The present invention relates to a wind turbine rotor blade and a wind turbine.
Since rotor blades are exposed to all weather conditions unprotected, the rotor blades can become iced at specific temperatures. A rotor blade heater can be used to prevent this. Either a heater can be provided outside on the rotor blade, or heated air can be made available inside of the rotor blade. For example, this can take place by means of a heating register, which generates hot air that is then blown into the interior of the rotor blade.
WO 2017/021350 A1 shows a wind turbine rotor blade with a rotor blade root area and a rotor blade tip area, as well as a rotor blade heater. At least one web is further provided along a longitudinal axis of the rotor blade. A deflection unit in the form of a bar drop can be provided on the web, so as to reduce air turbulence in the deflection process.
WO 2018/211055 shows a wind turbine rotor blade with a rotor blade heater. The rotor blade has a web and a deflection unit in the area of the rotor blade tip for deflecting heated air.
Provided is a wind turbine rotor blade that enables an improved heating of the rotor blade.
Provided is a wind turbine rotor blade with a rotor blade root, a rotor blade tip, a pressure side, a suction side, a leading edge, and a trailing edge. The rotor blade has a longitudinal direction. A rotor blade heater is used to generate hot air, which is then blown into the interior of the rotor blade. At least one static or passive aerodynamic mixer is provided in the air duct inside of the rotor blade. The mixer causes turbulence in the air flowing through it and/or an at least local increase in the flow rate. As a result of the mixer, the air masses with varying temperatures (hot air in the middle of the air flow and colder air toward the rotor blade exterior) mix together better.
According to an aspect of the disclosure, the static aerodynamic mixer can be configured like an aerodynamic mixer, a stator vane or baffle plate. Alternatively or additionally thereto, the mixer can take the form of a helical profiling (e.g., spiral grooves can be provided in a tube wall) on the inner walls of the air duct.
The aerodynamically active elements of the mixer convert a uniform air flow at least partially into an air flow with a swirl added to it.
According to an aspect of the disclosure, at least one web is provided between the pressure side and the suction side along the longitudinal direction of the rotor blade. The air heated by the rotor blade heater can be blown along the web in the direction of the rotor blade tip, where it is deflected, so that the heated air on the other side of the web can flow back from the rotor blade tip area to the rotor blade root area. An aerodynamic mixer can be provided along a web.
The static or passive aerodynamic mixer optionally has no active elements that would have to be driven to mix the air flowing through.
According to an aspect, one side of the aerodynamic mixer can be coupled to the rotor blade inner wall or to a web.
Additional embodiments of the disclosure are the subject of the subclaims.
Advantages and exemplary embodiments of the invention will be described in more detail below with reference to the drawing.
At least one web 410, 411, 412 extends along a longitudinal direction L of the rotor blade 200 inside of the rotor blade, and is part of the air guide 400 or already present for other reasons, with the air guide 400 having only a secondary function. More than one web can optionally be provided.
The air heated by the rotor blade heater 300 can be guided along the web 411 as part of the air guide 400 in the direction of the rotor blade tip 220, and then be deflected in the area of the rotor blade tip 220. To this end, a deflection section 202 can be present in the area of the rotor blade tip 220. The rotor blade tip 220 can optionally be at least partially hollow in design, so that a portion of the heated air can flow through the rotor blade tip 220, in order to also deice the rotor blade tip 220.
The heated air can be generated by means of the rotor blade heater 300 either in the rotor blade root area, by virtue of a heating unit heating the air, or the heated air is supplied to the rotor blade 200 in the area of the rotor blade root 210.
At least one aerodynamic mixer 600 can be provided along the length L of the rotor blade 200 in the air guide. The mixer 600 can be used to add a swirl to the air flow of the rotor blade heater, or to swirl the air flow. This is advantageous, since it can lead to an improved mixing of the air flow.
The mixer is used to change the air flow of the rotor blade heater. In particular, the mixer 600 can be used to add a swirl to the air flow. Alternatively or additionally thereto, the mixer can be used to influence the flow rate of the air flow.
Alternatively to the aforementioned, heat transfer can also take place at another location of the rotor blade, so that not only the rotor blade leading edge is necessarily heated.
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As a result of the mixer 700, an exemplarily laminar air flow is influenced by the mixer, so that that a swirl is added to the air flow.
The first end of the mixer can be fastened to an inner wall of the rotor blade or to a web in the rotor blade.
According to an aspect of the present disclosure, the aerodynamic mixer 700 can be provided at different locations along the length L of the rotor blade 200 and inside of the rotor blade 200, for example between a web and the rotor blade leading edge 230 or between the web 410 and a rotor blade trailing edge 230.
According to an aspect of the present disclosure, the aerodynamic mixers 600, 700 are used to locally influence an air flow inside of the air guide of the rotor blade.
According to an aspect of the present disclosure, imprinting a swirl on the air flow in the air guide for the rotor blade heater yields a significant improvement in blade heater performance due to an elevated heat exchange on the surface to be heated (for example, rotor blade leading edge).
The aerodynamic mixers can be designed as stators, baffle plates, spiral grooves (e.g., in the inner wall of the rotor blade). These can allow a streamlined design owing to a negligibly small additional pressure loss inside of the flow channel. Additionally generating a swirl in the air flow can thus not necessarily lead to an increase in pressure losses.
This happens because wall pressure losses depend primarily on normal straight lines of the velocity component along the primary direction of flow on the wall due to the surface friction, and not on gradients of the velocity components of the secondary flow (i.e., deflection of the flow by the baffle plates, for example).
The mixer improves how well the flow near the wall being cooled on the surface is mixed with the air flow essentially located in the flow channel, which has a higher temperature. This increases the temperature of the air flow that comes into contact with the wall of the flow channel. As a consequence, the heat transfer to the wall of the rotor blades is significantly improved. This also significantly raises the efficiency of the rotor blade heater, without having to increase the performance of the rotor blade heater.
According to an aspect of the present disclosure, already installed rotor blades can be retrofitted with the aerodynamic mixers according to the invention, so as to increase the efficiency of the rotor blade heater.
The solution according to the disclosure can be used in particular in rotor blades of a wind turbine that have a large length and a smaller inner cross section.
According to an aspect of the present disclosure, using the mixer disclosure makes it possible to significantly improve a temperature of the air flow on the rotor blade shell. While the temperature of the air flow on the shell can already drop to 50° C. in prior art, the aerodynamic mixers can be used to increase the temperature of the air flow on the inner wall significantly, in particular to
An improved heat transfer from the heated air to the material of the shell of the rotor blade can thus be achieved without the pressure losses being raised significantly in the process.
A thermal exchange cooler can thus improve a flow near the wall with a warm flow remote from the wall, without higher pressure losses resulting at the same time. Providing the aerodynamic mixer makes it possible to add a swirl to the air flow, which leads to an improved heat transfer, without at the same time increasing the performance of the rotor blade heater.
As the length of the rotor blade increases, the effect of the aerodynamic mixer can diminish, meaning that the swirl component of the flow can diminish. As a consequence, the flow becomes increasingly homogeneous once again. In order to further improve the air flow, several aerodynamic mixers can thus be provided in the rotor blade, so that these aerodynamic mixers are provided at several locations, and can thereby add a swirl at several locations of the air flow.
According to an aspect of the present disclosure, the aerodynamic mixer can be provided by providing a plurality of spiral grooves on the inner wall of the rotor blade shell. These spiral grooves can be used to add a swirl to the air flow.
According to an aspect of the present disclosure, local constrictions inside of the rotor blade can also be aerodynamically optimized using an aerodynamic mixer. This makes it possible to prevent the flow from separating inside of the rotor blade.
The aerodynamic mixer can be a static or passive mixer. To this end, the mixer optionally has no active or movable parts, so as to mix the air flow or create turbulence.
The various embodiments described above can be combined to provide further embodiments. These and other changes can be made to the embodiments in light of the above-detailed description. In general, in the following claims, the terms used should not be construed to limit the claims to the specific embodiments disclosed in the specification and the claims, but should be construed to include all possible embodiments along with the full scope of equivalents to which such claims are entitled. Accordingly, the claims are not limited by the disclosure.
Number | Date | Country | Kind |
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22182753.8 | Jul 2022 | EP | regional |