Hammer drill

The invention claimed is: 1. A hammer drill comprising: a body; a cylinder mounted within the body; a piston slideably mounted within the cylinder; a motor mounted within the body having an output spindle; a reciprocating drive mechanism mounted within the body which, when the motor is activated, converts the rotary movement of the spindle of the motor into a reciprocating movement of the piston within the cylinder; a ram slideably mounted within the cylinder which is reciprocatingly driven by the reciprocating movement of the piston via an air spring; at least two air entry points formed through the wall of the cylinder in different axial positions along the length of the cylinder, each of which are capable of replenishing the air spring; a tool holder mounted on the body, the tool holder being capable of holding a cutting tool which, during normal use, is repetitively struck by the reciprocating ram; the tool holder is capable of holding a cutting tool in a range of axial positions, the average axial position of the cutting tool within the tool holder during use being dependent on the hardness of the material being cut by the cutting tool; wherein there is further provided a selector mechanism which selectively opens and close the air entry points; characterized in that the selector mechanism opens only one air entry point at any one time during normal use, the selector mechanism closing all other air entry points, each of the air entry points capable of replenishing the air spring during normal use when opened by the selector mechanism; and a detection mechanism which determines the position of a cutting tool within the tool holder and provides an indication of the cutting tools position; and the selector mechanism, in response to indication of the detection mechanism, opens and closes the air entry points dependent on the average position of the cutting tool within the tool holder. 2. The hammer of claim 1 , wherein the cylinder comprises two air entry points, the selector mechanism opening one air entry point when it closes the other air entry point and vice versa. 3. The hammer of claim 1 , wherein the dimensions of the at least two air entry points are different relative to each other. 4. The hammer of claim 1 , wherein at least one of the air entry points is further opened and closed using the ram. 5. The hammer of claim 1 , wherein at least one of the air entry points is further opened and closed using the piston. 6. The hammer of claim 1 , wherein the air entry points comprise a single bleed hole formed through the wall of the cylinder. 7. The hammer of claim 6 , wherein the selector mechanism comprises a sleeve mounted in an axially slideable manner on the cylinder and which comprises at least two apertures which are capable of being selectively aligned with one or more of the bleed holes as the sleeve is axially slid along the cylinder, the sleeve closing the remaining bleed holes. 8. The hammer of claim 1 , wherein the detection mechanism determines the average position of the cutting tool. 9. The hammer of claim 1 , wherein there is further provided: a beat support structure mounted within the housing; a beat piece slideably mounted within the beat piece support structure, wherein the ram strikes a cutting tool via the beat piece, the detection mechanism determining the position of a cutting tool within the tool holder by determining the position of the beat piece within the beat piece support structure. 10. The hammer of claim 9 , wherein the detection mechanism determines the average position of the beat piece. 11. The hammer of claim 9 , wherein the beat piece comprises a flange, wherein the detection mechanism determines the position of the flange. 12. The hammer of claim 11 , wherein the detection mechanism comprises a rod which is biased towards and capable of engaging with the flange. 13. A hammer drill comprising: a body; a cylinder mounted within the body; a piston slideably mounted within the cylinder; a motor mounted within the body having an output spindle; a reciprocating drive mechanism mounted within the body which, when the motor is activated, converts the rotary movement of the spindle of the motor into a reciprocating movement of the piston within the cylinder; a ram slideably mounted within the cylinder which is reciprocatingly driven by the reciprocating movement of the piston via an air spring; at least two air entry points formed through the wall of the cylinder in different axial positions along the length of the cylinder, each of which are capable of replenishing the air spring; a tool holder mounted on the body, the tool holder being capable of holding a cutting tool which, during normal use, is repetitively struck by the reciprocating ram; wherein there is further provided a selector mechanism which selectively opens and close the air entry points; characterized in that the selector mechanism opens only one air entry point at any one time during normal use, the selector mechanism closing all other air entry points, each of the air entry points capable of replenishing the air spring during normal use when opened by the selector mechanism; wherein the selector mechanism comprises a finger pad capable of being engaged by the operator, the finger pad being movable and operated manually to open and close the air entry points. 14. A method of altering the performance characteristics of a hammer comprising: a body; a cylinder mounted within the body; a piston slideably mounted within the cylinder; a motor mounted within the body having an output spindle; a reciprocating drive mechanism mounted within the body which, when the motor is activated, converts the rotary movement of the spindle of the motor into a reciprocating movement of the piston within the cylinder; a ram slideably mounted within the cylinder which is reciprocatingly driven by the reciprocating movement of the piston via an air spring; at least two air entry points formed through the wall of the cylinder in different axial positions along the length of the cylinder, each of which are capable of replenishing the air spring; a tool holder mounted on the body; a cutting tool held by the tool holder which, during use, is repetitively struck by the reciprocating ram, the cutting tool being capable of being held by the tool holder in a range of axial positions, the average axial position of the cutting tool within the tool holder during use being dependent on the hardness of the material being cut by the cutting tool; characterized in that the method comprises the steps of measuring the position of the cutting tool within the tool holder; and selectively opening one of the air entry points dependent on the average position of the cutting tool within the tool holder whilst closing the other air entry points, the open air entry point replenishing the air spring during normal use. 15. The method of claim 14 , wherein the method further comprising the step of measuring the average position of the cutting tool within the tool holder. 16. The method of claim 14 , wherein there is further provided: a beat support structure mounted within the housing; a beat piece slideably mounted within the beat piece support structure, wherein the ram strikes the cutting tool via the beat piece, the method further comprising the steps of determining the position of a cutting tool within the tool holder by determining the position of the beat piece within the beat piece support structure. 17. The method of claim 16 , wherein the method further comprising the step of me