ES1245275U - TOWER - Google Patents

Abstract

Tower comprising a first section (1) of concrete, characterized in that the first section (1) comprises a geometry with a plurality of flat first faces (4a) of decreasing width as it ascends from a first end (6) towards a second end (7) of the first section (1) of the hybrid tower, and where the first section (1) comprises a plurality of flat second faces (5a) sandwiched between said first faces (4a), where the second faces (5a) comprise a constant width as it ascends from the first end (6) to the second end (7) of the first section (1) of the hybrid tower, so that at each height of the first section (1), said first section (1) It includes polygonal straight sections, where the surface of the polygonal straight sections at different heights of the first section (1) decreases continuously from the first end (6) to the second end (7) of the first section (1) of the hybrid tower. .

Description

DESCRIPTION

Tower

Object of the invention

A subject of the present invention is a tower, specifically a tower for a wind turbine. Preferably, the present invention has application in hybrid towers, which comprise a first concrete height section and a second metallic height section.

The tower object of the present invention provides a great simplicity of construction as well as a lower cost compared to other conventional towers.

The tower object of the present invention has special application in the field of the construction industry of infrastructures for power generation and, more specifically, in the construction industry of wind farms.

Background of the invention and technical problem to solve

The industry dedicated to the construction of wind turbine towers has evolved since the generation of electrical energy from wind energy was established as one of the main sources of renewable energy generation.

In the state of the art, there are completely metallic wind turbine towers. However, the development of high-rise towers requires the use of different materials for the design of the towers. That is why, in the state of the art, there are also hybrid towers formed by a lower concrete section on which another metal rests until reaching the desired height. This concrete section has a variable height between towers, and must be adapted to the needs of each park and each wind turbine.

For the execution of the concrete section, there are different alternatives.

The alternative construction of a concrete wind tower is known, as described in ES 2404781 A1. This alternative has the drawback of involving the production of curved formwork molds. Likewise, the design of this concrete tower involves the elaboration of the steel reinforcement armor with an equally curved geometry. In these cases, it is difficult to guarantee the thickness of the concrete coating, and this may ultimately affect the durability of the wind tower.

On the other hand, the alternative described in document ES 2611774 B1 is also known. According to this alternative, the support towers have an exclusively curved section at the upper end of the tower where the wind turbine is coupled. The upper curved section is configured by maintaining constant curved areas throughout the entire tower and progressively decreasing the width of some straight parts until they disappear. This alternative in turn presents a series of drawbacks, such as: the fact that the circular upper geometry requires the provision of specific formwork molds for each of the infinite possible tower heights, assuming a cost in auxiliary elements that prevents or makes it difficult to use this design for hybrid towers; the need to make curved formwork molds; the need to elaborate the reinforcing steel reinforcement with curved geometry, and; the lack of guarantee in the thickness of the reinforced concrete covering, affecting the durability of the towers.

The alternative described in document FR 1295463 A is also known. According to this alternative, all the faces of the tower are straight, thus avoiding the problems of curved formwork molds and the problems of curved steel reinforcing armor . However, in this design, all faces of the tower are of variable width in height. This also implies a complexity in the formwork molds, which have to be manufactured with all their faces variable in height, therefore the section of the entire mold must vary as it is ascending in the sub-sections of the formwork of the tower. The latter also implies that the adaptation times of the molds as the tower is executed by subsections are very high.

Description of the Invention

In order to solve the aforementioned drawbacks, the present invention refers to a tower, specially designed to support a wind turbine.

The tower object of the present invention comprises a first section (lower section) of concrete.

Optionally, the tower object of the present invention also comprises a second metallic section (upper section).

The first section comprises a geometry with a plurality of first flat faces of decreasing width as one ascends from a first (lower) end to a second (upper) end of the first section of the tower.

The first section comprises a plurality of second flat faces sandwiched between the first faces. The second faces comprise a constant width as one ascends from the first end to the second end of the first span of the tower.

As described above, at any height of the first section of the tower, said first section comprises a polygonal straight section (section orthogonal to the axis of the tower), where the surface of the polygonal straight sections at different heights of the first section decreases from continuously from the first end to the second end of the first section of the tower.

The configuration or geometry of the tower described above allows a great simplicity of construction, with no need for curved formwork molds (whose manufacture is complex and which give rise to later problems in guaranteeing the thickness of the tower's reinforced concrete coating) and not being necessary molds that change all its sides and / or all its section as it ascends in the execution of the tower, since the second sides of the tower have a constant width, and only the width of the first sides varies.

In this way, the execution of concrete sub-sections in towers of any height is allowed, keeping the geometry variation constant, facilitating the reuse of the necessary formwork molds in each project.

In each straight section at any height of the first section of the tower there is a polygon with first sides (corresponding to the first faces of the first section) and with second sides (corresponding to the second faces of the first section), where the The length of the first sides decreases in the straight sections, as you ascend from the first end to the second end of the first section of the tower.

According to a possible embodiment, the number of sides at the second end of the first span of the tower is less than the number of sides at the first end of the first span of the tower.

In this way, at the second end (upper end) of the first section of the tower, the first sides have decreased until they disappear, leaving only a section with a polygon in which only the second sides are present (of constant length in all straight sections of the first section).

As already advanced, the present invention contemplates that the tower be a hybrid, where the tower includes, in addition to the first concrete section (lower section), a second metallic section (upper section).

According to a preferred embodiment of the aforementioned hybrid tower, the second section is connected to the first section by means of a connection piece. This connecting piece is configured to smooth the change from the polygonal geometry of the second end of the first section to a cylindrical or conical geometry of the second section of the hybrid tower.

This facilitates the on-site assembly of the second metallic section (or shaft) of the hybrid tower on the first section, since fitting / anchoring a connection piece (lower than the shaft) in the first concrete section is a much simpler and more reliable maneuver than fitting / anchoring directly in said first concrete section the entire second metallic section of the hybrid tower.

Subsequently, the union of the second metal section to the connection piece (already anchored to the first section) can be carried out in a much more reliable and safe maneuver.

The connection piece comprises anchoring means to the first section of the hybrid tower.

According to a possible embodiment, said anchoring means comprise an "L" shaped geometry. In this way, a robust connection is provided between the connection and first section (and, therefore, between the second section and the first section of the tower) that provides a surface (base of the "L") for a connection screwed through through screws.

According to another possible embodiment, the anchoring means comprise a "T" (or inverted "T") geometry. This also provides a firm and robust connection between the connection piece and the first section of the hybrid tower (and, therefore, between the second section and the first section of the tower) that provides a more symmetrical surface (more symmetrical and balanced than in the case of the “L” connection) for a connection screwed in through bolts.

Therefore, the present invention provides a tower with a first concrete section that dispenses with curved surfaces or faces, thus freeing itself from the problems that this geometry brings, as previously described.

At the same time, by the described configuration, devoid of curved faces or surfaces, the need for curved passive steel reinforcement is eliminated.

As it has been advanced previously, the elaboration of the steel (bending of reinforcements) in a traverse is easier than in curved sections. In the case of curved sections, the curvature deviations of the steel with respect to the theoretical geometry can cause a lack or excess of concrete covering (loss of quality, durability and structural strength).

Also, through the present invention, a tower with a simple geometry is provided that facilitates the use of new generation reinforced concrete, such as concrete with metal or plastic fibers.

Brief description of the figures

As part of the explanation of at least one embodiment of the invention, the following figures have been included.

Figure 1: Shows a sectional view of an embodiment of the tower of the present invention, wherein said tower is represented as a hybrid tower with a first (lower) section of concrete and a second (upper) section of metal.

Figure 2: Shows a sectional view of another embodiment of the tower of the invention, also represented as a hybrid tower, where the tower has the same total height as the tower in Figure 1, but where the first section (of concrete ) of the hybrid tower is higher than the first section of the hybrid tower in Figure 1.

Figure 3: Shows a top view of the first section of the hybrid tower in Figure 1.

Figure 4: Shows a top view of the first section of the hybrid tower in Figure 2.

Figure 5: Shows a schematic view of the L-shaped anchoring means of the connection piece to the second end of the first section of the hybrid tower.

Figure 6: Shows a schematic view of the "T" -shaped anchoring means of the connection piece to the second end of the first section of the hybrid tower.

Detailed description

The present invention relates, as mentioned above, to a tower, especially indicated to support a wind turbine. As shown in the figures, the tower of the present invention may be a hybrid tower that comprises a first section (1) (lower section) of concrete and a second section (2) (upper section) (or shaft) metal.

The first concrete section (1) comprises a straight section with a polygonal geometry along its entire height.

Figure 1 and Figure 2 show two hybrid towers of the same height, where it is observed that the first section (1) of the tower reaches different heights, the hybrid tower maintaining the same total height.

As you ascend the length of the hybrid tower, the straight section of the tower decreases in surface. Each straight section comprises two opposite first two sides (4b), of decreasing length in each straight section as it ascends from a first end (6) (lower end) to a second end (7) (upper end) along its length. of the first section (1) of the tower, and where each straight section comprises second sides (5b) of constant length in each straight section along the entire height of the first section (1) of the hybrid tower. Figure 3 and Figure 4 show, in respective top views, the sides of the straight section corresponding to the second end (7) of the first section (1) of the hybrid tower of each of said towers.

In Figure 3 and Figure 4 the first section (1) of the hybrid tower is observed, according to embodiments where said first section (1) reaches different heights (as observed, respectively, in Figure 1 and in Figure 2). It is observed that some first flat faces (4a) of the first section (1) of the tower have a width that decreases as one ascends along the first section (1) of the tower, until it even disappears at the second end (7) of the first section (1) of the tower of Figure 2 and Figure 4. On the other hand, it is also observed that second flat faces (5a) of the first section (1) of the tower have a width that is it remains constant as it ascends along the first section (1) of the tower.

The first faces (4a) of the first section (1) of the tower correspond to the first sides (4b) of the straight sections and the second end (7) of Figure 3. The second faces (5a) of the first section ( 1) of the tower correspond to the second sides (5b) of the straight sections and the second end (7) of Figure 3 and Figure 4.

According to the configuration of the first section (1) of the hybrid tower that has been described, said first section (1) presents a polygonal configuration both at its first end (6) and at its second end (7). The number of sides at its second end (7) can be less than the number of sides at its first end (6), as shown in Figure 4.

The hybrid tower comprises a second section (2) or metal shaft.

According to an embodiment of the invention, at the junction of the second section (2) to the first section (1) of the hybrid tower, there is a connection piece (3) or ferrule.

This connection piece (3) preferably comprises a circular section.

The connection piece (3) comprises anchoring means (8) with the second end (7) of the first section (1) of the hybrid tower.

According to a possible embodiment (see Figure 6), said anchoring means (8) can comprise a "T" shaped geometry.

According to another possible embodiment (see Figure 5), said anchoring means (8) can comprise an "L" shaped geometry.

The anchoring means (8) can have a connection by means of through screws with the second end (7) of the first section (1) of the hybrid tower.

The connection piece (3) facilitates and / or smooths the transition between the first section (1) (polygonal) of the hybrid tower and the second section (2) (cylindrical or conical) of the hybrid tower.

Claims (6)

1. Tower comprising a first concrete section (1), characterized in that the first section (1) comprises a geometry with a plurality of flat first faces (4a) of decreasing width as it ascends from a first end (6) towards a second end (7) of the first section (1) of the hybrid tower, and where the first section (1) comprises a plurality of flat second faces (5a) sandwiched between said first faces (4a), where the second faces (5a ) comprise a constant width as it rises from the first end (6) towards the second end (7) of the first section (1) of the hybrid tower, so that at each height of the first section (1), said first section ( 1) comprises polygonal straight sections, where the surface of the polygonal straight sections at different heights of the first section (1) decreases continuously from the first end (6) to the second end (7) of the first section (1) of the hybrid tower. Tower according to claim 1, characterized in that the number of sides at the second end (7) of the first section (1) of the hybrid tower is less than the number of sides at the first end (6) of the first section (1 ) of the hybrid tower. 3. Tower according to any of the preceding claims, characterized in that it comprises a second metallic section (2). Tower according to claim 3, characterized in that the second section (2) is joined to the first section (1) by means of a connection piece (3), where said connection piece (3) is configured to smooth the change from the polygonal geometry of the second end (7) of the first section (1) to a cylindrical or conical geometry of the second section (2) of the hybrid tower. Tower according to claim 4, characterized in that the connection piece (3) comprises anchoring means (8) in the shape of an "L" to the second end (7) of the first section (1) of the hybrid tower. Tower according to claim 4, characterized in that the connection piece (3) comprises anchoring means (8) in the form of a "T" to the second end (7) of the first section (1) of the hybrid tower.