| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 1 | 压缩机声音抑制 | CN200580048983.5 | 2005-03-07 | CN101137824B | 2010-05-12 | S·L·舒尔德斯 |
| 一种压缩机设备具有止回阀(70),该止回阀具有允许沿着流动路径向下游流动的第一状态和阻止反向流动的第二状态。阀元件包括共振器(112)。 | ||||||
| 2 | 压缩机 | CN98122937.9 | 1998-11-27 | CN1083534C | 2002-04-24 | 木村直文; 中本昭; 鸿村哲志; 大林正和 |
| 有旋转件的压缩机,包括驱动轴(18)和斜盘(34)。活塞(31)压缩气体使旋转件扭振。减振器(48)联于该轴以减小旋转件扭振,其固有频率基本等于旋转件的,包括连于轴的金属销(49),连于旋转件的重块(51)和设于轴和重块间的橡胶体(50)。销用作沿扭振方向作用的弹簧,其弹簧常数在压缩机运转温度范围内基本相同。重块经销跟旋转件一起扭振以抵消后者扭振。减振器固有频率主要由重块质量和销的弹簧常数确定。橡胶体吸收旋转件的扭振,其弹簧常数小于销的,使减振器固有频率基本不受橡胶体影响。 | ||||||
| 3 | 压缩机 | CN98122937.9 | 1998-11-27 | CN1222645A | 1999-07-14 | 木村直文; 中本昭; 鸿村哲志; 大林正和 |
| 有旋转件的压缩机,包括驱动轴(18)和斜盘(34)。活塞(31)压缩气体使旋转件扭振。减振器(48)联于该轴以减小旋转件扭振,其固有频率基本等于旋转件的,包括连于轴的金属销(49),连于旋转件的重块(51)和设于轴和重块间的橡胶体(50)。销用作沿扭振方向作用的弹簧,其弹簧常数在压缩机运转温度范围内基本相同。重块经销跟旋转件一起扭振以抵消后者扭振。减振器固有频率主要由重块质量和销的弹簧常数确定。橡胶体吸收旋转件的扭振,其弹簧常数小于销的,使减振器固有频率基本不受橡胶体影响。 | ||||||
| 4 | 涡旋压缩机 | CN201010144905.8 | 2010-03-29 | CN102003389A | 2011-04-06 | 饭塚敏; 杉本和禧 |
| 本发明提供一种能够省时省力地降低刺耳的频率的噪声级的涡旋压缩机。在密闭容器(1)内设有涡旋压缩要素(2)与电动要素(3)。涡旋压缩要素(2)包括:竖立设置有涡旋状的卷板(17)的固定涡盘(14);在电动要素(3)的旋转轴的作用下相对于固定涡盘(14)回旋运动、且竖立设置有涡旋状的卷板(21)的摆动涡盘(15)。通过使由两个卷板(17、21)相互啮合形成的多个压缩空间(25)从外侧朝向内侧逐渐缩小,而对制冷剂进行压缩,并将压缩后的制冷剂向密闭容器(1)内的喷出压力空间(11)喷出。具有:形成于固定涡盘(14)并将压缩空间(25)与喷出压力空间(11)连通的贯通孔(32);设置在固定涡盘(14)的喷出压力空间(11)侧并对贯通孔(32)进行开闭的常闭的溢流阀(35),其中,贯通孔(32)的深度尺寸设为与噪声峰值频率的波长相对应的值。 | ||||||
| 5 | 压缩机声音抑制 | CN200580048983.5 | 2005-03-07 | CN101137824A | 2008-03-05 | S·L·舒尔德斯 |
| 一种压缩机设备具有止回阀(70),该止回阀具有允许沿着流动路径向下游流动的第一状态和阻止反向流动的第二状态。阀元件包括共振器(112)。 | ||||||
| 6 | Microsystems for converting pressures and compression | US13321977 | 2010-05-25 | US08764422B2 | 2014-07-01 | Thierry Hilt |
| The invention relates to a microsystem for converting a difference in pressures in a fluid into mechanical movement, this microsystem comprising: —an inlet nozzle (6) for compressed fluid and an outlet nozzle (8) for expanded fluid, —at least two arms (12, 14), at least one of which is hinged and between which flows the fluid in order to pass from the inlet nozzle to the outlet nozzle by moving these arms with respect to one another, the arms (12, 14) being designed and hinged such that, while they move, they define at least one pocket of fluid which is moved away from the inlet nozzle in order then to return to the outlet nozzle while at the same time increasing in volume, each of the arms (12, 14) being mechanically connected to a single plane (20). | ||||||
| 7 | MICROSYSTEMS FOR CONVERTING PRESSURES AND COMPRESSION | US13321977 | 2010-05-25 | US20120068474A1 | 2012-03-22 | Thierry Hilt |
| The invention relates to a microsystem for converting a difference in pressures in a fluid into mechanical movement, this microsystem comprising:—an inlet nozzle (6) for compressed fluid and an outlet nozzle (8) for expanded fluid,—at least two arms (12, 14), at least one of which is hinged and between which flows the fluid in order to pass from the inlet nozzle to the outlet nozzle by moving these arms with respect to one another, the arms (12, 14) being designed and hinged such that, while they move, they define at least one pocket of fluid which is moved away from the inlet nozzle in order then to return to the outlet nozzle while at the same time increasing in volume, each of the arms (12, 14) being mechanically connected to a single plane (20). | ||||||
| 8 | SCROLL COMPRESSOR | US12756615 | 2010-04-08 | US20110052437A1 | 2011-03-03 | Satoshi Iitsuka; Kazuyoshi Sugimoto |
| There is disclosed a scroll compressor which can lower the noise level of a harsh frequency without taking a lot of troubles. In a sealed container, a scroll compression element and an electromotive element are provided. The scroll compression element is constituted of a fixed scroll including a vertically provided spiral lap, and a swingable scroll including a vertically provided spiral lap and swiveled by a rotary shaft of the electromotive element with respect to the fixed scroll. A refrigerant compressed by gradually reducing, from the outside to the inside, a plurality of compression spaces formed by engaging both the laps with each other is discharged to a discharge pressure space in the sealed container. The scroll compressor further includes through holes formed in the fixed scroll to connect the compression spaces to the discharge pressure space, and normally closed relief valves provided in the fixed scroll on the side of the discharge pressure space to open and close the through holes, and the depth dimension of each of the through holes is set to a value corresponding to the wavelength of a noise peak frequency. | ||||||
| 9 | Microsystems for compressing or for converting a pressure difference into a displacement | US13988783 | 2011-11-16 | US09200624B2 | 2015-12-01 | Thierry Hilt |
| A microsystem for converting pressure difference in fluid into mechanical displacement includes input and output nozzles, two interleaved parts, one of which is mobile part, between which the fluid flows. During displacement, the parts define an expanding fluid pocket that moves from the input nozzle to the output nozzle. The micro-system also includes top and bottom planes between which the mobile part is mounted for displacement relative to each plane, an overhanging distal portion along which the fluid flows, and a proximal portion mechanically linked to a plane via a link allowing only longitudinal translation of the proximal portion, and a reinforcement including a first side fastened to one of the planes and, a second side that is either fastened to or in sliding contact with the overhanging distal portion of the mobile part to limit its deformation in a transverse direction perpendicular to the longitudinal direction. | ||||||
| 10 | Scroll compressor having through holes with a set depth | US12756615 | 2010-04-08 | US08475148B2 | 2013-07-02 | Satoshi Iitsuka; Kazuyoshi Sugimoto |
| There is disclosed a scroll compressor which can lower the noise level of a harsh frequency without taking a lot of troubles. In a sealed container, a scroll compression element and an electromotive element are provided. The scroll compression element is constituted of a fixed scroll including a vertically provided spiral lap, and a swingable scroll including a vertically provided spiral lap and swiveled by a rotary shaft of the electromotive element with respect to the fixed scroll. A refrigerant compressed by gradually reducing, from the outside to the inside, a plurality of compression spaces formed by engaging both the laps with each other is discharged to a discharge pressure space in the sealed container. | ||||||
| 11 | Device for regulating compressors or aspirators | US10156828 | 2002-05-30 | US20030044295A1 | 2003-03-06 | Ennio Cattani |
| In a delivery conduit for a compressor or an aspiration conduit for an aspirator, which connects the compressor or the aspirator to a closed environment, a first valve is inserted, and opening and a closing of which is commanded by a temperature of an external environment. The valve is normally closed for external temperatures which are lower than a predetermined level and open, placing the conduit in communication with the outside environment, when the external temperature exceeds the predetermined level. | ||||||
| 12 | Wheel with electromechanical conversion system | US13322017 | 2010-05-25 | US08607627B2 | 2013-12-17 | Thierry Hilt; Bruno Mourey |
| A wheel includes a tire, an electrical device requiring power for operation, and a conversion system for providing electrical energy for powering the electrical device. The electrical energy is obtained from conversion of a difference between pressure of a gas confined under pressure within the tire and ambient pressure of air outside the tire. The conversion system includes an inlet nozzle fluidly connected to the gas confined under pressure in the tire, an outlet nozzle fluidly connected to the air outside the tire, a movable arm configured to be moved by gas expanding while flowing from the inlet nozzle to the outlet nozzle, and an electromechanical transducer capable of converting mechanical energy from movement of the arm into electrical energy used to power the electrical device. | ||||||
| 13 | MICROSYSTEMS FOR COMPRESSING OR FOR CONVERTING A PRESSURE DIFFERENCE INTO A DISPLACEMENT | US13988783 | 2011-11-16 | US20130259715A1 | 2013-10-03 | Thierry Hilt |
| A microsystem for converting pressure difference in fluid into mechanical displacement includes input and output nozzles, two interleaved parts, one of which is mobile part, between which the fluid flows. During displacement, the parts define an expanding fluid pocket that moves from the input nozzle to the output nozzle. The microsystem also includes top and bottom planes between which the mobile part is mounted for displacement relative to each plane, an overhanging distal portion along which the fluid flows, and a proximal portion mechanically linked to a plane via a link allowing only longitudinal translation of the proximal portion, and a reinforcement including a first side fastened to one of the planes and, a second side that is either fastened to or in sliding contact with the overhanging distal portion of the mobile part to limit its deformation in a transverse direction perpendicular to the longitudinal direction. | ||||||
| 14 | Compressor sound suppression | US11813767 | 2005-03-07 | US08162622B2 | 2012-04-24 | Stephen L. Shoulders |
| A compressor apparatus (20) has a housing (22) having first (53) and second (58) ports along a flowpath. One or more working elements (26; 28) cooperate with the housing (22) to define a compression path between suction (60) and discharge (62) locations along the flowpath. A check valve (70; 170; 270) has a valve element (72; 172; 272) mounted for movement between a first condition permitting downstream flow along the flowpath and a second condition blocking a reverse flow. The valve element includes a resonator (112; 174; 274). | ||||||
| 15 | WHEEL | US13322017 | 2010-05-25 | US20120067116A1 | 2012-03-22 | Thierry Hilt; Bruno Mourey |
| This wheel is equipped with a tyre and an electric device (100), which needs to be supplied with power in order to operate. The device comprises a system (200) for converting the difference in pressure between the pressurized gas inside the tyre and the free air outside the tyre into electric power used for supplying the electric device. | ||||||
| 16 | Compressor Sound Suppression | US11813767 | 2005-03-07 | US20080260546A1 | 2008-10-23 | Stephen L. Shoulders |
| A compressor apparatus having a check valve (70) having a first condition permitting downstream flow along the flowpath and a second condition blocking a reverse flow. The valve element includes a resonator (112). | ||||||
| 17 | Device for regulating compressors or aspirators | US10156828 | 2002-05-30 | US06817842B2 | 2004-11-16 | Ennio Cattani |
| In a delivery conduit for a compressor or an aspiration conduit for an aspirator, which connects the compressor or the aspirator to a closed environment, a first valve is inserted, and opening and a closing of which is commanded by atemperature of an external environment. The valve is normally closed for external temperatures which are lower than a predetermined level and open, placing the conduit in communication with the outside environment, when the external temperature exceeds the predetermined level. | ||||||
| 18 | Compressor | US187724 | 1998-11-05 | US6092997A | 2000-07-25 | Naofumi Kimura; Akira Nakamoto; Masakazu Obayashi; Satoshi Koumura |
| A compressor having a rotating member, which includes a drive shaft and a swash plate. A piston compresses gas and torsionally vibrates the rotating member. A damper is coupled to the shaft to reduce torsional vibrations of the rotating member. The natural frequency of the damper is substantially equal to that of the rotating member. The damper includes a metal pin coupled to the shaft, a weight coupled to the rotating member, and a rubberlike body arranged between the shaft and the weight. The pin functions as a spring acting in the direction of the torsional vibrations and has a spring constant that remains substantially the same within the operating temperature range of the compressor. The weight is vibrated torsionally with the rotating member by the pin to offset the torsional vibrations of the rotating member. The natural frequency of the damper is determined mainly by the mass of the weight and the spring constant of the pin. The rubberlike body absorbs the torsional vibrations of the rotating member and has a spring constant smaller than that of the pin such that the natural frequency of the damper is substantially unaffected by the rubberlike body. | ||||||
| 19 | wheel | JP2012512345 | 2010-05-25 | JP5587988B2 | 2014-09-10 | イルト ティエリ; ムレー ブリュノ |
| 20 | Enclosed compressor | JP2008315715 | 2008-12-11 | JP2009162222A | 2009-07-23 | TOMIOKA NAOTO; YANAGISAWA MASANORI; MORIMOTO MITSUKI; OGASAWARA HIROSUKE |
| PROBLEM TO BE SOLVED: To provide an enclosed compressor provided with a structure capable of inhibiting variation in the supported height of an accumulator relative to a support base in fixing the accumulator or an intake muffler to a casing. SOLUTION: A support base 200A includes a base 201 and a pair of support sections 210, 220. The base 201 is formed in a gentle curve so as to extend along the circumferential direction (arrow A in figure) of an outer peripheral surface of the casing. The support section 210 includes an upstanding section 211 upstanding at an angle of approximately 90 degrees from the base 201 and also a receiving section 212 bent from the base 201 in a direction in which the receiving section 212 separates away from the base 201. A circular engaging hole 213 is formed in the head part of the receiving section 212. Further, in a substantially center region in a height direction (h in figure) of the receiving section 212, a projection 214 is provided at a location which is a portion of contact with a barrel of the accumulator. COPYRIGHT: (C)2009,JPO&INPIT | ||||||
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