Concentricity adjustment sleeve

The invention claimed is: 1. A method of adjusting a position and a concentricity of a die subassembly relative to a central axial tip, the method comprising: using a die body assembly that includes the central axial tip; using a die subassembly positioned adjacent and in contact with the die body assembly, the die subassembly comprising a retaining device to connect the die subassembly to the die body assembly; using an adjustment sleeve subassembly including an adjustment sleeve circumferentially positioned adjacent the die subassembly and rotationally moveable relative thereto and an adjustment device connected to the adjustment sleeve at a fixed position thereon, the adjustment device being radially moveable relative to the die subassembly and in contact with the die subassembly; rotating the adjustment sleeve relative to the die body and the die subassembly and thereby moving the adjustment device connected thereto to any degree of rotation relative to the die subassembly to thereby adjust the concentricity of the die subassembly relative to the die body assembly and the central axial tip thereof from any rotational position of the adjustment device relative to the die subassembly through the adjustment device's contact with the die subassembly while maintaining the retaining device tightened sufficiently to prevent leakage between the die subassembly and the die body assembly. 2. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 1 , wherein said die subassembly includes a die. 3. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 2 , wherein said die subassembly additionally includes a die holder and one or more die nuts circumferentially joined to the die holder and an axial bore is formed between the central axial tip of the die body assembly and the die of the die subassembly. 4. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 3 , further including a tip module which is a solid module positioned in the axial bore forming a gap with the die subassembly and includes the central axial tip. 5. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 1 , wherein said adjustment sleeve subassembly comprises a concentrical shouldered sleeve with more than one adjustment device that is placed over the die subassembly. 6. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 1 , wherein said adjustment sleeve subassembly maintains concentricity of the die subassembly, and said adjustment sleeve subassembly is capable of rotating around the die subassembly when the adjustment device is loosened. 7. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 4 , wherein the gap is an annular exit channel. 8. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 4 , wherein the gap is a profile exit channel. 9. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 1 , wherein said adjustment device is a bolt. 10. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 1 , wherein the adjustment sleeve subassembly is rotated by a first motor. 11. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according claim 10 , wherein the adjustment device is actuated by a second motor. 12. The method of adjusting the position and the concentricity of the die subassembly relative to the central axial tip according to claim 11 , wherein operation of the first and second motors are controlled by feedback of results of testing the concentricity of an extruded product.