| 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 | 液动力机器的轴同辐流式轮体,包括该轮体的液动力机器和该轮体的组装方法 | CN200980141507.6 | 2009-09-04 | CN102187084A | 2011-09-14 | Y·布韦; F·陶希; L·马蒂厄; G·罗西 |
| 用于液动力机器的轴同辐流式轮体包括:围绕轮体的中心轴线转动对称的一环带体,围绕该轴线转动对称的一顶板体,和在顶板体和环带体之间延伸的多个叶片(21,22)。此外,轮体包括部分地确定至少环带体和/或顶板体的至少两个元件(41,42,43,61,62,63),以及一叶片(21,22)的至少一个边部(231,232,241,242)嵌接在确定环带体和/或顶板体的两元件之间。 | ||||||
| 2 | 冲击式风力发电装置 | CN201010623950.1 | 2010-12-31 | CN102052255A | 2011-05-11 | 郭文礼 |
| 本发明属于风电技术领域,公开了一种冲击式风力发电装置,包括垂直轴冲击式风力发电装置和水平轴冲击式风力发电装置,该两种类型的冲击式风力发电装置利用多级冲动叶片的动力转子机构,最大限度的利用了来风的能量,提高了风能利用率;利用高位排风管的高度差及侧向排风,可以加大来风的能量,即使在晴朗无风的天气,动力转子也可低负荷发电;可以做成单机功率大、体积小的发电机组,便于运输和安装,维护,大大降低了风力发电装置的单位发电量的投资成本;垂直轴式可接受任意方向的来风,没有复杂的变桨距系统,传动系统和发电机可放置在地面,便于操作维护;克服了风能利用率低,动力转子难启动的缺点。 | ||||||
| 3 | 压缩机及涡轮制冷机 | CN201380067583.3 | 2013-07-26 | CN104884817B | 2017-03-08 | 古贺淳; 大村真太郎 |
| 本发明提供一种压缩机及涡轮制冷机。本发明的压缩机(2)具备:旋转轴(12);多个叶轮,安装于旋转轴;主流路,将流体从前级的叶轮导向后级的叶轮;腔室(31),呈以轴线为中心的环状,且与主流路连通;吸入喷嘴(32),将流体从外周侧朝向内周侧导入到腔室;可动翼片,在主流路内沿轴线的周向间隔设置有多个,且通过可动来调整在主流路内流通的流体的流量;及驱动机构一侧,并改变多个可动翼片的角度,其中,吸入喷嘴(32)朝向周向另一侧倾斜,以使在腔室(31)内的周向一侧及周向另一侧中流向周向另一侧的流体的流量增加。(42),设置于腔室(31)内的吸入喷嘴(32)的周向 | ||||||
| 4 | 压缩机及涡轮制冷机 | CN201380067583.3 | 2013-07-26 | CN104884817A | 2015-09-02 | 古贺淳; 大村真太郎 |
| 本发明提供一种压缩机及涡轮制冷机。本发明的压缩机(2)具备:旋转轴(12);多个叶轮,安装于旋转轴;主流路,将流体从前级的叶轮导向后级的叶轮;腔室(31),呈以轴线为中心的环状,且与主流路连通;吸入喷嘴(32),将流体从外周侧朝向内周侧导入到腔室;可动翼片,在主流路内沿轴线的周向间隔设置有多个,且通过可动来调整在主流路内流通的流体的流量;及驱动机构(42),设置于腔室(31)内的吸入喷嘴(32)的周向一侧,并改变多个可动翼片的角度,其中,吸入喷嘴(32)朝向周向另一侧倾斜,以使在腔室(31)内的周向一侧及周向另一侧中流向周向另一侧的流体的流量增加。 | ||||||
| 5 | 液动力机器的轴同辐流式轮体,包括该轮体的液动力机器和该轮体的组装方法 | CN200980141507.6 | 2009-09-04 | CN102187084B | 2014-02-26 | Y·布韦; F·陶希; L·马蒂厄; G·罗西 |
| 用于液动力机器的轴同辐流式轮体包括:围绕轮体的中心轴线转动对称的一环带体,围绕该轴线转动对称的一顶板体,和在顶板体和环带体之间延伸的多个叶片(21,22)。此外,轮体包括部分地确定至少环带体和/或顶板体的至少两个元件(41,42,43,61,62,63),以及一叶片(21,22)的至少一个边部(231,232,241,242)嵌接在确定环带体和/或顶板体的两元件之间。 | ||||||
| 6 | 冲击式风力发电装置 | CN201010623950.1 | 2010-12-31 | CN102052255B | 2012-03-07 | 郭文礼 |
| 本发明属于风电技术领域,公开了一种冲击式风力发电装置,包括垂直轴冲击式风力发电装置和水平轴冲击式风力发电装置,该两种类型的冲击式风力发电装置利用多级冲动叶片的动力转子机构,最大限度的利用了来风的能量,提高了风能利用率;利用高位排风管的高度差及侧向排风,可以加大来风的能量,即使在晴朗无风的天气,动力转子也可低负荷发电;可以做成单机功率大、体积小的发电机组,便于运输和安装,维护,大大降低了风力发电装置的单位发电量的投资成本;垂直轴式可接受任意方向的来风,没有复杂的变桨距系统,传动系统和发电机可放置在地面,便于操作维护;克服了风能利用率低,动力转子难启动的缺点。 | ||||||
| 7 | Francis-type runner for a hydraulic machine, hydraulic machine including such a runner, and method for assembling such a runner | US13060769 | 2009-09-04 | US09175662B2 | 2015-11-03 | Yves Bouvet; Fabrice Tassy; Louis Mathieu; Georges Rossi |
| The present invention relates to a Francis runner for a hydraulic machine that comprises a belt with a rotational symmetry about a central axis of the runner, a ceiling with a rotational symmetry about the axis, and a plurality of blades (21, 22) extending between the ceiling and the belt. The runner also includes at least two elements (41, 42, 43, 61, 62, 63) partially defining at least the belt and/or the ceiling while at least one edge (231, 232, 241, 242) of a blade (21, 22) is inserted between the two elements defining the belt and/or the ceiling. | ||||||
| 8 | Impact Type Wind-Driven Power Generating Device | US13977431 | 2011-07-28 | US20130328319A1 | 2013-12-12 | Wenli Guo |
| An impact type wind-driven power generating device is classified into a vertical shaft impact type wind-driven power generating device and a horizontal shaft impact type wind-driven power generating device. The two types of the impact type wind-driven power generating device adopt a power rotor mechanism of a multi-stage impacting blade to utilize the energy of in-coming wind to the maximum extent, thereby improving the utilization of the wind energy. The energy of the in-coming wind is increased due to the height difference and the lateral exhaust of a high-altitude exhaust duct, so that the power rotor can generate electric power at a low load even in a sunny windless day. The power generating device overcomes the disadvantages of low utilization of the wind energy and the power rotor being difficult to be activated. | ||||||
| 9 | A TURBINE FOR EXTRACTING KINETIC ENERGY FROM FLOWING FLUID, AND RELATED METHODS AND SYSTEMS | US15325979 | 2016-06-01 | US20180209395A1 | 2018-07-26 | Nathan J. Smith |
| A turbine for extracting kinetic energy from a fluid includes a runner, a turbine-inlet having an entrance and an exit that is adjacent the turbine's runner, and a turbine-outlet having an entrance that is adjacent the runner and an exit. The runner extracts kinetic energy from fluid flowing through the turbine; the turbine inlet directs flowing fluid into the runner; and the turbine-outlet directs flowing fluid away from the runner. When fluid flows through the turbine, the fluid flowing through the turbine-inlet toward the runner flows around and adjacent the fluid flowing through the turbine-outlet away from the runner. | ||||||
| 10 | Compressor and turbo chiller | US14655030 | 2013-07-26 | US09897092B2 | 2018-02-20 | Jun Koga; Shintaro Omura |
| A compressor (2) characterized by being equipped with: a rotary shaft (12); multiple impellers attached to the rotary shaft; a main flow path that guides a fluid from the prior-stage impeller to the latter-stage impeller; a chamber (31) that forms a circle centered around the axial line and connects to the main flow path; a suction nozzle (32) that guides the fluid from the outer circumferential side toward the inner circumferential side in the chamber; multiple movable vanes provided in the main flow path at intervals in the circumferential direction of the axial line and capable of moving and thereby adjusting the flow volume of the fluid passing through the main flow path; and a drive mechanism (42) that is provided at one side in the circumferential direction of the suction nozzle (32) within the chamber (31), and that changes the angle of the multiple movable vanes. In addition, of the one side and the other side in the circumferential direction within the chamber (31), the suction nozzle (32) is inclined toward the other side so as to increase the flow volume of the fluid toward the other side. | ||||||
| 11 | COMPRESSOR AND TURBO CHILLER | US14655030 | 2013-07-26 | US20150345507A1 | 2015-12-03 | Jun KOGA; Shintaro OMURA |
| A compressor (2) characterized by being equipped with: a rotary shaft (12); multiple impellers attached to the rotary shaft; a main flow path that guides a fluid from the prior-stage impeller to the latter-stage impeller; a chamber (31) that forms a circle centered around the axial line and connects to the main flow path; a suction nozzle (32) that guides the fluid from the outer circumferential side toward the inner circumferential side in the chamber; multiple movable vanes provided in the main flow path at intervals in the circumferential direction of the axial line and capable of moving and thereby adjusting the flow volume of the fluid passing through the main flow path; and a drive mechanism (42) that is provided at one side in the circumferential direction of the suction nozzle (32) within the chamber (31), and that changes the angle of the multiple movable vanes. In addition, of the one side and the other side in the circumferential direction within the chamber (31), the suction nozzle (32) is inclined toward the other side so as to increase the flow volume of the fluid toward the other side. | ||||||
| 12 | TURBINE ROTOR FOR REDIRECTING FLUID FLOW | US15726701 | 2017-10-06 | US20190195195A1 | 2019-06-27 | Michael R. Theis |
| A fluid flow turbine having a turbine rotor with a plurality of blades (also known as “vanes”) for converting the kinetic energy of a flowing fluid into mechanical rotational energy of the turbine rotor is provided by this invention. The plurality of blades are defined by a continuously sinuous curve outer edge that results in the lateral surface of the blades having a lower concave portion for scooping up the horizontal incoming fluid flow and redirecting it to a substantially vertical fluid flow along the lateral surface of the blade. The upper portion of the lateral surfaces of the blades is convex, causing the upper edge of the blades to tail off laterally so that the fluid flow exits the turbine in a substantially vertical direction, instead of turning back upon itself to reduces turbulence of the fluid flow inside the turbine. The fluid flow turbine can comprise a small wind turbine that will produce electrical power at low wind speeds, and can be mounted to the top of a building. | ||||||
| 13 | Wind Funneling Device for Energy Production | US15586384 | 2017-05-04 | US20180320656A1 | 2018-11-08 | Herbert Newsam |
| A wind funneling device for energy production. The present system includes a wind funneling device for energy production having a housing with side panels, a top panel and a rear panel forming an interior volume with a front opening and a lower opening. A plurality of parallel planar members is disposed within the interior volume of the housing, wherein each of the plurality of parallel planar members extends parallel to the side panels. One or more wind vanes are secured to the housing and configured to direct the front opening to the direction of the wind. An electric generator is connected to the housing. Air flows toward the generator, producing electricity. A battery is operably connected to the generator to store the electricity for future use. Solar panels and a vibration powered generator may provide an additional source of energy production. | ||||||
| 14 | Improved Turbine | US14786796 | 2014-04-25 | US20160102499A1 | 2016-04-14 | Kenneth Roderick Stewart; Donald Stewart |
| An improved turbine or motor, such as a fluid or liquid driven turbine or motor or hydraulic turbine or motor including a downhole turbine for the oil/gas and geothermal industries, such as a drilling turbine or downhole drilling turbine. The turbine or motor provides a fluid passage comprising at least one portion or zone arranged to cause a drive fluid to be moved or diverted, such as at least partly radially. The turbine or motor may comprise a rotor having a rotor blade extending within the fluid passage. The turbine or motor may comprise a stator having a stator blade extending within the fluid passage. The stator (30) may comprise or define at least part of the at least one portion or zone configured or arranged to cause the fluid to be moved in or diverted from an at least part axial path to an at least part radial path or radially inward path. | ||||||
| 15 | Impact type wind-driven power generating device | US13977431 | 2011-07-28 | US09018791B2 | 2015-04-28 | Wenli Guo |
| An impact type wind-driven power generating device is classified into a vertical shaft impact type wind-driven power generating device and a horizontal shaft impact type wind-driven power generating device. The two types of the impact type wind-driven power generating device adopt a power rotor mechanism of a multi-stage impacting blade to utilize the energy of in-coming wind to the maximum extent, thereby improving the utilization of the wind energy. The energy of the in-coming wind is increased due to the height difference and the lateral exhaust of a high-altitude exhaust duct, so that the power rotor can generate electric power at a low load even in a sunny windless day. The power generating device overcomes the disadvantages of low utilization of the wind energy and the power rotor being difficult to be activated. | ||||||
| 16 | FRANCIS-TYPE RUNNER FOR A HYDRAULIC MACHINE, HYDRAULIC MACHINE INCLUDING SUCH A RUNNER, AND METHOD FOR ASSEMBLING SUCH A RUNNER | US13060769 | 2009-09-04 | US20110206518A1 | 2011-08-25 | Yves Bouvet; Fabrice Tassy; Louis Mathieu; Georges Rossi |
| The present invention relates to a Francis runner for a hydraulic machine that comprises a belt with a rotational symmetry about a central axis of the runner, a ceiling with a rotational symmetry about the axis, and a plurality of blades (21, 22) extending between the ceiling and the belt. The runner also includes at least two elements (41, 42, 43, 61, 62, 63) partially defining at least the belt and/or the ceiling while at least one edge (231, 232, 241, 242) of a blade (21, 22) is inserted between the two elements defining the belt and/or the ceiling. | ||||||
| 17 | Improvement in hydraulic motors | US42980D | US42980A | 1864-05-31 | ||
| 18 | COMPRESSOR AND TURBO CHILLER | EP13866799.3 | 2013-07-26 | EP2940314A1 | 2015-11-04 | KOGA Jun; OMURA Shintaro |
A compressor (2) characterized by being equipped with: a rotary shaft (12); multiple impellers attached to the rotary shaft; a main flow path that guides a fluid from the prior-stage impeller to the latter-stage impeller; a chamber (31) that forms a circle centered around the axial line and connects to the main flow path; a suction nozzle (32) that guides the fluid from the outer circumferential side toward the inner circumferential side in the chamber; multiple movable vanes provided in the main flow path at intervals in the circumferential direction of the axial line and capable of moving and thereby adjusting the flow volume of the fluid passing through the main flow path; and a drive mechanism (42) that is provided at one side in the circumferential direction of the suction nozzle (32) within the chamber (31), and that changes the angle of the multiple movable vanes. In addition, of the one side and the other side in the circumferential direction within the chamber (31), the suction nozzle (32) is inclined toward the other side so as to increase the flow volume of the fluid toward the other side. |
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| 19 | ROUE DE TYPE FRANCIS POUR MACHINE HYDRAULIQUE, MACHINE HYDRAULIQUE COMPRENANT UNE TELLE ROUE ET PROCÉDÉ D'ASSEMBLAGE D'UNE TELLE ROUE | EP09741373.6 | 2009-09-04 | EP2326828B8 | 2013-08-28 | BOUVET, Yves; TASSY, Fabrice; MATHIEU, Louis; ROSSI, Georges |
| 20 | IMPACT TYPE WIND-DRIVEN POWER GENERATING DEVICE | EP11852639.1 | 2011-07-28 | EP2660466A1 | 2013-11-06 | GUO, Wenli |
An impact type wind-driven power generating device is classified into a vertical shaft impact type wind-driven power generating device and a horizontal shaft impact type wind-driven power generating device. The two types of the impact type wind-driven power generating device adopt a power rotor mechanism (10) of a multi-stage impacting blade to utilize the energy of in-coming wind to the maximum extent, thereby improving the utilization of the wind energy. The energy of the in-coming wind is increased due to the height difference and the lateral exhaust of a high-altitude exhaust duct (8), so that the power rotor (10) can generate electric power at a low load even in a sunny windless day. The power generating device can be manufactured into a power generator set with large power and small volume per unit, being convenient to transport, install and maintain, thereby greatly reducing the investment cost of unit power generation amount. The power generating device can receive in-coming wind from any direction without a complicated variable propeller pitch system. A transmission system and a power generator may be arranged on the ground, which is convenient to operate and maintain. The power generating device overcomes the disadvantages of low utilization of the wind energy and the power rotor being difficult to be activated. |
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