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    • 1. 发明申请
    • Refrigeration System
    • 制冷系统
    • US20100229582A1
    • 2010-09-16
    • US12224661
    • 2007-03-05
    • Masahiro YamadaTakahiro Yamaguchi
    • Masahiro YamadaTakahiro Yamaguchi
    • F25B27/00F25B41/00F25B43/00F25B1/10
    • F25B1/10F25B13/00F25B2313/02741F25B2400/05F25B2400/053F25B2400/13F25B2400/23F25B2500/01
    • A refrigerant circuit (20) is provided with an intermediate pressure heat exchanger (40) and a gas/liquid separator (51). In a cooling mode, a part of refrigerant condensed in an outdoor heat exchanger (36) flows into injection piping (43). The refrigerant admitted into the injection piping (43) is pressure reduced down to an intermediate pressure during its passage through an injection expansion valve (44), evaporates in the intermediate pressure heat exchanger (40), and is supplied to an intermediate pressure port (32) of a compressor (31). In a heating mode, refrigerant condensed in an indoor heat exchanger (71) is pressure reduced down to an intermediate pressure during its passage through an indoor expansion valve (72) and then flows into the gas/liquid separator (51). And, the intermediate pressure gas refrigerant within the gas/liquid separator (51) is supplied to the intermediate pressure port (32) of the compressor (31).
    • 制冷剂回路(20)设有中压热交换器(40)和气/液分离器(51)。 在冷却模式中,室外热交换器(36)中冷凝的一部分制冷剂流入注入管道(43)。 进入注入管道(43)的制冷剂在其通过注射膨胀阀(44)的过程中被压力降低到中间压力,在中压热交换器(40)中蒸发,并被供应到中间压力端口 32)。 在加热模式中,室内热交换器(71)中冷凝的制冷剂在通过室内膨胀阀(72)的过程中被压力降低到中间压力,然后流入气/液分离器(51)。 并且,气/液分离器51内的中压气体制冷剂被供给到压缩机31的中间压力口32。
    • 2. 发明授权
    • Refrigeration system
    • 制冷系统
    • US08225624B2
    • 2012-07-24
    • US12224420
    • 2007-03-06
    • Takahiro YamaguchiSatoshi IshikawaMasahiro YamadaKazuhiro Furusho
    • Takahiro YamaguchiSatoshi IshikawaMasahiro YamadaKazuhiro Furusho
    • F25B1/10F25B7/00
    • F04C23/001F04C18/02F04C18/045F04C18/322F04C23/008F04C29/0035F04C2270/03F04C2270/12F25B1/04F25B2400/075F25B2400/13
    • A compressor (20) is provided with compression mechanisms (61, 62) to have four compression chambers (61, 62, 63, 64) in total. In the compressor (20), the first compression chamber (61) and the second compression chamber (62) differ in the phase of capacity changing cycle from each other by 180° and the third compression chamber (63) and the fourth compression chamber (64) also differ in the phase of capacity changing cycle from each other by 180°. In a cylinder nonoperating mode, refrigerant is compressed in a single stage in each of the first compression chamber (61) and the second compression chamber (62) while the refrigerant compression operation is halted in the third compression chamber (63) and the fourth compression chamber (64). In a two-stage compression mode, refrigerant compressed in a single stage in each of the first compression chamber (61) and the second compression chamber (62) is further compressed in the third compression chamber (63) and the fourth compression chamber (64).
    • 压缩机(20)设置有压缩机构(61,62),其总共具有四个压缩室(61,62,63,64)。 在压缩机20中,第一压缩室61和第二压缩室62的容量变化周期的相位相差180°,第三压缩室63和第四压缩室( 64)在容量变化周期的相位相差180°时也不同。 在气缸非操作模式中,制冷剂在第一压缩室61和第二压缩室62的一个阶段中被压缩,同时制冷剂压缩操作在第三压缩室63中被停止,第四压缩 室(64)。 在两级压缩模式中,在第一压缩室61和第二压缩室62中的单级压缩的制冷剂在第三压缩室63和第四压缩室64中被进一步压缩 )。
    • 5. 发明申请
    • Refrigeration System
    • 制冷系统
    • US20090013714A1
    • 2009-01-15
    • US12224420
    • 2007-03-06
    • Takahiro YamaguchiSatoshi IshikawaMasahiro YamadaKazuhiro Furusho
    • Takahiro YamaguchiSatoshi IshikawaMasahiro YamadaKazuhiro Furusho
    • F25B1/10
    • F04C23/001F04C18/02F04C18/045F04C18/322F04C23/008F04C29/0035F04C2270/03F04C2270/12F25B1/04F25B2400/075F25B2400/13
    • A compressor (20) is provided with compression mechanisms (61, 62) to have four compression chambers (61, 62, 63, 64) in total. In the compressor (20), the first compression chamber (61) and the second compression chamber (62) differ in the phase of capacity changing cycle from each other by 180° and the third compression chamber (63) and the fourth compression chamber (64) also differ in the phase of capacity changing cycle from each other by 180°. In a cylinder nonoperating mode, refrigerant is compressed in a single stage in each of the first compression chamber (61) and the second compression chamber (62) while the refrigerant compression operation is halted in the third compression chamber (63) and the fourth compression chamber (64). In a two-stage compression mode, refrigerant compressed in a single stage in each of the first compression chamber (61) and the second compression chamber (62) is further compressed in the third compression chamber (63) and the fourth compression chamber (64).
    • 压缩机(20)设置有压缩机构(61,62),其总共具有四个压缩室(61,62,63,64)。 在压缩机20中,第一压缩室61和第二压缩室62的容量变化周期的相位相差180°,第三压缩室63和第四压缩室( 64)在容量变化周期的相位相差180°时也不同。 在气缸非操作模式中,制冷剂在第一压缩室61和第二压缩室62的一个阶段中被压缩,同时制冷剂压缩操作在第三压缩室63中被停止,第四压缩 室(64)。 在两级压缩模式中,在第一压缩室61和第二压缩室62中的单级压缩的制冷剂在第三压缩室63和第四压缩室64中被进一步压缩 )。