SE460239B - Encapsulated electrical mains station - Google Patents

Abstract

The above-ground encapsulated mains station contains high and low voltage equipment and a transformer with conrolled ventilation hatches in the station walls. It has one main chamber in which the high and low voltage equipment (1,3) and the transformer (2) are located without screening walls. The high voltage equipment has devices for pressure unloading directly into the free atmosphere when an electrical fault occurs, and the ventilation hatches (5,6) are manually or automatically controlled so that ventilation air for the transformer is conducted towards the high and low voltage equipment to heat them by waste heat from the transformer. The hatches are of the plate type, and a control comprising temp-sensitive metal automatically controls the hatches dependent upon the monitored temp. conditions inside the station.

Description

460 239 2 1) the network station must be designed with a common space for high and low voltage equipment and transformer, 2) the high voltage equipment of the substation be equipped with devices for pressure relief out in the open in the event of a power failure in the normal way so that people in the environment of the station can not be damaged, and 3) manually or automatically controlled ventilation hatches be made in the walls of the station in such a way that the ventilation air from the transformer is led against the electrical equipment to heat them by means of ventilation the air transported loss heat from the transformer.

So far, the "booth thinking" has been the only thing that exists in this hang, ie it has been considered absolutely necessary from a safety point of view to arrange the voltage equipment, the low voltage equipment and the transformer in separate spaces. Then the transformer space will further serve as a pressure relief space in the event of a power failure in the high voltage equipment, it has been necessary to do so space is relatively stable to withstand the compressive forces.

By equipping the high voltage equipment with special pressure relief devices as proposed in the present invention can be used in unexpected ways depart from the above-mentioned previous construction method, with several different rooms, which previously considered absolutely necessary at substations, and with pressure relief into the matorutrymmet.

This also makes it possible to utilize waste heat from the transformer for heating purposes by setting up specially arranged, controllable ventilation hatches.

Control of the loss heat takes place with manual or automatic control of the ventilation hatches with eg temperature-sensitive memory metals. Such for memory metals suitable for this application are previously known and may consist of alloys, which, for example, shrink when exposed to an increasing temperature.

This movement is then used to open or close the ventilation system. the gaps. In practical application, care must be taken to ensure that it is temperature sensitive the memory metal device is positioned so that it senses the temperature appropriately place inside the station, at the same time it is desirable that it is located as close as possible to the ventilation hatch it is to control, since it facilitates the transfer of the movement of the memory metal device to the ventilation the door for its operation.

The realization of the invention is facilitated by modern electrical equipment for high voltage has become less susceptible to fouling due to the The risk equipment is built into hermetically sealed enclosures, often insulated with special dried gas, eg of type SF6 (sulfur hexafluoride). 460 239 At low temperatures, the SF6 gas can condense and the present invention also contributes to condensation not taking place.

The method of construction of the station enclosure according to the invention involves, as mentioned, that the normal internal shielding of the transformer and switchgear will be abolished and the station will thus be easier and cheaper to manufacture. In addition contributes to the fact that the transformer space is not used as a relief room without the high-voltage switchgear is relieved, in the event of a fault, straight into it free.

Furthermore, at the station according to the invention heat loss from the transformer for heating, thereby partly saving the installation of special heating equipment and partly saves special energy supply for heating purposes.

An exemplary embodiment of the network station according to the invention will be described in more detail below with reference to the accompanying drawings. on which Fig. 1 shows the network station according to the invention in cross section in plan view, Fig. 2 shows the network station according to the invention in cross section in a side view, Figs. 3-6 show the network station according to the invention in different side views, Fig. 7 shows in cross section a part of a station wall with a disc valve seen ventilation hatch, Fig. 8 schematically shows an embodiment of automatic temperature control of a plurality of poppet valves, Figs. 9 and 10 show an embodiment of a device for directing the blowing from a relief channel in the retracted or unfolded position, Figs. 11 and 12 show another embodiment of a device for direct the exhaust from a relief duct in the closed or open position, and Fig. 13 shows a section through the plane B-B in Fig. 12.

As shown in Fig. 1, the walls of the network station limit a single, contiguous space for both high and low voltage equipment 1, 3 as well as for the transformer and the transformer 2 is centrally located with high and the low voltage equipment on either side of the transformer.

At 4, a ventilation hatch for intake of ventilated air is displayed out of the power station through the ventilation slots 5 and 6. The ventilation slots 4-6 are placed on different side walls of the mains station and the ventilation hatch 4 for air intake is located at the bottom of the wall below the ventilation hatches 5 and 6 for the discharge of ventilation air are located at the top of the station side walls, cf. Figs. 3-5. In this way, the air taken in through the door 4 will first pass the transformer 2 for cooling it, then the ventilation air 460 259 passes towards and past the high voltage and low voltage equipment for heating these if necessary, before the air passes out through hatches 5 and 6. On in this way, the heat of loss from the transformer 2 will be used for heating of the electrical equipment 1, 3. Fig. 2 shows the ventilation air flow directions.

To regulate the air flow, the ventilation shutters 4-6 are open variable. The ventilation hatches can be controlled manually or automatically depending on the temperature conditions. For automatic control, a temperature turn-sensitive memory metal control is advantageously utilized as described above.

The temperature control itself takes place by varying the ventilation shutters 4-6 opening.

The ventilation hatches 4-6 can alternatively be designed as poppet valves according to Fig. 7. This valve comprises a tube 13, which passes through the station wall. At the outside of the ventilation pipe 13 a hood 14 is arranged, which hood has larger diameter than the tube so that an annular outlet 16 is obtained at the tube mouth. On a shaft 18 extending through the ventilation pipe 13 is a plate 20 rotatably arranged at the inlet side of the drum. In this plate 20 and in the inlet end of the ventilation pipe 13 are openings 22 and 24, respectively, wherein the opening of the valve is varied by rotating the plate so that the two the openings 22, 2§ will overlap each other more or less.

Disc valves are used in the outlet openings 5, 6 while the intake valve 4 suitably has a different construction so that the inlet area will be sufficient Big. The outlets are here suitably formed by a plurality of plates arranged in a row. valves, which replace the elongate openings 5 and 6 in Figs. 4 and 5, respectively.

Automatic control depending on the temperature can be done in a simple way provided with an arrangement according to Fig. 8.

The plates are connected to a spring-biased rope 54. The spring 56 strives to turn the plates 20 to the closed position. At the other end of the line 54 acts a temperature-sensitive element which generates a tensile force at increasing temperature in the line 54, which overcomes the spring force and turns the discs 20 into one more or less open position of the valve, depending on the temperature. Rotary movement then is maximized to 450.

For pressure relief in the event of a power failure in the high voltage switchgear 1 is a pressure relief channel or drum 12 arranged at the upper of the switchgear 1 part, see Fig. 1, which channel 12 opens into the open through relief openings 7, 8 in the walls of the substation, cf. also Figs. 3 and 6. Through these openings take place a targeted blowout to reduce the risk of accidents. Through this pressure loading directly into the open air, the entire station space can be exposed, which required to achieve the benefits of the invention. 46U 239 The figures show an embodiment with two openings 7,8 in two opposite ones station walls. For some applications, however, only one relief option is sufficient.

By providing the relief openings 7,8 with a specially designed device order for directional exhaust, you can deflect the exhaust close to 900 and direct it upwards. Figures 9 and 10 show a first embodiment of such a device to direct the blowout. It comprises an arrangement of foldable sheet metal hatches as shown in Fig. 9 in an unaffected position in the unloading opening 25.

In the event of a pressure increase inside the station, the hatch arrangement in the relief opening part 26 and in a first stage the part 31 is folded out of the opening and into one in the second stage, the part 32 is also unfolded. During the first stage, the hatch the arrangement around a pivot point 28 at the lower edge of the opening and in the other the stage rotates the part 32 about the pivot point 30 at the transition between the part 31 and part 32.

At 34, 36 and 38 abutments are shown and during the first stage it thus moves stops 34 and 36 from the position shown in Fig. 9 to the position shown in Fig. 10 and 38 to the dashed position in Fig. 10 and during the second stage moves stroke 38 along the path indicated by dashed lines.

The part 32 has an opening 40 which in the position shown in Fig. 9 is directed upwards so that the exhaust will be directed in this direction. At the described In this embodiment, the opening 40 will be at a distance from the station road. outside, so that the exhaust passes outside any roof projections on the network the station.

The relief opening 26 in the embodiment shown in Figs. 9 and 10 has suitably rectangular cross-section and the hatch arrangement a corresponding shape.

An alternative embodiment of the device for providing upward movement exhaust is shown in Figs. 11-13. It comprises two interconnected tubes 42, 44, of which the inner tube is displaceable in the axial direction and has a smaller diameter so that a gap is formed between the pipes. In the embodiment shown, the pipes have circular section but they can also be square.

In the upper side of the inner tube 44 an opening 46 is cut out, see Fig. 13.

The mouth of the inner tube 44 is provided with a hood 48, as shown in FIG. 11, the closed position sealingly abuts against the outside of the wall around the relief the opening.

Around the outside of the relief opening a ring 50 is arranged and at the inside the rear end of the tube is provided with a flange 52, which partly serves as a guide at it the movement of the inner tube 44 inside the outer tube 42, and partly as a stop stop against ring 50, when the inner tube 44 has reached the fully extended position (Fig. 12) as a result of a pressure increase, which corresponds to the maximum open relief opening. 460 239 and 6 A plurality of defrost openings formed in this manner may be provided. in a row up at the station, in the position of the deviations shown in Figs. 3 and 6. the openings 7, 8.

The network station has two operating sides, namely high and low voltage side.

The high-voltage equipment is operated via doors 9 and the low-voltage equipment via the doors 10, cf. also Figs. 4 and 5. The ventilation hatches 4 and 5 are operated in manual control, through the doors 9 while the ventilation hatch 6 with benefits are served through the doors 10.

To monitor the temperature of the transformer, a thermometer 11 is provided at this. The thermometer 11 can advantageously be read via the doors 9, since the the format door at conventional network stations is omitted at the station according to the invention, which further simplifies and bypasses the station. li II

Claims (9)

7,460,239 Patent claims Encapsulated overhead network substation with electrical power distribution equipment, including high and low voltage equipment and a transformer, controlled ventilation hatches being provided in the station walls, characterized in that the station is designed with a coherent internal outlet, in which the high and low voltage equipment (1,3) and the transformer (2) are located without shielding walls and that the high voltage equipment is equipped with devices for pressure relief directly into the open in the event of electrical failure, and the ventilation hatches (4-6) are manually or automatically controlled and arranged in the walls of the station in such a way that the ventilation air for the transformer is directed towards the electrical high and low voltage equipment for heating them by means of loss heat from the transformer. Station according to claim 1, characterized in that a ventilation hatch (4) for intake of ventilation air is arranged in the lower part of a side wall next to the transformer (2), and in that two ventilation hatches (5,6) for drainage of ventilation air are arranged in the upper part of each side wall (9,10) perpendicular to the wall with the intake door, the high and low voltage equipment (1,3) being located next to said side walls with drainage hatches. Station according to claim 1 or 2, characterized in that control means, comprising temperature-sensitive memory metal, are arranged to automatically control the ventilation hatches (4, 6) depending on sensed temperature conditions inside the station. Station according to Claim 2 or 3, characterized in that the ventilation doors are of the plate type (13, 14, 16, 18, 20, 22, 24, 24). Station according to one of Claims 1 to 4, characterized in that the pressure relief devices comprise a relief channel (12) extending at the upper part of the high-voltage equipment, which opens into the open air through at least one opening (7, 8) in the station wall. Station according to claim 5, characterized in that the mouth of the relief channel (12) is provided with a device (31,32,34,36,38,40; 42,44,46, 48,50,52) for to direct effluent gases substantially vertically upwards. Station according to claim 6, characterized in that said devices comprise a hatch arrangement (31, 32) which is expandable in two steps, from a recessed position inside the mouth of the relief channel (12) to a recessed position in response to a pressure increase in the relief channel, the door arrangement being arranged to thereby form an upwardly directed exhaust opening (40) at a distance from the outside of the station wall. 460 239 m Station according to claim 6, characterized in that said device comprises two tubes (42,44) arranged in each other, wherein the outer end of the inner tube is joined and its side wall is formed with an upwardly directed opening (46), and the inner tube is displaceable in the axial direction in response to an increase in pressure in the relief channel to expose the upward opening. Station according to claim 8, characterized in that the inner tube (44) and the mouth of the discharge duct are provided with cooperating stop means (50, 52) for stopping the movement of the inner tube, when maximum open position is reached. u!