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LAMBDA SENSORSUNIVERSAL APPLICATIONS OPTIMUM PERFORMANCEProduct / Technical InformationI n c l u d e s n e w P re m i u m S e n s o r s r a n g eLambda Sensors detect and measure the presence of oxygen in exhaustgases. It then compares this information with the air sample found insidethe sensor. This information is relayed to the fuel injection control unit(computer) in order to calculate the optimal air/fuel ratio mix.HELLA LAMBDA SENSORSThe fuel injection control unit (computer) does not use the sensor signal when:The engine is cold, because during this period the mixture will be rich.In fast acceleration or in full load.During cut-off, as the mixture will be poor.FUNCTIONINGThe Lambda Sensor generates millivolts according to the quantity of oxygen in the exhaust gases.The “heart“ of the Lambda Sensor is the thimble shaped part made of a ceramic material called zirconium dioxide.This thimble shaped part is also covered on both sides with an extremely thin layer of microporous platinum. This part works as a galvanic cell (battery). When the zirconium dioxide is heated to above 300°C (572°F) it becomes an electrical conductor, allowing the oxygen ions to move from the internal platinum layer (in contact with the atmosphere) to the external platinum layer (in contact with the exhaust gases).The generation of a high millivoltage means that practically all oxygen that was injected in the combustion chamber has been consumed.On the other hand, the generation of a low millivoltage means that there is more oxygen in the combustion chamber than is needed for combustion, leading to a surplus of oxygen in the exhaust gases.The fuel injection control unit registers the generated millivoltage and adjusts the air/fuel mixture to be as close to the ideal ratio as possible.GASES CREATED DURING COMBUSTIONH2O = waterCO2 = carbon dioxideNOx = nitrogen oxideCH4 = methaneCO = carbon monoxideH2 = hydrogenHC = hydrocarbonsSOx = sulfur oxideN2 = nitrogenDear customer:This HELLA Lambda Sensor brochure, provides a technical specification overview for universal applications.Apart from technical specification we also include assembly and wiring reference in a simplified manner.The Lambda Sensor is one of the most important sensors in the engine management system. This sensor is critical and serves to control the air/fuel ratio, making it possible for vehicles to comply with the emissions standards set by law worldwide.We trust you will find this brochure informative and enhance your understanding of how HELLA Lambda Sensors function.Your HELLA AutomotiveSouth Africa TeamHELLA LAMBDA SENSORSMAIN COMPONENTSSWITCHINGThe transition of the Lambda Sensoroutput signal from a rich to lean mixtureis called switching.RICH MIXTUREWhen an engine runs on a RICH mixturevery little oxygen will be found in theexhaust gases. This is due to almostall the oxygen having been consumedin the combustion of the excess injectedfuel. The result will be a low quantity ofoxygen ions in the external electrodeleading to a higher voltage generation.LEAN MIXTUREOn the other hand, when the engine runson a LEAN mixture, more oxygen will befound in the exhaust gases. This is dueto the lack of fuel to burn all the injectedoxygen. This will lead to a higher numberof oxygen ions in the external electrode,resulting in the generation of a smallervoltage.3HousingStainless steelTop cover protectorOUTPUT SIGNALFrom 0 to 1.1 volts (0 to 1 100 millivolts).RICH MIXTURE λ < 1 More than 0.45 volts(450 mV) = Excess of fuel.LEAN MIXTURE λ > 1 Less than 0.45 volts(450 mV) = Excess of oxygen.There are a number of issues to consider when a troubleshooting problems, including, poor fuel quality, short circuit from signal to negative or ground, wire corrosion and/or solvents or detergents in the exhaust system. Futhermore:Check whether there is any damage to the main body, wiresor the plugDue to its proximity to the exhaust system, poor fitting maycause the plug or wire covers to melt, which results in the need to replace the sensorOther physical damage to the sensor body, water ingress orloosening of cable sealsThe sensor element can also be affected by chemicals whichshould not be present in the vehicles emissions In each case, the problem should be rectified and the sensor replaced.The following pictures show how chemicals, which should not be present in the fuel system, as well as engine damage, can detramentally affect the sensors.HELLALAMBDA SENSORSRich fuel mixtureSilicon poisoningLead poisoningCoolant / anti-freeze contamination High oil consumptionNOTE: Lambda Sensors cannot be cleaned / restored / repaired following contamination or damage.TROUBLESHOOTINGWHY HELLA LAMBDA SENSORS UNIVERSAL APPLICATIONSThe replacement of a used Lambda Sensor ensures the optimal air/fuel mix ratio during the combustion process. Therefore in most cases, significant lower fuel consumption is evident: Saving money and fuelInhibits environmental impactReduces wear and tare as well as repair expensesKey benefits of HELLA Lambda Sensors include:Only 6 different part numbers cover the majority of vehicles inthe car parcLower expenses on capital commitmentUniversal parts are generally less expensive than vehiclespecific parts (You get the same technology and quality under the HELLA banner.)COLOUR WIRE ASSEMBLY TABLE OEM | UNIVERSALNote: The heater is not polarity dependent.5MOST COMMON DEFECTSExaggerated fuel consumption Loss of powerFailure in the ignition system Damaged catalytic converter High level of hydrocarbonsFuel tank over-filled » damages the canister and causes rich mixtureCrack in the ceramic thimblecaused by accidental drop of the sensor Loss of signal can be caused by: Use of welding in the connectionof the Universal Lambda Sensor Terminal or connection plugproblemsREPLACEMENT AND INSTALLATIONRemove the old Lambda Sensor carefully / thread corrosion oroxidation can prove problematic. Use high temperature grease in the thread of the new Lambda Sensor, so it can easily be removed later.Avoid hitting or dropping the Lambda Sensor because the ceramic parts can be damaged.HELLA LAMBDA SENSORSHELLA LAMBDA SENSOR ASSEMBLY INSTRUCTIONSUNIVERSAL APPLICATIONSDisconnect the used sensor and remove it from the exhaust system.Cut the used sensor wires close to sensor’s body.This procedure should be repeated for all the wires of the sensor.Pass the plastic tube through the wire and make the connection to the new Sensor using the provided clip.For ease of reference please check the wire color assembly table on page 5.A er making the connection, slide the plastic tube over the clip and heat it carefullyusing a match or a lighter until it shrinks and completely covers the connection.OLD SENSORMatchEXCLUSIVE FEATURESNickel plated wires with teflon cover for high temperature resistanceFull coverage of direct-fit sensorsDouble layer ceramic protection to prevent contamination100% Function testedLaser welded housings to protect against water and contaminationCompact sensing element, resulting in faster heatingCoated threadsHELLA UNIVERSAL LAMBDA SENSOR RANGEGENERAL INFORMATIONThread HexInitial working temperatureMaximum working temperature TorqueInput Voltage of the heaterM18x1.522 mm300°C without internal heater 1 000°C40 - 60 Nm 12 to 14 voltsLS8884Short Code Short Code LS88897Extended wireREPLACEMENT AND INSTALLATIONRemove the old Lambda Sensor carefully / thread corrosionor oxidation can prove problematic. Use high temperature grease in the thread of the new Lambda Sensor, so it can easily be removed later.Avoid hitting or dropping the Lambda Sensor because the ceramic parts can be damaged.HELLA LAMBDA SENSORSHELLA PREMIUM LAMBDA SENSOR ASSEMBLY INSTRUCTIONS UNIVERSAL APPLICATIONSFull coverage of direct-fit sensorsDouble layer ceramic protection to prevent contaminationLaser welded housings to protect against water and contaminationCompact sensing element, resulting in Universal plugConnector fittedfor the universal plugTerminalRed guideCoated threads[1] Cut wires off close to body ofused sensor.[5] Insert wire into terminal(pass through the closing rubber).[2] Remove the end insulation of each wire.[6] Press crimp toll to lock wire in terminal.[3] Insert terminal into crimptool with open part in crimp tool cavity.[7] Insert each terminal/wire into universal plug connector.[4] Partially close crimp tool to hold terminal in place and insert closing rubber with smaller diameter.[8] Ensure good connection andwiring fitment in correct order. [9] Insert red guide into connector.[10] Clip the connector into the universal plug to complete process.EXCLUSIVE FEATURESClosing rubberHELLA UNIVERSAL PREMIUM LAMBDA SENSOR RANGEGENERAL INFORMATIONThread HexInitial working temperatureMaximum working temperature TorqueInput Voltage of the heaterM18x1.522 mm300°C without internal heater 1 000°C40 - 60 Nm 12 to 14 voltsShort Code LS80099Extended wireNotesHELLA LAMBDA SENSORSNotes11HELLA Automotive South Africa (Pty) Ltd. P O Box 6130Moselville, Uitenhage,SOUTH AFRICA6230Sales Telephone: +27 (0) 41 996 5700 Sales Telefax: +27 (0) 41 996 5720 http://www.hella.co.za© HELLA KGaA Hueck & Co., LippstadtPN: 6-002 07.2011Printed in South Africa。
42 Overview Guided Wave Radar 46VEGAFLEX series 8054VEGAPASS 81Area of applicationThe TDR sensors of the VEGAFLEX series are suitable for level measurement in liquids and bulk solids. In liquids, they can also detect the interface bet-ween two products. They measure liquids reliably, even under high pressure and extreme temperatures. They can be used in simple as well as in aggres-sive liquids and are suitable for applications with stringent hygiene require-ments. The sensors measure light as well as heavy bulk solids with absolute reliability, even in the presence of dust and noise, and without being affected by buildup or condensation.Measuring principleHigh-frequency radar pulses are coupled onto a cable (solids) or rod (liquids) and guided along the probe. The pulse is reflected by the product surface. The instrument calculates the level from the running time of the radar pulsesand the entered tank height.AdvantagesTDR sensors operate independently of noise, pressure or temperature fluctuations and are also completely unaffected by changes in density, foaming, steam or dust. Buildup on the probe or on the container wall does not affect the measurement either. This allows simple, straightforward system design and engineering. The menu-driven adjustment routines allow simple, time-saving and confident setup.123① Cable version for process temperature -20 … +200 °C ② Rod version ③ Coax versionrestrictions./configuratorInstrument documentation and drawings: /downloadsMounting accessories, welded sockets and housing overview: Chapter AccessoryDelivery time:VEGAFLEX 81TDR sensor for continuous level and interface measurement of liquids Application areaThe VEGAFLEX 81 level sensor measures maintenance-free all kind of liquids. Even in applications with vapour, buildup, foam generation and condensation, the sensor delivers precise and reliable measured values. The VEGAFLEX 81 is the economical solution for various level and interface measurements.Your benefit−The guided adjustment enables a simple, time-saving and reliable setup−Comprehensive diagnostic possibilities ensure a maintenance-free operation and hence a high plant availability−Shortenable probes offer a simple standardisation and highest flexibility in the planning Technical data Version:exchangeable cable (ø 2 mm, ø 4 mm)exchangeable rod (ø 8 mm, ø 12 mm)coax (ø 21.3, mm, ø 42 mm)Measuring range:cable probe up to 75 m rod probe up to 6 m coax probe up to 6 m Process fitting:thread from G¾, ¾ NPT flanges from DN 25, 1"Process temperature:-40 … +200 °C-60…+150°C for volatile substances, e.g. AmmoniaProcess pressure:-1 …+40 bar (-100 … +4000 kPa)Accuracy:±2 mmScopeA Europe ......................................................................................................................................................................................Length (from seal surface)Cable ø2 mm/316 (500-75000 mm) per 100 mmRod ø8 mm/316L (300-6000 mm) per 100 mmRod ø12 mm/316L (300-4000 mm) per 100 mmCoax ø21.3mm/316L (300-6000 mm) per 100 mmCoax Ø42.2mm/316L (300-6000 mm) per 100 mm12① Cable version ② Rod version ③ Flange versionrestrictions./configuratorInstrument documentation and drawings: /downloadsMounting accessories, welded sockets and housing overview: Chapter AccessoryDelivery time:VEGAFLEX 82TDR sensor for continuous level measurement of bulk solidsApplication areaThe VEGAFLEX 82 level sensor measures maintenance-free light and heavy-weight bulk solids. Even in applications with strong dust generation,condensation or buildup, the sensor delivers precise and reliable measured values. The VEGAFLEX 82is an economical and reliable solution for your application.Your benefit−The guided adjustment enables a simple, time-saving and reliable setup−Shortenable probes offer a simple standardisation and highest flexibility in the planning−Virtually all bulk solids can be measured with the automatic probe end tracking Technical data Version:exchangeable cable (ø 4 mm, ø 6 mm)exchangeable rod (ø 16 mm)Measuring range:cable probe up to 75 m rod probe up to 6 m Process fitting:thread from G¾, ¾NPT flanges from DN 25, 1"Process temperature:-40 … +200 °CProcess pressure:-1 … +40 bar (-100 … +4000 kPa)Accuracy:±2 mmScopeA Europe ...................................................................................................................................................................................Length (from seal surface)Cable ø4 mm/316 (500-75000 mm) per 100 mmCable ø6 mm/316 (500-75000 mm) per 100 mmRod ø16 mm/316L (300-6000 mm) per 100 mm123① Version / Material: Rod (ø 10 mm) / PFA② Version / Material: Cable (ø 4 mm) with gravity weight / PFA③ Version / Material: Exchangeable rod (ø 8 mm) / 1.4435 (Basle Standard 2)restrictions./configuratorInstrument documentation and drawings: /downloadsMounting accessories, welded sockets and housing overview: Chapter AccessoryDelivery time:VEGAFLEX 83TDR sensor for continuous level and interface measurement of liquids Application areaThe VEGAFLEX 83 level sensor measures maintenance-free agressive liquids or liquid media with highest hygienic requirements. Even in applications with vapour, buildup, foam generation and condensation, the sensor delivers precise andreliable measured values. The VEGAFLEX 83 is the economical and ideal solution for your application.Your benefit−The guided adjustment enables a simple, time-saving and reliable setup −The gap-free hygienic design ensures simple and reliable cleanability −The maintenance-free operation increases the plant efficiency Technical data Version:cable (ø 4 mm)rod (ø 8 mm, ø 10 mm)Measuring range:cable probe up to 32 m rod probe up to 4 m Process fitting:flanges from DN 25, 1"hygienic fittings Process temperature:-40 … +150 °CProcess pressure:-1 … +16 bar (-100 … +1600 kPa)Accuracy:±2 mmScopeA Europe ...................................................................................................................................................................................Length (from seal surface)Cable ø4 mm / PFA isolated (500-32000 mm) per 100 mmRod ø10 mm/PFA insulated (300-4000 mm) per 100 mmRod ø8 mm/1.4435 Ra < 0.76 µm (BN2) (300-4000 mm) per 100 mm132 ø 16 mm (0.63")(0.84")① Version: -20 … +250 °C; coax ② Version: -196 … +280 °C; rod ③ Version: -196 … +450 °C; cablerestrictions./configuratorInstrument documentation and drawings: /downloadsMounting accessories, welded sockets and housing overview: Chapter AccessoryDelivery time:VEGAFLEX 86TDR sensor for continuous level and interface measurement of liquids Application areaThe VEGAFLEX 86 level sensor measures maintenance-free all liquids under extreme pressure and temperature conditions. Even in applications with buildup, foam generation and condensation, the sensor delivers precise and reliable measured values. In saturated steam applications, a special reference probe ensures a density-independent measurement. The VEGAFLEX 86 offers an economical level and interface measurement for your application.Your benefit−The guided adjustment enables a simple, time-saving and reliable setup−Comprehensive diagnostic possibilities ensure a maintenance-free operation and hence a high plant availability−The maintenance-free operation increases the plant efficiency Technical data Version:exchangebale cable (ø2 mm, ø 4 mm)exchangeable rod (ø 16 mm, ø 8 mm)coax (ø 42 mm, ø 21.3 mm)Measuring range:cable probe up to 75 m rod probe up to 6 m coax probe up to 6 m Process fitting:thread from G¾, ¾ NPT flanges from DN 25, 1"Process temperature:-196 … +450 °CProcess pressure:-1 … +400 bar (-100 … +40000 kPa)Accuracy:±2 mmScopeA Europe ...................................................................................................................................................................................Length (from seal surface)Cable ø4 mm / 316 (500-60000 mm) per 100 mmRod ø8 mm/316L (300-6000 mm) per 100 mmRod ø16 mm/316L (300-4000 mm) per 100 mmCoax ø21.3mm/316L (300-6000 mm) per 100 mmCoax ø42.2mm/316L (300-6000 mm) per 100 mmVersion: side - side / two connections Additional instrument options and possible restrictions./configurator Instrument documentation and drawings: /downloadsMounting accessories, welded sockets and housing overview:Chapter AccessoryVEGAPASS 81Bypass for continuous level measurement of liquidsApplication areaThe combination of VEGAPASS 81 with VEGAFLEX enables a continuous level measurement outside the vessel. The bypass consists of a standpipe which is mounted as communicating vessel laterally to the vessel via two process fittings. This kind of mounting ensures that the level in the standpipe and the vessel are the same.Your benefit−Maintenance-free system without mechanically moving parts−Simple, robust and proven mechanical constructionTechnical dataVersion:according to ASME or PEDProcess temperature:-196 ... +450 °C; dependent on the installedsensorProcess pressure:0 ... 250 bar; dependent on the installedsensorProcess fitting vessel:flanges from DN 20, 1"Measuring range:up to 4 mClassificationD Pressure device directive 97/23/EC /PED 97/23/EC .............................................................................................................Center - Center (M)Ø60.3x2 mm /316L (300-4000 mm) per 100 mmØ60.3x2.77 mm (2"Schedule 10)/316L (300-4000 mm) per 100 mmØ88.9x2 mm / 316L (300-4000 mm) per 100 mmØ88.9x3.05 mm (3"Schedule 10)/316L (300-4000 mm) per 100 mmDistance vessel connections 90° displaced (L)Ø60.3x2 mm /316L (300-4000 mm) per 100 mmØ60.3x2.77 mm (2"Schedule 10)/316L (300-4000 mm) per 100 mmØ88.9x2 mm / 316L (300-4000 mm) per 100 mmØ88.9x3.05 mm (3"Schedule 10)/316L (300-4000 mm) per 100 mm。
美国MOTOROLA压力传感器美国MOTOROLA公司的MPX系列硅压力传感器,主要以气压测量为主,适合用于医疗器械,气体压力控制等领域,输出数字信号。
其测量方式可分为:表压(GP)、绝压(A、AP)、差压(D、DP)型。
在宽温度范围工作时需外加补偿网络和信号调整电路。
具体型号分类而定名称:MPX2010DP 名称:MPX5700DP MPX5700GP 名称:MPX2100AP名称:MPX5500DP 名称:MPX5100AP 名称:MPX5050DP名称:MPX5010DP 名称:MPX4115AP 名称:MPX2200A 名称:MPX2200AP 名称:MPXH6115A6U 名称:MPX4250DP名称:MPX4115A 名称:MPX2202DP 名称:MPX2102AP名称:MPX2053GP 名称:MPXY8300A6U 压力传感器 名称:触力型压力传感器 FSG15N1A 名称:硅压力传感器 MPXH6115A 名称:MPX5700DP 硅压力传感器 名称:MPX53GP 硅压力传感器 名称:压力传感器FPM07 名称:轮胎压力传感器TP015 名称:轮胎压力传感器NPP301名称:Freescale 压力传感器 MPX2010DP商斯达实业传感器与智能控制分公司专门从事各种进口传感器的营销工作,代理多家欧美知名公司的产品。
涉及压力、温度、湿度、电流、液位、磁阻、霍尔、流量、称重、光纤、倾角、扭矩、气体、光电、位移、触力、红外、速度、加速度等多种产品。
广泛应用于航空航天、医疗器械(如血压计)、工业控制、冶金化工、汽车制造、教育科研等领域。
商斯达实业代理的品牌产品主要有:压 力:Kulite、ACSI、Honeywell、Entran、Gems、Dwyer、SSI、Smi、Senstronics、Intersema、Motorola、 NAIS、E+H、Fujikura、Dytran、APM称重测力:Transcell、HBM、Interface、Thamesside、Philips、Entran 温 湿 度:Honeywell、Dwyer流 量:Gems、Dwyer、Honeywell、Folwline、WorldMagnetics 液 位:Honeywell、Siccom、Gems、Dwyer、Kulite、SSI 加 速 度:Entran、Silicondesigns、Dytran 压力开关:ACSI、Gems、Dwyer、台湾矽微航空器材:TexTech 隔音材料、Honeywell 薄膜加热片、DigirayX 射线探伤仪 仪 表:Honeywell、Transcell、东辉、上润、AD、东崎商斯达实业 除代理上述产品外,还有几条传感器生产线,一条压力传感器组装线,可为用户提供各种用途的、特殊要求的配套产品。
Page 1/3电流传感器 LT 208-S7原边和副边之间是绝缘的,用于测量直流、交流和脉冲电流。
电参数I PN原边额定有效值电流 200AI PM 原边电流, 测量范围 0 .. ± 300AR M 测量电阻R M min R M max with ± 12 V @ ± 200 A max 0 50 Ω@ ± 300 A max 0 26 Ω with ± 15 V @ ± 200 A max 0 73 Ω @ ± 300 A max0 40ΩI SN 副边额定有效值电流 100 mA K N 转换率1 : 2000V C 电源电压 (± 5 %) ± 12 .. 15 V I C电流消耗28 (@ ± 12V) + I S mA精度 - 动态参数X G总精度 @ I PN , T A = 25°C ± 0.5 %εL线性度 < 0.1 %Typ Max I O 零点失调电压 @ I P = 0, T A = 25°C± 0.20 mA I OM 磁性失调电流 1) @ I P = 0, 通过 3 x I PN 的过载 ± 0.20 mA I OT I O 的温漂 (- 10°C .. + 70°C) ± 0.20 ± 0.64 mA t ra 反应时间 to 10 % of I PN < 500 ns t r 响应时间 2) to 90 % of I PN < 1 µs di/dt di/dt 跟随精度 > 100 A/µs BW频带宽度 (- 3 dB)DC .. 100kHz一般参数T A环境操作温度 - 10 .. + 70 °C T S 环境贮存温度- 25 .. + 80 °C R S 副边线圈电阻 @ T A = 70°C 21 Ωm 质量 79g标准3)EN 50178注释1)磁场的强磁力的结果 2)100 A/µs 的 di/dt3)备有相应的检测清单I PN = 200 A 性能应用霍尔原理的闭环(补偿)电流 ●传感器符合 ●UL 94-V0 标准的绝缘外壳优势出色的精度 ●良好的线性度 ●低温漂 ●最佳的反应时间 ●宽频带 ●无插入损失 ●抗干扰能力强 ●电流过载能力●应用交流变频调速、伺服电机 ●直流电机牵引的静电转换 ●电池电源 ●不间断电源 ●(UPS)开关电源 ●(SMPS)电焊机电源 ●应用领域工业●用霍尔原理的闭环(补偿)电流传感器•符合 UL 94-V0标准的绝缘外壳优势•出色的精度•良好的线性度•低温漂•最佳的反应时间•宽频带•无插入损失•抗干扰能力强•电流过载能力应用•交流变频调速伺服电机•直流电机牵引的静电转换•电池电源•不间断电源 (UPS)•开关电源 (SMPS)•电焊机电源I PN =50 APage 2/3电流传感器 LT 208-S7电隔离性能V d 交流隔离耐压测试有效值 1) , 50 Hz, 1 分钟 3.52kV V w 瞬态耐压 1.2/50 µs 6.5 kVMin dCp 爬电距离 2)10 mm dCI 电气间隙距离 2) 6mmCTI比较路经指数 (group IIIa)275应用参考依据 EN 50178 及 IEC 61010-1 标准,应用条件示范如下:负载电压类别: ●OV 3污染等级: ●PD2非特殊应用领域●注释 1)原副边之间2)原边至外壳表面端子安全事项传感器必须按照使用说明要求安放在符合应用标准和安全要求的电子或电气设备中.注意,小心电击传感器工作时,某些部位可能会承受危险电压(如原边母排,电源)忽视这些将导致损坏和严重危险. 传感器是内置式设备,在安装完毕后其导电部分一定要保证不被外界触及. 可采用保护壳或附加屏蔽铠装. 主电源必须能被断开.EN 50178IEC 61010-1dCp, dCI,额定耐压值额定电压单绝缘600 V 600 V 加强型绝缘300 V300 VV wPage 3/3说明I ●S 在 I P 按箭头方向流动时, 是正向的.原边导体温度不超过 ●100°C.母排完全充满原边穿孔时动态表现 ● (di/dt 和响应时间)为最佳.此模块为标准传感器. 对于不同的应用 ● (电源电压、匝比, 单项测量...)请与我们联系.机械性能自然公差 ● ± 0.5 mm紧固点 ● 2 孔 ∅ 5.4 mm 原边穿孔 ● ∅ 20 mm副边连接 ● 插座 2541 WV-4P(上海嘉仁)LT 208-S7外形尺寸 (in mm)。
B I 10-M 30-Y 1X -H 1141 | 11/29/2022 05-46 | t e c h n i c a l c h a n g e s r e s e r v e dBI10-M30-Y1X-H1141Inductive SensorTechnical dataBI10-M30-Y1X-H114140202 Rated switching distance 10 mmFlushSecured operating distance ≤ (0.81 × Sn) mmSt37 = 1; Al = 0.3; stainless steel = 0.7; Ms = 0.4≤ 2 % of full scale ≤ ±10 %1…10 %2-wire, NAMUR 0.5 kHz Nom. 8.2 VDC Non-actuated current consumption ≥ 2.1 mA Actuated current consumption ≤ 1.2 mAKEMA 02 ATEX 1090X )/inductance (L i )150 nF/150 µHÉ II 1 G Ex ia IIC T6 Ga/II 1 D Ex ia IIIC T135 °C Da(max. U i = 20 V, I i = 20 mA, PThreaded barrel, M30 × 1.562 mmFeatures■M30 × 1.5 threaded tube ■Chrome-plated brass ■DC 2-wire, nom. 8.2 VDC■Output acc. to DIN EN 60947-5-6 (NAMUR)■M12 x 1 male connector■ATEX category II 1 G, Ex zone 0■ATEX category II 1 D, Ex zone 20■SIL2 (Low Demand Mode) acc. to IEC 61508,PL c acc. to ISO 13849-1 at HFT0■SIL3 (All Demand Mode) acc. to IEC 61508,PL e acc. to ISO 13849-1 with redundant configuration HFT1Wiring diagramFunctional principleInductive sensors detect metal objectscontactless and wear-free. For this, they use a high-frequency electromagnetic AC field that interacts with the target. Inductive sensors generate this field via an RLC circuit with a ferrite coil.Technical dataMounting instructions11H-X1Y-3M-1IBB I 10-M 30-Y 1X -H 1141 | 11/29/2022 05-46 | t e c h n i c a l c h a n g e s r e s e r v e d AccessoriesBST-30B6947216Mounting clamp for threaded barrel sensors, with dead-stop; material:PA6QM-306945103Quick-mount bracket with dead-stop;material: Chrome-plated brass. Male thread M36 × 1.5. Note: The switching distance of the proximity switches may change when using quick-mount brackets.MW-306945005Mounting bracket for threaded barrel sensors; material: Stainless steel A21.4301 (AISI 304)BSS-306901319Mounting clamp for smooth andthreaded barrel sensors; material:PolypropyleneWiring accessoriesDimension drawingTypeID RKC4.221T-2/TEB6628420Connection cable, female M12, straight,2-pin, cable length: 2 m, sheathmaterial: PVC, black; cULus approval;other cable lengths and qualities available, see WKC4.221T-2/TEB 6628427Connection cable, M12 femaleconnector, angled, 2-pin, cable length:2 m, jacket material: PVC, black; cULus approval; other cable lengths andqualities available, see B I 10-M 30-Y 1X -H 1141 | 11/29/2022 05-46 | t e c h n i c a l c h a n g e s r e s e r v e dInstructions for useIntended useThis device fulfills Directive 2014/34/EC and is suited for use in areas exposed to explosion hazards according to EN 60079-0:2018 and EN 60079-11:2012.Further it is suited for use in safety-related systems, including SIL2 as per IEC61508.In order to ensure correct operation to the intended purpose it is required to observe the national regulations and directives.For use in explosion hazardous areas conform to classificationII 1 G and II 1 D (Group II, Category 1 G, electrical equipment for gaseous atmospheres and category 1 D, electrical equipment for dust atmospheres).Marking (see device or technical data sheet)É II 1 G and Ex ia IIC T6 Ga and É II 1 D Ex ia IIIC T135 °C Da acc. to EN 60079-0, -11Local admissible ambient temperature -25…+70 °CInstallation/CommissioningThese devices may only be installed, connected and operated by trained and qualified staff. Qualified staff must have knowledge of protection classes, directives and regulations concerning electrical equipment designed for use in explosion hazardous areas.Please verify that the classification and the marking on the device comply with the actual application conditions.This device is only suited for connection to approved Exi circuits according to EN 60079-0 and EN 60079-11. Please observe the maximum admissible electrical values.After connection to other circuits the sensor may no longer beused in Exi installations. When interconnected to (associated) electrical equipment, it is required to perform the "Proof of intrinsic safety" (EN60079-14).Attention! When used in safety systems, all content of the security manual must be observed.Installation and mounting instructionsAvoid static charging of cables and plastic devices. Please only clean the device with a damp cloth. Do not install the device in a dust flow and avoid build-up of dust deposits on the device.If the devices and the cable could be subject to mechanical damage, they must be protected accordingly. They must also be shielded against strong electro-magnetic fields.The pin configuration and the electrical specifications can be taken from the device marking or the technical data sheet.Service/MaintenanceRepairs are not possible. The approval expires if the device is repaired or modified by a person other than the manufacturer. The most important data from the approval are listed.。
新产品技术参数说明V2021.11.24杭州安布雷拉自动化科技有限公司曾工186****3652目录超声波接近开关(DA-AAF-35RJG) (1)超声波接近开关(DA-AAM38-35R0N) (2)M33水下测距传感器(DE-WLM33-35R0N) (3)HART二线超声波物位计(DYYL-WW-HART) (4)M60水下六路避障传感器(DF-WAM60-20R0N) (5)M100水下六路避障传感器(DG-WAM100-300R0N) (6)水下噪声检测传感器(DI-WA43-BON) (7)TI小型测距传感器(DA-AAGH-40RMG) (8)手持式超声波测深仪(DD-WAP-70MLG) (9)超声波水下通讯传感器(DJ-WAM33-300MRON) (10)六波束超声波传感器(DK-AAM38-50R0N) (11)M30超声波测距传感器(DC-AS30-40RMG) (12)外贴式超声波液位开关(DL-WA-50JOG) (13)超声波五路水下避障传感器(DK-WNB-50R0G) (13)双路超声波传感器(DO-ALN1-15RNG) (15)小型超声波多普勒流速仪(DP-WPB-FR0G) (16)低功耗窨井液位计(DQ-WAB-10NB) (17)六波束超声传感器(DK-WNM70-50R0N) (18)M36水下测距传感器(DE-WNQ-M36-00-RON) (19)科鼎物位计(DC-ALM30M2500MM-RON) (20)M50水下测距传感器(DM-WAM50-R0N) (21)M80水下测距传感器(DM-WAM80-R0N) (22)M33贴片水下测距传感器(DE-WLM33-35R0N) (23)M36水下测距传感器航插款(DE-WNQ-M36-00-RON) (24)十波束超声波测距避障传感器 (25)超声波五路水下避障传感器(DK-WNB-50R0G) (26)超声波接近开关(DA-AAF-35RJG)连接器出线方式。
你的手机到底有多少传感器13种传感器的介绍和工作原理概述摇动手机就可以控制赛车方向;拿着手机在操场散步,就能记录你走了几公里?这些你越来越熟悉的场景,都少不了天天伴你身旁的智能手机。
而手机能完成以上任务,主要都是靠内部安装的传感器。
你知道手机中的传感器有多少种?又是倚靠那些原理来运作?1、光线传感器(Ambient Light Sensor)光线传感器类似于手机的眼睛。
人类的眼睛能在不同光线的环境下,调整进入眼睛的光线,例如进入电影院,瞳孔会放大来让更多光线进入眼睛。
而光线传感器则可以让手机感测环境光线的强度,用来调节手机屏幕的亮度。
而因为屏幕通常是手机最耗电的部分,因此运用光线传感器来协助调整屏幕亮度,能进一步达到延长电池寿命的作用。
光线传感器也可搭配其他传感器一同来侦测手机是否被放置在口袋中,以防止误触。
2、距离传感器(proximity sensor)透过红外线LED灯发射红外线,被物体反射后由红外线探测器接受,藉此判断接收到红外线的强度来判断距离,有效距离大约在10米左右。
它可感知手机是否被贴在耳朵上讲电话,若是则会关闭屏幕来省电;距离传感器也可以运用在部分手机支持的手套模式中,用来解锁或锁定手机。
iPhone 4/4s与iPhone 5/5s的距离传感器与光传感器位置。
3、重力传感器(G-Sensor)透过压电效应来实现。
重力传感器内部有一块重物与压电片整合在一起,透过正交两个方向产生的电压大小,来计算出水平的方向。
运用在手机中时,可用来切换横屏与直屏方向,运用在赛车游戏中时,则可透过水平方向的感应,将数据运用在游戏里,来转动行车方向。
4、加速度传感器(Accelerometer Sensor)作用原理与重力传感器相同,但透过三个维度来确定加速度方向,功耗小但精度低。
运用在手机中可用来计步、判断手机朝向的方向。
Mobile传感器
2014-07-18
如今的智能手机已经逐渐演变成为不可思议的小机器,它所能够完成的功能在几十年前无疑会被视为“巫术”。
不过,我们已经习惯我们的iPhone和Android为我们带来很多炫酷的技术。
今天,我们就以传感器为例,来见证一下当前智能手机的奇妙之处。
1.加速度计
下面,就让我们自一种最为常用的传感器说起,它就是加速度计。
顾名思义,加速度计用于测量手机处于相对自由落体时的“加速度”。
当用户以任何方向移动智能手机的时候,加速度计中的传感器数据将会上涨。
而当智能手机处于平稳状态时,这个传感器中的数据将会走平。
加速度计还可以用来确定设备沿三个轴的方向,使用加速度计数据的应用程序可以来判断手机是处于纵向还是横向的状态,屏幕是处于朝上还是朝下的状态。
2.陀螺仪
陀螺仪也是一种能够提供定位信息的传感器,但是它所提供的信息精度更高。
得益于这种特殊的传感器,Android手机的“照片球”相机功能能够指出手机旋转的“度数”以及“方向”。
与此同时,谷歌旗下的星云图(Sky Map)还可以利用陀螺仪的定位功能让
你了解自己头上的星系。
Galaxy S5中的加速度计/陀螺仪传感器(蓝色标记)
3.磁强计
当前,大多数智能手机还配有的一种传感器就是“磁强计”,它能够检测磁域。
磁强计是一种能够被指南针应用程序用来指出星系北极的传感器。
另外,这种传感器也可以被检测金属的应用程序利用。
4.近物体传感器
接下来我们要说到的是“近物体传感器”(proximity sensor),它是由一个红外LED和红外光探测器组成的,它一般被放置于手机的听筒附近。
这样一来,当您将手机放在耳边的时候,传感器就会让系统知道你正在进行通话,并且自动将屏幕关闭以节约电源。
5.光传感器
手机的光传感器一般被用来检测环境光的强度,手机软件会利用光传感器的数据来自动调整显示屏的亮度。
当环境光线充足的时候,手机显示屏的亮度就会加强,当环境光线暗淡的时候,手机显示屏的亮度也会暗下来。
有趣的是,高端三星Galaxy智能手机使用的是一种非常先进的光传感器,它能够分别检测到白色、红色、绿色和蓝色的光线,并且能够使用这一数据来调整图像的显示效果。
手机的光和近物体传感器通常被放置在靠近听筒的地方
6.晴雨表传感器
如今,高端智能手机中还拥有一个内置的晴雨表传感器,它能够测量大气压力(Barometer)。
晴雨表传感器所测得的数据将能够被用来确定设备的海拔高度,从而提升GPS的精确度。
就相关的说明得知,摩托罗拉XOOM和三星Galaxy Nexus、Galaxy S4是首批使用晴雨表传感器的Android设备。
三星Galaxy S4内置气压计,用三星app商店里的S Baro软件可以显示气压并换算出海平面高度。
(可以联网读取当地当前海平面气压,并校准气压高度表)
Galaxy S4内置气压计1——10楼
7.温度计
之前,三星曾吹嘘Galaxy S4内置一个能够测量环境温度的温度计。
不过,实际上,几乎所有的智能手机中都配有一个温度计,有些手机中甚至还不止配有一个温度计。
不同的是,这个温度计是用来监测设备和其电池的温度。
当手机中有组件被检测到过热的时候,系统就会自动关闭以防止造成损坏。
Ambient Temperature & Humidity
8.空气湿度传感器
说到Galaxy S4,它开创了在智能手机中使用空气湿度传感器的“先河”,它所检测到的数据可以被“S Health”健康应用程序利用,用以确认用户对周围的环境(空气的温度和湿度)是否感到舒适。
S Health
9.计步器
提起健康和健身,“计步器”就是一个不得不说的传感器,它可以被用来计算用户的行走步数。
当前,内置“计步器”的手机并不多见,谷歌Nexus 5就是一个内置真正计步器的智能手机。
Android 4.4系统平台同样也原生支持计步器功能,但需要专属的传感器设备,目前只支持谷歌Nexus 5设备。
Android4.4原生计步app
10.心率传感器
三星在Galaxy S5中内置了心率传感器功能,它位于背部相机的下面,用户将手指放置在上面5到10秒就可以监测到自己的脉搏。
当用户锻炼的时候,还可以将心率传感器与内置的S Health应用配合使用,监测自己的心率以及卡路里消耗情况。
Galaxy S5中的心率传感器
11.指纹传感器
在这里,我们还不得不提的就是指纹传感器。
如今,有多个智能手机都集成了指纹传感器功能,例如iPhone 5S、Galaxy S5和HTC One Max等。
其中,iPhone 5S中的指纹传感器使用起来最为方便,用户只需将手指放置到Home键上即可解锁手机。
当前,指纹扫描已经被视为最为常用的安全功能,它足以替代锁屏密码。
iPhone 5S指纹传感器
iPhone 5S指纹传应用
12.M7运动感应协处理器
iPhone 5s中的M7协处理器是iPhone产品线中首次加入的一种芯片,能处理来自指南针、加速计、陀螺仪和数字罗盘的的数据。
通过将这些数据处理工作转移至专用处理器,分担CPU工作量,就算CPU处于休眠状态也能够继续运作,提升iPhone的效率。
iPhone将可以取代类似Fitbit的计步器,而用户一天中的大部分时间都会在口袋中携带这一手机。
苹果公司的官方说明显示:“M7芯片能知道用户步行、跑步,甚至开车的状态。
例如,当用户停车并转而步行时,地图将从驾车导航自动转为步行导航。
由于M7能知道用户是否正在汽车中,因此iPhone 5s不会提醒在车中的用户登录附近的WiFi网络。
而如果手机在一段时间内没有移动,例如当用户睡觉时,那么M7就会减少联网频率,从而降低耗电量。
”
苹果公司还发布了一款新应用“Nike+ Move”。
该应用将使用来自M7协处理器的数据实现类似计步器的追踪功能。
苹果公司还在iOS中提供了新的API(应用程序接口),将这些数据开放给第三方健身和运动追踪应用使用。
Nike+ Move
虽然目前来看一些健康监测的软件,如耐克的FuelBand、心率监测软件Withings Pulse会充分利用M7的功能,但未来,这一应用的前景将十分广阔,比如扩展到第三方配件市场当中。
13.辐射传感器
值得一提的是,有的智能手机中还集成了能够检测有害辐射的传感器,例如来自夏普的Pantone 5。
目前,夏普Pantone 5仅限在日本地区发售,它具备一个专门的应用程序启动按钮,用以检测用户当前所处地区的辐射水平。
14.三星暗示虹膜扫描技术将用于未来智能手机
北京时间7月15日消息,三星可能准备发布一款具备虹膜扫描功能的智能手机。
该公司Exynos官方Twitter账号上周发布推文称“安全性将通过独一无二的功能提升,这是我们的愿景”。
推文配图中的智能手机拥有极窄的边框,手机屏幕中心聚焦一只眼睛,这暗示着识别正在进行。
手机旁边还展示了几种常见的账单,这暗示着眼睛识别技术可能会被用于支付领域。
图片上方的标题是“Unlock the Future(解锁未来)”,暗示着眼睛扫描仪将代替PIN码保护手机安全。
早在三星Galaxy S5发布之前,就有消息称三星将在手机中添加眼睛识别功能。
最近,有其他报道称Galaxy Note 4将配备这项新功能,该款旗舰级预计将于今年底发布。
至于最终虹膜扫描技术能否出现在Note 4上,或许只能在其发布时才能揭晓。
15.紫外线传感器
今天,SamMobile又得到曝料称,该传感器能以500毫秒的间隔精度跟踪紫外线、紫外辐射。
三星给手机装个紫外传感器要干啥?更好地自动调节亮度(尤其是室外AMOLED屏幕确实存在亮度不足)?还是警告用户太阳太毒辣了快回屋里去?
16.NFC(近距离无线通讯技术)
NFC技术的应用可分为五类:
(1)接触通过(TouchandGo),如门禁管理、车票和门票等,用户将储存着票证或门控密码的设备靠近读卡器即可,也可用于物流管理。
(2)接触支付(TouchandPay),如非接触式移动支付,用户将设备靠近嵌有NFC模块的POS机可进行支付,并确认交易。
(3)接触连接(TouchandConnect),如把两个NFC设备相连接(如图1中手机和笔记本电脑),进行点对点(Peer-to-Peer)数据传输,例如下载音乐、图片互传和交换通讯录等。
图1手机和笔记本电脑的NFC点对点通信
图2三星NFC影响
(4)接触浏览(TouchandExplore),用户可将NFC手机接靠近街头有NFC 功能的智能公用电话或海报,来浏览交通信息等。
(5)下载接触(LoadandTouch),用户可通过GPRS网络接收或下载信息,用于支付或门禁等功能,如前述,用户可发送特定格式的短信至家政服务员的手机来控制家政服务员进出住宅的权限。
M7运动感应
17.其他
Android 4.4 (KitKat) 将新增对地磁场旋转航向传感器、步进探测器及步进计数器这3种传感器的支持。
手机的摄像头、麦克风、蓝牙、WIFI是应用最为广泛的传感器。
