US20110179822A1 - Refrigerating apparatus - Google Patents

Refrigerating apparatus Download PDF

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Publication number
US20110179822A1
US20110179822A1 US13/121,541 US200913121541A US2011179822A1 US 20110179822 A1 US20110179822 A1 US 20110179822A1 US 200913121541 A US200913121541 A US 200913121541A US 2011179822 A1 US2011179822 A1 US 2011179822A1
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Prior art keywords
compression mechanism
pressure
refrigerant
pipe
suction
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US13/121,541
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English (en)
Inventor
Takazou Sotojima
Yoshitaka Shibamoto
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Daikin Industries Ltd
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Daikin Industries Ltd
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Assigned to DAIKIN INDUSTRIES, LTD. reassignment DAIKIN INDUSTRIES, LTD. ASSIGNMENT OF ASSIGNORS INTEREST (SEE DOCUMENT FOR DETAILS). Assignors: SHIBAMOTO, YOSHITAKA, SOTOJIMA, TAKAZOU
Publication of US20110179822A1 publication Critical patent/US20110179822A1/en
Abandoned legal-status Critical Current

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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B1/00Compression machines, plants or systems with non-reversible cycle
    • F25B1/10Compression machines, plants or systems with non-reversible cycle with multi-stage compression
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C18/00Rotary-piston pumps specially adapted for elastic fluids
    • F04C18/30Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
    • F04C18/32Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having both the movement defined in group F04C18/02 and relative reciprocation between the co-operating members
    • F04C18/322Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having both the movement defined in group F04C18/02 and relative reciprocation between the co-operating members with vanes hinged to the outer member and reciprocating with respect to the outer member
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C18/00Rotary-piston pumps specially adapted for elastic fluids
    • F04C18/30Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
    • F04C18/34Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members
    • F04C18/356Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the outer member
    • F04C18/3562Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having the movement defined in group F04C18/08 or F04C18/22 and relative reciprocation between the co-operating members with vanes reciprocating with respect to the outer member the inner and outer member being in contact along one line or continuous surfaces substantially parallel to the axis of rotation
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C23/00Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids
    • F04C23/001Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids of similar working principle
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C23/00Combinations of two or more pumps, each being of rotary-piston or oscillating-piston type, specially adapted for elastic fluids; Pumping installations specially adapted for elastic fluids; Multi-stage pumps specially adapted for elastic fluids
    • F04C23/008Hermetic pumps
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C28/00Control of, monitoring of, or safety arrangements for, pumps or pumping installations specially adapted for elastic fluids
    • F04C28/02Control of, monitoring of, or safety arrangements for, pumps or pumping installations specially adapted for elastic fluids specially adapted for several pumps connected in series or in parallel
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C28/00Control of, monitoring of, or safety arrangements for, pumps or pumping installations specially adapted for elastic fluids
    • F04C28/24Control of, monitoring of, or safety arrangements for, pumps or pumping installations specially adapted for elastic fluids characterised by using valves controlling pressure or flow rate, e.g. discharge valves or unloading valves
    • F04C28/26Control of, monitoring of, or safety arrangements for, pumps or pumping installations specially adapted for elastic fluids characterised by using valves controlling pressure or flow rate, e.g. discharge valves or unloading valves using bypass channels
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B41/00Fluid-circulation arrangements
    • F25B41/20Disposition of valves, e.g. of on-off valves or flow control valves
    • F25B41/26Disposition of valves, e.g. of on-off valves or flow control valves of fluid flow reversing valves
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F04POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
    • F04CROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; ROTARY-PISTON, OR OSCILLATING-PISTON, POSITIVE-DISPLACEMENT PUMPS
    • F04C18/00Rotary-piston pumps specially adapted for elastic fluids
    • F04C18/30Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members
    • F04C18/32Rotary-piston pumps specially adapted for elastic fluids having the characteristics covered by two or more of groups F04C18/02, F04C18/08, F04C18/22, F04C18/24, F04C18/48, or having the characteristics covered by one of these groups together with some other type of movement between co-operating members having both the movement defined in group F04C18/02 and relative reciprocation between the co-operating members
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B2309/00Gas cycle refrigeration machines
    • F25B2309/06Compression machines, plants or systems characterised by the refrigerant being carbon dioxide
    • F25B2309/061Compression machines, plants or systems characterised by the refrigerant being carbon dioxide with cycle highest pressure above the supercritical pressure
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B2400/00General features or devices for refrigeration machines, plants or systems, combined heating and refrigeration systems or heat-pump systems, i.e. not limited to a particular subgroup of F25B
    • F25B2400/07Details of compressors or related parts
    • F25B2400/074Details of compressors or related parts with multiple cylinders
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B2400/00General features or devices for refrigeration machines, plants or systems, combined heating and refrigeration systems or heat-pump systems, i.e. not limited to a particular subgroup of F25B
    • F25B2400/13Economisers
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25BREFRIGERATION MACHINES, PLANTS OR SYSTEMS; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS
    • F25B2600/00Control issues
    • F25B2600/02Compressor control
    • F25B2600/027Compressor control by controlling pressure
    • F25B2600/0272Compressor control by controlling pressure the suction pressure

Definitions

  • the present invention relates to a refrigerating apparatus for a two-stage compression refrigeration cycle, and particularly relates to a technique for adjusting a suction volume ratio in a compressor in which a plurality of compression mechanisms are mechanically connected together through a single drive shaft.
  • a refrigerating apparatus in which a two-stage compression refrigeration cycle is performed.
  • a compressor In such a refrigerating apparatus, e.g., a compressor is used, in which two compression mechanisms are mechanically connected to a single drive shaft (see, e.g., Patent Document 1).
  • the compressor of the refrigerating apparatus one of the compression mechanisms serves as a low-pressure compression mechanism, and the other compression mechanism serves as a high-pressure compression mechanism.
  • a rotational speed of each of the compressors is changed to change a quantitative ratio (volume ratio) of refrigerant to be taken into the compressor, thereby controlling the COP.
  • rotational speeds of the low-pressure and high-pressure compression mechanisms are equal to each other, and a suction volume ratio of the low-pressure compression mechanism to the high-pressure compression mechanism is constant.
  • the intermediate pressure cannot be controlled. The same applies not only to a case where refrigerant is carbon dioxide, but also to a case where other type of refrigerant is used.
  • the present invention has been made in view of the foregoing problem, and it is an objective of the present invention to, in a refrigerating apparatus in which a two-stage compression refrigeration cycle is performed, adjust a suction volume ratio in a compressor in which a plurality of compression mechanisms are mechanically connected together through a single drive shaft, and allow an operation with optimum COP.
  • a first aspect of the invention is intended for a refrigerating apparatus in which a two-stage compression refrigeration cycle is performed, which includes a refrigerant circuit ( 60 ), ( 180 ) connected to a compressor ( 1 ), ( 100 ) in which a plurality of compression mechanisms ( 20 , 30 ), ( 110 , 120 , 130 , 140 ) are mechanically connected together through a single drive shaft ( 53 ), ( 173 ).
  • the refrigerating apparatus further includes four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the compression mechanisms ( 20 , 30 ), ( 110 , 120 , 130 , 140 ); and volume ratio changing units ( 7 , 8 ), ( 107 , 108 ) configured to change a ratio of a suction volume of a low-pressure compression mechanism to a suction volume of a high-pressure compression mechanism.
  • C 1 , C 2 , C 3 , C 4 in the compression mechanisms ( 20 , 30 ), ( 110 , 120 , 130 , 140 ); and volume ratio changing units ( 7 , 8 ), ( 107 , 108 ) configured to change a ratio of a suction volume of a low-pressure compression mechanism to a suction volume of a high-pressure compression mechanism.
  • the volume ratio changing units ( 7 , 8 ), ( 107 , 108 ) change the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism while performing an operation.
  • a second aspect of the invention is intended for the refrigerating apparatus of the first aspect of the invention, in which the volume ratio changing unit ( 7 , 8 ), ( 107 , 108 ) is configured to change the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism (in some cases, hereinafter referred to as a “suction volume ratio” or merely referred to as a “volume ratio”) by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ).
  • the combination of the cylinder chambers to be used as the low-pressure compression mechanism and the cylinder chambers to be used as the high-pressure compression mechanism is changed while performing the operation. That is, when two cylinder chambers are used for each of the low-pressure and high-pressure compression mechanisms, a combination of the low-pressure cylinder chambers and the high-pressure cylinder chambers is changed, and therefore the volume ratio can be adjusted depending on operational conditions when cylinder volumes of the compression chambers are different from each other.
  • the volume ratio can be also adjusted depending on the operational conditions by using three cylinder chambers at the low-pressure stage and one cylinder chamber at the high-pressure stage, or by using one cylinder chamber at the low-pressure stage and three cylinder chambers at the high-pressure stage.
  • a third aspect of the invention is intended for the refrigerating apparatus of the first or second aspect of the invention, in which the plurality of compression mechanisms ( 20 , 30 ) are a first compression mechanism ( 20 ) and a second compression mechanism ( 30 ), each of which includes two cylinder chambers (C 1 , C 2 ), (C 3 , C 4 ), each of the compression mechanisms ( 20 , 30 ) includes a cylinder ( 21 , 31 ) with a circular cylinder space and a circular eccentric piston ( 22 , 32 ) eccentrically rotating in the cylinder space, an inner cylinder chamber (C 2 , C 4 ) is formed on an inner circumferential side of the circular eccentric piston ( 22 , 32 ) in the cylinder space, and an outer cylinder chamber (C 1 , C 3 ) is formed on an outer circumferential side of the circular eccentric piston ( 22 , 32 ).
  • each of the two compression mechanisms ( 20 , 30 ) provided in the compressor ( 1 ) includes the two cylinder chambers (C 1 , C 2 ), (C 3 , C 4 ) on the outer and inner circumferential sides of the circular pistons ( 22 , 32 ).
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is changed while performing the operation.
  • a fourth aspect of the invention is intended for the refrigerating apparatus of the third aspect of the invention, in which the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are set to at least two suction volume levels.
  • the two compression mechanisms ( 20 , 30 ) are configured so that the inner cylinder chambers (C 2 , C 4 ) have the same volume, and the outer cylinder chambers (C 1 , C 3 ) have the same volume.
  • the compression mechanisms ( 20 , 30 ) can be easily realized, which include the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) set to at least two suction volume levels.
  • a fifth aspect of the invention is intended for the refrigerating apparatus of the third aspect of the invention, in which suction volumes of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are different from each other.
  • the volumes of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are different from each other, and therefore the number of combination patterns of the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) for changing the volume ratio can be maximum.
  • the present invention is available under various operational conditions.
  • a sixth aspect of the invention is intended for the refrigerating apparatus of any one of the third to fifth aspects of the invention, in which, when the first compression mechanism ( 20 ) is at the low-pressure stage and the second compression mechanism ( 30 ) is at the high-pressure stage, the volume ratio changing unit ( 7 ) is a switching mechanism which is switchable between a state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected together in parallel, and a state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected together in series.
  • the first compression mechanism ( 20 ) when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected in parallel and the state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected in series.
  • the volume ratio can be adjusted between two operational states.
  • a seventh aspect of the invention is intended for the refrigerating apparatus of any one of the third to fifth aspects of the invention, in which the volume ratio changing unit ( 7 ) is a switching mechanism which is switchable between a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 4 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is used as the high-pressure compression mechanism.
  • the volume ratio changing unit ( 7 ) is a switching mechanism which is switchable between a state in which both of the cylinder chambers (C 1
  • the seventh aspect of the invention it is switched between the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 4 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • An eighth aspect of the invention is intended for the refrigerating apparatus of any one of the third to fifth aspects of the invention, in which the volume ratio changing unit ( 8 ) is a switching mechanism which is switchable between a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and a state in which one of the cylinder chambers (C 1 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 3 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) and the other cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism.
  • the volume ratio changing unit ( 8 ) is a switching mechanism which is switchable
  • the eighth aspect of the invention it is switched between the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and the state in which one of the cylinder chambers (C 1 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 3 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) and the other cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • a ninth aspect of the invention is intended for the refrigerating apparatus of any one of the third to fifth aspects of the invention, in which, when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, the volume ratio changing unit ( 7 ) is a switching mechanism which is switchable between a state in which refrigerant is compressed in both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) to provide a difference between a′ suction pressure and a discharge pressure, and a state in which refrigerant is compressed in one of the cylinder chambers (C 3 ), (C 4 ) of the second compression mechanism ( 30 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other cylinder chamber (C 4 ), (C 3 ) allow uncompressed refrigerant to pass through the other cylinder chamber (C 4 ), (C 3 ) (a state in
  • the first compression mechanism ( 20 ) when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ), and the state in which refrigerant is compressed only in one of the cylinder chambers (C 3 ), (C 4 ) of the second compression mechanism ( 30 ), and uncompressed refrigerant passes through the other cylinder chamber (C 4 ), (C 3 ).
  • the volume ratio can be adjusted between the two operational states.
  • a tenth aspect of the invention is intended for the refrigerating apparatus of any one of the third to fifth aspects of the invention, in which, when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, the volume ratio changing unit ( 7 ) is a switching mechanism which is switchable between a state in which refrigerant is compressed in both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) to provide a difference between a suction pressure and a discharge pressure, and a state in which refrigerant is compressed in one of the cylinder chambers (C 1 ), (C 2 ) of the first compression mechanism ( 20 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other cylinder chamber (C 2 ), (C 1 ) allow uncompressed refrigerant to pass through the other cylinder chamber (C 2 ), (C 1 ).
  • the first compression mechanism ( 20 ) when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ), and the state in which refrigerant is compressed only in one of the cylinder chambers (C 1 ) of the first compression mechanism ( 20 ), and uncompressed refrigerant passes through the other cylinder chamber.
  • the volume ratio can be adjusted between the two operational states.
  • An eleventh aspect of the invention is intended for the refrigerating apparatus of any one of the first to tenth aspects of the invention, in which the switching mechanism ( 7 , 8 ) is a switching valve configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 20 , 30 ).
  • the flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant is switched by the switching valve ( 7 , 8 ), thereby adjusting the volume ratio of the compressor ( 1 ) depending on the different operational states.
  • a twelfth aspect of the invention is intended for the refrigerating apparatus of any one of the first to eleventh aspects of the invention, in which the volume ratio changing unit ( 7 , 8 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is adjusted depending on the change in operational conditions.
  • a thirteenth aspect of the invention is intended for the refrigerating apparatus of the first or second aspect of the invention, in which the plurality of compression mechanisms ( 110 , 120 , 130 , 140 ) are a first compression mechanism ( 110 ), a second compression mechanism ( 120 ), a third compression mechanism ( 130 ), and a fourth compression mechanism ( 140 ), each of which includes a single cylinder chamber, and each of the compression mechanisms ( 110 , 120 , 130 , 140 ) includes a cylinder ( 111 , 121 , 131 , 141 ) with a circular cylinder space and an eccentric piston ( 112 , 122 , 132 , 142 ) eccentrically rotating in the cylinder space.
  • each of the four compression mechanisms ( 110 , 120 , 130 , 140 ) provided in the compressor ( 1 ) includes the cylinder ( 111 , 121 , 131 , 141 ) with the circular cylinder space, and the eccentric piston ( 112 , 122 , 132 , 142 ) eccentrically rotating in the cylinder space.
  • the compressor including the compression mechanisms ( 110 , 120 , 130 , 140 ) in which the eccentric pistons ( 112 , 122 , 132 , 142 ) eccentrically rotate in the cylinder spaces the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is changed while performing the operation.
  • a fourteenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and a state in which the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the fourth compression mechanism ( 140 ) is used as the high-pressure compression mechanism.
  • the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and a state in
  • the fourteenth aspect of the invention it is switched between the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and the state in which the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the fourth compression mechanism ( 140 ) is used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • a fifteenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and a state in which the first compression mechanism ( 110 ) is used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and a state in
  • the fifteenth aspect of the invention it is switched between the state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and the state in which the first compression mechanism ( 110 ) is used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • a sixteenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which a cylinder volume of at least one of the compression mechanisms is different from cylinder volumes of the other compression mechanisms, and the volume ratio changing unit ( 108 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and a state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • a seventeenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which refrigerant is compressed in both of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide a difference between a suction pressure and a discharge pressure, and a state in which refrigerant is compressed in one of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other compression mechanism allow uncompressed refrigerant to pass through the other compression mechanism.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide the difference between the suction pressure and the discharge pressure, and the state in which refrigerant is compressed in one of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other compression mechanism allow uncompressed refrigerant to pass through the other compression mechanism.
  • the volume ratio can be adjusted between the two operational states.
  • An eighteenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in both of the low-pressure and high-pressure compression mechanisms to provide a difference between a suction pressure and a discharge pressure, and a state in which, when the first compression mechanism ( 110 ) is at the low-pressure stage, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in the low-pressure compression mechanism to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in one of the second compression mechanism ( 120
  • the eighteenth aspect of the invention it is switched between the state in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in both of the low-pressure and high-pressure compression mechanisms to provide the difference between the suction pressure and the discharge pressure, and the state in which, when the first compression mechanism ( 110 ) is at the low-pressure stage, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in the low-pressure compression mechanism to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in one of the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), or the fourth compression mechanism ( 140 ) at the high-pressure stage allow uncompressed refrigerant to pass through the one of the second compression
  • a nineteenth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in parallel, and a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in series.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, it is switched between the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in parallel, and the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in series.
  • the volume ratio can be adjusted between the two operational states.
  • a twentieth aspect of the invention is intended for the refrigerating apparatus of the thirteenth aspect of the invention, in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, the volume ratio changing unit ( 107 ) is a switching mechanism which is switchable between a state in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in parallel, and a state in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in series.
  • the volume ratio can be adjusted between the two operational states.
  • a twenty-first aspect of the invention is intended for the refrigerating apparatus of any one of the thirteenth to twentieth aspects of the invention, in which the switching mechanism ( 107 , 108 ) is a switching valve configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 , 120 , 130 , 140 ).
  • the flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant is switched by the switching valve ( 107 , 108 ), thereby adjusting the volume ratio of the compressor ( 1 ) depending on the different operational states.
  • a twenty-second aspect of the invention is intended for the refrigerating apparatus of any one of the thirteenth to twenty-first aspects of the invention, in which the volume ratio changing unit ( 107 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is adjusted depending on the change in operational conditions.
  • a twenty-third aspect of the invention is intended for the refrigerating apparatus of any one of the first to twenty-second aspects of the invention, in which refrigerant is carbon dioxide.
  • the volume ratio can be adjusted in the compressor in which refrigerant is carbon dioxide.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism can be adjusted.
  • a change in volume ratio changes a compression torque, thereby adjusting a compression torque variation.
  • the combination of the cylinder chambers to be used as the low-pressure compression mechanism and the cylinder chambers to be used as the high-pressure compression mechanism is changed while performing the operation.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism can be adjusted, thereby realizing the operation with optimum COP.
  • each of the two compression mechanisms ( 20 , 30 ) provided in the compressor ( 1 ) includes the two cylinder chambers (C 1 , C 2 ), (C 3 , C 4 ) on the outer and inner circumferential sides of the circular pistons ( 22 , 32 ), the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism can be adjusted, thereby realizing the operation with optimum COP.
  • suction volume ratio is adjusted by unloading the low-pressure or high-pressure compression mechanism in the two-stage compression mechanism.
  • refrigerant is not compressed in the middle of a compression stroke in the present embodiment, thereby realizing a smooth operation.
  • the two compression mechanisms ( 20 , 30 ) are configured so that the inner cylinder chambers (C 2 , C 4 ) have the same volume, and the outer cylinder chambers (C 1 , C 3 ) have the same volume.
  • the compression mechanisms ( 20 , 30 ) can be easily realized, which include the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) set to at least two suction volume levels.
  • the lengths of the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in a shaft direction are adjusted, and therefore the suction volumes of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) can be easily differentiated.
  • the volumes of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are different from each other, and therefore the number of the combination patterns of the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) for changing the volume ratio can be increased to maximum.
  • the operation with optimum COP can be realized depending on various operational conditions.
  • the sixth aspect of the invention when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected in parallel and the state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected in series.
  • the volume ratio can be adjusted between two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the seventh aspect of the invention it is switched between the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 4 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the eighth aspect of the invention it is switched between the state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism, and the state in which one of the cylinder chambers (C 1 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 3 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) and the other cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the ninth aspect of the invention when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ), and the state in which refrigerant is compressed only in one of the cylinder chambers (C 3 ), (C 4 ) of the second compression mechanism ( 30 ), and uncompressed refrigerant passes through the other cylinder chamber (C 4 ), (C 3 ).
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the first compression mechanism ( 20 ) when the first compression mechanism ( 20 ) is at the low-pressure stage, and the second compression mechanism ( 30 ) is at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ), and the state in which refrigerant is compressed only in one of the cylinder chambers (C 1 ), (C 2 ) of the first compression mechanism ( 20 ), and uncompressed refrigerant passes through the other cylinder chamber (C 2 ), (C 1 ).
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant is switched by the switching valve, thereby adjusting the volume ratio of the compressor ( 1 ) depending on the different operational states.
  • the adjustment of the volume ratio of the compressor ( 1 ) can be realized with a simple configuration.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is adjusted depending on the change in operational conditions.
  • the operation with optimum COP can be realized depending on, e.g., a change in external air temperature.
  • each of the four compression mechanisms ( 110 , 120 , 130 , 140 ) provided in the compressor ( 1 ) includes the cylinder ( 111 , 121 , 131 , 141 ) with the circular cylinder space, and the eccentric piston ( 112 , 122 , 132 , 142 ) eccentrically rotating in the cylinder space
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is adjusted, thereby realizing the operation with optimum COP.
  • a case is considered, where the suction volume ratio is adjusted by unloading the low-pressure or high-pressure compression mechanism in the two-stage compression mechanism.
  • refrigerant is not compressed in the middle of the compression stroke in the present embodiment, thereby realizing the smooth operation.
  • the fourteenth aspect of the invention it is switched between the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and the state in which the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the fourth compression mechanism ( 140 ) is used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the fifteenth aspect of the invention it is switched between the state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and the state in which the first compression mechanism ( 110 ) is used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the sixteenth aspect of the invention in the configuration in which the cylinder volume of at least one of the compression mechanisms is different from the cylinder volumes of the other compression mechanisms, it is switched between the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism, and the state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, it is switched between the state in which refrigerant is compressed in both of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide the difference between the suction pressure and the discharge pressure, and the state in which refrigerant is compressed in one of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other compression mechanism allow uncompressed refrigerant to pass through the other compression mechanism.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the eighteenth aspect of the invention it is switched between the state in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in both of the low-pressure and high-pressure compression mechanisms to provide the difference between the suction pressure and the discharge pressure, and the state in which, when the first compression mechanism ( 110 ) is at the low-pressure stage, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are at the high-pressure stage, refrigerant is compressed in the low-pressure compression mechanism to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in one of the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), or the fourth compression mechanism ( 140 ) at the high-pressure stage allow uncompressed refrigerant to pass through the one of the one of
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, it is switched between the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in parallel, and the state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in series.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are at the low-pressure stage, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are at the high-pressure stage, it is switched between the state in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in parallel, and the state in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in series.
  • the volume ratio can be adjusted between the two operational states. Consequently, the operation with optimum COP can be realized depending on the different operational states.
  • the flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant is switched by the switching valve, thereby adjusting the volume ratio of the compressor ( 1 ) depending on the different operational states.
  • the adjustment of the volume ratio of the compressor ( 1 ) can be realized with a simple configuration.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism is adjusted depending on the change in operational conditions.
  • the operation with optimum COP can be realized depending on, e.g., a change in external air temperature.
  • refrigerant is carbon dioxide. This provides a noticeable effect in the two-stage compression as compared to other refrigerant, thereby increasing a COP improvement effect.
  • FIG. 1 is a longitudinal sectional view of a compressor used for an air conditioning apparatus of a first embodiment.
  • FIG. 2 is a cross-sectional view of a compression mechanism of the first embodiment.
  • FIGS. 3(A)-3(H) are views illustrating operational states in the compression mechanism of the first embodiment.
  • FIG. 4 is a refrigerant circuit diagram illustrating a first operational state of the air conditioning apparatus of the first embodiment.
  • FIG. 5 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the first embodiment.
  • FIG. 6 is a cross-sectional view illustrating a first operational state switching pattern of a variation of the first embodiment.
  • FIG. 7 is a cross-sectional view illustrating a second operational state switching pattern of the variation of the first embodiment.
  • FIG. 8 is a cross-sectional view illustrating a third operational state switching pattern of the variation of the first embodiment.
  • FIG. 9 is a cross-sectional view illustrating a fourth operational state switching pattern of the variation of the first embodiment.
  • FIG. 10 is a cross-sectional view illustrating a fifth operational state switching pattern of the variation of the first embodiment.
  • FIG. 11 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a second embodiment.
  • FIG. 12 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the second embodiment.
  • FIG. 13 is a cross-sectional view illustrating a first operational state switching pattern of a variation of the second embodiment.
  • FIG. 14 is a cross-sectional view illustrating a second operational state switching pattern of the variation of the second embodiment.
  • FIG. 15 is a cross-sectional view illustrating a third operational state switching pattern of the variation of the second embodiment.
  • FIG. 16 is a cross-sectional view illustrating a fourth operational state switching pattern of the variation of the second embodiment.
  • FIG. 17 is a cross-sectional view illustrating a fifth operational state switching pattern of the variation of the second embodiment.
  • FIG. 18 is a cross-sectional view illustrating a sixth operational state switching pattern of the variation of the second embodiment.
  • FIG. 19 is a cross-sectional view illustrating a seventh operational state switching pattern of the variation of the second embodiment.
  • FIG. 20 is a cross-sectional view illustrating an eighth operational state switching pattern of the variation of the second embodiment.
  • FIG. 21 is a cross-sectional view illustrating a ninth operational state switching pattern of the variation of the second embodiment.
  • FIG. 22 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a third embodiment.
  • FIG. 23 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the third embodiment.
  • FIG. 24 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a fourth embodiment.
  • FIG. 25 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the fourth embodiment.
  • FIG. 26 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a fifth embodiment.
  • FIG. 27 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the fifth embodiment.
  • FIG. 28 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a sixth embodiment.
  • FIG. 29 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the sixth embodiment.
  • FIG. 30 is a longitudinal sectional view of a compressor used for a refrigerating apparatus (air conditioning apparatus) of a seventh embodiment.
  • FIG. 31 is a cross-sectional view of a compression mechanism of the seventh embodiment.
  • FIGS. 32(A)-32(D) are views illustrating operational states in the compression mechanism of the seventh embodiment.
  • FIG. 33 is a refrigerant circuit diagram illustrating a first operational state of the air conditioning apparatus of the seventh embodiment.
  • FIG. 34 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the seventh embodiment.
  • FIG. 35 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of an eighth embodiment.
  • FIG. 36 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the eighth embodiment.
  • FIG. 37 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a ninth embodiment.
  • FIG. 38 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the ninth embodiment.
  • FIG. 39 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a tenth embodiment.
  • FIG. 40 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the tenth embodiment.
  • FIG. 41 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of an eleventh embodiment.
  • FIG. 42 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the eleventh embodiment.
  • FIG. 43 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a twelfth embodiment.
  • FIG. 44 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the twelfth embodiment.
  • FIG. 45 is a refrigerant circuit diagram illustrating a first operational state of an air conditioning apparatus of a thirteenth embodiment.
  • FIG. 46 is a refrigerant circuit diagram illustrating a second operational state of the air conditioning apparatus of the thirteenth embodiment.
  • FIG. 47 is a cross-sectional view illustrating a variation in which an internal pressure of a casing is at a high pressure level.
  • FIG. 48 is a cross-sectional view illustrating a variation in which the internal pressure of the casing is at an intermediate pressure level.
  • FIG. 49 is a cross-sectional view illustrating a first variation of a combination of suction and discharge ports.
  • FIG. 50 is a cross-sectional view illustrating a second variation of the combination of the suction and discharge ports.
  • FIG. 51 is a cross-sectional view illustrating a third variation of the combination of the suction and discharge ports.
  • FIG. 52 is a cross-sectional view illustrating a fourth variation of the combination of the suction and discharge ports.
  • FIG. 53 is a cross-sectional view illustrating a fifth variation of the combination of the suction and discharge ports.
  • FIG. 54 is a cross-sectional view illustrating a sixth variation of the combination of the suction and discharge ports.
  • FIG. 55 is a cross-sectional view illustrating a seventh variation of the combination of the suction and discharge ports.
  • FIG. 56 is a cross-sectional view illustrating an eighth variation of the combination of the suction and discharge ports.
  • FIG. 57 is a cross-sectional view illustrating a ninth variation of the combination of the suction and discharge ports.
  • FIG. 58 is a cross-sectional view illustrating a tenth variation of the combination of the suction and discharge ports.
  • FIG. 59 is a cross-sectional view illustrating an eleventh variation of the combination of the suction and discharge ports.
  • FIG. 60 is a cross-sectional view illustrating a twelfth variation of the combination of the suction and discharge ports.
  • FIG. 61 is a cross-sectional view illustrating a thirteenth variation of the combination of the suction and discharge ports.
  • FIG. 62 is a cross-sectional view illustrating a fourteenth variation of the combination of the suction and discharge ports.
  • FIG. 1 is a longitudinal sectional view of a compressor ( 1 ) used for a refrigerating apparatus (air conditioning apparatus) of the first embodiment
  • FIG. 2 is a cross-sectional view of a compression mechanism (first compression mechanism)
  • FIGS. 3(A)-3(H) are views illustrating operational states in the compression mechanism (first compression mechanism).
  • FIG. 4 is a refrigerant circuit diagram illustrating a first operational state of the air conditioning apparatus
  • FIG. 5 is a refrigerant circuit diagram illustrating a second operational state.
  • the compressor ( 1 ) is used for compressing refrigerant sucked from an evaporator, and discharging such refrigerant to a condenser.
  • the compressor ( 1 ) is a rotary compressor, and includes a first compression mechanism ( 20 ) and a second compression mechanism ( 30 ) which are mechanically connected together through a single drive shaft ( 53 ).
  • the compressor ( 1 ) is configured so that carbon dioxide which is refrigerant (working fluid) is compressed at two stages. That is, the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) form a two-stage compression mechanism. Since the cross-sectional view and the operational state view of the second compression mechanism ( 30 ) are the substantially same as those of the first compression mechanism ( 20 ), reference numerals of the second compression mechanism ( 30 ) are shown in FIG. 2 without details.
  • the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) are arranged so that their phases are shifted by 180°.
  • the compressor ( 1 ) includes a casing ( 10 ) in which the first compression mechanism ( 20 ), the second compression mechanism ( 30 ), and an electrical motor (drive mechanism) ( 50 ) are accommodated; and is hermetic.
  • the first compression mechanism ( 20 ) serves as a low-pressure compression mechanism
  • the second compression mechanism ( 30 ) serves as a high-pressure compression mechanism.
  • the casing ( 10 ) includes a cylindrical body section ( 11 ), an upper end plate ( 12 ) fixed to an upper end portion of the body section ( 11 ), and a lower end plate ( 13 ) fixed to a lower end portion of the body section ( 11 ).
  • a first suction port pipe ( 14 - 1 ) and a first discharge port pipe ( 15 - 1 ) are provided as a suction port pipe for a first outer cylinder chamber (described later) and a discharge port pipe for a first inner cylinder chamber (described later) in the first compression mechanism ( 20 ).
  • a second suction port pipe ( 14 - 2 ) is provided as a suction port pipe of the second compression mechanism ( 30 ).
  • the second suction port pipe ( 14 - 2 ) includes two suction port pipes, i.e., a second suction port a-pipe ( 14 - 2 a ) for a later-described second outer cylinder chamber, and a second suction port b-pipe ( 14 - 2 b ) for a later-described second inner cylinder chamber.
  • Each of two second discharge port pipes ( 15 - 2 ) is provided in the body section ( 11 ) and the upper end plate ( 12 ).
  • a second discharge port a-pipe ( 15 - 2 a ) for the outer cylinder chamber is provided in a lower portion of the body section ( 11 ) relative to the middle of the body section ( 11 ), and a second discharge port b-pipe ( 15 - 2 b ) for the inner cylinder chamber is provided in an upper portion of the body section ( 11 ).
  • the first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • the first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the second suction port pipe ( 14 - 2 ) includes the second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and the second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • the second discharge port pipe ( 15 - 2 ) includes the second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and the second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ) by way of a space inside the casing ( 10 ).
  • the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) are stacked in two tiers, and are interposed between a front head ( 16 ) and a rear head ( 17 ) which are fixed to the casing ( 10 ).
  • the second compression mechanism ( 30 ) is arranged on an electrical motor side (upper side as viewed in FIG. 1 )
  • the first compression mechanism ( 20 ) is arranged on a bottom side of the casing ( 10 ) (lower side as viewed in FIG. 1 ).
  • a middle plate ( 19 ) is provided between the front head ( 16 ) and the rear head ( 17 ).
  • the first compression mechanism ( 20 ) includes a first cylinder ( 21 ) having a first circular cylinder chamber (C 1 , C 2 ); a first circular piston ( 22 ) arranged inside the first cylinder chamber (C 1 , C 2 ); and a first blade ( 23 ) dividing the first cylinder chamber (C 1 , C 2 ) into a high-pressure chamber (compression chamber) (C 1 -Hp, C 2 -Hp) which is a first chamber, and a low-pressure chamber (suction chamber) (C 1 -Lp, C 2 -Lp) which is a second chamber as illustrated in FIGS. 2 and 3 .
  • the second compression mechanism ( 30 ) has a reversed shape of the first compression mechanism ( 20 ).
  • the second compression mechanism ( 30 ) includes a second cylinder ( 31 ) having a second circular cylinder chamber (C 3 , C 4 ); a second circular piston ( 32 ) arranged inside the second cylinder chamber (C 3 , C 4 ); and a second blade ( 33 ) dividing the second cylinder chamber (C 3 , C 4 ) into a high-pressure chamber (not shown in the figure) which is a first chamber, and a low-pressure chamber (not shown in the figure) which is a second chamber.
  • the front head ( 16 ) serves as the second cylinder ( 31 ), and the rear head ( 17 ) serves as the first cylinder ( 21 ).
  • the first cylinder ( 21 ) having the first cylinder chamber (C 1 , C 2 ) and the second cylinder ( 31 ) having the second cylinder chamber (C 3 , C 4 ) are fixed, and the first circular piston ( 22 ) and the second circular piston ( 32 ) are movable.
  • the first circular piston ( 22 ) eccentrically rotates in the first cylinder ( 21 ), and the second circular piston ( 32 ) eccentrically rotates in the second cylinder ( 31 ).
  • the electrical motor ( 50 ) includes a stator ( 51 ) and a rotor ( 52 ).
  • the stator ( 51 ) is arranged above the second compression mechanism ( 30 ), and is fixed to the body section ( 11 ) of the casing ( 10 ).
  • the drive shaft (crankshaft) ( 53 ) is connected to the rotor ( 52 ), and rotates together with the rotor ( 52 ).
  • the drive shaft ( 53 ) vertically penetrates the first cylinder chamber (C 1 , C 2 ) and the second cylinder chamber (C 3 , C 4 ).
  • an oil supply structure using an oil supply path extending in a shaft direction inside the drive shaft ( 53 ) is employed in the compressor ( 1 ), but the oil supply structure is omitted in the present embodiment.
  • a first eccentric section ( 53 a ) is formed in a portion positioned in the first cylinder chamber (C 1 , C 2 ), and a second eccentric section ( 53 b ) is formed in a portion positioned in the second cylinder chamber (C 3 , C 4 ).
  • the first eccentric section ( 53 a ) is formed so as to have a diameter larger than that of a main shaft portion above and below the first eccentric section ( 53 a ), and is eccentric from the center of the drive shaft ( 53 ) by a predetermined distance.
  • the second eccentric section ( 53 b ) is formed so as to have the same diameter as that of the first eccentric section ( 53 a ), and is eccentric from the center of the drive shaft ( 53 ) by the same distance as that of the first eccentric section ( 53 a ).
  • the first eccentric section ( 53 a ) and the second eccentric section ( 53 b ) have phases shifted from each other by 180° about the center of the drive shaft ( 53 ).
  • the first circular piston ( 22 ) is an integrally-formed member.
  • the first circular piston ( 22 ) includes a first bearing section ( 22 a ) slidably fitted on the first eccentric section ( 53 a ) of the drive shaft ( 53 ), a first circular piston body section ( 22 b ) positioned concentric to the first bearing section ( 22 a ) on an outer circumferential side of the first bearing section ( 22 a ), and a first piston-side end plate ( 22 c ) connecting between the first bearing section ( 22 a ) and the first circular piston body section ( 22 b ).
  • the first circular piston body section ( 22 b ) is formed in C-shape, i.e., a part of the annular ring splits (see FIG. 2 ).
  • the second circular piston ( 32 ) is an integrally-formed member.
  • the second circular piston ( 32 ) includes a second bearing section ( 32 a ) slidably fitted on the second eccentric section ( 53 b ) of the drive shaft ( 53 ), a second circular piston body section ( 32 b ) positioned concentric to the second bearing section ( 32 a ) on an outer circumferential side of the second bearing section ( 32 a ), and a second piston-side end plate ( 32 c ) connecting between the second bearing section ( 32 a ) and the second circular piston body section ( 32 b ).
  • the second circular piston body section ( 32 b ) is formed in C-shape, i.e., a part of the annular ring splits (see FIG. 2 ).
  • the first cylinder ( 21 ) includes a first inner cylinder section ( 21 b ) positioned concentric to the drive shaft ( 53 ) between the first bearing section ( 22 a ) and the first circular piston body section ( 22 b ), a first outer cylinder section ( 21 a ) positioned concentric to the first inner cylinder section ( 21 b ) on an outer circumferential side of the first circular piston body section ( 22 b ), and a first cylinder-side end plate ( 21 c ) connecting between the first inner cylinder section ( 21 b ) and the first outer cylinder section ( 21 a ).
  • the second cylinder ( 31 ) includes a second inner cylinder section ( 31 b ) positioned concentric to the drive shaft ( 53 ) between the second bearing section ( 32 a ) and the second circular piston body section ( 32 b ), a second outer cylinder section ( 31 a ) positioned concentric to the second inner cylinder section ( 31 b ) on an outer circumferential side of the second circular piston body section ( 32 b ), and a second cylinder-side end plate ( 31 c ) connecting between the second inner cylinder section ( 31 b ) and the second outer cylinder section ( 31 a ).
  • Bearing sections ( 16 a , 17 a ) supporting the drive shaft ( 53 ) are formed in the front head ( 16 ) and the rear head ( 17 ), respectively.
  • the compressor ( 1 ) of the present embodiment has a through-shaft structure in which the drive shaft ( 53 ) vertically penetrates the first cylinder chamber (C 1 , C 2 ) and the second cylinder chamber (C 3 , C 4 ), and both side portions of the first eccentric section ( 53 a ) and the second eccentric section ( 53 b ) in the shaft direction are held by the casing ( 10 ) through the bearing sections ( 16 a , 17 a ).
  • the first and second compression mechanisms ( 20 , 30 ) have the substantially same configuration, except that, in order to change a cylinder volume, the length of the circular piston ( 22 , 32 ) in the shaft direction and the length of the corresponding cylinder ( 21 , 31 ) in the shaft direction are different between the first and second compression mechanisms ( 20 , 30 ).
  • the first compression mechanism ( 20 ) will be described as a representative example.
  • the first compression mechanism ( 20 ) includes a first swing bush ( 27 ) as a connecting member swingably connecting the first circular piston ( 22 ) to first blade ( 23 ) at the split portion of the first circular piston ( 22 ).
  • the first blade ( 23 ) extends from an inner circumferential wall surface of the first cylinder chamber (C 1 , C 2 ) (outer circumferential surface of the first inner cylinder section ( 21 b )) to an outer circumferential wall surface of the first cylinder chamber (C 1 , C 2 ) (inner circumferential surface of the first outer cylinder section ( 21 a )) through the split portion of the first circular piston ( 22 ) in a radial direction of the first cylinder chamber (C 1 , C 2 ).
  • the first blade ( 23 ) is fixed to the first outer cylinder section ( 21 a ) and the first inner cylinder section ( 21 b ).
  • the first blade ( 23 ) may be integrally formed with the first outer cylinder section ( 21 a ) and the first inner cylinder section ( 21 b ), or another member may be attached to both of the cylinder sections ( 21 a , 21 b ).
  • the example illustrated in FIG. 2 is an example where another member is fixed to both of the cylinder sections ( 21 a , 21 b ).
  • the inner circumferential surface of the first outer cylinder section ( 21 a ) and the outer circumferential surface of the first inner cylinder section ( 21 b ) are cylindrical surfaces arranged concentric to each other, and the first cylinder chamber (C 1 , C 2 ) is formed between the inner circumferential surface of the first outer cylinder section ( 21 a ) and the outer circumferential surface of the first inner cylinder section ( 21 b ).
  • the first circular piston ( 22 ) is formed so that an outer circumferential surface of the first circular piston ( 22 ) has a diameter smaller than that of the inner circumferential surface of the first outer cylinder section ( 21 a ), and an inner circumferential surface of the first circular piston ( 22 ) has a diameter larger than that of the outer circumferential surface of the first inner cylinder section ( 21 b ).
  • the first outer cylinder chamber (C 1 ) is formed between the outer circumferential surface of the first circular piston ( 22 ) and the inner circumferential surface of the first outer cylinder section ( 21 a ), and the first inner cylinder chamber (C 2 ) is formed between the inner circumferential surface of the first circular piston ( 22 ) and the outer circumferential surface of the first inner cylinder section ( 21 b ).
  • the compressor ( 1 ) includes the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ), each of which has the two compression chambers (C 1 , C 2 ), (C 3 , C 4 ).
  • Each of the compression mechanisms ( 20 , 30 ) includes the cylinder ( 21 , 31 ) with the circular cylinder space, and the circular piston ( 22 , 32 ) eccentrically rotating in the cylinder space.
  • the inner cylinder chamber (C 2 , C 4 ) is formed on an inner circumferential side of the circular piston ( 22 , 32 )
  • the outer cylinder chamber (C 1 , C 3 ) is formed on an outer circumferential side of the circular piston ( 22 , 32 ).
  • the first outer cylinder chamber (C 1 ) is defined by the first cylinder-side end plate ( 21 c ), the first piston-side end plate ( 22 c ), the first outer cylinder section ( 21 a ), and the first circular piston body section ( 22 b ).
  • the first inner cylinder chamber (C 2 ) is defined by the first cylinder-side end plate ( 21 c ), the first piston-side end plate ( 22 c ), the first inner cylinder section ( 21 b ), and the first circular piston body section ( 22 b ).
  • a space ( 25 ) where the eccentric rotation of the first bearing section ( 22 a ) is allowed on an inner circumferential side of the first inner cylinder section ( 21 b ) is defined by the first cylinder-side end plate ( 21 c ), the first piston-side end plate ( 22 c ), the first bearing section ( 22 a ) of the first circular piston ( 22 ), and the first inner cylinder section ( 21 b ) (see FIG. 2 ).
  • the first circular piston ( 22 ) and the first cylinder ( 21 ) are configured so that the inner circumferential surface of the first circular piston ( 22 ) and the outer circumferential surface of the first inner cylinder section ( 21 b ) substantially contact each other at one point which is shifted from the foregoing contact point by 180°.
  • the first swing bush ( 27 ) includes an outlet-side bush ( 27 A) positioned on the high-pressure chamber (intermediate-pressure chamber) (C 1 -Hp, C 2 -Hp) side relative to the first blade ( 23 ), and an inlet-side bush ( 27 B) positioned on the low-pressure chamber (C 1 -Lp, C 2 -Lp) side relative to the first blade ( 23 ).
  • the outlet-side bush ( 27 A) and the inlet-side bush ( 27 B) are formed in the same shape having a substantially semicircular cross section, and flat surfaces of the outlet-side bush ( 27 A) and the inlet-side bush ( 27 B) are arranged so as to face each other.
  • a space between the opposing surfaces of both of the bushes ( 27 A, 27 B) forms a blade groove ( 28 ).
  • the first blade ( 23 ) is inserted into the blade groove ( 28 ).
  • the flat surfaces of the first swing bushes ( 27 A, 27 B) are in substantial surface contact with the first blade ( 23 ), and arc-shaped outer circumferential surfaces of the first swing bushes ( 27 A, 27 B) are in substantial surface contact with the first circular piston ( 22 ).
  • the first swing bushes ( 27 A, 27 B) move back and forth along surfaces of the first blade ( 23 ) with the first blade ( 23 ) being inserted into the blade groove ( 28 ).
  • the first swing bushes ( 27 A, 27 B) are configured so that the first circular piston ( 22 ) swings relative to the first blade ( 23 ).
  • the first swing bush ( 27 ) is configured so that the first circular piston ( 22 ) can swing relative to the first blade ( 23 ) about a swing center, i.e., a center point of the first swing bush ( 27 ), and the first circular piston ( 22 ) can move back and forth along the surfaces of the first blade ( 23 ).
  • the example has been described, where the bushes ( 27 A, 27 B) are separated members.
  • the bushes ( 27 A, 27 B) may have an integrated structure by partially connecting to each other.
  • the first circular piston ( 22 ) moves back and forth along the first blade ( 23 ) and swings about the swing center, i.e., the center point of the first swing bush ( 27 ) together with the first swing bush ( 27 ).
  • the second circular piston ( 32 ) also swings about a swing center, i.e., a center point of a second swing bush ( 37 ) as in the first circular piston ( 22 ).
  • Such a swing continuously moves a first contact point between the first circular piston ( 22 ) and the first cylinder ( 21 ) as illustrated from FIG. 3(A) to FIG. 3(H) .
  • a second contact point between the second circular piston ( 32 ) and the second cylinder ( 31 ) is shifted from the first contact point by 180° about the center of the drive shaft ( 53 ). That is, as viewed from above the drive shaft ( 53 ), when the operational state in the first compression mechanism ( 20 ) is as illustrated in FIG. 3(A) , the operational state in the second compression mechanism ( 30 ) is as illustrated in FIG. 3(E) .
  • FIGS. 3(A)-3(H) are the views illustrating the operational states in the first compression mechanism ( 20 ), and illustrate a state in which the first circular piston ( 22 ) moves at 45° interval in a clockwise direction as viewed in FIGS. 3(A)-3(H) . In such a state, the first circular piston ( 22 ) revolves about the drive shaft ( 53 ), but does not rotate.
  • the first compression mechanism ( 20 ) includes the first suction port pipe ( 14 - 1 ) through which low-pressure refrigerant is sucked, and the first discharge port pipe ( 15 - 1 ) through which intermediate-pressure refrigerant is discharged.
  • a first inlet ( 41 a ) to be connected to the first suction port pipe ( 14 - 1 ) is formed in the rear head ( 17 ).
  • the first inlet ( 41 a ) of the rear head ( 17 ) is communicated with the low-pressure chambers of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ) through a first injection path ( 42 a ).
  • the first suction port pipe ( 14 - 1 ) is fixed to the rear head ( 17 ), and is communicated with the cylinder chamber (C 1 , C 2 ) of the first compression mechanism ( 20 ).
  • An intermediate discharge space ( 17 b ) communicating with the cylinder chamber (C 1 , C 2 ) of the first compression mechanism ( 20 ) is formed in the rear head ( 17 ).
  • Intermediate-pressure refrigerant compressed in the first compression mechanism ( 20 ) is discharged to the intermediate discharge space ( 17 b ) through an outer outlet ( 45 a ) and an inner outlet ( 46 a ) which are illustrated in FIG. 2 and a discharge valve (not shown in the figure, but a discharge valve holder ( 47 ) is illustrated in the figure) configured to open/close the outer outlet ( 45 a ) and the inner outlet ( 46 a ).
  • the first discharge port pipe ( 15 - 1 ) penetrating the body section ( 11 ) of the casing ( 10 ) is fixed to the rear head ( 17 ).
  • An inner end portion of the first discharge port pipe ( 15 - 1 ) opens to the intermediate discharge space ( 17 b ) of the rear head ( 17 ), and an outer end portion of the first discharge port pipe ( 15 - 1 ) is connected to an intermediate-pressure refrigerant pipe (not shown in FIG. 1 ) of the refrigerant circuit.
  • the second compression mechanism ( 30 ) includes the second suction port pipe ( 14 - 2 ) through which intermediate-pressure refrigerant is sucked.
  • the second suction port pipe ( 14 - 2 ) includes the second suction port a-pipe ( 14 - 2 a ) for the outer cylinder chamber (C 3 ), and the second suction port b-pipe ( 14 - 2 b ) for the inner cylinder chamber (C 4 ).
  • a second inlet ( 41 b - 1 ) to be connected to the second suction port a-pipe ( 14 - 2 a ) is formed so as to be communicated with the low-pressure chamber of the second outer cylinder chamber (C 3 ), and a second inlet ( 41 b - 2 ) to be connected to the second suction port b-pipe ( 14 - 2 b ) is formed so as to be communicated with the low-pressure chamber of the second inner cylinder chamber (C 4 ).
  • the second suction port pipe ( 14 - 2 ) is fixed to the front head ( 16 ), and is communicated with the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ).
  • High-pressure refrigerant compressed in the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) is discharged to discharge spaces ( 49 a , 49 b ) through outlets ( 45 b , 46 b ) of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) and a discharge valve (not shown in the figure, but a discharge valve holder ( 48 ) is illustrated in the figure).
  • the second discharge port a-pipe ( 15 - 2 a ) for the outer cylinder chamber (C 3 ) is connected to the outer discharge space ( 49 a ).
  • the inner discharge space ( 49 b ) is communicated with the space inside the casing ( 10 ). Gas refrigerant in the casing ( 10 ) is discharged to a high-pressure gas pipe of the refrigerant circuit through the second discharge port b-pipe ( 15 - 2 b ) provided in an upper portion of the casing ( 10 ).
  • the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) form the two-stage compression mechanism, and a cylinder volume of the second compression mechanism ( 30 ) at the high-pressure stage is smaller than a cylinder volume of the first compression mechanism ( 20 ) at the low-pressure stage.
  • the length of the second circular piston body section ( 32 b ) in the shaft direction is shorter than the length of the first circular piston body section ( 22 b ) in the shaft direction. According to the foregoing configuration, volumes of the four cylinder chambers are different from each other in the present embodiment.
  • a refrigerant circuit ( 60 ) of the air conditioning apparatus carbon dioxide which is refrigerant is compressed to a supercritical pressure level by the compressor ( 1 ), thereby performing a refrigeration cycle.
  • the refrigerant circuit ( 60 ) includes the compressor ( 1 ), a gas cooler ( 2 ), an evaporator ( 3 ), a gas-liquid separator ( 4 ), a first expansion valve ( 5 ), and a second expansion valve ( 6 ).
  • two three-way valves (switching valves) ( 7 ) are provided in the refrigerant circuit.
  • the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ) is connected to a gas-side end of the evaporator ( 3 ) through a first suction pipe ( 61 ).
  • the first discharge port pipe ( 15 - 1 ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of the gas-liquid separator ( 4 ) through a first discharge pipe ( 63 ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including the second expansion valve ( 6 ) in the middle thereof.
  • the second discharge port b-pipe ( 15 - 2 b ) of the compressor ( 1 ) is connected to a second discharge pipe ( 64 b ).
  • the second discharge pipe ( 64 b ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ) through the gas cooler ( 2 ) and the first expansion valve ( 5 ).
  • the second discharge port a-pipe ( 15 - 2 a ) of the compressor is connected to a first port (P 1 ) of the first three-way valve ( 7 a ) through a second discharge pipe ( 64 a ).
  • a connecting pipe ( 67 a ) is connected to a second port (P 2 ) of the first three-way valve ( 7 a ), and the connecting pipe ( 67 a ) joins the second discharge pipe ( 64 b ) upstream the gas cooler ( 2 ).
  • a third port (P 3 ) of the first three-way valve ( 7 a ) is connected to a second port (P 2 ) of the second three-way valve ( 7 b ) through an intermediate suction pipe ( 65 ) including a muffler ( 9 ).
  • the first discharge pipe ( 63 ) branches into a branched pipe ( 68 ) in the middle thereof.
  • the branched pipe ( 68 ) is connected to the second suction port a-pipe ( 14 - 2 a ) of the second compression mechanism ( 30 ) through a second suction pipe ( 62 a ) including the muffler ( 9 ), and has a function of an injection pipe configured to inject intermediate-pressure refrigerant to the compressor ( 1 ).
  • a third port (P 3 ) of the second three-way valve ( 7 b ) is connected to second suction pipe ( 62 a ) downstream the muffler ( 9 ).
  • a first port (P 1 ) of the second three-way valve ( 7 b ) is connected to the second suction port b-pipe ( 14 - 2 b ) of the second compression mechanism ( 30 ) through a second suction pipe ( 62 b ).
  • the three-way valve ( 7 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other.
  • the three-way valve ( 7 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the three-way valve ( 7 ) is configured so that, by changing a connection order of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism ( 20 ) to a suction volume of the high-pressure compression mechanism ( 30 ) is changed.
  • the switching mechanism ( 7 ) switches the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) so that some of the cylinder chambers are used as the low-pressure compression mechanism ( 20 ), and the remaining cylinder chambers are used as the high-pressure compression mechanism ( 30 ).
  • the three-way valve ( 7 ) is switchable between a state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected together in parallel, and a state in which the inner cylinder chamber (C 4 ) and the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) are connected together in series.
  • the switching mechanism (volume ratio changing unit) ( 7 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • a process is carried out in the first and second compression mechanisms ( 20 , 30 ) in a state in which the phases of the first and second compression mechanisms ( 20 , 30 ) are shifted from each other by 180°.
  • the first compression mechanism ( 20 ) When starting the electrical motor ( 50 ), rotation of the rotor ( 52 ) is transmitted to the first circular piston ( 22 ) through the drive shaft ( 53 ) in the first compression mechanism ( 20 ) which is the low-pressure compression mechanism. Then, the first swing bushes ( 27 A, 27 B) reciprocate (move back and forth) along the first blade ( 23 ), and the first circular piston ( 22 ) and the first swing bushes ( 27 A, 27 B) together swing relative to the first blade ( 23 ). In such a state, the first swing bushes ( 27 A, 27 B) are in substantial surface contact with the first circular piston ( 22 ) and the first blade ( 23 ). The first circular piston ( 22 ) revolves while swinging relative to the first outer cylinder section ( 21 a ) and the first inner cylinder section ( 21 b ). Thus, the first compression mechanism ( 20 ) carries out a predetermined compression process.
  • the volume of the low-pressure chamber (C 1 -Lp) is substantially minimum in the state illustrated in FIG. 3(B) .
  • the volume of the low-pressure chamber (C 1 -Lp) is increased as the state illustrated in FIG. 3(C) is changed to the state illustrated in FIG. 3(A) by rotating the drive shaft ( 53 ) clockwise as viewed in the figure.
  • refrigerant is sucked into the low-pressure chamber (C 1 -Lp) through the first suction port pipe ( 14 - 1 ).
  • the volume of the high-pressure chamber (intermediate-pressure chamber) (C 1 -Hp) is decreased, thereby compressing refrigerant in the high-pressure chamber (intermediate-pressure chamber) (C 1 -Hp).
  • the discharge valve is opened by intermediate-pressure refrigerant of the high-pressure chamber (intermediate-pressure chamber) (C 1 -Hp). Then, the intermediate-pressure refrigerant is discharged from the casing ( 10 ) through the first discharge port pipe ( 15 - 1 ) after passing through the intermediate discharge space ( 17 b ).
  • the volume of the low-pressure chamber (C 2 -Lp) is substantially minimum in the state illustrated in FIG. 3(F) .
  • the volume of the low-pressure chamber (C 2 -Lp) is increased as the state illustrated in FIG. 3(G) is changed to the state illustrated in FIG. 3(E) by rotating the drive shaft ( 3 ) clockwise as viewed in the figure.
  • refrigerant is sucked into the low-pressure chamber (C 2 -Lp) of the first inner cylinder chamber (C 2 ) through the first suction port pipe ( 14 - 1 ) and the first injection path ( 42 a ).
  • the volume of the high-pressure chamber (intermediate-pressure chamber) (C 2 -Hp) is decreased, thereby compressing refrigerant in the high-pressure chamber (intermediate-pressure chamber) (C 2 -Hp).
  • a pressure in the high-pressure chamber (intermediate-pressure chamber) (C 2 -Hp) reaches a predetermined value, and a pressure difference between the high-pressure chamber (intermediate-pressure chamber) (C 2 -Hp) and the intermediate discharge space ( 17 b ) reaches a set value
  • the discharge valve is opened by intermediate-pressure refrigerant of the high-pressure chamber (intermediate-pressure chamber) (C 2 -Hp).
  • the intermediate-pressure refrigerant is discharged from the casing ( 10 ) through the first discharge port pipe ( 15 - 1 ) after passing through the intermediate discharge space ( 17 b ).
  • the discharge of refrigerant is started at a timing at which the compression mechanism is substantially in the state illustrated in FIG. 3(E) .
  • the discharge is started at a timing at which the compression mechanism is substantially in the state illustrated in FIG. 3(A) . That is, the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ) are different from each other in the discharge timing by about 180°.
  • the second compression mechanism ( 30 ) In the second compression mechanism ( 30 ), the rotation of the rotor ( 52 ) is transmitted to the second circular piston ( 32 ) through the drive shaft ( 53 ). Then, the second swing bush ( 37 ) reciprocates (moves back and forth) along the second blade ( 33 ), and the second circular piston ( 32 ) and the second swing bush ( 37 ) together swing relative to the second blade ( 33 ). In such a state, the second swing bush ( 37 ) is in substantial surface contact with the second circular piston ( 32 ) and the second blade ( 33 ). The second circular piston ( 32 ) revolves while swinging relative to the second outer cylinder section ( 31 a ) and the second inner cylinder section ( 31 b ). Thus, the second compression mechanism ( 30 ) carries out a predetermined compression process.
  • the compression process is the substantially same as that of the first compression mechanism ( 20 ), except that a pressure is different.
  • Refrigerant is compressed in the cylinder chambers (C 3 , C 4 ).
  • the discharge valve is opened by a refrigerant pressure, and refrigerant flows out from the compression chambers through the outlets ( 45 b , 46 b ) of the front head ( 16 ) and the discharge valve.
  • Refrigerant in the second outer cylinder chamber (C 3 ) flows out from the casing ( 10 ) through the second discharge port a-pipe ( 15 - 2 a ), and refrigerant in the second inner cylinder chamber (C 4 ) flows out from the casing through the second discharge port b-pipe ( 15 - 2 b ) after filling the casing ( 10 ).
  • the air conditioning apparatus is switchable between the first operational state illustrated in FIG. 4 and the second operational state illustrated in FIG. 5 depending on the change in operational conditions. Note that the operation which will be described below is assumed as a cooling operation.
  • the first three-way valve ( 7 a ) is set to the first position
  • the second three-way valve ( 7 b ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port pipe ( 14 - 1 ) of the compressor.
  • such refrigerant is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) branches into the second suction pipe ( 62 a ) and the second suction pipe ( 62 b ), and is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a part of the high-pressure refrigerant, which flows out from the second outer cylinder chamber (C 3 ) is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the remaining refrigerant flowing out from the second inner cylinder chamber (C 4 ) is discharged through the second discharge port b-pipe ( 15 - 2 b ) after filling the casing ( 10 ).
  • the refrigerant discharged through the second discharge port a-pipe ( 15 - 2 a ) and the refrigerant discharged through the second discharge port b-pipe ( 15 - 2 b ) join together and flow into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ). After the pressure of the liquid refrigerant is decreased to a low pressure level by the second expansion valve ( 6 ), such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the first three-way valve ( 7 a ) is set to the second position
  • the second three-way valve ( 7 b ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port pipe ( 14 - 1 ).
  • such refrigerant is compressed into intermediate-pressure refrigerant (such a pressure is referred to as a “first intermediate pressure”) in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the first intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and then flows into the branched pipe ( 68 ).
  • the first intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 a ).
  • the pressure of the first intermediate-pressure refrigerant sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is increased in the second outer cylinder chamber (C 3 ) (such a pressure is referred to as a “second intermediate pressure”).
  • the refrigerant, the pressure of which is increased to the second intermediate pressure is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the refrigerant flowing out through the second discharge port a-pipe ( 15 - 2 a ) passes through the first three-way valve ( 7 a ) and the second three-way valve ( 7 b ), and then is sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the refrigerant is further compressed so as to have a high pressure, and is discharged to a high-pressure space inside the casing ( 10 ).
  • the high-pressure refrigerant filling the casing ( 10 ) is discharged through the second discharge port b-pipe ( 15 - 2 b ), and flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to the first intermediate pressure by the first expansion valve ( 5 ), and flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the suction volume of the first compression mechanism ( 20 ) is the same in the first and second operational states.
  • first operational state intermediate-pressure refrigerant is sucked into both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • second operational state intermediate-pressure refrigerant is only sucked into the second outer cylinder chamber (C 3 ). That is, the suction volume at the low-pressure stage is the same in the first and second operational states, whereas the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the present embodiment it is switchable between the first operational state in which the two cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used in parallel, and the second operational state in which the cylinder chambers (C 3 , C 4 ) are used in series.
  • the compressor ( 1 ) in which the two compression mechanisms ( 20 , 30 ) are mechanically connected to the single shaft ( 53 ) the ratio of the suction volume of the low-pressure compression mechanism ( 20 ) to the suction volume of the high-pressure compression mechanism ( 30 ) in the first and second operational states can be adjusted.
  • the ratio of the suction volume of the low-pressure compression mechanism ( 20 ) to the suction volume of the high-pressure compression mechanism ( 30 ) in the compressor ( 1 ) is adjusted depending on the operational conditions, thereby allowing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • suction volume ratio is adjusted by unloading the low-pressure or high-pressure compression mechanism in the two-stage compression mechanism.
  • refrigerant is not compressed in the middle of a compression stroke in the present embodiment, thereby realizing a smooth operation.
  • FIGS. 6-10 illustrate examples of switching patterns when switching (changing) the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) of the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) between a connection in series and a connection in parallel.
  • Each of the foregoing figures is a cross-sectional view of a main section.
  • the first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into the first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into the first inner cylinder chamber (C 2 ).
  • the first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • the second suction port pipe ( 14 - 2 ) includes the second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into the second outer cylinder chamber (C 3 ), and the second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into the second inner cylinder chamber (C 4 ).
  • the second discharge port pipe ( 15 - 2 ) includes the second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and the second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • low-pressure refrigerant (LP) is sucked to the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and first intermediate-pressure refrigerant (IP 1 ) is discharged through the first discharge port a-pipe ( 15 - 1 a ).
  • the first intermediate-pressure refrigerant (IP 1 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) through the second suction port a-pipe ( 14 - 2 a ) and the second suction port b-pipe ( 14 - 2 b ), and is compressed to the second intermediate pressure.
  • Such refrigerant is discharged through the second discharge port a-pipe ( 15 - 2 a ) and the second discharge port b-pipe ( 15 - 2 b ).
  • the second intermediate-pressure refrigerant (IP 2 ) is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ).
  • Such refrigerant is compressed into high-pressure refrigerant (HP), and is discharged through the first discharge port b-pipe ( 15 - 1 b ).
  • low-pressure refrigerant (LP) is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ).
  • the pressure of the refrigerant is increased to the first intermediate pressure in the first inner cylinder chamber (C 2 ) and the second outer cylinder chamber (C 3 ), and the first intermediate-pressure refrigerant (IP 1 ) is discharged through the first discharge port b-pipe ( 15 - 1 b ) and the second discharge port a-pipe ( 15 - 2 a ).
  • the first intermediate-pressure refrigerant (IP 1 ) is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ). Then, the pressure of the refrigerant is increased to the second intermediate pressure, and is discharged through the first discharge port a-pipe ( 15 - 1 a ).
  • the second intermediate-pressure refrigerant (IP 2 ) is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • Such refrigerant is compressed into high-pressure refrigerant (HP), and is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant LP is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ). Then, the pressure of the refrigerant is increased to the first intermediate pressure, and is discharged through the first discharge port a-pipe ( 15 - 1 a ).
  • the first intermediate-pressure refrigerant (IP 1 ) is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ). Then, the pressure of the refrigerant is increased to the second intermediate pressure, and such refrigerant is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the second intermediate-pressure refrigerant (IP 2 ) is sucked into the first inner cylinder chamber (C 2 ) through the second suction port b-pipe ( 14 - 2 b ). Then, the pressure of the refrigerant is increased to a third intermediate pressure, and such refrigerant is discharged through the first discharge port b-pipe ( 15 - 1 b ).
  • the third intermediate-pressure refrigerant (IP 3 ) is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • Such refrigerant is compressed into high-pressure refrigerant (HP), and is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant (LP) is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the pressure of the refrigerant is increased to the first intermediate pressure in the first outer cylinder chamber (C 1 ) and the second inner cylinder chamber (C 4 ), and the first intermediate-pressure refrigerant (IP 1 ) is discharged through the first discharge port a-pipe ( 15 - 1 a ) and the second discharge port b-pipe ( 15 - 2 b ).
  • the first intermediate-pressure refrigerant (IP 1 ) is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ). Then, the pressure of the refrigerant is increased to the second intermediate pressure, and such refrigerant is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the second intermediate-pressure refrigerant (IP 2 ) is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ). Such refrigerant is compressed into high-pressure refrigerant (HP), and is discharged through the first discharge port b-pipe ( 15 - 1 b ).
  • low-pressure refrigerant (LP) is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ).
  • the pressure of the refrigerant is increased to the first intermediate pressure in the first outer cylinder chamber (C 1 ) and the second outer cylinder chamber (C 3 ), and the first intermediate-pressure refrigerant (IP 1 ) is discharged through the first discharge port a-pipe ( 15 - 1 a ) and the second discharge port a-pipe ( 15 - 2 a ).
  • the first intermediate-pressure refrigerant (IP 1 ) is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ). Then, the pressure of the refrigerant is increased to the second intermediate pressure, and such refrigerant is discharged through the first discharge port b-pipe ( 15 - 1 b ).
  • the second intermediate-pressure refrigerant (IP 2 ) is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ). Such refrigerant is compressed into high-pressure refrigerant (HP), and is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are switchable so that some of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are used in series, and the remaining cylinder chambers (C 1 , C 2 , C 3 , C 4 ) are used in parallel, thereby adjusting the volume ratio of the cylinder chambers.
  • the operation with optimum COP is allowed depending on the operational conditions.
  • the combination of the low-pressure and high-pressure compression mechanisms may be freely changed, and it is not necessary that, e.g., the low-pressure compression mechanism is limited to the lower cylinder.
  • FIGS. 11 and 12 A second embodiment of the present invention will be described with reference to FIGS. 11 and 12 .
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ) by way of a space inside a casing ( 10 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • refrigerant circuit ( 60 ) will be described. Components of the refrigerant circuit ( 60 ) are the same as those of the first embodiment.
  • the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ) is connected to a gas-side end of an evaporator ( 3 ) through a first suction pipe ( 61 ).
  • the first discharge port pipe ( 15 - 1 ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of a gas-liquid separator ( 4 ) through a first discharge pipe ( 63 ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including a second expansion valve ( 6 ) in the middle thereof.
  • the first discharge pipe ( 63 ) branches into a first branched pipe ( 68 a ) in the middle thereof, and further branches into a second branched pipe ( 68 b ).
  • the first branched pipe ( 68 a ) is connected to the second suction port a-pipe ( 14 - 2 a ) of a second compression mechanism ( 30 ) through a second suction pipe ( 62 a ) including a muffler ( 9 ).
  • the second branched pipe ( 68 b ) is connected to a second port (P 2 ) of a second three-way valve (switching valve) ( 7 b ), and a first port (P 1 ) of the second three-way valve ( 7 b ) is connected to the second suction port b-pipe ( 14 - 2 b ) of the second compression mechanism ( 30 ) through a second suction pipe ( 62 b ) including a muffler ( 9 ).
  • a third port (P 3 ) of the second three-way valve ( 7 b ) is connected to the first suction pipe ( 61 ) between the gas-side end of the evaporator ( 3 ) and the first suction port pipe ( 14 - 1 ) through a connecting pipe ( 67 b ).
  • One end of a second discharge pipe ( 64 a ) is connected to the second discharge port a-pipe ( 15 - 2 a ) of the second compression mechanism ( 30 ), and the other end of the second discharge pipe ( 64 a ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ).
  • a gas cooler ( 2 ) and a first expansion valve ( 5 ) are provided in this order from the second discharge port a-pipe ( 15 - 2 a ) side.
  • the second discharge port b-pipe ( 15 - 2 b ) of the second compression mechanism ( 30 ) is connected to a first port (P 1 ) of a first three-way valve (switching valve) ( 7 a ) through a second discharge pipe ( 64 b ).
  • a second port (P 2 ) of the first three-way valve ( 7 a ) is connected to a high-pressure injection pipe ( 18 ) provided so as to penetrate a body section of the casing ( 10 ), through a connecting pipe ( 67 c ).
  • a third port (P 3 ) of the first three-way valve ( 7 a ) is connected to the first discharge pipe ( 63 ) between the first discharge port pipe ( 15 - 1 ) and the first branched pipe ( 68 a ) through a connecting pipe ( 67 d ).
  • the three-way valve ( 7 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other.
  • the three-way valve ( 7 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the three-way valve ( 7 ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 7 ) is switchable between a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism; and a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 3 , C 4 ) of the second compression mechanism ( 30 ) is used as the high-pressure compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 7 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • a refrigerating apparatus In a refrigerating apparatus, it is switchable between a first operational state illustrated in FIG. 11 and a second operational state illustrated in FIG. 12 depending on the change in operational conditions.
  • the first three-way valve ( 7 a ) and the second three-way valve ( 7 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and flows into the first branched pipe ( 68 a ) and the second branched pipe ( 68 b ).
  • the intermediate-pressure refrigerant flowing through the first branched pipe ( 68 a ) is sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 a ), and the intermediate-pressure refrigerant flowing through the second branched pipe ( 68 b ) is sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 b ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out from the second inner cylinder chamber (C 4 ) through the second discharge port b-pipe ( 15 - 2 b ), and flows into the casing ( 10 ) through the connecting pipe ( 67 c ).
  • the refrigerant flowing out from the second outer cylinder chamber (C 3 ) is also discharged to the casing ( 10 ). That is, the casing ( 10 ) is filled with the high-pressure refrigerant.
  • the high-pressure refrigerant filling the casing ( 10 ) is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the refrigerant discharged through the second discharge port a-pipe ( 15 - 2 a ) flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to a low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the first three-way valve ( 7 a ) and the second three-way valve ( 7 b ) are set to the second position.
  • a part of low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the remaining low-pressure gas refrigerant is sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second three-way valve ( 7 b ) and the second suction port b-pipe ( 14 - 2 b ), and is changed into intermediate-pressure refrigerant in the second inner cylinder chamber (C 4 ).
  • the intermediate-pressure refrigerant flowing through the first branched pipe ( 68 a ) is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ) of the second compression mechanism ( 30 ).
  • the refrigerant sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ).
  • the high-pressure refrigerant flows out from the second outer cylinder chamber (C 3 ) to the space inside the casing ( 10 ), and fills such a space.
  • the high-pressure refrigerant is discharged through the second discharge port a-pipe ( 15 - 2 a ), and flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to the low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the suction volume of low-pressure refrigerant in the second operational state is larger than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is smaller than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • a suction amount at the low-pressure stage is larger in the second operational state than in the first operational state, whereas a suction amount at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the cylinder chambers of the second compression mechanism ( 30 ) are used while changing their combination with other cylinder chambers between the first and second operational states.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the suction volume ratio of the compressor is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • FIGS. 13-21 illustrate examples of switching patterns when changing a combination of the four cylinder chambers of the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ).
  • Each of the foregoing figures is a cross-sectional view of a main section.
  • the first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into the first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into the first inner cylinder chamber (C 2 ).
  • the first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • the second suction port pipe ( 14 - 2 ) includes the second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into the second outer cylinder chamber (C 3 ), and the second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into the second inner cylinder chamber (C 4 ).
  • the second discharge port pipe ( 15 - 2 ) includes the second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and the second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • low-pressure refrigerant LP is sucked into the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ) through the first suction port a-pipe ( 14 - 1 a ) and the first suction port b-pipe ( 14 - 1 b ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ). Then, such refrigerant is compressed, and therefore the pressure of the refrigerant is increased to the intermediate pressure level.
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port a-pipe ( 15 - 1 a ), the first discharge port b-pipe ( 15 - 1 b ), and the second discharge port a-pipe ( 15 - 2 a ), and is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the second inner cylinder chamber (C 4 ), and is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant LP
  • first outer cylinder chamber C 1
  • first suction port a-pipe 14 - 1 a
  • first intermediate-pressure refrigerant IP
  • second outer cylinder chamber C 3
  • second inner cylinder chamber C 4
  • second suction port a-pipe 14 - 2 a
  • second suction port b-pipe 14 - 2 b
  • low-pressure refrigerant LP
  • LP low-pressure refrigerant
  • first inner cylinder chamber C 2
  • second outer cylinder chamber C 3
  • second suction port a-pipe 14 - 2 a
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port b-pipe ( 15 - 1 b ) and the second discharge port a-pipe ( 15 - 2 a ).
  • the intermediate-pressure refrigerant (IP) is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP).
  • the high-pressure refrigerant (HP) is discharged through the first discharge port a-pipe ( 15 - 1 a ) and the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant LP is sucked into the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ) through the first suction port a-pipe ( 14 - 1 a ) and the first suction port b-pipe ( 14 - 1 b ), and is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ). Then, such refrigerant is compressed, and therefore the pressure of the refrigerant is increased to the intermediate pressure level.
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port a-pipe ( 15 - 1 a ), the first discharge port b-pipe ( 15 - 1 b ), and the second discharge port b-pipe ( 15 - 2 b ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the second outer cylinder chamber (C 3 ), and is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • low-pressure refrigerant LP
  • first outer cylinder chamber C 1
  • first suction port a-pipe
  • IP intermediate-pressure refrigerant
  • Such refrigerant is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ), into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ), and into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the first inner cylinder chamber (C 2 ), the second outer cylinder chamber (C 3 ), and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant (HP) is discharged through the first discharge port b-pipe ( 15 - 1 b ), the second discharge port a-pipe ( 15 - 2 a ), and the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant LP
  • LP low-pressure refrigerant
  • first outer cylinder chamber C 1
  • second inner cylinder chamber C 4
  • second suction port b-pipe 14 - 2 b
  • the intermediate-pressure refrigerant IP
  • first discharge port a-pipe 15 - 1 a
  • second discharge port b-pipe 15 - 2 b
  • Such refrigerant is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ), and into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the first inner cylinder chamber (C 2 ) and the second outer cylinder chamber (C 3 ).
  • the high-pressure refrigerant (HP) is discharged through the first discharge port b-pipe ( 15 - 1 b ) and the second discharge port a-pipe ( 15 - 2 a ).
  • low-pressure refrigerant LP is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ), and is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) through the second suction port a-pipe ( 14 - 2 a ) and the second suction port b-pipe ( 14 - 2 b ). Then, such refrigerant is compressed, and therefore the pressure of the refrigerant is increased to the intermediate pressure level.
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port b-pipe ( 15 - 1 b ), the second discharge port a-pipe ( 15 - 2 a ), and the second discharge port b-pipe ( 15 - 2 b ), and is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the first outer cylinder chamber (C 1 ), and is discharged through the first discharge port a-pipe ( 15 - 1 a ).
  • low-pressure refrigerant LP is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ). Then, such refrigerant is compressed, and therefore the pressure of the refrigerant is increased to the intermediate pressure level.
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port a-pipe ( 15 - 1 a ) and the first discharge port b-pipe ( 15 - 1 b ).
  • the intermediate-pressure refrigerant (IP) is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ), and is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ), and is discharged through the second discharge port a-pipe ( 15 - 2 a ) and the second discharge port b-pipe ( 15 - 2 b ).
  • low-pressure refrigerant (LP) is sucked into the first outer cylinder chamber (C 1 ) through the first suction port a-pipe ( 14 - 1 a ), and is sucked into the second outer cylinder chamber (C 3 ) through the second suction port a-pipe ( 14 - 2 a ). Then, such refrigerant is compressed, and therefore the pressure of the refrigerant is increased to the intermediate pressure level.
  • the intermediate-pressure refrigerant (IP) is discharged through the first discharge port a-pipe ( 15 - 1 a ) and the second discharge port a-pipe ( 15 - 2 a ).
  • the intermediate-pressure refrigerant (IP) is sucked into the first inner cylinder chamber (C 2 ) through the first suction port b-pipe ( 14 - 1 b ), and is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ).
  • the intermediate-pressure refrigerant (IP) is compressed into high-pressure refrigerant (HP) in the first inner cylinder chamber (C 2 ) and the second inner cylinder chamber (C 4 ), and is discharged through the first discharge port b-pipe ( 15 - 1 b ) and the second discharge port b-pipe ( 15 - 2 b ).
  • FIGS. 22 and 23 A third embodiment of the present invention will be described with reference to FIGS. 22 and 23 .
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ) by way of a space inside a casing ( 10 ).
  • refrigerant circuit ( 60 ) will be described. Components of the refrigerant circuit ( 60 ) are the same as those of the first embodiment.
  • the first suction port a-pipe ( 14 - 1 a ) of the compressor ( 1 ) is connected to a gas-side end of an evaporator ( 3 ) through a first suction pipe ( 61 a ).
  • the first discharge port a-pipe ( 15 - 1 a ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of a gas-liquid separator ( 4 ) through a first discharge pipe ( 63 a ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including a second expansion valve ( 6 ) in the middle thereof.
  • the first discharge pipe ( 63 a ) branches into a first branched pipe ( 68 a ) and a second branched pipe ( 68 b ).
  • the second branched pipe ( 68 b ) includes a muffler ( 9 ), and is connected to the second suction port b-pipe ( 14 - 2 b ) of a second compression mechanism ( 30 ) through a second suction pipe ( 62 b ).
  • the first branched pipe ( 68 a ) is connected to a first port (P 1 ) of a second four-way valve (switching valve) ( 8 b ).
  • a second port (P 2 ) of the second four-way valve ( 8 b ) is connected to one end of a second suction pipe ( 62 a ) including a muffler ( 9 ), and the other end of the second suction pipe ( 62 a ) is connected to the second suction port a-pipe ( 14 - 2 a ) of the second compression mechanism ( 30 ).
  • a third port (P 3 ) of the second four-way valve ( 8 b ) is connected to the first suction pipe ( 61 a ) between the gas-side end of the evaporator ( 3 ) and a muffler ( 9 ).
  • a fourth port (P 4 ) of the second four-way valve ( 8 b ) is connected to one end of a first suction pipe ( 61 b ) including a muffler ( 9 ), and the other end of the first suction pipe ( 61 b ) is connected to the first suction port b-pipe ( 14 - 1 b ).
  • One end of a first discharge pipe ( 63 b ) is connected to the first discharge port b-pipe ( 15 - 1 b ), and the other end of the first discharge pipe ( 63 b ) is connected to a first port (P 1 ) of a first four-way valve (switching valve) ( 8 a ).
  • One end of a connecting pipe ( 67 e ) is connected to a second port (P 2 ) of the first four-way valve ( 8 a ), and the other end of the connecting pipe ( 67 e ) is connected to the first discharge pipe ( 63 a ) between the first discharge port pipe ( 15 - 1 ) and the first branched pipe ( 68 a ).
  • the second discharge port a-pipe ( 15 - 2 a ) is connected to a third port (P 3 ) of the first four-way valve ( 8 a ) through a second discharge pipe ( 64 a ).
  • One end of a second discharge pipe ( 64 b ) is connected to the second discharge port b-pipe ( 15 - 2 b ), and the other end of the second discharge pipe ( 64 b ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ).
  • a gas cooler ( 2 ) and a first expansion valve ( 5 ) are provided in this order from the second discharge port b-pipe ( 15 - 2 b ) side.
  • a fourth port (P 4 ) of the first four-way valve ( 8 a ) is connected to the second discharge pipe ( 64 b ) between the second discharge port b-pipe ( 15 - 2 b ) and the gas cooler ( 2 ) through a connecting pipe ( 67 f ).
  • Each of the four-way valves ( 8 a , 8 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and the third port (P 3 ) and the fourth port (P 4 ) are communicated with each other (see FIG. 22 ); and a second position in which the first port (P 1 ) and the fourth port (P 4 ) are communicated with each other, and the second port (P 2 ) and the third port (P 3 ) are communicated with each other (see FIG. 23 ).
  • the four-way valve ( 8 a , 8 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the four-way valve ( 8 a , 8 b ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 8 a , 8 b ) is switchable between a state in which both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) are used as the low-pressure compression mechanism, and both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism; and a state in which one of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) and one of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the low-pressure compression mechanism, and the other cylinder chamber (C 1 , C 2 ) of the first compression mechanism ( 20 ) and the other cylinder chamber (C 3 , C 4 ) of the second compression mechanism ( 30 ) are used as the high-pressure compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 8 a , 8 b ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • a refrigerating apparatus In a refrigerating apparatus, it is switchable between a first operational state illustrated in FIG. 22 and a second operational state illustrated in FIG. 23 depending on the change in operational conditions.
  • the first four-way valve ( 8 a ) and the second four-way valve ( 8 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port a-pipe ( 14 - 1 a ) and the first suction port b-pipe ( 14 - 1 b ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant flows while joining refrigerant from other direction through the first four-way valve ( 8 a ). Such refrigerant further joins refrigerant from the gas-liquid separator ( 4 ), and flows into the first branched pipe ( 68 a ) and the second branched pipe ( 68 b ).
  • the intermediate-pressure refrigerant flowing through the first branched pipe ( 68 a ) is sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 a ), and the intermediate-pressure refrigerant flowing through the second branched pipe ( 68 b ) is sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 b ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out through the second discharge port a-pipe ( 15 - 2 a ), and flows into the connecting pipe ( 67 f ) through the first four-way valve ( 8 a ). Meanwhile, the high-pressure refrigerant flowing out from the second inner cylinder chamber (C 4 ) is discharged into the casing ( 10 ), and fills the casing ( 10 ). Then, such refrigerant is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to a low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the first four-way valve ( 8 a ) and the second four-way valve ( 8 b ) are set to the second position.
  • a part of low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port a-pipe ( 14 - 1 a ) of the compressor ( 1 ), and the remaining refrigerant is sucked into the second compression mechanism ( 30 ) through the second suction port a-pipe ( 14 - 2 a ).
  • Such refrigerant is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the second outer cylinder chamber (C 3 ).
  • the intermediate-pressure refrigerant discharged from the first outer cylinder chamber (C 1 ) of the first compression mechanism ( 20 ) and the intermediate-pressure refrigerant discharged from the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) flow while joining together through the first four-way valve ( 8 a ).
  • Such refrigerant further joins refrigerant from the gas-liquid separator ( 4 ), and flows into the first branched pipe ( 68 a ) and the second branched pipe ( 68 b ).
  • the intermediate-pressure refrigerant flowing through the second branched pipe ( 68 b ) is sucked into the second inner cylinder chamber (C 4 ) through the second suction port b-pipe ( 14 - 2 b ) of the second compression mechanism ( 30 ).
  • the refrigerant sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out from the second inner cylinder chamber (C 4 ) to the space inside the casing ( 10 ), and fills such a space. Then, such refrigerant is discharged through the second discharge port b-pipe ( 15 - 2 b ).
  • the intermediate-pressure refrigerant flowing through the first branched pipe ( 68 a ) is sucked into the first inner cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) through second four-way valve ( 8 b ) and the first suction port b-pipe ( 14 - 1 b ).
  • the refrigerant is compressed into high-pressure refrigerant.
  • the high-pressure refrigerant flows out from the first inner cylinder chamber (C 2 ) to outside the casing ( 10 ) through the first discharge port b-pipe ( 15 - 1 b ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to the low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the outer cylinder chambers (C 1 , C 3 ) are larger than the inner cylinder chambers (C 2 , C 4 ), and therefore the suction volume of low-pressure refrigerant in the second operational state is larger than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is smaller than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • the suction volume at the low-pressure stage is larger in the second operational state than in the first operational state, whereas the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the cylinder chambers (C 1 , C 2 , C 3 . C 4 ) of the first compression mechanism ( 20 ) and the second compression mechanism ( 30 ) are used while changing their combination between the first and second operational states.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the suction volume ratio of the compressor is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • FIGS. 24 and 25 A fourth embodiment of the present invention will be described with reference to FIGS. 24 and 25 .
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ) by way of a space inside a casing ( 10 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • refrigerant circuit ( 60 ) will be described. Components of the refrigerant circuit ( 60 ) are the same as those of the first embodiment.
  • the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ) is connected to a gas-side end of an evaporator ( 3 ) through a first suction pipe ( 61 ).
  • the first discharge port pipe ( 15 - 1 ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of a gas-liquid separator ( 4 ) through a first discharge pipe ( 63 ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including a second expansion valve ( 6 ) in the middle thereof.
  • the first discharge pipe ( 63 ) branches into a branched pipe ( 68 ) in the middle thereof.
  • the branched pipe ( 68 ) is connected to the second suction port pipe ( 14 - 2 ) of a second compression mechanism ( 30 ) through a second suction pipe ( 62 ).
  • the second discharge port a-pipe ( 15 - 2 a ) of the second compression mechanism ( 30 ) is connected to one end of a second discharge pipe ( 64 a ), and the other end of the second discharge pipe ( 64 a ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ).
  • a gas cooler ( 2 ) and a first expansion valve ( 5 ) are provided in this order from the second discharge port a-pipe ( 15 - 2 a ) side.
  • the second discharge port b-pipe ( 15 - 2 b ) of the second compression mechanism ( 30 ) is connected to a first port (P 1 ) of a three-way valve ( 7 ) through a second discharge pipe ( 64 b ).
  • a second port (P 2 ) of the three-way valve ( 7 ) is connected to a high-pressure injection pipe ( 18 ) provided so as to penetrate a body section of the casing ( 10 ), through a connecting pipe ( 67 c ).
  • a third port (P 3 ) of the three-way valve ( 7 ) is connected to the first discharge pipe ( 63 ) between the first discharge port pipe ( 15 - 1 ) and a first branched pipe ( 68 a ) through a connecting pipe ( 67 d ).
  • the three-way valve ( 7 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other.
  • the three-way valve ( 7 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the three-way valve ( 7 ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the three-way valve ( 7 ) is switchable between a state in which refrigerant is compressed in both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) to provide a difference between a suction pressure and a discharge pressure; and a state in which refrigerant is compressed in one of the cylinder chambers (outer cylinder chamber) (C 3 , C 4 ) of the second compression mechanism ( 30 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other cylinder chamber (inner cylinder chamber) (C 3 , C 4 ) allow uncompressed refrigerant to pass through the other cylinder chamber (C 3 , C 4 ). That is, refrigerant can merely pass through the inner cylinder chamber (C 4 ).
  • the switching mechanism (volume ratio changing unit) ( 7 ) changes the ratio of the suction volume of the low-pressure compression mechanism ( 20 ) to the suction volume of the high-pressure compression mechanism ( 30 ) depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 24 and a second operational state illustrated in FIG. 25 depending on the change in operational conditions.
  • the three-way valve ( 7 ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in an evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction pipe ( 61 ) and the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 ) and the second suction port pipe ( 14 - 2 ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out through the second discharge port b-pipe ( 15 - 2 b ), and flows into the casing ( 10 ) through the connecting pipe ( 67 c ).
  • the refrigerant flowing out from the second outer cylinder chamber (C 3 ) is also discharged into the casing ( 10 ). That is, the casing ( 10 ) is filled with the high-pressure refrigerant.
  • the high-pressure refrigerant filling the casing ( 10 ) is discharged through the second discharge port a-pipe ( 15 - 2 a ).
  • the refrigerant discharged through the second discharge port a-pipe ( 15 - 2 a ) flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to a low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the three-way valve ( 7 ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction pipe ( 61 ) and the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure discharged from the first compression mechanism ( 20 ) joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) through the second suction port pipe ( 14 - 2 ) of the second compression mechanism ( 30 ).
  • the refrigerant sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ).
  • the high-pressure refrigerant flows out from the second outer cylinder chamber (C 3 ) to the space inside the casing ( 10 ), and fills such a space.
  • the high-pressure refrigerant is discharged through the second discharge port a-pipe ( 15 - 2 a ), and flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to the low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the three-way valve ( 7 ) is switched to the second position, and therefore the second discharge port b-pipe ( 15 - 2 b ) is communicated with the first discharge pipe ( 63 ). That is, the second discharge port b-pipe ( 15 - 2 b ) is under an intermediate pressure.
  • the intermediate-pressure refrigerant sucked into the second inner cylinder chamber (C 4 ) substantially flows out (merely pass) through the second discharge port b-pipe ( 15 - 2 b ) without being compressed.
  • a cylinder volume (discharge volume) of the second compression mechanism ( 30 ) is smaller in the second operational state than in the first operational state.
  • the suction volume of low-pressure refrigerant in the first operational state is the same as the suction volume of low-pressure refrigerant in the second operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is smaller than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • the suction volume at the low-pressure stage is the same between the first and second operational states, and the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • refrigerant merely passes through the inner cylinder chamber of the second compression mechanism ( 30 ) in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the suction volume ratio of the compressor is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • FIGS. 26 and 27 A fifth embodiment of the present invention will be described with reference to FIGS. 26 and 27 .
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ) by way of a space inside a casing ( 10 ).
  • refrigerant circuit ( 60 ) will be described. Components of the refrigerant circuit ( 60 ) are the same as those of the first embodiment.
  • the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ) is connected to a gas-side end of an evaporator ( 3 ) through a first suction pipe ( 61 ).
  • the first discharge port pipe ( 15 - 1 ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of a gas-liquid separator ( 4 ) through a first discharge pipe ( 63 ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including a second expansion valve ( 6 ) in the middle thereof.
  • the first discharge pipe ( 63 ) branches into a branched pipe ( 68 ) in the middle thereof.
  • the branched pipe ( 68 ) is connected to the second suction port pipe ( 14 - 2 ) of a second compression mechanism ( 30 ) through a second suction pipe ( 62 ).
  • the second discharge port b-pipe ( 15 - 2 b ) of the second compression mechanism ( 30 ) is connected to one end of a second discharge pipe ( 64 b ), and the other end of the second discharge pipe ( 64 b ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ).
  • a gas cooler ( 2 ) and a first expansion valve ( 5 ) are provided in this order from the second discharge port b-pipe ( 15 - 2 b ) side.
  • the second discharge port a-pipe ( 15 - 2 a ) of the second compression mechanism ( 30 ) is connected to a first port (P 1 ) of a three-way valve ( 7 ) through a second discharge pipe ( 64 a ).
  • a second connecting pipe ( 67 i ) is connected to a second port (P 2 ) of the three-way valve ( 7 ), and the second connecting pipe ( 67 i ) is connected to the second discharge pipe ( 64 b ) between the second discharge port b-pipe ( 15 - 2 b ) and the gas cooler ( 2 ).
  • a first connecting pipe ( 67 j ) is connected to a third port (P 3 ) of the three-way valve ( 7 ), and the first connecting pipe ( 67 j ) joins the first discharge pipe ( 63 ).
  • the three-way valve ( 7 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other.
  • the three-way valve ( 7 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the three-way valve ( 7 ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the three-way valve ( 7 ) is switchable between a state in which refrigerant is compressed in both of the cylinder chambers (C 3 , C 4 ) of the second compression mechanism ( 30 ) to provide a difference between a suction pressure and a discharge pressure; and a state in which refrigerant is compressed in one of the cylinder chambers (inner cylinder chamber) (C 3 , C 4 ) of the second compression mechanism ( 30 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other cylinder chamber (outer cylinder chamber) (C 3 , C 4 ) allow uncompressed refrigerant to pass through the other cylinder chamber (C 3 , C 4 ). That is, refrigerant can merely pass through the outer cylinder chamber (C 3 ).
  • the switching mechanism changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 26 and a second operational state illustrated in FIG. 27 depending on the change in operational conditions.
  • the three-way valve ( 7 ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction pipe ( 61 ) and the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction pipe ( 62 ) and the second suction port pipe ( 14 - 2 ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out through the second discharge port a-pipe ( 15 - 2 a ), and joins the second discharge pipe ( 64 b ) through the three-way valve ( 7 ) and the second connecting pipe ( 67 i ).
  • the refrigerant is discharged from the casing ( 10 ) through the second discharge port b-pipe ( 15 - 2 b ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to a low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the three-way valve ( 7 ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction pipe ( 61 ) and the first suction port pipe ( 14 - 1 ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the first compression mechanism ( 20 ) joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) through the second suction port pipe ( 14 - 2 ) of the second compression mechanism ( 30 ).
  • the refrigerant sucked into the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant flows out from the second inner cylinder chamber (C 4 ) to the space inside the casing ( 10 ), and fills such a space.
  • the high-pressure refrigerant is discharged through the second discharge port b-pipe ( 15 - 2 b ), and flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to the low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the three-way valve ( 7 ) is switched to the second position, and therefore the second discharge port a-pipe ( 15 - 2 a ) is communicated with the first discharge pipe ( 63 ).
  • the refrigerant sucked into the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) is not compressed. That is, the second discharge port a-pipe ( 15 - 2 a ) is under an intermediate pressure.
  • the intermediate-pressure refrigerant sucked into the second outer cylinder chamber (C 3 ) substantially flows out (merely pass) through the second discharge port a-pipe ( 15 - 2 a ) without being compressed.
  • a cylinder volume (discharge volume) of the second compression mechanism ( 30 ) is smaller in the second operational state than in the first operational state.
  • the suction volume of low-pressure refrigerant in the first operational state is the same as the suction volume of low-pressure refrigerant in the second operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is smaller than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • the suction volume at the low-pressure stage is the same between the first and second operational states, and the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • refrigerant merely passes through the second outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 ) in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted. Consequently, the suction volume ratio of the compressor is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a configuration may be employed, in which refrigerant merely pass through the outer cylinder chamber of the first compression mechanism, thereby adjusting the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states.
  • FIGS. 28 and 29 A sixth embodiment of the present invention will be described with reference to FIGS. 28 and 29 .
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) by way of a space inside a casing ( 10 ).
  • refrigerant circuit ( 60 ) will be described. Components of the refrigerant circuit ( 60 ) are the same as those of the first embodiment.
  • the first suction port a-pipe ( 14 - 1 a ) of the compressor ( 1 ) is connected to a gas-side end of an evaporator ( 3 ) through a first suction pipe ( 61 a ) including a muffler ( 9 ).
  • One end of a first suction pipe ( 61 b ) is connected to the first suction port b-pipe ( 14 - 1 b ) of the compressor ( 1 ), and the other end of the first suction pipe ( 61 b ) is connected to a first port (P 1 ) of a three-way valve ( 7 ).
  • a second port (P 2 ) of the three-way valve ( 7 ) is connected to the first suction pipe ( 61 a ) between the first suction port a-pipe ( 14 - 1 a ) and the muffler ( 9 ) through a connecting pipe ( 67 g ).
  • the first discharge port pipe ( 15 - 1 ) of the compressor ( 1 ) is connected to a refrigerant gas outlet ( 4 a ) of a gas-liquid separator ( 4 ) through a first discharge pipe ( 63 ).
  • An outlet ( 4 c ) of the gas-liquid separator ( 4 ) is connected to a liquid-side end of the evaporator ( 3 ) through a liquid pipe ( 66 ) including a second expansion valve ( 6 ) in the middle thereof.
  • the first discharge pipe ( 63 ) branches into a branched pipe ( 68 ) in the middle thereof.
  • the branched pipe ( 68 ) is connected to the second suction port pipe ( 14 - 2 ) of a second compression mechanism ( 30 ) through a second suction pipe ( 62 ).
  • the branched pipe ( 68 ) further branches into a connecting pipe ( 67 h ) including a muffler ( 9 ), and the connecting pipe ( 67 h ) is connected to a third port (P 3 ) of the three-way valve ( 7 ).
  • the second discharge port pipe ( 15 - 2 ) of the second compression mechanism ( 30 ) is connected to one end of a second discharge pipe ( 64 ), and the other end of the second discharge pipe ( 64 ) is connected to an inlet ( 4 b ) of the gas-liquid separator ( 4 ).
  • a gas cooler ( 2 ) and a first expansion valve ( 5 ) are provided in this order from the second discharge port pipe ( 15 - 2 ) side.
  • the three-way valve ( 7 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other.
  • the three-way valve ( 7 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into the compression mechanism ( 20 , 30 ).
  • the three-way valve ( 7 ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 60 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism is switchable between a state in which refrigerant is compressed in both of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) to provide a difference between a suction pressure and a discharge pressure; and a state in which refrigerant is compressed in one of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other cylinder chamber (C 1 , C 2 ) allow uncompressed refrigerant to pass through the other cylinder chamber (C 1 , C 2 ). That is, refrigerant can merely pass through the cylinder chamber (C 2 ).
  • the switching mechanism changes the ratio of the suction volume of the low-pressure compression mechanism ( 20 ) to the suction volume of the high-pressure compression mechanism ( 30 ) depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 28 and a second operational state illustrated in FIG. 29 depending on the change in operational conditions.
  • the three-way valve ( 7 ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port a-pipe ( 14 - 1 a ) and the first suction port b-pipe ( 14 - 1 b ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) is sucked into the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ) through the second suction port pipe ( 14 - 2 ).
  • the intermediate-pressure refrigerant sucked into the second compression mechanism ( 30 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant is discharged into the casing ( 10 ). That is, the casing ( 10 ) is filled with the high-pressure refrigerant.
  • the high-pressure refrigerant filling the casing ( 10 ) is discharged through the second discharge port pipe ( 15 - 2 ).
  • the refrigerant discharged through the second discharge port pipe ( 15 - 2 ) flows into the gas cooler ( 2 ) through the second discharge pipe ( 64 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 5 ), and such refrigerant flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to a low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the three-way valve ( 7 ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 3 ) is sucked into the first compression mechanism ( 20 ) through the first suction port a-pipe ( 14 - 1 a ) of the compressor ( 1 ), and is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ).
  • the intermediate-pressure refrigerant discharged from the first compression mechanism ( 20 ) joins refrigerant from the gas-liquid separator ( 4 ), and flows into the branched pipe ( 68 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 68 ) branches into the connecting pipe ( 67 h ), and is sucked into the first inner cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) through the first suction port b-pipe ( 14 - 1 b ).
  • the first discharge port pipe ( 15 - 1 ) is under an intermediate pressure, and therefore refrigerant is not substantially compressed in the first inner cylinder chamber (C 2 ).
  • the refrigerant sucked into the second compression mechanism ( 30 ) through the branched pipe ( 68 ) is compressed into high-pressure refrigerant in the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the high-pressure refrigerant is discharged into the casing ( 10 ), and fills the casing ( 10 ).
  • the high-pressure refrigerant in the casing ( 10 ) is discharged through the second discharge port pipe ( 15 - 2 ), and flows into the gas cooler ( 2 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 5 ), and flows into the gas-liquid separator ( 4 ).
  • the liquid refrigerant separated in the gas-liquid separator ( 4 ) flows out from the gas-liquid separator ( 4 ).
  • the pressure of the refrigerant is decreased to the low pressure level by the second expansion valve ( 6 )
  • such refrigerant is evaporated in the evaporator ( 3 ), and is sucked into the first compression mechanism ( 20 ).
  • the suction volume of intermediate-pressure refrigerant in the second operational state is larger than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • the suction volume of low-pressure refrigerant in the second operational state is smaller than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of low-pressure refrigerant is smaller in the second operational state than in the first operational state, whereas the suction volume of intermediate-pressure refrigerant is the same between the first and second operational states.
  • refrigerant merely passes through one of the cylinder chambers (C 1 , C 2 ) of the first compression mechanism ( 20 ) (inner cylinder chamber) in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted. Consequently, the suction volume ratio of the compressor ( 1 ) is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a seventh embodiment of the present invention will be described with reference to FIGS. 30-34 .
  • FIG. 30 is a longitudinal sectional view of a compressor ( 100 ) used for a refrigerating apparatus (air conditioning apparatus) of the seventh embodiment.
  • FIG. 31 is a cross-sectional view of a compression mechanism (first compression mechanism ( 110 )).
  • FIGS. 32(A)-32(D) are views illustrating operational states in the compression mechanism (first compression mechanism ( 110 )).
  • FIG. 33 is a refrigerant circuit diagram illustrating a first operational state of the air conditioning apparatus, and
  • FIG. 34 is a refrigerant circuit diagram illustrating a second operational state.
  • the compressor ( 100 ) is used for compressing refrigerant sucked from an evaporator at two stages and discharging such refrigerant to a condenser in a refrigerant circuit of the air conditioning apparatus.
  • the compressor ( 100 ) is a rotary compressor, and includes the first compression mechanism ( 110 ), a second compression mechanism ( 120 ), a third compression mechanism ( 130 ), and a fourth compression mechanism ( 140 ) which are mechanically connected together through a single drive shaft ( 173 ).
  • the compressor ( 100 ) is configured so that carbon dioxide which is refrigerant (working fluid) is compressed from a low pressure level to a high pressure level.
  • the cross-sectional views and the operational state views of the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are the substantially same as those of the first compression mechanism ( 110 ), reference numerals of the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are shown in FIG. 2 without details.
  • the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are of the same phase, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are arranged so that their phases are shifted from the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) by 180°. However, for convenience of reference, such a phase difference is not shown in FIG. 2 .
  • the compressor ( 100 ) includes a casing ( 150 ) in which the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), the fourth compression mechanism ( 140 ), and an electrical motor (drive mechanism) ( 170 ) positioned above the compression mechanisms ( 110 - 140 ) are accommodated in this order from bottom to top; and is hermetic.
  • later-described volume ratio changing units are provided, by which a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) of the compression mechanisms ( 110 - 140 ) is changed, and therefore a ratio of a suction volume of a low-pressure compression mechanism to a suction volume of a high-pressure compression mechanism is changed.
  • a refrigerant flow in a refrigerant circuit ( 180 ) is switched, and therefore a combination of the compression mechanisms ( 110 - 140 ) to be used for the two-stage compression is switchable.
  • the casing ( 150 ) includes a cylindrical body section ( 151 ), an upper end plate ( 152 ) fixed to an upper end portion of the body section ( 151 ), and a lower end plate ( 153 ) fixed to a lower end portion of the body section ( 151 ).
  • a suction port pipe ( 154 ) and a discharge port pipe ( 155 ) corresponding to each of the compression mechanisms ( 110 - 140 ) are provided in the casing ( 150 ).
  • the suction port pipe ( 154 ) includes a first suction port pipe ( 154 - 1 ) corresponding to the first compression mechanism ( 110 ), a second suction port pipe ( 154 - 2 ) corresponding to the second compression mechanism ( 120 ), a third suction port pipe ( 154 - 3 ) corresponding to the third compression mechanism ( 130 ), and a fourth suction port pipe ( 154 - 4 ) corresponding to the fourth compression mechanism ( 140 ).
  • the discharge port pipe includes a first discharge port pipe ( 155 - 1 ) corresponding to the first compression mechanism ( 110 ), a second discharge port pipe ( 155 - 2 ) corresponding to the second compression mechanism ( 120 ), a third discharge port pipe ( 155 - 3 ) corresponding to the third compression mechanism ( 130 ), and a fourth discharge port pipe ( 155 - 4 ) corresponding to the fourth compression mechanism ( 140 ).
  • a refrigerant injection port ( 156 ) is provided, through which refrigerant flowing through the refrigerant circuit ( 180 ) is injected into the casing ( 150 ).
  • the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are stacked in four tiers, and are provided between a front head ( 157 ) fixed to the casing ( 150 ) and a rear head ( 158 ) below the first compression mechanism ( 110 ).
  • Each of the compression mechanisms ( 110 - 140 ) is a rotary fluid machine which is one type of a positive-displacement fluid machine.
  • the first to fourth compression mechanisms ( 110 - 140 ) are arranged in this order from a bottom side of the casing ( 150 ) to top (the electrical motor ( 170 ) side).
  • Middle plates ( 159 ) are provided, each of which is interposed between each pair of the compression mechanisms ( 110 - 140 ).
  • the rear head ( 158 ) is fastened to the front head ( 157 ) with bolts (not shown in the figure) from bottom in a state in which each of the three middle plates ( 159 ) is sandwiched between each pair of the four compression mechanisms ( 110 - 140 ), thereby forming the compression mechanisms ( 110 - 140 ).
  • the front head ( 157 ) is fixed to the casing ( 150 ), and therefore the compression mechanisms ( 110 - 140 ) are positioned within the casing ( 150 ).
  • Bearing sections ( 157 a , 158 a ) are provided in the front head ( 157 ) and the rear head ( 158 ), respectively.
  • a cover plate ( 160 ) is fixed to a lower surface of the rear head ( 158 ).
  • the electrical motor ( 170 ) includes a stator ( 171 ) and a rotor ( 172 ).
  • the stator ( 171 ) is arranged above the fourth compression mechanism ( 140 ), and is fixed to the body section ( 151 ) of the casing ( 150 ).
  • the rotor ( 172 ) is arranged inside the stator ( 171 ).
  • a main shaft section of the drive shaft (crankshaft) ( 173 ) is connected to a center portion of the rotor ( 172 ), and the drive shaft ( 173 ) rotates together with the rotor ( 172 ).
  • the center of the main shaft section is on the center of the casing ( 150 ).
  • each of the compression mechanisms ( 110 - 140 ) includes a circular cylinder ( 111 , 121 , 131 , 141 ) and a circular rotary piston (eccentric piston) ( 112 , 122 , 132 , 142 ).
  • the reference numerals which are not in parentheses are reference numerals for the first compression mechanism ( 110 )
  • the reference numerals in parentheses are reference numerals for the second to fourth compression mechanisms ( 120 - 140 ).
  • the cylinder ( 111 , 121 , 131 , 141 ) and the rotary piston ( 112 , 122 , 132 , 142 ) are sandwiched between the rear head ( 158 ) and the middle plate ( 159 ), between the middle plates ( 159 ), or between the middle plate ( 159 ) and the front head ( 157 ).
  • An inner diameter of the cylinder ( 111 , 121 , 131 , 141 ) is larger than an outer diameter of the rotary piston ( 112 , 122 , 132 , 142 ).
  • a cylinder chamber (C 1 , C 2 , C 3 , C 4 ) is formed between an inner circumferential surface of the cylinder ( 111 , 121 , 131 , 141 ) and an outer circumferential surface of the rotary piston ( 112 , 122 , 132 , 142 ).
  • a flat plate-like blade ( 113 , 123 , 133 , 143 ) is provided so as to protrude from the outer circumferential surface of the rotary piston ( 112 , 122 , 132 , 142 ).
  • the blade ( 113 , 123 , 133 , 143 ) is slidably sandwiched between a pair of swing bushes ( 114 , 124 , 134 , 144 ) which are provided so as to swing relative to the cylinder ( 111 , 121 , 131 , 141 ).
  • the rotary piston ( 112 , 122 , 132 , 142 ) can swing relative to the cylinder ( 111 , 121 , 131 , 141 ) together with the blade ( 113 , 123 , 133 , 143 ).
  • the blade ( 113 , 123 , 133 , 143 ) divides the cylinder chamber (C 1 , C 2 , C 3 , C 4 ) into two sections.
  • An eccentric section ( 173 a , 173 b , 173 c , 173 d ) of the drive shaft ( 173 ) is rotatably fitted into an inside of the rotary piston ( 112 , 122 , 132 , 142 ).
  • the eccentric section ( 173 a , 173 b , 173 c , 173 d ) has a diameter larger than that of the main shaft section, and is eccentric to the main shaft section.
  • an inner circumferential surface of the rotary piston ( 112 , 122 , 132 , 142 ) slidably contacts an outer circumferential surface of the eccentric section ( 173 a , 173 b , 173 c , 173 d ) through an oil film
  • the outer circumferential surface of the rotary piston ( 112 , 122 , 132 , 142 ) slidably contacts the inner circumferential surface of the cylinder ( 111 , 121 , 131 , 141 ) through an oil film.
  • the rotary piston ( 112 , 122 , 132 , 142 ) eccentrically rotates.
  • the suction port pipe ( 154 - 1 , 154 - 2 , 154 - 3 , 154 - 4 ) is connected to the cylinder ( 111 , 121 , 131 , 141 ) so as to be communicated with the cylinder chamber (C 1 , C 2 , C 3 , C 4 ).
  • the suction port pipe ( 154 - 1 , 154 - 2 , 154 - 3 , 154 - 4 ) opens near one of the swing bushes ( 114 , 124 , 134 , 144 ) (swing bush ( 114 , 124 , 134 , 144 ) on the right side as viewed in FIG. 31 ).
  • a side to which the suction port pipe ( 154 - 1 , 154 - 2 , 154 - 3 , 154 - 4 ) opens is a low-pressure side.
  • the “low-pressure side” includes a low-pressure side against an intermediate-pressure side, and an intermediate-pressure side against a high-pressure side.
  • a discharge space ( 161 , 162 ) is formed in each of the compression mechanisms ( 110 - 140 ), and the discharge port pipe ( 155 - 1 , 155 - 2 , 155 - 3 , 155 - 4 ) is connected to the discharge space ( 161 , 162 ).
  • the discharge space ( 161 , 162 ) is communicated with the cylinder chamber (C 1 , C 2 , C 3 , C 4 ) through, e.g., an outlet ( 110 a , 140 a ).
  • a discharge valve (reed valve) ( 163 , 164 ) configured to open/close the outlet ( 110 a , 140 a ) (the discharge valves for the second and third compression mechanisms are not shown in the figure).
  • the discharge port pipes ( 155 - 1 , 155 - 2 , 155 - 3 ) are communicated with, e.g., the discharge space ( 161 ).
  • the discharge port pipe ( 155 - 4 ) is communicated with the discharge space ( 162 ) through a space inside the casing ( 150 ).
  • the outlets ( 110 a , 140 a ) of the first compression mechanism ( 110 ) and the fourth compression mechanism ( 140 ) open near the other swing bush ( 114 , 124 , 134 , 144 ) (swing bush ( 114 , 124 , 134 , 144 ) on the left side as viewed in FIG. 31 ).
  • a side to which the outlet ( 110 a , 140 a ) opens is a high-pressure side.
  • the “high-pressure side” includes a high-pressure side against an intermediate-pressure side, and an intermediate-pressure side against a low-pressure side.
  • the compressor ( 100 ) includes the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) each having the single cylinder chamber (C 1 , C 2 , C 3 , C 4 ).
  • Each of the compression mechanisms ( 110 - 140 ) includes the cylinder ( 111 , 121 , 131 , 141 ) having a circular cylinder space, and the rotary piston (eccentric piston) ( 112 , 122 , 132 , 142 ) eccentrically rotating in the cylinder space.
  • suction volumes of the four cylinder chambers are different.
  • the length of the rotary piston ( 112 , 122 , 132 , 142 ) in a shaft direction and the length of the corresponding cylinder ( 111 , 121 , 131 , 141 ) in the shaft direction are different in each of the compression mechanisms ( 110 - 140 ).
  • the lengths of the cylinder ( 111 ) and the rotary piston ( 112 ) of the first compression mechanism ( 110 ) in the shaft direction are longest, and the lengths of the cylinder ( 111 , 121 , 131 , 141 ) and the rotary piston ( 112 , 122 , 132 , 142 ) in the shaft direction are set so as to decrease in the order from the first compression mechanism ( 110 ) to the fourth compression mechanism ( 140 ).
  • An oil sump in which lubricant oil is stored is formed in a bottom portion of the casing ( 150 ).
  • a centrifugal oil pump ( 174 ) soaked in the lubricant oil of the oil sump is provided in a lower end portion of the drive shaft ( 173 ).
  • the oil pump is connected to an oil supply path (not shown in the figure) vertically extending inside the drive shaft ( 173 ).
  • the oil pump ( 174 ) is configured to supply the lubricant oil to sliding sections of the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ), and the bearing sections of the drive shaft ( 173 ) through the oil supply path.
  • the refrigerant circuit ( 180 ) of the air conditioning apparatus carbon dioxide which is refrigerant is compressed to a supercritical pressure level by the compressor ( 100 ), thereby performing a refrigeration cycle.
  • the refrigerant circuit ( 180 ) includes the compressor ( 100 ), a gas cooler ( 102 ), an evaporator ( 103 ), a gas-liquid separator ( 104 ), a first expansion valve ( 105 ), and a second expansion valve ( 106 ).
  • the refrigerant circuit ( 180 ) further includes a first three-way valve (switching mechanism) ( 107 a ) on an inlet side of the compressor ( 100 ), and a second three-way valve (switching mechanism) ( 107 b ) on an outlet side of the compressor ( 100 ).
  • the first suction pipe ( 182 a ) is connected to the first suction port pipe ( 154 - 1 ) of the compressor ( 100 ), and the second section pipe ( 182 b ) is connected to the second suction port pipe ( 154 - 2 ).
  • a first discharge pipe ( 183 a ) is connected to the first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to the second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ) join together, and then branch into an intermediate-pressure refrigerant pipe ( 184 ) and a first connecting pipe ( 189 a ).
  • the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the first connecting pipe ( 189 a ) is connected to a third port (P 3 ) of the second three-way valve ( 107 b ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) is connected to a second port (P 2 ) of the first three-way valve ( 107 a ).
  • One end of a third suction pipe ( 182 c ) is connected to a first port (P 1 ) of the first three-way valve ( 107 a ), and the other end of the third suction pipe ( 182 c ) is connected to the third suction port pipe ( 154 - 3 ) of the compressor ( 100 ).
  • the branched pipe ( 185 ) branches into a fourth suction pipe ( 182 d ) between a point at which the branched pipe ( 185 ) is connected to the intermediate-pressure refrigerant pipe ( 184 ) and a point at which the branched pipe ( 185 ) is connected to the first three-way valve ( 107 a ).
  • the fourth suction pipe ( 182 d ) is connected to the fourth suction port pipe ( 154 - 4 ) of the compressor ( 100 ).
  • the second section pipe ( 182 b ) branches into a second connecting pipe ( 189 b ) between the second suction port pipe ( 154 - 2 ) and the low-pressure refrigerant pipe ( 181 ), and the second connecting pipe ( 189 b ) is connected to a third port (P 3 ) of the first three-way valve ( 107 a ).
  • the third discharge port pipe ( 155 - 3 ) is connected to a first port (P 1 ) of the second three-way valve ( 107 b ) through a third discharge pipe ( 183 c ).
  • a second port (P 2 ) of the second three-way valve ( 107 b ) is connected to the refrigerant injection port ( 156 ) through a high-pressure refrigerant injection pipe ( 186 ).
  • the fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through the gas cooler ( 102 ) and the first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including the second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism (injection pipe) through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • Each of the three-way valves ( 107 a , 107 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 33 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 34 ).
  • the three-way valve ( 107 a , 107 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 a , 107 b ) is configured so that, by changing a combination of the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 a , 107 b ) can change the four cylinder chambers (C 1 , C 2 , C 3 , C 4 ), i.e., the cylinder chambers used as the low-pressure compression mechanism and the cylinder chambers used as the high-pressure compression mechanism.
  • the switching mechanism ( 107 a , 107 b ) is switchable between a state illustrated in FIG. 33 , in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism; and a state illustrated in FIG. 34 , in which the first compression mechanism ( 110 ), the second compression mechanism ( 120 ), and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the fourth compression mechanism ( 140 ) is used as the high-pressure compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 107 a , 107 b ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • FIGS. 32(A)-32(D) A process in which refrigerant flows into the compressor ( 100 ) will be described with reference to FIGS. 32(A)-32(D) .
  • the drive shaft ( 173 ) slightly rotates from a state in which an angle of rotation is 0° as illustrated in FIG. 32(A) , and a point where the first rotary piston ( 112 ) and the first cylinder ( 111 ) contact each other passes through an opening of the first suction port pipe ( 154 - 1 ), refrigerant begins to flow into the first outer cylinder chamber (C 1 ) through the first suction port pipe ( 154 - 1 ).
  • refrigerant flows into the first outer cylinder chamber (C 1 ) as the angle of rotation of the drive shaft ( 173 ) is increased to 90° as illustrated in FIG. 32(B) , 180° as illustrated in FIG. 32(C) , and 270° as illustrated in FIG. 32(D) , and refrigerant continuously flows into the first outer cylinder chamber (C 1 ) until the angle of rotation reaches 360° as illustrated in FIG. 32(A) .
  • the air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 33 and a second operational state illustrated in FIG. 34 depending on the change in operational conditions. Note that the operation which will be described below is assumed as a cooling operation.
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 ) passes through the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ). Then, such refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, such refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the second three-way valve ( 107 b ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ). Thus, the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ), the second section pipe ( 182 b ), and the third suction pipe ( 182 c ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ), and the refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ), the second cylinder chamber (C 2 ), and the third cylinder chamber (C 3 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 , C 3 ) passes through the first discharge pipe ( 183 a ), the second discharge pipe ( 183 b ), and the third discharge pipe ( 183 c ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant further joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) flows into the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant is sucked into the fourth compression mechanism ( 140 ) through the fourth suction pipe ( 182 d ) and the fourth discharge port pipe ( 155 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the pressure of the liquid refrigerant is decreased to the low pressure level by the second expansion valve ( 106 )
  • such refrigerant is evaporated in the evaporator ( 103 ), and is sucked into the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ).
  • the gas refrigerant in the gas-liquid separator ( 104 ) is injected to the fourth compression mechanism ( 140 ).
  • the suction volume of low-pressure refrigerant in the second operational state is larger than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is smaller than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • a suction amount at the low-pressure stage is larger in the second operational state than in the first operational state, whereas a suction amount at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) of the compression mechanisms ( 110 - 140 ) are used while changing their combination between the first and second operational states.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the suction volume ratio of the compressor ( 100 ) is adjusted depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • suction volume ratio is adjusted by unloading the low-pressure or high-pressure compression mechanism in the two-stage compression mechanism.
  • refrigerant is not compressed in the middle of a compression stroke in the present embodiment, thereby realizing a smooth operation.
  • the present embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that components of the refrigerant circuit ( 180 ) are the same as those of the seventh embodiment.
  • a low-pressure refrigerant pipe ( 181 ) connected to a gas-side end of an evaporator ( 103 ) is connected to a first suction port pipe ( 154 - 1 ) through a first suction pipe ( 182 a ).
  • the low-pressure refrigerant pipe ( 181 ) branches into a connecting pipe ( 189 c ) on an outlet side of the evaporator ( 103 ), and the connecting pipe ( 189 c ) is connected to a second port (P 2 ) of a first three-way valve ( 107 a ).
  • One end of a third suction pipe ( 182 c ) is connected to a first port (P 1 ) of the first three-way valve ( 107 a ), and the other end of the third suction pipe ( 182 c ) is connected to a third suction port pipe ( 154 - 3 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ).
  • the first discharge pipe ( 183 a ) is connected to one end of an intermediate-pressure refrigerant pipe ( 184 ), and the other end of the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • One end of a third discharge pipe ( 183 c ) is connected to a third discharge port pipe ( 155 - 3 ), and the other end of the third discharge pipe ( 183 c ) is connected to a first port (P 1 ) of a second three-way valve ( 107 b ).
  • One end of a connecting pipe ( 189 d ) is connected to a second port (P 2 ) of the second three-way valve ( 107 b ), and the other end of the connecting pipe ( 189 d ) joins the first discharge pipe ( 183 a ) and is connected to the intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a first branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) is connected to a third port (P 3 ) of the first three-way valve ( 107 a ).
  • the branched pipe ( 185 ) branches into a second branched pipe ( 185 b ) between a point where the branched pipe ( 185 ) and the intermediate-pressure refrigerant pipe ( 184 ) are connected together, and a point where the branched pipe ( 185 ) and the first three-way valve ( 107 a ) are connected together.
  • the second branched pipe ( 185 b ) further branches into a second section pipe ( 182 b ) and a fourth suction pipe ( 182 d ).
  • the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ) of the compressor ( 100 ), and the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ).
  • a third port (P 3 ) of the second three-way valve ( 107 b ) is connected to a refrigerant injection port ( 156 ) through a high-pressure refrigerant injection pipe ( 186 ).
  • One end of a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ), and the other end of the second discharge pipe ( 183 b ) is connected to the high-pressure refrigerant injection pipe ( 186 ).
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to compression mechanisms ( 110 - 140 ).
  • Each of the three-way valves ( 107 a , 107 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 35 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 36 ).
  • the three-way valve ( 107 a , 107 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 a , 107 b ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 a , 107 b ) is switchable between a state illustrated in FIG. 35 , in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism; and a state illustrated in FIG. 36 , in which the first compression mechanism ( 110 ) is used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 107 a , 107 b ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 35 and a second operational state illustrated in FIG. 36 depending on the change in operational conditions.
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the third suction pipe ( 182 c ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the third cylinder chamber (C 3 ).
  • the intermediate-pressure refrigerant discharged from the first cylinder chamber (C 1 ) flows through the first discharge pipe ( 183 a ), and the intermediate-pressure refrigerant discharged from the third cylinder chamber (C 3 ) flows through the third discharge pipe ( 183 c ), the second three-way valve ( 107 b ), and the connecting pipe ( 189 d ).
  • Such refrigerant joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the first branched pipe ( 185 ).
  • the intermediate-pressure refrigerant further branches into the second branched pipe ( 185 b ) from the first branched pipe ( 185 ). Then, the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ), and the refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). The refrigerant is compressed into high-pressure refrigerant in the second cylinder chamber (C 2 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the second discharge port pipe ( 155 - 2 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ). Thus, the high-pressure refrigerant compressed in the second cylinder chamber (C 2 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) flows into the first suction pipe ( 182 a ) through the low-pressure refrigerant pipe ( 181 ), and is sucked into the first compression mechanism ( 110 ) through the first suction pipe ( 182 a ) and the first suction port pipe ( 154 - 1 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ).
  • the intermediate-pressure refrigerant discharged from the first cylinder chamber (C 1 ) is discharged from the first discharge pipe ( 183 a ), and flows into the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the first branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the first branched pipe ( 185 ) branches into the second section pipe ( 182 b ), the third suction pipe ( 182 c ), and the fourth suction pipe ( 182 d ).
  • the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ), the refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the second cylinder chamber (C 2 ), the third cylinder chamber (C 3 ), and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant compressed in the second cylinder chamber (C 2 ) is discharged through the second discharge port pipe ( 155 - 2 ), and flows through the second discharge pipe ( 183 b ) toward the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) is discharged through the third discharge port pipe ( 155 - 3 ), and flows through the third discharge pipe ( 183 c ) and the high-pressure refrigerant injection pipe ( 186 ) toward the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant discharged from the second cylinder chamber (C 2 ) and the third cylinder chamber (C 3 ) and the high-pressure refrigerant discharged from the fourth cylinder chamber (C 4 ) are mixed together.
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the suction volume of low-pressure refrigerant in the second operational state is smaller than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is larger than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • a suction amount at the low-pressure stage is smaller in the second operational state than in the first operational state, whereas a suction amount at the high-pressure stage is larger in the second operational state than in the first operational state.
  • the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) of the compression mechanisms ( 110 - 140 ) are used while changing their combination between the first and second operational states.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the suction volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • a ninth embodiment will be described with reference to FIGS. 37 and 38 .
  • the ninth embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that, in the present embodiment, four-way switching valves ( 108 a , 108 b ) are used as components of the refrigerant circuit ( 180 ) instead of the three-way valves ( 107 a , 107 b ).
  • a low-pressure refrigerant pipe ( 181 ) connected to a gas-side end of an evaporator ( 103 ) is connected to a first suction port pipe ( 154 - 1 ) through a first suction pipe ( 182 a ).
  • the low-pressure refrigerant pipe ( 181 ) branches into a connecting pipe ( 189 e ) on an outlet side of the evaporator ( 103 ), and the connecting pipe ( 189 e ) is connected to a second port (P 2 ) of the first four-way switching valve ( 108 a ).
  • One end of a second section pipe ( 182 b ) is connected to a first port (P 1 ) of the first four-way switching valve ( 108 a ), and the other end of the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) is connected to one end of an intermediate-pressure refrigerant pipe ( 184 ), and the other end of the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • the second discharge pipe ( 183 b ) is connected to a first port (P 1 ) of the second four-way switching valve ( 108 b ).
  • the first discharge pipe ( 183 a ) branches into a connecting pipe ( 189 f ), and the connecting pipe ( 189 f ) is connected to a second port (P 2 ) of the second four-way switching valve ( 108 b ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) is connected to a fourth port (P 4 ) of the first four-way switching valve ( 108 a ).
  • One end of a third suction pipe ( 182 c ) is connected to a third port (P 3 ) of the first four-way switching valve ( 108 a ), and the other end of the third suction pipe ( 182 c ) is connected to a third suction port pipe ( 154 - 3 ) of the compression mechanism.
  • the branched pipe ( 185 ) branches into a fourth suction pipe ( 182 d ) between a point where the branched pipe ( 185 ) and the intermediate-pressure refrigerant pipe ( 184 ) are connected together, and a point where the branched pipe ( 185 ) and the first four-way switching valve ( 108 a ) are connected together, and the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ) of the compressor ( 100 ).
  • the third discharge port pipe ( 155 - 3 ) is connected to a third port (P 3 ) of the second four-way switching valve ( 108 b ) through a third discharge pipe ( 183 c ).
  • a fourth port (P 4 ) of the second four-way switching valve ( 108 b ) is connected to a refrigerant injection port ( 156 ) through a high-pressure refrigerant injection pipe ( 186 ).
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • Each of the four-way valves ( 108 a , 108 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other, and the third port (P 3 ) and the fourth port (P 4 ) are communicated with each other (see FIG. 37 ); and a second position in which the first port (P 1 ) and the fourth port (P 4 ) are communicated with each other, and the second port (P 2 ) and the third port (P 3 ) are communicated with each other (see FIG. 38 ).
  • the four-way valve ( 108 a , 108 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the four-way valve ( 108 a , 108 b ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 108 a , 108 b ) is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism; and a state in which the first compression mechanism ( 110 ) and the third compression mechanism ( 130 ) are used as the low-pressure compression mechanism, and the second compression mechanism ( 120 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 108 a , 108 b ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 37 and a second operational state illustrated in FIG. 38 depending on the change in operational conditions.
  • the first four-way switching valve ( 108 a ) and the second four-way switching valve ( 108 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 ) passes through the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant further joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the second four-way switching valve ( 108 b ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ). Thus, the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first four-way switching valve ( 108 a ) and the second four-way switching valve ( 108 b ) are set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the third suction pipe ( 182 c ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the third cylinder chamber (C 3 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 3 ) passes through the first discharge pipe ( 183 a ) and the third discharge pipe ( 183 c ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant further joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the second section pipe ( 182 b ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the second cylinder chamber (C 2 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the second discharge port pipe ( 155 - 2 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the second four-way switching valve ( 108 b ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ). Thus, the high-pressure refrigerant compressed in the second cylinder chamber (C 2 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the suction volume of low-pressure refrigerant in the second operational state is smaller than the suction volume of low-pressure refrigerant in the first operational state.
  • the suction volume of intermediate-pressure refrigerant in the second operational state is larger than the suction volume of intermediate-pressure refrigerant in the first operational state.
  • a suction amount at the low-pressure stage is smaller in the second operational state than in the first operational state, whereas a suction amount at the high-pressure stage is larger in the second operational state than in the first operational state.
  • the cylinder chambers (C 1 , C 2 , C 3 , C 4 ) of the compression mechanisms ( 110 - 140 ) are used while changing their combination between the first and second operational states.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • a tenth embodiment will be described with reference to FIGS. 39 and 40 .
  • the tenth embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that the present embodiment is different from the first embodiment in that a three-way valve or a four-way valve is not used on an inlet side of the compressor ( 100 ) as components of the refrigerant circuit ( 180 ).
  • the first suction pipe ( 182 a ) is connected to a first suction port pipe ( 154 - 1 ) of the compressor ( 100 ), and the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ) join together, and are connected to an intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • the second discharge pipe ( 183 b ) branches into a connecting pipe ( 189 g ).
  • the connecting pipe ( 189 g ) is connected to a third port (P 3 ) of a three-way valve ( 107 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) branches into a third suction pipe ( 182 c ) and a fourth suction pipe ( 182 d ).
  • the third suction pipe ( 182 c ) is connected to a third suction port pipe ( 154 - 3 ) of a third compression mechanism ( 130 ).
  • the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ) of the compressor ( 100 ).
  • the third discharge port pipe ( 155 - 3 ) is connected to a first port (P 1 ) of the three-way valve ( 107 ) through a third discharge pipe ( 183 c ).
  • a second port (P 2 ) of the three-way valve ( 107 ) is connected to a refrigerant injection port ( 156 ) through a high-pressure refrigerant injection pipe ( 186 ).
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 39 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 40 ).
  • the three-way valve ( 107 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 ) is switchable between a state in which refrigerant is compressed in both of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) to provide a difference between a suction pressure and a discharge pressure; and a state in which refrigerant is compressed in one of the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) (in the fourth compression mechanism ( 140 )) to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in the other compression mechanism (third compression mechanism ( 130 )) allow uncompressed refrigerant to pass through such a compression mechanism.
  • the switching mechanism (volume ratio changing unit) ( 107 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 39 and a second operational state illustrated in FIG. 40 depending on the change in operational conditions.
  • the three-way valve ( 107 ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 ) passes through the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant further joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into a casing ( 150 ) of the compressor ( 100 ) through the three-way valve ( 107 ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ). Meanwhile, the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ). Thus, the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the three-way valve ( 107 ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 ) passes through the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ).
  • the three-way valve ( 107 ) is switched to the second position, and therefore the third discharge pipe ( 183 c ) and the second discharge pipe ( 183 b ) are communicated with each other under an intermediate pressure.
  • refrigerant is not substantially compressed in the third compression mechanism ( 130 ), and the intermediate-pressure refrigerant is discharged as it is.
  • the refrigerant is compressed into high-pressure refrigerant in the fourth cylinder chamber (C 4 ) of the fourth compression mechanism ( 140 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the pressure of the liquid refrigerant is decreased to the low pressure level by the second expansion valve ( 106 )
  • such refrigerant is evaporated in the evaporator ( 103 ), and is sucked into the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ).
  • the gas refrigerant in the gas-liquid separator ( 104 ) is injected to the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ).
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • intermediate-pressure refrigerant merely passes through the third compression mechanism ( 130 ) as it is.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and only the fourth compression mechanism ( 140 ) is used as the high-pressure compression mechanism.
  • the suction volume at the low-pressure stage is the same between the first and second operational states, whereas the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state. That is, a suction amount at the low-pressure stage is the same in the first and second operational states, but a substantive suction amount at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • refrigerant is not compressed in the third compression mechanism ( 130 ) in the second operational state.
  • the compressor ( 100 ) in which the four compression mechanisms ( 110 - 140 ) are mechanically connected to a single shaft the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • the present embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that the present embodiment is different from the seventh embodiment in that a three-way valve or a four-way valve is not used on an outlet side of the compressor ( 100 ) as components of the refrigerant circuit ( 180 ).
  • a low-pressure refrigerant pipe ( 181 ) connected to a gas-side end of an evaporator ( 103 ) is connected to a first suction port pipe ( 154 - 1 ) of a first compression mechanism ( 110 ) through a first suction pipe ( 182 a ).
  • the first suction pipe ( 182 a ) branches into a connecting pipe ( 189 h ), and the connecting pipe ( 189 h ) is connected to a second port (P 2 ) of a three-way valve ( 107 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ) join together, and are connected to an intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) is connected to a third port (P 3 ) of the three-way valve ( 107 ).
  • One end of a second section pipe ( 182 b ) is connected to a first port (P 1 ) of the three-way valve ( 107 ), and the other end of the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ) of a second compression mechanism ( 120 ).
  • the branched pipe ( 185 ) branches into a third suction pipe ( 182 c ) and a fourth suction pipe ( 182 d ) between a point where the branched pipe ( 185 ) and the intermediate-pressure refrigerant pipe ( 184 ) are connected together, and a point where the branched pipe ( 185 ) and the three-way valve ( 107 ) are connected together.
  • the third suction pipe ( 182 c ) is connected to a third suction port pipe ( 154 - 3 ) of a third compression mechanism ( 130 ), and the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ) of a fourth compression mechanism ( 140 ).
  • a third discharge port pipe ( 155 - 3 ) is connected to a refrigerant injection port ( 156 ) through a third discharge pipe ( 183 c ) and a high-pressure refrigerant injection pipe ( 186 ).
  • the third discharge pipe ( 183 c ) and the high-pressure refrigerant injection pipe ( 186 ) form a single pipe.
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 41 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 42 ).
  • the three-way valve ( 107 ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 ) is switchable between a state in which, when the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) serve as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) serve as the high-pressure compression mechanism, refrigerant is compressed in both of the low-pressure and high-pressure compression mechanisms to provide a difference between a suction pressure and a discharge pressure; and a state in which, when the first compression mechanism ( 110 ) serves as the low-pressure compression mechanism, and the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), and the fourth compression mechanism ( 140 ) serve as the high-pressure compression mechanism, refrigerant is compressed in the low-pressure compression mechanism to provide the difference between the suction pressure and the discharge pressure, and, on the other hand, the substantially same suction and discharge pressures in one of the second compression mechanism ( 120 ), the third compression mechanism ( 130 ), or the fourth compression mechanism ( 140 ) at the high-pressure stage allow uncompressed refrigerant to
  • the switching mechanism (volume ratio changing unit) ( 107 ) changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 41 and a second operational state illustrated in FIG. 42 depending on the change in operational conditions.
  • the three-way valve ( 107 ) is set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the cylinder chambers (C 1 , C 2 ) passes through the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ), respectively, and joins together in the intermediate-pressure refrigerant pipe ( 184 ).
  • Such refrigerant further joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into a casing ( 150 ) of the compressor ( 100 ) through the third discharge pipe ( 183 c ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ).
  • the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the three-way valve ( 107 ) is set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) is sucked into the first compression mechanism ( 110 ) through the low-pressure refrigerant pipe ( 181 ), the first suction pipe ( 182 a ), and the first suction port pipe ( 154 - 1 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ).
  • the intermediate-pressure refrigerant discharged from the first cylinder chamber (C 1 ) passes through the first discharge pipe ( 183 a ), and flows into the intermediate-pressure refrigerant pipe ( 184 ). Then, the intermediate-pressure refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the second section pipe ( 182 b ), the third suction pipe ( 182 c ), and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ), the refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ).
  • the second discharge pipe ( 183 b ) joins the first discharge pipe ( 183 a ), and is connected to the intermediate-pressure refrigerant pipe ( 184 ).
  • an outlet side of the second compression mechanism ( 120 ) is constantly under an intermediate pressure. Consequently, the intermediate-pressure refrigerant sucked into the second compression mechanism ( 120 ) is not substantially compressed, and flows out from the second compression mechanism ( 120 ) as it is.
  • the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the third discharge pipe ( 183 c ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used as the low-pressure compression mechanism, and the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the second operational state intermediate-pressure refrigerant passes through the second compression mechanism ( 120 ) as it is.
  • the first compression mechanism ( 110 ) is used as the low-pressure compression mechanism
  • the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used as the high-pressure compression mechanism.
  • the suction volume at the high-pressure stage is the same between the first and second operational states, whereas the suction volume at the low-pressure stage is smaller in the second operational state than in the first operational state. That is, a suction amount at the high-pressure stage is the same between the first and second operational states, but a substantive suction amount at the low-pressure stage is smaller in the second operational state than in the first operational state.
  • refrigerant is not compressed in the second compression mechanism ( 120 ) in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • the present embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that components of the refrigerant circuit ( 180 ) are the same as those of the seventh embodiment.
  • a low-pressure refrigerant pipe ( 181 ) connected to a gas-side end of an evaporator ( 103 ) is connected to a first suction pipe ( 182 a ).
  • the first suction pipe ( 182 a ) is connected to a first suction port pipe ( 154 - 1 ) of a first compression mechanism ( 110 ).
  • the low-pressure refrigerant pipe ( 181 ) branches into a connecting pipe ( 189 i ), and the connecting pipe ( 189 i ) is connected to a second port (P 2 ) of a first three-way valve ( 107 a ).
  • One end of a second section pipe ( 182 b ) is connected to a first port (P 1 ) of the first three-way valve ( 107 a ), and the other end of the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ) of a second compression mechanism ( 120 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) is connected to a first port (P 1 ) of a second three-way valve ( 107 b ).
  • One end of a connecting pipe ( 189 j ) is connected to a second port (P 2 ) of the second three-way valve ( 107 b ), and the other end of the connecting pipe ( 189 j ) is connected to the second discharge pipe ( 183 b ).
  • the second discharge pipe ( 183 b ) and the connecting pipe ( 189 j ) join together, and are connected to an intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • a third port (P 3 ) of the first three-way valve ( 107 a ) and a third port (P 3 ) of the second three-way valve ( 107 b ) are connected together through a communication pipe ( 190 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) further branches into a third suction pipe ( 182 c ) and a fourth suction pipe ( 182 d ).
  • the third suction pipe ( 182 c ) is connected to a third suction port pipe ( 154 - 3 ) of a third compression mechanism ( 130 ), and the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ) of a fourth compression mechanism ( 140 ).
  • a third discharge port pipe ( 155 - 3 ) is connected to a refrigerant injection port ( 156 ) through a third discharge pipe ( 183 c ) and the high-pressure refrigerant injection pipe ( 186 ).
  • the third discharge pipe ( 183 c ) and the high-pressure refrigerant injection pipe ( 186 ) form a single pipe.
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • Each of the three-way valves ( 107 a , 107 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 43 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 44 ).
  • the three-way valve ( 107 a , 107 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 a , 107 b ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) (switching the low-pressure compression mechanisms between connection in series and connection in parallel) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 a , 107 b ) is switchable between a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in parallel, and a state in which the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are connected together in series.
  • the switching mechanism changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 43 and a second operational state illustrated in FIG. 44 depending on the change in operational conditions.
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the intermediate-pressure refrigerant discharged from the first cylinder chamber (C 1 ) flows into the connecting pipe ( 189 j ) through the first discharge pipe ( 183 a ) and the second three-way valve ( 107 b ). Then, such refrigerant is discharged from the second cylinder chamber (C 2 ), and joins intermediate-pressure refrigerant flowing through the second discharge pipe ( 183 b ) in the intermediate-pressure refrigerant pipe ( 184 ).
  • the refrigerant flowing through the intermediate-pressure refrigerant pipe ( 184 ) joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ).
  • the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into a casing ( 150 ) of the compressor ( 100 ) through the third discharge pipe ( 183 c ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ).
  • the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) is sucked into the first compression mechanism ( 110 ) through the low-pressure refrigerant pipe ( 181 ), the first suction pipe ( 182 a ), and the first suction port pipe ( 154 - 1 ).
  • the refrigerant is compressed into first intermediate-pressure refrigerant in the first cylinder chamber (C 1 ).
  • the first intermediate-pressure refrigerant is discharged from the first cylinder chamber (C 1 ), and passes through the first discharge pipe ( 183 a ), the second three-way valve ( 107 b ), the communication pipe ( 190 ), the first three-way valve ( 107 a ), and the second section pipe ( 182 b ). Then, the first intermediate-pressure refrigerant is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ). The refrigerant is compressed into second intermediate-pressure refrigerant (intermediate-pressure refrigerant in a two-stage compression) in the second cylinder chamber (C 2 ).
  • the second intermediate-pressure refrigerant discharged from the second cylinder chamber (C 2 ) passes through the second discharge pipe ( 183 b ), and flows into the intermediate-pressure refrigerant pipe ( 184 ). Then, the second intermediate-pressure refrigerant joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ).
  • the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into the casing ( 150 ) of the compressor ( 100 ) through the third discharge pipe ( 183 c ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) at the low-pressure stage are used in parallel in the first operational state, and, on the other hand, are used in series in the second operational state.
  • the suction volume at the low-pressure stage is smaller in the second operational state than in the first operational state.
  • the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) are used in parallel in both of the first and second operational states, and the suction volume is not changed.
  • the suction volume at the high-pressure stage is the same between the first and second operational states, whereas the suction volume at the low-pressure stage is smaller in the second operational state than in the first operational state. That is, a suction amount at the high-pressure stage is the same between the first and second operational states, but a substantive suction amount at the low-pressure stage is smaller in the second operational state than in the first operational state.
  • the two compression mechanisms ( 110 , 120 ) at the low-pressure stage are used in parallel in the first operational state, and are used in series in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • a thirteenth embodiment will be described with reference to FIGS. 45 and 46 .
  • the present embodiment has a structure of a compressor ( 100 ) same as that of the seventh embodiment, and has a configuration of a refrigerant circuit ( 180 ) different from that of the seventh embodiment. Thus, only the refrigerant circuit ( 180 ) will be described below. Note that components of the refrigerant circuit ( 180 ) are the same as those of the seventh embodiment.
  • the first suction pipe ( 182 a ) is connected to a first suction port pipe ( 154 - 1 ) of a first compression mechanism ( 110 )
  • the second section pipe ( 182 b ) is connected to a second suction port pipe ( 154 - 2 ) of a second compression mechanism ( 120 ).
  • a first discharge pipe ( 183 a ) is connected to a first discharge port pipe ( 155 - 1 ) of the compressor ( 100 ), and a second discharge pipe ( 183 b ) is connected to a second discharge port pipe ( 155 - 2 ).
  • the first discharge pipe ( 183 a ) and the second discharge pipe ( 183 b ) join together, and are connected to an intermediate-pressure refrigerant pipe ( 184 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) is connected to a refrigerant gas outlet ( 104 a ) of a gas-liquid separator ( 104 ).
  • the intermediate-pressure refrigerant pipe ( 184 ) branches into a branched pipe ( 185 ) downstream the refrigerant gas outlet ( 104 a ) of the gas-liquid separator ( 104 ).
  • the branched pipe ( 185 ) is connected to a third suction port pipe ( 154 - 3 ) of a third compression mechanism ( 130 ) through a third suction pipe ( 182 c ).
  • the branched pipe ( 185 ) branches into a connecting pipe ( 189 k ) in the middle thereof, and the connecting pipe ( 189 k ) is connected to a second port (P 2 ) of a first three-way valve ( 107 a ).
  • One end of a fourth suction pipe ( 182 d ) is connected to a first port (P 1 ) of the first three-way valve ( 107 a ), and the other end of the fourth suction pipe ( 182 d ) is connected to a fourth suction port pipe ( 154 - 4 ) of a fourth compression mechanism ( 140 ).
  • One end of a third discharge pipe ( 183 c ) is connected to a third discharge port pipe ( 155 - 3 ), and the other end of the third discharge pipe ( 183 c ) is connected to a first port (P 1 ) of a second three-way valve ( 107 b ).
  • a second port (P 2 ) of the second three-way valve ( 107 b ) is connected to a refrigerant injection port ( 156 ) through a high-pressure refrigerant injection pipe ( 186 ).
  • a third port (P 3 ) of the first three-way valve ( 107 a ) and a third port (P 3 ) of the second three-way valve ( 107 b ) are connected together through a communication pipe ( 190 ).
  • a fourth discharge port pipe ( 155 - 4 ) of the compressor ( 100 ) is connected to one end of a high-pressure refrigerant pipe ( 187 ).
  • the other end of the high-pressure refrigerant pipe ( 187 ) is connected to an inlet ( 104 b ) of the gas-liquid separator ( 104 ) through a gas cooler ( 102 ) and a first expansion valve ( 105 ).
  • An outlet ( 104 c ) of the gas-liquid separator ( 104 ) is connected to a liquid-side end of the evaporator ( 103 ) through a liquid pipe ( 188 ) including a second expansion valve ( 106 ) in the middle thereof.
  • the branched pipe ( 185 ) serves as an injection mechanism through which intermediate-pressure refrigerant is injected to the compression mechanisms ( 110 - 140 ).
  • Each of the three-way valves ( 107 a , 107 b ) is switchable between a first position in which the first port (P 1 ) and the second port (P 2 ) are communicated with each other (see FIG. 45 ), and a second position in which the first port (P 1 ) and the third port (P 3 ) are communicated with each other (see FIG. 46 ).
  • the three-way valve ( 107 a , 107 b ) serves as a switching mechanism (volume ratio changing unit) configured to switch a flow path of low-pressure, intermediate-pressure, or high-pressure refrigerant into each of the compression mechanisms ( 110 - 140 ).
  • the three-way valve ( 107 a , 107 b ) is configured so that, by changing a combination of four cylinder chambers (C 1 , C 2 , C 3 , C 4 ) (switching the high-pressure compression mechanisms between connection in series and connection in parallel) in the refrigerant circuit ( 180 ), a ratio of a suction volume of the low-pressure compression mechanism to a suction volume of the high-pressure compression mechanism is changed.
  • the switching mechanism ( 107 a , 107 b ) is switchable between a state illustrated in FIG. 45 , in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in parallel; and a state illustrated in FIG. 46 , in which the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are connected together in series.
  • the switching mechanism changes the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism depending on a change in operational conditions.
  • an air conditioning apparatus it is switchable between a first operational state illustrated in FIG. 45 and a second operational state illustrated in FIG. 46 depending on the change in operational conditions.
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the first position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into intermediate-pressure refrigerant in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the refrigerant flowing through the intermediate-pressure refrigerant pipe ( 184 ) joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) branches into the third suction pipe ( 182 c ) and the fourth suction pipe ( 182 d ).
  • the intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and the intermediate-pressure refrigerant from the fourth suction pipe ( 182 d ) is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ). Then, the refrigerant is compressed into high-pressure refrigerant in the third cylinder chamber (C 3 ) and the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant discharged through the third discharge port pipe ( 155 - 3 ) is injected into a casing ( 150 ) of the compressor ( 100 ) through the third discharge pipe ( 183 c ), the high-pressure refrigerant injection pipe ( 186 ), and the refrigerant injection port ( 156 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from a discharge space ( 162 ) of a front head ( 157 ) to a space inside the casing ( 150 ).
  • the high-pressure refrigerant compressed in the third cylinder chamber (C 3 ) and the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) join together in the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to an intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the first three-way valve ( 107 a ) and the second three-way valve ( 107 b ) are set to the second position.
  • low-pressure gas refrigerant evaporated by exchanging heat with air in the evaporator ( 103 ) branches into the first suction pipe ( 182 a ) and the second section pipe ( 182 b ) from the low-pressure refrigerant pipe ( 181 ).
  • the refrigerant from the first suction pipe ( 182 a ) is sucked into the first compression mechanism ( 110 ) through the first suction port pipe ( 154 - 1 ), and the refrigerant from the second section pipe ( 182 b ) is sucked into the second compression mechanism ( 120 ) through the second suction port pipe ( 154 - 2 ).
  • the refrigerant is compressed into first intermediate-pressure refrigerant (intermediate-pressure refrigerant in a two-stage compression) in the first cylinder chamber (C 1 ) and the second cylinder chamber (C 2 ).
  • the refrigerant flowing through the intermediate-pressure refrigerant pipe ( 184 ) joins intermediate-pressure refrigerant from the gas-liquid separator ( 104 ), and flows into the branched pipe ( 185 ).
  • the intermediate-pressure refrigerant flowing through the branched pipe ( 185 ) flows into the third suction pipe ( 182 c ).
  • the first intermediate-pressure refrigerant from the third suction pipe ( 182 c ) is sucked into the third compression mechanism ( 130 ) through the third suction port pipe ( 154 - 3 ), and is compressed into second intermediate-pressure refrigerant in the third cylinder chamber (C 3 ).
  • the second intermediate-pressure refrigerant discharged from the third cylinder chamber (C 3 ) flows through the third discharge port pipe ( 155 - 3 ), the third discharge pipe ( 183 c ), the second three-way valve ( 107 b ), the communication pipe ( 190 ), and the fourth suction pipe ( 182 d ) in this order.
  • the second intermediate-pressure refrigerant is sucked into the fourth compression mechanism ( 140 ) through the fourth suction port pipe ( 154 - 4 ).
  • the refrigerant is compressed into high-pressure refrigerant in the fourth cylinder chamber (C 4 ).
  • the high-pressure refrigerant compressed in the fourth cylinder chamber (C 4 ) flows out from the discharge space ( 162 ) of the front head ( 157 ) to the space inside the casing ( 150 ).
  • the high-pressure refrigerant in the casing ( 150 ) is discharged from the casing ( 150 ) through the fourth discharge port pipe ( 155 - 4 ), and flows into the gas cooler ( 102 ) through the high-pressure refrigerant pipe (fourth discharge pipe) ( 187 ).
  • the pressure of the refrigerant is decreased to the intermediate pressure level by the first expansion valve ( 105 ), and such refrigerant flows into the gas-liquid separator ( 104 ).
  • the refrigerant is separated into gas and liquid in the gas-liquid separator ( 104 ), and the liquid refrigerant flows out from the gas-liquid separator ( 104 ).
  • the third compression mechanism ( 130 ) and the fourth compression mechanism ( 140 ) at the high-pressure stage are used in parallel in the first operational state, and, on the other hand, are used in series in the second operational state.
  • the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the first compression mechanism ( 110 ) and the second compression mechanism ( 120 ) are used in parallel in both of the first and second operational states, and the suction volume is not changed.
  • the suction volume at the low-pressure stage is the same between the first and second operational states, whereas the suction volume at the high-pressure stage is smaller in the second operational state than in the first operational state. That is, a suction amount at the low-pressure stage is the same between the first and second operational states, but a substantive suction amount at the high-pressure stage is smaller in the second operational state than in the first operational state.
  • the two compression mechanisms ( 130 , 140 ) at the high-pressure stage are used in parallel in the first operational state, and are used in series in the second operational state.
  • the ratio of the suction volume of the low-pressure compression mechanism to the suction volume of the high-pressure compression mechanism in the first and second operational states can be adjusted.
  • the volume ratio of the compressor ( 100 ) is switched depending on the operational conditions while performing an operation with high COP (coefficient of performance).
  • a torque variation due to the compression of refrigerant can be adjusted.
  • the foregoing embodiments may have the following configurations.
  • the volumes of the four cylinder chambers are different from each other.
  • the four cylinder chambers may be set to at least two suction volume levels.
  • the volume of the outer cylinder chamber (C 1 ) of the first compression mechanism ( 20 ) is the same as that of the outer cylinder chamber (C 3 ) of the second compression mechanism ( 30 )
  • the volume of the inner cylinder chamber (C 2 ) of the first compression mechanism ( 20 ) is the same as that of the inner cylinder chamber (C 4 ) of the second compression mechanism ( 30 ).
  • the volumes of the cylinder chambers (C 1 -C 4 ) may be the same except for the ninth embodiment.
  • the configuration of the compressor may be changed to any configurations as long as the compressor including the four cylinder chambers is used in the refrigerating apparatus.
  • a rolling piston compressor may be used, in which a blade and a piston are separated.
  • the three-way valve ( 7 ) is used in the first, second, fourth, and fifth embodiments, and the four-way valve ( 8 ) is used in the third embodiment.
  • a plurality of opening/closing valves solenoid valves may be combined and used.
  • an internal pressure of the casing ( 10 ) may be at any of low, high, and intermediate pressure levels.
  • the refrigerant circuit may be configured as necessary, thereby freely changing a setting of the internal pressure.
  • refrigerant filling the refrigerant circuit ( 60 , 180 ) may be refrigerant other than carbon dioxide (e.g., Freon refrigerant).
  • the injection pipe ( 68 , 185 ) is used as a cooling unit configured to cool refrigerant at an intermediate-pressure stage of the compressor ( 1 , 100 ), but a heat exchanger (intermediate cooler) may be used as the cooling unit.
  • the air conditioning apparatus performing the cooling operation has been described, but a target to which the present invention is applied is not limited to a unit only for cooling.
  • the first suction port pipe ( 14 - 1 ), the first discharge port pipe ( 15 - 1 ), the second suction port pipe ( 14 - 2 ), and the second discharge port pipe ( 15 - 2 ) may have the following configurations as illustrated in, e.g., FIGS. 49-62 .
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) includes a second discharge port a-pipe ( 15 - 2 a ) through which refrigerant is discharged from the second outer cylinder chamber (C 3 ), and a second discharge port b-pipe ( 15 - 2 b ) through which refrigerant is discharged from the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) is a single suction port pipe through which refrigerant is sucked into both of a first outer cylinder chamber (C 1 ) and a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) includes a first discharge port a-pipe ( 15 - 1 a ) through which refrigerant is discharged from the first outer cylinder chamber (C 1 ), and a first discharge port b-pipe ( 15 - 1 b ) through which refrigerant is discharged from the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) is a single suction port pipe through which refrigerant is sucked into both of a second outer cylinder chamber (C 3 ) and a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • a first suction port pipe ( 14 - 1 ) includes a first suction port a-pipe ( 14 - 1 a ) through which refrigerant is sucked into a first outer cylinder chamber (C 1 ), and a first suction port b-pipe ( 14 - 1 b ) through which refrigerant is sucked into a first inner cylinder chamber (C 2 ).
  • a first discharge port pipe ( 15 - 1 ) is a single discharge port pipe through which refrigerant is discharged from both of the first outer cylinder chamber (C 1 ) and the first inner cylinder chamber (C 2 ).
  • a second suction port pipe ( 14 - 2 ) includes a second suction port a-pipe ( 14 - 2 a ) through which refrigerant is sucked into a second outer cylinder chamber (C 3 ), and a second suction port b-pipe ( 14 - 2 b ) through which refrigerant is sucked into a second inner cylinder chamber (C 4 ).
  • a second discharge port pipe ( 15 - 2 ) is a single discharge port pipe through which refrigerant is discharged from both of the second outer cylinder chamber (C 3 ) and the second inner cylinder chamber (C 4 ).
  • the suction and discharge port pipes can be used in various combinations. Such combinations are arbitrarily selected, thereby adjusting the volume ratio.
  • the present invention is useful for the refrigerating apparatus for the two-stage compression refrigerant cycle.

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  • General Engineering & Computer Science (AREA)
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US13/121,541 2008-09-30 2009-09-08 Refrigerating apparatus Abandoned US20110179822A1 (en)

Applications Claiming Priority (5)

Application Number Priority Date Filing Date Title
JP2008254569 2008-09-30
JP2008-254569 2008-09-30
JP2008-334264 2008-12-26
JP2008334264A JP5040907B2 (ja) 2008-09-30 2008-12-26 冷凍装置
PCT/JP2009/004443 WO2010038360A1 (ja) 2008-09-30 2009-09-08 冷凍装置

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EP (1) EP2336675A4 (ja)
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Cited By (9)

* Cited by examiner, † Cited by third party
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US20170022988A1 (en) * 2014-04-10 2017-01-26 Gree Electric Appliances, Inc. Of Zhuhai Compressor and air conditioner
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US20170022988A1 (en) * 2014-04-10 2017-01-26 Gree Electric Appliances, Inc. Of Zhuhai Compressor and air conditioner
US10633784B2 (en) * 2014-05-29 2020-04-28 Qingdao Jiaonan Haier Washing Machine Co., Ltd. Heat pump dryer with dual-exhaust compressor system and control method thereof
US20170198428A1 (en) * 2014-05-29 2017-07-13 Qingdao Jiaonan Haier Washing Machine Co., Ltd. Heat pump dryer with dual-exhaust compressor system and control method thereof
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CN102159906A (zh) 2011-08-17
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