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    • 1. 发明申请
    • Ultrasonic Testing Method and Ultrasonic Testing Device Using This
    • 超声波检测方法及超声波检测装置
    • US20080302188A1
    • 2008-12-11
    • US11988306
    • 2006-06-30
    • Hideki YabushitaTatsuyuki NagaiShigeyuki MatsubaraNorio NemotoHiroshi Miyamoto
    • Hideki YabushitaTatsuyuki NagaiShigeyuki MatsubaraNorio NemotoHiroshi Miyamoto
    • G01N29/24
    • G01N29/225G01N29/2487G01N2291/02854G01N2291/0425G01N2291/0427G01N2291/057G01N2291/102G01N2291/2693
    • A ultrasonic testing method capable of carrying out a test of high degree of freedom where a degree of freedom of arranging a transmission element and a reception element is high and the scope of an object of testing is not likely to be limited, and a ultrasonic testing device using this. An ultrasonic wave is sent from a transmission element (20) to a test element (100) to produce a plate wave in the test element, and the plate wave propagating through the test element is received by a reception element (30) to thereby test the test element on the propagation route of the plate wave. The other probe that is the other reception element (20) or transmission element (30) is disposed between the transmission element (20) and the reception element (30). A probe holding mechanism (40) that has support legs (46) contacting the surface of the test element and keeps constant an angle of the other probe with respect to the surface of the test element is allowed to support the other probe. And, the other probe is allowed to cross over in non-contact the propagation route of the plate wave extending from the transmission element to the reception element by means of support legs (46).
    • 能够进行发送元件和接收元件的配置的自由度高,测试对象的范围不太可能被限制的高自由度的超声波检测方法,超声波检查 设备使用这个。 从传输元件(20)向测试元件(100)发送超声波,以在测试元件中产生平板波,并且通过接收元件(30)接收通过测试元件传播的平板波,从而测试 测试元件在板波传播路径上。 作为另一个接收元件(20)或发送元件(30)的另一个探针被配置在发送元件(20)和接收元件(30)之间。 具有支撑腿(46)的探针保持机构(40)允许支撑腿(46)与测试元件的表面接触并且使另一个探针相对于测试元件的表面保持恒定的角度来支撑另一个探针。 并且,另一个探针被允许通过支撑腿(46)非接触地从传播元件延伸到接收元件的板波的传播路径交叉。
    • 3. 发明授权
    • Ultrasonic wave testing method and ultrasonic testing device using this method
    • 超声波检测方法及超声波检测装置采用该方法
    • US08225668B2
    • 2012-07-24
    • US11988304
    • 2006-06-30
    • Hideki YabushitaTatsuyuki NagaiShigeyuki MatsubaraNorio NemotoHiroshi Miyamoto
    • Hideki YabushitaTatsuyuki NagaiShigeyuki MatsubaraNorio NemotoHiroshi Miyamoto
    • G01N29/26
    • G01N29/2456G01N29/223G01N29/2487G01N2291/0231G01N2291/0425G01N2291/0427G01N2291/056G01N2291/101G01N2291/2693G01N2291/2694
    • An ultrasonic wave propagating method capable of propagating plate waves between a probe and a test piece despite variations in the thickness or the surface angle of a test piece, and an ultrasonic propagating device and an ultrasonic testing device using this method. Ultrasonic waves are propagated between a probe (20) for transmitting or receiving ultrasonic waves and a test piece (100) for propagating plate waves. When propagating ultrasonic waves, a probe that can set an ultrasonic wave incident angle from the probe (20) to the test piece (100) and/or an ultrasonic wave receivable angle from the test piece to the probe in a plurality of states is used. A focal point type probe may be used as the above probe (20). When this type of a probe is used, it is oriented such that an oscillating direction axis L1 in the direction of which a reference axis along the propagation route of ultrasonic waves is oscillated around the focal point of the probe crosses the propagation element surface L2 including the test piece surface of a ultrasonic wave propagation element.
    • 尽管测试件的厚度或表面角度发生变化,但是使用该方法的超声波传播装置和超声波检测装置,能够在探针和试验片之间传播平板波的超声波传播方法。 超声波在用于发送或接收超声波的探针(20)和用于传播平板波的测试片(100)之间传播。 当传播超声波时,可以使用能够以多个状态从探头(20)到测试件(100)设置超声波入射角和/或从测试片到探针的超声波可接收角度的探针 。 可以使用焦点型探针作为上述探针(20)。 当使用这种类型的探针时,其取向为使得沿着超声波的传播路径的参考轴在探针的焦点周围摆动的方向的振动方向轴线L1穿过传播元件表面L2,包括: 超声波传播元件的测试片表面。
    • 5. 发明授权
    • Ultrasonic test method and ultrasonic test instrument used for the method
    • 超声波检测方法和超声波检测仪用于该方法
    • US07721606B2
    • 2010-05-25
    • US11667772
    • 2005-11-11
    • Makoto ShiraiHiroshi MiyamotoShigeyuki Matsubara
    • Makoto ShiraiHiroshi MiyamotoShigeyuki Matsubara
    • G01N9/24
    • G01N29/043G01N29/07G01N29/223G01N29/32G01N29/38G01N2291/0231G01N2291/0427G01N2291/044G01N2291/056G01N2291/102G01N2291/2694
    • An ultrasonic test method for detecting a defective portion more precisely in a noncontact reflection way, and ultrasonic test instrument used for the method. An ultrasonic wave is transmitted from a transmitter (20 (21)) provided on one side of an object under test, and the reflected wave is received by a receiver (30 (31)) provided on the same side. The ultrasonic wave is transmitted/received through an air layer between the transmitter and the object (100) under test and between the receiver and the object (100). The relative positions of the transmitter (20), the receiver (30), and the object (100) are so determined that the air propagation time ta of the air path (RA) between the transmitter and the receiver is longer than the propagation time tb of the reflected wave in the reflection path (RB). The propagation of the ultrasonic wave through the solid body between the transmitter and the receiver is blocked. This invention is suitable to test laminated material (100) such as a laminate of CFRP (101) and insulation (102) in a noncontact way.
    • 一种用于以非接触反射方式更准确地检测缺陷部分的超声波测试方法,以及用于该方法的超声波测试仪器。 从设置在被测物体的一侧的发送器(20(21))发送超声波,反射波由设置在同一侧的接收器(30(31))接收。 超声波通过发射机与待测物体(100)之间的空气层和接收器与物体(100)之间的空气层进行传送/接收。 如此确定发射器(20),接收器(30)和物体(100)的相对位置,使得发射器和接收器之间的空气路径(RA)的空气传播时间ta比传播时间长 反射波(RB)中的反射波的tb。 超声波在发射机和接收机之间通过固体的传播被阻断。 本发明适合以非接触方式测试诸如CFRP(101)和绝缘体(102)的层压材料的层压材料(100)。
    • 6. 发明申请
    • Ultrasonic Test Method And Ultrasonic Test Instrument Used For The Method
    • 用于该方法的超声波测试方法和超声波测试仪器
    • US20080127731A1
    • 2008-06-05
    • US11667772
    • 2005-11-11
    • Makoto ShiraiHiroshi MiyamotoShigeyuki Matsubara
    • Makoto ShiraiHiroshi MiyamotoShigeyuki Matsubara
    • G01N29/00
    • G01N29/043G01N29/07G01N29/223G01N29/32G01N29/38G01N2291/0231G01N2291/0427G01N2291/044G01N2291/056G01N2291/102G01N2291/2694
    • An ultrasonic test method for detecting a defective portion more precisely in a noncontact reflection way, and ultrasonic test instrument used for the method. An ultrasonic wave is transmitted from a transmitter (20 (21)) provided on one side of an object under test, and the reflected wave is received by a receiver (30 (31)) provided on the same side. The ultrasonic wave is transmitted/received through an air layer between the transmitter and the object (100) under test and between the receiver and the object (100). The relative positions of the transmitter (20), the receiver (30), and the object (100) are so determined that the air propagation time ta of the air path (RA) between the transmitter and the receiver is longer than the propagation time tb of the reflected wave in the reflection path (RB). The propagation of the ultrasonic wave through the solid body between the transmitter and the receiver is blocked. This invention is suitable to test laminated material (100) such as a laminate of CFRP (101) and insulation (102) in a noncontact way.
    • 一种用于以非接触反射方式更准确地检测缺陷部分的超声波测试方法,以及用于该方法的超声波测试仪器。 从设置在被测物体的一侧的发送器(20(21))发送超声波,反射波由设置在同一侧的接收器(30(31))接收。 超声波通过发射机与待测物体(100)之间的空气层和接收器与物体(100)之间的空气层进行传送/接收。 如此确定发射器(20),接收器(30)和物体(100)的相对位置,使得发射器和接收器之间的空气路径(RA)的空气传播时间ta比传播时间长 反射波(RB)中的反射波的tb。 超声波在发射机和接收机之间通过固体的传播被阻断。 本发明适合以非接触方式测试诸如CFRP(101)和绝缘体(102)的层压材料的层压材料(100)。
    • 9. 发明授权
    • Process for producing metallic lithium
    • 金属锂制造方法
    • US08911610B2
    • 2014-12-16
    • US13608561
    • 2012-09-10
    • Eiji NakamuraHiroaki TakataYukihiro YokoyamaHiroshi Miyamoto
    • Eiji NakamuraHiroaki TakataYukihiro YokoyamaHiroshi Miyamoto
    • C25C3/02C01D15/04
    • C01D15/04C25C3/02
    • Provided is a safe and efficient method for producing lithium metal which facilitates efficient production of anhydrous lithium chloride without corrosion of the system materials by chlorine gas or molten lithium carbonate, and which allows production of lithium metal by molten salt electrolysis of the produced anhydrous lithium chloride as a raw material. The method includes the steps of (A) contacting and reacting lithium carbonate and chlorine gas in a dry process to produce anhydrous lithium chloride, and (B) subjecting the raw material for electrolysis containing the anhydrous lithium chloride to molten salt electrolysis under such conditions as to produce lithium metal, wherein the chlorine gas generated by the molten salt electrolysis in step (B) is used as the chlorine gas in step (A) to continuously perform steps (A) and (B).
    • 提供了一种安全有效的生产锂金属的方法,其有助于无氯氯化物的有效生产,而不会由于氯气或熔融碳酸锂而使系统材料腐蚀,并且通过熔融盐电解生产无机氯化锂的锂金属 作为原料。 该方法包括以下步骤:(A)在干法中使碳酸锂和氯气接触并反应生成无水氯化锂;(B)将含有无水氯化锂的电解原料进行熔融盐电解, 为了生产锂金属,其中在步骤(B)中通过熔融盐电解产生的氯气用作步骤(A)中的氯气,以连续进行步骤(A)和(B)。