| 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 | 具有称重装置的运输铁轨系统 | CN201480019609.1 | 2014-04-04 | CN105190259A | 2015-12-23 | 沃尔克·瓦泽查; 埃里奇·库班德纳 |
| 本发明涉及一种能够检测铁轨车辆(2)的重量的运输铁轨系统(1)。运输铁轨系统(1)包括一个或多个铁轨(3a、3b)、以及用于测量磁特性的一个或多个传感器(7)。至少一个传感器(7)适于测量磁特性的变化,以便确定支承在一个或多个铁轨(3a、3b)上的重量,磁特性的变化由所述重量施加在所述铁轨(3a、3b)上的应力而导致。运输铁轨系统(1)的特征在于,一个或多个所述传感器(7)适于测量所述铁轨(3a、3b)本身的磁特性的变化,且/或一个或多个传感器(7)适于测量所述铁轨(3a、3b)的支撑结构(4a、4b)的磁特性的变化。本发明允许以更低的价格提供运输铁轨系统(1),因为这样的系统的复杂度可以被降低。 | ||||||
| 2 | 全自动烟草动态水分分析气候箱 | CN201310442801.9 | 2013-09-25 | CN103471958A | 2013-12-25 | 吴达; 沙云菲; 楼佳颖; 王兵; 刘百战 |
| 本发明提供一种全自动烟草动态水分分析气候箱,它包括一密闭的恒温恒湿舱,恒温恒湿舱与空气温湿度处理器连通形成空气循环回路;恒温恒湿舱的内部设有一称重台,恒温恒湿舱的内部吊有样品输送吊架,样品输送吊架的下方设有至少一个安放支架,安放支架上放置有样品皿,样品输送吊架还与位于恒温恒湿舱外部的驱动机构连接,驱动机构驱动样品输送吊架动作,将样品皿放置在称重台上称重。该全自动烟草动态水分分析气候箱,实现最大限度地减少测试周期,减少中间环节和人为操作误差,得到烟草样品含水率变化的规律,作为评价烟草保润剂性能的重要依据。 | ||||||
| 3 | 车辆的乘客分类装置 | CN201010208552.3 | 2010-06-24 | CN102189969A | 2011-09-21 | 黄载皓; 朴柔泰; 黄永秀; 朴炳赫 |
| 本发明公开了一种车辆的乘客分类装置,其可以通过坐在座位上的乘客导致的第一和第二电极之间的电场的改变而检测坐在座位上的乘客。所述乘客分类装在包括:座位,用于乘客坐在其上;第一电极,布置在所述座位内;第二电极,布置在所述座位内且与第一电极隔开,从而在第一和第二电极之间形成电场;电流检测装置,检测与由坐在座位上的乘客导致的电场变化对应的电流值的变动。 | ||||||
| 4 | 变形检测传感器及其制造方法 | CN201680015048.7 | 2016-03-02 | CN107407574A | 2017-11-28 | 福田武司; 都筑拓也; 河合敏晃 |
| 本发明人以在使用在树脂中分散有磁性填料的磁性树脂并与磁性传感器组合的变形检测传感器中,使传感器灵敏度和稳定性提高为目的。本发明提供一种变形检测传感器及其制造方法,其特征在于,所述变形检测传感器包含含磁性树脂的高分子发泡体、及检测起因于该含磁性树脂的高分子发泡体的变形的磁性变化的磁性传感器,所述含磁性树脂的高分子发泡体包含磁性树脂和高分子发泡体,所述磁性树脂在树脂中含有磁性填料,所述高分子发泡体在其一部分具有所述磁性树脂,所述磁性树脂在与磁性传感器相对设置的面或与磁性传感器相反侧的面的任一面上具有凸部。 | ||||||
| 5 | 车辆的乘客分类装置 | CN201010208552.3 | 2010-06-24 | CN102189969B | 2015-04-22 | 黄载皓; 朴柔泰; 黄永秀; 朴炳赫 |
| 本发明公开了一种车辆的乘客分类装置,其可以通过坐在座位上的乘客导致的第一和第二电极之间的电场的改变而检测坐在座位上的乘客。所述乘客分类装在包括:座位,用于乘客坐在其上;第一电极,布置在所述座位内;第二电极,布置在所述座位内且与第一电极隔开,从而在第一和第二电极之间形成电场;电流检测装置,检测与由坐在座位上的乘客导致的电场变化对应的电流值的变动。 | ||||||
| 6 | 收集固体废弃物的垃圾箱 | CN201180012908.9 | 2011-02-21 | CN102781792B | 2014-11-26 | G.罗曼; R.德托尼 |
| 本文描述了一种收集固体废弃物的垃圾箱,尤其是城市废弃物,该垃圾箱设置有用于称量由单个用户放置的产品的设备,并且是由两个容器构成的类型,外部覆盖容器(1)和用于收集废弃物的内部容器(2)。这种垃圾箱的特征在于,其包括布置在所述两个容器(1、2)之间的间隙中的刚性框架(3)。该刚性框架在较外部容器(1)的底部支撑在四个支柱(3.1)上,其中应用有轮(4),同时在上边缘(3.2)上布置有一些负载传感器(5),负载传感器支承最内部容器(2)以便能够检测由用户放置在垃圾箱中的废弃物的重量。 | ||||||
| 7 | 全自动烟草动态水分分析气候箱 | CN201310442801.9 | 2013-09-25 | CN103471958B | 2015-11-18 | 吴达; 沙云菲; 楼佳颖; 王兵; 刘百战 |
| 本发明提供一种全自动烟草动态水分分析气候箱,它包括一密闭的恒温恒湿舱,恒温恒湿舱与空气温湿度处理器连通形成空气循环回路;恒温恒湿舱的内部设有一称重台,恒温恒湿舱的内部吊有样品输送吊架,样品输送吊架的下方设有至少一个安放支架,安放支架上放置有样品皿,样品输送吊架还与位于恒温恒湿舱外部的驱动机构连接,驱动机构驱动样品输送吊架动作,将样品皿放置在称重台上称重。该全自动烟草动态水分分析气候箱,实现最大限度地减少测试周期,减少中间环节和人为操作误差,得到烟草样品含水率变化的规律,作为评价烟草保润剂性能的重要依据。 | ||||||
| 8 | 收集固体废弃物的垃圾箱 | CN201180012908.9 | 2011-02-21 | CN102781792A | 2012-11-14 | G.罗曼; R.德托尼 |
| 本文描述了一种收集固体废弃物的垃圾箱,尤其是城市废弃物,该垃圾箱设置有用于称量由单个用户放置的产品的设备,并且是由两个容器构成的类型,外部覆盖容器(1)和用于收集废弃物的内部容器(2)。这种垃圾箱的特征在于,其包括布置在所述两个容器(1、2)之间的间隙中的刚性框架(3)。该刚性框架在较外部容器(1)的底部支撑在四个支柱(3.1)上,其中应用有轮(4),同时在上边缘(3.2)上布置有一些负载传感器(5),负载传感器支承最内部容器(2)以便能够检测由用户放置在垃圾箱中的废弃物的重量。 | ||||||
| 9 | 秤 | CN200780048037.X | 2007-10-23 | CN101568810A | 2009-10-28 | 耶夫盖尼·曼哈特; 西里尔·罗特林; 马克·罗伯特; 杰罗姆·贝恩哈德 |
| 一种秤,具有用于支承将要称重的重物的支承表面(12)、导电的传感器板(3)、与传感器板(3)隔开设置的扁平线圈(7)、包围传感器板(3)及扁平线圈(7)的壳体(1,4)和按钮(6),其中扁平线圈(7)用于感应测量传感器板(3)与扁平线圈(7)之间的距离,按钮(6)突出于壳体(1,4)并且与传感器板(3)相连。根据本发明的秤结构简单,尽管如此却能够应用于多个方面。 | ||||||
| 10 | DEFORMATION DETECTION SENSOR AND PRODUCTION OF THE SAME | US15554834 | 2016-03-02 | US20180035813A1 | 2018-02-08 | Takeshi Fukuda; Takuya Tsuzuki; Toshiaki Kawai |
| The present invention provides a deformation detection sensor which combines a magnetic resin dispersing a magnetic filler in a resin with a magnetic sensor, of which stability of detection property is highly enhanced. The present invention thus provides a deformation detection sensor which comprises: a magnetic resin-containing polymer foam which comprises a magnetic resin, in which a magnetic filler is contained, and a polymer foam in which the magnetic resin is included, and a magnetic sensor that detects a magnetic change caused by a deformation of the magnetic resin-containing polymer foam, wherein the magnetic resin has a convex portion on either a surface facing the magnetic sensor or a surface facing opposite to the magnetic sensor, and its production method. | ||||||
| 11 | Temperature modulated thermogravimetric analysis | US14705612 | 2015-05-06 | US09816907B2 | 2017-11-14 | Jürgen Schawe |
| A sample is analyzed by temperature-modulated thermogravimetric analysis (TMTGA), using a thermogravimetric analysis (TGA) instrument. The TGA instrument comprises a furnace arranged in a furnace housing and an electronic balance with a load receiver arranged in a balance housing, wherein the load receiver extends into the furnace housing. A measuring position is arranged at one end of the load receiver within the furnace housing. A control unit controls the balance and/or the furnace. The TMTGA method includes at least using the TGA instrument to subject the sample to a temperature program that varies the temperature of the furnace and provides temperature-time setpoints for controlling the sample temperature, measuring the mass change of the sample as a function of time, and determining at least one kinetic parameter of the sample based on mass change. The temperature program may be stochastic and/or event-controlled in nature. | ||||||
| 12 | TEMPERATURE MODULATED THERMOGRAVIMETRIC ANALYSIS | US14705612 | 2015-05-06 | US20150323438A1 | 2015-11-12 | Jürgen Schawe |
| A sample is analyzed by temperature-modulated thermogravimetric analysis (TMTGA), using a thermogravimetric analysis (TGA) instrument. The TGA instrument comprises a furnace arranged in a furnace housing and an electronic balance with a load receiver arranged in a balance housing, wherein the load receiver extends into the furnace housing. A measuring position is arranged at one end of the load receiver within the furnace housing. A control unit controls the balance and/or the furnace. The TMTGA method includes at least using the TGA instrument to subject the sample to a temperature program that varies the temperature of the furnace and provides temperature-time setpoints for controlling the sample temperature, measuring the mass change of the sample as a function of time, and determining at least one kinetic parameter of the sample based on mass change. The temperature program may be stochastic and/or event-controlled in nature. | ||||||
| 13 | Scale | US12447041 | 2007-10-23 | US20100012395A1 | 2010-01-21 | Jevgenij Mannhart; Cyrill Röthlin; Marc Robert; Jérôme Bernhard |
| The invention relates to scales comprising a bearing surface for supporting a load to be weighed, an electroconductive sensor plate, a flat coil arranged at a distance from the sensor plate and used for the inductive measurement of a distance between the sensor plate and the flat coil, a housing surrounding the sensor plate and the flat coil, and a push-button which protrudes out of the housing and is connected to the sensor plate. The inventive scales are easy to assemble but also versatile. | ||||||
| 14 | Method and apparatus for measuring weight of CNC workpieces | US11754217 | 2007-05-25 | US07550681B2 | 2009-06-23 | Shih-Ming Wang; Ming-Hua Li |
| This invention discloses a method and apparatus for measuring the weight of a CNC workpiece. As the weight of the workpiece on a loading platform increases, the loading of a driving module which drives the loading platform in constant speed increases accordingly. On the contrary, as the weight of the workpiece on the loading platform decreases, the loading of the driving module which drives the loading platform in constant speed also decreases. This invention determines the weight of the workpiece on the loading platform by measuring the electrical signal which drives the driving module and utilizing a calibration curve data in a preconfigured database. | ||||||
| 15 | Method and Apparatus for Measuring Weight of CNC Workpieces | US11754217 | 2007-05-25 | US20080289882A1 | 2008-11-27 | Shih-Ming Wang; Ming-Hua Li |
| This invention discloses a method and apparatus for measuring the weight of a CNC workpiece. As the weight of the workpiece on a loading platform increases, the loading of a driving module which drives the loading platform in constant speed increases accordingly. On the contrary, as the weight of the workpiece on the loading platform decreases, the loading of the driving module which drives the loading platform in constant speed also decreases. This invention determines the weight of the workpiece on the loading platform by measuring the electrical signal which drives the driving module and utilizing a calibration curve data in a preconfigured database. | ||||||
| 16 | Load measuring transducer including elastic structure and gauge using induced voltage, and load measuring system using the same | US10537403 | 2004-05-10 | US20060081072A1 | 2006-04-20 | Heung Park |
| The present invention relates to a load measuring transducer including gauges and elastic structure and weighing system for measuring weight applied to a structure. The load measuring transducer of the present invention comprises a stationary gauge which is constructed of a plurality of repeated coil (or electric wire) patterns with a predetermined pitch and has both ends to which an AC electricity is applied; and a moving gauge which is provided to move in a longitudinal direction (or perpendicular direction with respect to the longitudinal direction) of the stationary gauge without contact therewith in response to the occurrence of the elastic deformation of the deformation-producing portion of the structure of the transducer. | ||||||
| 17 | Ultra-sensitive force detector employing servo-stabilized tunneling junction | US608931 | 1990-11-05 | US5103682A | 1992-04-14 | John M. Moreland; William P. Dube |
| A highly sensitive force detector using a tunneling junction as a strain gauge is disclosed. The tunneling junction is connected to a deflection member which receives the force to be measured. The junction is connected in a nulling circuit to a magnetic flux motor which generates a restoring force precisely equal to the force to be measured. The magnetic flux required by the flux motor to do so is measured by a SQUID, the output of which is directly proportional to the flux to be measured. The device has applications in pressure sensing, weighing, gravity measurements, detection of massive objects, and elsewhere. | ||||||
| 18 | Friction-free balance | US3123165D | US3123165A | 1964-03-03 | ||
| 19 | Force measuring apparatus | US73107547 | 1947-02-26 | US2620657A | 1952-12-09 | STOVALL JR JOHN R |
| 20 | Electronic balance | US43428142 | 1942-03-11 | US2360751A | 1944-10-17 | HERBERT ZIEBOLZ |
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