| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 101 | 使用压力产生装置的有摩擦限制滑动差速器 | CN200580010933.8 | 2005-02-07 | CN1942691A | 2007-04-04 | 石昌星 |
| 本发明涉及一种使用压力产生装置的有摩擦限制滑动差速器,用于执行汽车的滑动差速器功能,且同时通过在产生大的滑动差速时限制滑动差速器的部分功能,用于使汽车运动,以便使两个车轮平滑旋转,该差速器包括:本体部分(12),具有固定盖(11);第一侧部小齿轮(14),布置在所述本体部分(12)的内部,并与汽车的驱动轴连接;第二侧部小齿轮(13),与汽车的驱动轴可旋转地连接,并与第一侧部小齿轮(14)相对;一对差速器小齿轮(15、16),各差速器小齿轮与第一侧部小齿轮(14)和第二侧部小齿轮(13)啮合地旋转;摩擦板,布置在第一侧部小齿轮(14)和第二侧部小齿轮(13)的后侧;以及压力产生装置(20),构成为使其盖齿轮(22)和活塞齿轮(25)分别与第二侧部小齿轮(13)和第一侧部小齿轮(14)啮合,并能够沿该装置的纵向方向相互远离。 | ||||||
| 102 | 旋转密封压缩机和制冷循环系统 | CN200480018640.X | 2004-06-15 | CN1816697A | 2006-08-09 | 北市昌一郎; 渡边哲永; 富永健; 高岛和; 川边功; 铃木政行 |
| 本发明提供一种旋转密封压缩机,其第一气缸腔室(14a)的叶片受一弹性件(26)的推压和施力。第二气缸腔室(14b)里的叶片对应于被导入叶片室的壳体内的压力与被导入气缸腔室(14a、14b)内的吸气压力或排气压力之间的压力差而被推压和施力。一用于引导吸气压力或排气压力的压力转换机构(K)具有一分支管(P1)以及一第二开/关阀门29或单向阀(29A)。分支管(P1)的一端连接于制冷循环的高压侧而其另一端连接于吸气管,分支管(P1)还具有在其一中间部分上的一第一开/关阀门(28)。第二开/关阀门(29)设置在比分支管连接部分(D)更上游的一吸气管(16b)上,同时也位于比储气器里的回油口(24b)更下游的下游侧。 | ||||||
| 103 | 真空泵 | CN03147023.8 | 2003-09-09 | CN1495363A | 2004-05-12 | 藏本觉; 川口真广; 山本真也; 星野伸明; 井田昌宏 |
| 一真空泵,具有一主泵、一增压泵和一连接件。主泵具有一第一壳体和一容纳在第一壳体内的第一泵机构。增压泵具有一第二壳体和一容纳在第二壳体内的第二泵机构。增压泵和主泵顺序连接,从而将气体从增压泵传送到主泵。连接件将第一壳体和第二壳体彼此连接起来。连接件直接与围绕第一泵机构末级的第一壳体的一部分连接,从而将热量传送到该部分。 | ||||||
| 104 | 旋转式压缩机的主轴承 | CN85106950 | 1985-09-18 | CN85106950A | 1986-06-10 | 埃德温·L·甘纳韦 |
| 一种密封旋转式压缩机安装有改进的轴承(40),它在围绕轴承的圆周的等距离间隔的三个点(97)上和压缩机机壳(12)连接。压缩机缸筒(42)固定到轴承上。轴承压缩夹持在机壳内,从而机壳起弹簧的作用以使轴承外径尺寸的偏差能够被机壳的弹簧作用所适应。 | ||||||
| 105 | 包括吸入隔挡件的压缩机 | CN201320405488.7 | 2013-07-09 | CN203453064U | 2014-02-26 | 布雷德利·D·斯特朗; 凯勒·M·贝格曼; 基思·A·布朗 |
| 一种压缩机包括罩壳、支承壳体、压缩机构和吸入隔挡件。罩壳限定吸入压力区域和吸入气体入口。支承壳体在吸入压力区域内相对于罩壳固定。压缩机构位于罩壳内、支承在支承壳体上、且与吸入压力区域连通。吸入隔挡件位于吸入压力区域内并且包括:主体,该主体在径向上位于支承壳体与吸入气体入口之间;第一凸片,该第一凸片从主体的第一横向端延伸;以及第二凸片,该第二凸片从主体的第一横向端延伸且与第一凸片轴向地间隔开,以在第一凸片与第二凸片之间限定第一凹部。支承壳体限定在凹部内延伸的第一腿部。 | ||||||
| 106 | Electric compressor | US14867283 | 2015-09-28 | US10087759B2 | 2018-10-02 | Takuro Yamashita; Tatsuya Ito; Tetsuya Yamada |
| An electric compressor includes an inverter housing accommodating an inverter, a compressor housing accommodating a compression mechanism and an electric motor, and a seal member having an annular shape and interposed between an end surface of a peripheral wall of the compressor housing and an end surface of the inverter housing. The compressor housing has the peripheral wall in which the inverter is disposed. The seal member is retained to the inverter housing by a retaining structure which is disposed inside the peripheral wall of the compressor housing. The retaining structure includes a first projection and a second projection. The first projection is formed on the seal member and projects radially inward. The second projection is formed on the inverter housing. The first projection is located between the second projection and the end surface of the inverter housing so as to restrict movement of the seal member in a direction. | ||||||
| 107 | A MOTOR PUMP AND CONTROL MANIFOLD ASSEMBLY | US15762589 | 2016-09-23 | US20180266417A1 | 2018-09-20 | Andries Broekx; Paul Leadley |
| A motor pump assembly is provided that comprises a motor, a drive shaft connected to the motor, a pump and control manifold including means for controlling fluid flow to and/or from the pump. The motor, drive shaft, pump and manifold are contained within a single common housing. The manifold forms an integral part of the housing and includes a pump chamber that contains the pump. | ||||||
| 108 | Compressor system | US14815405 | 2015-07-31 | US10072673B2 | 2018-09-11 | Justinn B. Eddie |
| A gas compressor system is disclosed. The gas compressor system includes a dryer assembly, a receiver tank, and at least one support level. The at least one support level has two slide channels supported by two beams. A platform is slidably attached to the slide channels. An isolator is disposed between each of the slide channels and the beams. A compressor is mounted to each platform. | ||||||
| 109 | OIL-LUBRICATED SLIDE VANE ROTARY VACUUM PUMP WITH OIL SEPARATING AND RECONDITIONING DEVICE | US15575055 | 2016-05-17 | US20180142554A1 | 2018-05-24 | Artjom KRAFT; Islam AKYILDIZ; Markus LOEBEL; Frank RISCHEWSKI |
| An oil-lubricated slide vane rotary vacuum pump with a slide vane unit, and with an oil separating and reconditioning device, wherein oil and gas are separated by separating devices, possibly complemented by oil coolers and/or oil pumps. One or more monitoring and/or servicing devices are provided, and the oil separating and reconditioning device is installed in an oil separating and reconditioning housing. Side walls extend transversely to a plane of rotation of a slide vane rotor, and define a longitudinal extent of the oil separating and reconditioning housing. The one or more monitoring and/or servicing devices are arranged only in one or more cover parts which are attached to one or both end walls of the oil separating and reconditioning housing. The oil separating and reconditioning housing is formed with the side walls, the bottom wall and the top wall without being configured for a monitoring and/or servicing device. | ||||||
| 110 | Skeleton base for a compressor system | US14957740 | 2015-12-03 | US09777882B2 | 2017-10-03 | Ritesh Kumar Mistry |
| A compressor system is disclosed with a skeleton base structure configured to support a compressor. The skeleton base includes a first portion and a second portion configured to support the compressor system. The first portion includes a lower elongate support leg extending along a longitudinal direction, a support platform spaced above the lower support leg, and an open space formed between the lower support leg and the support platform. The second portion includes an extension beam projecting along the longitudinal direction from the first portion and a cross member support positioned transversely across the extension beam. | ||||||
| 111 | Compressor Mounting System | US15614857 | 2017-06-06 | US20170268493A1 | 2017-09-21 | William C. Maier |
| A mounting system for an industrial compression system including a first component close-coupled to a second component includes a first support for the first component. The first support is configured to resist movement of the first component in a first direction substantially horizontal relative to the first component, a second direction substantially vertical relative to the first component, and an axial direction relative to the first component. The mounting system also includes a second support for the second component. The second support is configured to resist movement of the second component in a first direction substantially horizontal relative to the second component and a second direction substantially vertical relative to the second component, wherein the second support permits movement of the second component in an axial direction relative to the second component. | ||||||
| 112 | Screw Spindle Pump | US15114483 | 2015-01-22 | US20170114785A1 | 2017-04-27 | Thomas Eschner |
| The invention relates to a screw spindle pump, with a housing (2) which surrounds a delivery chamber (5), two spindles (7, 8), namely a drive spindle (7) and an opposed running spindle (8), a housing insert (6) which is arranged in the housing (2) and in which the spindles (7, 8) are accommodated, at least one bearing element (13′, 13″), which is connected to the housing insert (6) and on which bearings (12) of the spindles (7, 8) are arranged, and with at least one housing cover (14′, 14″), closing a housing opening. It is the object of the invention to provide a screw spindle pump at which maintenance and inspection work can be carried out more simply and cost-effectively. The invention achieves this object in that the bearing element (13′, 13″) together with the housing insert (6) and the spindles (7, 8) accommodated therein forms a unit (15) which, after the housing cover (14′, 14″) is taken off, is removable from the housing (2) through the housing opening. | ||||||
| 113 | Fluid machine | US14126128 | 2012-06-12 | US09546656B2 | 2017-01-17 | Shinji Nakamura; Hirofumi Wada; Yuuta Tanaka; Yasuhiro Furusawa |
| The present invention relates to a fluid machine. A pump integrated expander (29A) includes a pump unit (60) and an expansion unit (50). In the pump unit (60), a casing member (65) supports a gear pump (61), a rotating shaft (28) and a driven crank mechanism (81). In the expansion unit (50), a casing including a main body (51a) and a casing member (54) supports an expander (23) including a fixed scroll (51) and an orbiting scroll (52). The pump integrated expander (29A) is divided into the pump unit (60) and the expansion unit (50) by separating at the fitted portion of a tubular portion (65c) on the pump unit (60) side and a smaller inner diameter portion (54b) on the expansion unit (50) side and by pulling the eccentric bush (83) out of a drive bearing (56). | ||||||
| 114 | SUCTION/COMPRESSION ASSEMBLY FOR A WASTE MATERIAL INTAKE EQUIPMENT OR SYSTEM | US15184786 | 2016-06-16 | US20160369800A1 | 2016-12-22 | DANILO SANTAROSSA |
| The invention relates to a suction/compression assembly for aspirating/compressing gases from/in a system to/from an external environment. The assembly includes an operating machine comprising a body, which defines a chamber, within which one or more rotors are housed, rotating about a corresponding rotation axis. Such a chamber has a symmetrical transverse section evaluated on a plane with respect to at least one first reference plane on which said rotation axis lies. The assembly comprises a device for injecting gas into said chamber which comprises a manifold, connectable to an external source, and a plurality of injection pipes connected to the manifold and to the body of the machine. The body defines a plurality of injection passages, each of which is configured to make one of said injection pipes communicating with the chamber of the machine. | ||||||
| 115 | Compressed air device for allowing the expeditious adjustment of drive belts | US14517084 | 2014-10-17 | US09416854B2 | 2016-08-16 | William Gregory Hood; Timothy Eugene Hornbuckle; Harold Edward Massey |
| The present invention provides methods and systems for a device for producing compressed air that allows for the expeditious adjustment of a drive belt that includes a base having a substantially triangular shape with at least a first side having a top portion and a bottom portion, a second side having a top portion and a bottom portion, and a third side having a top portion and a bottom portion. The first side, second side, and third side collectively form a cavity therein. A motor is disposed within the cavity of the base and engaged to the first side of the base. A first compressor is slidingly engaged to the second side of the base and a second compressor is slidingly engaged to the third side of the base. | ||||||
| 116 | Compressor motor and electric compressor including the same | US13817252 | 2011-12-19 | US09404503B2 | 2016-08-02 | Takayuki Watanabe; Masashi Kuroko; Kazutaka Nakamura |
| Provided is a compressor motor that can achieve reduction in length of a motor lead wire, compactification of a motor housing, and reduction in size and weight of an electric compressor, and also provided is an electric compressor including the compressor motor. A cluster block (39) that is connected to a stator coil end of a motor (10) via a motor lead wire is placed in an outer circumferential region of a stator coil end cover (38) or a bobbin (37A) of the motor (10) such that a terminal connection port of the cluster block (39) faces an outer circumferential side. An opening (34) and a placement bearing surface (35) for inserting and placing a hermetic terminal (8) are provided in an outer circumferential region of a motor housing (4), the outer circumferential region facing the cluster block (39) provided on the motor (10) side. The hermetic terminal (8) is inserted and placed from an outer circumferential side of the motor housing (4) to the opening (34) and the placement bearing surface (35), to be thereby made directly connectable to the terminal connection port of the cluster block (39). | ||||||
| 117 | Sub-frame integration of motor-compressor systems | US13628154 | 2012-09-27 | US09366268B2 | 2016-06-14 | William C. Maier; Jose L. Gilarranz |
| Apparatus and methods for supporting a compression system are provided. The apparatus includes a compressor support coupled to a compressor, and a motor support coupled to a motor, the motor and the compressor being stand-alone units and having a shaft extending therebetween. The apparatus also includes a subframe connector coupled to the compressor support and the motor support and configured to prevent radial and axial misalignment of the shaft. | ||||||
| 118 | Oil free compressor system | US13528060 | 2012-06-20 | US09328731B2 | 2016-05-03 | Toshiaki Yabe; Natsuki Kawabata; Masakatsu Okaya; Kohei Sakai |
| An oil free compressor includes a cooling fan, a low-pressure stage air-cooled heat exchanger, a high-pressure stage air-cooled heat exchanger, and a lubricating oil air-cooled heat exchanger. The cooling fan is provided independently from each of the low-pressure stage air-cooled heat exchanger, the high-pressure stage air-cooled heat exchanger, and the lubricating oil air-cooled heat exchanger. | ||||||
| 119 | ELECTRIC COMPRESSOR | US14867283 | 2015-09-28 | US20160090987A1 | 2016-03-31 | Takuro YAMASHITA; Tatsuya ITO; Tetsuya YAMADA |
| An electric compressor includes an inverter housing accommodating an inverter, a compressor housing accommodating a compression mechanism and an electric motor, and a seal member having an annular shape and interposed between an end surface of a peripheral wall of the compressor housing and an end surface of the inverter housing. The compressor housing has the peripheral wall in which the inverter is disposed. The seal member is retained to the inverter housing by a retaining structure which is disposed inside the peripheral wall of the compressor housing. The retaining structure includes a first projection and a second projection. The first projection is formed on the seal member and projects radially inward. The second projection is formed on the inverter housing. The first projection is located between the second projection and the end surface of the inverter housing so as to restrict movement of the seal member in a direction. | ||||||
| 120 | COMPRESSOR SYSTEM | US14815405 | 2015-07-31 | US20160032943A1 | 2016-02-04 | Justinn B. Eddie |
| A gas compressor system is disclosed. The gas compressor system includes a dryer assembly, a receiver tank, and at least one support level. The at least one support level has two slide channels supported by two beams. A platform is slidably attached to the slide channels. An isolator is disposed between each of the slide channels and the beams. A compressor is mounted to each platform. | ||||||
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