| 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 | 用于超声波振动辅助加工的设备 | CN200480043874.X | 2004-08-26 | CN101014436A | 2007-08-08 | 刘向东; 丁欣 |
| 本发明提供一种用于超声波振动辅助加工的设备,所述设备包括:超声波转换器,用于在振动臂中产生超声波;位于所述超声波的静态节点处在所述振动臂上的第一钳;以及位于所述第一钳与所述振动臂的最下端之间的第二钳。所述第二钳包括线性轴承,用于减小所述振动臂在所述振动臂的横向方向上的振动,并用于允许所述振动臂在所述振动臂的纵向方向上的振动。 | ||||||
| 2 | 一种轧辊辊颈超声波冲击硬化方法 | CN201410845695.3 | 2014-12-31 | CN104607666A | 2015-05-13 | 朱庆华; 马旭东; 秦斌 |
| 本发明公开一种轧辊辊颈超声波冲击硬化方法,应用于工件表面硬化处理。用到的设备包括超声波光整设备、带有圆弧形刀具的数控车床,加工步骤包括:将轧辊装卡于车床上,将超声波光整设备连接到车床的刀具上,使刀具的圆弧中心与辊颈表面接触;开启超声波设备和车床,并从辊颈的轴径里侧对刀,轧辊旋转的最大线速度不超过80m/min,纵向走刀量0.25-0.3mm,使吃刀深度达到0.25-0.5mm,调整超声波光整设备的电流值至1.0A~1.3A,走刀方向由轴径里侧向外走;走刀完毕后,关闭超声波光整设备的开关。本发明经超声波处理后的金属表面能够达到更理想的表面粗糙度要求,能够提高辊颈表面的显微硬度、耐磨性、耐腐蚀性及疲劳强度和疲劳寿命。 | ||||||
| 3 | 用于超声波振动辅助加工的设备 | CN200480043874.X | 2004-08-26 | CN100553835C | 2009-10-28 | 刘向东; 丁欣 |
| 本发明提供一种用于超声波振动辅助加工的设备,所述设备包括:超声波转换器,用于在振动臂中产生超声波;位于所述超声波的静态节点处在所述振动臂上的第一钳;以及位于所述第一钳与所述振动臂的最下端之间的第二钳。所述第二钳包括线性轴承,用于减小所述振动臂在所述振动臂的横向方向上的振动,并用于允许所述振动臂在所述振动臂的纵向方向上的振动。 | ||||||
| 4 | 用于在刀具上产生旋转超声振动的装置 | CN201480026115.6 | 2014-05-05 | CN105531057A | 2016-04-27 | M·鲍尔; F·迪施特尔 |
| 本发明涉及一种用于在刀具上产生旋转超声振动的装置(1),该装置包括:第一部分(11),其设计用于与围绕旋转轴线(2)旋转的机床主轴旋转固定地连接;第二部分(12),其设计用于与刀具旋转固定地连接;爪式联接器(10),其与两个部分(11,12)相互旋转固定地连接,且具有至少一个第一侧面(5)在第一部分上和至少一个第二侧面(7)在第二部分(12)上的形状配合,第二侧面(7)与第一侧面(5)相对;以及至少一个压电振荡元件(8),其设置在爪式联接器(10)的两个侧面(5,7)之间以用于产生旋转超声振动。 | ||||||
| 5 | 基于切削液超声空化与刀具振动复合的微小孔钻削方法 | CN201510846630.5 | 2015-11-27 | CN105312607A | 2016-02-10 | 梁志强; 张素燕; 王西彬; 聂倩倩; 周天丰; 焦黎; 解丽静; 刘志兵; 颜培 |
| 本发明公开一种基于切削液超声空化与刀具振动复合的微小孔钻削方法,能够针对微小孔钻削加工的特点,提高断屑排屑能力,降低钻削力和扭矩,提高孔的表面质量和尺寸形状精度,该发明可实现微小孔的精密钻削,其主要方法为将钻削刀具安装在钻削主轴上,利用钻削主轴的振动功能对钻削刀具施加轴向超声振动;将待加工零件放置于装有水基切削液的箱体内,使切削液漫过待加工零件,将超声振动装置的振动杆的一端安置于切削液中待加工零件的附近,通过超声波发生器对振动杆施加轴向超声振动,激发切削液的超声空化效应。通过钻削刀具的超声振动作用和切削液的超声空化效应实现微小深孔的精密钻削。 | ||||||
| 6 | 用于成形工件的方法 | CN201380041761.5 | 2013-08-07 | CN104520026A | 2015-04-15 | 豪格·海西尔; 哈拉德·海西尔; 托马斯·海西尔 |
| 本发明涉及用于成形工件(2)的方法(31),其中工件(2)被引入接触刀具(3)并且紧靠刀具(3)放置,以相对于刀具(3)的相对速度(vR)移动,其中相对速度(vR)具有恒定分量(vK)和变化分量(vS)。为了减少要施加的制造力或成形力,根据本发明,前提条件是变化分量(vS)对恒定分量(vK)的比率大于或等于0.7。 | ||||||
| 7 | 装备刀具的超声波振动体的支承结构 | CN201380039210.5 | 2013-07-23 | CN104470664A | 2015-03-25 | 大西一正 |
| 提供一种支承结构,通过以高稳定性来支承刀具与超声波振动体二者的振动复合体,并且将超声波振动体上产生的超声波振动的振动能量向该复合体的支承体(固定支承体)的泄漏抑制于低水平,从而使得振动能量可以高效率地施加给刀具。采用在装备刀具的超声波振动体上附设凸缘,使凸缘的单侧侧面与另行准备的形成在固定体上的凸缘支承面,在作用有应力的状态下接触从而进行结合支承的支承结构,其中采用如下结构:超声波振动体的凸缘不接合到固定体的凸缘支承面,再者与固定体的支承面相接触而被结合支承的超声波振动体的凸缘,在该超声波振动体处于振动状态时沿凸缘的厚度方向进行超声波振动。 | ||||||
| 8 | 带有工件台振动单元的机床及工件加工方法 | CN201180049132.8 | 2011-10-12 | CN103313821A | 2013-09-18 | 阿克塞尔.黑森坎普尔; 汉斯-约尔格.普克尔 |
| 本发明涉及一种用于使用刀具(2)加工工件(1)的机床(10),其具有机器框架(5),与机器框架相连接的刀架(4),与机器框架相连接的工件台(3),和用于振动工件台的第一振动单元(11),其优选地具有大于5kHz或大于10kHz的振动频率。 | ||||||
| 9 | 超声波加工主轴装置 | CN200680024192.3 | 2006-06-29 | CN101213042A | 2008-07-02 | 久保田治; 由井隆行; 古川英雄 |
| 本发明不产生部件的磨耗或损伤,此外也不需要定期的部件更换,能对超声波产生元件提供稳定的电信号。在构成加工主轴(101)的轴(30)的壳体(1)的外周面,卷绕装配有连接于振动器(6)的接收线圈(11),另一方面,在其周围,隔开适宜的间隔并以同轴状设置有发送线圈(12),从超声波驱动装置(21)输出的、用于驱动振动器(6)的预定的电信号被施加在发送线圈(12)上,能通过发送线圈(12)和接收线圈(11)间的电磁感应并经接收线圈(11)向振动器(6)施加预定的电信号。 | ||||||
| 10 | Electrically-adjustable tool holder | US14711951 | 2015-05-14 | US09744600B2 | 2017-08-29 | Ming-Lu Yang; Yang-Mao Peng; Jian-Shi Jia; Jing-Shuang Sui; Zhen-Guang Xu; Jie Li |
| An electrically-adjustable tool holder precisely movable in a straight line within a magnetic field under electrical stimulation includes a handle body, a connecting member, and a driving member. The connecting member has a first end securely coupled to an end of the handle body, a second end opposite to the first end, and defines a through hole passing through the first end and the second end. The driving member includes a magnet securely received in the through hole, and an electrical electric coil movably received in the magnet. The electric coil is configured to be securely coupled to the tool, and moves the tool up or down along the central axis of the handle body. | ||||||
| 11 | Method and device for producing a vibrating motion of a mass | US13979149 | 2012-01-09 | US09505062B2 | 2016-11-29 | Holger Hielscher; Harald Hielscher; Thomas Hielscher |
| The invention relates to a method and device for producing an oscillatory motion of a mass, in particular of a tool, wherein the mass is mechanically connected to at least two clamping elements between said clamping elements in the direction of oscillation propagation and the mass (50) is clamped in by the two clamping elements (10, 20) under the application of pressing force (F), and at least the clamping elements are designed as components of a resonance system, and an excitation oscillation is introduced into the resonance system, the frequency of the excitation oscillation substantially corresponding to the resonance frequency of the resonance system so that the resonance system oscillates. The invention further relates to a method for processing solid or liquid material while using the method according to the invention in order to produce an oscillatory motion of a mass. | ||||||
| 12 | ACOUSTIC BREAKTHROUGH DETECTION | US15041636 | 2016-02-11 | US20160229019A1 | 2016-08-11 | Quinlan Yee Shuck; Martin Lee McCormick |
| Disclosed techniques include creating a pressure differential within an interior of a dual-wall component relative to pressure at an exterior of the dual-wall component, fabricating a hole in a first wall of the dual-wall component, while fabricating the hole in the first wall of the dual-wall component, acoustically monitoring the hole fabrication, while acoustically monitoring the hole fabrication, detecting breakthrough of the first wall of the dual-wall component based on an acoustic signal due to gas passing through the fabricated hole, and based on the acoustic signal, ceasing the fabrication of the hole. | ||||||
| 13 | METHOD FOR SHAPING A WORKPIECE | US14420097 | 2013-08-07 | US20150202671A1 | 2015-07-23 | Holger Hielscher; Harald Hielscher; Thomas Hielscher |
| The invention relates to a method (31) for shaping a workpiece (2), in which the workpiece (2) is brought into contact with a tool (3) and, lying against the tool (3), is moved at a relative velocity (vR) in relation to the tool (3), wherein the relative velocity (vR) has a constant component (vK) and a changing component (vS). In order to reduce fabricating or shaping forces to be applied, it is provided according to the invention that a ratio of the changing component (vS) to the constant component (vK) is greater than or equal to 0.7. | ||||||
| 14 | Modularized ultrasonic vibration machining apparatus | US12968801 | 2010-12-15 | US08522893B2 | 2013-09-03 | Zhong-Yi Yang; Hui-Ping Lin |
| A modularized ultrasonic vibration machining apparatus is provided, which includes a tool holder module. The tool holder module further includes: a housing, having a positioning pin disposed thereon; a tool holder linking part, disposed in the housing; a transmitting mechanism, disposed in the housing and linked to the tool holder linking part in a transmission manner; an expanding device, disposed in the housing and linked to the transmitting mechanism in a transmission manner; a piezoelectric element, disposed in the housing and linked to the expanding device; and an electrical connector, disposed in the housing and electrically connected to the piezoelectric element and the positioning pin. Therefore, the modularized tool holder has an internal vibration mechanism and closed circuit setting of power supply, is capable of being assembled and applied conveniently, and has good security, economical efficiency, and applicability in industry. | ||||||
| 15 | Tool Head and Method of Cutting Machining | US13558637 | 2012-07-26 | US20130028675A1 | 2013-01-31 | Ulrich Vogler; Francois Brouet; Thorsten Fausta |
| The present invention concerns a tool head comprising a machine connection for connecting the tool head to a machine tool, and a tool 5 portion which either has at least one geometrically defined cutting edge or has a receiving means for a tool insert having a geometrically defined cutting edge. To provide a tool head, like a drilling head, and a method with which highly precise machining is possible with very high feed speeds and good surface quality without the cutting edge being exposed to 10 a high rate of wear, it is proposed that there is a converter for converting electrical AC voltage into a mechanical vibration, wherein the converter is arranged, designed and connected to the tool portion so that the unit comprising the converter and the tool portion and possibly a tool insert 15 received in the receiving means can be excited to perform an ultrasonic vibration. | ||||||
| 16 | ULTRASONIC MACHINING MODULE | US13046099 | 2011-03-11 | US20110222975A1 | 2011-09-15 | Matthew A. Short |
| A device for use in a machining system, including an ultrasonic transducer, wherein the ultrasonic transducer is adapted to receive a tool bit; a housing adapted to be both compatible with the machining system and to receive the ultrasonic transducer, wherein the housing is operative to isolate all radial and other vibrations generated by the ultrasonic transducer except the axial vibrations transmitted to the tool bit; and a tool holder, wherein the tool holder and the top portion of the housing are mechanically coupled to one another. | ||||||
| 17 | Spindle and flexible hinge used in ultrasonic machine | US12117187 | 2008-05-08 | US07816840B2 | 2010-10-19 | Kuo-Yu Tang; Chun-Hung Huang; Yu-Chieh Chen |
| A spindle used in an ultrasonic machine for transmitting vibration to a working tool of the ultrasonic machine is disclosed. The spindle includes a main body, a rotor disposed in the main body, an elastic clamping unit disposed in the rotor, a vibrating unit having one end thereof connected to the inner wall of the rotor while the other end connected to the elastic clamping unit, and a pre-pressure unit penetrating the rotor and one end thereof connected to the elastic clamping unit to provide the elastic clamping unit with rigidity against the rotor, thereby making the elastic clamping unit provide pre-pressure to the vibrating unit which further provides the elastic clamping unit with vibration against the rotor. The present invention further provides a flexible hinge for the spindle. | ||||||
| 18 | SPINDLE AND FLEXIBLE HINGE USED IN ULTRASONIC MACHINE | US12117187 | 2008-05-08 | US20090146530A1 | 2009-06-11 | Kuo-Yu TANG; Chun-Hung Huang; Yu-Chieh Chen |
| A spindle used in an ultrasonic machine for transmitting vibration to a working tool of the ultrasonic machine is disclosed. The spindle includes a main body, a rotor disposed in the main body, an elastic clamping unit disposed in the rotor, a vibrating unit having one end thereof connected to the inner wall of the rotor while the other end connected to the elastic clamping unit, and a pre-pressure unit penetrating the rotor and one end thereof connected to the elastic clamping unit to provide the elastic clamping unit with rigidity against the rotor, thereby making the elastic clamping unit provide pre-pressure to the vibrating unit which further provides the elastic clamping unit with vibration against the rotor. The present invention further provides a flexible hinge for the spindle. | ||||||
| 19 | Apparatus For Ultrasonic Vibration-Assisted Machining | US11661082 | 2004-08-26 | US20070257579A1 | 2007-11-08 | Xiang Liu; Xin Ding |
| Apparatus for ultrasonic vibration-assisted machining, the apparatus comprising an ultrasonic transducer for generating ultrasonic waves in a vibration horn; first clamp on the vibration horn at a static node of the ultrasonic waves; and a second clamp between the first clamp and a lowermost end of the vibration horn. The second clamp comprises a linear bearing for reducing vibration of the vibration horn in a direction laterally of the vibration horn, and allowing vibration of the vibration horn in the direction of a longitudinal axial of the vibration horn. | ||||||
| 20 | TOOL HOLDER | US15756281 | 2016-08-11 | US20180264611A1 | 2018-09-20 | Gaston SCHWENK; Jens KETELAER; Manuel PRAETORIUS |
| The present invention relates to a tool holder for accommodating a tool, having a housing, a transmitting element, movably arranged in the housing, for transmitting a movement to the tool accommodated at a first end portion of the tool holder, a fastening portion at a second end portion of the tool holder, located opposite the first end portion of the tool holder, for fastening the tool holder to a machine tool, and a coolant line portion for conducting coolant from the second end portion of the tool holder to the first end portion of the tool holder, wherein the coolant line portion has a first section extending through the transmitting element, wherein the first section is configured at least in part as a bore in the transmitting element. | ||||||
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