Air compressor

The invention claimed is: 1. An air compressor for compressing atmospheric air to provide compressed air suitable for installing optical fiber units and cable using a blown fiber method, the compressor including an oil separator connected to a supply of compressed air, the oil separator comprising: a chamber having a wall defining a cavity within the chamber, the wall having an externally-facing surface; and a vent comprising a channel within the wall, or on the externally-facing surface of the wall, and extending between, at a first end, a first aperture and, at a second end, a second aperture through the wall to the cavity, such that in operation heated, compressed air laden with both oil and water vapor enters the vent via the first aperture, is cooled by being driven in a first direction along the channel, and exits the vent into the cavity via the second aperture in a second direction opposite the first direction. 2. A compressor according to claim 1 wherein if the channel is on the externally-facing surface, the wall is configured to cooperate with an internally-facing surface of an oil separator housing to form the vent. 3. A compressor according to claim 1 further comprising: a compressor housing; a moveable element within the compressor housing which in use compresses air by reducing space available to the air; and a motor which during operation moves the movable element, being coupled in a parallel arrangement to the moveable element via a gearing allowing for the moveable element to move at a speed different from a motor operation speed. 4. A compressor according to claim 3 wherein the moveable element moves at a speed slower than the motor operation speed. 5. A compressor according to claim 3 wherein the moveable element comprises blades in a rotary vane arrangement, and wherein the motor is arranged to rotate the blades during operation. 6. A compressor according to claim 3 wherein the gearing comprises an arrangement including a belt and pulleys. 7. A compressor according to claim 3 wherein the compressed air is pressurized to 10 bar. 8. A compressor according to claim 3 wherein the air is further processed to obtain a smooth, pulse-free supply of air which is substantially free of at least one of excessive moisture, excessive dryness, excessive warmth, or excessive oil. 9. A compressor according to claim 1 , wherein the compressor is configured to blow an optical fiber into a tube. 10. A system for installing an optical fiber into a tube using pressurized air supplied by an air compressor for compressing atmospheric air, the compressor comprising an oil separator connected to a supply of compressed air, the oil separator comprising: a chamber having a wall defining a cavity within the chamber, the wall having an externally-facing surface; and a vent comprising a channel within the wall, or on the externally-facing surface of the wall, and extending between, at a first end, a first aperture and, at a second end, a second aperture through the wall to the cavity, such that in operation heated, compressed air laden with both oil and water vapor enters the vent via the first aperture, is cooled by being driven in a first direction along the channel, and exits the vent into the cavity via the second aperture in a second direction opposite the first direction. 11. A method for installing an optical fiber into a tube by using pressurized air supplied by a compressor, the method comprising: blowing the optical fiber into the tube using the compressor, the compressor comprising an oil separator connected to a supply of compressed air, the oil separator comprising: a chamber having a wall defining a cavity within the chamber, the wall having an externally-facing surface, a vent comprising a channel within the wall, or on the externally-facing surface of the wall, and extending between, at a first end, a first aperture and, at a second end, a second aperture through the wall to the cavity, such that heated, compressed air laden with both oil and water vapor enters the vent via the first aperture, is cooled by being driven in a first direction along the channel, and exits the vent into the cavity via the second aperture in a second direction opposite the first direction.