Compressor or vacuum pump device, a liquid return system for such a compressor or vacuum pump device and a method for draining liquid from a gearbox of such a compressor or vacuum pump device

The invention claimed is: 1. A compressor or vacuum pump device with a liquid-injected compressor or vacuum pump element ( 2 ), which compressor or vacuum pump device ( 1 ) further comprises a liquid return system ( 7 ), a motor ( 4 ) to drive the liquid-injected compressor or vacuum pump element ( 2 ), a gearbox ( 3 ) provided between the motor ( 4 ) and the liquid-injected compressor or vacuum pump element ( 2 ), and a liquid separator vessel ( 5 ) in fluid connection with an outlet ( 6 ) of the liquid-injected compressor or vacuum pump element ( 2 ), wherein the liquid return system ( 7 ) comprises a main body ( 8 ) with a chamber provided with an outlet ( 16 ) and a first inlet ( 9 ), wherein the first inlet ( 9 ) is in fluid connection with the liquid separator vessel ( 5 ) and receives a first compressed gas flow ( 11 ) from the liquid separator vessel ( 5 ), and wherein the outlet ( 16 ) is in fluid connection with an injection point ( 17 ) of the liquid-injected compressor or vacuum pump element ( 2 ), wherein the chamber is also provided with a second inlet ( 12 ) which is in fluid connection with the gearbox ( 3 ) and receives a second fluid flow ( 15 ) from the gearbox ( 3 ), and wherein the chamber is configured to mix the aforementioned first compressed gas flow ( 11 ) and a second fluid flow ( 15 ) together into a third fluid flow ( 20 ), which third fluid flow ( 20 ) leaves the chamber via the outlet ( 16 ) and is directed via the injection point ( 17 ) into the liquid-injected compressor or vacuum pump element ( 2 ). 2. The compressor or vacuum pump device according to claim 1 , wherein the second inlet ( 12 ) is in fluid connection with the gearbox ( 3 ) by means of a suction line ( 13 ). 3. The compressor or vacuum pump device according to claim 2 , wherein the suction line ( 13 ) is made of a transparent material. 4. The compressor or vacuum pump device according to claim 2 , wherein the suction line ( 13 ) is provided with a sensor ( 21 ) which is configured to detect a presence of liquid in the suction line ( 13 ). 5. The compressor or vacuum pump device according to claim 4 , wherein the sensor ( 21 ) is an optical sensor. 6. The compressor or vacuum pump device according to claim 4 , wherein the sensor ( 21 ) is provided with a transmitter ( 22 ) that is configured to send a signal that can be received by a receiver. 7. The compressor or vacuum pump device according to claim 6 , wherein the signal is a wireless signal. 8. The compressor or vacuum pump device according to claim 1 , wherein the liquid-injected compressor or vacuum pump element ( 2 ) is an oil-injected compressor or vacuum pump element. 9. The compressor or vacuum pump device according to claim 1 , wherein the liquid-injected compressor or vacuum pump element ( 2 ) is a water-injected compressor or vacuum pump element. 10. The compressor or vacuum pump device according to claim 1 , wherein the liquid return system ( 7 ) further comprises a relief valve ( 25 ) integrated on the main body ( 8 ). 11. The compressor or vacuum pump device according to claim 1 , wherein the liquid return system ( 7 ) is configured to control a flow rate of the third fluid flow ( 20 ). 12. The compressor or vacuum pump device according to claim 1 , wherein the liquid return system ( 7 ) further comprises an underpressure generating means ( 19 ), which underpressure generating means ( 19 ) generates an underpressure in the gearbox ( 3 ). 13. The compressor or vacuum pump device according to claim 12 , wherein the underpressure generating means ( 19 ) is provided in the main body ( 8 ) of the liquid return system ( 7 ) as a venturi ejector. 14. The compressor or vacuum pump device according to claim 1 , wherein the second inlet ( 12 ) is in fluid connection with the gearbox ( 3 ) via a non-return valve ( 14 ), which non-return valve ( 14 ) allows only a fluid flow from the gearbox ( 3 ) to the liquid return system ( 7 ). 15. The liquid return system for the compressor or the vacuum pumping device according to claim 1 , which compressor or vacuum pump device ( 1 ) further comprises the motor ( 4 ) to drive the liquid-injected compressor or vacuum pump element ( 2 ), the gearbox ( 3 ) provided between the motor ( 4 ) and the liquid-injected compressor or vacuum pump element ( 2 ), and the liquid separator vessel ( 5 ) in fluid connection with the outlet ( 6 ) of the liquid-injected compressor or vacuum pump element ( 2 ), wherein the liquid return system ( 7 ) comprises the main body ( 8 ) with the chamber provided with the outlet ( 16 ) and the first inlet ( 9 ), wherein the first inlet ( 9 ) is configured to be in fluid connection with the liquid separator vessel ( 5 ) and to receive the first compressed gas flow ( 11 ), and wherein the outlet ( 16 ) is configured to be in fluid connection with the injection point ( 17 ) of the liquid-injected compressor or vacuum pump element ( 2 ), wherein the chamber is further provided with the second inlet ( 12 ) which is configured to be in fluid connection with the gearbox ( 3 ) and to receive the second fluid flow ( 15 ), wherein the chamber is configured to mix the aforementioned first compressed gas flow ( 11 ) and second fluid flow ( 15 ) together into the third fluid flow ( 20 ), which third fluid flow ( 20 ) leaves the chamber via the outlet ( 16 ), and wherein the liquid return system ( 7 ) is configured to control a flow rate of the third fluid flow ( 20 ). 16. The liquid return system according to claim 15 , wherein it further comprises a relief valve ( 25 ) integrated on the main body ( 8 ). 17. The liquid return system according to claim 15 , wherein it further comprises an underpressure generating means ( 19 ) provided in the main body ( 8 ), which underpressure generating means ( 19 ) is configured to generate an underpressure in the gearbox ( 3 ). 18. The liquid return system according to claim 17 , wherein underpressure generating means ( 19 ) is a venturi ejector. 19. The liquid return system according to claim 18 , wherein it is designed as a modular element in relation to the compressor or vacuum pump device ( 1 ) in such a way that the liquid return system ( 7 ) can be detachably arranged in fluid connection with the compressor or vacuum pumping device ( 1 ) and that after detaching the liquid return system ( 7 ) the compressor or vacuum pump device ( 1 ) can continue to function under normal operating conditions. 20. A method for draining liquid from a gearbox ( 3 ) of a compressor or vacuum pump device ( 1 ) with a liquid-injected compressor or vacuum pump element ( 2 ), wherein the compressor or vacuum pump device ( 1 ) further comprises a motor ( 4 ) for driving the liquid-injected compressor or vacuum pump element ( 2 ) and a liquid separator vessel ( 5 ) in fluid connection with an outlet ( 6 ) of the liquid-injected compressor or vacuum pump element ( 2 ), wherein the gearbox ( 3 ) is provided between the motor ( 4 ) and the liquid-injected compressor or vacuum pump element ( 2 ), wherein by means of a liquid return system ( 7 ) liquid is removed from the gearbox ( 3 ) by a fluid connection between said liquid return system ( 7 ) and the gearbox ( 3 ), and mixed with a liquid flow from the liquid separator vessel ( 5 ), after which the liquid mixed with this fluid flow is directed into the liquid-injected compressor or vacuum pump element ( 2 ). 21. The method according to claim 20 , wherein an underpressure generating means ( 19 ) is used to generate an underpre