Abstract: A compressor comprises a compressing mechanism for compressing a fluid that contains lubricating oil, and a separation chamber that is to have revolved therein fluid compressed by the compressing mechanism, wherein at least part of the lubricating oil contained in the fluid is separated by centrifugal force produced by this revolution, and wherein only this introduced fluid is present in the separation chamber.

Abstract: A compressor comprises a compressing mechanism which compresses fluid including a lubricant, a separation chamber into which the fluid compressed by the compressing mechanism is introduced and in which at least a portion of the lubricant included in the fluid is separated from the fluid, and an oil-storage chamber in which the lubricant separated from the fluid in the separation chamber is stored. An oil-introducing passage is formed between the separation chamber and the oil-storage chamber to bring these chambers into communication with each other, the oil-introducing passage introduces the lubricant separated in the separation chamber into the oil-storage chamber, an opening of the oil-introducing passage on the side of the oil-storage chamber is lower than an oil level of the lubricant stored in the oil-storage chamber in the vertical direction.

Abstract: A sealed type motor-driven compressor includes a cylindrical motor housing and an annular stator core fastened to the interior of the motor housing. A method of assembling the compressor includes fastening the stator core to the motor housing by mechanically deforming at least one of the motor housing and the stator core. It is thus possible to set the fastening interference between the motor housing and the stator core to a sufficiently great level for suppressing loosening of the stator core with respect to the motor housing, which may otherwise be caused by a relatively high pressure produced by refrigerant gas.

Abstract: A cooling unit which contains refrigerant for exchanging heat with an object member of cooling includes a refrigerant passage and cooling means. The refrigerant passage allows the refrigerant to circulate therethrough. The cooling means communicates with the refrigerant passage for supplying the refrigerant passage with the refrigerant. The cooling means includes a refrigeration circuit, a compressor, a condenser, decompression means, an evaporator, a refrigerant supply path, a refrigerant return path, refrigerant control means and first pressure control means. The refrigerant control means has an on mode which allows the refrigerant to circulate through the refrigerant passage at a flow rate which enables the refrigerant to maintain gas-liquid two-phase flow by allowing the condenser to communicate with the refrigerant passage, and an off mode which prevents the refrigerant from circulating through the refrigerant passage by preventing the condenser from communicating with the refrigerant passage.

Abstract: A sealed type motor-driven compressor includes a cylindrical motor housing and an annular stator core fastened to the interior of the motor housing. A method of assembling the compressor includes fastening the stator core to the motor housing by mechanically deforming at least one of the motor housing and the stator core. It is thus possible to set the fastening interference between the motor housing and the stator core to a sufficiently great level for suppressing loosening of the stator core with respect to the motor housing, which may otherwise be caused by a relatively high pressure produced by refrigerant gas.

Abstract: The compressor of the invention is reduced in the size of separation chamber by eliminating the separation pipes in the separation chamber, and is hence manufactured at low cost. The compressor of the invention is a compressor comprising a compressing mechanism (1, 2, 4) for compressing a fluid that contains lubricating oil, and a separation chamber (51) that is revolved by having introduced thereinto the fluid compressed by the compressing mechanism (1, 2, 4) and in which at least part of the lubricating oil contained in the fluid is separated by the centrifugal force produced by this revolution, in which only the introduced fluid is present in the separation chamber.

Abstract: A torque receiving member is fixed to a rotary shaft of a compressor. A pulley, which is rotated by an external drive source, is rotatably supported by a housing of the compressor. The pulley is substantially coaxial with the torque receiving member. A rubber damper is located between the pulley and the torque receiving member. The rubber damper absorbs rotational vibration transmitted from the torque receiving member to the pulley. The pulley has a dynamic damper. The dynamic damper includes rollers, which swing like pendulums to reduce rotational vibration of the pulley. Stress produced due to displacement between the axis of the pulley and the torque receiving member is reduced by the rubber damper.

Abstract: A compressor includes a housing, a rotary shaft, a pulley, an electric motor, a pulley one-way clutch, and a motor one-way clutch. The shaft is rotatably supported by the housing. The pulley is operably connected to the shaft and includes a power transmission portion. When power is transmitted from a vehicular engine to the power transmission portion, the pulley is rotated. The electric motor rotates the shaft and includes a rotor, which is operably connected to the shaft. At least part of the electric motor overlaps the power transmission portion in the axial direction of the shaft. The pulley one-way clutch is located between the pulley and the shaft and selectively permits and prevents power transmission between the pulley and the shaft. The motor one-way clutch is located between the rotor and the shaft and selectively permits and prevents power transmission between the rotor and the shaft.

Abstract: A compressor comprises a compressing mechanism which compresses fluid including a lubricant, a separation chamber into which the fluid compressed by the compressing mechanism is introduced and in which at least a portion of the lubricant included in the fluid is separated from the fluid, and an oil-storage chamber in which the lubricant separated from the fluid in the separation chamber is stored. An oil-introducing passage is formed between the separation chamber and the oil-storage chamber to bring these chambers into communication with each other, the oil-introducing passage introduces the lubricant separated in the separation chamber into the oil-storage chamber, an opening of the oil-introducing passage on the side of the oil-storage chamber is lower than an oil level of the lubricant stored in the oil-storage chamber in the vertical direction.

Abstract: A compressor has a pulley for transmitting torque from an external drive source to a rotary shaft to drive a compression mechanism. The pulley has a pulley body. The compressor has a mass body located in a range that is radially inward of the outer circumference of the pulley. The mass body swings about an axis that is spaced from the rotation axis of the pulley body by a predetermined distance and is substantially parallel to the rotation axis of the pulley body.

Abstract: A mechanical rotational device includes a housing. An end portion of a rotary shaft protrudes from a front wall of the housing. An electric rotational device is coaxial with the rotary shaft and is coupled to the end portion of the rotary shaft. The electric rotational device functions as at least one of a motor and a generator. A rotational member is coupled to the rotary shaft and has a power transmitting mechanism for transmitting power between the rotational unit and an external device. A one-way clutch is located in the power transmitting path between the rotary shaft and rotational member. The one-way clutch is located inward of the rotational member. The electric rotational device is located on or forward of the housing. At least part of the electric rotational device is located outward of the power transmitting mechanism.

Abstract: A power transmitting mechanism transmits power from an engine to a drive shaft of a compressor. A pulley is supported by the compressor and is coupled to the engine. A hub is attached to the drive shaft. Rollers are located on the pulley. Elastic transmission arms are located between the pulley and the hub. The distal end of each arm is curved, and the proximal end is coupled to the hub. When the rollers are engaged with the arms, power is transmitted between the pulley and the hub. When, due to excessive torque, the rollers escape from the corresponding arm, power transmission between the pulley and the hub is disconnected. The distal ends of the arms are movable in the radial direction. When the rollers disengage from the corresponding arms, the distal ends of the arms move radially such that the pulley and the hub relatively rotate without interference by the arms.

Abstract: When an electric appliance unit functions as an electric motor, a rotary shaft is rotated by electric current supplied to the electric appliance unit. When the electric appliance unit functions as a generator, the generator generates electricity as the rotary shaft rotates. A first rotation permitting mechanism is located between the rotor and the rotary shaft to permit the rotor and the rotary shaft to rotate relative to each other. A one-way clutch is located between the rotor and the rotary shaft. The one-way clutch permits the rotary shaft to rotate in one direction relative to the rotor and prevents the rotary shaft from rotating in the other direction relative to the rotor. A second rotation permitting mechanism is located between the housing and the rotor. The second rotation permitting mechanism permits the rotor to rotate relative to the housing. Power transmitted from the external drive source to the rotor is transmitted to the rotary shaft via the one-way clutch.

Abstract: A housing of a compressor supports a rotary shaft. The rotary shaft is coupled to a pulley with a pulley one-way clutch and is coupled to a rotor of an electric motor with a motor one-way clutch. The pulley is supported by the housing with a pulley bearing. The electric motor overlaps a power transmission portion in the axial direction of the rotary shaft. At least two of the bearing, the pulley one-way clutch, the motor one-way clutch, and a brush device of the electric motor overlap each other in the axial direction of the rotary shaft. As a result, the size of the compressor is reduced in the axial direction of the rotary shaft.

Abstract: A power transmission mechanism has a first rotating member rotating around an axis, a second rotating member rotating around the axis and an elastic member located between the first rotating member and the second rotating member. The first rotating member has a first rotating member surface, and the second rotating member has a second rotating member surface. The elastic member has at least a protrusion contacting at least the first rotating member surface. The protrusion extends in a circumferential direction of the first rotating member. The protrusion has gradually tapering shape toward the first rotating member surface. The elastic member is deformed by compression as the elastic member engages the first rotating member surface and the second rotating member surface by rotation of the first rotating member, thereby causing relative rotation of the first rotating member and the second rotating member.

Abstract: A torque limiter is placed between a first rotary body and a second rotary body in a power transmission path. The torque limiter has a breaking portion, a flange connected to the first rotary body and a connecting portion protruding from the flange. The connecting portion is screwed to the second rotary body at a predetermined value of fastening torque. The torque is transmitted between the first rotary body and the second rotary body in a relative rotational direction of fastening the connecting portion to the second rotary body. A portion of the flange belongs to the first rotary body after the breaking portion of the flange is broken. The portion of the flange forms a regulating surface for fastening the connecting portion to the second rotary body. The fastening torque is regulated by a contact on the regulating surface between the flange and the second rotary body.

Abstract: An engaging projection is engaged with an engaging recess to connect a pulley and a receiving member to each other so that power is transmitted. The engaging recess deforms with respect to the pulley and the receiving member. During the power transmission between the pulley and the receiving member, an elastic member permits engaging recess to deform, thereby enabling the pulley to rotate relative to the receiving member in a predetermined angular range. In this state, the engaging projection normally abuts against a sliding surface of the engaging recess at a neutral position, and the contact position of the engaging projection and the engaging recess separates from the neutral position in accordance with the increase of the load on the receiving member. As the contact position separates from the neutral position, the inclination angle of the sliding surface with respect to the circumferential direction of the rotary bodies gradually increases.

Abstract: A compressor includes a housing, a rotary shaft, a pulley, an electric motor, a pulley one-way clutch, and a motor one-way clutch. The shaft is rotatably supported by the housing. The pulley is operably connected to the shaft and includes a power transmission portion. When power is transmitted from a vehicular engine to the power transmission portion, the pulley is rotated. The electric motor rotates the shaft and includes a rotor, which is operably connected to the shaft. At least part of the electric motor overlaps the power transmission portion in the axial direction of the shaft. The pulley one-way clutch is located between the pulley and the shaft and selectively permits and prevents power transmission between the pulley and the shaft. The motor one-way clutch is located between the rotor and the shaft and selectively permits and prevents power transmission between the rotor and the shaft.

Abstract: A housing of a compressor supports a rotary shaft. The rotary shaft is coupled to a pulley with a pulley one-way clutch and is coupled to a rotor of an electric motor with a motor one-way clutch. The pulley is supported by the housing with a pulley bearing. The electric motor overlaps a power transmission portion in the axial direction of the rotary shaft. At least two of the bearing, the pulley one-way clutch, the motor one-way clutch, and a brush device of the electric motor overlap each other in the axial direction of the rotary shaft. As a result, the size of the compressor is reduced in the axial direction of the rotary shaft.

Abstract: A rotor is connected to a main body of a rotary machine. The rotor includes a rotor main body and a dynamic damper provided in the rotor main body. The rotor main body is made of resin. The dynamic damper has a weight that swings like a pendulum. The axis of the pendulum motion of the weight is separated by a predetermined distance from and is substantially parallel to the rotation axis of the rotor. This suppresses rotational vibration and reduces noise.