Screw compressor

1 .- 36 . (canceled) 37 . A vertical screw compressor comprising: a compression chamber, comprising an inlet and an outlet, that is formed by a compression housing in which a pair of meshed helical compressor rotors in the form of a screws are rotatably mounted; rotor shafts of said meshed helical compressor rotors extend parallel to one another along first and second rotational axes, respectively; a non-return valve provided at the inlet of the compression chamber; a drive motor that is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned pair of meshed helical compressor rotors, wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another, and wherein the rotor shafts of the compressor rotors extend at an angle with or transverse to the horizontal plane during normal operation of the vertical screw compressor, and a pressure vessel, arranged downstream and separate from the compressor housing, comprising an outlet valve; wherein, when the vertical screw compressor is stopped, the pressure vessel, the compression chamber, and the motor chamber are configured to be able to be in fluid communication and be under a practically equal pressure such that a seal between the compression chamber and the motor chamber is not necessary. 38 . The vertical screw compressor according to claim 37 , wherein the motor shaft is directly coupled to one of the rotor shafts of the compressor rotors and extends along an axial direction in line with the first or second rotational axes of the rotor shaft of the compressor rotor concerned. 39 . The vertical screw compressor according to claim 37 , wherein the motor shaft also forms the rotor shaft of one of the compressor rotors. 40 . The vertical screw compressor according to claim 37 , wherein the drive motor is an electric motor with a motor rotor and a motor stator. 41 . The vertical screw compressor according to claim 40 , wherein the electric motor is equipped with permanent magnets to generate a magnetic field. 42 . The screw compressor according to claim 40 , wherein the electric motor is a synchronous motor. 43 . The screw compressor according to claim 40 , wherein the drive motor is of a type that can withstand the compressor pressure. 44 . The screw compressor according to claim 40 , wherein the drive motor is of a type that can generate a sufficiently large start-up torque to start up the screw compressor when the compression chamber is under compressor pressure. 45 . The screw compressor according to claim 37 , wherein the compressor rotors have a high pressure end that are supported axially and radially in the compressor housing by bearings, by means of one or more outlet bearings. 46 . The screw compressor according to claim 37 , wherein the compressor rotors have a low pressure end that is only supported radially in the compressor housing by one or more inlet bearings. 47 . The screw compressor according to claim 37 , wherein the motor shaft, at the end opposite the driven compressor rotor, is supported axially and radially in the compressor housing by means of one or more motor bearings. 48 . The screw compressor according to claim 37 , wherein the compression housing forms a base or bottom section of the compressor housing, and that the motor housing forms a head or top section of the compressor housing and wherein the compression chamber inlet for drawing in air is provided near a low pressure end, and wherein the low pressure end is at the ends of the compressor rotor that is closest to the head of the compressor housing, and the outlet for removing compressed air is provided near a high pressure end, and wherein the high pressure end is at the ends of the compressor rotors that are the closest to the base or bottom section of the compressor housing. 49 . The screw compressor according to claim 37 , wherein the screw compressor is provided with a fluid, with which both the drive motor and the compressor rotors are cooled and/or lubricated, wherein the screw compressor is provided with a cooling circuit for cooling both the drive motor and the compression chamber and through which fluid can flow from a head of the compressor housing to a base of the compressor housing, wherein the cooling circuit consists of cooling channels that are provided in the motor housing and of the compression chamber itself, wherein the cooling channels at least partially extend along an axial direction, and wherein the fluid is driven through the cooling channels under a compressor pressure generated by the screw compressor. 50 . A screw compressor that at least comprises the following elements: a compression chamber, comprising an inlet and an outlet, that is formed by a compression housing in which a pair of meshed helical compressor rotors in the form of a screws are rotatably mounted; rotor shafts of said meshed helical compressor rotors extend parallel to one another along first and second rotational axes, respectively; a non-return valve provided at the inlet of the compression chamber; a drive motor that is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned pair of meshed helical compressor rotors, wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, whereby the motor chamber and the compression chamber are not sealed off from one another and whereby the screw compressor is a vertical screw compressor in which the rotor shafts of the compressor rotors as well as the motor shaft extend at an angle transverse to the horizontal plane during normal operation of the screw compressor, wherein, when the screw compressor is stopped, a pressure vessel, the compression chamber, and the motor chamber are configured to be able to be in fluid communication and remain under a substantially equal compression pressure until the screw compressor is restarted, wherein the drive motor is an electric motor with a motor rotor and a motor stator, wherein the electric motor is equipped with permanent magnets to generate a magnetic field, and wherein the position of the motor rotor is determined by measuring the difference between an inductance of the electric motor along a direct motor axis and an inductance of the electric motor along an axis perpendicular to said direct motor axis, wherein the measuring takes place at a position outside of the compressor housing. 51 . A method for controlling a vertical screw compressor comprising the steps: providing a vertical screw compressor comprising a compression chamber, including an inlet and an outlet, that is formed by a compression housing in which a pair of meshed helical compressor rotors in the form of screws are rotably mounted, rotor shafts of said meshed helical compressor rotors extending parallel to one another along first and second rotational axes, respectively, wherein a non-return valve provided at the inlet of the compression chamber, a drive motor is provided with a motor chamber formed by a motor housing, in which a motor shaft is rotatably mounted that drives at least one of the aforementioned pair of meshed helical compressor rotors, wherein the compression housing and the motor housing are connected directly to one another to form a compressor housing, wherein the motor chamber and the compression chamber are