Piston compressor with enlarged regulating region

The invention claimed is: 1. A piston compressor comprising: at least one cylinder for compressing air with a respective piston, which is arranged movably therein; a compression chamber arranged above the piston in the cylinder, wherein the compression chamber has an air inlet and an air outlet and is connected at the air inlet to an inlet arrangement for air to be compressed and is connected at the air outlet to an outlet arrangement for compressed air, wherein the piston compressor is drivable by a first drive device, wherein the inlet arrangement has a pre-compression device, the pre-compression device comprising an external fan, which is drivable with variable power by a second drive device, for increasing the intake pressure at the air inlet, and a cooling device for cooling the air to be compressed, and a crankcase in which a crankshaft is arranged, on which at least one connecting rod which is connected to the respective piston is rotatably mounted, an air supply line configured to guide ambient air into the crankcase via suction by the pre-compression device, wherein intake air of the at least one cylinder is guided through the crankcase. 2. The piston compressor of claim 1 , wherein the inlet arrangement has an air-diverting device. 3. The piston compressor of claim 1 , further comprising an after-cooling device for cooling the compressed air after passage through the at least one cylinder of the piston compressor. 4. The piston compressor of claim 1 , further comprising a regulating device which regulates the power of the pre-compression device and the intake pressure at the air inlet. 5. The piston compressor of claim 4 , wherein the regulating device regulates the power of the pre-compression device between a maximum value, which corresponds to a maximum intake pressure (p max ) at the air inlet, and a minimum value, which corresponds to the intake pressure (p 0 ), which is produced by the piston stroke movement in the cylinder, at the air inlet. 6. The piston compressor of claim 5 , wherein the regulating device is connected for signaling to at least one signal transmitter and/or to at least one sensor, wherein the regulating device regulates the power of the pre-compression device depending on at least one value and/or signal from the at least one signal transmitter and/or the at least one sensor. 7. The piston compressor of claim 6 , wherein the at least one sensor is selected from a group which comprises pressure sensors, temperature sensors, volumetric flow sensors and rotational speed sensors. 8. The piston compressor of claim 6 , wherein the at least one signal transmitter is selected from a group which comprises operating management systems or control devices. 9. The piston compressor of claim 5 , wherein the regulating device regulates the power of the cooling device independently of the power of the pre-compression device. 10. A method of controlling a piston compressor, the method comprising: compressing air using at least one cylinder with a respective piston, which is arranged movably therein; driving the piston compressor by a first drive device, wherein a compression chamber arranged above the piston in the at least one cylinder, wherein the compression chamber has an air inlet and an air outlet and is connected at the air inlet to an inlet arrangement for air to be compressed and is connected at the air outlet to an outlet arrangement for compressed air; driving a pre-compression arrangement provided in the inlet arrangement with variable power by a second drive device, for increasing the intake pressure at the air inlet, the pre-compression device comprising an external fan: and cooling the air to be compressed using a cooling device, wherein a crankcase in which a crankshaft is arranged, on which at least one connecting rod which is connected to the respective piston is rotatably mounted, and an air supply line guides ambient air into the crankcase via suction by the pre-compression device, wherein intake air of the at least one cylinder is guided through the crankcase. 11. The method of claim 10 , wherein the inlet arrangement has an air-diverting device. 12. The method of claim 10 , wherein an after-cooling device is provided for cooling the compressed air after passage through the at least one cylinder of the piston compressor. 13. The method of claim 10 , wherein a regulating device is provided which regulates the power of the pre-compression device and the intake pressure at the air inlet. 14. The method of claim 13 , wherein the regulating device regulates the power of the pre-compression device between a maximum value, which corresponds to a maximum intake pressure (p max ) at the air inlet, and a minimum value, which corresponds to the intake pressure (p 0 ), which is produced by the piston stroke movement in the cylinder, at the air inlet. 15. The method of claim 14 , wherein the regulating device is connected for signaling to at least one signal transmitter and/or to at least one sensor, wherein the regulating device regulates the power of the pre-compression device depending on at least one value and/or signal from the at least one signal transmitter and/or the at least one sensor. 16. The method of claim 15 , wherein the at least one sensor is selected from a group which comprises pressure sensors, temperature sensors, volumetric flow sensors and rotational speed sensors. 17. The method of claim 15 , wherein the at least one signal transmitter is selected from a group which comprises operating management systems or control devices. 18. The method of claim 14 , wherein the regulating device regulates the power of the cooling device independently of the power of the pre-compression device.