DE102011001250A1 - Apparatus and method for the transition between a steel tower section and a prestressed concrete tower section - Google Patents

Abstract

The invention describes a T-shaped component (1) - preferably made of steel - which is particularly suitable for the transition between the lower prestressed concrete section (7) of a tower - preferably a wind turbine - and the rising tower section made of steel (6) - or an alternative material - to form. The tendons (8) of the lower prestressed concrete tower section (7) are led through, anchored and prestressed through recesses (3, 5) arranged in the center in a T cross section. The component (1) is thus anchored without further anchoring elements and without additional loads from eccentrically acting forces.

Description

Technical area

The present invention relates to a connection between two construction sections of a tower - preferably a tower of a wind turbine - with each other. The coupling point is the transition between a generally prestressed reinforced concrete tower section and the rising steel structure.

State of the art

Wind turbine towers with tower sections made of different materials are also referred to as hybrid towers. The lower section of concrete may consist of prefabricated concrete elements that are joined together, or of a monolithic concrete component. In order to obtain a higher stability, the construction section made of concrete material is often preloaded. This is done by means of tendons freely accessible in the tower interior or by means of tendons, which lie within the concrete cross-section and are cast after preloading. By casting the cavity between the tendon and cladding tube with an alkaline potting the tendon is particularly well protected against corrosion. In addition, the position of the tendon in the concrete cross section allows a centric biasing force with respect to the heavy line of the concrete cross section; There are no additional bending loads.

The rising tower section made of steel may consist of several tubular tower segments, which are either made in one piece or consist of several joined segments over the circumference of the section. Centric stress conditions also prevail in this steel ring cross section. As an alternative to an embodiment in steel, the upper tower section may be made of high-strength, aging-resistant plastic-for example glass fiber reinforced plastic.

At the junction of the upper tower section with the lower, prestressed concrete tower section, different materials and component thicknesses meet. Both components must be permanently connected firmly to withstand the high dynamic loads.

Various solutions of the prior art are known for this detail. Such is the patent DE 102 30 273 B3 a ring-shaped adapter element made of steel, which has holes through which the tendons are guided out of the lower concrete tower section. Above the adapter element, the tendons are anchored, so that there is a firm connection between the adapter element and prestressed concrete. At the upper end of the adapter element is a flange construction, to which the rising steel structure is connected. Due to the design, an offset of the load transfer occurs in the adapter ring, since the tendon anchoring lies outside the rising wall.

At the DE 10 2007 031 065 A1 known construction is arranged at the upper end of the concrete tower segment, an annular head beam through which the inside of the tower lying, free tendons are guided and anchored. The rising steel structure has a one-sided flange. Through the head bar extends an inclined bore through which anchoring bolts are guided. These connect steel flange and concrete component and are each fastened with two nuts. This solution allows the replacement of the anchor bolt, but also here creates an offset in the line of action of the vertical forces.

DE 10 2004 017 006 A1 describes an anchoring structure, the lower component - a bolted steel plate - is poured into the concrete of the tower shaft or the foundation. The structure of the construction is symmetrical: in the rising steel component a symmetrical, T-shaped flange is arranged through which an anchor rod is guided on both sides of the web and fastened with a nut. In the arrangement of prestressing strands in the lower tower shaft they can indeed be performed in the concrete cross-section and subsequently potted, however, the final anchorage of the tendon in the concrete cross-section is laterally adjacent to the anchoring of the rising steel segment. In order to accommodate both the anchoring structure for the rising steel tower and the final anchorage of the tendon in cross-section, an expansion of the concrete cross-section is necessary.

Alternatively, an L-shaped, one-sided flange can be formed on the rising steel segment. This is placed on the upper end of the concrete component and anchored directly from the tendon. Because of the high forces occurring and the offset between normal stresses in the steel ring and the load introduction of the preload force of the flange must be made very thick. In addition, it is also necessary in this design for geometric reasons that the concrete cross-section is widened - and that the tendon is warped out of its axis out to the final anchorage out. Due to the curvature of the tendon arise in this construction deflection forces that must also be included in the concrete section.

All known solutions have in common that at this dynamic high-load point offset from the biasing force and the Normalallkraft arises in the steel tower section.

Object of the invention

The object of the invention is to provide a transitional construction for a hybrid tower - with an upper tower section made of steel or glass fiber reinforced plastic and a lower section of prestressed concrete - which withstands the high dynamic effects, is compact and economical and the construction of the Tower simplified.

Presentation of the invention

The object is solved by the features specified in the characterizing part of claim 1.

For this purpose, the invention provides a prefabricated annular or ring segment-shaped component made of steel - or alternaively made of glass fiber reinforced plastic (GRP) - as a transition element. This has in cross section the shape of an inverted Ts with a vertically arranged web, which represents the transition to the rising cross section of the upper tower section. In the flange openings are recessed centrally in the ring direction at a defined distance from each other, through which the tendons of the prestressed concrete tower section are performed. In the area of these flange intersections, the web is preferably recessed in rounded form so as to reduce stress concentrations so that the anchor heads of the tendons can be accommodated. The tendons are threaded through the recesses in the component according to the invention. The transition element is aligned in its final position on the upper edge of the reinforced concrete tower section and potted with non-positive grout. To increase the shear force capacity so-called push knobs are arranged in an alternative embodiment below the flange, which are introduced into previously prepared depressions in the concrete. After hardening of the potting material, the anchor heads are installed and applied a defined biasing force. The anchor heads are determined, d. H. the tendons are wedged and the cladding tubes of the tendons filled with - preferably alkaline - injection material. In the next step, a corrosion protection is attached to the anchor head; this can be done demountable, so that a check of the anchor heads in the course of maintenance is possible at any time.

By applying and fixing the preload force, the transition element is connected directly to the reinforced concrete shaft. An additional fitting for anchoring or attachment of the steel tower section on the prestressed concrete tower section is not necessary.

Since the center of gravity of the steel cross-section is in line with that of the concrete cross section, there is no offset and thus no additional load resulting therefrom. The wall of the rising tower and the component thickness of the lower concrete tower section can be minimized and carried out economically. Also, a geometric expansion of the reinforced concrete wall - to accommodate other built-in parts or curved tendon guide - can be omitted.

Due to the central load introduction of the biasing and thus also the connection force in the flange of the steel component of this no bending stress in the transverse direction and can thus be designed geometrically optimized: even at this point material is saved.

In one embodiment, the transition element is ring segment-shaped and can be connected to at least one further or, for example, two or three or more, in particular identically shaped, ring-segment-shaped transition components to form a closed ring. The interconnected segments together form an annular transition element.

The invention will be explained below with reference to four drawings. Show it:

1 schematically shows a partial view of the tower - preferably the tower of a wind turbine - with the transition point between rising steel tower section six and lower prestressed concrete tower section 7 ,

In 2 is the transitional component according to the invention 1 shown in detail in the installed state. In the flange 2 of the T-shaped component 1 are recesses 3 exactly to the position of the tendons 8th arranged. In the same place is the footbridge 4 with a recess 5 Mistake. The limp tendon 8th is in the course of assembly of the component 1 through the recesses 3 in the flange 2 guided. After aligning the mortar bed 11 between component 1 and lower tower section made of concrete 7 with grout 11 filled. After hardening of the mortar 11 can the anchor head 10 in the provided recess 5 in the dock 4 to be mounted: the tendon strands 9 be through the anchor head 10 guided and secured with wedges. The biasing force is applied by means of pressing at the lower end of the tendons.

3 shows a cross section through the transition point between two tendons 8th lies. In an alternative embodiment, to increase the shear force capacity below the flange in addition so-called Schubknaggen 13 arranged in previously prepared wells 14 placed in the concrete and grouted with mortar.

4 shows a cross section through the transition point, directly in the tendon 8th lies. After preloading and securing the tendon strands 9 becomes the cladding tube 12 pressed. Subsequently, the anchor head - not shown in the drawing - protected against corrosion.

LIST OF REFERENCE NUMBERS

1

T-shaped component made of steel

2

flange

3

Recess in the flange

4

web

5

Recess in the bridge

6

Steel tower section

7

Prestressed concrete tower section

8th

tendon

9

Tendon strands

10

anchor head

11

mortar bed

12

cladding tube

13

Push knob on the insert

14

Recess in the concrete

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 10230273 B3 [0005]
• DE 102007031065 A1 [0006]
• DE 102004017006 A1 [0007]

Claims (5)

T-shaped component made of steel ( 1 ) as a transitional component at the coupling point between a lower tower section of prestressed concrete ( 7 ) and the rising tower section made of steel ( six ) which is ring-shaped or ring-segment-shaped and at least one further or for example two or three or more, in particular identically shaped annular segment-shaped transitional components to a closed ring connectable, characterized in that centrally in cross-section and at a defined distance from one another in the ring direction recesses ( 3 . 5 ) in flange ( 2 ) and bridge ( 4 ) are arranged, through which the tendons ( 8th ) of the lower prestressed concrete tower section ( 7 ) are guided, anchored and biased. Component ( 1 ) according to claim 1, characterized in that its geometric position at the transition point is such that the line of action of the tendons ( 8th ) with the heavy line of the component ( 1 ) and so a centric load introduction takes place. Component ( 1 ) according to one of claims 1 and 2, characterized in that the component ( 1 ) on the underside of the flange in addition with Schubknaggen ( 13 ), which are placed in designated depressions ( 14 ) in the lower component. Component ( 1 ) according to one of claims 1 to 3, characterized in that the component ( 1 ) made of an alternative material - preferably glass fiber reinforced plastic - is made. Method for assembling a transitional structure ( 1 ) of a hybrid tower of a rising tower section made of steel ( six ) and a lower tower section of prestressed concrete ( 7 ) according to one of claims 1 to 4, comprising the steps of: - aligning the transitional component ( 1 ) on the upper edge of the lower prestressed concrete tower section ( 7 ) with passing the tendons ( 8th ) through the openings provided ( 3 ) in the flange ( 2 ) of the component ( 1 ) - non-positive pouring of the mortar bed ( 11 ) - after curing of the mortar bed ( 11 ): Installation of anchor heads ( 10 ), Anchoring the tendon strands ( 9 ) and clamping the tendons ( 8th ) - filling the cladding tube ( 12 )

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