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    • 6. 发明专利
    • System and method for acquiring damping characteristic value of vibration insulating member
    • 振动阻尼器阻尼特性值的系统与方法
    • JP2010096628A
    • 2010-04-30
    • JP2008267552
    • 2008-10-16
    • Toyota Motor Corpトヨタ自動車株式会社
    • KONDO TAKUYAMIYAJIMA KAZUHIRONAKAYAMA TOMOMIOKAMURA HIROMASA
    • G01M13/00
    • PROBLEM TO BE SOLVED: To provide a system and a method for acquiring a damping characteristic value of a vibration insulating member which can quantitatively specify the vibration damping performance of the vibration insulating member, in relation to vibrations acting on the vibration insulating member in the inside-plane direction and the outside-plane direction, that is, the vibrations in two directions, using an extremely simple system formation or an extremely simple method.
      SOLUTION: The system 10 for acquiring the damping characteristic value of the vibration insulating member includes the vibration insulating member 2 on a surface plate 6; a block material 1 installed on the vibration insulating member 2 and provided with a through-hole 14; a sensor 3 fitted to the block material 1; first and second vibration-imparting means which make the installation attitude of the block material change and impart vibrations thereto; and a first calculating means which calculates the in-plane and out-plane vibration damping characteristic values of the vibration insulating member 2 from vibration waveforms being obtained.
      COPYRIGHT: (C)2010,JPO&INPIT
    • 要解决的问题:提供一种系统和方法,用于获得能够定量地确定隔振构件的减震性能的振动特性值,相对于作用在隔振构件上的振动 使用非常简单的系统形成或非常简单的方法,在内侧面方向和外侧面方向,即两个方向的振动。 解决方案:用于获取隔振构件的阻尼特性值的系统10包括在表面板6上的隔振构件2; 安装在隔振构件2上并设置有通孔14的块材1; 安装在块体材料1上的传感器3; 第一和第二振动赋予装置,其使块体材料的安装姿态变化并赋予振动; 以及第一计算装置,其从获得的振动波形中计算出隔振构件2的平面内和外平面振动阻尼特性值。 版权所有(C)2010,JPO&INPIT
    • 7. 发明专利
    • GAS STORAGE METHOD
    • JP2000018497A
    • 2000-01-18
    • JP18871198
    • 1998-07-03
    • TOYOTA MOTOR CORP
    • OKAZAKI TOSHIHIRONAKAMURA NAOKIKONDO TAKUYASUGIYAMA MASAHIKO
    • F17C11/00
    • PROBLEM TO BE SOLVED: To realize a remarkably high storage concentration by adsorption without applying very low temperature by keeping the gas to be stored and an adsorbent in a vessel below the liquefication temperature of the gas to be stored. SOLUTION: 5 g of activated carbon powder is charged into a sample capsule of sealed structure, and the capsule is depressurized to 1×10-6 MPa by a rotary pump. Methane is introduced into the capsule from a methane cylinder and the pressure in the capsule is controlled to 0.5 MPa. Then the capsule is dipped in the liquid nitrogen filled in a Dewar vessel and kept at the liquid nitrogen temperature (-196 deg.C) for 20 minutes, whereby the methane gas in the capsule is completely liquefied and adsorbed by the activated carbon. When the aqueous vapour generated from a water reservoir is introduced, the aqueous vapour is immediately frozen to be ice at the liquid nitrogen temperature, and the liquefied and adsorbed methane gas is frozen in the ice and sealed. Thereby, the remarkably high storage concentration can be realized by the adsorption without using a cryogenic method.
    • 8. 发明专利
    • LIQUID INFORMATION MEASURING DEVICE USING SOUND WAVE
    • JPH11153471A
    • 1999-06-08
    • JP31739197
    • 1997-11-18
    • NIPPON SOKENTOYOTA MOTOR CORP
    • SUGINO MASAYOSHISUZUKI YUTAKAKONDO TAKUYATAKAHASHI TOSHIMITSU
    • G01F23/28
    • PROBLEM TO BE SOLVED: To provide a liquid information measuring device designed to measure the liquid level and the propagation time of a sound wave by use of a single sound wave oscillating element which produces the sound wave. SOLUTION: An ultrasonic sensor S has an ultrasonic oscillating element 20 having a transmitting-receiving part 22 disposed in fuel and has reflectors 33, 34 disposed in the fuel. A reflector 35 reflects ultrasonic waves of mutually proximate frequencies transmitted from the ultrasonic oscillating element 20 and reflects the waves toward the ultrasonic oscillating element 20. The reflector 34 reflects toward the level of the fuel the ultrasonic waves transmitted from the ultrasonic oscillating element 20 and, when sound waves reflected from the level of the fuel impinge thereon, reflects the sound waves toward the transmitting-receiving part 22. A phase measuring apparatus 90 binarizes the received outputs derived from the reflected ultrasonic waves from the ultrasonic oscillating element 20, and calculates the phase difference between the binarized outputs. A microcomputer 40 calculates the propagation time of the sound wave and the level of the fuel according to the phase difference and each of the frequencies.
    • 10. 发明专利
    • IMPROVEMENT IN IGNITABILITY OF SOLID FUEL AND SOLID FUEL EXCELLENT IN IGNITABILITY
    • JPH10183147A
    • 1998-07-14
    • JP34746796
    • 1996-12-26
    • TOYOTA MOTOR CORP
    • KONDO TAKUYA
    • B01J23/74C10L5/44C10L9/10C10L10/18
    • PROBLEM TO BE SOLVED: To safely and readily improve the ignitability of a solid fuel by lowering the ignition temperature of the solid fuel by a solid or liquid oxidation catalyst having extremely low ignitability of its own by adding the oxidation catalyst. SOLUTION: (B) A solid or liquid oxidation catalyst such as (B1 ) iron (oxide) or (B2 ) iron naphthenate and optionally (C) a readily burning agent such as an alcohol or wood powder are added to (A) a solid fuel such as (A1 ) a natural wood. To be concrete, for example, the component B2 is sprayed on the component A1 to form a coated layer of the component B2 on the surface of the component A1 . Thus the ignition temperature of the component A1 is lowered from 290 deg.C as that of the component A1 alone to 230 deg.C by 60 deg.C without danger of explosion caused by heating the component B2 , an exothermic peak occurs in the vicinity of a higher temperature of 400 deg.C besides in the vicinity of 230 deg.C showing ignition, great heat generation is caused during combustion following ignition once. Not only ignitability is promoted but also the duration of combustion after ignition can be safely improved.