DE29804513U1 - Substation in compact design - Google Patents

Description

BATHROOM 101/FLOOR/DE

Applicant: Badenwerk AG, Karlsruhe, DE

Compact transformer station

The invention is directed to a transformer station in a compact design. Such transformer stations are used primarily in local network supply to convert a medium voltage (in Germany between 12 and 36 kV, in other countries sometimes up to 52 kV) into the distribution voltage of the local network (usually 0.4 kV). They have three main components, namely a transformer and a switchgear on the high-voltage side and on the low-voltage side of the transformer. The high-voltage side switchgear is referred to here as a high-voltage switchgear, although as explained it switches a medium voltage in the sense of network technology.

In earlier times, transformer stations were manufactured as individual buildings. For several decades, however, factory-built compact stations have become increasingly common, the housing of which is usually made of precast concrete. Such factory-built

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Compact substations must meet a variety of sometimes contradictory requirements.

On the one hand, they should have as small a volume as possible. It is becoming increasingly difficult for energy supply companies to obtain approval to place a substation in a technically suitable location. The decisive factor is that the station is as small and inconspicuous as possible so that its construction is accepted even in built-up areas (for example in front gardens). A design that is as compact as possible and a low weight is also important with regard to the transportability of the station. Ideally, the station, including the pre-installed equipment, should be transportable using the construction vehicles commonly used in this area (which are also used to transport cable drums, for example).

On the other hand, the possibility of reducing the size of the station is limited by the requirements for its function, especially in terms of usability, low noise and safety. The assembly, maintenance and testing of the station equipment requires good accessibility and therefore sufficient free space within the housing. The more compact the design, the more problematic noise insulation becomes.

Safety in the event of a malfunction is a particular problem. The relevant standards set strict criteria for safety. For example, IEC 1330 recommends an arc safety test for factory-assembled substations. If an arc fault (i.e. an arc between two components due to a malfunction) occurs during operation within the high-voltage switchgear,

When an explosion occurs (e.g. between conductive components with different electrical potentials), a strong and hot gas blast is created. This gas blast is also known in technical jargon as an "explosion pressure wave". Even if the process of igniting and burning a fault arc in the high-voltage system is not to be regarded as an explosion in the true sense of the word, this term illustrates the strength and intensity of the spread of hot gases. They spread almost explosively in the station housing and escape through its ventilation openings. Since the installation locations of compact stations are usually accessible to everyone, the risk of injury must be avoided even in unfavorable cases in which a person is in the immediate vicinity of the ventilation opening. This is understandably more difficult to achieve the more compact the building is.

In order to meet these requirements and still achieve the most compact possible design of at least the visible part of the substation, stations have been proposed that are suitable for partial submersion into the ground ("partial underground stations"). One such station is described in EP 0209027 Bl, for example. Underground constructions do reduce the visible external dimensions after installation. However, the raw dimensions, which are crucial for transport, weight and manufacturing costs of the housing, are not affected by this. The thermal and safety problems are further exacerbated because ventilation openings are naturally only possible in the above-ground area of the station housing.

In order to achieve an improved solution with regard to these diverse requirements, the invention provides a transformer station in compact design, in particular for

partially sunk into the ground, with a transformer, a high-voltage switchgear, a low-voltage switchgear and a housing that can be closed by means of a cover, in which the transformer is positioned below the high-voltage switchgear in a common chamber.

The arrangement of the transformer below the high-voltage switchgear does not necessarily mean that the switchgear is positioned vertically above the transformer. Rather, an embodiment is also possible in which the high-voltage switchgear is offset horizontally from the transformer, i.e. is arranged diagonally above the transformer. However, with regard to a particularly compact design, a design in which at least parts of the high-voltage switchgear are located vertically above the largest cross-sectional area of the transformer is particularly preferred.

In contrast to the station according to EP 0209027 Bl, the transformer and the high-voltage switchgear in the invention are located in a common chamber in which a substantially unhindered gas exchange is possible. This open construction facilitates the assembly and maintenance of the equipment. Preferably, the transformer and the high-voltage switchgear are attached to a common support structure, for example a frame made of steel profiles, in such a way that they can be removed from the chamber together. In a partially underground construction, this is done by pulling them out upwards, with the opened cover revealing a sufficiently large section of the upper cover surface, preferably the entire clear cross-section at the upper end of the substation.

The design according to the invention initially appears to be unfavorable for thermal reasons because, on the one hand, the waste heat from the transformer, which becomes hot during operation, rises from its cooling surfaces to the high-voltage switchgear and puts a thermal load on it, and, on the other hand, because, in the case of a partially underground construction, the transformer is arranged in the unventilated part of the housing that is thermally insulated by the ground. However, within the scope of the invention it was found that, despite these concerns, no serious thermal problems arise. In fact, a particularly favorable combination of extremely compact dimensions and high safety in the event of an arc fault is achieved. The gas surge that occurs in the event of an arc fault in the high-voltage switchgear is preferably directed downwards in the direction of the transformer.

The invention is explained in more detail below using an embodiment shown schematically in the figures. These show further preferred embodiments that are used individually or in combination in the invention. They show:

Fig. 1 A longitudinal section through a transformer station according to the invention,

Fig. 2 A side section through the substation according to Fig. 1,

Fig. 3 A side section corresponding to Fig. 2 during the replacement of the station equipment.

The transformer station 1 shown in the figures has a substantially cuboid-shaped housing 2. The housing is embedded in the ground 4 with its lower section 3.

lowers, while its upper part 5 protrudes above the ground surface 6. Preferably, the lower section 3 is larger than the upper section, i.e. the housing 2 is sunk more than halfway into the ground. The height of the upper section should not be significantly more than 1 m (maximum 1.1 m).

The upper section 5 of the housing 2 has an assembly and operating opening 8, which makes at least a large part, preferably the entire clear cross-section of the housing 2 accessible from above. Advantageously, the assembly and operating opening 8 extends not only over the upper cover surface 9, but also over part of the front surface 10 of the upper section 5 of the transformer station 1 protruding from the ground 4. It can be closed with a cover lid 11 that is L-shaped in side section. It is pivotably attached to the upper edge of the rear wall 13 of the lower part 7 of the housing 2, which is designed as a prefabricated concrete part.

It is particularly advantageous if - as shown - a removable wall plate 12 is provided on the front 10, adjacent to the shorter leg of the L-shaped cover 11. For normal maintenance and operating work, it is sufficient to open the cover 11. The wall plate 12 prevents tools or other objects from accidentally falling into the interior of the station 1. On the other hand, it can be loosened (preferably with a simple lock) and removed if access to the depth of the station is required for special repairs.

Inside the station 1, in a common chamber 14, there is a transformer 15 and above it a high-voltage

Switchgear 16 is positioned. These two devices are attached to a common support structure 17 in the form of a steel frame in such a way that they can be inserted into or removed from the chamber 14 as a functional unit 18 by means of a crane (of which only the hook 19 is shown in Figure 3).

The high-voltage switchgear 16 is preferably gas-insulated, i.e. its switches are enclosed in a hermetically sealed enclosure filled with a gas that is good at insulating electrical power (sulfur hexafluoride is common). To facilitate simple operation, it is advantageous if it is mounted in such a way that its operating surface 20, as shown, is oriented at an angle upwards.

To increase safety in the event of an arc fault, as explained, the gas flow in the housing 2 is preferably designed in such a way that the gas blast emerging from the high-voltage switchgear 16 is directed downwards in the direction of the transformer.

An encapsulated high-voltage switchgear usually has a bursting disk 22 in the event of an arc fault, which in the embodiment shown in the figures is located on the rear wall of the enclosure and is shown in dashed lines. A baffle plate 23 is provided behind the bursting disk 22 as a gas guide element, which in the event of an arc fault deflects the gases escaping through the bursting disk 22 backwards and then, in conjunction with the design and positioning of the high-voltage switchgear 16, downwards towards the transformer (arrow 24). Preferably, the gas surge continues parallel to the cooling elements (which run vertically on the sides of the transformer 15).

surfaces 25. Although the cooling surfaces 25 are hot when the transformer 15 is in operation, this results in a highly effective reduction in the temperature and the flow rate of the explosively escaping gases.

This effect is further improved if, according to a particularly preferred embodiment, the gas jet is directed in such a way that it is guided around the transformer, first downwards on a first side (arrow 24), then horizontally below the transformer (arrow 26) and finally upwards again on a second side of the transformer (arrow 27). Finally, the gas jet exits through ventilation openings (not shown in the figures) in the upper section 5 of the housing 2 protruding from the ground 4. These can be provided in particular in the front wall 10, both in the vertical section of the L-shaped profile of the cover 11 and in the removable wall plate 12.

In the embodiment shown, such a gas flow is achieved through the interaction of the baffle plate 23, the cooling surfaces 25 running on both sides of the transformer 15 and through a gap 29 in the base 28 of the transformer. The elements 23, 25 and 28 thus form a gas guide which brings about the desired steering of the gas pulse around the transformer.

As explained, the transformer 15 and the high-voltage switchgear 16 are housed together in a single chamber 14, which can be referred to as the main chamber of the station. This does not, of course, exclude the presence of intermediate supports within the main chamber 14. An intermediate floor extending over part of the cross-sectional area can also be provided.

However, such installations should be designed in such a way that a free exchange of gas within the main chamber 14 (in particular the flow of the gas pulse described in the event of an arc fault) is possible.

In the most general form of the invention, the low-voltage switchgear can be positioned within the housing 2 - preferably in a chamber 31 separate from the main chamber 14. However, a modular construction of the station 1 is preferred, in which the low-voltage switchgear 30 is located in a module 32 that can be detachably attached to the outside of the station. The cable connection between the low-voltage switchgear 30 and the main chamber 14 is led directly through a rear wall 33 of the module 32 that is adjacent to the housing 2 of the station 1 when attached. For the sake of clarity, only the opening 34 in the wall of the housing 2 intended for this cable feedthrough is shown in Figure 1.

The modular construction of the low-voltage switchgear 3 0 enables a flexible design in which a low-voltage switchgear 30 can be used either on each side of the housing 2 (a second low-voltage switchgear is shown in dotted lines in Figure 1) or as a spatially separate component of the substation 1.

In order to ensure a sufficiently large bending radius of the high-voltage cable 34 leading to the high-voltage switchgear 16 while at the same time keeping the dimensions of the housing 2 minimal, the corresponding wall (here the front wall 3 7) of the lower section 3 of the housing 2 has a bulge with a downwardly inclined

Section 35, in which the moisture-proof cable bushing for the high-voltage cable 34 is arranged. For similar reasons, the design of the plug connection for the high-voltage switchgear shown in Figure 3 is
16 is advantageous, in which the cable 34 is inserted into the plug 3 6 transversely to its plugging direction.

Claims (11)

BAD 101/OG/DE Claims 1. Transformer station (1) in compact design, in particular for partial submersion in the ground (4), with a transformer (15), a high-voltage switchgear (16), a low-voltage switchgear (30) and a housing (2) that can be closed by means of a cover (11), characterized in that the transformer (15) is positioned below the high-voltage switchgear (16) in a common chamber (14). 2. Transformer station according to claim 1, characterized in that at least one part (7) of the housing (2) is designed as a precast concrete part. 3. Transformer station according to claim 1 or 2, characterized in that the transformer (15) and the high-voltage switchgear (16) are fastened to a common support structure (17) in such a way that they can be removed together from the chamber (14). 4. Transformer station according to one of the preceding claims, characterized in that the operating surface (20) of the high-voltage switchgear (16) is oriented obliquely upwards for operation from an elevated position. 5. Transformer station according to one of the preceding claims, characterized in that the high-voltage switchgear (16) is encapsulated with gas insulation. 6. Transformer station according to one of the preceding claims, characterized in that the high-voltage switchgear (16) is designed and positioned such that a gas blast emerging from the high-voltage switchgear (16) in the event of an arc fault is directed downwards in the direction (arrow 24) towards the transformer (15). 7. Transformer station according to claim 6, characterized in that the gas jet is directed parallel to the cooling surfaces (25) of the transformer. 8. Transformer station according to one of claims 6 or 7, characterized in that the gas jet is directed around the transformer (15) on a first side downwards (arrow 24), below the transformer (15) horizontally (arrow 26) and on a second side upwards (arrow 27). 9. Transformer station according to one of the preceding claims, characterized in that the low-voltage switchgear (30) is arranged in a separate chamber (31), outside the main chamber (14) containing the transformer and the high-voltage switchgear. 10. Transformer station according to claim 9, characterized in that the separate chamber (31) is located in a module (32) which can be detachably fastened to the outside of the station. 13 11. Transformer station according to claim 10, characterized in that the cable connection between the low-voltage switchgear (30) and the main chamber (14) is directly
through a rear wall (33) of the module (32) which, when fastened, is adjacent to the housing of the station.