초록 ▼

The present invention provides a wind generator tower and a process for assembly thereof. A truncated conical tower assembled from reinforced concrete modules disposes of a tensioning system which provides greater resistance to the same and, in turn, the joints defined between the modules which form

The present invention provides a wind generator tower and a process for assembly thereof. A truncated conical tower assembled from reinforced concrete modules disposes of a tensioning system which provides greater resistance to the same and, in turn, the joints defined between the modules which form the tower are sealed.

대표청구항 ▼

1. A wind turbine tower defined by a surface of revolution, the wind turbine tower being tapered upwardly and comprising: at least one annular section composed of at least four modules that join together to form the at least one annular section, wherein the at least four modules respectively dispose

1. A wind turbine tower defined by a surface of revolution, the wind turbine tower being tapered upwardly and comprising: at least one annular section composed of at least four modules that join together to form the at least one annular section, wherein the at least four modules respectively dispose of an upper horizontal side, a lower horizontal side and a first lateral side and a second lateral side, each side comprising a beginning endpoint and an ending endpoint, wherein for at least two of the modules of the at least one annular section: at least a portion of the first lateral side and at least an opposing portion of the second lateral side are parallel and directly adjacent to the lower horizontal side, andthe upper horizontal side is shorter than the lower horizontal side. 2. The wind turbine tower according to claim 1, further comprising guiding means which are located on the lateral sides of the modules. 3. The wind turbine tower according to claim 2, further comprising horizontal joints set by pouring a filler into horizontal spaces and vertical joints set by pouring a filler into the vertical spaces, wherein the guiding means are additionally adapted to act as provisional fixing means of the modules until the setting of the vertical and horizontal joints. 4. The wind turbine tower according to claim 3, wherein the guiding means comprise of at least one projection destined to fit in a guide located respectively in the lateral sides of the modules. 5. The wind turbine tower according to claim 1, wherein each annular section defines horizontal spaces with each one of the adjacent annular sections, the wind turbine tower further comprising horizontal joints set by pouring a filler into the horizontal spaces. 6. The wind turbine tower according to claim 1, wherein each module comprises longitudinal inclusions defined in the lateral sides which delimit vertical spaces between adjacent modules, the wind turbine tower further comprising vertical joints set by pouring a filler into the vertical spaces. 7. The wind turbine tower according to claim 6, wherein the lateral sides further comprise elastic elements designated to seal a defined space between the adjacent modules. 8. The wind turbine tower according to claim 1, wherein the modules are positioned in a stepped way with a first module located at a greater height than a second module and a third module. 9. The wind turbine tower according to claim 8, wherein each of the lateral sides of the second module and the third module comprise two surfaces that form an angle between them of less than about 180°. 10. The wind turbine tower according to claim 1, further comprising joints between lateral sides wherein the joints further comprise bolts which cross at least one of the modules and are threaded onto one of the modules adjacent to the first. 11. The wind turbine tower according to claim 10, wherein the bolts comprise an intermediate part with a non-circular section. 12. The wind turbine tower according to claim 1, further comprising tensioning cables which are anchored at their lower part to a foundation close to the base of the tower and at their upper part to a mast running along the exterior surface of the modules. 13. The wind turbine tower according to claim 12, wherein the modules further comprise grooves on their exterior surface arranged to house the tensioning cables. 14. The wind turbine tower according to claim 12, wherein the tensioning cables are fixed to intermediate positions on the tower using anchors. 15. The wind turbine tower according to claim 1, wherein the two lateral sides adjacent to the lower horizontal side of at least one of the modules are comprised on a vertical plane. 16. The wind turbine tower according to claim 1, wherein the modules further comprise two upper lateral sides, each one of them adjacent to one lateral side. 17. A method for assembling a wind turbine tower, the tower being tapered upwardly, the method comprising: providing at least one annular section composed of at least four modules that join together to form the at least one annular section, wherein the at least four modules respectively dispose of an upper horizontal side, a lower horizontal side and a first lateral side and a second lateral side, wherein for at least two of the modules of the at least one annular section: at least a portion of the first lateral side and at least an opposing portion of the second lateral side are parallel and directly adjacent to the lower horizontal side, andthe upper horizontal side is shorter than the lower horizontal side; andinserting, using a guiding means incorporated in the vertical sides of the modules, a first module by a movement at least partially vertical between a second module and a third module. 18. The method of claim 17, further comprising: thermally conditioning a filler;the vertical part of at least one of the two lateral sides creating a vertical space; andfilling the vertical space with the conditioned filler. 19. The method of claim 18, wherein the thermal conditioning of the filler comprises heating the filler above an optimal temperature if an ambient temperature is less than the optimal temperature or cooling the filler below the optimal temperature if the ambient temperature is greater than the optimal temperature, the optimal temperature being between about 15° C. and about 25° C. 20. The method of claim 17, further comprising joining the joints using joining bolts before filling the joints.