| 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 | 用于研磨和测试齿轮的装置 | CN201410858395.9 | 2014-11-20 | CN104722852B | 2017-09-29 | H·穆勒 |
| 本发明涉及用于研磨或测试齿轮(T、R)的装置(100),其具有:第一主轴组(111),其用于卡特第一齿轮(T),由此第一齿轮(T)能够安装在第一主轴组(111)上,从而能够绕着第一旋转轴(TA)旋转;第二主轴组(112),其用于卡持第二齿轮(R),由此第二齿轮(R)能够安装在第二主轴组(112)上,从而能够绕着第二旋转轴(RA)旋转;第一线性轴(LA1),其用于实施第一齿轮(T)与第一主轴组(111)相对于第二齿轮(R)与第二主轴组(112)的第一线性位移;以及第二线性轴(LA2),其用于实施第一齿轮(T)与第一主轴组(111)相对于第二齿轮(R)与第二主轴组(112)的第二线性位移,其中所述装置(100)还包括:回转轴(SA),用于使第一齿轮(T)与第一主轴组(111)或者第二齿轮(R)与第二主轴组(112)绕着该回转轴(SA)枢转。 | ||||||
| 2 | 旋转加工机以及其加工方法 | CN201480041404.3 | 2014-08-18 | CN105392588B | 2017-07-28 | 加藤进; 高开明; 大谷昌弘 |
| 旋转加工机(1)具备对形成有螺旋齿的工件进行支承并使其旋转的旋转装置(2)、通过旋转砂轮(7)的磨削齿(71)对由于旋转装置(2)而旋转的工件的螺旋齿进行磨削加工的加工装置(3)、以及进行工件(8)朝旋转装置(2)的搬入搬出的搬运装置(4)。搬运装置(4)分别具有多个用于夹持工件的夹持爪(51)、和用于使磨削齿(71)成形的砂轮修整器(52)。搬运装置(4)绕回转中心轴线(401)旋转,使各夹持爪(51)依次接近旋转装置(2),并且使各砂轮修整器(52)依次接近加工装置(3)。各砂轮修整器(52)的修整齿具有相互不同的齿面的形状。 | ||||||
| 3 | 用于对工件进行齿加工的方法 | CN201410204365.6 | 2014-05-14 | CN104148744A | 2014-11-19 | 汉斯约尔格·热塞 |
| 本发明涉及一种用于在齿轮切削机床上对工件进行齿加工的方法,其中一方面齿轮切削机床包括至少一个主加工站和具有至少两个工件轴的至少一个次站,其中此外两个工件轴交替地横穿入主加工站和次站的工作区域,其中对工件进行齿加工的方法还包括精切齿步骤,其中在主加工站对设置在工件轴中的一个处的工件施加精切齿,并且其中最终对工件进行齿加工的方法包括二次加工步骤,其中在次站处通过材料去除和/或材料成形对设置在工件轴中的一个处的工件施加二次加工,其特征在于对于在主加工站处执行精切齿的期间,在次站处没有执行每个二次加工。 | ||||||
| 4 | 一种对齿装置 | CN201710857415.4 | 2017-09-21 | CN107498120A | 2017-12-22 | 周庆成; 包明玉; 金平; 舒志国; 刘进步 |
| 一种对齿装置,属于搓齿机床工装夹具技术领域;针对工件新搓齿与原来的齿间存在固定角度关系的工件加工对齿的问题,本发明提供一种对齿装置,包括顶尖座,旋转轴通过轴承固定在顶尖座内部,旋转轴一端固定有顶尖;所述旋转轴在靠顶尖一端端面上与连接板固定连接,连接板由相互垂直固定连接的第一连接板和第二连接板构成,连接板能够随旋转轴转动而转动;所述的连接板的第二连接板上设置有支撑工件的第一V型架和第二V形架,连接板的第二连接板中部下端面设置有气缸,气缸活塞杆末端连接V形压块;所述的连接板的第一连接板顶端设置刻度板,指示装置固定在顶尖座上且指向刻度板;本发明能够根据刻度板的指示调整角度进行对齿。 | ||||||
| 5 | 用于研磨和测试齿轮的装置 | CN201410858395.9 | 2014-11-20 | CN104722852A | 2015-06-24 | H·穆勒 |
| 本发明涉及用于研磨或测试齿轮(T、R)的装置(100),其具有:第一主轴组(111),其用于卡特第一齿轮(T),由此第一齿轮(T)能够安装在第一主轴组(111)上,从而能够绕着第一旋转轴(TA)旋转;第二主轴组(112),其用于卡持第二齿轮(R),由此第二齿轮(R)能够安装在第二主轴组(112)上,从而能够绕着第二旋转轴(RA)旋转;第一线性轴(LA1),其用于实施第一齿轮(T)与第一主轴组(111)相对于第二齿轮(R)与第二主轴组(112)的第一线性位移;以及第二线性轴(LA2),其用于实施第一齿轮(T)与第一主轴组(111)相对于第二齿轮(R)与第二主轴组(112)的第二线性位移,其中所述装置(100)还包括:回转轴(SA),用于使第一齿轮(T)与第一主轴组(111)或者第二齿轮(R)与第二主轴组(112)绕着该回转轴(SA)枢转。 | ||||||
| 6 | 成形铣削的花键装置和用于制造该装置的成形铣削过程 | CN201110323718.0 | 2011-10-21 | CN104279209A | 2015-01-14 | D·E·菲布斯; W·H·哈伊沃德 |
| 本发明涉及成形铣削的花键装置和用于制造该装置的成形铣削过程。通过组合成形和铣削动作,或者成形铣削,切削刀具能够移动通过花键的整个可用部分,并且在收回、反向和重复循环之前在诸如轴肩的相邻特征部的表面中加工退刀部。成形铣削装置和制造方法消除了对环形花键退刀部的需要,并且花键接合件的全长能够被用于强度。通过所述成形铣削过程制造的花键连接装置的有效宽度节省了空间并且提高了所述花键连接件的负荷承载能力。 | ||||||
| 7 | 用于动力传动的增速或减速齿轮副 | CN200610088875.7 | 2006-07-21 | CN101109436B | 2011-02-16 | 姜虹; 王小椿 |
| 本发明涉及一种用于动力传动的增速或减速齿轮副,其中主动齿轮(1)和被动齿轮(2)的齿形在参考点处分段设计,上齿面齿形(15、25)由共轭曲线构成,下齿面齿形(14、24)由光滑的凸解析曲线构成,被动齿轮(2)齿面上的参考点(22)在其有效工作齿高的中部附近,主动齿轮(1)齿面(11)上的参考点(12)和被动齿轮齿面(21)上的参考点(22)是一对共轭接触点。本发明可以大幅度提高齿轮副的承载能力。 | ||||||
| 8 | 旋转加工机以及其加工方法 | CN201480041404.3 | 2014-08-18 | CN105392588A | 2016-03-09 | 加藤进; 高开明; 大谷昌弘 |
| 旋转加工机(1)具备对形成有螺旋齿的工件进行支承并使其旋转的旋转装置(2)、通过旋转砂轮(7)的磨削齿(71)对由于旋转装置(2)而旋转的工件的螺旋齿进行磨削加工的加工装置(3)、以及进行工件(8)朝旋转装置(2)的搬入搬出的搬运装置(4)。搬运装置(4)分别具有多个用于夹持工件的夹持爪(51)、和用于使磨削齿(71)成形的砂轮修整器(52)。搬运装置(4)绕回转中心轴线(401)旋转,使各夹持爪(51)依次接近旋转装置(2),并且使各砂轮修整器(52)依次接近加工装置(3)。各砂轮修整器(52)的修整齿具有相互不同的齿面的形状。 | ||||||
| 9 | 适用于动力传动的增速或减速齿轮副 | CN200610088875.7 | 2006-07-21 | CN101109436A | 2008-01-23 | 姜虹; 王小椿 |
| 本发明涉及一种适用于动力传动的增速或减速齿轮副,其中主动齿轮(1)和被动齿轮(2)的齿形在参考点处分段设计,上齿面齿形(15、25)由共轭曲线构成,下齿面齿形(14、24)由光滑的凸解析曲线构成,被动齿轮(2)齿面上的参考点(22)在其有效工作齿高的中部附近,主动齿轮(1)齿面(11)上的参考点(12)和被动齿轮齿面(21)上的参考点(22)是一对共轭接触点。本发明可以大幅度提高齿轮副的承载能力。 | ||||||
| 10 | 齿轮精加工方法和齿轮 | CN99813427.9 | 1999-11-22 | CN1110395C | 2003-06-04 | H·J·斯帕达费尔德 |
| 一种利用精加工工具对齿轮的齿侧面进行机加工的方法。该方法包括:使工具(例如一磨削工具)转动,并使工具与齿侧面接触。在工具和齿轮之间形成相对运动,以使工具沿一路径横穿过齿侧面。其中,所述路径可以产生这样一种形式的齿侧面几何形状,即,当齿侧面在无载或轻载情况下与一相配的齿侧面相啮合而形成一个齿对时,可以形成一运动曲线(A),该曲线与一紧挨在前面的齿对(P)和一紧挨在后面的齿对(F)的运动曲线至少有两次交叉。齿对的运动曲线描绘了齿对的各齿侧面从一最初的啮合入口到一最终的啮合出口,即齿转动量高于1.0齿距(最好是大约1.5齿距至3.0齿距)的接触情况。 | ||||||
| 11 | 齿轮精加工方法和齿轮 | CN99813427.9 | 1999-11-22 | CN1326391A | 2001-12-12 | H·J·斯帕达费尔德 |
| 一种利用精加工工具对齿轮的齿侧面进行机加工的方法。该方法包括:使工具(例如一磨削工具)转动,并使工具与齿侧面接触。在工具和齿轮之间形成相对运动,以使工具沿一路径横穿过齿侧面。其中,所述路径可以产生这样一种形式的齿侧面几何形状,即,当齿侧面在无载或轻载情况下与一相配的齿侧面相啮合而形成一个齿对时,可以形成一运动曲线(A),该曲线与一紧挨在前面的齿对(P)和一紧挨在后面的齿对(F)的运动曲线至少有两次交叉。齿对的运动曲线描绘了齿对的各齿侧面从一最初的啮合入口到一最终的啮合出口,即齿转动量高于1.0齿距(最好是大约1.5齿距至3.0齿距)的接触情况。 | ||||||
| 12 | GEAR ASSEMBLY AND MANUFACTURING METHOD THEREOF | US15671651 | 2017-08-08 | US20180045286A1 | 2018-02-15 | Masayuki ISHIBASHI; Makoto FUNAHASHI; Daisuke OKAMOTO |
| A gear assembly that can prevent a reduction in power transmission efficiency and a manufacturing method thereof are provided. The gear assembly comprises a first gear and a second gear. The gear assembly is designed in such a manner that first gear tooth and the second gear tooth are contacted properly to each other in a plane of action when operated in a predetermined condition. A rigidity reducing portion is formed on a first base portion to avoid improper contact in the plane of action when the gear assembly is operated in a different condition. | ||||||
| 13 | Apparatus for the lapping or testing of gears | US14549014 | 2014-11-20 | US09702784B2 | 2017-07-11 | Hartmuth Müller |
| An apparatus including a first spindle group for chucking a first gear, whereby the first gear is mountable on the first spindle group so that it is rotatable, and a second spindle group for chucking a second gear, whereby the second gear is mountable on the second spindle group so that it is rotatable. The apparatus further defining a first linear axis oriented to perform a first linear displacement of the first spindle group relative to the second spindle group; a second linear axis oriented to perform a second linear displacement of the first spindle group relative to the second spindle group; and at least one of a swivel axis oriented to perform pivoting of the first spindle group thereabout, and a swivel axis oriented to perform pivoting of the second spindle group thereabout. | ||||||
| 14 | Smilled spline apparatus and smilling process for manufacturing the smilled spline apparatus | US13099080 | 2011-05-02 | US09387544B2 | 2016-07-12 | Dan E. Phebus; William H. Hayward |
| A spline connection apparatus includes a male spline apparatus and a female collar apparatus coupled together. The male spline apparatus includes an external spline and a plurality of first tooth spaces having spline relief portions for tool clearance extending angularly and conically into a shoulder portion and base portion of the male spline apparatus. The female collar apparatus includes and internal spline and a plurality of second tooth spaces having an internal spline relief portion for tool clearance extending angularly and conically into the counterbore engagement surface of the female collar apparatus. The external teeth of the external spline and the internal teeth of the internal are equal in length. The effective face width of the engagement is equal to the length of the external and internal teeth. | ||||||
| 15 | ROTARY MACHINING APPARATUS AND MACHINING METHOD USING THE SAME | US14900830 | 2014-08-18 | US20160136744A1 | 2016-05-19 | Susumu KATO; Akira TAKAGAI; Masahiro OTANI |
| A rotary machining apparatus that includes a rotary that supports and rotates a workpiece having helical teeth; a grinding wheel that grinds the helical teeth of the workpiece to be rotated by the rotary with grinding teeth; and a conveyor for carrying the workpiece in and out of the rotary, wherein the conveyor includes, around a turning center axis, a plurality of grippers for sandwiching the workpiece and a plurality of dressers for forming toothed surfaces of the grinding teeth, and turns around the turning center axis so that the grippers sequentially approach the rotary and the dressers sequentially approach the grinding wheel, and dress teeth of the dressers each have different shapes of toothed surfaces. | ||||||
| 16 | Machining Method for Hard-Fine Machining of Noise-Optimized Gears on a Gear-Cutting Machine | US14195985 | 2014-03-04 | US20140256223A1 | 2014-09-11 | Hansjörg Geiser |
| The present invention relates to a method for hard-fine machining of tooth flanks with corrections and/or modifications on a gear-cutting machine, wherein respective toothed wheel pairings which mesh with one another within a transmission or a test device are machined while taking account of the respective mating flanks, and wherein the tooth flanks of the relevant workpieces are provided with periodic waviness corrections or waviness modifications. In accordance with the invention, the rotational error extent is determined by means of rotational distance error measurement of the toothed wheel pairs in a gear measuring device and/or transmission. This measurement result serves as an input value for defining the amplitude, frequency and phase position for the periodic flank waviness corrections on the tooth flanks of the toothed wheel pairings for production in the gear-cutting machine. | ||||||
| 17 | DETECTING A RELATIVE SHAFT POSITION ON GEARED SHAFTS | US13462421 | 2012-05-02 | US20130291672A1 | 2013-11-07 | Gary L. Hess; James A. Gosse; Paul J. Leblanc; James Saloio |
| A system for determining a relative position of a secondary gear includes a gear assembly including a phonic wheel fixed to a primary gear and a secondary gear rotatably engaged to the first gear, a sensor configured to output a signal upon detecting a tooth of the phonic wheel, and a digital logic circuit configured to detect a revolution of the phonic wheel, to generate a primary gear tooth pulse at intervals corresponding to intervals of teeth of the primary gear based on the detected revolution of the phonic wheel, and to generate a secondary gear revolution signal at an interval corresponding to a revolution of the secondary gear based on the primary gear tooth pulse. | ||||||
| 18 | SMILLED SPLINE APPARATUS AND SMILLING PROCESS FOR MANUFACTURING THE SMILLED SPLINE APPARATUS | US13099080 | 2011-05-02 | US20120282022A1 | 2012-11-08 | DAN E. PHEBUS; WILLIAM H. HAYWARD |
| By combining shaping and milling actions, or smilling, the cutting tool can move through the entire usable portion of the spline and machine a tool relief into the face of the adjacent feature such as a shoulder before retracting, reversing direction, and repeating the cycle. The smilling apparatus and manufacturing method eliminates the need for an annular spline relief and the full length of spline engagement can be utilized for strength. The effective width of the spline connection apparatus manufactured by the smilling process conserves space and increases the load carrying capability of the spline connection. | ||||||
| 19 | Worm gear unit and method of producing same | US11819201 | 2007-06-26 | US07979988B2 | 2011-07-19 | Kohtaro Shiino; Yusuke Fukuda |
| By finding a range of an allowable error of maximum meshing position of a worm shaft in an axial direction relative to a worm wheel, that is higher than that of a worm shaft of a conventional worm gear unit, a worm gear unit of the present invention is provided. | ||||||
| 20 | Optimum number of teeth setting method for helical gear pair and helical gear pair manufactured by this method | US11376739 | 2006-03-16 | US07810238B2 | 2010-10-12 | Yasuhiro Uenishi; Toshiki Hirogaki; Eiichi Aoyama; Yuusuke Nakano |
| In optimum number of teeth setting method for a helical gear pair and the helical gear pair manufactured on the basis of the set optimum number of teeth of each helical gear of the helical gear pair, a sound pressure level of a gear sound is compared with the sound pressure level of an audible limit with respect to a meshing frequency of the helical gear pair at a predetermined vehicle speed of an automotive vehicle in which the helical gear pair is mounted to select a frequency region in which the calculated sound pressure of the gear sound is relatively low to the sound pressure level of the audible limit, and number of teeth of each helical gear of the helical gear pair corresponding to the selected frequency region is set to an optimum number of teeth of each helical gear of the helical gear pair. | ||||||
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