| 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 | 加工头 | CN200880128356.6 | 2008-12-16 | CN102015180B | 2015-10-07 | 托马斯·策勒 |
| 本发明涉及一种用于机床的加工头,最好是用于齿铣床和齿磨床的加工头,其具有直接驱动装置,所述直接驱动装置设置在机床的加工头托座内,其中所述直接驱动装置包括至少两个可相互同步地驱动的马达。 | ||||||
| 2 | 加工头 | CN200880128356.6 | 2008-12-16 | CN102015180A | 2011-04-13 | 托马斯·策勒 |
| 本发明涉及一种用于机床的加工头,最好是用于齿铣床和齿磨床的加工头,其具有直接驱动装置,所述直接驱动装置设置在机床的加工头托座内,其中所述直接驱动装置包括至少两个可相互同步地驱动的马达。 | ||||||
| 3 | 一种非圆齿轮连续展成滚齿的加工方法 | CN201611221427.X | 2016-12-26 | CN106735601A | 2017-05-31 | 韩江; 夏链; 李大柱; 高婷; 田晓青 |
| 本发明涉及一种非圆齿轮连续展成滚齿的加工方法。该方法基于包括工作台、齿坯回转轴、滚刀回转轴、滚刀前后移动轴、滚刀上下移动轴和柔性电子齿轮箱的数控滚齿机;将非圆齿坯固定在工作台上,齿坯回转轴带动工作台变速转动;当滚刀回转轴的转速恒定转速时,滚刀前后移动轴和齿坯回转轴的实时速度通过柔性电子齿轮箱实时运算并作闭环控制,实现非圆齿坯滚切;滚切过程中,实时监测、计算齿坯回转轴、滚刀前后移动轴与滚刀回转轴之间的速比系数,并对齿坯回转轴和滚刀前后移动轴的速度进行控制,从而实现非圆齿轮节曲线的连续展成滚齿加工。本发明只需将非圆齿轮节曲线的极坐标方程导入数控系统,即可加工,大大缩短了非圆齿轮的制造周期。 | ||||||
| 4 | 用于制造设有处于内部的工作轮齿部的厚壁空心轮的装置和方法 | CN201380021745.X | 2013-04-23 | CN104411426B | 2017-05-24 | F.鲁赫; D.德里亚兹 |
| 本发明涉及一种用于制造设有处于内部的工作轮齿部(6)的空心轮(1a)的方法,其中,工件(1)具有带有纵轴线(Z)的管形的区段,通过纵轴线(Z)来定义以下所使用的术语径向。通过使工件围绕所述纵轴线以在时间上变化的旋转速度执行旋转运动并且该至少一个位于工作位置中的压印工具(23)分别执行与所述旋转运动同步的径向振荡运动,通过N≥2个压印工具(21,22,...)(其中的每个在执行该方法期间被带到工作位置中)来加工工件以在管形的区段的内侧处产生工作轮齿部。所述至少一个位于工作位置中的压印工具重复地加工工件(1)。 | ||||||
| 5 | 用于制造设有处于内部的工作轮齿部的厚壁空心轮的装置和方法 | CN201380021745.X | 2013-04-23 | CN104411426A | 2015-03-11 | F.鲁赫; D.德里亚兹 |
| 本发明涉及一种用于制造设有处于内部的工作轮齿部(6)的空心轮(1a)的方法,其中,工件(1)具有带有纵轴线(Z)的管形的区段,通过纵轴线(Z)来定义以下所使用的术语径向。通过使工件围绕所述纵轴线以在时间上变化的旋转速度执行旋转运动并且该至少一个位于工作位置中的压印工具(23)分别执行与所述旋转运动同步的径向振荡运动,通过N≥2个压印工具(21,22,...)(其中的每个在执行该方法期间被带到工作位置中)来加工工件以在管形的区段的内侧处产生工作轮齿部。所述至少一个位于工作位置中的压印工具重复地加工工件(1)。 | ||||||
| 6 | 齿轮加工机械 | CN201080048488.5 | 2010-04-21 | CN102596470A | 2012-07-18 | 赤间知; 大段诚作 |
| 本发明提供一种提高铣头的刚性,在对外齿轮或内齿轮中的任一者进行加工时,均能够实现加工精度的提高及品质的均匀化的齿轮加工机械。为此,齿轮加工机械具备:移动基座(12),其将安装有外齿轮(W1)或内齿轮(W2)的旋转工作台(13)支承为能够旋转且被支承为能够移动;门形柱体(14)的架桥部(14c),其设置在移动基座(12)的上方;鞍座(15),其以可升降的方式支承在架桥部(14c);铣头(16),其设置在(15)的前表面且在下端支承有可旋转的工具(T),其中,在铣头(16)的前侧设有朝向前方突出的突出部(16a),将工具(T)以其前部从突出部(16a)中的最向前方突出的顶面(16b)更向前方突出的方式配置。 | ||||||
| 7 | Sintered composite and method for its manufacture | US13196971 | 2011-08-03 | US09144844B2 | 2015-09-29 | Angelika Pohl; Alfred Boelstler |
| A method for powder-metallurgically manufacturing a rotational body, including compacting a first starting body is compacted from a metal powder; forming a second starting body from metal, separately from the first starting body; placing the starting bodies against each other in axial contact via end faces in relation to a longitudinal axis of the rotational body; and permanently and firmly sintered the first starting body and the second starting body to each other by collective sintering. The first starting body is compacted from an aluminum-based powder, the second starting body is formed from an aluminum material, and the starting bodies are sintered to each other at their respective end faces. | ||||||
| 8 | Processing Head | US12935401 | 2008-12-16 | US20110027031A1 | 2011-02-03 | Thomas Zeller |
| The present invention relates to a processing head for processing machines, preferably tooth milling and tooth grinding machines, comprising a direct drive which is arranged in a processing head bed of a processing machine, wherein the direct drive comprises at least two motors actuatable in synchronism with each other. | ||||||
| 9 | Gear processing machine | JP2009276208 | 2009-12-04 | JP2011115908A | 2011-06-16 | AKAMA TOMO; ODAN SEISAKU |
| <P>PROBLEM TO BE SOLVED: To provide a gear processing machine which improves processing accuracy, and uniforms quality, even when processing an external gear or an internal gear, by improving the rigidity of a cutter head. <P>SOLUTION: This gear processing machine includes a moving base 12 for rotatably supporting and movably supporting a rotary table 13 for installing the external gear W1 or the internal gear W2, a bridge part 14c of a portal column 14 arranged above the moving base 12, a saddle 15 liftably supported by the bridge part 14c, and the cutter head 16 arranged in front of the saddle 15 and rotatably supporting a tool T on the lower end. A projecting part 16a projecting forward is arranged on the front side of the cutter head 16, and the tool T is arranged so as to project further forward from the top surface 16a projecting its front part most forward in the projecting part 16a. <P>COPYRIGHT: (C)2011,JPO&INPIT | ||||||
| 10 | 内歯車歯を有する厚壁の中空ホイールを製造するための装置および方法 | JP2015507318 | 2013-04-23 | JP6392204B2 | 2018-09-19 | ルー,ファビアン; デリアツ,ダニエル |
| 11 | BEVEL GEAR HAVING MODIFIED GEOMETRY | US14816606 | 2015-08-03 | US20160040769A1 | 2016-02-11 | Gary Töpfer |
| Bevel gear having a main body comprises a heel-side skin surface. The bevel gear has at least one tooth gap, which exits from the main body in the region of the skin surface. The tooth gap has a tooth base, the profile of which is defined by a base cone angle in relation to the workpiece axis of rotation. A concentric circumferential ring structure is provided on the skin surface, which is raised in relation to the skin surface, and which results in a heel-side exit angle between the tooth base and the ring structure, which is in the range between 125° and 160°. | ||||||
| 12 | Processing head | US12935401 | 2008-12-16 | US08931984B2 | 2015-01-13 | Thomas Zeller |
| The present invention relates to a processing head for processing machines, preferably tooth milling and tooth grinding machines, comprising a direct drive which is arranged in a processing head bed of a processing machine, wherein the direct drive comprises at least two motors actuatable in synchronism with each other. | ||||||
| 13 | GEAR MACHINING MACHINE | US13504903 | 2010-04-21 | US20120263549A1 | 2012-10-18 | Satoru Akama; Seisaku Odan |
| A gear machining machine has a cutter head with improved rigidity. The machine is equipped with a movement base that is movably supported and rotatably supports a rotation table on which an external gear or an internal gear is mounted; a bridge section of a gate-shaped column provided at a location above the movement base; a saddle which is supported by the bridge section in a vertically movable manner; and a cutter head on the front surface of the saddle, the lower end of which rotatably supports a tool. A protrusion which projects forward is provided on the front surface of the cutter head. The tool is disposed so that the front thereof protrudes further forward of an end surface which is the most forward projecting portion of the protrusion. | ||||||
| 14 | Gear cutting apparatus | US15037661 | 1961-11-06 | US3110135A | 1963-11-12 | SHMUEL BERLINSKY |
| 15 | Bevel gear having modified geometry | US14816606 | 2015-08-03 | US09776266B2 | 2017-10-03 | Gary Töpfer |
| Bevel gear having a main body comprises a heel-side skin surface. The bevel gear has at least one tooth gap, which exits from the main body in the region of the skin surface. The tooth gap has a tooth base, the profile of which is defined by a base cone angle in relation to the workpiece axis of rotation. A concentric circumferential ring structure is provided on the skin surface, which is raised in relation to the skin surface, and which results in a heel-side exit angle between the tooth base and the ring structure, which is in the range between 125° and 160°. | ||||||
| 16 | Apparatus and method for manufacturing thick-walled hollow wheels having an internal gear toothing | US13803230 | 2013-03-14 | US09174291B2 | 2015-11-03 | Fabian Ruh; Daniel Deriaz |
| A method for manufacturing a hollow wheel equipped with an internal gear toothing, wherein a work-piece includes a tubular section with a longitudinal axis, by which the term radial utilized in the following is defined. By N≧2 stamping tools, of which each one during the implementation of the method is brought into a working position, the tool for producing the gear toothing is processed on the inside of the tubular section, wherein the work-piece carries out a rotating movement with a rotation speed varying in time around the mentioned longitudinal axis and at least one stamping tool in the working position carries out radially oscillating movements, which are synchronized with the mentioned rotating movement. The at least one stamping tool in the working position processes the work-piece repeatedly. | ||||||
| 17 | Apparatus and method for manufacturing thick-walled hollow wheels having an internal gear toothing | US13803230 | 2013-03-14 | US20130287513A1 | 2013-10-31 | Fabian Ruh; Daniel Deriaz |
| A method for manufacturing a hollow wheel equipped with an internal gear toothing, wherein a work-piece includes a tubular section with a longitudinal axis, by which the term radial utilised in the following is defined. By N≧2 stamping tools, of which each one during the implementation of the method is brought into a working position, the tool for producing the gear toothing is processed on the inside of the tubular section, wherein the work-piece carries out a rotating movement with a rotation speed varying in time around the mentioned longitudinal axis and at least one stamping tool in the working position carries out radially oscillating movements, which are synchronised with the mentioned rotating movement. The at least one stamping tool in the working position processes the work-piece repeatedly. | ||||||
| 18 | SINTERED COMPOSITE AND METHOD FOR ITS MANUFACTURE | US13196971 | 2011-08-03 | US20120037104A1 | 2012-02-16 | Angelika Pohl; Alfred Boelstler |
| A method for powder-metallurgically manufacturing a rotational body, including compacting a first starting body is compacted from a metal powder; forming a second starting body from metal, separately from the first starting body; placing the starting bodies against each other in axial contact via end faces in relation to a longitudinal axis of the rotational body; and permanently and firmly sintered the first starting body and the second starting body to each other by collective sintering. The first starting body is compacted from an aluminium-based powder, the second starting body is formed from an aluminium material, and the starting bodies are sintered to each other at their respective end faces. | ||||||
| 19 | Method and apparatus for alignment of gearing | US344383 | 1982-02-01 | US4512694A | 1985-04-23 | Charles D. Foran; Jack D. Smith |
| A double helical gear set having a pair of driving pinions meshed with a pair of driven gears, respectively, is aligned by providing accurately aligned integral or demountable pinions on one shaft and aligning the driven gears using a fixture which is operable to locate a keyway or other aligning device on each of the driven gears so that the driven gears can be timed or aligned on their support shaft. The fixture has a hub member which fits in the bore of the gear hub and includes a locating pin engageable with opposed flanks of adjacent teeth at corresponding points on the tooth profile such as the pitch point. The fixture includes interchangeable locating pin support members for use in aligning helical gears having different diametral pitches and helix angles. Integral pinions of the opposed helical type are formed on a shaft and aligned with each other by providing aligned locating recesses in the shaft and mounting gear master parts on each end of the shaft which are used for centering a gear hob in the tooth spaces of the gear master parts prior to machining the gear teeth. | ||||||
| 20 | John william taylor | US510207D | US510207A | 1893-12-05 | ||
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