NO322750B1 - Method for de-icing a rotor blade for a wind power plant, as well as such a rotor blade - Google Patents

Abstract

In order to de-ice a rotor blade of a wind driven power station with communicating cavities (9, 10), an optionally preheated heat-transfer fluid is passed through the cavities by means of electric fans. Near the root of the blade, where the blade is connected to the rotor hub, means are provided for making the heat-transfer fluid flow into at least one cavity (9) located along the leading edge of the blade. Heat-transfer fluid flow channels that interconnect adjacent cavities are arranged at the blade-tip end (12) of the chambers.

Description

The present invention relates to a method for de-icing a rotor blade for a wind energy plant, which has cavities that are connected to each other. The invention also relates to a rotor blade which is advantageously suitable for carrying out the method.

From DE PS 842 330, a wind turbine with rotor blades is known, which must be protected against ice formation on the rotor blade tips. For this purpose, the rotor blade in the area near the leading edge has an internal cavity which, parallel to the rotor blade's longitudinal axis with a breakthrough in the stiffening elements, is flow-technically connected to each other. Heated air coming out of the rotor blade hub thus comes through the flow channels to the area at the rotor blade tips and is then released through controllable discharge openings. The heated air is thus led radially from the central area of the wind turbine to the end area of a rotor tip, and during the release of heat energy to the heat carrier medium, the leading edge of the blade is heated, whereby an attempt is made to prevent the formation of ice.

The ice coating on the surface of the rotor blades of a wind energy plant can lead to unwanted imbalances with the mechanical loads on the plant that this entails, but also to aerodynamic disturbances that can inhibit the plant's performance. In addition, an ice formation on a plant that is in progress represents an accident risk, because the ice can fall off and pieces of ice can in certain cases be thrown far into the surroundings.

Wind energy plants must be built with the lowest possible costs and operated with a high yield. Further precautions to prevent icing should preferably not have a negative impact, either on the manufacturing costs or on the yield, but due to the construction and building costs necessary for this, an impact on the manufacturing costs can hardly be avoided. In this respect, special problems of a constructional nature represent the tendency of the rotor blades to form ice, as they move in contrast to fixed building parts in the plant, and the transitions between stationary and moving parts in the wind energy plant must therefore be taken into account and determined securely in terms of construction.

The task that forms the basis of the invention is to find a structurally simplest possible and thus reasonable, but still effective method to prevent the disadvantages that arise from ice formation on the rotor blades, and also to make a suitable rotor blade that is suitable for this.

This task is solved with a rotor blade of the type described in the previous section relating to the invention, that if necessary from approx. +1 DC to +5 DC slightly preheated heat carrier medium is passed through the cavities.

At outside temperatures around the freezing point, e.g. from -2 DC to -5 DC but also only when the humidity is correspondingly high can ice form. The method relating to the invention takes advantage of the fact that ice that settles on the rotor blade forms an insulating layer between the blade surface and the surrounding air. Thus, with a relatively small amount of heat, it is possible to heat up the de-iced surface of the blade wall to such an extent that the ice melts and falls off the rotor blade by itself. For the de-icing that relates to the invention, the rotor blade is not heated, i.e. a de-icing is not generally prevented, as in the above-mentioned DE PS 842 330, but ice that has already formed is removed again.

Deicing of a rotor blade occurs especially at the leading edge of the blade that points in the direction of travel and also at the outer blade tips. As far as the invention is concerned, it is therefore proceeded in such a way that the heated heat-carrying medium, after flowing through a cavity in the leading edge of the blade with corresponding heat release to the area by the blade wall, is led to a cavity next to this, preferably a cavity in the rear edge of the blade, and led away from there.

If there are stiffening bulkheads in the rotor blades that run parallel to the longitudinal axis of the blade, these can be used particularly advantageously to design flow paths for heat-carrying medium that is led in, which first flows through cavities in the leading edge of the blade and there emits its heat to the blade wall, especially to the leading edge of the blade, for there to melt ice that has formed there. Subsequently, the heat carrier medium can also flow through other cavities through which it is led before a discharge takes place. Of course, cavities that are connected to each other can also be designed with e.g. inserted or built-in pipes, pipe pieces and the like.

Particularly advantageously, the heat carrier medium is led into the foot area of the rotor blade which can be connected to a rotor hub and in the area of the rotor blade tip is led into the corresponding cavity, namely a chamber in the rear edge of the blade and again led back to the foot area. In this way, a circulation is formed in the simplest way for the heat-carrying medium inside the rotor blade. Here, the air inside the rotor blade can be used as a heat-carrying medium. But it is also conceivable to fill rotor blades with the gas or vapors with more useful properties than air, which, for example, in the temperature ranges where there is a risk of ice formation can set free condensation heat to reduce the energy supply for any necessary heating of the heat carrier medium that circulates in the rotor blade. An electrically non-conductive heat carrier medium such as air is furthermore advantageous with regard to protection against lightning strikes for the wind energy plant in contrast to electrical heating with e.g. resistance wires.

In order to possibly subject the diverted heat carrier medium to a heating after its outflow from the last cavity, the chamber in the rear edge of the blade, to then lead it again into the first cavity chamber in the front edge of the blade, in order to create and maintain heat carrier medium circulation in the rotor blade, electric fans and also electric heating elements which are placed in the flow created for the heat-carrying medium.

As the fan and also possibly the heating element that is integrated in the fan are located in the foot area of the rotor blade, they sit advantageously close to the axis of rotation and thereby run at a low rotational speed, so that static and dynamic influences through the installation of the fans and heating elements are in practice negligible. This gives you the particular advantage that rotor blades which have already been constructed and made which have proven themselves in use, with respect to the construction, do not have to be significantly changed in order to be able to use the de-icing that relates to the invention. Electric fans and also heating elements with a suitably small output which is fully sufficient to maintain the circulation of the heated air through the cavities or chambers in the rotor blade have small dimensions and can be obtained as industrial series parts.

The electrical wiring to the electric fans and also the associated heating elements installed in the rotor blade are likewise easy to perform. The required electrical energy is relatively small.

In order for de-icing when ice formation occurs on the rotor blades of the wind energy plant to take place by itself, after a further development of the method relating to the invention, it is assumed that vibrations due to imbalance in running wind energy plants, which occur due to ice formation on the rotor blades, are recorded by measurement technology and converted into a switching signal to stop the rotor of the wind energy plant and also to initiate the circulation of the heat carrier medium in the rotor blades and possibly the assigned heating elements, that after a predetermined effective time for the circulation and the heating elements, the wind energy plant is started again and that, if necessary, the sequence is repeated until the wind energy plant due to the icing which has taken place again runs vibration-free.

Precautions can be taken, that the outside temperature, the temperature of the heat carrier medium, the rotor speed, the wind speed and the vibrations are recorded with suitable sensors and processed in a program-controlled automatic system into suitable control switching signals that initiate a de-icing.

A suitable rotor blade for carrying out the method relating to the invention, for which separate protection is also claimed, is characterized by the fact that, in the foot area of the rotor blade, means are provided for the introduction of a heat-carrying medium into at least one cavity in the leading edge of the blade, which can be connected to a rotor hub, and that in the end area of the chambers at the tip of the blade there are flow paths conducting heat carrier medium which connect cavities that lie next to each other.

For a rotor blade that relates to the invention, the cavities can be formed by a blade inner space surrounded by an outer blade wall with at least one stiffening bulkhead running parallel to the blade's longitudinal axis is divided into chambers, at least one chamber at the leading edge of the blade and one chamber at the trailing edge of the blade.

The connecting flow paths can simply be openings in the stiffening bulkheads that divide the cavities or chambers. If the heat-carrying medium is led into the chamber at the leading edge of the blade in the foot area of the rotor blade, this flows in the chamber at the leading edge of the blade to its end area at the tip of the blade and runs there into the chamber that is next to , preferably the chamber at the trailing edge of the blade, where it e.g. . can flow back to the root area of the rotor blade.

Of course, it is also possible to design the flow paths in the rotor blade in the area at the blade tip, so that the heat carrier medium washes over the entire end area of the inner space of the rotor blade at the blade tip.

The means for introducing a heat-carrying medium comprises at least one electric fan with integrated heating elements, whereby the suction side of each fan is connected to a cavity which has last been flowed through, the chamber in the rear edge of the blade, and the pressure side of each fan to the first cavity, the chamber in leading edge of the blade.

Electric fans with integrated heating elements can advantageously be sized so small that they can easily be built into an inner space in a rotor blade, and thus in the foot area, even in multiple devices. The performance of the smallest fans should be sufficient to start and maintain an air circulation through the cavities in the rotor blade. As a heating element, simple resistance heating wires with heating coils or similar can be used which are integrated into each fan. If it turns out that the performance of an electric fan is not sufficient, several suitably small sized fans, each with their own integrated heating element, can be combined into a built-in unit so that the performances of the fans are added.

In order to ensure optimal circulation in the inner space of a rotor blade, the cavity in the leading edge of the blade, which at the end faces the foot area of the rotor blade, is sealed with a cover to the inner space which is open to the cavity in the rear edge of the blade.

The cover can be particularly advantageously used as a carrier of the electric fans with heating elements, at least having an opening where a shaft part containing the fan is inserted.

Here, each shaft part is placed in an opening in the cover, so that it leans towards the leading edge of the blade and protrudes into the chamber at the leading edge of the blade. Thus, the air passage created by the operation of the fan is directed towards the leading edge of the blade and is located at an advantageous distance from the foot area to the rotor blade, so that its unwanted heating during de-icing is avoided. As shaft parts, it can e.g. hoses are used.

Heat loss can also be further reduced by providing the transition area between the end of the rotor blade in the foot area and a blade adapter that serves as a connection to a rotor hub with an interior lining of an insulating material. The interior lining can e.g. be a properly shaped foam sheet inserted into the end of the rotor blade in the foot area which is approximately parallel to the cover.

If the cover is also made of insulating material, the inner space on the suction side of the fan is mostly insulated.

A design example for the invention showing other characteristic features relating to the invention is shown in the drawing. It shows in figure 1 the foot area of a rotor blade in longitudinal section, figure 2 shows a longitudinal section through a rotor blade II-II in figure 1, figure 3 shows the rotor blade in section III-III in figure 3 and figure 4 shows a connection diagram for an automatic control of the de-icing.

In figure 1, the lower part of a rotor blade, its root area is shown in a schematic longitudinal section. The arrow 1 indicates the flow direction, where the leading edge 2 of the rotor blade is made clear. The rear edge of the blade is designated 3.

A blade adapter 4 serves as the connection of the rotor blade to a rotor hub, which is not shown here, to which the foot end of the rotor blade is attached. A foam plate 5 has been inserted in the transition area between the foot end and the blade adapter 4.

The rotor blade is shaped hollow and the inner space 7 which is surrounded by the outer blade wall 6 has at least one stiffening bulkhead 8 or 8a, 8b which runs parallel to the blade's longitudinal axis divided into chambers, at least one chamber 9 at the leading edge of the blade and a chamber 10 at the trailing edge of the blade. The stiffening bulkhead 8a ends shortly before the tip 11 of the rotor blade. With the arrow 12, it is made clear here that there is a through connection from the chamber 9 in the leading edge of the blade to the chamber 10 in the trailing edge of the blade in the tip 11 of the rotor blade.

The end of the chamber 9 which faces the foot area of the rotor blade and in this design example also the functionless chamber which lies next to it and which is located between the stiffening bulkheads 8 and 8a is sealed again with a cover 13 against the inner space 7 which is open to the chamber 10 at the rear edge of the blade .

The cover serves as a carrier for the shaft parts 14, 15 which are bent towards the leading edge of the blade 2 and which protrude into the chamber 9 at the leading edge of the blade.

A fan 16 or 16' with an integrated heating element is arranged in each shaft part. The reference 17 here is an electrical wire for the power supply to the fan and heating elements which is only indicated. Figure 3 shows the foot area for the rotor blade in a section III-III in Figure 1. Identical components have again been given the same reference number. Figure 2 shows the rotor blade in section II-II in Figure 1. Identical components have the same reference numbers as in Figure 1. Figure 3 makes it clear that the cover 13 serves as a carrier for a total of four shaft parts 14, 15 and 14', 15' respectively. The shaft parts 14, 15 and 14', 15' respectively with the fans are fixed in a mounting insert 18, which in turn can be adapted correctly as a unit in a suitable opening 19 in the cover 13 which serves as a carrier for the mounting insert 18. Figure 4 shows a schematic connection diagram of a design possibility for a control of the de-icing of three rotor blades on a rotor in a wind energy plant. Each rotor blade 19, 20 and 21 is represented by a dotted field drawn as a square and corresponds with its design to a rotor blade according to figures 1-3.1 each rotor blade has the sensors 22, 23 and 24 built in for recording the temperature of a heat-carrying medium. Electric fans 25, 26 and 27 are likewise inserted in each rotor blade 19, 20 and 21 respectively (corresponding to the fans 16 and 16' in Figure 1), each of which with assigned heating elements 28, 29 and 30 are combined into a building unit, whereby the building units form means for introducing a heat carrier medium into each of the chambers in the inner space at the leading edge of the blade in each rotor blade, where the temperatures are registered by each of the sensors 22, 23 and 24 respectively. The measurement of the temperature of the heat carrier medium in the rotor blade with the sensors 22, 23 and 24 respectively serves as function monitoring for the fans 25, 26, 27 and also the heating elements 28, 29 and 30 and protects the rotor blades against overheating.

The temperatures are read by a program-controlled automatic system 31. The program-controlled automatic system 31 also records the outside temperature with a sensor 32 and the wind speed with sensor 33, with sensor 34 the number of revolutions and with sensor 35 the vibrations, e.g. the oscillations in the tower.

As soon as the wind speed is sufficient for operation of the plant and the outside temperature is in an area where ice formation on the rotor blades is possible, the units in each rotor blade that include the heating elements and fans are switched on by the automatic system. After a certain time, the wind energy plant is then started. Should there be an imbalance in the rotor due to different de-icing of the rotor blades, the vibrations with the rotor in motion which are the result of this are recorded when measuring the tower's oscillations, the system is switched off and the de-icing of the blades is repeated with a stationary rotor.

Claims (15)

1. Method for de-icing a rotor blade of a wind energy plant, which has cavities that are connected to each other, through which a heat-carrying medium is passed which has been pre-heated for the occasion, characterized in that the heated heat-carrying medium after having flowed through the cavity (9) in the front edge of the blade with corresponding heat release to areas near the blade wall is led into a cavity (10) in the rear edge of the blade and from there led away. 2. Method according to claim 1, characterized in that the heat-carrying medium in a foot area of the rotor blade which can be connected to a rotor hub is led into the cavity (9) in the leading edge of the blade and in the rotor blade tip area (11) is led over into the cavity (10) of the blade back and again led back to the foot area. 3. Method according to the preceding claim, characterized in that the air in the rotor blade is used as heat-carrying medium. 4. Method according to the preceding claim, characterized in that the derived heat-carrying medium, after the outflow from the last through-flowing cavity (10), is subjected to a heating for the occasion and is then led again into the cavity (9) at the leading edge of the blade. 5. Method according to the preceding claim, characterized in that electric fans (16, 16' and 25, 26, 27 respectively) are used to create heat carrier circulation in the rotor blade and heating elements (28, 29, 30) are placed in the air flow that is formed. 6. Method according to the preceding claim, characterized in that vibrations due to imbalance in wind energy plants that are in operation, which occur due to ice formation on the rotor blades, are picked up by measuring technology and translated into a switching signal to stop the rotor of the wind energy plant and also the initiation of the heat carrier medium circulation in the rotor blades and for the occasion the assigned heating elements (28,29, 30), that after a predetermined effective time for the circulation and the heating elements (28, 29, 30) the wind energy system is switched on again and that the process is repeated on occasion until the wind energy system runs vibration-free after the de-icing . 7. Method according to claim 6, characterized in that the outside temperature, the temperature of the heat-carrying medium, rotor speed, wind speed and vibrations are recorded with suitable sensors (32, 22, 23, 24, 34, 33, 35) and in a program-controlled automatic system (31 ) are processed into suitable switching signals that initiate and control a de-icing. 8. Rotor blades for wind energy systems that have cavities that are connected to each other, characterized in that the rotor blade on the inner side has a partition wall (8, 8a, 8b) that runs along the longitudinal axis of the rotor blade and which forms a chamber (9) at the leading edge of the blade and a chamber (10) at the trailing edge of the blade and that there is a connection between the two chambers, where a heat-carrying medium can flow through the connection between the chamber at the leading edge of the blade and the chamber at the trailing edge of the blade. 9. Rotor blade according to claim 8, characterized in that means are provided in the foot area of the rotor blade which can be connected to a rotor hub for introducing a heat-carrying medium to at least the cavity (9) in the leading edge of the blade. 10. Rotor blade according to claims 8-9, characterized in that the means for introducing a heat-carrying medium comprise at least one electric fan (16, 16' or 25, 26, 27) with integrated heating elements (28, 29, 30), and that the suction side of each fan (16, 16' respectively 25, 26, 27) is connected to the cavity (chamber 10) in the rear edge of the blade and the pressure side of each fan (16, 16' respectively 25,26, 27) is connected to the cavity (chamber 9 ) at the front of the leaf. 11. Rotor blade according to claims 8-10, characterized in that the end of the rotor blade that faces the foot area of the cavity (chamber 9) in the leading edge of the blade is sealed with a cover (13) against the inner space (7) which is open to the cavity (10) in back edge of the blade. 12. Rotor blade according to claim 11, characterized in that the cover (13) has at least one opening where a shaft part (14, 15, 14', 15') which accommodates the fan (16, 16' or 25, 26, 27) with heating elements (28, 29, 30) are placed. 13. Rotor blade according to claim 12, characterized in that each shaft part (14, 15, 14', 15') bends towards the leading edge (2) of the blade and protrudes into the cavity (chamber 9) in the leading edge of the blade. 14. Rotor blade according to the preceding claim, characterized in that the transition area between the end of the rotor blade in the foot area and a blade adapter (4) which serves as a connection to a rotor hub is provided with an inner lining of insulating materials. 15. Rotor blade according to claim 14, characterized in that the inner lining is a form-fitting foam sheet (5) which is inserted into the end of the rotor blade in the foot area which is approximately parallel to the cover (13).