Wind Energy Needs Lightweight Giants - Vacuum ensures rotor blade stability

Wind Energy Needs Lightweight Giants - Vacuum ensures rotor blade stability

The huge mill blades of modern wind turbines are assembled and preformed from various materials. Synthetic resin then bonds the sandwich structure into a stable unit. BUSCH vacuum pumps help in this process.
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One of the biggest challenges in transport logistics is transporting rotor blades for wind turbines from the manufacturer's location to the site of installation. This is because windmill blades are true giants: when the big boom in wind energy began in the early 2000s, a rotor blade was on average about 25 meters long. Nowadays, it is almost 70 meters for new turbines on land and over 80 meters at sea.

Eighteen times acceleration due to gravity

Even the largest rotor blades, however, weigh no more than about 25 tons and are still incredibly stable. Wind speeds of more than 350 kilometers per hour occur at the rotor tips; the centrifugal forces there correspond to eighteen times gravitational acceleration. To ensure the greatest possible energy yield, the giant wings must also deform only minimally. They owe their strength to their material and to a sophisticated manufacturing process. Nonwovens made of glass and carbon fibers are reinforced with balsa wood or foam materials, impregnated with synthetic resin and "baked" into a solid composite.

Degassing and infusion

Vacuum is used twice in this process. First, the resin mass needs to be degassed because it usually contains small air bubbles that interfere with the next production step and affect the strength of the overall composite after curing. Therefore, the resin is exposed to a vacuum that reliably removes all air pockets.

The next step is vacuum infusion: the preformed component is sealed with a vacuum foil and evacuated. Now the atmospheric pressure can press the heated, liquid synthetic resin into the smallest pores of the sandwich composite. Various vacuum solutions from BUSCH are used in these processes. Even the pre-preg process cannot function without vacuum. Here, the fiber mats of the composite material were already impregnated with resin before assembly. To ensure that the resin is optimally distributed during curing under pressure and heat, the composite is also deaerated by vacuum beforehand.

The longest rotor blades are found on offshore turbines on the high seas. Despite their enormous size, transportation is pretty simple: the factories where these giants are manufactured are usually located near the port. They can load their products directly onto ships, such that lengths of 80 meters and more do not pose a problem.

However, the situation is quite different for onshore turbines, which are often located far from highways and are only accessible via smaller roads. Particularly in windy mountainous regions, tight bends are also a factor. A rotor blade that is 50 or 60 meters long lying on the transporter cannot even manage to go around a large traffic circle – not to mention negotiating serpentine roads and narrow village streets.

That is why special transporters with a tipper body have been developed for this logistically tricky task. The base of the rotor is attached to it in the same way as it is later attached to the nacelle of the wind turbine. The tilt mechanism allows the blade to be placed at any angle. In an almost vertical position, it can thus also be maneuvered around tight bends, provided there are no trees, bridges, or overhead lines in the way. At any rate, with the blade in front, it only ever moves forward at a snail's pace.


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