NO324465B1 - Procedure for assembling / dismantling heavy elements at wind turbines - Google Patents

Abstract

The present invention relates to a method for mounting or dismantling heavy parts from the top of the tower (1) in a wind turbine. In a first stage of construction of a permanent tower (1), two separate tower parts (1A) and (1B) are first constructed with a through opening (6) between said parts. Above or adjacent to the opening (6), at least one lifting device (5) is provided for lifting or lowering heavy elements. The tower parts (1A) and (1B) are connected so that the wind turbine in its normal operating time is connected to one tower (1). The coupling of the two tower parts (1A) and (1B) can be done in different ways, for example by means of braces (3) or only by coupling at the top of the tower under the turbine (2). The stiffeners (3) can be mounted as the heavy parts are lifted upwards in the opening (6). When dismantling heavy parts and lowering them to ground level, the stiffeners (3) are removed as the heavy parts are to be lowered. anchored in devices arranged in advance.

Description

The present invention relates to a method for assembly/disassembly of the heavy elements of a wind power plant such as a turbine with shaft, balance weight and propeller.

When building a wind power plant, mounting the turbine with propeller on top of a tall tower involves a number of problems. Wind turbines are often built in places with poor or no infrastructure. Getting there with heavy lifting equipment is a problem in itself and normally requires supply routes etc to be built and dimensioned for such equipment. The heaviest unit to be mounted is normally the turbine itself. The practical difficulties of assembling a turbine of smaller components on top of a tower with a height of perhaps 150 meters and in a windy location are in themselves, for safety and quality reasons, a limitation. For quality reasons, the turbine is normally produced as complete as possible in a factory, transported to the assembly site, lifted up and mounted with a minimum of additional work on top of the tower. In the case of smaller wind turbines, a complete turbine can weigh around 60-80 tonnes. For the largest wind turbines, a turbine can weigh over 250 tonnes and the trend seems to be towards wind turbines with even greater outputs and thus even greater turbine weights and taller towers.

In large parts of the world, there is a wind-based basis for building large and small wind power plants both on land and at sea. Lifting cranes with sufficient lifting capacity and with sufficient height to lift and mount turbines with the large weights involved here are, on the other hand, only available in the industrially developed countries. The availability of lifting equipment and the costs of getting it to the installation site are therefore today an obstacle to the development of wind power plants. For most countries, even lifting and installing the turbine for small wind power plants will be an insurmountable obstacle without importing equipment from outside. Furthermore, the assembly methods and the availability of necessary powerful assembly equipment and the costs for these, to assemble, maintain, repair, replace parts of the wind turbine, will constitute a limitation to the development of wind turbines. The assembly methods that are usually used today are therefore the use of heavy cranes that must be brought to the construction site and then removed from there. When maintaining and replacing parts, heavy equipment must be acquired again. From patent document EP 1 350 953 A2, a device comprising a crane is known which is mounted on top of the wind power tower. The heavy units such as the turbine and parts of the tower can then be lifted up and mounted on the top of the tower. During this operation it will be exposed to all the problems that wind can create. The individual components must then be assembled together at the top of the tower. After assembly, the crane must be dismantled and removed from the tower. A significant disadvantage of this solution is that lifting the heavy elements and installing them will be very vulnerable to weather conditions. Furthermore, from EP 1 129 984 the use of a large crane placed next to a wind power plant placed on the seabed is known. Placement on the seabed will in practice be complicated as the seabed must be leveled and reinforced before the crane can be placed there. This solution at sea will be very expensive and lifting the heavy elements and installing them on top of the tower will involve a number of other uncertainties such as checking the ground conditions under the crane during the lifting, the impact from waves, currents etc.

The main purpose of the present invention was to come up with a simple and affordable method for mounting/dismounting heavy parts such as a turbine at the top of the tower of a wind power plant.

A further purpose was to arrive at lifting devices that could be an integral part of the wind power plant and could be used for maintenance and replacement of its heavy parts.

Another purpose was to avoid the use of heavy large lifting cranes that had to be brought to the construction site and removed from there after the heavy elements such as the turbine, propeller etc had been mounted on top of the tower

Based on the experiences one has with today's technology and the demands placed on the use of external, heavy and expensive equipment, the inventor tried to attack the problem of lifting heavy elements into place in a new way. While testing this, he came to the conclusion that the solution could be achieved by initially building the tower in two parts with a continuous opening between the two parts. Lifting devices for the heavy parts can be placed on top of said tower parts. Here you can use a winch with wires or the use of hydraulic lifting equipment with wire or lifting rods. The lifting devices can be placed at the top of the tower so that they can be quickly put into use for maintenance and possibly lowering heavy parts. Other lifting arrangements that are not placed on the tower top are also an option. When the heavy parts have been lifted into place at the top of the tower, the two tower parts can be connected together to form one tower. This pairing can be done in a number of different ways. As the turbine is lifted up, the opening between the two tower parts can be stiffened and thus bind the two tower parts together. This bracing can possibly be carried out after the turbine has been lifted into place at the top of the tower. When dismantling and lowering the turbine to ground level, the procedure is reversed. This means that the bracing is removed so that the turbine can be lowered into the tower. After the turbine has been lifted some distance up the tower, the propeller can be attached to the axis of the turbine so that the whole unit can be lifted as one element to the top of the tower.

A particular advantage of the method according to the invention is that in the event of predicted extreme weather such as hurricanes and tropical storms, weather conditions with the possibility of ice formation, etc., the risk of damage to the wind power plant can be reduced by lowering the heavy parts such as the turbine and propeller. These parts can be lowered so low that two of the propeller blades almost touch the ground and can be fixed in devices arranged in advance.

The main feature of the method according to the invention is that a wind power plant's permanent tower in a first stage is built as two separate parts and with a continuous opening between said parts and that at least one lifting device is arranged above or adjacent to this opening for lifting and lowering heavy elements which turbine, propeller etc. The two tower parts are then connected together so that during the wind power plant's normal operating hours the tower parts are connected to one tower.

The connection of the two tower parts can be carried out using a number of horizontal or vertical braces. It can also be carried out by only connecting the two tower parts at the top of the tower below the turbine.

Another feature of the method is that the stiffeners can be arranged as the heavy parts are lifted upwards into the opening between the tower parts.

A further feature is that after the turbine has been raised to a certain level, the propeller is mounted to the axis of the turbine and that the whole unit is then raised as one element

Furthermore, with the method according to the invention, by dismantling heavy parts and lowering them to ground level, the stiffeners between the tower parts can be removed before or after the heavy parts are to be lowered.

In advance of predicted extreme weather, it is also possible, according to the invention, to temporarily lower the heavy parts such as the turbine and propeller to the lowest possible level so that two of the propeller blades almost touch the ground and are fixed in devices arranged in advance and the upper propeller blade and the turbine are anchored in the tower with a fastening device to reduce the risk of damage to the wind power plant.

The invention will be explained in more detail during the description of the drawings.

Figure 1 shows a wind power tower seen from the side as well as a cross section of the tower.

Figure 2 shows section B-B from fig. 1 and where the turbine is lifted up.

Figure 3 shows the wind power plant after the installation of the turbine and propeller has been completed and where a series of braces have been arranged in the opening between the two towers which bind the two tower parts together, as well as a cross-section of the tower with braces.

Figure 4 shows a hydropower tower with turbine and propeller lowered to ground level.

Figure 1 shows the tower 1 consisting of the tower parts IA and IB placed at a distance from each other so that a continuous opening 6 is formed. A cross section B-B is also shown. Figure 2 shows the tower part IB where the turbine 2 with axis and propeller is lifted up a distance between the tower parts using the lifting devices 5 at the top of the tower 1. Lifting preferably takes place using standard lifting rods or wire, but winches with wires or other types of lifting arrangement can also be used. The heavy parts can be lifted in one step all the way to the top, but if unacceptable wind conditions occur during the lifting operation, the lifting can be interrupted and resumed when wind conditions permit. During the interruption, the heavy parts can be temporarily anchored to the tower parts IA and IB so that any movements do not damage the tower or what is being lifted.

Before the lifting starts, the turbine is inserted into the through opening 6 and a lifting hook or similar is attached to the heavy part and then the lifting can start. Figure 3 shows the wind power plant in a fully assembled state. The two tower parts IA and IB are now connected by means of a series of stiffeners 3. These stiffeners 3 can be fitted as the heavy part is lifted up or after it has been lifted all the way to the top. The section C-C shows the toe part IA and IB with the continuous opening 6 and a horizontal bracing 3 which binds the two toe part together. In addition, vertical braces can be fitted between the horizontal braces 3. These braces can be easily dismantled if the turbine or other heavy parts have to be lowered to ground level. The procedures are therefore the opposite of those used when lifting the heavy parts to the top of the tower. Figure 4 shows the vmdkraft tower 1 where the turbine and propeller have been lowered as far as possible in connection with expected extreme weather conditions. Two of the propeller blades 4 will then be almost down to the ground and can be anchored in pre-placed devices 7 at ground level. The turbine body itself and the upper propeller blade can be anchored to the tower 1. The third propeller blade is shown fixed in the device 8 at the top of the tower. Section D-D shows the tower parts IA and IB with the fastening device 8 for the propeller blade 4. A similar arrangement can be used for offshore wind turbines.

With the present invention, a method has been arrived at which does not have the disadvantages that known methods and devices represent. The new solution provides a simple and safe method for lifting heavy parts to the top of the tower. Mounting a turbine with a propeller becomes very easy as large parts can be lifted into place in one lifting operation. A major advantage of the new method is that dismantling heavy equipment and lowering it to ground level can be carried out in a simple and cheap way without having to bring in heavy and expensive lifting equipment to the construction site.

The present invention also has the advantage over known methods and devices that the wind power plant's windbreak can be significantly reduced, when extreme weather is announced by lowering the turbine with the propellers almost to ground level and anchoring them there. This advantage means that the load basis for dimensioning the tower can be significantly reduced. Furthermore, the invention implies that in extreme weather conditions such as hurricanes, tropical storms, ice formation etc., the propeller blades can be anchored at their ends, in contrast to known methods where the propellers must remain up on the top of the tower in the storm with only irine attachment in the turbine shaft. A support for the propeller blades at both ends provides a significant reduction in the load basis for the propeller blades. The present invention's method and the reduction of the load basis for the tower and the propeller blades that is achieved will reduce the total cost of building and operating the wind power plant.

Claims (7)

1. Procedure for mounting or dismounting heavy parts such as all or parts of a turbine (2) with shaft and propeller (4) at the top of a tower (1) of a wind power plant, characterized by the permanent tower (1) in a first stage is built as two separate parts (IA) and (IB) with a continuous opening (6) between said parts and that above or adjacent to the opening (6) at least one lifting device (5) is arranged ) for lifting or lowering heavy elements such as turbines (2), propellers (4) etc., as the tower parts (IA) and (IB) are then connected together so that during the wind power plant's normal operating hours the tower parts (1 A,1B ) are connected to form one tower (1). 2. Method according to claim 1, characterized by the tower parts (IA) and (IB) are connected by means of a number of horizontal braces (3) and/or vertical braces. 3. Method according to claim 1, characterized by the tower parts (IA) and (lB) are only connected at the top of the tower (1) below the turbine (2) 4. Method according to claim 1, characterized by the stiffeners (3) are arranged as the heavy parts are lifted upwards into the opening (6). 5. Method according to claim 1, characterized by after the turbine (2) has been raised to a certain level, the propeller (4) is mounted to the axis of the turbine (2) and the whole unit is then raised as one element. 6. Method according to claim 1, characterized by when dismantling heavy parts and lowering them to ground level, the bracing (3) between the tower parts IA, IB is removed within, or as the heavy parts are to be lowered. 7. Method according to claim 1, characterized by ahead of predicted extreme weather, the heavy parts such as the turbine (2) and propeller (4) are temporarily lowered to the lowest possible level and where the two propeller blades (4) at ground level are anchored in prearranged devices (7) and that the upper propeller blade is anchored in the tower ( 1) with the fastening device (8) and that the turbine part is anchored to the tower (1).