Single-screw compressor with a gap adjuster mechanism

What is claimed is: 1. A single-screw compressor, comprising: a screw rotor provided with a helical groove; a cylindrical wall housing the screw rotor such that the screw rotor is rotatable; a gap adjuster mechanism; and a gear-shaped gate rotor having a plurality of flat gates, the gate rotor being arranged outside the cylindrical wall, and some of the plurality of flat gates entering a space inside the cylindrical wall via an opening formed in the cylindrical wall and meshing with the screw rotor so that the gate rotor rotates together with the screw rotor, and a fluid being compressed in a compression chamber defined in the helical groove by the screw rotor, the plurality of flat gates meshing with the screw rotor, and the cylindrical wall, and the gap adjuster mechanism being configured to avoid contact between a front surface of the gate rotor toward the compression chamber and a sealing surface of the cylindrical wall facing the front surface by displacing at least one of the gate rotor and the sealing surface of the cylindrical wall in an axial direction of the gate rotor. 2. The single-screw compressor of claim 1 , wherein the gate rotor is displaceable in the axial direction, and the gap adjuster mechanism is further configured to displace the gate rotor in the axial direction so that a distance between the front surface of the gate rotor and the sealing surface of the cylindrical wall is a predetermined distance. 3. The single-screw compressor of claim 2 , wherein the gap adjuster mechanism includes a first cylinder chamber on which a first pressure acts, the first pressure varying according to an increase or a decrease in the distance between the front surface of the gate rotor and the sealing surface of the cylindrical wall, a second cylinder chamber on which a second pressure acts, the second pressure being constant, and a piston provided between the first cylinder chamber and the second cylinder chamber so as to be displaceable in an arrangement direction of the first and second cylinder chambers, and the gate rotor is configured to be displaced in the axial direction in association with displacement of the piston. 4. The single-screw compressor of claim 3 , wherein the gap adjuster mechanism further includes a first passage connecting the first cylinder chamber and a gap between the front surface of the gate rotor and the sealing surface of the cylindrical wall, a high pressure fluid passage in which a fluid in a high pressure state flows, and a pressure regulating valve provided at the high pressure fluid passage so as to adjust a pressure of the fluid flowing in the high pressure fluid passage to a constant high pressure, and the first passage is connected to a downstream side of the pressure regulating valve of the high pressure fluid passage via a throttle. 5. The single-screw compressor of claim 4 , wherein the gap adjuster mechanism further includes a second passage connecting the second cylinder chamber to the downstream side of the pressure regulating valve of the high pressure fluid passage, and the pressure regulating valve is configured to adjust the pressure of the fluid flowing in the high pressure fluid passage to the second pressure. 6. The single-screw compressor of claim 5 , further comprising: a support member supporting the gate rotor from a back side opposite to the compression chamber; and a holder rotatably supporting the support member, the holder being displaceable in the axial direction of the gate rotor, the first and second cylinder chambers being provided on an outer periphery of the holder, and the first and second cylinder chambers being arranged in the axial direction of the gate rotor, and the piston being integrated with the holder. 7. The single-screw compressor of claim 4 , wherein the gap adjuster mechanism further includes a second passage connecting the second cylinder chamber to an upstream side of the pressure regulating valve of the high pressure fluid passage, and a second pressure regulating valve provided at the second passage so as to maintain a pressure of the fluid flowing in the second passage at the second pressure. 8. The single-screw compressor of claim 7 , further comprising: a support member supporting the gate rotor from a back side opposite to the compression chamber; and a holder rotatably supporting the support member, the holder being displaceable in the axial direction of the gate rotor, the first and second cylinder chambers being provided on an outer periphery of the holder, and the first and second cylinder chambers being arranged in the axial direction of the gate rotor, and the piston being integrated with the holder. 9. The single-screw compressor of claim 3 , further comprising: a support member supporting the gate rotor from a back side opposite to the compression chamber; and a holder rotatably supporting the support member, the holder being displaceable in the axial direction of the gate rotor, the first and second cylinder chambers being provided on an outer periphery of the holder, and the first and second cylinder chambers being arranged in the axial direction of the gate rotor, and the piston being integrated with the holder. 10. The single-screw compressor of claim 4 , further comprising: a support member supporting the gate rotor from a back side opposite to the compression chamber; and a holder rotatably supporting the support member, the holder being displaceable in the axial direction of the gate rotor, the first and second cylinder chambers being provided on an outer periphery of the holder, and the first and second cylinder chambers being arranged in the axial direction of the gate rotor, and the piston being integrated with the holder. 11. The single-screw compressor of claim 1 , wherein the gap adjuster mechanism includes a detection section configured to detect a distance between the front surface of the gate rotor and the sealing surface of the cylindrical wall or a physical quantity correlating to the distance, and the gap adjuster mechanism is further configured to displace at least one of the gate rotor and the sealing surface of the cylindrical wall in the axial direction of the gate rotor, based on a value detected by the detection section in order to avoid contact between the front surface of the gate rotor and the sealing surface of the cylindrical wall.