传感器一致性测试工装使用说明V1.1版

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浙江高联科技开发有限公司目录CSY-XS-01传感器系统实验箱说明书：一、产品简介二、实验箱组成三、产品特点四、传感器五、V9.0数据采集卡及处理软件CSY-XS-01传感器系统实验箱使用（示范实验举例）实验一应变片单臂特性实验实验二应变片半桥特性实验实验三应变片全桥特性实验实验四应变片单臂、半桥、全桥特性比较实验五应变直流全桥的应用—电子秤实验实验六应变片的温度影响实验*实验七应变片温度补偿实验实验八移相器、相敏检波器实验实验九应变片交流全桥的应用(应变仪)—振动测量实验实验十压阻式压力传感器的压力测量实验实验十一电容式传感器的位移实验实验十二差动变压器的性能实验实验十三激励频率对差动变压器特性的影响实验十四差动变压器零点残余电压补偿实验实验十五差动变压器测位移实验实验十六差动变压器的应用—振动测量实验实验十七电涡流传感器位移特性实验实验十八被测体材质对电涡流传感器特性影响实验十九被测体面积大小对电涡流传感器的特性影响实验实验二十电涡流传感器测振动实验实验二十一压电式传感器测振动实验实验二十二温度源的温度控制调节实验实验二十三 K热电偶测温特性实验实验二十四 Pt100铂电阻(热电阻)测温特性实验实验二十五集成温度传感器(AD590)温度特性实验实验二十六NTC热敏电阻温度特性实验实验二十七PN结温度传感器温度特性实验实验二十八线性霍尔式传感器位移特性实验实验二十九开关式霍尔传感器测转速实验实验三十磁电式传感器测转速实验实验三十一光电传感器测转速实验实验三十二利用光电传感器控制电机转速实验三十三光纤传感器的位移特性实验实验三十四气敏传感器实验实验三十五湿敏传感器实验实验三十六数据采集系统实验—静态采集举例实验三十七数据采集系统实验—动态采集举例注：红色代表实验未做，绿色代表实验已做。

asymtek操作说明 S-920用户培训手册SOHIGH目录一．机器外观介绍二．软体菜单介绍三．机器校正四．程式编写五．生产运行六．机器保养一．机器外观介绍1.灯塔2.工作灯3.冷却风扇4.轨道5.轨道口6.系统开关7.地线接口8底座9.前盖10.鼠标.键盘11.急停开关12.液晶显示器13.安全开关14.上盖1.胶水压力调节器12.胶管架3.加热及传送控制器4.电脑5.加热块风力表6.夹板气压调节器 7.胶水压力调节器28.点胶阀气压调节器1.排风口2.冷却风扇3.主电源接口4.后盖5.主气压接口6.电线安全封盖7.急停开关8.xy轴马达安全盖9.控制卡安全盖10.灯塔1.主气压表2.主开关3.后盖4.主电源线5.SMEMA连接上线6.SMEMA连接下线7.网络接口8.主气压调节阀及过滤器1.胶水压力调节器2.胶水压力指示表3.点胶阀压力指示表4.点胶阀压力调节器5.加热块风力流量表6.夹板气压调节器7.夹板气压指示表8.加热块气压开关1.轨道2.针槽3.指示灯4.校正块5.接触感应器上图为点胶头的接线图,装点胶头时请参考此图.二．软体菜单介绍 1.当我们打开应用软体时，会进入下面的画面：自动运行程式菜单硬体参数设置菜单编写程式菜单点胶头移动及轨道调宽系统测试及诊断2.点击“Runaprogram”会弹出下面的画面：调用生产程式机器校正及参数设置运行程式关闭软体点胶头移动及调宽操作画面返回主菜单3.点击“Configuration”会弹出下面的画面：select language软体语言选择setupunits单位选择changeoperationlevel操作级别选择machineoffsets机器校正菜单setupruntimepreferences程式运行参数设置菜单setupfluidmanger胶水参数设置setupvalves点胶阀参数设置heightsensor高度探测sensor参数设置setuplocations点胶停止后点胶头停止位置设置 setuppurgestationpurge参数及位置设置setupscale称重系统设置setupvisionvision系统设置setupworkpiecealignment设置Workpiecesetupconveyors轨道系统参数设置菜单scanner扫描仪系统设置setupheaters加热器系统设置setupdispense点胶系统设置setuplogging报警事件查询setuppassword不同操作级别的用户密码设置FeatureAccess其它参数设置ConfigurationfilesConfiguration文件库4.点击“Teachaprogram”,进入编程窗口：新建一个程式打开程式文件夹保存程式运行程式单步运行程式停止程式运行进板出板运行程式时不点胶初始化打开相机排胶水称重移动点胶头选择编程方式插入程式的注释选择要执行或者不执行的程式在程式中插入一个发送命令创建一个子程式插入一个处理命令到程式中插入一个处理过程到程式中插入一个移动命令到程式中插入一个时间命令到程式中做连板程式５．点击主菜单的，进入轨道调宽及点胶头移动窗口：当选择“Dispenser”时：１点胶头移动平面２Y轴方向移动，双箭头为快速移动，单箭头为慢速移动３X轴方向移动，双箭头为快速移动，单箭头为慢速移动５方向移动,箭头为快速移动,头为慢速移动６胶头初始化对应的键盘造作如下：x轴向左慢速移动y轴向后慢速移动x轴向右慢速移动y轴向前慢速移动z轴向下慢速移动z轴向上慢速移动x轴向左快速移动y轴向后快速移动x轴向右快速移动y轴向前快速移动z轴向下快速移动z轴向上快速移动当选择“Conveyors”时：1.轨道调宽，双箭头是快速，单箭头是慢速2.传送带动作，双箭头是快速，单箭头是慢速对应的键盘操作如下：传送带向左慢速移动轨道向后慢速移动传送带向右慢速移动轨道向前慢速移动传送带轴向左快速移动轨道向后快速移动传送带向右快速移动轨道向前快速移动三．机器校正当点胶头被拆下清洗重新安装上后，要做校正，校正步骤如下： 1．在主菜单里点“Configuration”.2．从“Configuration”菜单里选择“Machineoffsets”3．在“Machineoffsets”中选择“Valveoffsets”4．在弹出的画面中，我们会看到校正一共分七步，点击“runtoend”,进入第一个校正5．第一个校正是“teachsafeZ”,将点胶头在Z轴方向移动到一个安全高度后，点击“teach”,软体会自动记下这一高度作为点胶头移动时的安全高度。

Product DescriptionThe PA18C.T... is part of a family of inexpensive general purpose through-beam sen-sors in industrial standard 18 mm cylindrical ABS housing. The sensors are useful in applications where high-ac-curacy detection as well as small size is required.Compact housing and highperformance-size ratio.The potentiometer used for adjustment of the sensitivi-ty makes the sensors highly flexible. The output type is NPN or PNP and the output switching function is NO and NC.• Miniature sensor range• Range: 20 m (Axial), 16 m (Radial)• Sensitivity adjustment by potentiometer • Modulated, infrared light 850 nm • Supply voltage: 10 to 30 VDC• Output: 100 mA, NPN or PNP, N.O + N.C.• Degree of protection IP67, IP69K• LED indication for output, stability and power ON• Protection: reverse polarity, short circuit and transients • Cable and plug versions • Excellent EMC performancePhotoelectrics Through-beamType PA18C.T..., DCType SelectionHousing type Range Connec- Ordering no. Ordering no. Receiver Ordering no. Receiver S n tion Emitter N P N P N PMake or break switching Make or break switchingM18 Axial type 20 m Cable PA 18 CAT 20 PA 18 CAT 20 NASA PA 18 CAT 20 PASA M18 Axial type 20 m Plug PA 18 CAT 20M1 PA 18 CAT 20 NAM1SA PA 18 CAT 20 PAM1SA M18 Radial type 16 m Cable PA 18 CRT 16 PA 18 CRT 16 NASA PA 18 CRT 16 PASA M18 Radial type16 mPlugPA 18 CRT 16M1PA 18 CRT 16 NAM1SAPA 18 CRT 16 PAM1SASpecifications Receiver according to EN60947-5-2PA18C.T...Specifications Common according to EN60947-5-2Operation DiagramOperation DiagramPower supply OFF ON Target (emitter)Present Make Output (N.O.)OFFON Break Output (N.C.)OFF ONObjectPresent tv = Power ON delay* The IP69K test according to DIN 40050-9 for high-pressure, high-temperature wash-down applications.The sensor must not only be dust tight (IP6X), but also able to withstand high-pressure and steam cleaning. The sensor is exposed to high pressure water from a spray nozzle that is fed with 80°C water at 8’000– 10’000 KPa (80–100bar) and a flow rate of 14–6L/min. The nozzle is held 100 –150 mm from the sensor at angles of 0°, 30°, 60° and 90° for 30s each. The test device sits on a turntable that rotates with a speed of 5 times per minute. The sensor must not suffer any damaging effects from the high pressure water in appea-rance and function.90°60°30°0°Specifications Emitter according to EN60947-5-2PA18C.T...Wiring DiagramsDetection DiagramExcess GainPA18C.T...Dimensions Radial versionPA18C.T...Dimensions Axial versionSignal Stability IndicationAPA18-MB1Delivery Contents• Photoelectric switch: PA 18 C.T...• Installation instruction on plastic bag • Screwdriver• Mounting bracket APA18-MB1• 2 M18 locknuts• P ackaging: Plastic bag• Emitter and receiver is packed separatelyTo avoid interference from inductive voltage /current peaks, separate the proximity switch cables from any other power cables. E.g.Engine, contactor or solenoid cablesIncorrectCorrectThe cable should not be pulledA proximity switch should not serve as mechanical stopRelief of the cable strain Protection of the sensing face Incorrect> 100 mmCorrect IncorrectInstallation HintsAccessories• Connector type CONG1A.. / CONM14NF.. seriesPA18C.T...Mounting SystemsPA18 mounting with a combination of 1 x APA18-MB1 and 1 x M18 locknut.Maximum torque 0.9 NMPA18 mounting with a combination of 2 x M18 locknuts. Maximum torque 2.0 NMAPA18-MB1APA18-MB1M18 LocknutM18 Locknut.0 m m . 4.5 m m。

目录THSMP-1型传感器实验系统仿真软件手册 (2)实验一金属箔式应变片――单臂电桥性能实验 (2)实验二金属箔式应变片――半桥性能实验 (4)实验三金属箔式应变片――全桥性能实验 (5)实验四直流全桥的应用――电子秤实验 (6)实验五交流全桥的应用――振动测量实验 (7)实验六扩散硅压阻压力传感器差压测量实验 (9)实验七差动变压器的性能实验 (10)实验八动变压器零点残余电压补偿实验 (11)实验九励频率对差动变压器特性的影响实验 (12)实验十差动变压器的应用――振动测量实验 (13)实验十一电容式传感器的位移特性实验 (15)实验十二容传感器动态特性实验 (16)实验十三直流激励时霍尔式传感器的位移特性实验 (17)实验十四流激励时霍尔式传感器的位移特性实验 (18)实验十五霍尔测速实验 (19)实验十六霍尔式传感器振动测量实验 (20)实验十七磁电式转速传感器的测速实验 (22)实验十八压电式传感器振动实验 (24)实验十九电涡流传感器的位移特性实验 (25)实验二十被测体材质、面积大小对电涡流传感器的特性影响实验 (26)实验二十一电涡流传感器测量振动实验 (29)实验二十二光纤传感器的位移特性实验 (30)实验二十三光纤传感器的测速实验 (31)实验二十四光纤传感器测量振动实验 (32)实验二十五光电转速传感器的转速测量实验 (34)实验二十六PT100温度控制实验 (35)实验二十七集成温度传感器的温度特性实验 (36)实验二十八铂电阻温度特性实验 (37)实验二十九热电偶测温实验 (38)实验三十E型热电偶测温实验 (39)实验三十一热电偶冷端温度补偿实验 (40)实验三十二气敏传感器实验 (41)实验三十三湿敏传感器实验 (42)实验三十四转速控制实验 (43)THSMP-1型传感器实验系统仿真软件手册实验一属箔式应变片――单臂电桥性能实验（1）点击虚拟实验模板右上角“操作步骤帮助”，将为您提供顺利完成本模拟实验的操作步骤。

EC01(Test chamber for gas sensor evaluation)Instruction Manual1. Safety instructions2. Precautions for use3. Parts names and functions4. Measurement preparation5. Measuring procedure6. SpecificationsTable of contents Thank you very much for purchasing EC01 (Test chamber for gas sensor evaluation). Please read this instruction manual carefully to use the product correctly.Page1 12 4 6 8Figaro Engineering Inc.(1) (2) (3) (4)1. Safety instructionsMake sure to follow2. Precautions for useThis product is a simplified test chamber. Make sure to close the lid firmly without any gaps. For highly accurate gas testing, use more airtight test chambers than this product.Placing large-volume equipment such as gas detectors in the test chamber reduces the effective volume of the test chamber, and may lead to errors in the gas concentration.Highly adsorbent gases such as ammonia, VOCs and organic solvent vapors attach to the inner surface of the test chamber easily, and are therefore not suitable for such applications. If the gas is adsorbed in the chamber and liquefied, the concentration of the gas in a gaseous state may decrease. If you need to test with highly adsorbent gases, use a test chamber made of a material resistant to gas adsorption or with an internal coating.If highly adsorbent gases are injected into the test chamber, remove adsorbed gases by appropriate measures such as cleaning the inside of the test chamber with alcohol and venting the inside with clean air for a long time.Measurements in high / low temperature or in extremely high / low humidity in indoor environments may affect the measurement values of the gas sensor. Check the specification of each sensor.This test chamber is not explosion-proof. Do not use it for measurements when using flammable gases with greater than 50% concentration of the Lower Explosive Limit (LEL).The test chamber does not guarantee a completely sealed condition. Do not use it for measurements with high concentrations of toxic gases hazardous to the human body.When measuring with flammable gas, make sure to handle flames with caution, and only exhaust gas from the test chamber in an area with adequate ventilation. Also be sure to take necessary safety precautions such as installing gas detectors.Perform measurements in a well-ventilated area, especially when using toxic gases. Also, be careful not to inhale gases when venting them from the test chamber. Make sure to ventilate gases outdoors or in fume hoods for safety.(1) (2) (3) (4) (5)* Make sure that the test chamber for gas sensor evaluation itself and the following accessories are included in the packageTest chamber for gas sensor evaluation(with signal cable)Lid Syringe (5ml) Test board forevaluation modules③① Test chamber body② Control box③ AC power cable④ Power switch⑤ Switch of mixing fan⑥ Mixing fan⑦ Power supply cable⑧ Ribbon cable for measuring sensor output (50-core)⑨ Supply voltage adjustment hole(not used normally) ⑩ Test chamber lid⑪ Gas inlet* Adhesive tape is affixed to the syringe insertion rubber.Do not remove this tape, because it is used to prevent the insertion rubber from coming off when removing the syringe during measurement.⑫ Test board for gas sensor evaluation modules⑬ Connectors for module measurement (CH1 to CH12) ⑭ Connector for ribbon cable connection (CN1)⑮ Connector for power supply (CN2)⑥④⑫⑧⑩⑬⑭⑮⑨⑦⑤Instruction Manual(this document) ②⑪3. Parts names and functionsProducts and accessories①Parts namesCN1 Pin number Evaluation module Connector pin numberEvaluation module CH number 1 to 6 1 CommonVC (5.0 V DC)7 2 CH18 3 9 4 10 2 CH211 3 12 4 13 2 CH314 3 15 4 16 2 CH417 3 18 4 19 2 CH520 3 21 4 22 2 CH623 3 24 4 25 2 CH7 26 3 274Connector pin layout for power supply (CN2)Signal from the test board for evaluation modules (CN1)CN1 Pin number Evaluation module Connector pin number Evaluation module CH number28 2CH829 3 30 4 312 CH932 3 33 4 342 CH1035 3 36 4 372 CH1138 3 39 4 402 CH1241 3 42 443NC 44NC45 to 505CommonGNDPin numberNameFunction 1 VC Power input2GNDGround* The red line on the ribbon cable line (50-core) corresponds to number "1" of the CN1 pin.Connector pin layout for gas sensor evaluation modulePin numberModel number of the gas sensor evaluation moduleEM26EM3870AEM5042AEM5141AEM-FECS (A)1 VC VC VC VC VC2 V OUT V OUT1 (CH4)3 V OUT2 (CO)V OUTV OUTV OUT4 5GND GND GND GND GNDVC = Power input VOUT = Sensor output GND = Ground* Refer to the Product Information of each gas sensor evaluation module for details.Wiring specifications4. Measurement preparationPrepare a measuring instrument (such as data logger or digital multimeter) that can measure the voltage.Wire the voltage measuring instrument.・The measurement device on the right is an example.Connecting a ribbon cable directly to a data logger or other voltage measuring instrument. The signal wires coming out of the test chamber for gas sensor evaluation correspond to connector pins 1 to 50, starting with the red line.[Example of connection to a data logger](2) Connecting a ribbon cable with a connector from the chamber to an extension ribbon cableRibbon cable: Cable with 2.54 pitch (50-core) compatible with a MIL standard connectorDisconnect the connector by cutting the end of the ribbon cable coming out of the chamber body.Check “Wiring specifications” on page 3, and connect the required lines to the voltage measuring device.5V GNDCH1 CH2……CH12 Wiring using recommended connectors prepared by the user (1) Connecting a ribbon cable with a connector from the chamber to a printed circuit board, etc.There are two methods for wiring:Recommended connector: XG4A-5031 (Omron)Recommended connector: XG4E-5031 (Omron)1B .A .Attach the sensor to the gas sensor evaluation module, and attach it to the test board for evaluation modules. Match the pin number of the gas sensor evaluationmodule and the terminal number of the connector on the test board for evaluation modules, and insert it fully.[Example of attachment of the test board forevaluation modules]Insert the terminal of the gas sensor evaluation module into the larger hole of the connector for the module.15Open the lid of the test chamber and turn on the mixing fan for 2 to 3 minutes to remove the contaminated air in the chamber.① Connect the AC power cable of the test chamber to the power outlet, and turn the power switch on the top of the control box ("POWER") to "ON".* The “green LED” in the control box lights up.Green LED② Turn on the “FAN” switch and rotate the mixing fan for 2 to 3 minutes to remove the contaminated air in the chamber, and stop it when it is done. Connector for power supplyConnector for ribbon cable (50-core)Place the test board for evaluation modules attached with the gas sensor evaluation modules in the test chamber. Connect the power supply cable and the ribbon cable to their respective connectors on the test board.③ Set the power switch to “OFF”.① Set the power switch to “ON”.② Check if they are properly wired with data logger, for example, in advance.* If the power supply voltage needs to be adjusted, see “How to adjust the power supply voltage” in page 7. The factory setting of the supply voltage is 5 V. When testing with our gas sensor evaluation module, the power supply voltage does not require adjustment.Check the output voltage.2345Make sure that the power switch is “OFF ” before connection.Close the lid of the test chamber.5. Measuring procedureThe adhesive tape is affixed to the top surface to prevent the "rubber for syringe insertion" from popping out. Replace it with a new adhesive tape as it ages. * Use standard mending tape.After the measurement is complete, open the lid in a well ventilated area and turn the fan to vent the gas in the chamber.When opening the lid after the measurement, make sure to place the test chamber in a well ventilated area, open the lid and turn the fan to remove the gas in the chamber. Be careful not to inhale the gas from the test chamber or spread it into the room.* The lid should be closed by lightly pressing down to make it airtight.Before injecting the gas, make sure to measure the output voltage from the evaluation module in clean air, and confirm the voltage is stable.Insert the syringe needle into the gas inlet on the lid and inject the gas.* Calculate the required gas injection volume from the inner volume of the chamber and the gas concentration to measure. (See below for calculation method)After the injection, turn on the fan switch and mix the gas for approximately 30 seconds. Then perform the measurement considering the operating conditions of the sensor.The injection volume V (ml) of 100% concentration gas required to make a test gas of concentration C (ppm) in the test chamber can be calculated from the following formula.1352 4 When diluting 100% concentration gas:V = (chamber capacity) xC1,000,000* Chamber capacity = 10,300 mlExample: Test gasconcentration100% concentration gas injection volume1,000 ppm 5,000 ppm10.3 ml 51.5 mlCalculation of the injection volume of the gasTurn clockwise (+) 4.00V -> 5.50VTurn counterclockwise (-) 5.50V -> 4.00VThe factory setting of the power supply voltage to the test board is set to 5V, and users do not need to adjust it usually.This adjustment should only be made if any adjustment is required between 4.00 V and 5.50 V.ScrewdriverThe power supply voltage can be adjusted by inserting a + screwdriver into the supply voltage adjustment hole on the side of the control box and turning the adjustment volume.Check the voltages between ribbon cable connector pin numbers 1 to 6 (VC+) and 45 to 50 (GND).Control boxHow to adjust the power supply voltageName Test chamber for gas sensor evaluationModel number EC01Product configurationTest chamber body and lid without openingTest board for gas sensor evaluation modules (12 modules max.)Syringe (5ml)Main power AC 100 V to 240 VACPower consumption 2W (when fan is on)* excluding power consumption required for gas sensor operationOperating temperaturerange 0 °C to 50 °C Effective inner capacity 10,300 mlExternal dimensions340 (W) x 270 (D) x 202 (H) mm (excluding ribbon cable) Weight Approx. 4 kg (including test board for evaluation modules)Main materialChamber body: Polyvinyl chloride Lid: Acrylic6. SpecificationsContact for inquiries about our products:This manual is subject to change without notice to improve product performance.ConnectorsPart numberManufacturerStandardsCN1XG4A-5031OMRONMIL standard MIL-C-83503UL standard (File No. E103202) certified CN2 B2P-VH-1 JSTUL standard (File no. E60387) certified CSA standard LR20812Evaluation module Connectors (CH1 to CH12)05JQ-BT JSTUL standard(File no. E60387) certifiedCSA standard LR20812Standards of connectors (Model number: EC-P01)The following parts are available separately.Lid with air supply and exhaust openingsTest board for evaluation modulesOptional partsBoard size: 200 x 258 mmAir inlet and outlet, outer diameter: 32 mm Φ(Model number: EC-P02)Figaro USA, Inc.121 S. Wilke Rd. Suite 300Arlington Heights, IL 60005 USA TEL.: (1) 847-832-1701 FAX.: (1) 847-832-1705E-mail:**************************。

INSTRUCTION MANUALELECTRICAL LOAD CELLModel ANCLORoctest Limited, 2017. All rights reserved.This product should be installed and operated only by qualified personnel. Its misuse is potentially dangerous. The Company makes no warranty as to the information furnished in this manual and assumes no liability for damages resulting from the installation or use of this product. The information herein is subject to change withoutnotification.Tel.: 1.450.465.1113 • 1.877.ROCTEST (Canada, USA) • 33 (1) 64.06.40.80 (Europe) • • www.telemac.frE1033-170413TABLE OF CONTENTS1PRODUCT (2)1.1D ESCRIPTION (2)1.2S PECIFICATIONS (2)2INSTALLATION (3)2.1C ABLE INSTALLATION (4)2.2E LECTRICAL SPLICES (5)2.3C ABLE WIRING (5)2.4L IGHTNING PROTECTION (5)3DATA READING AND ANALYSIS (7)3.1G ENERAL (7)3.2R EADING O UTPUT IN ENGINEERING UNITS (7)3.3R EADING O UTPUT IN M V/V (9)3.4D ATA REDUCTION (12)3.5V ERIFICATION OF CELL CIRCUIT (13)3.6P OTENTIAL EFFECTS OF INSTALLATION OVER READINGS (13)4MISCELLANEOUS (14)4.1C ONVERSION FACTORS (14)4.2C ALIBRATION DATA SHEET (15)4.3W IRING DIAGRAM (17)1PRODUCT1.1DESCRIPTIONANCLO load cells are used to measure tensile loads in tie-back anchors and rockbolts, or compressive loads in structures. Typical applications include:∙ Anchored retaining walls, tieback.∙ Anchoring systems for deep excavations∙ Tie-down anchors for buoyant structures∙ Rockbolts and soil nails monitoring in mines and slope stabilization∙ Load monitoring in structures∙ To check on the load as determined by hydraulic pressure applied to a jack during proof-testing on tiebacks. Note that in this case because of many parameters, the agreement cannot be guaranteed better than +/-20%.The load sensing element is a spool of high strength heat-treated steel that withstands rough handling and loading. The ANCLO load cell is built with a hollow cylindrical core onto which four to eight strain gages are bonded in pairs at 90o intervals around the periphery and connected in a Wheatstone bridge circuit. Load cells less than 152 mm in internal diameter use four bonded strain gages whereas 152 mm or larger internal diameter load cells use eight pairs of bonded strain gages. The gages are wired in a full bridge configuration for temperature compensation, optimum sensitivity and the accurate measurement of non-uniformly distributed loads. A steel housing with o-ring seals covers the spool and protects the strain gauges from mechanical damage and water infiltration. The plain PVC or armor-jacketed electrical cable connects to the cell by∙either a detachable multi-pin electrical connector mounted on the cell∙or permanent factory wiring of the lead cable to the cell. The cable enters the cell through a watertight electrical connectorThe load cells are protected against moisture intrusion and are splash proof.An identification plate on the outside of the cell holds the following information: ∙The serial number∙The capacity of the cell in kN1.2SPECIFICATIONS2INSTALLATIONThe load cell support surface should be smooth and perpendicular to the axis of the anchor or tieback. The use of a load bearing plate of suitable thickness between cell base and the bearing surface, and a load distribution plate between the anchor or tieback head and the load cell is required.Load distribution on bearing plates that are too thin or improperly dimensioned will result in uneven load distribution causing erroneous results. The inside diameter of the load bearing and distribution plates should be identical to the inside diameter of the load cell.The load distribution plate can be either a single plate or double spherically seated plates. Use of latter can compensate for misalignment of the bearing surface, load cell and distribution plate. Upon installation, locate the electrical connector downward to minimize the risk of damage.TABLE 1: Wiring code for connecting load cell to a “P3” readout unit.Load cells are accurate instruments and should be treated with care. They should under no circumstances be picked up by the cable. Even if the cells have been designed to be watertight and robust, they can be damaged by misuse, particularly with respect to the cable. Load cells have to be installed with a special care to their installation. From the design arrangements comes the quality of the measurements. The installation design should minimize the eccentric loading and the misalignment of load, whatever the context of measurement (tie-backs, pile test …). Therefore, cells have to be set between two flat, smooth and stiff plates. The wall where the tie-back applies or the top of the pile during a load test should be plane as well. If necessary, make it so with cement or concrete. If the cells are installed on tie-backs, bushings are often useful to center the hollow cylinder.Figure 1: Anclo typical installation on a tie-back2.1CABLE INSTALLATIONCable identificationThe electrical signal coming from the sensor is transmitted through an electrical cable. This cable is generally supplied in rolls. Cables are identified with the serial number that is labelled on the sensor housing. The serial number is stamped on a tag that is fastened to the readout end of the cable. In the case where the sensor cable has to be cut or if the cable end is inaccessible, make sure to be able to identify it (by marking its serial number for instance with an indelible marker or using a color code). It is very important to clearly identify the instrument for reading or wiring purposes.Cable routingSome of the more important considerations that must be given to cable runs are: ∙Avoid traversing transition zones where large differential settlements could create excessive strain in the cable.∙Avoid cable splices. If necessary, refer to the special paragraph below.∙Do not lay cables one on top of the other.∙Use horizontal snaking or vertical snaking of the cable within the trenches. For most materials, a pitch of 2 m with amplitude of 0.4 m is suitable. In very wet clays increase the pitch to 1 m.∙Use a combination of horizontal and vertical snaking at transition zones.Once a cell is installed, route its cable towards the junction or switching box. Make sure that the cable is protected from cuts or abrasion, potential damage caused by angular material, compacting equipment or stretching due to subsequent deformations duringconstruction or fill placement. If necessary, run the cable through rigid or flexible conduit to the terminal location. To provide protection for cable running over concrete lifts, hand placed concrete is sometimes used, depending on site conditions. Check that the cable does not cross over itself or other cables in the same area. Surface installations require continuous surveillance and protection from the earth moving equipment circulating on the field. During the cable routing, read the instruments at regular intervals to ensure continued proper functioning. Record the cable routing with care and transfer this routing to the drawings.2.2ELECTRICAL SPLICESGenerally, cable splices are to be avoided. If necessary, use only the manufac turer’s approved standard or high-pressure splice kit. Splicing instructions are included with the splice kit. Should the cable be cut, we recommend the use of our cable splice kits, especially if the splice is located underwater. Furthermore, in special cases on site (large distance between sensors, readout position for example), splices are useful to limit the number of cables to lay. Individual sensor cables can be merged into a multi-conductor cable using a splice or a junction box.Figure 2: Example of junction box usePlease contact Roctest for additional information about junction boxes and splice kits.2.3CABLE WIRINGBefore cutting a cable, make sure of its identification. Strip back the conductor insulation by about 1cm. If possible, tin the exposed conductors with a solder.2.4LIGHTNING PROTECTIONAt all times during the installation, any cable that is exposed to potential damage by lightning must be protected. A large grounded metal cage placed over the cable bundle, combined with direct grounding of all leads and shields is an effective way to prevent lightning damage to the instruments and cables during the installation process. Please contact Roctest for additional information on protecting instruments, junction boxes and data logging systems against power surges, transients and electromagnetic pulses. Alljunction boxes and data logging systems furnished by Roctest are available with lightning protection.3DATA READING AND ANALYSIS3.1GENERALEach load cell comes with a calibration certificate. The certificate lists the sensitivity factor used with a P-3 VISHAY strain indicator or equivalent.Read each load cell immediately prior to installation. Record each reading under no-load conditions and compare it with the initial value on the calibration data sheet. Readings should agree within +/-0.025mV/V. ANCLO load cells are temperature compensated for a range of -40 °C to +75 °C for equilibrium temperature conditions. It is recommended to protect it from direct sunlight.If there is a wide discrepancy during storage temperature of the cell and the ambient temperature prior to installation, the cells should be conditioned to the ambient temperature until temperature equilibrium is reached. This ensures that initial reading, made under no-load conditions prior to installation, is a stable value to which subsequent measurements can be referenced. ANCLO load cells can be read with most strain gage indicators. The following procedure applies to the P-3 VISHAY Micro-Measurements indicators.3.2READING OUTPUT IN ENGINEERING UNITS(For more details on other P-3 features, please refer to “P-3 Strain Indicator and Recorder Instruction Manual”)LCD DisplayKeypadIf you want to see the reading of the load cell directly in engineering units as kN then refer to the following instruction for P-3 configuration. You can connect up to four load cells to a P-3 readout unit as it has four channels available.1.Press POWER key on the face plate2.Press CHAN key“Chan” Sub-menuUse left and right arrows to activate appropriate ChannelConfirm entry by pressing key MENU3.Press BRIDGE key“Bridge” Sub-menuSelect the appropriate ChannelUse left and right arrows to select appropriate bridge type.For ANCLO Load Cell, select “Undef FB” for each channel to be used.Confirm entry by pressing key MENU4.Press GF/SCALING key“Chan” Sub-menuUse left and right arrows to select appropriate Channel“Units” Sub-menuSet appropriate unit among available listNote that units are provided for convenience only, and have no effect on the calculated values. In order to properly scale the data, it is necessary to supply the full scale value and the mV/V output at the full scale value.“Full Scale” Sub-menuSet appropriate Full Scale to the full scale value of the load in engineering units as shown on the calibration data sheet.“F.S. mV/V” Sub-menuSet sensitivity at full scale (in mV/V) according to load cell sensitivity value indicated on the calibration data sheet.“Dec.Places” Sub-menuSet the Dec. Places to the correct number in accordance with the units and the full scale reading previously chosen or select Auto for automatic adjustment.To return to reading display, confirm entry by pressing key MENUWe highly recommend to take note now of the no load zero reading.5.Press BAL keyBefore to use the BAL key you should check if the balance is not in the disable mode. Then go to the main menu and select balance. For each channel be sure to select the mode Auto and press key menu to confirm and come back to reading value.The balance will do a null reading to see a value near of zero when there is no load on the load cell.Then press the BAL key on the face plate. Depress the balance button a second time to select auto. This will trigger the auto balance procedure. When completed it will automatically bring up to the Saving Settings menu. Save the settings by depressing the record button on the face plate. The display should now read zero and you are ready to display the load directly in engineering units.Note that the auto balance only works when the load cell is under zero load. Do not switch from one load cell to another if the load cells are under load.For more details on readings relative to an absolute ZERO, refer to “Manual Balance” topic in “P-3 Strain Indicator and Recorder Instruction Manual”.3.3READING OUTPUT IN MV/VThe simplest way to read multiple load cells using the P-3 readout unit is to read the output in mV/V and then use the load cell sensitivity factor in mV/V at full scale to compute the load as shown on the section 3.4.Before to read in mV/V be sure to erase all previous parameters and settings in the readout unit. To erase the settings go to the Main Menu and select Options as shown on following pictures.In the menu OPTIONS select AdvancedAnd select Factory Defaults.Then press the record button on the front panel to restore factory defaults.After erasing the settings, set up the P-3 readout unit as follows:First connect the load cell according to wiring and color code as mentioned on table 1 on channel 1.Then press CHAN key or from the main menu press ‘’select channel’’ and activate all channels where you have connected a load cell. Confirm entry by pressing key MENUThen press “Bridge” Sub-menu, select the appropriate Channel and use left and right arrows to select appropriate bridge type. For ANCLO Load Cell, select “Undef FB” for each channel to be used. Confirm entry by pressing key MENUThen Press GF/SCALING key and in “Chan” Sub-menu use left and right arrows to select appropriate channel. In “Units” Sub-menu set appropriate unit to mV/V like following picture.Be sure in the BAL key menu to disable all channels.Then reading will be displayed in mV/V. See next section for conversion in engineering unit.3.4DATA REDUCTIONReading output in engineering unitIf you display the value in engineering unit on the P-3 readout (section 3.2) then actual load is obtained following this equation:Load = (L - L o)Where L = Current reading in P-3 unitsL o= Initial reading in P-3 unitsLoad = Load in engineering unitsReading output in mV/VIf you display the value in mV/V on the P-3 readout (section 3.3) then actual load is obtained following this equation:Load = Full scale x (L1 - L0)Load cell sensitivity (S)WhereLoad= Applied load in engineering unit (kN)L1= Current reading in mV/VL0= The regression zero no-load reading in mV/V (see calibration data sheet for the value of L0.S= is the load cell sensitivity at full scale in mV/V (see the calibration data sheet for the value)Full Scale= is the full scale capacity of the load cell (see the calibration data sheet for the value)Here is an example based on the calibration data sheet as defined on section 4.2.For example if the current load cell reading is 1.508mV.Load = [2000kN x (1.508mV/V – 0.218mV/V)] / 2.1515 mV/V = 1199.16kN3.5VERIFICATION OF CELL CIRCUITThe cell circuit may be checked by reading resistance and comparing it with values below: ∙Between P+ and P- wires: 700 ohms (1400 ohms when 8 pairs)∙Between S+ and S- wires: idem∙Other combination between wires: 500 ohms∙Between any wire and ANCLO/structure/shield: >1000 Mega ohms3.6POTENTIAL EFFECTS OF INSTALLATION OVER READINGSHollow-center load cells are susceptible to varying conditions of end loading. Eccentric loading, warping of the distribution plate and friction between the distribution plate and the load cell can significantly affect readings. Special precautions must be taken to minimize these effects.Furthermore, cells have to be set between two flat and stiff plates. Thickness of the distribution plate should be at least 25 mm. This thickness should be more important when load range increases and when surfaces of the load cell and the loading element (hydraulic ram) differ. Also, the user may consider asking for doing a calibration using the same distribution and bearing plates he intends to use in the field. Please contact Roctest for more information about distribution plates and calibration.Finally, different friction conditions between the distribution plate and the cell will also affect readings. We suggest using flat, smooth, non-lubricated, plates in the field as we do during calibration. Friction losses within the hydraulic jack can also affect readings.4MISCELLANEOUS4.1CONVERSION FACTORSTABLE 2: Conversion Factors.4.2CALIBRATION DATA SHEETA calibration data sheet is supplied with each load cell. It enables conversion of raw readings into load values. All the sensors are individually calibrated over their working capacity before shipment. The calibration factor coefficient, which is the load cell sensitivity, is obtained using regression techniques through a linear regression formula which may introduce a substantial non-linearity error around the zero reading. See the following page for an example of calibration data sheet.CALIBRATION DATA SHEETLOAD CELLModel: ANCLO-2000Serial number: 33012030Capacity: 2000 kNMax. excitation: 10.00 VDCTemperature: 21 °CCable model: IRC-41ACable length: 12 mColor code: Red: Power P +Black: Power P -Green: Signal S +White: Signal S -Calibration data:Load cell sensitivity: 2.1515 mV/V at full scaleRegression zero (L o): 0.2180 mV/VTraceability no: TR-12-07Certificate no: 033012028-030.xlsxCalibrated by: Eric Tremblay Date: 2017/04/124.3WIRING DIAGRAMFIGURE 3: ANCLO Load cell wiring diagram (Full Bridge Configuration).。

操作手册绝缘电阻测试仪MIC-10k1 和 MIC-5050SONEL SAul. Wokulskiego 1158-100 Świdnica, Poland2019.07.23 第1.01a版MIC-10k1和MIC-5050测试仪是高品质现代测量仪器，操作简单、安全。

使用前，请熟读本手册，以避免发生测量错误和操作问题。

2MIC-10k1 ● MIC-5050 第1.01a版操作手册目录1安全 (5)2菜单 (6)2.1无线传输 (6)2.2测量设置 (6)2.2.1电源频率 (7)2.2.2计算吸收系数的时间t1，t2，t3 (7)2.2.3吸收系数的类型 (8)2.2.4I ISO测试电流 (8)2.2.5设置极限值 (8)2.2.6温度单位 (9)2.2.7存储单元数目自动递增 (9)2.2.8过滤器 (10)2.2.9选择图表类型 (10)2.3仪表设置 (11)2.3.1LCD 对比度 (11)2.3.2自动关机 (11)2.3.3日期和时间 (12)2.3.4出厂（默认）设置 (12)2.3.5软件升级 (13)2.3.6按键音 (13)2.4选择语言 (14)2.5制造商信息 (14)3测量 (14)3.1测试仪诊断-极限 (14)3.2测量绝缘电阻 (15)3.2.1两线法测量 (16)3.2.2三线法测量 (21)3.2.3使用 AutoISO-5000测量 (22)3.2.4通过增加步进电压SV测量 (25)3.2.5介质放电指示器 - DD (26)3.2.6破损位置（后燃） (29)3.3低压测量电阻 (30)3.3.1使用±200 mA电流测量保护导体和等电位联结的电阻 (30)3.3.2校准测试线 (32)3.4温度测量 (33)MIC-10k1 ● MIC-5050 第1.01a版操作手册 34测量结果存储器 (33)4.1存储器结构 (33)4.1.1测量记录模式下的主窗口外观 (33)4.2在存储器中存储测量结果 (35)4.2.1输入结果而不扩展存储器结构 (36)4.2.2扩展存储器结构 (37)4.3查看存储器数据 (42)4.4删除存储器数据 (44)5数据传输 (45)5.1连接测试仪与计算机的套件 (45)5.2通过USB接口传输数据 (45)5.3连接到蓝牙迷你键盘 (46)5.3.1手动连接 (46)5.3.2自动连接 (48)5.4使用蓝牙模块传输数据 (48)5.5为蓝牙连接读取和更改PIN码 (48)6测试仪电源 (50)6.1监测电源电压 (50)6.2电池电源 (50)6.3对充电电池充电 (50)6.4电源线电源 (51)6.5使用（引线）充电电池的总则 (51)7清洁与保养 (52)8储存 (52)9拆卸与回收 (52)10技术规格 (52)10.1基本数据 (52)10.2其它数据 (55)10.2.1依照EN 61557-2 (R ISO)的附加精度 (55)10.2.2依照EN 61557-4 (R CONT)的附加精度 (56)11设备 (56)11.1标准设备 (56)11.2可选配件 (56)12制造商 (58)4MIC-10k1 ● MIC-5050 第1.01a版操作手册1安全MIC-10k1 和 MIC-5050 测试仪用于检测电源系统中的电击保护。