Concrete tower with enhanced diameter and wind turbine associated therewith
The varying diameter concrete tower design for wind turbines addresses structural and cost challenges by optimizing blade clearance and material efficiency, improving energy production and assembly costs.
Patent Information
- Authority / Receiving Office
- WO · WO
- Patent Type
- Applications
- Current Assignee / Owner
- NORDEX ENERGY SPAIN SAU
- Filing Date
- 2025-12-03
- Publication Date
- 2026-06-25
AI Technical Summary
Existing wind turbine towers face challenges in balancing structural integrity, cost-effectiveness, and efficiency, particularly in managing blade tip clearance and material usage, which affects annual energy production and assembly costs.
A concrete tower design with varying diameters, featuring a first end with a larger diameter than a second end, and a truncated cone shape, reduces blade tip to tower distance and conicity differences to enhance structural stability and efficiency, allowing for longer blades and improved energy production.
The design minimizes blade collisions and material usage, enhancing annual energy production and reducing manufacturing and assembly costs while maintaining structural integrity.
Smart Images

Figure EP2025085322_25062026_PF_FP_ABST
Abstract
Description
[0001] CONCRETE TOWER WITH ENHANCED DIAMETER AND WIND TURBINE
[0002] ASSOCIATED THEREWITH
[0003] TECHNICAL FIELD
[0004] The present disclosure relates to wind turbines. More particularly, the present disclosure relates to, but is not limited to, concrete towers for wind turbines and wind turbines with such towers.
[0005] BACKGROUND
[0006] Wind turbines generate electricity by capturing the energy of wind using components like the nacelle, rotor, and blades. These parts are typically placed high off the ground, such as, e.g., 70 meters or more, which puts significant demands on the tower of the turbine.
[0007] To make transportation and assembly easier, many towers are built from sections stacked on top of each other. This design also simplifies dismantling the turbine at the end of its lifespan.
[0008] The tower, especially its sections, i.e., tower sections, plays a crucial role in the overall cost of a wind turbine. It affects not only manufacturing, shipping, and assembly but also the ability of the wind turbine to produce electricity.
[0009] Designing the tower requires a careful balance. It needs to be strong enough to withstand strong wind gusts and vortices, while also being efficient and cost-effective. The goal is to maximize the performance of the wind turbine without sacrificing structural integrity.
[0010] DESCRIPTION
[0011] Aspects of the present disclosure are intended to provide wind turbines and towers thereof with more cost-effective manufacturing and / or assembling. Additionally or alternatively, aspects of the present disclosure are intended to provide wind turbines with greater productivity in terms of annual energy production (AEP).
[0012] A first aspect of the disclosure relates to a concrete tower for a wind turbine. The concrete tower includes a plurality of tower sections. The plurality of tower sections is stacked or stackable one another to form a tower such that a diameter of the tower sections varies, for example progressively or intermittently, from a first diameter to a second diameter. A tower section at a first end of the tower has the first diameter and a tower section at a second end of the tower has the second diameter. The first diameter is greater than the second diameter. The first end corresponds to a bottom end of the tower and the second end corresponds to a top end of the tower. When the tower is erected, the first end is connected to a foundation and it is closest to a surface such as the ground, whereas the second end is generally connected to a nacelle or a steel tower in case the tower is a hybrid tower.
[0013] The concrete tower is for the part of concrete tower of a wind turbine, or a full concrete tower, or a hybrid tower (with concrete and steel sections). The concrete tower has a truncated cone shape.
[0014] The first and second diameters taken are either outer diameters or inner diameters, preferably outer diameters. In any case, a first inner diameter of the tower section at the first end is greater than a second inner diameter of the tower section at the second end, and a first outer diameter of the tower section at the first end is greater than a second outer diameter of the tower section at the second end.
[0015] The tower has an outer diameter between 5.0 and 7.0 m at a predetermined height falling between the first end and the second end. In particular, the predetermined height is a height (when the tower is arranged on a surface such as, e.g., the ground) that is proximate to a height of a tip of at least one blade arranged on the tower or a wind turbine with the concrete tower (namely, proximate to a height that the tip of the at least one blade is at) when the at least one blade is oriented according to six o’clock. The predetermined height is a height that may additionally or alternatively be proximate to a region where a minimum blade tip to tower distance may occur. Preferably, the outer diameter at the predetermined height is between 5.5 and 6.0 m.
[0016] The minimum blade tip to tower distance is defined between an external surface of the tower and the tip of a blade when arranged on the concrete tower (and, thus, on the wind turbine), and it is the minimum distance that can be measured between the tip (i.e. , a point on the surface thereof) of the at least one blade and a point on the surface of the tower, such as, for example but without limitation, during operation of the wind turbine. The distance is measured with a straight line perpendicular to the segment defining the total height of the tower (i.e., between the first and second ends) and is generally parallel to the surface on or in which the tower is arranged. The minimum blade tip to tower distance may be a TCA distance, i.e., tower closest approach distance. A position of the tip of the blade considered for the minimum blade tip to tower distance is that of the tip while the blade is not rotating, i.e., while the rotor of the wind turbine is not in operation, and / or while the blade is rotating, i.e., while the rotor of the wind turbine is in operation.
[0017] Concerning the height that the tip of the at least one blade is at, the blade is oriented such that a root of the at least one blade is closest to the second end and the tip of the at least one blade is closest to the first end. The height of the tip of the at least one blade, which is configured to be connected to the tower or wind turbine, may be measured, for example, by means of a projection of the tip perpendicularly to a tower axis (thus, e.g., a horizontal projection) on the surface of the tower.
[0018] The predetermined height is considered to be proximate to said region and / or height of the tip when a distance in height (i.e., along a tower axis) measured between them is not greater than 15% of the tower height and / or 10 m, preferably not greater than 10% of the tower height and / or 5 m, and more preferably as close as possible to 0% and / or 0 m, e.g., less than 2% and / or 2 m, equal to 0% and / or 0 m, etc.
[0019] In the context of the present disclosure, heights, including, e.g., the first and second heights, may be defined by an axis, such as a vertical axis (tower axis), extending from the first end to the second end or vice versa.
[0020] A tower according to the present disclosure may reduce the likelihood of the blades of the wind turbine clipping the tower, especially when a rotor of the wind turbine is in operation and / or in presence of strong wind gusts or vortices, thereby improving the performance of the wind turbine. The aforesaid outer diameters at the predetermined height results in a distance between the tip of the blades and the tower that is reduced or even minimum, which influences energy production. Consequently, for a same wind power density, the wind turbine associated with the tower of the present disclosure yields, in some examples, a greater AEP than some other wind turbines known in the art having towers without such diameters at the predetermined height; for example, but without limitation, a gain in AEP of 0.1 % or 0.2% may be achieved, in some cases even a gain of 1 .0% or more may be achieved.
[0021] Additionally or alternatively, a tower according to the present disclosure may make a more cost-effective use of materials for manufacturing of the tower and / or more cost- effective assembling of the tower, for example but without limitation, when volume and / or mass are / is reduced. By way of example, blades of a wind turbine that includes the tower according to the present disclosure may be less rigid than blades of wind turbines with other towers, and / or less steps for making the blades rigid are necessary in the manufacturing of the blades, thereby reducing manufacturing costs.
[0022] In the context of the present disclosure, the minimum blade tip to tower distance is preferably measured when the at least one blade is facing the tower and towards the first end, for example a surface (e.g., a ground) when the concrete tower is erected on a surface.
[0023] In some examples, the minimum blade tip to tower distance occurring at the predetermined height is for a predetermined length of at least one blade of the tower or wind turbine. In some examples, a predetermined length of the at least one blade (from a root thereof to a tip thereof) is greater than or equal to 75 m. Preferably, the predetermined length is greater than or equal to 80 m.
[0024] In some examples, a predetermined length of the at least one blade (from a root thereof to a tip thereof) is smaller than or equal to 90 m. Preferably, the predetermined length Is smaller than or equal to 85 m.
[0025] In some examples, the predetermined length of the at least one blade is between 80 and 83 m.
[0026] In some examples, a predetermined length of the at least one blade is greater than or equal to 0.6 times a total height of the tower.
[0027] In some examples, a predetermined length of the at least one blade is smaller than 0.9 times a total height of the tower.
[0028] In some examples, the concrete tower includes any one of: a rotor with a plurality of blades (with the at least one blade), a nacelle, a drive train, a gearbox, a generator, a steel tower, or a combination thereof. In some examples, each blade of the plurality of blades has the predetermined length.
[0029] In some examples, the tower, and optionally the rotor and / or plurality of blades, is / are designed and arranged such that the predetermined height is greater than or equal to one eighth (i.e. , 0.125) of a total height of the tower and smaller than or equal to one third (i.e., 0.333) of the total height of the tower.
[0030] In some examples, the minimum blade tip to tower distance occurs in a range between to one eighth and one third of the total height of the tower when the at least one blade is rotating and when the at least one blade is not rotating, i.e., while the rotor of the wind turbine is in operation and while it is not in operation.
[0031] In some examples, the rotor is arranged on the tower with a conning smaller than or equal to 10°. Preferably, the conning is smaller than or equal to 5°.
[0032] In some examples, a first portion or region of the tower has a first conicity and a second portion or region of the tower has a second conicity. The first portion or region has a first height ranging from the first end to a reference position of the tower that is between the first and second ends. The second portion or region has a second height ranging from the reference position of the tower to the second end. Hereinafter, the first and second portions or regions will be referred to as first portion and second portion, respectively, although they could be referred to as first region and second region, respectively, as well. Preferably, the first and second portions each has a truncated cone shape. Also, the reference position may also be referred to as reference level or height without departing from the scope of the present disclosure. The first conicity is greater than the second conicity.
[0033] Conicity, a, in degrees, of a tower section or a portion (e.g., first portion, second portion) can be calculated as follows:
[0034] _ Di ~ ^2
[0035] C~ h a = arctan where c is the conicity in dimensionless units or radians, Di is the greatest diameter of the tower section or portion, D2 is the smallest diameter of the tower section or portion, and h is the height (i.e., length) of the tower section or portion. Di and D2 are, preferably, the greatest and smallest outer diameters of the respective tower section or portion.
[0036] In the context of the present disclosure, conicity may be calculated for tower sections or portions regardless of whether respective lateral surface(s) or generatrix(es) thereof are straight or curved, said lateral surface(s) or generatrix(es) corresponding to an outer surface of the tower.
[0037] In some examples, Di is measured or measurable at an end of the tower section closest to the first end of the tower or at an end of the portion that is closest to the first end of the tower; D2 is measured or measurable at an opposite end to that for measuring Di , i.e., the end of the tower section or portion farthest away from the first end of the tower; and h is a height of the tower section or portion.
[0038] Other suitable equations for calculating conicity are also possible and fall within the scope of the present disclosure.
[0039] In some examples, the reference position is at a length (i.e., height) of the tower equal to the predetermined height.
[0040] In some examples, the first conicity is greater than or equal to 1 .50 times the second conicity.
[0041] In some examples, the first conicity is smaller than or equal to 2.50 times the second conicity. That is to say, in some examples, the conicity of the portion closest to a foundation, when the tower is assembled, is between 1.50 to 2.50 times the conicity of the portion farthest away from the foundation.
[0042] Such conicity relationship reduces, or further reduces, the likelihood of the blades of the wind turbine colliding with the tower, especially when a rotor of the wind turbine is in operation and / or in presence of strong wind gusts or vortices.
[0043] In some examples, at least each tower section completely within the first portion has a conicity greater than a conicity of each tower section completely within the second portion.
[0044] In some examples, a conicity of one, some or all tower sections completely within the first portion is between 1.5 and 3.0 times a conicity of one, some or all tower sections completely within the second portion. Preferably, a conicity of one, some or all tower sections completely within the first portion is between 1.5 and 2.0 times a conicity of one, some or all tower sections completely within the second portion.
[0045] In some examples, the first conicity is between 1.00° and 2.50°. Preferably, the first conicity is between 1.05° and 2.00°. In some examples, the first conicity is between 1.10° and 2.00°.
[0046] In some examples, the second conicity is between 0.65° and 1.50°. Preferably, the second conicity is between 0.70° and 1.05°. In some examples, the second conicity is smaller than or equal to 1 .00°.
[0047] In some examples, a ratio defined by an outer diameter of the tower at the predetermined height divided by an outer diameter of the tower at the first end of the tower is between 0.70 and 0.90, and preferably the ratio is between 0.75 and 0.85.
[0048] Such ratio characterizes the reduction of outer diameter at the predetermined height with respect to the outer diameter at the first end, i.e. , at the part of the tower section that is attached to the ground or a foundation. Some known towers feature a ratio greater than 0.90, for example equal to or greater than 0.95. Accordingly, a tower according to these examples achieves a greater reduction in outer diameter than known towers, which consequently enables attachment of longer blades and / or have the blades at a greater distance from the tower.
[0049] In some examples, the plurality of tower sections has two or more tower sections with different height.
[0050] In some examples, the plurality of tower sections has two or more tower sections with same height.
[0051] In some examples, the reference position is at a distance smaller than or equal to 1 / 3 (i.e., one third) of a height of the tower from the first end.
[0052] In some examples, the reference position is at a distance greater than or equal to 1 / 8 (i.e., one eighth) of a height of the tower from the first end.
[0053] In some examples, the reference position is, with respect to a height of the tower or stack, at a distance greater than or equal to 0.85 times the predetermined length of the blade from the second end, and / or greater than or equal to the length of the blades minus 10 m from the second end. Preferably, the distance is greater than or equal to 0.90 and / or 0.95 and / or 1 .00 times the predetermined length of the blade.
[0054] In some examples, the reference position is, with respect to a height of the tower or stack, at a distance smaller than or equal to 1.15 times the predetermined length of the blade from the second end, and / or smaller than or equal to the length of the blades plus 10 m from the second end. Preferably, the distance is smaller than or equal to 1.10 and / or 1.05 and / or 1 .00 times the predetermined length of the blade.
[0055] That is to say, in some examples, the reference position is close to the blade tip, and that closeness is with a variation of ±15% and / or ± 10 m in height.
[0056] In some examples, an outer diameter of a tower section at the reference position is between 5.0 m and 7.0 m, and more preferably between 5.5 m and 6.0 m.
[0057] In some examples, an outer diameter of the tower section at the first end of the tower is between 6.0 m and 9.0 m, preferably between 7.0 m and 8.5 m, and more preferably between 7.25 m and 8.0 m, and an outer diameter of the tower section at the second end of the tower is between 2.5 m and 5.0 m, preferably between 3.0 m and 4.5 m, and more preferably between 3.5 m and 4.0 m.
[0058] A second aspect of the disclosure relates to a wind turbine. The wind turbine includes a concrete tower as described in the first aspect.
[0059] The first end of the concrete tower is adapted to include or be connected to a foundation. The second end of the concrete tower is adapted to include or be connected to a nacelle or a steel tower with a nacelle.
[0060] In some examples, the wind turbine includes a rotor with a plurality of blades.
[0061] In some examples, the wind turbine includes a nacelle.
[0062] In some examples, the wind turbine includes a drive train.
[0063] In some examples, the wind turbine includes a gearbox.
[0064] In some examples, the wind turbine includes a generator.
[0065] In some examples, the wind turbine includes a steel tower.
[0066] In some examples, a ratio of A1 divided by A2 is defined, and the ratio is smaller than or equal to 0.625. Preferably, the ratio is smaller than or equal to 0.525. More preferably, the ratio is smaller than or equal to 0.40.
[0067] In some examples, the ratio is greater than or equal to 0.20.
[0068] A1 is, when the rotor is in operation, a first minimum distance between a tip of one or more blades of the plurality of blades and the tower. A2 is, when the rotor is not in operation, a second minimum distance between the tip of the one or more blades and the tower.
[0069] The rotor being in operation preferably means that the blades are moving at a speed greater than a predetermined speed such as, for example but without limitation, 0.62 rad / s, or rotating such that the blades at least perform a predetermined number of revolutions per minute as, for example but without limitation, 6 rpm. The rotor not being in operation preferably means that the blades are moving at a speed lower than or equal to a predetermined speed such as, for example but without limitation, 0.62 rad / s, or rotating such that the blades perform fewer revolutions than a predetermined number of revolutions per minute as, for example but without limitation, 6 rpm. In some cases, the rotor is not in operation when the blades are not moving or rotating.
[0070] In some examples, A1 is between 1 / 15 (i.e. , one fifteenth) and 1 / 8 (i.e. , one eighth) times a length of the one or more blades (from a root thereof to a tip thereof), and A2 is between 1 / 6 (i.e., one sixth) and 1 / 3 (i.e., one third) times the length of the one or more blades.
[0071] In some examples, the minimum blade tip to tower distance varies between A1 and A2 when the rotor is in operation and when the rotor is not in operation, respectively.
[0072] In some examples, the reference position is a position, in height of the tower, of the tip of the plurality of blades when arranged according to six o’clock or that falls within a height range corresponding to the height the tip of the plurality of blades plus-minus 10 m. Additionally or alternatively, in some examples, the reference position is in a position, in height of the tower, of minimum blade tip (of the one or more blades) to tower distance.
[0073] A third aspect relates to a wind farm. The wind farm may include a plurality of wind turbines as described in the second aspect. The wind farm may additionally or alternatively include a plurality of concrete towers as described in the first aspect.
[0074] A fourth aspect relates to a method of manufacturing a concrete tower. The method includes the step of arranging a plurality of tower sections. The method also includes the step of stacking the plurality of tower sections up to form a concrete tower as described in the first aspect.
[0075] Accordingly, in examples, the plurality of tower sections is stacked up to form a tower, thereby providing the concrete tower, such that at least: a tower section at a first end of the tower has the first diameter and a tower section at a second end of the tower has the second diameter, with the first diameter being greater than the second diameter; a diameter of the tower varies, progressively or intermittently, from the first diameter to the second diameter between the first and second ends of the tower; the tower has an outer diameter between 4.0 and 8.0 m, preferably between 5.0 m and 7.0 m and / or 5.5 and 7.0 m, at a predetermined height, falling between the first end and the second end, proximate to a height that a tip of at least one blade is at when oriented according to six o’clock.
[0076] Examples as those described with reference to the first aspect may also be manufactured with the method of the fourth aspect in some examples.
[0077] A fifth aspect relates to a method of manufacturing a wind turbine. The method includes a step of arranging a plurality of tower sections. The method also includes a step of stacking the plurality of tower sections up to form a concrete tower as described in the first aspect. The method also includes a step of arranging a nacelle with a rotor, or a steel tower with the nacelle, at the second end of the tower. The rotor includes a plurality of blades (with the at least one blade).
[0078] Examples as those described with reference to the first aspect and / or the second aspect may also be manufactured with the method of the fifth aspect in some examples.
[0079] BRIEF DESCRIPTION OF THE DRAWINGS
[0080] To complete the description and in order to provide for a better understanding of the disclosure, a set of drawings is provided. Said drawings form an integral part of the description and illustrate embodiments of the disclosure, which should not be interpreted as restricting the scope of the disclosure, but just as examples of how the disclosure can be carried out. The drawings comprise the following figures:
[0081] Figure 1 shows a wind turbine in accordance with some examples.
[0082] Figure 2 shows a wind turbine in accordance with some examples.
[0083] Figure 3 shows a tower section of a tower in accordance with some examples.
[0084] Figure 4 shows a wind turbine in accordance with some examples.
[0085] Figure 5 shows a tower in accordance with some examples.
[0086] Figure 6 shows a tower in accordance with some examples.
[0087] DETAILED DESCRIPTION
[0088] Figure 1 shows a wind turbine 10 in accordance with some examples, particularly with the wind turbine and a rotor thereof not in operation. Figure 2 also shows a wind turbine 10 in accordance with some examples, for example the same wind turbine 10 of Figure 1 with blades of the wind turbine moving, thus with the wind turbine and a rotor thereof in operation.
[0089] The wind turbine 10 includes a tower 20 with stacked up tower sections 21 between a first end 22 and a second end 23 according to an axis h (e.g., a vertical axis, a tower axis), which may correspond to a height axis of the tower 20 when assembled on or in a surface 1 , e.g., a ground. Each tower section 21 has or is made of concrete.
[0090] The wind turbine 10 may also include a nacelle 50 arranged at the second end 23 of the tower 20, a rotor 40 and a plurality of blades 30. Each blade ends on a tip 30b thereof and has a length 31 along a length axis of the respective blade, which may be measured when the blade is not moving or when the rotor 40 is not in operation.
[0091] Each tower section 21 of the tower 20 has a frustoconical shape with a base surface larger than a top surface, as it will be explained in more detail in Figure 3. A minimum blade tip to tower distance 35, A1 , A2 may be measured when blades 30 are moving and / or when blades 30 are motionless, i.e., when the rotor 40 is in operation and / or when the rotor 40 is not in operation. The distance 35 is the minimum distance that may be measured, in a straight line perpendicular to the axis h (and, when the tower is assembled on a ground, parallel to the ground in a horizontal plane), e.g., the tower axis, to a closest point on the surface of the tower 20. When blades 30 are moving, such as in Figure 2, the minimum blade tip to tower distance A2 may be smaller than the distance A1 when blades 30 are motionless owing to the flection of the blades 30. As aforesaid, in the context of the present disclosure, the minimum blade tip to tower distance 35 is preferably measured when the blade 30 is facing the tower and downwards to the surface 1 (e.g., the ground), such as in Figures 1 and 2, so that the distance is the minimum that can be measured owing to the geometry of the tower 20 and the greater proximity between the tip 30b of the blade 30 and an external surface of the tower 20, particularly the external surface of the closest tower section 21. This means that the blade 30 is preferably at a six o’clock position when observing the tower 20 from a front thereof.
[0092] A predetermined height 80, according to axis h, in a vicinity at which the minimum blade tip to tower distance 35 occurs in the tower 20 and / or a height of the tip 30b when oriented downwardly is preferably measured from the first end 22. The predetermined height 80 may be measured when the rotor 40 is not in operation, as in Figure 1 , or when the rotor 40 is in operation, as in Figure 2. Generally, the predetermined height 80 will be different when measured when the rotor 40 is not in operation than from the predetermined height 80 measured when the rotor 40 is in operation. At the predetermined height 80, the tower 20 has an outer diameter D between 4.0 and 8.0 m, preferably between 5.0 m and 7.0 m.
[0093] In some examples, when the predetermined height 80 is measured from the first end 22, the predetermined height 80 is between 0.125 (i.e., 1 / 8) and 0.333 (i.e., 1 / 3) of a height (illustrated with arrowed line L) of the tower 20. An alternate predetermined height (not illustrated) may also be measured from the second end 23, and it is between 0.667 (2 / 3) and 0.875 (7 / 8) of the height of the tower 20. Such positioning for the predetermined height 80 may be convenient for providing the minimum blade tip to tower distance 35.
[0094] As illustrated in Figure 2, in some examples, a first portion 24a and a second portion 24b of the tower 20 may be defined with respect to a given reference position 24’, which may correspond to a cross-section of the tower 20 that is taken perpendicularly to the axis h (e.g., the tower axis); the first portion 24a is the portion closest to the surface 1 when the tower 20 is assembled thereon or therein, whereas the second portion 24b is the portion farthest away from the surface 1 when the tower 20 is assembled thereon or therein. The reference position 24’ may be, for example, at a distance between 0.125 (i.e., 1 / 8) and 0.333 (i.e., 1 / 3) of the height of the tower 20 measured from the first end 22, and / or at a distance between 0.85 and 1.15 times the length 31 of the blades 30 measured from the second end 23. By way of example, but without limitation, the distance from the second end 23 is between 68 m and 92 m.
[0095] A conicity may be defined and computed for each of the first portion 24a and the second portion 24b. The conicity of the first portion 24a, which depends on the tower section(s) 21 (if any) within the first portion 24a and also on part of a tower section 21 at the reference position 24’ (particularly the part within the first portion 24a), is greater than the conicity of the second portion 24b, which depends on the tower section(s) 21 within the second portion 24b and also on part of a tower section 21 at the reference position 24’ (particularly the part within the second portion 24b).
[0096] Although not illustrated, in some examples, the reference position 24’ falls at an interface between two tower sections 21 and, thus, the conicity of the first portion 24a is defined and computed considering the tower sections 21 within the first portion 24a and the conicity of the second portion 24b is defined and computed considering the tower sections 21 within the second portion 24b.
[0097] Figure 3 shows a tower section 21 of a tower in accordance with some examples.
[0098] The tower section 21 has a base surface with an outer diameter 28 and a top surface with an outer diameter 29. The tower section 21 is frustoconical with respect to a height or length 27 dimension, which upon stacking two or more tower sections 21 is a dimension parallel to a height axis h as illustrated in Figure 1.
[0099] A conicity can be calculated per tower section 21 based on length 27 and outer diameters 28, 29.
[0100] When a tower section 21 is not completely within a tower portion such as the first portion 24a or the second portion 24b as illustrated in Figure 2, a third outer diameter may be defined along the height or length 27. Particularly, a cross-section taken at the reference position 24’ defines a circumference within the height or length 27 dimension. The outer diameter resulting from the cross-section may be considered for computing the conicity of both the first and second portions 24a, 24b as it acts as top surface for the first portion 24a and base surface for the second portion 24b. In these cases, it must be considered that the reference position 24’ is defined for the entire tower, thus when considering an intermediate tower section 21 of the tower with the reference position 24’ being at such intermediate tower section 21 , the height difference between the reference position 24’ (with respect to the first end) and the height or length 27 of all tower sections 21 to be beneath the intermediate tower section 21 must be computed. The diameters considered for the conicities in such situation are that at the first end and at the reference position 24’ for the first portion, and the diameters at the reference position 24’ and the second end for the second portion.
[0101] Figure 4 shows a wind turbine 10 in accordance with some examples.
[0102] The wind turbine 10 includes a tower 20 with two stacked up tower sections 21 between a first end 22 and a second end 23. Each tower section 21 has or is made of concrete.
[0103] Like in Figures 1 and 2, the wind turbine 10 may also include a nacelle 50 arranged at the second end 23 of the tower 20, a rotor 40 and a plurality of blades 30. Each blade ends on its tip 30’.
[0104] In these examples, the tower 20 has a reference position 24’ delimiting first and second portions 24a, 24b such that the first portion 24a has a conicity greater than the conicity of the second portion 24b.
[0105] The tower 20 is configured to make the tip 30b of the blades 30, when positioned according to six o’clock on the rotor 40, to be at a height 80 as described, for example, with reference to Figure 2. The height 80 of the tip 30b coincides with the predetermined height 80. Further, the tower 20 may be configured such that a reference position 24’ is within a height interval 60 from the tip 30b, the height interval 60 extending parallelly to the tower axis. The height interval 60 is defined centered at the height 80 of the tip 30b when positioned as aforesaid, and the interval 60 extends along both ends a respective predetermined distance 60a, 60b. The predetermined distance 60a, 60b may be, for example, 10 m or less. By having the predetermined height 80 and / or the reference position 24’ be at a height falling within the height interval 60, a distance between the tip 30b and the surface of the tower 20 may be ensured to let the blades 30 rotate without clipping the tower 20.
[0106] The distance of ends of the height interval 60 from any of the first and second ends 22, 23 along the tower axis can be computed based on the position of the tip 30b of the blades 30. By way of example, an end of the predetermined height interval 60 closest to the first end 22 is at a height 80 of the tip 30b minus the predetermined distance 60a.
[0107] Figure 5 shows a tower 20 in accordance with some examples.
[0108] The tower 20 includes a plurality of tower sections which has respective ends at a first end 22 and a second end 23, with a length L of the entire tower 20 being measurable between the first end 22 and the second end 23 along a tower axis. Each tower section starts and / or ends at indentations 39. Each tower section has outer diameters 25 and inner diameters 26. When conicities are computed, they may be computed with either diameters 25, 26, yet all conicities are to be computed with the same type of diameters, thus outer or inner diameters, preferably outer diameters 25.
[0109] A rotor 40 with blades 30 (only one blade being illustrated for the sake of clarity) is also shown. The rotor 40, which may be part of the tower 20 or the wind turbine including the tower 20, is arrangeable on a nacelle (not illustrated) that is couplable with the tower 20 on the second end 23, or at an end of a steel tower when coupled with the tower 20.
[0110] A root 30a of the blades 30, when the blades are arranged according to a six o’clock arrangement, is at a distance 91 , from the second end 23, in a direction parallel to the tower axis. And a tip 30b of the blades 30, in the six o’clock arrangement, is at a height 80 from the first end 22 and / or a surface 1 , in a direction parallel to the tower axis.
[0111] In some examples, a predetermined height according to the present disclosure and / or the height 80 is greater than or equal to a minimum height Hi and smaller than or equal to a maximum height H2.
[0112] The height Hi may be, for example, 1 / 8 of the length L, or 1 / 6 of the length L, or 1 / 5 of the length L, or 1 / 4 of the length L. The height H2 may be, for example, 1 / 3 of the length L, or 1 / 4 of the length L, or 1 / 5 of the length L, or 1 / 6 of the length L.
[0113] In the example of Figure 5, at least part of the tower 20 does not have a regular lateral surface or generatrix; particularly, the lateral surface or generatrix has a slope with changing sign corresponding to concave and convex slopes at different vertical positions of the tower 20. More particularly, a first portion 24a of the tower 20 has a curved generatrix, and a bottom-most part of a second portion 24b of the tower 20 also has a curved generatrix, whereas a top-most part of the second portion 24b has a substantially straight generatrix. In some other examples, a tower 20 has differently shaped generatrixes.
[0114] The following table shows the ranges of height and outer diameter of the tower 20 at different heights.
[0115] Namely, a first portion is defined between the base and the reference level 24’, and it has a height between 15.0 and 30.0 m; and a second portion is defined between the reference level 24’ and the top, and it has a height between 60.0 and 100.0 m.
[0116] Figure 6 shows a tower 20 in accordance with some examples.
[0117] Like in Figure 5, the tower 20 includes a plurality of tower sections which have respective ends at a first end 22 and a second end 23. Each tower section starts and / or ends at indentations 39. In comparison with the tower 20 of Figure 5, which has five tower sections, the tower 20 of Figure 6 has six tower sections. In other examples, the tower 20 has more tower sections or less tower sections, e.g., two tower sections or more than two tower sections.
[0118] Heights 80, Hi, H2 and distances 91 as described in relation to Figure 5 have also been illustrated in Figure 6.
[0119] The following table shows the values of height and outer diameter of the tower 20 at different heights.
[0120] Namely, a first portion is defined between the base and the reference level 24’, and it has a height between 30.0 and 50.0 m; and a second portion is defined between the reference level 24’ and the top, and it has a height between 55.0 and 105.0 m.
[0121] It will be noted that combinations of tower sections, heights and diameters (outer and / or inner) other than those shown, for the sake of clarity only, with reference to Figures 5 and 6 are possible within the scope of the present disclosure.
[0122] In the context of the present disclosure, all disclosed ranges also include the endpoints thereof.
[0123] In this text, the term “includes”, “comprises” and derivations thereof (such as “including”, “comprising”, etc.) should not be understood in an excluding sense, that is, these terms should not be interpreted as excluding the possibility that what is described and defined may include further elements, steps, etc.
[0124] On the other hand, the disclosure is obviously not limited to the specific embodiment(s) described herein, but also encompasses any variations that may be considered by any person skilled in the art (for example, as regards the choice of materials, dimensions, components, configuration, etc.), within the general scope of the invention as defined in the claims.
Claims
CLAIMS1 . A concrete tower (20) for a wind turbine (10), the concrete tower comprising: a plurality of tower sections (21) stackable one another to form the tower such that a diameter of the tower sections varies from a first diameter to a second diameter; wherein a tower section at a first end (22) of the tower has the first diameter and a tower section at a second end (23) of the tower has the second diameter, the first diameter being greater than the second diameter; and wherein the tower has an outer diameter (D) between 5.0 and 7.0 m at a predetermined height (80), falling between the first end and the second end, that is proximate to a height (80) of a tip (30b) of at least one blade (30) arranged on the concrete tower or a wind turbine with the concrete tower and oriented according to six o’clock.
2. The concrete tower (20) of claim 1 , wherein the outer diameter at the predetermined height (80) is between 5.5 m and 6.0 m.
3. The concrete tower (20) of any one of the preceding claims, wherein the predetermined height (80), measured from the first end (22), is between 1 / 8 and 1 / 3 of a total height (L) of the tower between the first end and the second end.
4. The concrete tower (20) of any one of the preceding claims, wherein a ratio defined by the outer diameter (D) of the tower at the predetermined height (80) divided by an outer diameter of the tower at the first end (22) of the tower is between 0.70 and 0.90.
5. The concrete tower (20) of any one of the preceding claims, wherein a predetermined length (31) of the at least one blade (30) is between 75 and 90 m.
6. The concrete tower (20) of claim 5, further comprising a rotor (40) with a plurality of blades (30), wherein each blade of the plurality of blades has the predetermined length (31).
7. The concrete tower (20) of any one of the preceding claims, wherein a first portion (24a) of the tower comprises a first conicity and a second portion (24b) of the tower comprises a second conicity, wherein the first portion has a first height ranging from the first end to a reference position (24’) of the tower between the first and second ends, and wherein the second portion has a second height ranging from the reference position of the tower to the second end, wherein the first and second heights are defined by an axis (h) extending fromthe first end to the second end; and wherein the first conicity is greater than the second conicity.
8. The concrete tower (20) of claim 7, wherein the first conicity is between 1.50 times and 2.50 times the second conicity.
9. The concrete tower (20) of any one of claims 7-8, wherein the reference position (24’) is at a distance: between 1 / 8 and 1 / 3 of the total height (L) of the tower from the first end (22); and / or between 0.85 and 1.15 times a predetermined length (31) of the at least one blade (30) from the second end (23).
10. The concrete tower (20) of claim 9, wherein the reference position (24’) is at a height that falls within a height range corresponding to a height (80) of the tip (30b) of the at least one blade (30) plus-minus 10 m, and optionally the reference position is at the height of the tip of the at least one blade.11 . The concrete tower (20) of any one of the preceding claims, wherein the tower section (21) at the first end (22) is adapted for arrangement of the tower to a ground or foundation, and wherein the tower section (21) at the second end (23) is adapted for attaching a nacelle (50) or a steel tower thereto.
12. A wind turbine (10) comprising: a concrete tower (20) according to any one of the preceding claims; and a rotor (40) with a plurality of blades (30).
13. A wind farm comprising: a plurality of wind turbines (10) according to claim 12 and / or a plurality of concrete towers (20) according to any one of claims 1-11.
14. A method of manufacturing a concrete tower (20), the method comprising: arranging a plurality of tower sections (21); and stacking the plurality of tower sections up to form a concrete tower according to any one of claims 1-11.
15. A method of manufacturing a wind turbine (10), the method comprising: arranging a plurality of tower sections (21);stacking the plurality of tower sections up for providing a concrete tower (20) such that: a diameter of the concrete tower varies from a first diameter to a second diameter; a tower section at a first end (22) of the concrete tower has the first diameter and a tower section at a second end (23) of the concrete tower has the second diameter, the first diameter being greater than the second diameter; and the tower has an outer diameter (D) between 5.0 and 7.0 m at a predetermined height (80), falling between the first end and the second end, that is proximate to a height (80) of a tip (30b) of at least one blade (30) arranged on the concrete tower or a wind turbine with the concrete tower and the at least one blade is oriented according to six o’clock; and arranging a nacelle (50) with a rotor (40), or a steel tower with the nacelle, at the second end of the concrete tower, the rotor comprising a plurality of blades (30) with the at least one blade.