66181-011中文资料
LMH6611
LMH6611LMH6611 和LMH6612 都是345MHz输出放大器,消耗仅3.2mA静态电流,在电源单一供电系统中提供高性能。
LMH6611 和LMH6612 具有低噪音,低失真性能,精确地输入偏置电压,适用于要求精度高的视频,测试,测量和通信的应用。
LMH6611 和LMH6612具有超常的电源性能比。
0.022mV修整过的输入偏置电压,103分贝的高开环增益,LMH6611 和LMH6612 遇到了高要求的直流敏感高速应用,如低通滤波在基带的I和Q无线电频道。
100纳秒0.01%的时间设置,10√Hz的低噪音和100KHz时102分贝的高噪音,这些规格结合在一起,使得这些放大器特别适合于10,12,14-bit的高速模数转换器。
45MHz,0.1分贝的带宽传送2Vpp到150Ω,允许放大器传送1080和720p的高清电视的应用。
共模输入范围延伸到200毫伏以下,负供应高达1.2V。
在一个5V电源提供的负载为150Ω的电路,输出波动范围为49毫伏以下;当负载为1KΩ时,波动范围在77毫伏以下。
放大器将作用于单输入范围为2.7V 到11V,或分裂输入范围为±1.35V到±5.5V 的电路。
LMH6611可用于6管脚的TSOT23和独立活跃的管脚,可减少供应120uA的电流。
LMH6612可用于8管脚的SOIC。
LMH6611和LMH6612都可用在-40℃到+125℃的温度范围内。
产品特性:Vs=5V,Rl=1KΩ,Ta=25℃,Av=+1(除非另有说明)操作电压范围 2.7V 到11V电源电流 3.2mA小信号带宽345KHz开环路增益103dB输入偏置电压(限制在25℃)±0.750mV转换速率460V/uS0.1分贝带宽45MHz0.1%的设置时间67ns0.01%的设置时间100nsSFDR(f=100KHz,Av=2,V out=2Vpp) 102dBc低电压噪音10nV/√Hz输出电流±100mACMVR-0.2v到3.8v温度范围-40℃到+125℃应用:模数转换器,数模缓冲器,有源滤波器,高速传感放大器,电流感应放大器,1080i 和720p的模拟视频放大器,机顶盒,电视视频放大器,视频交换混合电路。
IEC608111译文
IEC 60811-1-1 第2.1版200107 电缆和光缆绝缘和护套材料通用试验方法第1-1部分通用试验方法—厚度和外形尺寸测量—机械性能试验60811-1-1IEC:1993A1:2001 I c c 目次1 范围................................................................................ 1 1.1 规范性引用文件..................................................................... 1 2 试验原则............................................................................ 1 3 适用范围............................................................................ 1 4 型式试验和其它试验.................................................................. 1 5 预处理.............................................................................. 1 6 试验温度............................................................................ 1 7 定义.. (2)7.1 (2)7.2 (2)7.3 (2)7.4 (2)7.5 .................................................................................... 2 8 厚度和外形尺寸的测量................................................................ 2 8.1 绝缘厚度的测量..................................................................... 2 8.2 非金属护套厚度测量................................................................. 3 8.3 外形尺寸测量....................................................................... 3 9 绝缘和护套材料机械性能测量方法...................................................... 4 9.1 绝缘材料........................................................................... 4 9.2 护套材料........................................................................... 7 附录A 资料性附录具有代表性的制备试样用设备的操作原理............................ 13 图1 绝缘和护套厚度测量圆形内表面.................................................. 8 图2 绝缘厚度测量扇形导体.......................................................... 8 图3 绝缘厚度测量绞合导体.......................................................... 9 图4 绝缘厚度测量绞合导体.......................................................... 9 图5 绝缘厚度测量不规整外表面...................................................... 9 图6 绝缘厚度测量扁平双芯无护套软线............................................... 10 图7 护套厚度测量不规整圆形内表面................................................. 10 图8 护套厚度测量非圆形内表面..................................................... 10 图9 护套厚度测量不规整外表面..................................................... 11 图10 护套厚度测量扁平带护套双芯软线.............................................. 11 图11 护套厚度测量多芯扁平电缆.................................................... 11 图12 哑铃试件........................................................................ 12 图13 小哑铃试件...................................................................... 12 图14 带凹槽的冲头一端................................................................ 12 图15 由带凹槽冲头冲切的试件.......................................................... 12 60811-1-1 IEC:1993A1:2001 1 c c 电缆和光缆绝缘和护套材料通用试验方法第1-1部分通用试验方法—厚度和外形尺寸测量—机械性能试验1 范围本国际标准IEC 60811-1规定了配电及通信用电缆和光缆包括船舶及近海用电缆和光缆的聚合物绝缘和护套材料的试验方法。
湖南省统计局、湖南省经济和信息化委员会关于做好全省新材料产业统计监测工作的通知
湖南省统计局、湖南省经济和信息化委员会关于做好全省新材料产业统计监测工作的通知文章属性•【制定机关】湖南省统计局,湖南省经济和信息化委员会•【公布日期】2013.05.07•【字号】•【施行日期】2013.05.07•【效力等级】地方规范性文件•【时效性】现行有效•【主题分类】统计正文湖南省统计局、湖南省经济和信息化委员会关于做好全省新材料产业统计监测工作的通知各市州统计局、经(工)信委:根据湖南省委、湖南省人民政府《关于加快培育发展战略性新兴产业的决定》(湘发〔2010〕14号)和《湖南省战略性新兴产业新材料产业专项规划实施方案》的有关精神,为及时、准确地掌握全省新材料产业运行状况,现就切实做好新材料产业统计工作有关事项通知如下:一、充分认识做好新材料产业统计监测工作的意义根据湘发〔2010〕14号文件精神,湖南将重点培育发展先进装备制造、新材料、文化创意等七大战略性新兴产业。
新材料产业作为七大重点扶持的战略性新兴产业之一,既是国民经济的基础性产业,也将是全省的支柱性产业。
做好全省新材料产业统计监测工作,是全面了解和把握新材料产业运行状况和发展趋势的需要,也是为各级政府及相关部门指导和服务新材料产业发展提供决策参考依据的需要。
各级各有关部门要充分认识做好新材料产业统计监测工作的重要意义,切实把这项工作抓紧抓实抓好。
二、认真做好新材料产业统计监测工作的组织实施省经济和信息化委员会、省统计局、省新材料协会联合开展新材料产业统计监测工作,由省统计局负责具体实施。
新材料产业统计监测工作采取新材料企业按季度报送相关调查指标数据的方式进行。
新材料企业认定工作参照《湖南省战略性新兴产业考核统计数据采集实施办法(修订)》(湘推新工办〔2012〕3号)文件办法,采取“企业申报,部门认定”的方式进行界定。
各市州经(工)信委、统计局等相关部门组织本地企业进行申报,由省经信委、省统计局、省新材料产业协会等部门对新材料企业进行审核认定。
66164;66166;66167;66168;66169;中文规格书,Datasheet资料
COMMON POINT GROUND
Per ANSI/ESD S6.1, Grounding section 4.1.1 “Every element to be grounded at an ESD protected station shall be connected to the same common point ground.” ESD Handbook ESD TR20.20 section 5.1.3 Basic Grounding Requirements “The first step in ensuring that everything in an EPA is at the same electrical potential is to ground all conductive components of the work area (worksurfaces, people, equipment, etc.) to the same electrical ground point. This point is called the common point ground. The next step in completing the ground circuit is to connect the common point ground to the equipment ground (third wire, green).”
General Grounding Guidelines
1. ANSI/ESD S20.20 requires that all conductors in an ESD protected area, including personnel, must be grounded. 2. The ESD ground must be tied directly to and at the same potential as the building or “green wire” equipment ground. 3. Per ANSI/ESD S20.20, the ESD control program can in no way replace or supercede any requirements for personnel safety. Ground fault circuit interrupters (GFCI) and other safety protection should be considered wherever personnel might come into contact with electrical sources. 4. All electrical outlets should be verified for proper wiring configuration, resistance or impedance and GFCI function when the mat is installed and periodically thereafter.
AC6611
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三、接线
+ 转 速 电 机 测 速 3
变 频 器
4
Chongqing University of Science & Technology
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X
Chongqing University of Science & Technology #/53
四、安装AC6611驱动程序 安装AC6611驱动程序 AC6611
Chongqing University of Science &6611驱动程序 安装AC6611驱动程序 AC6611
6.选择驱动所在目录, 6.选择驱动所在目录,进行安装 选择驱动所在目录 (\ac6611\driver\); ac6611\driver\ 7.按找到新硬件向导的提示进行下一步; 7.按找到新硬件向导的提示进行下一步; 按找到新硬件向导的提示进行下一步 8.Windows 2000/Xp将显示完成添加/删除硬件向导, 2000/Xp将显示完成添加 删除硬件向导, 将显示完成添加/ 单击完成即可完成安装过程 注:安装完毕后将在设备管理器中出现一个其他设备 (其他设备是问号不表示设备有问题,只是表示系统 其他设备是问号不表示设备有问题, 不知道AC6611板卡是何种类型设备) 不知道AC6611板卡是何种类型设备) AC6611板卡是何种类型设备
Chongqing University of Science & Technology
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①A/D转换指标 转换指标
A/D转换器: 12位 A/D转换器: 120KHZ 12位A/D 转换器 A/D芯片内置采样保持器 芯片内置采样保持器; A/D芯片内置采样保持器; 工作方式:软件查询; 工作方式:软件查询; 通道数:16路单端输入 路单端输入; 通道数:16路单端输入; 输入阻抗:1MΩ, 输入阻抗: 最大输入耐压电压: 5.5V; 最大输入耐压电压:< +12V / -5.5V; 瞬时输入耐压: +30V; 瞬时输入耐压:-25V - +30V; 双极性输入范围: 5V; 双极性输入范围: 5V; 单极性输入幅度: 10伏 单极性输入幅度:5伏、10伏; 连接器:DB25(孔式)。 连接器:DB25(孔式)。
psr661说明书
psr661说明书PSR60系列数字式综合测控装置技术说明书国电南京自动化股份有限公司GUODIAN NANJING AUTOMATION CO.,LTDPSR60系列数字式综合测控装置技术说明书编写审核批准V :1.1国电南京自动化股份有限公司2005年12月安全声明注意:对装置进行测试时,请使用可靠精确的测试仪进行测试。
有些模块的输入量程是通过板上跳线实现的,请在接线前仔细核对跳线,以免损坏模块。
危险:请不要用手触摸装置除机壳外的裸露带电部分和印制板上的器件管脚。
其他:出厂时,运行密码为1000,检修密码为2000,请用户重设。
请注意密码管理,以免由于越权使用密码,造成误操作。
版本声明本说明书适用于PSR60系列数字式综合测控装置主CPU 模块V1.49版本,详见下表。
1.软件本说明书对应的各模件最新版本号分别如下表:2.硬件初始版本。
产品说明书版本修改记录表* 技术支持电话:83537292传真:83537201* 本说明书可能会被修改,请注意核对实际产品与说明书的版本是否相符 * 005年12月第2版第1次印刷 * 国电南自技术部监制目录安全声明版本声明 1 概述 ................................................ ....................... 1 1.1 适用范围 ................................................ ................. 1. 性能特点 ................................................ ................. 技术参数 ....................................................................1 额定电气参数 ................................................ .............. 主要技术指标 ................................................ .............. 环境条件 ................................................ .................. 绝缘性能 ................................................ .................. 耐湿热性能 ................................................ ................ 电磁兼容性 ................................................ .............. 10. 机械性能 ................................................ ................ 10 装置硬件简介 ................................................ .............. 11.1 机箱结构 ................................................ ................ 11. 关于校准 ................................................ ................ 1 典型配置方案 .............................................................. 14.1 单模块类型定值简介 ................................................ ...... 14. 装置典型配置方案 ................................................ ........ 1 定值整定简介 ................................................ .............. 1 输入输出数据 ................................................ .............. 1 模块说明 ................................................ .................. 18.1 智能交流采集模块 ....................... 18.1.1 交流模块硬件说明 ................................................ ...... 18.1. 交流模块典型配置 ................................................ ...... 19.1. 交流模块定值及整定说明 ................................................2.1. 交流模块输入输出数据 ................................................ ..0. 管理主模块 ................................................ ..7.2.1 管理主模块硬件说....7.2. 管理主模块定值及整定说明 ..............................................8.2. 管理主模块输入输出数据 ................................................2. 电源模块 ................................................ .......5.3.1 电源模块硬件说明 ................................................ ......5. 智能开入模块 ................................................ ......5.4.1 开入模块硬件说明 ................................................ ......5.4. 开入模块典型配置 ................................................ ......6.4. 开入模块定值及整定说明 ................................................7.4. 开入模块输入输出数据 ................................................ ..1. 智能控制模块 ................................................ .....2.5.1 控制模块硬件说......2.5. 控制模块定值及整定说明 (3)PSRC1900系列微机式保护测控装置 PSRC1900系列保护控制自动化系统技术使用说明书杭州博瑞电气有限公司2012年2月目录1 概述 ................................................ . (1)1.1 产品特点 ................................................ ............................................... 1 1. PSRC1900系列装置分类 ................................................ ...................... 1 1. PSRC1900系列装置用途及主要功能 ................................................ .. 技术指....2.1 额定数据 ................................................ ................................................ 功率消耗 ................................................ ................................................ 过载能力 ................................................ ................................................ 测量及精度 ................................................ ............................................ 绝缘性能 ................................................ ................................................ 触点性能 ................................................ ................................................ 电磁兼容性 ................................................ ............................................ 环境条................................................ 应用标准 ................................................ ............................................... 装置硬件 ................................................ ....3.1 机械结构图 ................................................ ............................................ 电源插件 ................................................ ...................................... 操作插件 ................................................ ...................................... 遥信插件 ................................................ ...................................... 交流插件 ................................................ ...................................... CPU 板 ................................................ .................................................... 面板显示及操作说明 ..........................................4.1 面板显示 ................................................ ................................................ 菜单级别及说明 ................................................ .................................... 装置参数设定 ................................................ ..................................... 1 PSRC1910线路保护测控装置 . (14)5.1 基本配置及规格 ................................................ ................................. 14. 保护原理 ................................................ ............................................. 15. 定值设置 ................................................ ............................................. 15. 背板端子图111 ............................................... ................................... 18. 典型接线原理图 ................................................................................. 19. 保护逻辑框图 ................................................ .....................................1 PSRC1913线路自投保护测控装置 (2)6.1 基本配置及规格 ................................................ .................................6. 保护原理 ................................................ .............................................6. 定值设置 ................................................ .............................................6. 背板端子图 ................................................ .........................................6. 典型接线原理图 ................................................ .................................6. 保护逻辑框图 ................................................ ..................................... PSRC1920电容器保护测控装置 .. 07.1 基本配置及规 0机式保护测控装置7. 保护原理 ................................................ .............................................1. 定值设置 ................................................ .............................................2. 背板端子图 ................................................ .........................................3. 典型接线原理图 ................................................ .................................4. 保护逻辑框图 ................................................ ..................................... PSRC1950配变保护测控装置 . (7)8.1 基本配置及规格 ................................................ .................................8. 保护原理 ................................................值设置 ................................................ .............................................9. 装置背板端子图 ................................................ .................................0. 典型接线原理图 ................................................ .................................1. 保护逻辑框图 ................................................ ..................................... PSRC1960电动机保护测控装置 .. (4)9.1 基本配置及规格 ................................................ .................................9. 保护原理 ................................................ .............................................9. 定值设置 ................................................ .............................................6. 背板端子图 ................................................线原理图 ................................................ .................................9. 保护逻辑框图 ................................................ .....................................1 10 PSRC1982电压综合保护兼并列装置 (2)10.1 基本配置及规格 ................................................ ...............................10. 保护原理 ................................................ ...........................................10. 定值设置 ................................................ ...........................................10. 背板端子图 ................................................ .......................................10. 典型接线原理图 ................................................ ...............................10. 保护逻辑框图 ...................................................................................11 保护参考整定计算说明 ......................................1 用户安装调试说明 ..........................................1 通讯规约 ................................................ ..1 订货须知 ................................................ ..2PSRC1900系列微机式保护测控装置1 概述PSRC1900系列数字式保护测控装置是公司积累多年研发、生产数字式保护测控装置的基础上,经过大量的市场调研、配置方案论证所推出的面向35KV及以下电压等级的输配电元件及线路的保护、测量及控制系统。
698111KB中文资料
(4)
K2 59.444 50.117 70.164 156.891 127.990 191.986 96.541 160.902 52.336 78.503 104.671 98.921 134.203 72.674
(1) DC resistance is measured at 25°C. (2) The rated current (Irated) is the current at which the inductance will be decreased by 20% from its initial (zero DC) value. (3) The heating current is the DC current, which causes the component temperature to increase by approximately 40°C. This current is determined by soldering the component on a typical application PCB, and then apply the device for 30 minutes. (4) Core Loss approximation is based on published core data: Core Loss = K1 * (f)1.77 * (K2∆I)2.21 Where: core loss in watt f = switching frequency in kHz K1 and K2 = core loss factor ∆I = delta I across the component in Amp. K2∆I = one half of the peak to peak flux density across the component in Gauss
SCALANCE X101-1 商品说明书
24 V
6GK5101-1BB00-2AA3 Page 1/4
06/28/2018
Subject to change without notice © Copyright Siemens
● at DC / maximum
Supply voltage, current consumption, power loss Supply voltage ● external ● external Type of voltage / of the supply voltage Product component / fusing at power supply input Fuse protection type / at input for supply voltage Consumed current ● maximum Power loss [W] ● at DC / at 24 V
Compact 40 mm 125 mm 124 mm 0.55 kg
Yes Yes Yes
No No
FM3611: Class 1, Divison 2, Group A, B, C, D / T.., Class 1, Zone 2, Group IIC, T.. EN 600079-15 II 3 G EEx nA II T.. KEMA 06 ATEX 0021 X
Yes
Yes Yes Yes Yes Yes No 134 y
/snst
/simatic-net https:// /industry/infocenter /bilddb /cax https://
Security information
UL 60950-1, CSA C22.2 No. 60950-1 UL 1604 and UL 2279-15 (Hazardous Location), Class 1 / Division 2 / Group A, B, C, D / T.., Class 1 / Zone 2 / Group IIC / T.. EN 61000-6-3 EN 61000-6-4:2001 EN 61000-6-2:2001, EN 61000-6-4:2001 Yes Yes Yes
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66181 30kV HIGH VOLTAGE ISOLATOR WITH BUFFERED OUTPUT MiiOPTOELECTRONICPRODUCTSDIVISIONFeatures:•10 Mhz bandwidth typical•30kVdc isolation test voltage •TTL compatible input and output •High common mode rejection •Rugged ceramic package A pplications:•Military and Space•Voltage Level Shifting• GridCurrentModulator •Switching between power supplies • MedicalsystemsDESCRIPTIONThe 66181 high voltage isolator consisting of a LED optically coupled to a high speed, high gain inverting detector gate. Output is TTL capable with switching propagation delays of 55ns typical, hermetically sealed in TO-46 packages and mounted in a highly reliability, hermetically sealed ceramic package. Available in commercial (0° to +70°C), extended temperature range (-40° to +85°) and full Military temperature range (-55° to +125°C). Contact the factory for special custom or multi-channel requirements!ABSOLUTE MAXIMUM RATINGSStorage Temperature............................................................................................................................................-65°C to +150°C Operating Free-Air Temperature Range..............................................................................................................-55°C to +125°C Lead Solder Temperature.........................................................................................260°C for 10s (1.6mm below seating plane) Peak Forward Input Current ........................................................................................................................40mA (1ms duration) Average Forward Input Current ............................................................................................................................................20mA Input Power Dissipation .......................................................................................................................................................35mW Reverse Input Voltage (5V)Supply voltage - V CC.................................................................................................................................7V(1 minute maximum) Output Current - I O ................................................................................................................................................................25mA6618130kV HIGH VOLTAGE ISOLATOR WITH BUFFERED OUTPUTELECTRICAL CHARACTERISTICST a = 25°C unless otherwise specified.PARAMETERSYMBOLMIN TYPMAXUNITSTEST CONDITIONSNOTEHigh Level Output Current I OH 5250µA V CC = 5.5V, V O = 5.5V,I F = 20µA Low Level Output Voltage V OL 0.350.6V V CC = 5.5V, I F = 10mA I OL (Sinking) = 10mA High Level Supply Current I CCH 920mA V CC = 5.5V, I F = 0Low Level Supply Current I CCL 1330mA V CC = 5.5V, I F = 20mAInput Forward VoltageV F 1.51.75V I F = 15mA Input Reverse Breakdown Voltage BV R5V I R = 10µAInput-Output Insulation Leakage CurrentI I—O10.0µAV I —0 = 30kVdc,Relative Humidity = 45%T a = 25°C, t = 5 sec Propagation Delay Time To High Output Levelt PLH 65150ns R L = 510Ω, C L = 15Pf.I f = 13mA 9Propagation Delay Time To Low Output Levelt PHL55150nsR L = 510Ω, C L = 15PfI f = 13mA9TYPICAL CHARACTERISTICST A = 25°C, V CC = 5VPARAMETERSYMBOLMIN TYPMAX UNITSTEST CONDITIONSNOTEInput Diode Temperature Coefficient ∆v F ∆T A-1.9mV/°CI F = 20mA 1Resistance (Input-Output)R I-01012ΩV I—O = 500V 3Input-Input Insulation Leakage Current I I-I 0.5nARelative Humidity = 45%V I-I = 500V, t = 5s4Resistance (Input-Input)R I-I 1012ΩV I-I = 500V 4Common Mode Transient Immunity at High Output LevelCM H100010000V/µsV CM = 10V (peak),V O (min) = 2V,R L = 510Ω, I F = OmA 7Common Mode Transient Immunity at Low Output LevelCM L100010000V/µs V CM = 10V (peak),V O (max) = 0.8V,R L = 510Ω, I F = 1OmA8NOTES:1. Each channel2. Measured between pins 1 through 8 shorted together and pins 9 through 16 shorted together.3. Measured between pins 9 and 10 or 11 and 12 shorted together, and pins 9 through 16 shorted together.4. Measured between pins 9 and 10 shorted together, and pins 11 and 12 shorted together.5. The t plh propagation delay is measured from the6.5mA point on the trailing edge of the input pulse to the 1.5V point on the trailing edge of the output pulse.6. The t phl propagation delay is measured from the 6.5mA point on the leading edge of the input pulse to the 1.5V point on the leading edge of the output pulse.7. CM h is the max. tolerable common mode transient to assure that the output will remain in a high logic state (i.e. V O > 2.0V).8. CM l is the max. tolerable common mode transient to assure that the output will remain in a low logic state (i.e. V O < 0.8V).9. It is essential that a bypass capacitor (.01 to 0.1µF ceramic) be connected from pin 1 to pin 4.RECOMMENDED OPERATING CONDITIONS:PARAMETERSYMBOL MIN MAX UNITSInput Current, Low Level Each Channel I FL 0250µAInput Current, High Level Each Channel I FH 12.520Ma Supply VoltageV C 4.55.5VFan Out (TTL Load) Each Channel N 6Operating TemperatureT A-55125°CSELECTION GUIDEPART #PART DESCRIPTION66181-001Inverted output, military operating range (-55° to +125°C)66181-101Inverted output, full mil-temp (-55° to +125°C) with 100% device screening (on discrete components)66181-011Inverted output, commercial version Isolator (0° to 70°C)。