Liquid injected screw compressor, controller for the transition from an unloaded state to a loaded state of such a screw compressor and method applied therewith

The invention claimed is: 1. A liquid injected screw compressor, comprising: a compressor element with an inlet and a controllable inlet valve to be able to close the inlet; an outlet and a pressure pipe connected thereto that is connected to a downstream consumer network and a controllable blow-off valve for blowing off compressed gas at the inlet of the compressor element; a liquid circuit with an injector for injecting liquid into the compressor element; a liquid separator provided in the pressure pipe to separate liquid from the compressed gas and a pressure vessel to collect the separated liquid; an injection pipe that connects the pressure vessel to the injector; a controller for controlling the inlet valve and the blow-off valve during a transition from an unloaded state to a loaded state when a pressure in the consumer network falls to a set desired minimum network pressure, wherein in the unloaded state, the inlet valve is closed and the blow-off valve is open and maintains a compression pressure in the pressure vessel, and in the loaded state, the inlet valve is open and the blow-off valve is closed, wherein the controller is configured in a way such that upon a transition from the unloaded state to the loaded state, when an injection pressure lies below a minimum threshold which is lower than the compression pressure, the inlet valve remains closed and is opened with a delay so that the compression pressure in the pressure vessel is gradually increased during this delay in the opening of the inlet valve, and the inlet valve is only fully opened when the injection pressure reaches the minimum threshold, wherein the inlet valve and the blow-off valve can be controlled independently of one another and wherein the pressure in the pressure vessel during the transition from the unloaded state to the loaded state is increased by the fact that the controller is such that during the transition the open blow-off valve is closed while the inlet valve remains closed during the aforementioned delay, wherein the pressure is increased by including an additional bypass with a calibrated passage to bypass the inlet valve or drawing in gas when the inlet valve is closed, whereby a controllable shut-off valve is provided in this bypass, whereby the controller is such that the shut-off valve is closed in an unloaded state and opened during the transition from the unloaded to loaded state. 2. The liquid injected screw compressor according to claim 1 , wherein the blow-off valve opens out in the input of the inlet valve. 3. The liquid injected screw compressor according to claim 1 , wherein a calibrated passage is provided that forms a bypass across the inlet valve for drawing in gas when the inlet valve is closed, more specifically a passage between the input of the inlet valve and the inlet of the compressor element. 4. The liquid injected screw compressor according to claim 1 , wherein the controller is such that the blow-off valve is closed at the start of the transition from unloaded to loaded. 5. The liquid injected screw compressor according to claim 1 , wherein the shut-off valve of the additional bypass is opened at the start of the transition from the unloaded to loaded state. 6. The liquid injected screw compressor according to claim 1 , wherein the inlet valve and the blow-off valve are able to be controlled together but in the opposite sense, and that the controller is such that during the transition from the unloaded to loaded state, at the time that the network pressure falls to the minimum network pressure, the inlet valve remains closed and the blow-off valve remains open and these valves are controlled simultaneously with a certain delay to open in the case of the inlet valve and to close in the case of the blow-off valve and that the pressure in the pressure vessel during this delay is increased by including an additional bypass with a calibrated passage to bypass the inlet valve for drawing in gas when the inlet valve is closed, whereby a controllable shut-off valve is provided in this bypass and whereby the controller is such that this shut-off valve is closed in an unloaded state and opened during the transition from the unloaded to loaded state. 7. The liquid injected screw compressor according to claim 6 , wherein the shut-off valve of the additional bypass is opened at the start of the transition from the unloaded to loaded state. 8. The liquid injected screw compressor according to claim 1 , wherein the controller is an electric or electronic controller and that the inlet valve and the blow-off valve are controlled by an electric valve. 9. The liquid injected screw compressor according to claim 1 , wherein a pressure sensor is provided to measure the pressure in the pressure vessel or the injection pressure and that the controller is such that the opening of the inlet valve is initiated upon a transition from unloaded to loaded when the measured pressure is equal to a set value. 10. The liquid injected screw compressor according to claim 9 , wherein the measured pressure is the injection pressure and that the set value of the injection pressure is the aforementioned minimum threshold. 11. The liquid injected screw compressor according to claim 9 , wherein the measured pressure is the pressure in the pressure vessel and that the set value of the pressure is a calculated or experimentally determined pressure in the pressure vessel, above which value there is no failure of the screw compressor as a result of temperature peaks in the outlet of the compressor element during the transition from unloaded to loaded. 12. The liquid injected screw compressor according to claim 11 , wherein the set pressure is a calculated pressure or an experimentally determined pressure that is as low as possible, with a safety margin taken into account or otherwise, and which is a function of the ambient temperature and of the temperature of the liquid. 13. The liquid injected screw compressor according to claim 8 , wherein the controller is such that the delay in opening the inlet valve during the transition from unloaded to loaded is determined and the inlet valve is opened after the expiry of the delay. 14. The liquid injected screw compressor according to claim 8 , wherein the delay is calculated or experimentally determined for a certain liquid injected screw compressor as a function of the desired or minimum threshold of the pressure in the pressure vessel or of the injection pressure; the ambient temperature; the time that the compressor element has been running to take account of the heating of the liquid and the time that the compressor element has been stopped to take account of the cooling of the liquid. 15. The liquid injected screw compressor according to claim 1 , wherein the controller is a type of controller whereby the compressor element is not systematically stopped to switch over from loaded to unloaded. 16. An electric or electronic controller to control a transition of a liquid injected screw compressor according to claim 1 from unloaded to loaded, in order to prevent the injection pressure, at the time of opening the inlet valve, being lower than a minimum pressure below which undesired high temperature peaks could occur in the outlet of the compressor element. 17. A method for controlling a liquid injected screw compressor, comprising a compressor element with an inlet and a controllable inlet valve to be able to close the inlet; an outlet and a pressure pipe connected thereto that is connected to a downstream consumer network and a controllable blow-off valve for blowing