会员体验
专利管家(专利管理)
工作空间(专利管理)
风险监控(情报监控)
数据分析(专利分析)
侵权分析(诉讼无效)
联系我们
交流群
官方交流:
QQ群: 891211   
微信请扫码    >>>
现在联系顾问~
热词
    • 91. 发明申请
    • AIR CONDITIONING APPARATUS
    • 空调设备
    • US20110000240A1
    • 2011-01-06
    • US12919045
    • 2009-02-25
    • Takurou YamadaMasato KotakeTakahiro YamaguchiTadafumi Nishimura
    • Takurou YamadaMasato KotakeTakahiro YamaguchiTadafumi Nishimura
    • F25B49/00
    • F25B49/005F25B13/00F25B2700/04
    • An air conditioning apparatus includes a refrigerant circuit, an operation controlling device and a liquid refrigerant accumulation determining device. The refrigerant circuit has an accumulator. The operation controlling device performs normal operation control where each device of the heat source unit and the utilization unit are controlled in accordance with operating load of the utilization unit, and refrigerant quantity determination operation control where properness of quantity of the refrigerant in the refrigerant circuit is determined while performing the cooling operation. The liquid refrigerant accumulation determining device determines whether or not liquid refrigerant is accumulating in the accumulator. When it has been determined that liquid refrigerant is accumulating in the accumulator, liquid refrigerant accumulation control is performed to eliminate liquid refrigerant accumulation in the accumulator.
    • 空调装置包括制冷剂回路,运转控制装置和液体制冷剂积存判定装置。 制冷剂回路具有蓄能器。 操作控制装置执行正常操作控制,其中根据利用单元的操作负荷来控制热源单元和利用单元的每个装置,以及制冷剂量确定操作控制,其中制冷剂回路中的制冷剂的适当性为 在执行冷却操作时确定。 液体制冷剂积存确定装置确定液体制冷剂是否积聚在蓄能器中。 当已经确定液体制冷剂积聚在蓄液器中时,进行液体制冷剂积聚控制以消除储液器中的液体制冷剂积聚。
    • 92. 发明申请
    • AIR CONDITIONING APPARATUS AND REFRIGERANT QUANTITY DETERMINATION METHOD
    • 空调设备和制冷剂数量测定方法
    • US20110000234A1
    • 2011-01-06
    • US12918911
    • 2009-02-26
    • Tadafumi NishimuraTakahiro Yamaguchi
    • Tadafumi NishimuraTakahiro Yamaguchi
    • F25B45/00
    • F25B49/005F25B13/00F25B2313/02741F25B2400/13F25B2500/19F25B2500/222F25B2600/2501F25B2600/2509F25B2700/04F25B2700/2115F25B2700/21152
    • An air conditioning apparatus and a refrigerant quantity determination method are provided, whereby a refrigerant quantity can be determined in a simple and accurate manner without compromising the reliability of a compressor. A refrigerant circuit (10) has a compressor (21), an outdoor heat exchanger (23) that functions as a condenser, an indoor expansion valve (41, 51), an indoor heat exchanger (42, 52) that functions as an evaporator, an indoor unit interconnection pipe (4b, 5b), a liquid refrigerant connection pipe (6), a gas refrigerant connection pipe (7), and an outdoor unit interconnection pipe (8). A controller (9) performs liquefaction control for liquefying refrigerant and placing the refrigerant in a portion extending from the indoor expansion valve (41, 51) to the outdoor heat exchanger (23). The controller (9) directly or indirectly regulates the flow rate of refrigerant flowing through a liquid bypass circuit (70) from a liquid reserving portion (Q) toward the gas refrigerant connection pipe (7). A liquid level detection sensor (39) detects at least one of either a volume of liquid refrigerant in the portion where liquid refrigerant accumulates and a physical quantity equivalent to the volume.
    • 提供一种空调装置和制冷剂量确定方法,由此可以简单而准确地确定制冷剂量,而不会影响压缩机的可靠性。 制冷剂回路(10)具有作为冷凝器的压缩机(21),室外热交换器(23),室内膨胀阀(41,51),作为蒸发器起作用的室内热交换器(42,52) 室内单元互连管(4b,5b),液体制冷剂连接管(6),气体制冷剂连接管(7)和室外单元互连配管(8)。 控制器(9)进行用于液化制冷剂的液化控制,并且将制冷剂置于从室内膨胀阀(41,51)延伸到室外热交换器(23)的部分。 控制器(9)直接或间接地调节从储液部分(Q)流向液体旁路回路(70)的制冷剂流向气体制冷剂连接管(7)的流量。 液面检测传感器(39)检测液体制冷剂积聚的部分中的液体制冷剂的体积和与体积相当的物理量中的至少一个。
    • 94. 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。
    • 97. 发明申请
    • COLLISION PREVENTING DEVICE INCORPORATED IN NUMERICAL CONTROL APPARATUS
    • 数字控制装置中的防撞保护装置
    • US20100087948A1
    • 2010-04-08
    • US12573611
    • 2009-10-05
    • Takahiro Yamaguchi
    • Takahiro Yamaguchi
    • G05B19/4061G06G7/66
    • G05B19/4061G05B19/4069
    • A collision preventing device includes an acceleration/deceleration simulating unit 30 that performs acceleration/deceleration processing based on a moving command generated by a function generation unit 16 according to a method similar to that used by acceleration/deceleration units 18x and 18z and obtains a moving path resulting from the acceleration/deceleration processing, an interference check unit 34 that performs interference check between a mobile member and an interfering object along the moving path generated by the acceleration/deceleration simulating unit 30 and determines whether any interference may occur, a delay unit 32 that successively stores moving commands generated by the function generation unit 16 and successively outputs a moving command having been stored a predetermined time before, and a moving command blocking unit 36 that sends the moving command output from the delay unit 32 to the acceleration/deceleration units 18x and 18z if the interference check unit 34 determines that there is no interference, and blocks the moving command to be sent from the delay unit 32 to the acceleration/deceleration units 18x and 18z if the interference check unit 34 determines that interference may occur.
    • 防碰撞装置包括加速/减速模拟单元30,该加速/减速模拟单元30根据与加速/减速单元18x和18z所使用的方法类似的方法,基于由功能生成单元16生成的移动指令进行加速/减速处理,并获得移动 由加速/减速处理产生的路径的干扰检查单元34,执行沿着由加速/减速模拟单元30产生的移动路径的移动构件和干扰物体之间的干涉检查,并且确定是否存在干扰可以发生延迟单元 32,其连续地存储由功能生成单元16生成的运动指令,并连续地输出已经存储了预定时间的移动命令;以及移动指令阻止单元36,其将从延迟单元32输出的移动命令发送到加速/减速 单位18x和18z如果干扰检查单位 34确定没有干扰,并且如果干扰检查单元34确定可能发生干扰,则阻止将从延迟单元32发送到加速/减速单元18x和18z的移动命令。
    • 99. 发明申请
    • Ion Nitriding Method
    • 离子渗氮法
    • US20090314389A1
    • 2009-12-24
    • US11989930
    • 2006-08-04
    • Kazuo MinemuraTakahiro Yamaguchi
    • Kazuo MinemuraTakahiro Yamaguchi
    • C23C8/36
    • F01L3/02C23C8/02C23C8/36C23C8/38F01L3/04F01L2101/00
    • When a metal material such as an Fe alloy or Ni alloy is heated in the presence of an amino resin such as a melamine-formalin resin, a passivation film on the surface of the metal material is reduced and removed. During the reduction and removal of the passivation film, hydrogen sputtering may be also performed when the temperature becomes higher than 400° C., preferably not less than 450° C. By performing a glow discharge, the metal material having an exposed active metal surface is nitrided with N liberated from the amino resin. For example, the amino resin is applied onto the surface of the metal material directly or by using a solvent such as water.
    • 当在诸如三聚氰胺 - 福尔马林树脂之类的氨基树脂的存在下加热诸如Fe合金或Ni合金的金属材料时,金属材料表面上的钝化膜被减少和去除。 在钝化膜的还原和去除期间,当温度变得高于400℃,优选不低于450℃时也可以进行氢溅射。通过进行辉光放电,具有暴露的活性金属表面的金属材料 与从氨基树脂释放的N被氮化。 例如,将氨基树脂直接或通过使用溶剂如水施加到金属材料的表面上。