DK200000086U3 - Flexible and adjustable recirculation module for wind turbines - Google Patents

Description

DK 2000 00086 U3

Description: 1.0. Denominations

Flexible and adjustable recirculation module for wind turbines 1.1. Scope of production:

The production allows the installation of a built-in module in a wind turbine tower, where the flexibility of the module allows, with minimal modifications, to adjust the construction so that it can be used in the wind turbine roof of any Danish wind turbine manufacturer.

The generation is a completely independent module, which can be placed on the molded toe foundation, after which the bottom section of the wind turbine toe can subsequently be freely immersed in the foundation without noticeably modifying the toe section.

The built-in module can advantageously be used in very wet areas where it is very difficult to establish a previously known transformer foundation, most often in porous soil, the external wind turbine barrel. In addition, the generation will also be advantageous for offshore projects where all electrical components are protected from external corrosion, such as saline air, and liquid ingress.

In addition, the built-in module allows, in areas where the municipality or counties require special locations or designs, in the traditional solution form. Here we think of areas where it is thought that remotely located transformer stations are detrimental to the surrounding terrain.

The built-in module is thus a substitute for the previously known externally located station building, in which all electrical components are assembled and which, in addition, are visually removed from the vicinity of the wind turbine, whereby the wind turbine will appear stylish in the terrain.

1.2. Prior art

However, other known techniques also allow the station building to be compressed and moved into the wind turbine, but with this technique, it is not possible to get the transformer out through the door section of the toe section.

Previously used techniques are not constructed in such a flexible way that. The unit can easily be adapted to all types of wind turbines manufactured in Denmark.

DK 2000 00086 U3

Furthermore, the prior art does not provide optimal personal protection, in the form of a mechanical lock-in to live parts.

With reference to previously used standardized transformer stations, it was a necessity, for electrical protection on the secondary side of the transformer, to mount either fuses or circuit breaker. This protection can be completely overlooked when using the built-in module, as the connection between the transformer connection terminals and the windscreen's bottom control is very short and completely protected against accidental corrosion.

Accidental corrosion on the live system is physically impossible, since the safety device mentioned above only gives access to the transformer room when the voltage is switched off. The low voltage cables are readily available when accessing the transformer compartment.

With the prior art, the transformer and high and low voltage components are installed in an external wind turbine bar in a transformer station.

This technique requires more space around the wind turbine, thereby reducing the landowner's ability to cultivate the agricultural land subsequently. Furthermore, this form of solution requires the establishment of a molded foundation for the location of the station building and, most often, becomes difficult due to porous backfill materials around the wind turbine.

The technical problem to be solved

In order to make the wind turbine appear stylish and simple in the terrain, it is more often desired to remove the traditional transformer building from the vicinity of the wind turbine.

Since, for reasons of power loss, it is a necessity to place the transformer itself as close to the wind generator as possible, the only solution is precisely to place the transformer internally in the tower section of the wind turbine.

On the same footing as the traditional solution, a great replacement flexibility is desired, which means that the transformer can be effortlessly extended out through the door section of the toe section. With this creation, the desired flexibility is achieved. ........; .........

For the purpose of the toe section type approval, no major modifications to this ._______ can be made.

Wind turbine manufacturer's standard toe section. need only be modified at a single point in order to be immersed .over, the building module. This modification only involves moving the welded fittings to the windmill's control unit and communication unit, approximately ~ 3 meters further up the toe section.

The electrical protection in front of the transformer and the wind turbine is a so-called fuse load separator, which is mounted at medium voltage level. The mechanical operating mechanism of the fuse isolator is included as part of personal safety in that a specially designed triggering device on the door into the live parts is released only when the separator has separated to medium voltage level.

This allows servicing, without effort, to be carried out in and on the installation module itself, without risk of personal safety.

DK 2000 00086 U3 1.4. The new technique

The built-in module is designed in such a way that you can climb up on top of the built-in module via the mounted section of the toe section, and from here operate the wind turbine control unit and communication unit.

The top of the built-in module is constructed as a repos. The plate that forms the roof of the built-in module is made of aluminum floor plate. The reason why aluminum materials are chosen is that the magnetic fields that the transformer forms by induction cannot propagate up in the wind turbine control unit located immediately above the transformer.

The module is designed in such a way that the built-in transformer can easily be driven out through the door of the wind turbine, in the event of a failure. However, the door section door must have a minimum width of 700mm.

Due to the special feature of the built-in module, the transformer can be easily extended through the door of the tower section, the built-in module is raised on legs, level with the bottom of the door, and is furthermore prepared for mounting rails on which the transformer can be driven out into the open. . When the transformer is free from the door section of the toe section, with a mobile crane it can be hoisted on a truck, and possibly. put a replacement transformer in place in the built-in module.

The rails are one secondary component that is part of the production.

The built-in module can be adapted to the individual project so that it does not have any immediate impact on the design, whether a solution model with high voltage meter or low voltage meter, for distribution of produced and recorded power, is selected for the individual wind turbine.

In view of the power output of the transformer at idle and full load losses, the built-in module is designed in such a way that shaking at the bottom and top ensures a natural air flow into the transformer space, thereby substantially reducing the temperature rise of the transformer windings.

The grate in the dog of the transformer compartment can be further fitted with a fan so that better ventilation is achieved. This solution is only relevant when the transfonder_stortglse reaches 1250KVA and above. The wind turbine manufacturer's control unit is not designed to withstand a significant internal temperature rise. Therefore, the building module is designed in such a way that the heat from the transducer volume is not dissipated through the control unit together with the low voltage cables, but on the other side of the unit.

The p.t. most suitable materials are, as described aluminum sheet, and in addition galvanized steel profiles for the structural parts of the structure.

1.5. The technical turmoil

The technical effect of the production is that it is no longer time-consuming and resource-consuming, in the construction phase, to establish a sustainable foundation for the traditional station building, but on the other hand simplifies the stylish appearance of the windmill in the surrounding terrain.

DK 2000 00086 U3

The generation is ideal for wind turbines, which are set up in very wet areas, or directly offshore projects where it is not physically possible to erect a traditional station building next to the wind turbine.

The built-in module provides the necessary material and personal protection, since the module is designed in such a way that a mechanical safety device ensures that the system is voltage-free before people have access to live parts.

1 #

The construction of the built-in module is designed in such a way that the problem of, in the event of failure, getting the transformer out of the door section of the toe section is solved. In addition, no modifications to the doorway are required as the physical dimensions of the transformer are adjusted.

The top of the built-in module is made of materials such that any magnetic influences on the wind turbine control unit are significantly reduced.

The built-in module solves the problem of temperature rise internally around the transformer windings as the design allows for the natural flow of air in the transformer mist. Furthermore, the built-in module is designed in such a way that the hot air is not fed into the wind turbine's control unit.

1.6. drawing Explanation

Drawing 1: The drawing shows a 3D sketch of a built-in module, which is placed in the windmill's toe section.

Drawing 2: Sectional drawing showing the location of the assembled components.

Drawing 3: Sectional drawing showing how the dry barrel former can be extended through the doorway in the bar section section.

Drawing 4: 3D Drawing showing the basic construction of the supporting parts. ...

1.7. Udførelseseksenrpler

Figure 1 shows what the device in the wind turbine looks like when the built-in module is located at the bottom of the toe section. The example shown shows how to constantly use the wind turbine ladder to climb on top of the built-in module and for that matter. also up in the windmill's nacelle. It is also partly seen from the drawing that the left door of the recessed module is provided with a safety device which must be released before it is possible to open the two doors.

The example shown is extended with high voltage meters in the module side of the ladder.

Drawing 2 illustrates that the transformer can be driven out through the door section of the toe section. Furthermore, the door's safety device is outlined. The drawing gives a picture of how much space the built-in module occupies at the bottom of the tower .__

Drawing 3 shows that the transformer has been pushed out through the doorway and is in the process of being lifted away by a mobile crane. The drawing also illustrates the position of the rails for the transformer

Claims (7)

DK 2000 00086 U3 Pkt. 12: Appendix: Use model protection requirements: 1.0. Flexible and adjustable built-in module that can be used to integrate transformers and switchgear in the windmill's toe section. 2.0. Built-in module as requirement 1.0, and which is distinguished by being able to be adapted to a Danish manufactured wind turbine tower section. 3.0. Built-in module as requirement 1.0. and 2.O., and which are provided with aluminum repos, which protect against propagation of magnetic fields from the transformer, to the wind turbine control unit. 4.0. Built-in module as requirement 1.0. and 3.0, and designed in such a way that the natural air flow in the tower of the wind turbine can cool the transformer in an efficient manner, without, however, exposing the wind turbine control unit to an inappropriate temperature rise. 5.0. Built-in module as requirement 1.0. to 4.0., which is adapted to the windmill's toe section, in such a way that the integrated transformer can effortlessly bounce directly out of the door section's doorway, simply by mounting a set of specially constructed rails having such a carrying capacity that the transformer can are driven out into the open, and subsequently lifted off by a mobile crane. 6.0. Built-in module as requirement 1.0. to 5.O .. and designed in such a way that accidental touching of live parts, in connection with servicing, is eliminated as much as possible. 7.0. Built-in module as requirement 1.0. to 6.0., and designed in such a flexible manner as to enable the integration of either high voltage meter or low voltage meter,