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    • 3. 发明授权
    • Measuring method of sphericity of ball end mill
    • 球头铣刀的球形度测量方法
    • US5880847A
    • 1999-03-09
    • US965997
    • 1997-11-07
    • Shunske WakaokaTakao Hasebe
    • Shunske WakaokaTakao Hasebe
    • G01B11/30B23Q17/00B23Q17/22B23Q17/24G01B11/24G01B21/30
    • G01B11/2408
    • A method of automatically measuring sphericity of a ball end mill on a machining device under nearly identical conditions to those at the time of machining. Under a cross rail 1 of the machining device, a laser measuring device (6) is placed through a mount (7) so that a laser optical axis "a" is in the X-axis direction. A ball end mill T is fixed through a milling chuck (5) to a main spindle (4) carried rotatably by a main spindle ram (3) that can be positioned along the Z-axis direction of a main spindle head 2, which can itself be positioned in the Y-axis direction. While rotating, the tip of ball end mill T is set using laser beams. A position shifted by one radius of a tool from the tip is set as the ball center. One radius of a cutting face is measured by sliding the ball end mill on the nominal of the ball per an arbitrary angle within 90.degree.. The sphericity of the ball end mill T is obtained from the respective one radius at each angle.
    • 在几乎相同的条件下,在加工装置上自动测量球头铣刀的球形度的方法。 在加工装置的横梁1的下方,激光测量装置(6)通过安装件(7)放置,使得激光光轴“a”处于X轴方向。 球头铣刀T通过铣削卡盘(5)固定到主轴(4)上,该主轴(4)可以沿着主轴头2的Z轴方向定位的主轴冲头(3)可旋转地承载, 本身位于Y轴方向。 当旋转时,球头铣刀T的尖端使用激光束设置。 从尖端移动刀具的一个半径的位置被设定为球中心。 切割面的一个半径是通过在90度内任意角度将球头立铣刀在标称的球上滑动来测量的。 球头铣刀T的球形度从各自的一个半径获得。
    • 5. 发明授权
    • Method for automatically correcting deflection of stylus in digitizing
device
    • 自动校正数字化设备中触针偏转的方法
    • US5115401A
    • 1992-05-19
    • US441318
    • 1989-11-27
    • Hiroshi OyamaTakao Hasebe
    • Hiroshi OyamaTakao Hasebe
    • G01B21/20B23Q35/121G01B5/012G01B21/00G05B19/408
    • G01B5/012
    • The method for automatically correcting deflection of a stylus in a digitizing device enables correction of the displacement of the stylus. The coefficient of deflection correction is calculated by utilizing the fact that the displacement and deflection of the stylus are both in proportion to the contact pressure between the stylus and a three-dimensional model. A is a method for automatically correcting a deflection of a stylus in a digitizing device wherein the stylus held at a tracer head in the digitizing device is moved along surfaces of a three-dimensional model, and digitized data representing configuration of the three-dimensional model is calculated from the relative position between the three-dimensional model and the tracer head and the displacement of the stylus, includes the steps of moving the stylus in a direction of a predetermined axis relatively to the three-dimensional model, determining the relative position as a first relative position when a displacement of the stylus approximates a predetermined first displacement, determining the relative position as a second relative position when it approximates a predetermined second displacement, automatically obtaining a deflection correction coefficient of the stylus from the first and second displacements and the first and second relative positions, and automatically correcting the displacement of the stylus using the thus obtained deflection correction coefficient.
    • 用于自动校正数字化装置中的触针的偏转的方法能够校正触针的位移。 通过利用触针的位移和偏转都与触针和三维模型之间的接触压力成比例的事实来计算偏转校正系数。 A是用于自动校正数字化装置中的触针的偏转的方法,其中保持在数字化装置中的示踪器头的触针沿三维模型的表面移动,并且表示三维模型的配置的数字化数据 是从三维模型与示踪器头部之间的相对位置以及触控笔的位移计算的,包括以下步骤:相对于三维模型沿着预定轴线的方向移动触控笔,将相对位置确定为 当触针的位移接近预定的第一位移时的第一相对位置,当其近似于预定的第二位移时,将相对位置确定为第二相对位置,从第一和第二位移自动获得触针的偏转校正系数,并且 第一和第二相对位置,并自动校正t 使用由此获得的偏转校正系数来移动触控笔。