Foundation for a wind turbine

1 . An openwork load-bearing structure for a wind turbine, wherein the openwork load-bearing structure comprises: primary structures via which loads which occur in the load-bearing structure as a result of the wind turbine are dissipated; and secondary structures, which perform functional, rather than load-dissipating tasks; wherein the secondary structures are arranged on the primary structures and are connected integrally thereto, wherein the integral connection between the primary structures and the secondary structures is in the form of a connecting layer arranged therebetween. 2 . The openwork load-bearing structure according to claim 1 , wherein the connecting layer is in the form of an adhesive layer. 3 . The openwork load-bearing structure according to claim 1 , wherein each of the secondary structures is secured to a sleeve, which positively fits one of the primary structures, and wherein the connecting layer is formed between the sleeve and the primary structure. 4 . The openwork load-bearing structure according to claim 3 , wherein the sleeve is of multipart design. 5 . The openwork load-bearing structure according to claim 3 , wherein the primary structure is tubular, and wherein the sleeve is formed as a part-shell. 6 . The openwork load-bearing structure according to claim 5 , wherein the sleeve together with other sleeves or together with one or more auxiliary shells forms a complete ring. 7 . The openwork load-bearing structure according to claim 1 , wherein said openwork load-bearing structure is a foundation structure, wherein one or more of the primary structures is a corner post or a leg, and wherein one or more of the secondary structures is a pile stopper for depth-limiting the corner post or leg when the corner post or leg is inserted into a driven foundation pile. 8 . The openwork load-bearing structure according to claim 7 , wherein the pile stopper completely encloses the corner post or the leg forming an annular gap, and wherein the connecting layer is arranged in the annular gap. 9 . The openwork load-bearing structure according to claim 8 , wherein the pile stopper is constructed of several part-annular segments. 10 . The openwork load-bearing structure according to claim 7 , wherein the pile stopper is constructed of a bottom pile stopper ring plate with a central through hole for the corner post or the leg, a cylindrical extension surrounding the through hole and arranged on the inside of the ring of the pile stopper ring plate, and several reinforcing fins, which are arranged extending radially outwardly between pile stopper ring plate and extension along a perimeter of the extension which is arranged substantially perpendicular on the pile stopper ring plate, and wherein the pile stopper ring plate is sized radially surmounting the foundation pile at the corner post or leg inserted in the foundation pile. 11 . The openwork load-bearing structure according to claim 8 , wherein spacers are arranged on the annular gap side cylindrical surface of the pile stopper, via which the corner post or the leg are kept at a distance from the pile stopper. 12 . The openwork load-bearing structure according to claim 1 , wherein the secondary structure is a J tube or a boat dock. 13 . A method for producing an openwork load-bearing structure for a wind turbine, wherein the load-bearing structure includes primary structures via which loads which occur in the load-bearing structure as a result of the wind turbine are dissipated, and secondary structures, which perform functional, rather than load-dissipating tasks, the method comprising: integrally connecting at least one primary structure to a secondary structure by arranging a setting connecting layer between the at least one primary structure and the secondary structure. 14 . The method according to claim 13 , wherein the connecting layer is in the form of an adhesive layer. 15 . The method according to claim 13 , wherein the secondary structure is secured to a sleeve, which positively fits the primary structure, and wherein the connecting layer is formed between sleeve and primary structure. 16 . Method according to claim 15 , wherein the secondary structure is secured to the sleeve prior to connecting the sleeve to the primary structure. 17 . The method according to claim 13 , wherein the secondary structure is a pile stopper, and the primary structure is a corner post or leg. 18 . The method according to claim 17 , wherein, prior to connecting the pile stopper to the corner post or the leg, a measurement of the pre-driven foundation piles is performed to determine an appropriate location of the pile stopper at the corner post or leg, and wherein the pile stopper is secured at the appropriate location on the corner post or leg as determined by the measurement. 19 . The method according to claims 13 , wherein connecting device are arranged in an area of the connecting layer with the use of grout, for improving shear stability.