Oil circuit, oil-free compressor provided with such oil circuit and a method to control lubrication and/or cooling of such oil-free compressor via such oil circuit

The invention claimed is: 1. An oil circuit for lubrication and cooling of an oil-free compressor comprising a motor with a variable speed and a compressor element driven by said motor, whereby this oil circuit is provided with an oil reservoir with oil and a rotary oil pump configured to drive oil from the oil reservoir through an inlet channel upstream the rotary oil pump to the compressor element and/or the motor via an oil pipe; whereby this rotary oil pump is provided with a rotor mounted on a rotation shaft, whereby this rotary oil pump has a swept volume, and whereby this rotary oil pump is driven by the motor of the compressor element; whereby the oil circuit is further provided with a return pipe configured to guide oil from the compressor element and/or the motor back to the oil reservoir; whereby the oil circuit is further provided with a bypass pipe and a pressure-actuated bypass valve which are configured to directly guide a portion of the oil between the rotary oil pump and the compressor element and/or the motor back to the oil reservoir without this portion of the oil passing through the compressor element and/or the motor during its way back to the oil reservoir; and whereby the oil circuit is further provided with an oil cooler, wherein the oil cooler is placed in the bypass pipe and the bypass valve is placed in the oil pipe. 2. The oil circuit according to claim 1 , wherein the oil circuit is provided with only one rotary oil pump. 3. The oil circuit according to claim 1 , wherein the oil cooler has a fixed or constant cooling capacity. 4. The oil circuit according to claim 1 , wherein the bypass valve is a mechanical valve, preferably a spring-loaded valve. 5. The oil circuit according to claim 1 , wherein the inlet channel is provided with a dam with a height that is higher than a height of a centerline of the rotation shaft of the rotary oil pump reduced with a smallest diameter of the rotor of the rotary oil pump divided by two. 6. The oil circuit according to claim 5 , wherein the height of the dam is smaller than the height of the centreline of the rotation shaft of the rotary oil pump reduced with a smallest diameter of the rotation shaft of the rotary oil pump divided by two. 7. The oil circuit according to claim 5 , wherein the dam is configured such that the rotary oil pump and the inlet channel are able to contain a volume of the oil between the rotary oil pump and the dam which is at least twice the swept volume of the rotary oil pump. 8. The oil circuit according to claim 5 , wherein the oil circuit is provided with a sensor configured to register whether oil is present between the rotary oil pump and the dam. 9. The oil circuit according to claim 5 , wherein the oil circuit is provided with a fluid connection between the oil reservoir and a space in the inlet channel between the rotary oil pump and the dam, whereby the fluid connection is configured to transfer oil from the oil reservoir to the space between the rotary oil pump and the dam. 10. An oil-free compressor comprising an oil circuit for its lubrication and cooling, whereby this oil-free compressor comprises a motor with a variable speed and a compressor element driven by said motor; whereby this oil circuit is provided with an oil reservoir with oil and a rotary oil pump configured to drive oil from the oil reservoir through an inlet channel upstream the rotary oil pump to the compressor element and/or the motor via an oil pipe; whereby this rotary oil pump is provided with a rotor mounted on a rotation shaft, whereby this rotary oil pump has a swept volume, and whereby this rotary oil pump is driven by the motor of the compressor element; whereby the oil circuit is further provided with a return pipe configured to guide oil from the compressor element and/or the motor back to the oil reservoir; whereby the oil circuit is further provided with a bypass pipe and a pressure-actuated bypass valve which are configured to directly guide a portion of the oil between the rotary oil pump and the compressor element and/or the motor back to the oil reservoir without this portion of the oil passing through the compressor element and/or the motor during its way back to the oil reservoir; and whereby the oil circuit is further provided with an oil cooler, wherein the oil-free compressor is configured such that the oil cooler is placed in the bypass pipe and the bypass valve is placed in the oil pipe. 11. The oil-free compressor according to claim 10 , wherein the oil circuit is provided with only one rotary oil pump. 12. The oil-free compressor according to claim 10 , wherein the oil cooler has a fixed or constant cooling capacity. 13. The oil-free compressor according to claim 10 , wherein the bypass valve is a mechanical valve, preferably a spring-loaded valve. 14. The oil-free compressor according to claim 10 , wherein the inlet channel is provided with a dam with a height that is higher than a height of a centreline of the rotation shaft of the rotary oil pump reduced with a smallest diameter of the rotor of the rotary oil pump divided by two. 15. The oil-free compressor according to claim 14 , wherein the height of the dam is smaller than the height of the centreline of the rotation shaft of the rotary oil pump reduced with a smallest diameter of the rotation shaft of the rotary oil pump divided by two. 16. The oil-free compressor according to claim 14 , wherein the dam is configured such that the rotary oil pump and the inlet channel are able to contain a volume of the oil between the rotary oil pump and the dam which is at least twice the swept volume of the rotary oil pump. 17. The oil-free compressor according to claim 14 , wherein the oil circuit is provided with a sensor configured to register whether oil is present between the rotary oil pump and the dam. 18. The oil-free compressor according to claim 14 , wherein the oil circuit is provided with a fluid connection between the oil reservoir and a space in the inlet channel between the rotary oil pump and the dam, whereby the fluid connection is configured to transfer oil from the oil reservoir to the space between the rotary oil pump and the dam. 19. The oil-free compressor according to claim 10 , wherein the oil-free compressor is an oil-free screw compressor. 20. A method to control lubrication and/or cooling of an oil-free compressor via an oil circuit, whereby this oil-free compressor comprises a motor with a variable speed and a compressor element driven by said motor; whereby this oil circuit is provided with an oil reservoir with oil and a rotary oil pump configured to drive oil from the oil reservoir through an inlet channel upstream the rotary oil pump to the compressor element and/or the motor via an oil pipe; whereby this rotary oil pump is provided with a rotor mounted on a rotation shaft, and whereby this rotary oil pump is driven by the motor of the compressor element; whereby the oil circuit is further provided with a bypass pipe and a pressure-actuated bypass valve through which a portion of the oil between the rotary oil pump and the compressor element and/or the motor is directly guided back to the oil reservoir without this portion of the oil passing through the compressor element and/or motor during its way back to the oil reservoir; and whereby the oil circuit is further provided with an oil cooler, wherein the portion of the pumped oil which is guided back to the oil reservoir through the bypass pipe and the bypass valve, passes through the oi