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    • 2. 发明专利
    • Individual constituent component detection method of two-constituent system aqueous machining liquid
    • 双组分系统水性加工液的个体构成成分检测方法
    • JPS5973237A
    • 1984-04-25
    • JP18421282
    • 1982-10-20
    • Mitsubishi Electric Corp
    • KARASHIMA TOSHIHARU
    • B23H7/36B23H7/34B23P1/16
    • B23H7/34
    • PURPOSE:To detect each constituent of a two-constituent system aqueous machining liquid in a simple method by constituting a discharge or electrolytic machining device so as to detect the composition of each constituent based on measured values of the electric conductivity and the specific gravity of an aqueous machining liquid to be measured. CONSTITUTION:In a method detecting each constituent component of a mixed aqueous solution of sodium nitrate (NaNO3) and sodium chlorate (NaClO3) typical as a two-constituent system aqueous machining liquid of an electrolytic machining device, first deionized water is used to produce an aqueous solution, either one of NaCO3 and NaClO3 is kept constant in quantity and the other is gradually increased under a fixed condition of the liquid temperature at 25 deg.C, then the electric conductivity and the specific gravity of the aqueous solution are measured for at least ten types of individual additions, a relational equation among the constituent components, electric conductivity, and specific gravity is introduced, thereby each constituent composition can be detected based on the electric conductivity and specific gravity of the aqueous solution under measurement.
    • 目的:通过构成放电或电解加工装置,通过简单的方法检测双组分体系水性加工液的各成分,以便根据导电率和比重的测定值检测各成分的组成 水性加工液待测量。 构成:在电解加工装置的典型的双组分体系水性加工液的典型的硝酸钠(NaNO 3)和氯酸钠(NaClO 3)的混合水溶液的各种检测方法中,使用第一去离子水来制造 水溶液中,将NaCO 3和NaClO 3中的任一种保持恒定,另一种在液体温度在25℃的固定条件下逐渐增加,然后测量水溶液的电导率和比重 引入至少10种单独添加,构成成分之间的关​​系式,电导率和比重,从而可以基于测量的水溶液的电导率和比重来检测各组成成分。
    • 4. 发明专利
    • Electroerosion machining system and method
    • 电动加工系统及方法
    • JP2012179708A
    • 2012-09-20
    • JP2012033783
    • 2012-02-20
    • General Electric Co ゼネラル・エレクトリック・カンパニイ
    • TRIMMER ANDREW LEELUO YUANFENGWEI BINCINTULA MARK JAMES
    • B23H3/02C25F3/00
    • B23H1/08B23H3/08B23H5/06B23H5/12B23H7/34
    • PROBLEM TO BE SOLVED: To provide a new and improved electroerosion machining system and method having a higher flushing function for machining a workpiece.SOLUTION: The electroerosion machining system 10 includes one or more electrodes 15 configured to machine a workpiece 100, a power source 13 configured to apply voltages to the workpiece 100 and the respective one or more electrodes 15, an electrolyte supply source 14 configured to pass an electrolyte, and a working apparatus 11 configured to move the respective one or more electrodes 15 relative to the workpiece 100. The electroerosion machining system 10 further includes a controller 12 configured to control the working apparatus 11 to machine the workpiece 100, and a removal agent configured to cooperate with the electrolyte from the electrolyte supply source 14 to take out a removed material from the workpiece 100. There is also provided the electrochemical machining method.
    • 要解决的问题:提供一种新的改进的电腐蚀加工系统和方法,其具有用于加工工件的较高的冲洗功能。 电解加工系统10包括构造成加工工件100的一个或多个电极15,被配置为向工件100和相应的一个或多个电极15施加电压的电源13,配置为 通过电解质,以及被配置为相对于工件100移动相应的一个或多个电极15的加工装置11.电腐蚀加工系统10还包括控制器12,其被配置为控制加工装置11加工工件100,以及 配置成与来自电解质供应源14的电解质配合以从工件100中取出去除的材料的去除剂。还提供了电化学加工方法。 版权所有(C)2012,JPO&INPIT
    • 6. 发明专利
    • Electric discharging machine and electric discharging method
    • 电动放电机和电动放电方法
    • JP2010012592A
    • 2010-01-21
    • JP2009017541
    • 2009-01-29
    • Sodick Co Ltd株式会社ソディック
    • TAKAHASHI YASUNARIKANEKO YUJIHARADA TAKENORIDOI YUZOWAKAI AKIRA
    • B23H1/02B23H1/10
    • B23H1/10B23H7/02B23H7/34B23H7/36
    • PROBLEM TO BE SOLVED: To provide an electric discharging machine which can flexibly cope with various forms of corrosion of workpieces, and to provide an electric discharging method. SOLUTION: In the electric discharging machine 1, while immersing a workpiece W in a working fluid, a bipolar voltage which has bipolarity, that is, a straight polarity in which the workpiece W has a positive potential while a tool electrode E has a negative potential and a reversed polarity in which the workpiece has a negative potential while the tool electrode E has a positive potential, is applied to an interpolar portion 9 formed between the workpiece W and a wire electrode E to generate electric discharge and to perform electric discharge machining of the workpiece W. The electric discharging machine 1 comprises an average voltage setting device 50 which sets the average of voltages applied to the interpolar portion 9 to a predetermined value, and an adenine-adding device 44 that adds adenine to a working fluid. The average voltage of the interpolar portion 9 is set to a predetermined value, and, further, adenine is added to the working fluid. COPYRIGHT: (C)2010,JPO&INPIT
    • 要解决的问题:提供一种能够灵活应对各种形式的工件腐蚀的放电机,并提供放电方法。 解决方案:在放电机1中,在将工件W浸入工作流体中时,具有双极性的双极性电压,即工具电极E具有正电位的直线极性 在工具电极E具有正电位时工件具有负电位的负电位和相反的极性被施加到形成在工件W和线电极E之间的极间部分9,以产生放电并进行电 工件W的放电加工。放电机1包括将施加到极间部分9的电压的平均值设定为预定值的平均电压设定装置50和将腺嘌呤添加到工作流体的腺嘌呤添加装置44 。 将极间部分9的平均电压设定为预定值,此外,将腺嘌呤加入到工作流体中。 版权所有(C)2010,JPO&INPIT
    • 9. 发明专利
    • 放電加工方法および電極ガイド位置設定装置
    • 放电加工方法和电极引导位置设定装置
    • JPWO2014038074A1
    • 2016-08-08
    • JP2014534131
    • 2012-09-07
    • 株式会社牧野フライス製作所
    • 恭一 浜田恭一 浜田孝幸 塩水孝幸 塩水
    • B23H7/20B23H7/26B23H7/36
    • B23H7/18B23H1/00B23H7/20B23H7/34B23H9/10B23H9/14G05B15/02G05B19/402G05B2219/25294G05B2219/35134G05B2219/45043G05B2219/45221Y02P90/265
    • 傾斜したワークの表面に孔加工を施す場合に、電極ガイドがワーク表面に干渉するという課題を解決するために、本発明では、電極ホルダ(7)と電極ガイド(8)を有する放電加工機(100)によりワークを放電加工する際、予めワークモデル(321)と電極ガイドモデル(323)とを生成し、軸線(CLa)に沿って電極ガイドモデル(323)をワークモデル(321)に接近させたときの電極ガイドモデル(323)がワークモデル(321)に干渉し始める干渉開始位置を演算し、干渉開始位置を起点として、電極ガイドモデル(323)をワークモデル(321)から離れる方向に所定量移動させた位置を電極ガイド位置として設定する。そして、電極ガイド(8)を電極ガイド位置に位置決めした状態で、電極ホルダ(7)の下降により電極(10)をワーク表面に向けて下降し、ワークを放電加工する構成とした。
    • 当经受孔加工的倾斜工件到电极引导件的表面上解决了与工件表面的干扰问题,在本发明中,电极支架(7)和电极引导件(8),其具有放电加工机( 当放电加工100的工件),它是先前产生的在工作模型中的工作模型(321)和电极引导件模型(323),靠近轴沿着CLA(电极引导件模型)(323)(321) 电极引导件模型(323)计算干扰起始位置开始与工件模型(321)到干扰,从干涉起始位置开始,拥有在一个方向上的电极引导件模型(323)从所述工作模型(321)的距离,当 设定由定量而得到的位置移动作为电极引导位置。 然后,在状态被定位电极引导件(8)到电极引导位置,电极(10)由电极支架(7)的降低,并且被配置成放电加工工件朝向工件表面下降。