HLMP-K105-ML0B2中文资料

WAIN 10-41101 017 210 0101101 017 210 0301101 017 210 0401101 017 210 0601101 017 210 0801101 017 210 0901101 017 210 1001101 017 220 0101101 017 220 0301101 017 220 0401101 017 220 0601101 017 220 0801101 017 220 0901101 017 220 1001CDGF-0.25CDGF-0.37CDGF-0.50CDGF-0.75CDGF-1.0CDGF-1.5CDGF-2.5CDGM-0.25CDGM-0.37CDGM-0.50CDGM-0.75CDGM-1.0CDGM-1.5CDGM-2.5公订货号订货号母插针针数依据 EN 61 984 的电气数据 -额定电流 -额定电压 -额定脉冲电压-污染程度表面处理材料-绝缘体 -外部导体接触电阻温度范围依据UL 94 的阻燃等级表面处理卡口范围2x4+屏蔽10A 50V 0.8kV 3聚碳酸酯锌合金≤4mΩ-40℃...+85℃V0钝化5-12 mmDIN EN 60 664DIN EN 61 984接插件针数绝缘电阻材料工作温度范围依据UL 94 的阻燃等级可拔插次数规范技术参数规范适配器模块百兆插芯冷压针1≥1010Ω聚碳酸酯-40℃...+125℃V0≥500冷压连接 -mm 2 -AWG镀金0.14-2.5 mm 226-1450V 10A 插芯HMMB-008 百兆模块插芯公母型号HMMB-008-MC HMMB-008-FC 订货号129 008 010 0503 129 008 020 0503百兆插芯 冷压连接 冷压针需另外订购适配器模块需另外订购插芯公母型号HMB.C-M HMB.C-F 订货号129 000 001 0001129 000 002 0001适配器模块N EW可与框架及其他所有模块产品组合使用冷压针接触电阻≤3mΩ镀金10A 冷压针工具冷压钳退针器压接线径0.14-4mm ²型号TL02G订货号198 001 001 0011适用范围10A冷压针型号TL00订货号198 001 000 0001更多10A冷压针请详情参见第13-02,第13-02页.注意事项：冷压压接的工具关系到产品的品质稳定性，请选择我司认证的工具。

德国戴博热缩机参数
德国戴博热缩机作为具有一定竞争力的热缩包装机械，其技术参数如下：
1. 最大热缩尺寸：L+H≤600mm，W+H≤400mm
2. 最小热缩尺寸：L+H≥100mm，W+H≥60mm
3. 封包速度：15-25包/分钟
4. 热缩速度：0-1.5米/分钟
5. 适用薄膜材质：PVC、POF、PP等
6. 电源要求：220V/380V，50Hz/60Hz
7. 动力耗电：8.5kw(h)
从以上参数可以看出，德国戴博热缩机具有较高的封包速度和热缩速度，能够适应多种薄膜材质的包装需求。

同时，其最大热缩尺寸也比较大，可满足一些比较大型的产品包装要求。

除此之外，德国戴博热缩机还有以下优点：
1. 采用先进的进口电器元件和控制系统，性能稳定可靠。

2. 设计合理，操作方便，可实现自动化生产线操作。

3. 热缩效果好，包装外形美观，能够提高产品的形象和附加值。

4. 可以适应多种规格的产品包装，适用范围广泛。

5. 采用高品质材料，机器寿命长，维护简单方便。

德国戴博热缩机作为先进的热缩包装设备，可以提高生产效率，改善产品包装质量。

企业在选购时应结合自身产品特点和生产要求，综合考虑设备的技术参数、质量、效益等因素，选择合适的热缩机型号，以达到最佳的生产效果和节约成本的目的。

S52xxMLow Drop Output Voltage RegulatorDescriptionThe S52xxM is a u-cap 150mA linear voltage regulator in the SOT-25 package. This regulator has very low dropout voltage and very low ground current. It is designed especially for hand-sets, battery-powered devices and can be controlled by a CMOS or TTL. When the S52xxM is disabled, power consumption drops to nearly zero.Features• Low dropout voltage regulator• Low quiescent current and guaranteed 150mA output • Zero off-mode currentOrdering InformationType NO. Marking Package Code S52xxM5□□SOT - 25□□: V oltage CodeS e m i c o n d u c t o rAbsolute Maximum Ratings Ta=25°CUnitRatingsCharacteristic Symbol~+16 VInput supply voltage V IN -0.4Enable Input Voltage V EN -0.4~+16 VPower Dissipation Pd 500 mW~+125 °CJunction Temperature Range T j -40~+150 °CStorage Temperature Range T stg -60Lead Temperature Time T sol260 (5 Sec) °CElectrical Characteristics=(※V=V+1V; I = 100uA; C=4.7uF; V≥2.0V; T=25℃) Array *Note1 : Dropout V oltage is the difference between the input voltage and the output voltage at whitch point the regulatorstarts to fall out of regulation (this is the point when the output voltage decreases by 100mV).Table 1Electrical Characteristics TableTest Condition; V IN = V OUT(TYP) +1V , I OUT =100uA, T A =25℃, unless otherwise specified.Voltage Limit [V]Output Voltage[V] Voltage CodeMIN MAX1.5 15 1.440 1.560 1.8 18 1.728 1.8722.5 25 2.400 2.600 2.8 28 2.688 2.9123.0 30 2.880 3.120 3.3 33 3.168 3.432 5.0 504.8005.200■Typical ApplicationsElectrical Characteristic CurvesElectrical Characteristic Curves (Cont.)Shutdown (Dis/Enable) OperationThe S52xxM output can be turned off by applying 0.4V or less to the device’s Dis/Enable pin (pin3). In shutdown mode, the S52xxM draws less than 1uA quiescent current. The output of the S52xxM is enabled by applying 1.5V to 13V at the Dis/Enable pin. In applications were the S52xxM output will always remain enabled, the Dis/Enable pin may be connected to Vin(pin1). The S52xxM’s shutdown circuitry includes hysteresis, as such the device will operate properly even if a slow moving signal is applied to the Dis/Enable pin. The device’s shutdown pin includes a 2M Ω internal pull down resistor connected to ground.Short Circuit ProtectionThe S52xxM output can withstand momentary short circuit to ground. Moreover , the regulator can deliver very high output peak current due to its 1A instantaneous short circuit current capability.Noise Bypass CapacitorIn low noise applications, the self noise of the S52xxM can be decreased further by connecting a capacitor from the noise bypass pin (pin4) to ground (pin2). The noise bypass pin is a high impedance node as such care should be taken in printed circuit board layout to avoid noise pick-up from external sources. Moreover , the noise bypass capacitor should have low leakage. Noise bypass capacitors with a value as low as 470pF may be used. However , for optimum performance, use a 0.01uF or larger , ceramic chip capacitor . Note that the turn on and turn off response of the S52xxM is inversely proportional to the value of the noise bypass capacitor . For fast turn on and turn off, use a small value noise Bypass capacitor . In applications were exceptionally low output noise is not required, consider omitting the noise Bypass capacitor altogether .Output Capacitor SelectionAUK strongly recommends the use of low ESR(Equivalent series resistance) ceramic capacitors for Cout and C N . The S52xxM is stable with low ESR capacitor (as low as zero Ω). The value of the output capacitor should be 1uF or higher. Either ceramic chip or a tantalum capacitor may be used at the output. Use of ceramic chip capacitors offer significant advantages over tantalum capacitors. A Ceramic capacitor is typically cheaper than a tantalum capacitor, it usually has a smaller footprint, lower height, and lighter weight than a tantalum capacitor. Furthermore, unlike tantalum capacitors which are polarized and can be damaged if connected incorrectly, ceramic capacitors are non-polarized. Low value ceramic chip capacitors with X5R or X7R dielectric are available in the 100pF to 4.7uF range. Beware of using ceramic capacitors with Y5V dielectric since their ESR increases significantly at cold temperatures. Figure 9 shows a list of recommended ceramic capacitors for use at the output of S52xxM.If a tantalum output capacitor is used then for stable operation AUK recommends a low ESR tantalum capacitor with maximum rated ESR at or below 0.4Ω. Low ESR tantalum capacitors, such as the TPS series from AVX Corporation () or the T495 series from Kemet () may be used.In applications where a high output surge current can be expected, use a high value but low ESR output capacitor for superior load transient response. The S52xxM is stable with no load.Fig. 9C OUT Capacitor Size I OUT Dielectric Part Number Capacitor Vendor1µF 0805 0 to 150mA X5R C2012X5R1A105KT TDK′′0805 ′′X7R GRM40X7R105K010 muRata′′0805 ′′X7R LMK212BJ105KG Taiyo-Yuden ′′1206 ′′X7R GRM42-6X7R105K016 muRata′′1206 ′′X7R EMK316BJ105KL Taiyo-Yuden ′′1206 ′′X5R TMK316BJ105KL Taiyo-Yuden2.2µF 0805 0 to 150mA X5R GRM40X5R225K 6.3 muRata′′0805 ′′X5R C2012X5R0J225KT TDK′′1206 ′′X5R EMK316BJ225ML Taiyo-Yuden4.7µF 1206 0 to 150mA X5R GRM42-6X5R475K010 MuRata′′1206 ′′X7R LMK316BJ475ML Taiyo-Yuden。

HLP-C100系列海利普变频器参考资料1. 产品概述HLP-C100系列海利普变频器是一款高性能的变频器，广泛应用于各种工业自动化控制系统中。

该系列变频器具有稳定可靠、高效能、易操作等特点。

2. 技术参数- 输入电压：220V/380V- 额定功率：1.5kW-315kW- 频率范围：0Hz-400Hz- 输出电流：根据不同型号而定3. 产品特点- 整机结构紧凑，体积小，安装方便。

- 具备过流、过载、过压、欠压等多重保护功能，保证设备的安全运行。

- 支持多种控制方式，如键盘控制、外部信号控制、RS485通信控制等。

- 高效能的PWM控制方式，提供稳定的输出电流和电压。

- 具备良好的动态特性，响应速度快，能够满足各种工况的需求。

- 具有良好的抗干扰能力，适用于复杂的工业环境。

- 支持多种编码器接口，方便与其他设备进行联动控制。

4. 安装和调试- 安装前，请确保电源和电机的接线正确无误。

- 安装过程中，请注意保持变频器的通风良好，避免高温环境。

- 连接控制信号时，请确保信号线的可靠性和正确性。

- 安装完成后，请进行相关参数的设置和调试。

5. 故障排除- 变频器故障常见原因包括过载、过热、电源异常等，请根据具体的故障表现进行排查。

- 在排除故障时，请务必断开电源，并由专业人员进行处理。

- 如有需要，可参考附带的故障代码手册进行故障诊断。

6. 维护保养- 变频器使用一段时间后，应及时清洁设备表面和通风口，避免灰尘堆积影响散热效果。

- 定期检查电源线和控制线的连接状态，确保接触良好。

- 如发现异味、异常噪音等情况，请立即停机检查，并由专业人员进行维修。

以上是HLP-C100系列海利普变频器的参考资料，希望对您有所帮助。

如需进一步了解，请参考产品说明书或联系我们的技术支持团队。

1.在使用前，请仔细检查分析系统和相关器件。

同时，请仔细熟悉系统和相关资料。

2.通电之前请仔细检查系统的安装。

3.正式使用之前，请仔细熟悉相关信息。

4.系统在应用过程中请及时进行相关的检查、维护。

分析系统技术手册目录说明：带√表示在技术手册中存在。

设计员：（签字）部门经理：（签字）年月分析系统安装操作使用说明书西克麦哈克（北京）仪器有限公司目录一.用途及安装使用条件二.结构及工作原理三.主要技术数据四.成套性五.安装六.启动与调校七.使用与维护八.运输与保管九.制造厂的保证一.用途及安装使用条件1.系统的用途本系统是针对于含有大量的水和尘的工艺样气进行气体分析而设计的。

在系统中完成了对工艺样气的取样点处高温状态过滤、保温传送、室温缓冲粗脱水过滤、压缩机冷凝脱水、压缩机精脱水及缓冲过滤过程。

在这其过程中，完成了对尘的过滤和对大批量水的冷凝排放过程。

系统中的S710气体分析仪器监测工艺样气中的一氧化碳的浓度，并能够以4～20mA DC（已经隔离）的形式向控制室的二次仪表输出。

本系统可以跟据自动监测工艺样气的一氧化碳浓度含量，提供两个相应组分的报警（可设置）。

当相应组分的测量浓度超过其设定值时，系统将提出报警信号（无源开关量），当相应组分的测量值低于设定值时，报警信号将消失。

本系统自动完成对工艺样气的高温状态下过滤、保温传送、冷凝脱水、过滤和分析的过程。

同时，自动完成预处理过程中产生的冷凝水排放和取样探头的反吹过程。

同时，具有手动的工艺样气的取样、取样探头反吹、冷凝水排放功能。

2.系统的安装使用条件✧系统供电电源：电压AC 220V±10% 频率50Hz±1%✧取样探头供电电源：电压AC 220V±10% 频率50Hz±1%✧取样探头请安装在具有代表性的工艺管道。

✧为了减少测量的滞后时间，本分析系统应尽量安装在测量点附近，样气流路不适宜过长，气流阻力尽量减小。

✧本系统需要排水，现场应具备良好的排水条件，严禁室内排放。

Agilent HLMP-CxxxT-13/4 (5mm) Extra Bright Precision Optical Performance InGaN LED Lamps Data SheetDescriptionThese high intensity blue and green LEDs are based on the most efficient and cost effective InGaN material technology. The 470 nm typical dominant wave–length for blue and 525 nm typical wavelength for green is well suited to color mixing in full color signs. The 505 nm typical dominant wavelength for cyan is suitable for traffic signal application.These LED lamps are untinted, non-diffused, T-13/4 packagesFeatures•Well defined spatial radiationpattern•High luminous output•Available in blue, green, and cyancolor•Viewing angle: 15°, 23°and 30°•Standoff or non-standoff leads•Superior resistance to moistureApplications•Traffic signals•Commercial outdoor advertising•Front panel backlighting•Front panel indicator incorporating second generationoptics which produce well-definedspatial radiation patterns atspecific viewing cone angles.These lamps are made with anadvanced optical grade epoxy,offering superior temperatureand moisture resistance inoutdoor signal and signapplications. The high maximumLED junction temperature limitof +110°C enables hightemperature operation in brightsunlight conditions.HLMP-CB11, HLMP-CB12, HLMP-CM11, HLMP-CM12, HLMP-CE11,HLMP-CE12, HLMP-CB26, HLMP-CB27, HLMP-CM26, HLMP-CM27,HLMP-CE26, HLMP-CE27, HLMP-CB36, HLMP-CB37, HLMP-CM36,HLMP-CM37, HLMP-CE36, HLMP-CE37CAUTION: Devices are Class I ESD sensitive. Please observe appropriate precautions during handling and processing. Refer to Application Note AN-1142 for additional details.Package DimensionsPackage APackage B5.80 ± 0.20(0.228 ±∅ CATHODEFLATMIN.SQ. TYP.NOTES:1. MEASURED JUST ABOVE FLANGE.2. ALL DIMENSIONS ARE IN MILLIMETERS (INCHES).3. EPOXY MENISCUS MAY EXTEND ABOUT 1 mm (0.040") DOWN THE LEADS.4. IF HEAT SINKING APPLICATION IS REQUIRED, THE TERMINAL FOR HEAT SINK IS ANODE.Device Selection GuideTypicalViewing Angle,Intensity (cd) at 20 mA PackagePart Number Color2q1/2 (Degree)Min.Max.Standoff Dimension Lens HLMP-CB11-TW0xx Blue15 2.57.2No A Clear HLMP-CB11-UVAxx Blue15 3.2 5.5No A Clear HLMP-CB12-TW0xx Blue15 2.57.2Yes B Clear HLMP-CM11-Y20xx Green159.327.0No A Clear HLMP-CM11-Z1Cxx Green1512.021.0No A Clear HLMP-CM12-Y20xx Green159.327.0Yes B Clear HLMP-CE11-X10xx Cyan157.221.0No A Clear HLMP-CE12-X10xx Cyan157.221.0Yes B Clear HLMP-CB26-SV0xx Blue23 1.9 5.5No A Clear HLMP-CB26-TUDxx Blue23 2.5 4.2No A Clear HLMP-CB27-SV0xx Blue23 1.9 5.5Yes B Clear HLMP-CM26-X10xx Green237.221.0No A Clear HLMP-CM26-YZCxx Green239.316.0No A Clear HLMP-CM27-X10xx Green237.221.0Yes B Clear HLMP-CE26-WZ0xx Cyan23 5.516.0No A Clear HLMP-CE27-WZ0xx Cyan23 5.516.0Yes B Clear HLMP-CB36-QT0xx Blue30 1.15 3.2No A Clear HLMP-CB36-RSAxx Blue30 1.5 2.5No A Clear HLMP-CB37-RU0xx Blue30 1.5 4.2Yes B Clear HLMP-CB37-RSDxx Blue30 1.5 2.5Yes B Clear HLMP-CM36-X10xx Green307.221.0No A Clear HLMP-CM36-XYCxx Green307.212.0No A Clear HLMP-CM37-X10xx Green307.221.0Yes B Clear HLMP-CM37-XYCxx Green307.212.0Yes B Clear HLMP-CM37-XYDxx Green307.212.0Yes B Clear HLMP-CE36-WZ0xx Cyan30 5.516.0No A Clear HLMP-CE37-WZ0xx Cyan30 5.516.0Yes B ClearNotes:1.Tolerance for luminous intensity measurement is ±15%.2.The luminous intensity is measured on the mechanical axis of the lamp package.3.The optical axis is closely aligned with the package mechanical axis.4.LED light output is bright enough to cause injuries to the eyes. Precautions must be taken to prevent looking directly at the LED without propersafety equipment.5. 2q1/2 is the off-axis angle where the luminous intensity is 1/2 the on-axis intensity.Part Numbering SystemHLMP-x x xx-x x x xxMechanical Options00: BulkDD: Ammo PackColor Bin Options0: Full Color Bin DistributionA: Color Bin 1 and 2C: Color Bin 3 and 4D: Color Bin 4 and 5Maximum Intensity Bin0: No Maximum Intensity Bin LimitationOthers: Refer to Device Selection GuideMinimum Intensity BinRefer to Device Selection GuideViewing Intensity Bin11: 15° Without Standoff12: 15°With Standoff26: 23°Without Standoff27: 23°With Standoff36: 30°Without standoff37: 30°With StandoffColorB: Blue 470 nmM: Green 525 nmE: Cyan 505 nmPackageC: T-13/4 (5 mm) Round LampAbsolute Maximum Rating at T A = 25°CParameters Value UnitDC Forward Current [1]30mAPeak Pulsed Forward Current[3]100mAAverage Forward Current30mAPower Dissipation120mWLED Junction Temperature110°COperating Temperature Range–40 to +85°CStorage Temperature Range–40 to +100°CWave Soldering Temperature[2]250 for 3 secs°CNotes:1.Derate linearly as shown in Figure2.2.1.59 mm (0.060 inch) below body.3.Duty factor 10%, frequency 1 KHz.Electrical/Optical CharacteristicsT A = 25o CBlue Green CyanParameters Symbol Min.Typ.Max.Min.Typ.Max.Min.Typ.Max.Units Test Condition Forward Voltage V F 3.5 4.0 3.6 4.0 3.5 4.0V I F = 20 mA Reverse Voltage[1]V R 5.0 5.0 5.0V I R = 10 µA Thermal Resistance R q J-PIN240240240o C/W LED Junction toAnode Lead Dominant l d460470480520525540490505510nm I F = 20 mA Wavelength[2]Peak Wavelength l PEAK464516501nm Peak of Wavelengthof Spectral Distribu-tion at I F = 20 mA Spectral Half Width Dl1/2233230nm Wavelength Widthat Spectral Distribu-tion Power Pointat I F = 20 mA Luminous Efficacy[3]h v74484319lm/W Emitted LuminousPower/EmittedRadiant Power Notes:1.The reverse voltage of the product is equivalent to the forward voltage of the protective chip at I R = 10 µA.2.The dominant wavelength, l d, is derived from the Chromaticity Diagram and represents the color of the lamp.3.The radiant intensity, Ie in watts/steradian, may be found from the equation Ie = Iv/h v, where Iv is the luminous intensity in candelas and h v is theluminous efficacy in lumens/watt.Figure 5. Relative intensity vs. DC forward current.Figure 4. Relative dominant wavelength vs. DC forward current.DC FORWARD CURRENT – mAR E L A T I V E D O M I N A N T W A V E L E N G T H (N O R M A L I Z E D A T 20 m A )1020301.0250.9901.0151.0201.0101.0051.0000.995GREENBLUER E L A T I V E I N T E N S I T Y (N O R M A L I Z E D A T 20 m A )FORWARD CURRENT – mAFigure 1. Relative intensity vs. wavelength.Figure 3. Forward current vs. forward voltage.Figure 2. Forward current vs. ambient temperature.WAVELENGTH – nmR E L A T I V E I N T E N S I T Y1.0000.800.600.400.20030103.0202.01.0F O R W A R D C U R R E N T – m AFORWARD VOLTAGE – V 4.0CYANGREENBLUEI F – F O R W A R D C U R R E N T – m AV F – FORWARD VOLTAGE – VOLTSFigure 6. Spatial radiation pattern for Cx11 and Cx12.R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090Figure 7. Spatial radiation pattern for Cx26 and Cx27.Figure 8. Spatial radiation pattern for Cx36 and Cx37.R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090R E L A T I V E L U M I N O U S I N T E N S I T Y10ANGULAR DISPLACEMENT – DEGREES0.5-90-600-30306090Intensity Bin Limit TableIntensity (mcd) at 20 mA Bin Min MaxN680880P8801150Q11501500R15001900S1*******T25003200U32004200V42005500W55007200X72009300Y930012000Z1200016000 11600021000 Tolerance for each bin limit is ±15%.Blue Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1460.0464.00.14400.02970.17660.09660.18180.09040.13740.0374 2464.0468.00.13740.03740.16990.10620.17660.09660.12910.0495 3468.0472.00.12910.04950.16160.12090.16990.10620.11870.0671 4472.0476.00.11870.06710.15170.14230.16160.12090.10630.0945 5476.0480.00.10630.09450.13970.17280.15170.14230.09130.1327 Tolerance for each bin limit is ±0.5 nm.Cyan Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1490.0495.00.04540.29450.11640.38890.13180.3060.02350.4127 2495.0500.00.03450.41270.10570.47690.11640.38890.00820.5384 3500.0505.00.00820.53840.10270.55840.10570.47690.00390.6548 4505.0510.00.00390.65480.10970.62510.10270.55840.01390.7502 7498.0503.00.01320.48820.10280.52730.10920.44170.00400.6104 8503.0508.00.00400.61040.10560.60070.10280.52730.00800.7153 Tolerance for each bin limit is ±0.5 nm.Green Color Bin TableBin Min Dom Max Dom Xmin Ymin Xmax Ymax 1520.0524.00.07430.83380.18560.65560.16500.65860.10600.8292 2524.0528.00.10600.82920.20680.64630.18560.65560.13870.8148 3528.0532.00.13870.81480.22730.63440.20680.64630.17020.7965 4532.0536.00.17020.79650.24690.62130.22730.63440.20030.7764 5536.0540.00.20030.77640.26590.60700.24690.62130.22960.7543 Tolerance for each bin limit is ±0.5 nm./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152(Domestic/Interna-tional), or 0120-61-1280(Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc. December 7, 20045989-1022EN。

郎汉德PLC产品说明书LonHand-PLC文件版本：V1.0.2目录1.产品简介 (3)1.1产品概述 (3)1.2功能特点 (3)2.参数详情 (4)2.1电气参数 (4)2.2编程电缆参数 (5)2.3选型表 (6)2.4引脚定义 (8)2.4.1LH-M1410T(晶体管输出) (8)2.4.2LH-M1616T(晶体管输出) (9)2.4.3LH-M0808T(晶体管输出) (9)2.4.4LH-M1408R(继电器输出) (10)2.4.5LH-M0808R(继电器输出) (11)2.5PLC地址 (12)2.5.1PLC地址使用情况 (12)2.5.2特殊寄存器和位 (14)2.6模拟量转换 (18)2.7兼容三菱指令 (19)3.通信使用 (24)3.1串口通信配置 (24)3.2RS485通讯示例 (25)3.2.1PLC作为3U协议从站 (25)3.2.2PLC作为Modbus从站 (25)3.2.3PLC平时作为Modbus从站，临时切到3U下程序 (27)3.3自由通信协议ADPRW (28)3.3.1串口自由通信协议ADPRW指令使用 (28)3.3.2Modbus主站通信协议ADPRW指令使用 (30)4.售后 (32)5.更新历史 (32)1.产品简介1.1产品概述本PLC尺寸小巧，接口丰富，扩展性强，支持3U编程风格。

广泛应用于工业自动化领域。

1.2功能特点●极具有成本优势的高端PLC，支持3U编程风格；●外观紧凑，极省空间；可拔插压接端子，便于维护和调试；●直流供电，电源与外部隔离；●所有通讯口均隔离；●支持扩展，最大15个；●输出可支持NPN晶体管，继电器；●具有混合型主机以及混合型扩展模块，可有效节省模块数量；●最大编程步16K2.参数详情PLC 主机模块和PLC扩展模块的外观尺寸一致，如下图：2.1电气参数类别项目参数电气环境供电电源额定24V,12-32V 宽压输入范围;内部与外供电电气隔离工作温度-20~55°C湿度5%-95%RH (非结露)抗干扰性峰值:1500vp-p;幅度1uS;上升时间:30ms ;周期30-100HZ 抗震动符合IEC61121-2标准电气隔离性能通讯隔离性通讯口均与内部隔离电源隔离性内部5V、15V 之间隔离;与24V 输入隔离数字量量输入导通状态高于DC 15V,2.5mA 关断状态低于DC 7V,1mA晶体管输出响应时间ON->OFF20us以内OFF->ON50us以内输出电压范围DC5V~30V额定输出负载0.75A@DC24V继电器输出响应时间10ms以内输出电压范围DC5V-30或AC5V~250V 额定输出电压DC24V/2A或AC220V/2.0A 使用寿命机械1千万次电气10万次（额定负载）模拟量输出输出范围电压输出0~10V 电流输出0~20mA模拟量输入输入范围电流输入0-20mA或4-20mA 电压输入0-10V运动控制脉冲输出速度可达200KHZ 计数输入速度可200K以上2.2编程电缆参数本PLC对应的编程口为RS232通信。

AgilentT-13/4 (5 mm), T-1 (3 mm),High Intensity, Double Heterojunction AlGaAs Red LED LampsData SheetHLMP-D101/D105, HLMP-K101/K105DescriptionThese solid state LED lamps utilize newly developed doubleheterojunction (DH) AlGaAs/GaAs material technology. This LED material has outstanding lightoutput efficiency over a wide rangeFeatures• Exceptional brightness • Wide viewing angle• Outstanding material efficiency • Low forward voltage • CMOS/MOS compatible • TTL compatible • Deep red colorApplications• Bright ambient lighting conditions • Moving message panels • Portable equipment • General useof drive currents. The color is deep red at the dominantwavelength of 637 nanometres.These lamps may be DC or pulse driven to achieve desired light output.Package DimensionsA B CSelection GuideLuminous IntensityIv (mcd) at 20 mA2θ1/2[1]Package Package Description Device HLMP-Min.Typ.Max.Degree Outline T-1 3/4 Red Tinted Diffused D10135.270.0–65AD101-J00xx35.270.0–65AD101-JK0xx35.270.0112.865AT-1 3/4 Red Untinted Non-diffused D105138.0240.0–24BD105-M00xx138.0240.0–24BD105-NO0xx200.0290.0580.024BT-1 Red Tinted Diffused K10122.045.0–60CK101-100xx22.045.0–60CK101-IJ0xx22.045.070.460CT-1 Red Untinted Non-diffused K10535.265.0–45CK105-J00xx35.265.0–45CK105-KL0xx56.4110.0180.445CNote:1. θ1/2 is the off axis angle from lamp centerline where the luminous intensity is 1/2 the on-axis value.Part Numbering SystemHLMP - x x xx - x x x xxMechanical Option00: Bulk01: Tape & Reel, Crimped Leads02: Tape & Reel, Straight LeadsA1: Right Angle Housing, Uneven Leads, T1A2: Right Angle Housing, Even Leads, T1B1: Right Angle Housing, Uneven Leads, T-1 3/4B2: Right Angle Housing, Even Leads, T-1 3/4DD, UQ: Ammo PackColor Bin Options0: Full Color Bin DistributionMaximum Iv Bin Options0: Open (no max. limit)Others: Please refer to the Iv Bin TableMinimum Iv Bin OptionsPlease refer to the Iv Bin TableLens Type01: Tinted, Diffused05: Untinted, NondiffusedColor Options1: AlGaAs RedPackage OptionsD: T-1 3/4K: T-1Absolute Maximum Ratings at T A = 25°CParameter ValuePeak Forward Current[1,2]300 mAAverage Forward Current[2]20 mADC Current[3]30 mAPower Dissipation87 mWReverse Voltage (I R = 100 µA) 5 VTransient Forward Current (10 µs Pulse)[4]500 mALED Junction Temperature110°COperating Temperature Range-20 to +100°C Storage Temperature Range-55 to +100°C Wave Soldering Temperature [1.59 mm (0.063 in.) from body]250°C for 3 seconds Lead Solder Dipping Temperature [1.59 mm (0.063 in.) from body]260°C for 5 seconds Notes:1.Maximum I PEAK at f = 1 kHz, DF = 6.7%.2.Refer to Figure 6 to establish pulsed operating conditions.3.Derate linearly as shown in Figure 5.4.The transient peak current is the maximum non-recurring peak current the device can withstand without damaging the LED die and wire bonds. It isnot recommended that the device be operated at peak currents beyond the Absolute Maximum Peak Forward Current.Electrical/Optical Characteristics at T A = 25°CSymbol Description Min.Typ.Max.Unit Test ConditionV F Forward Voltage 1.8 2.2V I F = 20 mAV R Reverse Breakdown Voltage 5.015.0V I R = 100 µAλp Peak Wavelength645nm Measurement at Peakλd Dominant Wavelength637nm Note 1∆λ1/2Spectral Line Halfwidth20nmτS Speed of Response30ns Exponential TimeConstant, e-t/T SC Capacitance30pF V F = 0, f = 1 MHzRθJ-PIN Thermal Resistance260[3]°C/W Junction to Cathode Lead210[4]290[5]ηV Luminous Efficacy80Im/W Note 2Notes:1.The dominant wavelength, λd, is derived from the CIE chromaticity diagram and represents the color of the device.2.The radiant intensity, I e, in watts per steradian, may be found from the equation I e = l V/ηV, where I V is the luminous intensity in candelas and ηV isluminous efficacy in lumens/watt.3.HLMP-D101.4.HLMP-D105.5.HLMP-K101/-K105.Figure 3. Relative luminous intensity vs. dc forward current.Figure 4. Relative efficiency vs. peak forward current.Figure 7. Relative luminous intensity vs. angular displacement. HLMP-D101.Figure 8. Relative luminous intensity vs. angular displacement. HLMP-K101.Intensity Bin LimitsIntensity Range (mcd)Color Bin Min.Max.Red I24.839.6J39.663.4K63.4101.5L101.5162.4M162.4234.6N234.6340.0O340.0540.0P540.0850.0Q850.01200.0R1200.01700.0S1700.02400.0T2400.03400.0U3400.04900.0V4900.07100.0W7100.010200.0X10200.014800.0Y14800.021400.0Z21400.030900.0Maximum tolerance for each bin limit is ± 18%.Mechanical Option MatrixMechanical Option Code Definition00Bulk Packaging, minimum increment 500 pcs/bag01Tape & Reel, crimped leads, minimum increment 1300 pcs (T-1 3/4)/1800 pcs (T-1) 02Tape & Reel, straight leads, minimum increment 1300 pcs (T-1 3/4)/1800 pcs (T-1) A1Right Angle Housing, uneven leads, minimum increment 500 pcs/bagA2Right Angle Housing, even leads, minimum increment 500 pcs/bagB1Right Angle Housing, uneven leads, minimum increment 500 pcs/bagB2Right Angle Housing, even leads, minimum increment 500 pcs/bagDD Ammo Pack, straight leads in 2K incrementUQ Ammo Pack, horizontal leads in 2K incrementNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representative for further clarification/information./semiconductors For product information and a complete list of distributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or (916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939 Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only) Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand, Philippines, Indonesia: (+65) 6755 2044 Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc. Obsoletes 5968-1440ENovember 12, 20045988-2230EN。

BL21-CodonPlus-RP Competent Cells, Part Number 230250*************(24小时)化学品安全技术说明书GHS product identifier 应急咨询电话（带值班时间）::供应商/ 制造商:安捷伦科技贸易（上海）有限公司中国（上海）外高桥自由贸易试验区英伦路412号（邮编:200131)电话号码： 800-820-3278传真号码: 0086 (21) 5048 2818BL21-CodonPlus-RP Competent Cells, Part Number 230250化学品的推荐用途和限制用途BL21-CodonPlus-RP competent cells 230250-41pUC 18 DNA Control Plasmid 200231-42XL10-Gold 2-Mercaptoethanol 200314-43部件号:物质用途:分析试剂。

230250-41BL21-CodonPlus-RP competent cells1 ml（毫升） (10 x 100 µl)200231-42pUC 18 DNA ControlPlasmid0.01 ml（毫升） (0.1 ng/µl)200314-43XL10-Gold2-Mercaptoethanol0.05 ml（毫升）部件号（化学品试剂盒）:230250安全技术说明书根据 GB/ T 16483-2008 和 GB/ T 17519-2013GHS化学品标识:BL21-CodonPlus-RP 感受态细胞，部件号 230250物质或混合物的分类根据 GB13690-2009 和 GB30000-2013紧急情况概述BL21-CodonPlus-RP competent cells液体。

pUC 18 DNA Control Plasmid 液体。

LED Light Bars Technical DataFeatures•Large Bright, Uniform Light Emitting Areas•Choice of Colors •Categorized for Light Output •Yellow and Green Categorized for Dominant Wavelength•Excellent ON-OFF Contrast •X-Y Stackable•Flush Mountable•Can be Used with Panel and Legend Mounts• Light Emitting Surface Suitable for Legend Attachment per Application Note 1012•HLCP-X100 Series Designed for Low Current Operation •Bicolor Devices Available Applications•Business MachineMessage Annunciators •Telecommunications Indicators•Front Panel Process Status Indicators•PC Board Identifiers•Bar Graphs DescriptionThe HLCP-X100 and HLMP-2XXXseries light bars are rectangularlight sources designed for avariety of applications where alarge bright source of light isrequired. These light bars areconfigured in single-in-line anddual-in-line packages that containeither single or segmented lightemitting areas. The AlGaAs RedHLCP-X100 series LEDs usedouble heterojunction AlGaAs ona GaAs substrate. The HERHLMP-2300/2600 and YellowHLMP-2400/2700 series LEDshave their p-n junctions diffusedinto a GaAsP epitaxial layer on aGaP substrate. The Green HLMP-2500/2800 series LEDs use aliquid phase GaP epitaxial layeron a GaP substrate. The bicolorHLMP-2900 series use acombination of HER/Yellow orHER/Green LEDs.HLCP-A100, -B100, -C100,-D100, -E100, -F100, -G100,-H100HLMP-2300, -2350, -2400,-2450, -2500, -2550, -2600,-2620, -2635, -2655, -2670,-2685, -2700, -2720, -2735,-2755, -2770, -2785, -2800,-2820, -2835, -2855, -2870,-2885, -2950, -2965Selection GuideLight Bar Part Number Corresponding Size ofPackage Panel and HLCP-HLMP-Light Emitting AreasOutlineLegend Mount Part No. HLMP-AlGaAs HER Yellow Green A1002300240025008.89 mm x 3.81 mm 1A 2599(.350 in. x .150 in.)B10023502450255019.05 mm x 3.81 mm 1B 2598(.750 in. x .150 in.)D1002600270028008.89 mm x 3.81 mm 2D 2898(.350 in. x .150 in.)E1002620272028208.89 mm x 3.81 mm 4E 2899(.350 in. x .150 in.)F100263527352835 3.81 mm x 19.05 mm 2F 2899(.150 in. x .750 in.)C1002655275528558.89 mm x 8.89 mm 1C 2898(.350 in. x .350 in.)G1002670277028708.89 mm x 8.89 mm 2G 2899(.350 in. x .350 in.)H1002685278528858.89 mm x 19.05 mm 1H 2899(.350 in. x .750 in.)295029508.89 mm x 8.89 mm Bicolor I 2898(.350 in. x .350 in.)296529658.89 mm x 8.89 mm BicolorI2898(.350 in. x .350 in.)Number of Light Emitting AreasPart Numbering SystemHLCP- xx xx-xx x xxHLMP-xx xx-xx x xxMechanical Options[1]00: No mechanical optionColor Bin Options[1,2]0: No color bin limitationB: Color bins 2 & 3 (applicable for yellow devices only)C: Color bins 3 & 4 only (applicable for green devices only)Maximum Intensity Bin[1,2]0: No maximum intensity bin limitationMinimum Intensity Bin[1,2]0: No minimum intensity bin limitationDevice Specific Configuration[1]Refer to respective data sheetColor[1]x1: AlGaAs Red (applicable for HLCP-x100 only)23: High Efficiency Red24: Yellow25: Green26: High Efficiency Red27: Yellow28: Green29: Bicolor (High Efficiency Red/Yellow) OR (High Efficiency Red/Green) Notes:1. For codes not listed in the figure above, please refer to the respective data sheet or contact your nearest Agilent representativefor details.2. Bin options refer to shippable bins for a part-number. Color and Intensity Bins are typically restricted to 1 bin per tube(exceptions may apply). Please refer to respective data sheet for specific bin limit information.Package DimensionsNOTES:1. DIMENSIONS IN MILLIMETRES (INCHES). TOLERANCES ±0.25 mm (±0.010 IN.) UNLESS OTHERWISE INDICATED.2. FOR YELLOW AND GREEN DEVICES ONLY.Internal Circuit DiagramsAbsolute Maximum RatingsHER Yellow GreenAlGaAs Red HLMP-2300/HLMP-2400/HLMP-2500/ ParameterHLCP-X1002600/29XX2700/29502800/2965Series Series Series Series Average Power Dissipated per LED Chip37 mW[1]135 mW[2]85 mW[3]135 mW[2] Peak Forward Current per LED Chip45 mA[4]90 mA[5]60 mA[5]90 mA[5] Average Forward Current per LED Chip15 mA25 mA20 mA25 mADC Forward Current per LED Chip15 mA[1]30 mA[2]25 mA[3]30 mA[2] Reverse Voltage per LED Chip 5 V 6 V[6]Operating Temperature Range–20°C to +100°C[7]–40°C to +85°C–20°C to +85°C Storage Temperature Range –40°C to +85°CWave Soldering Temperature250°C for 3 seconds1.6 mm (1/16 inch) below BodyNotes:1.Derate above 87°C at 1.7 mW/°C per LED chip. For DC operation, derate above 91°C at 0.8 mA/°C.2.Derate above 25°C at 1.8 mW/°C per LED chip. For DC operation, derate above 50°C at 0.5 mA/°C.3.Derate above 50°C at 1.8 mW/°C per LED chip. For DC operation, derate above 60°C at 0.5 mA/°C.4.See Figure 1 to establish pulsed operation. Maximum pulse width is 1.5 mS.5.See Figure 6 to establish pulsed operation. Maximum pulse width is 2 mS.6.Does not apply to bicolor parts.7.For operation below –20°C, contact your local Agilent sales representative.Electrical/Optical Characteristics at T A = 25°CAlGaAs Red HLCP-X100 SeriesParameter HLCP-Symbol Min.Typ.Max.Units Test ConditionsA100/D100/E100I V37.5mcd I F = 3 mA Luminous Intensityper Lighting Emitting B100/C100/F100/G100615mcdArea[1]H1001230mcdPeak WavelengthλPEAK645nmDominant Wavelength[2]λd637nmForward Voltage per LED V F 1.8 2.2V I F = 20 mA Reverse Breakdown Voltage per LED V R515V I R = 100 µA Thermal Resistance LED Junction-to-Pin RθJ-PIN250°C/W/LEDParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2400/2700/2720IV 620mcd IF= 20 mALuminous Intensityper Lighting Emitting2450/2735/2755/2770/2950[3]1338mcd Area[1]27852670mcdPeak WavelengthλPEAK583nmDominant Wavelength[2]λd585nmForward Voltage per LED VF 2.1 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDHigh Efficiency Red HLMP-2300/2600/2900 SeriesParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2300/2600/2620IV 623mcd IF= 20 mALuminous Intensityper Lighting Emitting2350/2635/2655/2670/2950[3]1345mcd Area[1]2965[4]1945mcd26852280mcdPeak WavelengthλPEAK635nmDominant Wavelength[2]λd626nmForward Voltage per LED VF 2.0 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDYellow HLMP-2400/2700/2950 SeriesHigh Performance Green HLMP-2500/2800/2965 SeriesParameter HLMP-Symbol Min.Typ.Max.Units Test Conditions2500/2800/2820IV 525mcd IF= 20 mALuminous Intensityper Lighting Emitting2550/2835/2855/28701150mcd Area[1]2965[4]2550mcd288522100mcdPeak WavelengthλPEAK565nmDominant Wavelength[2]λd572nmForward Voltage per LED VF 2.2 2.6V IF= 20 mAReverse Breakdown Voltage per LED[5]VR 615V IR= 100 µAThermal Resistance LED Junction-to-Pin RθJ-PIN 150°C/W/LEDNotes:1.These devices are categorized for luminous intensity. The intensity category is designated by a letter code on the side of the package.2.The dominant wavelength, λd , is derived from the CIE chromaticity diagram and is the single wavelength which defines the color of thedevice. Yellow and Green devices are categorized for dominant wavelength with the color bin designated by a number code on the side of the package.3.This is an HER/Yellow bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Yellow electrical/opticalcharacteristics are shown in the Yellow table.4.This is an HER/Green bicolor light bar. HER electrical/optical characteristics are shown in the HER table. Green electrical/opticalcharacteristics are shown in the Green table.5.Does not apply to HLMP-2950 or HLMP-2965.Figure 1. Maximum Allowable Peak Current vs. Pulse Duration.Figure 4. Forward Current vs. Forward Voltage.Figure 5. Relative Luminous Intensity vs. DC Forward Current.AlGaAs RedFor a detailed explanation on the use of data sheet information and recommended soldering procedures,see Application Notes 1005, 1027, and 1031.HER, Yellow, GreenIntensity Bin Limits (mcd)HLMP-2300/2600/2620 Annunciators (.2 x .4 HER/AlGaAs), HLCP-A100/D100/E100IV Bin Category Min.Max.A 3.00 5.60B 4.508.20C 6.8012.10D10.1018.50E15.3027.80F22.8045.50G36.9073.80Notes:1. Minimum category A for Red L/C AlGaAs (-A100/-D100/-E100).2. Minimum category C for HER (-2300/-2600/-2620).HLMP-2350/2635/2655/2670 Annunciators (.2 x .8 HER/AlGaAs), HLCP-B100/C100/F100/G100 (.4 x .4 HER/AlGaAs)IV Bin Category Min.Max.A 5.4010.90B9.0016.00C13.1024.00D19.7036.10E29.6054.20F44.9088.80G71.90143.80Notes:1. Minimum category A for Red L/C AlGaAs (-B100/-C100/-F100/-G100).2. Minimum category C for HER (-2350/-2635/-2670).HLMP-2685/HLCP-H100 Annunciators (.4 x .8 HER/AlGaAs) IV Bin Category Min.Max.A10.8022.00B18.0027.10C22.0040.80D33.3061.10E50.0091.80F75.10150.00G121.70243.40Notes:1. Minimum category A for Red L/C AlGaAs (-H100).2. Minimum category C for HER (-2685).HLMP-2400/2700/2720 Annunciators (.2 x .4 Yellow)IV Bin Category Min.Max.C 6.1011.20D9.2016.80E13.8025.30F20.7041.40G33.6067.20HLMP-2450/2735/2755/2770 Annunciators (.2 x .8 Yellow & .4 x .4 Yellow) IV Bin Category Min.Max.C13.0022.00D18.0033.00E27.0050.00F40.5081.00G65.60131.20HLMP-2785 Annunciators (.4 x .8 Yellow)IV Bin Category Min.Max.C26.0044.40D36.0066.00E54.0099.00F81.00162.00G131.40262.80HLMP-2500/2800/2820 Annunciators (.2 x .4 Yellow)IV Bin Category Min.Max.C 5.6010.20D8.4015.30E12.6023.10F18.9037.80G30.6061.20H49.5097.90I80.10158.40HLMP-2550/2835/2855/2870 Annunciators (.2 x .8/.4 x .4 Green) IV Bin Category Min.Max.C11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20H99.81197.67I161.73320.21HLMP-2885 Annunciators (.4 x .8 Green)IV Bin Category Min.Max.C22.2040.80D33.4061.20E50.1091.90F75.10150.30G121.10242.20H196.10383.50I313.70613.60HLMP-2950 Bi-Color Annunciators (.4 x .4 HER/Yellow) IV Bin Category Min.Max.Red Iv CategoriesC11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20Yellow Iv CategoriesC13.0022.00D18.0033.00E27.0050.00F40.5081.00G65.60131.20HLMP-2965 Bi-Color Annunciators (.4 x .4/.2 x .8 HER/Green) IV Bin Category Min.Max.Red Iv CategoriesD19.7036.10E29.6054.20F44.9088.80G71.90143.80Green Iv CategoriesB7.5013.90C11.3020.60D17.0031.00E25.4046.50F38.1076.20G61.60123.20H100.00200.00Notes:1. Minimum category D for LPE Green (-2965).2. In green mode, the devices are to be color binned into standard color bins, perTable 2. (-2685).Color CategoriesNote:All categories are established for classification of products. Products may not be available in all categories. Please contact your local Agilent representatives for further clarification/information.I AVG I v TIME AVG =I TESTwhere:I TEST =3 mA for AlGaAs Red(HLMP-X000 series)20 mA for HER,Yellow and Green (HLMP-2XXX series)Example:For HLMP-2735 series ηI PEAK = 1.18 at I PEAK = 48 mA12 mA I v TIME AVG =20 mA= 25 mcd[][]ElectricalThese light bars are composed of two, four, or eight light emitting diodes, with the light from each LED optically scattered to form an evenly illuminated light emitting surface.The anode and cathode of each LED is brought out by separate pins. This universal pinoutarrangement allows the LEDs to be connected in three possible configurations: parallel, series, or series parallel. The typical forward voltage values can be scaled from Figures 4 and 9.These values should be used to calculate the current limiting resistor value and typical power consumption. Expected maximum V F values for driver circuit design and maximum power dissipation,may be calculated using the following V F MAX models:AlGaAs Red HLCP-X100 series V F MAX = 1.8 V + I Peak (20 Ω)For: I Peak ≤ 20 mAV F MAX = 2.0 V + I Peak (10 Ω)For: 20 mA ≤ I Peak ≤ 45 mA HER (HLMP-2300/2600/2900),Yellow (HLMP-2400/2700/2900)and Green (HLMP-2500/2800/2900) seriesV F MAX = 1.6 + I Peak (50 Ω)For: 5 mA ≤ I Peak ≤ 20 mA V F MAX = 1.8 + I Peak (40 Ω)For: I Peak ≥ 20 mAThe maximum power dissipation can be calculated for any pulsed or DC drive condition. For DC operation, the maximum powerdissipation is the product of the maximum forward voltage and the maximum forward current. For pulsed operation, the maximum power dissipation is the product of the maximum forward voltage at the peak forward current times the maximum average forward current. Maximum allowable power dissipation for any given ambient temperature and thermal resistance (R θJ-A ) can be deter-mined by using Figure 2 or 7. The solid line in Figure 2 or 7 (R θJ-A of 600/538 C/W) represents a typical thermal resistance of a device socketed in a printed circuitboard. The dashed lines represent achievable thermal resistances that can be obtained through improved thermal design. Once the maximum allowable power dissipation is determined, the maximum pulsed or DC forward current can be calculated.OpticalSize of Light Surface Area Emitting Area Sq. Metres Sq. Feet 8.89 mm x 8.89 mm 67.74 x 10–6729.16 x 10–68.89 mm x 3.81 mm 33.87 x 10–6364.58 x 10–68.89 mm x 19.05 mm 135.48 x 10–61458.32 x 10–63.81 mm x 19.05 mm72.85 x 10–6781.25 x 10–6The radiation pattern for these light bar devices is approximately Lambertian. The luminoussterance may be calculated using one of the two following formulas:I v (cd)L v (cd/m 2) =A (m 2)πI v (cd)L v (footlamberts) =A (ft 2)Refresh rates of 1 kHz or faster provide the most efficientoperation resulting in the maxi-mum possible time average luminous intensity.The time average luminousintensity may be calculated using the relative efficiency character-istic of Figure 3 or 8, ηI PEAK , and adjusted for operating ambient temperature. The time average luminous intensity at T A = 25°C is calculated as follows:(ηI PEAK ) (I v Data Sheet)(1.18) (35 mcd)The time average luminous intensity may be adjusted for operating ambient temperature by the following exponential equation:I v (T A) = I V (25°C)e[K (T –25°C)]Color KAlGaAs Red–0.0095/°CHER–0.0131/°C Yellow–0.0112/°C Green–0.0104/°CExample:I v (80°C) = (25 mcd)e[-0.0112 (80-25)] = 14 mcd.MechanicalThese light bar devices may beoperated in ambient temperaturesabove +60°C without deratingwhen installed in a PC boardconfiguration that provides athermal resistance pin to ambientvalue less than 280°C/W/LED. SeeFigure 2 or 7 to determine themaximum allowed thermalresistance for the PC board,RθPC-A, which will permitnonderated operation in a givenambient temperature.To optimize device opticalperformance, specially developedplastics are used which restrictthe solvents that may be used forcleaning. It is recommended thatonly mixtures of Freon (F113)and alcohol be used for vaporcleaning processes, with animmersion time in the vapors ofless than two (2) minutesmaximum. Some suggested vaporcleaning solvents are Freon TE,Genesolv DES, Arklone A or K. A60°C (140°F) water cleaningprocess may also be used, whichincludes a neutralizer rinse (3%ammonia solution or equivalent),a surfactant rinse (1% detergentsolution or equivalent), a hotwater rinse and a thorough airdry. Room temperature cleaningmay be accomplished with FreonT-E35 or T-P35, Ethanol,Isopropanol or water with a milddetergent.For further information onsoldering LEDs please refer toApplication Note 1027.A/semiconductorsFor product information and a complete list ofdistributors, please go to our web site.For technical assistance call:Americas/Canada: +1 (800) 235-0312 or(916) 788-6763Europe: +49 (0) 6441 92460China: 10800 650 0017Hong Kong: (+65) 6756 2394India, Australia, New Zealand: (+65) 6755 1939Japan: (+81 3) 3335-8152 (Domestic/Interna-tional), or 0120-61-1280 (Domestic Only)Korea: (+65) 6755 1989Singapore, Malaysia, Vietnam, Thailand,Philippines, Indonesia: (+65) 6755 2044Taiwan: (+65) 6755 1843Data subject to change.Copyright © 2004 Agilent Technologies, Inc.Obsoletes 5962-7197EJuly 8, 20045988-2221EN。