Hip joint implant with reshapeable fastening brackets

The invention claimed is: 1. A hip joint implant for fastening to a pelvic bone comprising: a support body comprising a socket with a convex outer face designed to bear on the pelvic bone; a concave inner face with a receiving seat to receive a joint head of a femoral component of a hip prosthesis, wherein the support body comprises a top between the convex outer face and the concave inner face; and a fastening ring comprising at least two outwardly directed flat fastening brackets arranged at the edge of the fastening ring and providing at least one opening for receiving the support body, wherein the fastening ring is dimensioned to extend around a perimeter of the support body, and wherein the top of the support body and a top of the fastening ring form a flat, level surface. 2. The hip implant joint of claim 1 , wherein the fastening brackets are made of a reshapeable biocompatible material. 3. The hip implant joint of claim 1 , wherein the fastening brackets are connected to the socket via a non-releasable cohesive bond, and the socket is made from a more stiff biocompatible material. 4. The hip joint implant of claim 3 , wherein the cohesive bond is a welded connection. 5. The hip joint implant of claim 4 , wherein the welded connection is an electron beam welded connection. 6. The hip joint implant of claim 5 , wherein the cohesive bond has a welded-through weld seam. 7. The hip joint implant of claim 1 , said fastening ring engaging around the support body and connected to the support body by a cohesive bond. 8. The hip joint implant of claim 7 , wherein the fastening brackets are prefabricated with openings for fastening, and the fastening ring is prefabricated with an opening for receiving the support body. 9. The hip joint implant of claim 1 , wherein an external diameter of the support body is dimensioned to enable an interference fit between the support body and the fastening ring. 10. The hip joint implant of claim 1 , wherein the support body is made of a non-cold-formable material. 11. The hip joint implant of claim 1 , wherein the support body is made of a titanium alloy which is less formable than pure titanium with tensile strength of at least 800 MPa. 12. The hip joint implant of claim 1 , wherein the fastening brackets are made of pure titanium of grade 2, 3, or 4, and the support body is made of a titanium alloy. 13. The hip joint implant of claim 1 , wherein the support body has a circumferential support shoulder, wherein the circumferential support shoulder is configured to contact a bottom of the fastening ring, wherein the bottom of the fastening ring is opposite the top of the fastening ring. 14. The hip joint implant of claim 1 , wherein the support body has a transition region between the support body and fastening brackets comprising a milled surface. 15. A modular hip joint system comprising: the hip joint implant of claim 1 , further comprising a plurality of sockets which are differently configured but have a uniform external diameter. 16. The modular hip joint system of claim 15 , wherein a plurality of uniform external diameters are provided graduated in different sizes. 17. A method for producing a hip joint implant for fastening to a pelvic bone, with a support body which has a socket and whose convex outer face is designed to bear on the pelvic bone and which, on a concave inner face, together with a bearing component, forms the seat for receiving a joint head of a femoral component of a hip prosthesis, wherein the support body comprises a top between the convex outer face and the concave inner face, and with a fastening ring comprising outwardly directed flat fastening brackets which are arranged at the edge region of the fastening ring and are each provided with at least one opening for receiving the support body, the method comprising: prefabricating the support body and the socket from a first material, prefabricating the fastening brackets from a reshapeable, biocompatible second material, pre-assembly of the fastening brackets on the support body, welding of the fastening brackets to the support body, and milling support body and the socket so that a top of the support body and the top of the fastening ring form a flat, level surface. 18. The method of claim 17 , wherein the welding is electron beam welding. 19. The method of claim 17 , wherein the welding step is an electron beam welding, forming a welded-through weld seam. 20. The method of claim 17 , wherein the support body has a circumferential support shoulder, wherein the circumferential support shoulder is configured to contact a bottom of the fastening ring, wherein the bottom of the fastening ring is opposite the top of the fastening ring.