Hammer drill and method for deep drilling

The invention claimed is: 1. A hammer drill comprising at least one housing having a cylinder bore, a piston mounted in said cylinder bore such that said piston can move axially between an upper end position and a lower end position, at least one lower fluid supply adapted to cyclically supply the cylinder bore with drive fluid, an upper cover and a lower cover closing the cylinder bore at each end, wherein the piston is in contact with an inner surface of the lower cover in a lower end position, and wherein a ring gap is formed between an outer surface of the piston and an inner wall of the cylinder bore, wherein said ring gap has a gap height H which is greater than H =2·( R a,cylinder +R a,piston )+3 ·D particles , wherein R a,cylinder and R a,piston denote a mean roughness values of the inner wall of the cylinder bore and the outer surface of the piston, respectively and D particle denotes a maximum particle size in the drive fluid. 2. The hammer drill of claim 1 , wherein the lower fluid supply comprises a first channel running through the upper cover and a cylinder wall and the lower cover. 3. The hammer drill of claim 1 , further comprising a flushing channel adapted to remove the drive fluid from the cylinder bore. 4. The hammer drill of claim 1 , further comprising a drilling tool, wherein an outer surface of the lower cover is in contact with said drilling tool. 5. The hammer drill of claim 1 , wherein the ring gap has a gap height between 45 μm and 1500 μm. 6. The hammer drill of claim 1 , wherein the piston has a length between 10 cm and 60 cm. 7. The hammer drill of claim 6 , wherein, during an operation of the hammer drill, a pressure loss dP gap of the drive fluid in the ring gap is greater than a quotient of a weight force F g of the piston and a cross-sectional area A of the piston, i.e. dP g ⁢ a ⁢ p > F g / A . 8. The hammer drill of claim 1 , further comprising a hydraulic pump adapted to convey the drive fluid into the cylinder bore or further comprising a hydraulic pump, adapted to deliver the drive fluid into the cylinder bore and adapted to be driven by a flushing fluid. 9. The hammer drill of claim 1 , further comprising a switching element having a cylindrical housing and a control piston slidably mounted therein, wherein the cylindrical housing has an inlet on an upper side of the cylindrical housing and a first outlet on a side wall of the cylindrical housing, wherein the control piston is adapted to be extended from the cylindrical housing by means of a compression spring so that the first outlet is unblocked and the control piston is adapted to be retracted inside the cylindrical housing in response to an axial load on the control piston against a force of the compression spring so that the first outlet is closed by the control piston, wherein the cylindrical housing furthermore has a second outlet, which is arranged inside the control piston and any of a spring valve or a throttle valve provided inside said second outlet. 10. The hammer drill of claim 9 , further comprising a flushing channel connected to the first outlet of the cylindrical housing of said switching element and the second outlet of the cylindrical housing of said switching element coupled to a hydraulic changeover switch, said hydraulic changeover switch coupled to the upper and the lower fluid supply. 11. The hammer drill of claim 1 , further comprising an upper fluid supply, said upper fluid supply comprising a second channel running through the upper cover and adapted to cyclically supply the cylinder bore with drive fluid. 12. A method for deep drilling using a hammer drill with at least one housing having a cylinder bore, the method comprising: mounting a piston inside said cylinder bore such that said piston can move axially between an upper end position and a lower end position, wherein a ring gap is formed between an outer surface of the piston and an inner wall of the cylinder bore, wherein said ring gap has a gap height H which is greater than H =2·( R a,cylinder +R a,piston )+3 ·D particle , wherein R a,cylinder and R a,piston denote a mean roughness values of the inner wall of the cylinder bore and the outer surface of the piston, respectively and D particle denotes a maximum particle size in the drive fluid; closing the cylinder bore with an upper cover and a lower cover at each end; cyclically supplying a drive fluid to the cylinder bore by at least a lower fluid supply: letting the piston strike against an inner surface of the lower cover in the lower end position. 13. The method of claim 12 , wherein the drive fluid is supplied alternately to both ends of the cylinder bore by said lower fluid supply and an upper fluid supply. 14. The method of claim 13 , wherein the drive fluid is supplied to the cylinder bore at a pressure dP gap that is greater than a quotient of a weight force of the piston Fg and a cross-sectional area A of the piston, dP g ⁢ a ⁢ p > F g / A . 15. The method of claim 14 , wherein the cylinder bore comprises a flushing channel and the drive fluid is removed from the cylinder bore by means of said flushing channel. 16. The method of claim 14 , wherein the drive fluid is delivered by a hydraulic pump which is driven by a flushing fluid. 17. The method of claim 16 , wherein the hammer drill further comprises a switching element, wherein the drive fluid is supplied to said switching element, wherein a fluid flow of said drive fluid to the hammer drill is blocked while the hammer drill is lowered into a drill hole and the fluid flow of said drive fluid to the hammer drill is switched on when a bottom of the drill hole is reached. 18. The method of claim 13 , wherein an outer surface of the lower cover is in contact with a drilling tool.