outer 4 electrodes are located in the inner cavity 2 of the cartridge, spring-loaded by the spring of the cartridge mounted, usually at the top, from the side of electrode 3. These electrodes are mechanically and electrically connected to each other by means of a fusible insert consisting of a high-resistance holder 5 rigidly glued to sealing tips 6 and 7, which are screwed to the upper electrode J and the lower 4, respectively. The electrical connection between the fuse electrodes is carried out by means of a conductive (smooth) element consisting of an upper, well-conducting part 8, having, for example, a larger cross-section, and a lower 9, having a lower conductivity, for example, with a smaller cross section . The upper tip 6 is provided with an additional dielectric sleeve 10. Inside it is the conductive element of the insert. The sleeve is sealed from above, and the memory is communicated with the internal cavity of the dielectric holder 5, At the high element of the conductive part, which has low conductivity, external 1 and internal 12 parts of the communicating vessels - holder 5 and bushings 10 are filled with liquid dielectric filler, for example, transformer oil , ether, alcohol, etc. The upper parts of cavities 13 and 14 are free and filled with air at normal atmospheric pressure. Through the axial holes 15 and 16 of the tips, the ends of the conductive (fusible) element are passed and soldered to the sealing tips at points 17 and 18. The solder layer at these points is used to seal the internal cavity of the fusible insert from ingress of external air or from the outflow and cavity liquid filler inserts. The latter could lead to a change in the time-current characteristics of the fuse-link. When starting the engines behind the transformer through the circuit breakers, the fuses installed in the three phases of the protected power down transformer begin to leak the starting current of these engines. It is several times the rated current of the transformer and lasts about 7-10 seconds. At this time, part 8 of the fusible link warms up slightly, so. as it has a high conductivity (or a larger cross section and the voltage of the transformer to react to damage currents during short circuits at the input of higher voltage and in the transformer tank. Low conductive part 9 also does not have time to heat to high temperatures, as it it is cooled by the filler of the fusible link - a dielectric fluid. Therefore, the insert does not react to the start of the engines behind the transformer. The same damping will be carried out by fuses both when it is put into operation and during short This is due to the short duration of disturbances and the insignificance of the current pulse. When a high short-circuit current occurs, when a two or three-phase short circuit occurs on the high-voltage BBOjie of the transformer the fusible element will warm up to hundredths of a second to its melting temperature at its entire height - between tips b and 7. This process takes place adiabatically without giving heat to the air in cavity 14 and the liquid inner part 12. It ends with the melting of a conductive element, evaporation of a fluid under the action of an arc and the explosion of a dielectric holder 5. The destruction of the base leads to the release of electrodes 3 and 4 of one from the other and their separation in different directions. In the gap between it1-1-1, a dielectric arc is ignited, which begins to affect the internal walls of cavity 2, the gas-generating cartridge 1 of the fuse. Gas begins to be generated from the walls, which forms a longitudinal gas blast going up and down the cartridge. In this case, the pressure can reach tens and hundreds of atmospheres. Under the influence of the gas flow, the electrode 4 is quickly ejected by the Nfuge, and the electrode 3 rises to its stop. The arc is gas deionized and cooled. After reaching the required gap between the electrodes 3 and 4, the arc goes out and the fuse turns off the protected phase of the transformer. Arc quenching occurs, as a rule, during cooling, the value of short circuit current through zero and is not accompanied by overvoltages. In the event of short circuits at the low-voltage output of the transformer — within the range of the fuses, the fault current will be several times greater than the rated current of the transformer. Part 8 of the fusible element will not react to this current. However, it will be significantly heated by it. In this case, the high resistance of the lower part 9 of the fuse-link will begin to rapidly release its heat to the filler of the inner part 12 and to heat it. The filler of the boil; em rapidly evaporates into the space of the VOLUME 14. The filler of the outer part 11 remains relatively cold due to the difficulty of ejecting from the filler of the inner part 12 through the wall of the sleeve 10 to the filler of the holder. Therefore, the gas pressure in the cavity 13 is practically the same. In cavity 14, on

Claims (1)

HIGH-VOLTAGE FUSE, containing vertically mounted cartridge made of solid insulating gas-generating material, internal and detection electrodes connected with a fuse-link consisting of a cylindrical dielectric holder with liquid non-conductive filler, upper and lower sealing tips and a compound fuse of an element having a high-resistance part from below, which is related to the fact that, in order to expand the functionality and speed, ah overload, the upper sealing member is provided with a tip s'plavkim additional dielectric sleeve, the inner cavity of which communicates with the bottom of a cavity holder, and the high resistance of the fuse element portion § full height submerged in the liquid vehicle. SU „, .10925> 1 092594