雷度米特AQT技术参数

C o u r t e s y o f t h e L a C r o s s e (W is c on s in )P u b li c L ibr a r y A r c h ive s It started over a hundred years ago ,when Reuben and James Trane made the decision to stand out from the crowd. To build a comfort system like no other, using uncompromising quality, innovation and reliability. Today, their legacy is found in everything Trane makes, from our premium materials to our industry-leading technology to our extensive product testing under the harshest conditions. When you buy a Trane, you’re buying a commitment from us, to you. A commitment to your total comfort, and your total peace of mind. Because that’s what Reuben and James would have done.Trane Storefront La Crosse, Wisconsin1891* Independent 2012 HVAC Claim Study, Funded by Ingersoll Rand** Trane received the highest numerical score in the United States in the proprietary Lifestory Research 2016 America’s Most Trusted™ Heating, Ventilation, & Air Conditioning (HVAC) System study. Study based on 17,878 surveys among residential consumers. Proprietary study results are based on experiences and perceptions of consumers surveyed between January and December 2015. For details see .”The most reliable and longest lasting in the industry.*Extreme is not even close to our approach to product testing. Cruel and unusual may be a better way to describe what a Trane endures to wear the badge. We push our systems and components to the limit and beyond, so you can rest easy knowing there’s a Trane working hard day in day out to make your family comfortable — for a long, long time.Our Indoor Air Quality products must pass rigorous safety and reliability testing standards to wear the Trane badge. This testing chamber measures the effectiveness of our products to counteract typical indoor contaminants.FRESHER,CLEANERResearch indicates that people spend approximately 90% of their time indoors. Today’s homes are better insulated, tightly sealed and use less energy, however this can trap indoor pollutants, making the indoor air up to five times less healthy than the outdoor air. Trane air quality products are designed to help make your home and the air your family breathes the best possible.™Ideal for homes with childrenOutdoor AirStale Indoor AirFresh Air Sent IndoorsStale AirSent OutdoorsHeat and Moisture Transfer™Filters 100% of the air passing through itApproximate particle size (microns)10050251010.50.40.30.10.01Effective Operating Range By Particle Size5" Media Filter Standard 1"Throwaway FilterVisible to Naked EyeVisible ThroughLight MicroscopeVisible Through Electron Microscope Effective Operating RangeApproximate particle size (microns)10050251010.50.40.30.10.01Visible toNaked EyeVisible Through Light MicroscopeVisible Through Electron MicroscopeCommon Air ContaminantsMistA T M O S P H E R I C P A R T I C L E SSmog Cooking Smoke S M O K E Tobacco Smoke Pet DanderD U S T S Household DustPollen HairSkin Flakes Mold Spores BacteriaP A R T I C U L A T E SCommon Household Air ContaminantsTrane Perfect Fit Air Filters are economical and effectiveSTEAM HUMIDIFIERSSix Different CapacitiesIn One Unit to satisfy any application from 11.5 gallons per day to 34.6gallons per day.Choose Precise Relative Humidity % Settings based on your needs and outdoor conditions. Works with Trane Nexia ™-enabled controls without the need for additional controls.Automatic Shut Down after 72 hours of inactivity; unit will drain to eliminateElectrode Type Steam Canister means fast, easy, low cost maintenance.* Percent Relative Humidity102030405060708090Viruses Bacteria MitesFungi Allergic Rhinitis & AsthmaRespiratory Infections Ozone ProductionChemical Interactions100OPTIMUM ZONEASHRAE Comfort WindowSource: “Criteria for Human Exposure to Humidity in Occupied Buildings”-Sterling,et al and other ASHRAE Studies.Optimum relative humidity range for human comfort and health (A decrease in bar height indicates a decrease in effect for each of the items).EVAPORATIVE HUMIDIFIERS+40°45%+30°40%+20°35%+10°30%0°25%-10°20%-20°15%greater comfort and welcome relief from dryness.Relative humidity settings are based on double-pane windows or single-pane windows with storm windows. These settings reduce the likelihood of condensation forming on the windows inside a home.Humidifier Sizing Chart (8’ Ceilings)1000 ft 2 4.38.612.71500 ft 2 6.412.819.12000 ft 28.517.025.52500 ft 210.621.331.83000 ft 212.725.438.14000 ft 217.034.051.05000 ft 221.242.663.6Structure TightnessTightAverageLooseSource: A HRI Air Conditioning, Heating, and RefrigerationInstitute GPD = Gallons Per Day Guideline F 2008A family of four will add two gallons ofhumidity per day through everyday activities like cooking, bathing and washing.Recommended Gallons of Humidity Per DayOutdoor Temperature (°F)Indoor Relative HumidityPowerLarge Bypass Small Bypass Flow-Through Design ••••Durable, Rust-Resistant Housing •••••Controlled Moisture Distribution ••Automatic Control ••Ingersoll Rand (NYSE:IR) advances the quality of life by creating comfortable, sustainable and efficient environments. Our people and our family of brands—including Club Car®, Ingersoll Rand®, Thermo King® and Trane®—work together to enhance the quality and comfort of air in homes and buildings; transport and protect food and perishables; and increase industrial productivity and efficiency. We are a $13 billion global business committed to a world of sustainable progress and enduring results.We are committed to using environmentally conscious print 。

Series TMV THERMOSTATIC EXPANSION VALVES INTERCHANGEABLE ORIFICE CARTRIDGEPRODUCT DATAApplicationThermostatic expansion valves series TMV are used in general refrigeration and for original equipment.Plants with one or more circuits such as refrigerated cabinets even with cramped mounting conditions, ice and cream machines, milk cooling units, water chillers, vehicle air conditioning systems, cold stores, and air conditioning systems.MaterialsBody brassThermal head stainless steelConnection solder: copperflare: brass Features•TMV / TMVBL: with internal pressure equalisation; for single injection in installations with one or morecooling circuits•TMVX / TMVXBL: with external pressure equalisation;for optimal evaporation effectiveness in allapplications. Obligatory for multiple injection by liquid distributors•Combi adsorber chargeThe same valve can be used for differentrefrigerants (see table on page 2)Controller charge is high sensitive and responsivethus lowest possible level of superheat can beachievedCharge is not sensitive to effects of temperature onthe capillary tube and valve headDamping characteristic results in stable controlbehaviour•Suitable for systems with hot gas defrosting •Adjustable superheat setting•Flare connections: TMV, TMVX•Flare / solder connections: TMVBL, TMVXBL •Extreme durable due to stainless steel head and stainless steel diaphragm welded using protective gas •Interchangeable orifice cartridges•Refrigerants: R134a, R401A, R12R22, R407C, R407A, R422DR404A, R507A, R402A, R407B, R502R410ASpecificationNominal capacity range 0.52 to 22.4 kW R22(small orifice graduation foroptimal control behaviour,interchangeable orificecartridges)Evaporating temperature range see table on page 2 Maximum pressure PS see table on page 2 Maximum test pressure PF see table on page 2Max. ambient temperature 100 °CMax. bulb temperature 140 °CStatic superheat approx. 3 KLength of capillary tube 1.5 mBulb diameter 12 mmTMVXBL TMVXSERIES TMVCapacitiesNominal capacity (kW)*TypeOrifice sizeR134aR22R407CR422DR404AR507AR410A0.3 0.36 0.52 0.50 0.36 0.36 0.36 0.62 0.5 0.69 0.99 0.95 0.67 0.68 0.69 1.2 0.7 1.0 1.4 1.3 0.92 0.97 0.98 1.61.0 1.42.0 1.9 1.3 1.4 1.4 2.4 1.5 2.23.2 3.1 2.2 2.2 2.3 3.8 2.0 2.94.0 3.9 2.7 2.8 2.9 4.8 2.5 4.05.8 5.6 3.9 4.1 4.16.9 3.0 6.6 9.3 8.9 6.3 6.5 6.6 11.1 3.5 8.7 12.2 11.7 8.3 8.6 8.7 14.6 4.5 11.8 17.0 16.4 11.3 12.0 12.1 20.3 TMV TMVX TMVBL TMVXBL4.75 15.9 22.4 21.6 15.3 15.8 15.9 26.8* Capacities are based on t 0 = +4 °C, t c = +38 °C and 1 K subcooled liquid refrigerant entering the valve.For other operating conditions see capacity charts in Honeywell catalogue or consult the Honeywell software.Dimensions and WeightsConnectionsTypeInlet (B)Outlet (A) Pressure equaliser (C)Weight (kg) TMV 5/8" UNF 3/4" UNF - approx. 0.35 TMVX 5/8" UNF 3/4" UNF 7/16" UNFapprox. 0.36 5/8" UNF 12 mm ODF - TMVBL 5/8" UNF 1/2" ODF - approx. 0.33 5/8" UNF 12 mm ODF 6 mm ODF TMVXBL 5/8" UNF1/2" ODF1/4" ODFapprox. 0.342. Adsorber charge with pressure limiting performance MOP Refri-gerant EvaporationtemperaturerangeMOPPS(bar(a))PF(bar(a))+5 °C to -30 °C MOP A +15 °C 3437.4 R134a, R401A, R12-10 °C to -30 °C MOP A ±0 °C 29 31.9 +5 °C to –45 °C MOP A +15 °C 36 39.6 -10 °C to -45 °C MOP A ±0 °C 2931.9 R22, R407C,R407A,R422D -27 °C to -45 °C MOP A -18 °C 29 31.9 -10 °C to -50 °C MOP A ±0 °C 36 39.6 -20 °C to -50 °C MOP A -10 °C 3437.4 R404A, R507A,R402A,R407B, R502-27 °C to -50 °C MOP A -18 °C 34 37.4Further refrigerants and MOP on requestThermal Charges and Temperature Ranges1. Adsorber charge RefrigerantEvaporationtemperature rangePS(bar(a))PF(bar(a))R134a, R401A, R12+15 °C to -30 °C 34 37.4 R22, R407C, R407A, R422D+15 °C to -45 °C 36 39.6 ±0 °C to -50 °C 36 39.6 R404A, R507A, R402A, R407B,R502 +15 °C to -30 °C 36 39.6 R407C +15 °C to -30 °C 36 39.6 R410A+15 °C to -20 °C4044Further refrigerants on request.Thermal systems with adsorber charge are completelyinsensitive to effects of temperature on the capillary tube and valve head. It reacts only according to the temperature of the bulb.Thus, Honeywell TMV valves with combi adsorber charge work absolutely reliable, even in icy condition or while defrosting using hot gas.SERIES TMVType Code / Order Information (Part Programme)1. Valve body2. Orifice cartridgeSERIES TMVInstallation• The valves may be installed in any position.• The external pressure equaliser line should be 6 mm or 1/4” in diameter and is to be connected downstream of the remote bulb. An overbow is recommended in order to prevent the ingress of oil into the equaliser line. • The bulb should preferably be positioned on the upper half of a horizontal suction line but never after a liquid trap. As a general rule, bulbs of expansion valves should be insulated to prevent them being affected by the ambient temperature. • Do not bend or squeeze the bulb when tightening the bulb clamp! • When soldering the valve, the valve body must not get warmer than 100 °C. • When tightening flare nuts of the flare connections grip at wrench flats on the valve body. • Constructive modifications at the valve are not allowed.Superheat AdjustmentIn general the Honeywell valves should be installed with the factory setting for the used refrigerant unaltered.At combi adsorber valves the label on the capillary tube indicates how to adjust the adjusting spindle (with arrow for direction), depending on the refrigerant used. This correction of the adjustment is essential to ensure that the controlperformance of the valve is correct. The refrigerant used must be marked on the label.This superheat adjustment is calibrated for lowestsuperheating and optimum evaporator utilisation. However, should it be necessary to adjust the superheat, turn the adjusting spindle as follows:Turning clockwise = reduced refrigerant mass flow, increase of superheat Turningcounterclockwise=increased refrigerant mass flow, decrease of superheatOne turn of adjusting spindle alters superheat setting by approx. 0.55 bar. Increase of superheat setting results in a lower MOP-value and vice versa.Special Accessory:Adapter series LA for solder connection at the inlet for 6 mm, 10 mm, 1/4”, 3/8”.K A T -T M V -002Automation and Control Solutions Honeywell GmbH Hardhofweg74821 Mosbach/Germany Phone: +49 (0) 62 61 / 81-475 Fax: +49 (0) 62 61 / 81-461E-Mail:*****************************Manufactured for and on behalf of the Environment and Combustion Controls Division of Honeywell Technologies Sàrl, 1180 Rolle, Z. A. La Pièce 16, Switzerlandby its authorized representative Honeywell GmbH。

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M-511⁄8 DIN Digital Panel RTD MetersThe DP63000-RTD meter accepts standard RTD inputs and precisely linearizes them into temperature readings. A full 4-digit display accommodates a wide range of temperature inputs. State-of-the-art digital circuitry virtually eliminates errors due to drift. The meter features a readout choice of either Fahrenheit or Celsius with 0.1 or 1° resolution. Display prompts and front panel buttons aid the operator through set-up and operation. Programmable digital filtering enhances the stability of the reading. All set-up data is stored in EEPROM, which will hold data for a minimum of 10 years without power. The meter provides a peak “HI” and valley “LO” reading memory with selectable capture delay time. The capture delay is used to prevent detection of false peak or valley readings that may occur during start-up or unusual process events. The peak and valley readings areDP63200-RTDU RTD Meter U 4-Digit, 14.2 mm (0.56") LEDU Accepts Standard 3-Wire 100 Ω RTD Sensors (ALPHA = 0.00385 or ALPHA =0.00392) U Conforms to ITS-90 StandardsU Selectable °F or °C with 0.1 or 1 Degree Display Resolution U P rogrammableTemperature Offset U Programmable Digital FilteringU Peak/Valley (High/Low Reading) Memory U NEMA 4X (IP65) Sealed Front BezelU Custom Units Overlay with BacklightOrdering Example: DP63200-RTD, RTD input, 85 to 250 Vac, 50/60 Hz.stored at power-down, allowing process limits to be monitored over any length of time. The meter has several built-in diagnostic functions to alert operators of any malfunction. Extensive testing of noise interference mechanisms and full burn-in makes the meter extremely reliable in industrial environments. The front bezel meets NEMA 4X (IP65) requirements for wash-down applications.Specifications Display: 4-digit, 14.2 mm H (0.56") LED, minus sign displayed for negative temperatures Power: 85 to 250 Vac, 50/60 Hz, 6 VA Isolation: 2300 Vrms for 1 minute between input and supply (300V working voltage)Resolution: 0.1 or 1°Range (Decimal Point Dependent): 0.1° Res: -199.9 to 850.0°C (-199.9 to 999.9°F) 1° Res: -200 to 850°C (-328 to 1562 °F)Lead Resistance Effect: 20 Ω max, 2.5 °C/Ω error for V exc and common lead unbalance Accuracy: 0.3°C, @ 23°C and 30 minute warm-up Reading Rate: 2.5 readings/s Response Time: 2 s to settle for step input (increases with programmable digital filtering)Low-Frequencey Noise Rejection: Normal Mode Rejection: 40 dB @ 50/60 Hz (may be improved by programmable digital filtering) Common Mode Rejection: 120 dB, DC to 50/60 Hz Environmental Conditions: Operating Temperature Range: 0 to 50°C (32 to 122°F) Storage Temperature Range: -40 to 80°C (-40 to 176°F) Operating and Storage Humidity: 85% max RH non-condensing from 0 to 50°C (32 to 122°F)Span Drift: 50 ppm/°C Zero Drift: 0.001°C/°C Altitude: Up to 2000 m (6562')Construction: This unit is rated for NEMA 4X (IP65) indoor use, 1 piece bezel/case, flame-resistant—panelgasket and mounting clip included Connections: High-compression, cage-clamp terminal block Dimensions: 104.1 D x 91.4 W x 44.5 mm H (4.10 x 3.50 x 1.75)Weight: 0.24 kg (0.65 lb)DP63200-RTD shown actual size.。

生物素链霉亲和素联合免疫层析用于快速检测NT-proBNP 孙宏浩;梁玉芬;赵晓双;黄玲;廖天作【摘要】为提高常规免疫层析技术的检测灵敏度,引入生物素-链霉亲和素系统,以荧光微球作为标记物,建立了一种新型快速定量检测NT-proBNP的方法.试验结果表明:新型试剂盒在0.02～30 μg·L－1范围能对NT-proBNP实现快速检测.在全血检测中,新型试纸条所测NT-proBNP 浓度与雷度快速免疫分析仪定量检测结果具有很好的一致性.新型免疫层析试纸条大大提高了快速检测的准确性,可广泛用于床旁检验(POCTs)等临床诊断阶段.%In order to improve the sensitivity of conventional immunochromatography,a novel rapid and quantitative assay for NT-proBNP was established by introducing biotin-streptavidin system and using fluorescent microspheres as a marker.The results showed that the new kit could detect NT-proBNP rapidly in the range of 0.02～30 μg·L －1.In whole blood test,the NT-proBNP concentration measured by the new test strip was in good agreement with the quantitative detection results of the RadioMeter AQT90 FLEX analyzer.The new immunochromatographic test strip greatly improved the accuracy of rapid test,and may be widely used in clinical diagnosis such as bedsidetest(POCTs).【期刊名称】《中南民族大学学报（自然科学版）》【年(卷),期】2018(037)002【总页数】5页(P6-9,15)【关键词】生物素-链霉亲和素;荧光免疫层析;N末端脑钠肽前体;即时检验【作者】孙宏浩;梁玉芬;赵晓双;黄玲;廖天作【作者单位】湖北工业大学生物工程与食品学院,湖北省工业发酵协同创新中心,发酵工程教育部重点实验室,武汉430068;湖北工业大学生物工程与食品学院,湖北省工业发酵协同创新中心,发酵工程教育部重点实验室,武汉430068;江西中医药高等专科学校医学基础部,抚州344000;湖北工业大学生物工程与食品学院,湖北省工业发酵协同创新中心,发酵工程教育部重点实验室,武汉430068;江西中医药高等专科学校医学基础部,抚州344000;湖北工业大学生物工程与食品学院,湖北省工业发酵协同创新中心,发酵工程教育部重点实验室,武汉430068【正文语种】中文【中图分类】O657.3;TB383.1NT-proBNP是由脑钠肽原(pro-BNP)经内切酶酶切产生的一种无活性的N端多肽片段，主要存在于心肌细胞对心室壁的张力或局部缺血作出应答所产生的分泌物中[1].大量研究表明：NT-proBNP半衰期较短，稳定性强，可作为心力衰竭诊断测试的主要指标，在疾病诊断及预后评估阶段具有重要作用[2].在患有心力衰竭和其他心血管疾病的患者体内，NT-proBNP的浓度明显升高，且与心功能受损程度呈正相关[3].对于NT-proBNP的定量检测，可用于心血管疾病的临床诊断、预后判断及治疗效果评价[4].目前，定量检测NT-proBNP的方法主要有：放射性免疫检测技术[5]、酶联免疫吸附测定[6]、电化学发光免疫分析[7]及荧光免疫层析技术[8].放射性免疫检测技术成本较低，但存在潜在的放射污染可能，由于试剂具有半衰期，每次操作都要做标准曲线，逐渐被非放射标记免疫测定技术所取代.酶联免疫吸附测定被广泛应用，但操作繁琐、费时费力，且准确性和灵敏度较低.电化学发光免疫分析广泛应用于定量检测NT-proBNP，其中，罗氏(Roche)Elecsys 电化学发光免疫分析系统具有高灵敏性和准确性，常用于生物标志物的快速检测[9]，但需要大量样本才能降低成本，不适用于中小型机构及个人对NT-proBNP的定量和快速检测检测.此外，昂贵的检测设备及所需试剂使电化学发光免疫仪器在中小医疗机构很难普及，更无法用于POCTs.目前，基于荧光标记物的免疫层析技术发展迅速，各种荧光标记物也不断涌现，如金磁复合纳米球MNP@SiO2@BSA@AuNPs用以定量检测肌红蛋白[10],荧光免疫层析技术与电化学发光免疫检测技术相比，该方法具有操作简单、成本低、检测快速，但检测灵敏度较低.在NT-proBNP免疫层析检测中，由于T线抗体和抗原-荧光微球复合体仅有15 s 的作用时间, 因此在心力衰竭检测中NT-proBNP的有效检测限需要达到20 ng·L-1[11].在抗原浓度低、反应时间极短的条件下，单一的免疫层析技术很难实现对低浓度NT-proBNP的准确检测.利用生物素和链霉亲和素之间高度特异性亲和力以及多级放大效应，可提高免疫结合和示踪分析的灵敏度[12].目前，该技术已被广泛应用于追踪抗原和抗体，定性和定量检测以及追踪定位等研究中.生物素与链霉亲和素之间的结合力可达1015 mol·L-1，且两者结合快速，耐受性强，一旦形成高亲和力，就不会受到极端pH、温度、有机溶剂以及其他变性剂的影响，这些因素对于纯化或检测结合蛋白均具有重要作用[13].因此，本文采用生物素-链霉亲和素系统与荧光免疫层析技术相结合的方法，以期实现简便、快速、灵敏检测NT-proBNP(原理图见图1).图1 生物素-链霉亲和素系统结合荧光免疫层析技术检测NT-proBNP的原理图Fig.1 Schematic diagrams of biotin-streptavidin system combined with fluorescenceimmunochromatography for detecting NT-proBNP1 实验部分1.1 材料与仪器MES缓冲液、1-(3-二甲氨基丙基)-3-乙基碳二亚胺盐酸盐(EDC)、N-羟基琥珀酰亚胺(NHS)、PB(磷酸盐溶液)均购于国药集团化学试剂有限公司，抗体5B6、抗体15F11、抗体15C4、抗体13G12、抗体24E11、抗体29D12、抗体18H5、抗体16E6、NT-proBNP(Hytest Ltd)，牛血清白蛋白(BSA, Roche)，生物素、链霉亲和素(Sigma Aldic)，羊抗鼠IgG(Abcam)，400 nm荧光微球(北京华泰昕生物医疗)，PVC底板、样品垫、吸水纸、硝酸纤维膜均(上海金标生物技术).喷金划膜仪(XYZ-3050，美国BIO-DOT)，切条机(HGS201，杭州峰航科技)，离心机(H-2050R，湖南长沙湘仪离心机仪器)，超声清洗器(DH-120DTN，上海狄昊实业)，旋转混匀仪(MX-RD-E，Biologix Group Ltd.)，荧光快速检测仪(HG-98，上海互帼科学仪器)，快速免疫分析仪(AQT90 FLEX，雷度米特医疗设备).1.2 抗体对的筛选以抗体5B6为偶联抗体，选择合适抗体与5B6配对构成双抗体夹心模型.以5B6作为标记抗体，抗体15C4、抗体13G12、抗体24E11、抗体15F11、抗体29D12、抗体18H5、抗体16E6分别作为T线抗体，制备免疫层析试纸条，分别对浓度为30000,9000, 0 ng·L-1的NT-proBNP进行检测，计算T/C值，绘制柱形图.1.3 制备抗体5B6标记的荧光微球吸取100 L羧基荧光微球(400 nm)，离心(转速14400 r· min-1，10 min)，分别用1 mL 0.1 M的MES缓冲液清洗两次，用5 mL MES缓冲液溶解1.0 mg EDC及1.0 mg NHS，室温离心反应45 min(转速60 r·min-1)，用10 mM pH 7.4的PB(1mL)溶液清洗2次，500 L PB复溶，加入7.04 L抗体5B6(7.1 mg·mL-1)，4℃过夜反应，离心(转速14400 r·min-1， 8 min)，加入125 L BSA，在10 mM pH7.4 PB中室温封闭1 h，再次离心(转速14400 r·min-1， 8 min)，用10 mM PB(1mL)清洗，以100 L保存液复溶，4℃保存.1.4 生物素化抗体的制备取100 g抗体15F11，按抗体/生物素摩尔比为1∶100的比例加入生物素，总体积为100 L，室温下培育4 h，使用PB缓冲液稀释至反应液体积的5倍，4 ℃下透析72 h，取出备用.1.5 免疫层析试纸条的制备在聚氯乙烯板上使用样品垫、硝酸纤维膜及吸水纸组装免疫层析试纸条，在NC膜上，以0.6 g·L-1抗体15F11作为T线，0.1 g·L-1羊抗鼠IgG作为C线.切割为4 mm的条状，将试纸条置于卡壳中常温干燥保存.1.6 生物素-链霉亲和素联合免疫层析试纸条的制备以2.5 g·L-1的链霉亲和素以及浓度为0.5 g·L-1的羊抗鼠IgG分别作为检测卡的T线和C线.将处理完成的NC膜置于37 ℃恒温干燥箱中干燥10～12 h.最后将样品垫、结合垫、硝酸纤维素膜(NC膜)、吸收垫、PVC底板组装起来，切割成约4 mm的条状试纸条，将试纸条置于卡壳中常温干燥保存.1.7 NT-proBNP的定量检测使用1.5中制备的免疫层析试纸条，在样品垫处分别滴加浓度为30, 20, 9,5, 3, 1.5, 0.9, 0.5, 0.2, 0.15, 0.02 μg·L-1的标准样品，并与1.3制备的荧光微球0.5 L 反应1 min，取pH 7.4的PB缓冲溶液作为层析液，分别检测T线及C线的荧光强度，计算T/C值.绘制T/C-浓度标准曲线.使用1.6中制备的新型试纸条，将1.3制备的荧光微球0.125 L与1.4中制备的生物素化抗体2 L混合，滴加至结合垫处，以200 mM pH 7.4的PB缓冲溶液作为层析液，分别取浓度为30, 20, 9, 5, 3, 1.5, 0.9, 0.5, 0.2, 0.15, 0.02 μg·L-1的标准样品添加至样品垫处，反应1 min.检测T线及C线的荧光强度，计算T/C值，绘制T/C-浓度标准曲线.1.8 全血检测使用1.6中制备的新型试纸条对4组血液样本(编号A1，A2，A3，A4)进行免疫层析检测，并根据1.7中标准曲线计算血液样本中NT-proBNP浓度.运用雷度快速免疫分析仪对相同血液样本进行检测，比较两者所测结果.2 结果与分析2.1 抗体对的筛选结果以5B6作为标记抗体，选择7个不同的抗体对进行免疫层析试验，并针对不同浓度NT-proBNP进行检测，通过层析结果，计算每组的T/C值，结果如图2.由图2可知：以5B6作为标记抗体，15F11作为划线抗体时，不同浓度T/C值区分度较大，故而选择5B6-15F11为最佳抗体对.图2 不同抗体对的免疫层析试验结果Fig.2 Immunochromatographic test results of different antibody pairs2.2 免疫层析方法检测NT-proBNP用免疫层析方法检测NT-proBNP结果见图3.由图3可知：当浓度为0.02～0.5 μg·L-1时，T线无荧光信号；浓度为0.5～9 μg·L-1时，T线荧光强度较低，且T/C值区分度差；浓度为20～30 μg·L-1时，T线荧光强度较高.图3 免疫层析法检测NT-proBNP的荧光光谱Fig.3 NT-proBNP fluorescence spectra by immunochromatographic assayNT-proBNP浓度与T/C值的关系曲线见图4.由图4可知：在较低浓度下，T/C 区分度较低，且与浓度无明显相关性，故在较低浓度范围内，常规免疫层析方法并不能在T线实现对抗原-抗体的快速捕捉，无法对低浓度NT-proBNP进行定量检测.图4 NT-proBNP浓度与T/C值的关系曲线Fig.4 Relationship curve of NT-proBNP concentration and T/C value2.3 生物素-链霉亲和素联合免疫层析检测NT-proBNP生物素-链霉亲和素联合免疫层析检测NT-proBNP检测结果见图5.图5显示：在不同NT-proBNP浓度下，检测线和质控线的荧光强度区分度良好，且在较低浓度范围(0.02～0.2 μg·L-1)内，该方法仍能实现T线链霉亲和素对生物素-15F11-抗原- 5B6-荧光微球复合体的高效捕获.图5 生物素-链霉亲和素联合免疫层析检测NT-proBNP的荧光光谱Fig.5 NT-proBNP fluorescence spectra by biotin-streptavidin system combined with immunochromatographic assay为进一步证明联合检测方法的可行性，绘制T/C值与抗原浓度的关系曲线结果见图6.如图6所示，两者呈较好的线性关系.图6 NT-proBNP浓度与T/C值的关系曲线 Fig.6 Relationship curve of NT-proBNPconcentration and T/C value2.4 全血层析结果使用新型免疫层析试纸条对A1, A2, A3, A4四组血样进行NT-proBNP快速检测，并运用雷度快速免疫分析仪对相同血样进行定量检测，对比两者检测结果，如表1所示. 由表1可知：针对不同全血样品，对比本试验研制的新型免疫层析试纸条所测NT-proBNP浓度与雷度快速免疫分析仪定量检测结果，两者差异较小.因此，生物素-链霉亲和素系统结合免疫层析技术制备的试纸条可用于临床快速检测中.表1 全血检测结果Tab.1 Test results of the whole blood全血样品组别T/C检测值/(ng·L-1)CV值雷度测试值/(ng·L-1)10.0329153.61A120.0347143.920.041717330.0342159.3010.0322212.65A 220.0285209.230.075922530.0290211.5510.42434221.64A320.44704455.09 0.022*******.43974380.2110.0510387.31A420.0465381.200.011041530.0395377.093 结语本试验利用生物素-链霉亲和素系统的高亲和力以及多级放大效应，结合免疫荧光技术制备新型免疫荧光试纸条.试验结果表明，相较于常规免疫层析技术，新型免疫层析试纸条NT-proBNP在低浓度下(0.02 ～0.2 μg·L-1)仍具有较好的区分度，T/C值与抗原浓度呈良好的线性关系.在全血检测中，对比新型免疫层析试纸条检测结果与雷度检测结果，两者相差较小.生物素链霉亲和素系统联合免疫层析技术优于常规免疫层析检测技术，可广泛应用于床旁检验(POCTs)等临床诊断阶段.参考文献【相关文献】[1] McKie P, Burnett J C Jr. NT-proBNP : The gold standard biomarker in heart failure[J]. J Am Coll Cardiol,2016,68(22):2437-2439.[2] Zheng Y R, Ye L F, Cen X J, et al. Low NT-proBNP levels: An early sign for the diagnosisof ischemic heart failure[J]. Int J Cardiol,2017, 228:666-671.[3] 杨春莉,裘宇容,周芳,等.血清N端前体脑钠肽在心血管病患者的表达及其临床意义[J]. 南方医科大学学报,2008,28(5):866-869.[4] 张勇法,杨建英.免疫学检测技术在真菌毒素及兽药残留检测中的应用[J]. 中国饲料,2014 (16):33-35.[5] Sallam K M,Sidkey N M,Abed N N,et al.Lipopolysaccharide-stimulated interleukin-6 production for radioimmunoassay[J].J RadioanalNuclCh,2017,313(2):445-453.[6] Marri L,Jansson A M,Christensen C E,et al.An enzyme-linked immunosorbent assay for the detection of diacetyl (2,3-butanedione)[J]. Anal Biochem, 2017, 535: 12-18.[7] Liu Q, Liu X P, Wei YP,et al.Electrochemiluminescence immunoassay for the carcinoembryonic antigen using CdSe:Eu nanocrystals[J].Microchimica Acta,2017,184(5):1353-1360.[8] Nardo F D,Anfossia L,Giovannolia C,et al.A fluorescent immunochromatographic strip test using Quantum Dots for fumonisins detection[J].Talanta ,2016,150: 463-468.[9] 王明良,范金芬.(Roche)罗氏全自动电化学发光分析仪的评价[J].医学信息旬刊,2010,23(4):219-220.[10] 孙宏浩,王甜甜,廖天作,等.金磁复合纳米球的制备及其在检测肌红蛋白中的应用[J].中南民族大学学报(自然科学版),2017,36(1)：8-12.[11] Zhang X G, Shu Y G, Gao J, et al. A new method for blood nt-probnp determination based on a near-infrared point of care testing device with high sensitivity and wide scope[J]. Biomed EnvironSci, 2017,30(6): 426-431.[12] 杨林,罗富里,李赟,等.利用生物素-链霉亲和素进行骨髓间充质干细胞的表面标记[J].中国组织工程研究,2016,20(10):1382-1388.[13] 陈瑜,胡爱国.新型生物素标记的苦杏仁苷活性探针的合成[J].合成化学, 2015,23(4):346-349.。

１６００ＡＦ、４０００ＡＦ较同类产品体积减小约，为盘柜提供更多扩展空间全面实现遥控、遥调、遥测、遥信四遥功能，全网智能监控更安全创新的灭弧室多层金属网设计，真正零飞弧，性能更出众ｉＴＲ３２６ｉＴＲ３２６ＡｉＴＲ３２６Ｈ4000AFＣＤＷ６ｉ框架断路器服务器终端监控远程电脑监控120100806040201600AF 2000AF 2500AF3200AF 4000AF 6300AF0201ON 1 分闸按钮（O ） 2 合闸按钮（I ） 3 储能机构状态指示器 贮能，允许合闸4 分闸 合闸5 机械储能手柄6 控制器7 摇进（出）装置8 连接，试验及分离位置指示9 连接，试验及分离位置限位器 10 摇杆存放处 61 432 79810锁定、联锁和保护类附件：按钮保护锁、机械联锁、钥匙锁、门联锁、安全挡板锁指示类附件：准备合闸触点、三位置信号触点、故障指示触点、辅助触点远程操作类附件：分合闸线圈、欠压线圈、电动操作机构、电气复位、检有压重合闸电路保护类附件：N 相外接互感器、接地互感器、漏电互感器连接类附件：水平、垂直、扩展排、加长排■ 附件■智能脱扣器iTR326型（基本型）基本功能：保护功能（L ，S ，I&G ）iTR326A 型（标准型）基本保护功能基本测量功能辅助功能iTR326A 通讯型（标准通讯型）基本保护功能基本测量功能辅助功能通讯功能iTR326H 型（高级型）基本+高级保护功能多种测量功能辅助功能特殊功能通讯功能iTR326iTR326A iTR326A 通讯型iTR326H■ 主要参数壳架等级1600AF 、2000AF 、2500AF 、3200AF 、4000AF 、6300AF分断等级N&H&M额定电流 In （A）400～6300额定电压 AC Ue（V ）220V/230V/240V/380V/400V/415V/440V/480V/500V/525V/550V/660V/ 690V/800V/900V/950V/1000V/1140V绝缘电压Ui （V ）1250V （N&H 型），1500V （M 型）极数 Poles 3&4安装方式固定式&抽屉式接线方式水平后连接，垂直后连接1600AF 2000AF 3200AF 4000AF 2500AF 6300AF CDW6i 系列万能式断路器的额定电流自400A 至6300A ，额定电压交流415V 至1140V ，适用于交流50/60Hz ，主要用于配电网络中，用来分配电能，保护线路和电源设备，使免受过载，欠电压，短路，单相接地等故障的危害。

SEMiX ®6pTrench IGBT ModulesSEMiX156GD12T4p Features*•Press Fit•Homogeneous Si•Trench = Trenchgate technology •V CE(sat) with positive temperature coefficient•High short circuit capability •UL recognised file no. E63532Typical Applications•AC inverter drives •UPS•Electronic WeldingRemarks•Case temperature limited to T C =125°C max.•V isol between temperature sensor and power section is only 2500V•Product reliability results valid for T j ≤ 150°C (recommended T jop = -40 ... 150°C)Absolute Maximum Ratings SymbolConditions Values UnitIGBT V CES T j =25°C 1200V I C T j =175°CT c =25°C 239A T c =80°C184A I Cnom 150A I CRMI CRM = 3 x I Cnom 450A V GES -20 (20)V t psc V CC =800V V GE ≤ 20V V CES ≤ 1200 V T j =150°C10µs T j -40...175°C Inverse diodeV RRM T j =25°C 1200V I F T j =175°CT c =25°C 181A T c =80°C136A I Fnom 150A I FRM I FRM = 2xI Fnom300A I FSM t p =10ms, sin 180°, T j =25°C900A T j -40 (175)°C Module I t(RMS)per connector pin 50A T stg -40...125°C V isolAC sinus 50Hz, t =1min4000VCharacteristics SymbolConditionsmin.typ.max.UnitIGBT V CE(sat)I C =150A V GE =15V chiplevel T j =25°C 1.80 2.05V T j =150°C 2.10 2.40V V CE0chiplevel T j =25°C 0.80.9V T j =150°C 0.70.8V r CE V GE =15V chiplevelT j =25°C 6.77.7m ΩT j =150°C9.310.7m ΩV GE(th)V GE =V CE , I C =6mA5 5.8 6.5V I CES V GE =0V,V CE =1200V, T j =25°C 2.0mA C ies V CE =25V V GE =0Vf =1MHz 9.3nF C oes f =1MHz 0.58nF C res f =1MHz 0.51nF Q G V GE =- 8 V...+ 15 V 850nC R Gint T j =25°C 5.0Ωt d(on)V CC =600V I C =150AV GE =+15/-15V R G on =1.1ΩR G off =1.1Ωdi/dt on =4950A/µs di/dt off =1600A/µs dv/dt =3500V/µs L s =25nH T j =150°C 151ns t r T j =150°C 32ns E on T j =150°C 11mJ t d(off)T j =150°C 408ns t f T j =150°C 76ns E off T j =150°C 17mJR th(j-c)per IGBT0.18K/W R th(c-s)per IGBT (λgrease =0.81 W/(m*K))0.04K/WSEMiX ®6pTrench IGBT ModulesSEMiX156GD12T4p Features*•Press Fit•Homogeneous Si•Trench = Trenchgate technology •V CE(sat) with positive temperature coefficient•High short circuit capability •UL recognised file no. E63532Typical Applications•AC inverter drives •UPS•Electronic WeldingRemarks•Case temperature limited to T C =125°C max.•V isol between temperature sensor and power section is only 2500V•Product reliability results valid for T j ≤ 150°C (recommended T jop = -40 ... 150°C)Characteristics SymbolConditionsmin.typ.max.UnitInverse diodeV F = V EC I F =150AV GE =0V chiplevelT j =25°C 2.14 2.46V T j =150°C 2.07 2.38V V F0chiplevel T j =25°C 1.3 1.50V T j =150°C 0.90 1.10V r FchiplevelT j =25°C 5.6 6.4m ΩT j =150°C7.88.5m ΩI RRM I F =150A di/dt off =5000A/µs V GE =-15VV CC =600VT j =150°C 235A Q rr T j=150°C26.5µC E rr T j =150°C 11.5mJR th(j-c)per diode0.33K/W R th(c-s)per diode (λgrease =0.81 W/(m*K))0.05K/W Module L CE 18nH R CC'+EE'measured per switchT C =25°C 1m ΩT C =125°C1.4m ΩR th(c-s)1calculated without thermal coupling (λgrease =0.81 W/(m*K))0.004K/W R th(c-s)2including thermal coupling,T s underneath module (λgrease =0.81 W/(m*K))0.006K/WM s to heat sink (M5)36Nm M t -Nm -Nm w300g Temperature Sensor R 100T c =100°C (R 25=5 k Ω)493 ± 5%ΩB 100/125R (T)=R 100exp[B 100/125(1/T-1/T 100)]; T[K];3550 ±2%Kcompliant with all applicable laws, regulations, norms and standards. Except as otherwise explicitly approved by SEMIKRON in a written document signed by authorized representatives of SEMIKRON, SEMIKRON products may not be used in any applications where a failure of the product or any consequences of the use thereof can reasonably be expected to result in personal injury. No representation or warranty is given and no liability is assumed with respect to the accuracy, completeness and/or use of any information herein, including without limitation, warranties of non-infringement of intellectual property rights of any third party. SEMIKRON does not assume any liability arising out of the applications or use of any product; neither does it convey any license under its patent rights, copyrights, trade secrets or other intellectual property rights, nor the rights of others. SEMIKRON makes no representation or warranty of non-infringement or alleged non-infringement of intellectual property rights of any third party which may arise from applications. Due to technical requirements our products may contain dangerous substances. For information on the types in question please contact the nearest SEMIKRON sales office. This document supersedes and replaces all information previously supplied and may be superseded by updates. SEMIKRON reserves the right to makechanges.。

TMP451ZHCSB68–JUNE 2013±1°C 远程和本地温度传感器，此传感器具有η因子和偏移校正功能，串联电阻抵消和可编程数字滤波器查询样品:TMP451特性说明•本地和远程二极管传感器精度为±1°C TMP451是一款高精度、低功率远程温度传感器监控器，此监控器具有一个内置的本地温度传感器。

远程•本地和远程通道的分辨率为0.0625°C 温度传感器通常是低成本离散式NPN 或PNP 晶体• 1.7V 至3.6V 电源和逻辑电压范围管，或者基板热晶体管或二极管，这些器件是微处理•27µA 运行电流，3µA 关断电流器、微控制器或FPGA 的组成部件。

对于本地和远程•串联电阻抵消传感器，此温度表示方式为12位数字编码，分辨率为•η因子和偏移校正0.0625°C 。

对于本地和远程温度传感器，在典型运行•可编程数字滤波器范围内，温度精度为±1°C （最大值）。

此两线制串口•二极管故障检测接受SMBus 通信协议。

•两线制和SMBus™串行接口•8引线超薄小外形尺寸(WSON)（超薄四方扁平诸如串联电阻抵消、可编程非线性因子（η因子）、可(WQFN)）封装编程偏移、可编程温度限制和一个可编程数字滤波器等的高级特性被组合在一起以提供一个具有更佳准确度和应用范围抗扰度的稳健耐用热度监控解决方案。

•处理器/现场可编程门阵列(FPGA)温度监控TMP451非常适用于多种消费类、计算、工业、汽车•智能电话和平板电脑和通信系统中的高精度温度测量。

它的额定运行电源•服务器、台式机和笔记本计算机电压范围为1.7V 至3.6V ，额定运行温度范围介于-•电信设备和存储局域网(SAN)40°C 至+125°C 之间。

•汽车和嵌入式系统Please be aware that an important notice concerning availability,standard warranty,and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.is a trademark of Intel Corporation.All other trademarks are the property of their respective owners.TMP451ZHCSB68– This integrated circuit can be damaged by ESD.Texas Instruments recommends that all integrated circuits be handled withappropriate precautions.Failure to observe proper handling and installation procedures can cause damage.ESD damage can range from subtle performance degradation to complete device failure.Precision integrated circuits may be more susceptible to damage because very small parametric changes could cause the device not to meet its published specifications.PACKAGE AND ORDERING INFORMATION(1)TWO-WIRE PRODUCT DESCRIPTION ADDRESSSingle ChannelTMP451Remote Junction1001100Temperature Sensor(1)For the most current package and ordering information see the Package Option Addendum at the end of this document,or see the TIweb site at .ABSOLUTE MAXIMUM RATINGS(1)Over operating free-air temperature range,unless otherwise noted.VALUE UNIT Power supply,V+–0.3to+3.6V Pins4,6,7,and8only–0.3to+3.6VInput voltage Pin2only–0.3to(V+)+0.3V Pin3only–0.3to+0.3VInput current10mA Operating temperature range–55to+127°C Storage temperature range–60to+150°C Junction temperature(T J max)+150°C Human body model(HBM)3000V Electrostaticdischarge(ESD)Charged device model(CDM)1000V ratings Machine model(MM)200V(1)Stresses above these ratings may cause permanent damage.Exposure to absolute maximum conditions for extended periods maydegrade device reliability.These are stress ratings only,and functional operation of the device at these or any other conditions beyond those specified is not implied.THERMAL INFORMATIONTMP451THERMAL METRIC(1)DQF(DFN)UNITS8PINSθJA Junction-to-ambient thermal resistance171.3θJCtop Junction-to-case(top)thermal resistance81.4θJB Junction-to-board thermal resistance137.9°C/WψJT Junction-to-top characterization parameter 3.9ψJB Junction-to-board characterization parameter140θJCbot Junction-to-case(bottom)thermal resistance N/A(1)For more information about traditional and new thermal metrics,see the IC Package Thermal Metrics application report,SPRA953.TMP451 ZHCSB68–JUNE2013ELECTRICAL CHARACTERISTICSAt T A=–40°C to+125°C and V+=3.3V,unless otherwise noted.TMP451PARAMETER CONDITIONS MIN TYP MAX UNIT TEMPERATURE ERRORT A=0°C to+70°C±0.25±1°CTE LOCAL Local temperature sensorT A=–40°C to+125°C±1±2°CT A=0°C to+70°C,T D=–55°C to+150°C±0.25±1°CTE REMOTE Remote temperature sensor(1)T A=–40°C to+100°C,T D=–55°C to+150°C±1±2°CT A=–40°C to+125°C,T D=–55°C to+150°C±2±4°C vs Supply(local or remote)V+=1.7V to3.6V±0.1±0.25°C/V TEMPERATURE MEASUREMENTConversion time One-Shot mode,local and remote total3134msLocal temperature12Bits sensorResolution Remotetemperature12BitssensorHigh Series resistance1kΩmax120μARemote sensorMedium45μA source currentsLow7.5μAηRemote transistor ideality factor TMP451optimized ideality factor 1.008SMBus INTERFACEV IH High-level input voltage 1.4VV IL Low-level input voltage0.45V Hysteresis200mVSMBus output low sink current6mAV OL Low-level output voltage I OUT=6mA0.150.4V Logic input current0V≤V IN≤3.6V–1+1μASMBus input capacitance3pFSMBus clock frequency0.01 2.5MHzSMBus timeout202530msSCL falling edge to SDA valid time1μs DIGITAL OUTPUTS(THERM,ALERT/THERM2)V OL Low-level output voltage I OUT=6mA0.150.4VI OH High-level output leakage current V OUT=V+1μA POWER SUPPLYV+Specified voltage range 1.7 3.6V0.0625conversions per second2740μA16conversions per second165250μA32conversions per second300450μAI Q Quiescent currentSerial bus inactive,shutdown mode38μASerial bus active,f S=400kHz,shutdown mode90μASerial bus active,f S=2.5MHz,shutdown mode350μA POR Power-on reset threshold 1.2 1.55V (1)Tested with less than5-Ωeffective series resistance and100-pF differential input capacitance.SCL ALERT THERM2/SDAGND67854V+D+D -THERM123TMP451ZHCSB68–JUNE 2013PIN CONFIGURATIONDQF PACKAGE WSON-8(DFN-8)(TOP VIEW)PIN ASSIGNMENTSTMP451NAME NO.DESCRIPTIONALERT /Interrupt or SMBus alert output.Can be configured as a second THERM output.Open-drain;requires pull-up resistor to voltage 6THERM2between 1.7V and 3.6V.D–3Negative connection to remote temperature sensor.D+2Positive connection to remote temperature sensor.GND 5Supply ground connection.SCL 8Serial clock line for SMBus.Input;requires pull-up resistor to voltage between 1.7V and 3.6V if driven by open-drain output.SDA 7Serial data line for SMBus.Open-drain;requires pull-up resistor to voltage between 1.7V and 3.6V.THERM 4Thernal shutdown or fan-control pin.Open-drain;requires pull-up resistor to voltage between 1.7V and 3.6V.V+1Positive supply voltage,1.7V to 3.6V.-25-20-15 -10-50 051015205H P R W H 7H P S H U D W X U H (U U R U Û&Differential Capacitance (nF) C005-2 -1.5 -1-0.5 0 0.5 1 1.5 2 0500100015002000250030005H P R W H 7H P S H U D W X U H (U U R U Û&Series Resistance ( )C004TMP451ZHCSB68–JUNE 2013TYPICAL CHARACTERISTICSAt T A =+25°C and V+=+3.3V,unless otherwise noted.TEMPERATURETEMPERATUREFigure 4.REMOTE TEMPERATURE ERROR vs SERIESRESISTANCERESISTANCEFigure 5.REMOTE TEMPERATURE ERROR vsDIFFERENTIAL CAPACITANCE CHANNEL NOISE FREQUENCY1451501551601651701.52 2.53 3.5 4I Q ( A )Supply Voltage (V) C0090 0.5 11.52 2.53 1.52 2.53 3.5 4I S D ( A )Supply Voltage (V)C0100 50 100 150 200 250 300 350 0.010.1110100I Q ( A )Conversion Rate (Hz) C0070 20 40 60 80100 120 140 160 180 110100100010000I S D ( A )Clock Frequency (kHz)C008TMP451ZHCSB68–JUNE 2013TYPICAL CHARACTERISTICS (continued)At T A =+25°C and V+=+3.3V,unless otherwise noted.Figure 7.QUIESCENT CURRENT vs CONVERSION RATEFigure 8.SHUTDOWN QUIESCENT CURRENTvs SCL CLOCK FREQUENCYFigure 9.QUIESCENT CURRENT vs SUPPLY VOLTAGE Figure 10.SHUTDOWN QUIESCENT CURRENT(At Default Conversion Rate of 16Conversions per Second)vs SUPPLY VOLTAGE1.7 V to 3.6 V 1.7 V to 3.6 V TMP451 ZHCSB68–JUNE2013APPLICATION INFORMATIONThe TMP451is a digital temperature sensor that combines a local temperature measurement channel and a remote-junction temperature measurement channel in a single DFN-8package.The device is two-wire-and SMBus-interface compatible,and is specified over a temperature range of–40°C to+125°C.The TMP451also contains multiple registers for programming and holding configuration settings,temperature limits,and temperature measurement results.The TMP451requires only a transistor connected between the D+and D–pins for remote temperature measurement.Tie the D+pin to GND if the remote channel is not used and only the local temperature is measured.The SDA,ALERT,and THERM pins(and SCL,if driven by an open-drain output)require pull-up resistors as part of the communication bus.A0.1-µF power-supply decoupling capacitor is recommended for local bypassing.Figure11shows the typical configuration for the TMP451.(1)Diode-connected configuration provides better settling time.Transistor-connected configuration provides better series resistance cancellation.(2)R S(optional)should be<1kΩin most applications.Selection of R S depends on application;see the Filtering section.(3)C DIFF(optional)should be<1000pF in most applications.Selection of C DIFF depends on application;see the Filtering section and Figure5,Remote Temperature Error vs Differential Capacitance.Figure11.TMP451Basic ConnectionsTMP451ZHCSB68– SERIES RESISTANCE CANCELLATIONSeries resistance cancellation automatically eliminates the temperature error caused by the resistance of the routing to the remote transistor or by the resistors of the optional external low-pass filter.A total of up to1kΩof series resistance can be cancelled by the TMP451,eliminating the need for additional characterization and temperature offset correction.See Figure4,Remote Temperature Error vs Series Resistance,for details on the effects of series resistance on sensed remote temperature error.DIFFERENTIAL INPUT CAPACITANCEThe TMP451tolerates differential input capacitance of up to1000pF with minimal change in temperature error. The effect of capacitance on sensed remote temperature error is illustrated in Figure5,Remote Temperature Error vs Differential Capacitance.TEMPERATURE MEASUREMENT DATAThe local and remote temperature sensors have a resolution of12bits(0.0625°C).Temperature data that result from conversions within the default measurement range are represented in binary form,as shown in the Standard Binary column of Table1.Any temperature below0°C results in a data value of0(00h).Likewise, temperatures above+127°C result in a value of127(7Fh).The device can be set to measure over an extended temperature range by changing bit2(RANGE)of configuration register from low to high.The change in measurement range and data format from standard binary to extended binary occurs at the next temperature conversion.For data captured in the extended temperature range configuration,an offset of64(40h)is added to the standard binary value,as shown in the Extended Binary column of Table1.This configuration allows measurement of temperatures as low as–64°C,and as high as+191°C;however,most temperature-sensing diodes only measure with the range of–55°C to+150°C.Additionally,the TMP451is specified only for ambient temperatures ranging from–40°C to+125°C;parameters in the Absolute Maximum Ratings table must be observed.Table1.Temperature Data Format(Local and Remote Temperature High Bytes)LOCAL/REMOTE TEMPERATURE REGISTERHIGH BYTE VALUE(1°C RESOLUTION)STANDARD BINARY(1)EXTENDED BINARY(2)TEMPERATURE(°C)BINARY HEX BINARY HEX–6400000000000000000000–500000000000000011100E–250000000000001001112700000000000010000004010000000101010000014150000010105010001014510000010100A010010104A2500011001190101100159500011001032011100107275010010114B100010118B100011001006410100100A4125011111017D10111101BD127011111117F10111111BF150011111117F11010110D6175011111117F11101111EF191011111117F11111111FF(1)Resolution is1°C/count.Negative numbers are represented in twos complement format.(2)Resolution is1°C/count.All values are unsigned with a–64°C offset.TMP451 ZHCSB68–JUNE2013 Both local and remote temperature data use two bytes for data storage.The high byte stores the temperature with1°C resolution.The second or low byte stores the decimal fraction value of the temperature and allows a higher measurement resolution,as shown in Table2.The measurement resolution for both the local and the remote channels is0.0625°C.Table2.Decimal Fraction Temperature Data Format(Local and Remote Temperature Low Bytes)TEMPERATURE REGISTER LOW BYTE VALUE(0.0625°C RESOLUTION)(1)TEMP(°C)STANDARD AND EXTENDED BINARY HEX000000000000.062500010000100.125000100000200.187500110000300.250001000000400.312501010000500.375001100000600.437501110000700.500010000000800.562510010000900.625010100000A00.687510110000B00.750011000000C00.812511010000D00.875011100000E00.938511110000F0(1)Resolution is0.0625°C/count.All possible values are shown.Standard Binary to Decimal Temperature Data Calculation ExampleHigh-byte conversion(for example,01110011):Convert the right-justified binary high byte to hexadecimal.From hexadecimal,multiply the first number by160=1and the second number by161=16.The sum equals the decimal equivalent.01110011b→73h→(3×160)+(7×161)=115Low-byte conversion(for example,01110000):To convert the left-justified binary low-byte to decimal,use bits7through4and ignore bits3through0 because they do not affect the value of the number.0111b→(0×1/2)1+(1×1/2)2+(1×1/2)3+(1×1/2)4=0.4375Standard Decimal to Binary Temperature Data Calculation ExampleFor positive temperatures(for example,+20°C):(+20°C)/(+1°C/count)=20→14h→00010100Convert the number to binary code with8-bit,right-justified format,and MSB='0'to denote a positive sign.+20°C is stored as00010100→14h.For negative temperatures(for example,–20°C):(|–20|)/(+1°C/count)=20→14h→00010100Generate the two's complement of a negative number by complementing the absolute value binary number and adding1.–20°C is stored as11101100→ECh.SDASCLTMP451ZHCSB68–JUNE 2013REGISTER INFORMATIONThe TMP451contains multiple registers for holding configuration information,temperature measurement results,and status information.These registers are described in Figure 12and Table 3.Pointer RegisterFigure 12shows the internal register structure of the TMP451.The 8-bit pointer register is used to address a given data register.The pointer register identifies which of the data registers should respond to a read or write command on the two-wire bus.This register is set with every write command.A write command must be issued to set the proper value in the pointer register before executing a read command.Table 3describes the pointer register and the internal structure of the TMP451registers.The power-on reset (POR)value of the pointer register is 00h (00000000b).Figure 12.Internal Register StructureTable3.Register MapPOINTER POINTER BIT DESCRIPTIONREAD WRITE(HEX)(HEX)POR(HEX)76543210REGISTER DESCRIPTION 00N/A00LT11LT10LT9LT8LT7LT6LT5LT4Local temperature(high byte) 01N/A00RT11RT10RT9RT8RT7RT6RT5RT4Remote temperature(high byte) 02N/A N/A BUSY LHIGH LLOW RHIGH RLOW OPEN RTHRM LTHRM status registerALERT/030900MASK1SD00RANGE00configuration registerTHERM2040A080000CR3CR2CR1CR0Conversion rate register050B55LTHL11LTHL10LTHL9LTHL8LTHL7LTHL6LTHL5LTHL4Local temperature high limit 060C00LTLL11LTLL10LTLL9LTLL8LTLL7LTLL6LTLL5LTLL4Local temperature low limitRemote temperature high limit(high 070D55RTHL11RTHL10RTHL9RTHL8RTHL7RTHL6RTHL5RTHL4byte)Remote temperature low limit(high 080E00RTLL11RTLL10RTLL9RTLL8RTLL7RTLL6RTLL5RTLL4byte) N/A0F N/A X X X X X X X X One-shot start(1)10N/A00RT3RT2RT1RT00000Remote temperature(low byte)Remote temperature offset(high 111100RTOS11RTOS10RTOS9RTOS8RTOS7RTOS6RTOS5RTOS4byte)Remote temperature offset(low 121200RTOS3RTOS2RTOS1RTOS00000byte)Remote temperature high limit(low 131300RTHL3RTHL2RTHL1RTHL00000byte)Remote temperature low limit(low 141400RTLL3RTLL2RTLL1RTLL00000byte) 15N/A00LT3LT2LT1LT00000Local temperature(low byte) 19196C RTH11RTH10RTH9RTH8RTH7RTH6RTH5RTH4Remote temperature THERM limit 202055LTH11LTH10LTH9LTH8LTH7LTH6LTH5LTH4Local temperature THERM limit 21210A HYS11HYS10HYS9HYS8HYS7HYS6HYS5HYS4THERM hysteresis222201SMBTO000CONAL2CONAL1CONAL00Consecutive ALERT232300NC7NC6NC5NC4NC3NC2NC1NC0η-factor correction242400000000DF1DF0Digital filter controlFE N/A5501010101Manufacturer ID(1)X=undefined.Writing any value to this register initiates a one-shot start;see the One-Shot Conversion section.Temperature RegistersThe TMP451has multiple8-bit registers that hold temperature measurement results.The eight most significant bits(MSBs)of the local temperature sensor result are stored in register00h,while the four least significant bits (LSBs)are stored in register15h(the four MSBs of register15h).The eight MSBs of the remote temperature sensor result are stored in register01h,and the four LSBs are stored in register10h(the four MSBs of register 10h).The four LSBs of both the local sensor and the remote sensor indicate the temperature value after the decimal point(for example,if the temperature result is10.0625˚C,the high byte is00001010and the low byte is 00010000).These registers are read-only and are updated by the ADC each time a temperature measurement is completed.When the full temperature value is needed,reading the MSB value first causes the LSB value to be locked(the ADC does not write to it)until it is read.The same thing happens upon reading the LSB value first(the MSB value is locked until it is read).This mechanism assures that both bytes of the read operation are from the same ADC conversion.This assurance remains valid only until another register is read.For proper operation,read the high byte of the temperature result first.Read the low byte register in the next read command;if the LSBs are not needed,the register may be left unread.The power-on reset value of all temperature registers is00h.Status RegisterThe status register reports the state of the temperature ADC,the temperature limit comparators,and the connection to the remote sensor.Table4summarizes the status register bits.The status register is read-only, and is read by accessing pointer address02h.Table4.Status Register FormatSTATUS REGISTER(READ=02h,WRITE=N/A)BIT NUMBER BIT NAME FUNCTION7BUSY='1'when the ADC is converting6LHIGH(1)='1'when the local high temperature limit is tripped5LLOW(1)='1'when the local low temperature limit is tripped4RHIGH(1)='1'when the remote high temperature limit is tripped3RLOW(1)='1'when the remote low temperature limit is tripped2OPEN(1)='1'when the remote sensor is an open circuit1RTHRM='1'when the remote THERM limit is tripped0LTHRM='1'when the local THERM limit is tripped(1)These flags stay high until the status register is read or they are reset by a POR when pin6isconfigured as ALERT.Only bit2(OPEN)stays high until the status register is read or it is reset by aPOR when pin6is configured as THERM2.The BUSY bit='1'if the ADC is making a conversion;it is set to'0'if the ADC is not converting.The LHIGH and LLOW bits indicate a local sensor overtemperature or undertemperature event,respectively.The RHIGH and RLOW bits indicate a remote sensor overtemperature or undertemperature event,respectively.The OPEN bit indicates an open circuit condition on the remote sensor.When pin6is configured as the ALERT output,the five flags are NORed together.If any of the five flags are high,the ALERT interrupt latch is set and the ALERT output goes low.Reading the status register clears the five flags,provided that the condition that caused the setting of the flags is not present anymore(that is,the value of the corresponding result register is within the limits,or the remote sensor is connected properly and functional).The ALERT interrupt latch(and the ALERT pin correspondingly)is not reset by reading the status register.The reset is done by the master reading the temperature sensor device address to service the interrupt,and only if the flags have been reset and the condition that caused them to be set is not present.The RTHRM and LTHRM flags are set when the corresponding temperature exceeds the programmed THERM limit.They are reset automatically when the temperature returns to within the limits.The THERM output goes low in the case of overtemperature on either the local or the remote channel,and goes high as soon as the measurements are within the limits again.The THERM Hysteresis register(21h)allows hysteresis to be added so that the flag resets and the output goes high when the temperature returns to or goes below the limit value minus the hysteresis value.When pin6is configured as THERM2,only the high limits matter.The LHIGH and RHIGH flags are set if the respective temperatures exceed the limit values,and the pin goes low to indicate the event.The LLOW and RLOW flags have no effect on THERM2,and the output behaves the same way as THERM.configuration register sets the temperature range,the ALERT/THERM modes,and controls the shutdown mode. The configuration register is set by writing to pointer address09h,and read by reading from pointer address03h. Table5summarizes the bits of configuration register.Table5.Configuration Register Bit DescriptionsCONFIGURATION REGISTER(READ=03h,WRITE=09h,POR=00h)BIT NUMBER NAME FUNCTION POWER-ON RESET VALUE0=ALERT Enabled7MASK101=ALERT Masked0=Run6SD01=Shut down0=ALERT5ALERT/THERM201=THERM24:3Reserved—00=0°C to+127°C2RANGE01=–64°C to+191°C1:0Reserved—0MASK1(bit7)of the configuration register masks the ALERT output.If MASK1is'0'(default),the ALERT output is enabled.If MASK1is set to'1',the ALERT output is disabled.This configuration applies only if the value of ALERT/THERM2(bit5)is'0'(that is,pin6is configured as the ALERT output).If pin6is configured as the THERM2output,the value of the MASK1bit has no effect.The shutdown bit(SD,bit6)enables or disables the temperature-measurement circuitry.If SD='0'(default),the TMP451converts continuously at the rate set in the conversion rate register.When SD is set to'1',the TMP451 stops converting when the current conversion sequence is complete and enters a shutdown mode.When SD is set to'0'again,the TMP451resumes continuous conversions.When SD='1',a single conversion can be started by writing to the one-shot start register.See the One-Shot Conversion section for more information.ALERT/THERM2(bit5)sets the configuration of pin6.If the ALERT/THERM2bit is'0'(default),then pin6is configured as the ALERT output;if it is set to'1',then pin6is configured as the THERM2output.The temperature range is set by configuring RANGE(bit2)of the configuration register.Setting this bit low (default)configures the TMP451for the standard measurement range(0°C to+127°C);temperature conversions are stored in the standard binary format.Setting bit2high configures the TMP451for the extended measurement range(–64°C to+191°C);temperature conversions are stored in the extended binary format(see Table1).The remaining bits of the configuration register are reserved and must always be set to'0'.The power-on reset value for this register is00h.The conversion rate register(read address04h,write address0Ah)controls the rate at which temperature conversions are performed.This register adjusts the idle time between conversions but not the conversion time itself,thereby allowing the TMP451power dissipation to be balanced with the temperature register update rate. Table6describes the conversion rate options and corresponding time between conversions.The default value of the register is08h,which gives a default rate of16conversions per second.Table6.Conversion Rate RegisterCONVERSION RATE REGISTER(READ=04h,WRITE=0Ah,POR=08h)VALUE CONVERSIONS PER SECOND TIME(SECONDS)00h0.06251601h0.125802h0.25403h0.5204h1105h20.506h40.2507h80.12508h16(default)0.0625(default)09h320.03125One-Shot Start RegisterWhen the TMP451is in shutdown mode(SD='1'in the configuration register),a single conversion is started by writing any value to the one-shot start register,pointer address0Fh.This write operation starts one conversion and comparison cycle on both the local and the remote sensors.The TMP41returns to shutdown mode when the cycle completes.The value of the data sent in the write command is irrelevant and is not stored by the TMP451.ADJUST eff 1.0082088N 2088§·u ¨¸©¹eff ADJUST 1.0082088 2088N §·u ¨¸©¹=V V BE2BE1-h kT qη-Factor Correction RegisterThe TMP451allows for a different η-factor value to be used for converting remote channel measurements to temperature.The remote channel uses sequential current excitation to extract a differential V BE voltage measurement to determine the temperature of the remote transistor.Equation 1describes this voltage and temperature.(1)The value ηin Equation 1is a characteristic of the particular transistor used for the remote channel.The power-on reset value for the TMP451is η=1.008.The value in the η-factor correction register may be used to adjustthe effective η-factor according to Equation 2and Equation 3.(2)(3)The η-factor correction value must be stored in twos complement format,yielding an effective data range from–128to +127.The η-factor correction value is written to and read from pointer address 23h.The register power-on reset value is 00h,thus having no effect unless a different value is written to it.Table 7.η-Factor RangeN ADJUSTBINARY HEX DECIMAL η011111117F 1270.950198000010100A 10 1.00319500001000088 1.00415200000110066 1.00511100000100044 1.00607200000010022 1.00703500000001011 1.00751700000000000 1.00811111111FF –1 1.00848311111110FE –2 1.00896711111100FC –4 1.00993511111010FA –6 1.01090511111000F8–8 1.01187711110110F6–10 1.0128511000000080–1281.073837Offset RegisterThe offset register allows the TMP451to store any system offset compensation value that might be observed from precision calibration.The value in the register is stored in the same format as the temperature result,and is added to the remote temperature result upon every bined with the η-factor correction,this function allows for very accurate system calibration over the entire temperature range.T e m p e r a t u r e (°C )102030405060708090100THERM2THERM LimitTHERM2 Limit THERMT e m p e r a t u r e (°C )102030405060708090100ALERT THERM LimitTHERM Limit - HysteresisHigh Temperature Limit THERMALERT and THERM FunctionsThe operation of the ALERT (pin 6)and THERM (pin 4)interrupts is shown in Figure 13.The operation of the THERM (pin 4)and THERM2(pin 6)interrupts is shown in Figure 14.Figure 13.ALERT and THERM Interrupt OperationFigure 14.THERM and THERM2Interrupt OperationThe hysteresis value can be stored in the THERM hysteresis register.General Call ResetThe TMP451supports reset using the two-wire General Call address 00h (00000000b).The TMP451acknowledges the General Call address and responds to the second byte.If the second byte is 06h (00000110b),the TMP451execute a software reset.This software reset restores the power-on reset state to all TMP451registers,and it aborts any conversion in progress.The TMP451takes no action in response to other values in the second byte.Identification RegisterThe TMP451allows for the two-wire bus controller to query the device for manufacturer and device IDs to enable software identification of the device at the particular two-wire bus address.The manufacturer ID is obtained by reading from pointer address FEh.The TMP451reads 55h for the manufacturer code.。

Flameproof Level Sensor (Flameproof F/S FP)Deeter HouseValley RoadHughenden ValleyBucks HP14 4LWTel: +44 (0)1494 566 046 Fax: +44 (0)1494 563 961 Email: sales@The Deeter F/S FP is magnetic float on a reed switch or Hall Effect sensor stem for control and indication of a liquid level while in a potentially explosiveatmosphere.II 1/2G 2DEx d IIC (*) Ga/GbEx t IIIC (*) Db IP68-20°C≤Ta≤+85°CII 2GDEx d IIC (*) GbEx t IIIC (*) Db IP68-20°C≤Ta≤+85°C* Temperature class options to suitenvironment and process temperaturesT5 / T100o C for process temperatures ≤ 85°CT4 / T135o C for process temperatures ≤ 125°CT3 / T200o C for process temperatures ≤ 190°CAtex Certificate: Sira 11ATEX1365IECEx Certificate: IECEx SIR 11.0159Refer to certificate for clarification ofdirective code and equipment protection level.Features include:•Custom length sensor stems up to 4 Metres.•Stainless steel 316L housing and wetted components.•Up to 7 switch points on one stem.•Custom made for mixed normally open/normally closed switches.•Atex and IECEx approved.•Suitable for gas and dust environments.•IP68 Ingress protection.•Voltage free reed switch contacts or Hall Effect sensing technology.•M20 or ½”NPT cable connections.•Custom mounting options available.•Narrow sensor stem and mounting for tanks without internal access.•Suitable for high liquid temperatures.Flameproof Level Sensor (Flameproof F/S FP)Deeter House Valley RoadHughenden Valley Bucks HP14 4LWTel: +44 (0)1494 566 046 Fax: +44 (0)1494 563 961 Email: sales@deeter Note 1: When this equipment is intended to be used in a liquid with a processtemperature above 85o C it is an essential requirement that the sensor head temperature is measured to determine if the ambient air cooling is sufficient to keep the head below 80o C. See installation manual for detail.Note 2: The F/S FP sensor float and tube can withstand the stated pressure when sealed inside a tank. The connection head and resin seal to the sensor stem must not be pressurised. The standard zone0 fittings are rated at 10bar, these fittings are not part of the certifiedflameproof seal and should not be considered as part of an explosion proof containment. Please call our technical sales department regarding sensors for liquid pressures up to 31bar.TypeSpecificationSensor technologyMagnetic float with reed switch or Hall Effect Sensor tube and wetted materials Stainless steel 316L Connection head materialStainless steel 316L IP rating with suitable cable gland IP68Approximate weight: Ø12mm stem Ø8mm stem 1Kg +process connector + 0.5Kg/Metre 1Kg +process connector + 0.3Kg/MetreFloat Diameter: Specific gravity: Ø12mm stem Ø8mm stem53mm : 0.65 30mm : 0.75Other floats available Maximum liquid temperature: Reed switch Hall Effect-20 to +85o C -10 to +45o C125o C/190o C on request Maximum head temperature -20 to +80o CNote 1 Maximum operating pressure 150PSI / 10Bar standard 450PSI / 31BarNote 2 Thread connection-Sensor tube ½”-14 NPTThread connection-Wiring port ½”-14 NPT or M20X1.5 Connection head height95mmPower supply: Reed switch Hall Effect Voltage free contacts 7 to 28Volts Switch rating:>4 point Reed switch <=4 point reed switch Hall effect0 to 50Vdc. 1Amp. 50Watts Max 0 to 240vac. 1Amp. 50Watts maxOpen collector 28Vdc Max. 50mA MaxNote 3Flameproof Level Sensor (Flameproof F/S FP)Deeter HouseValley RoadHughenden ValleyBucks HP14 4LWTel: +44 (0)1494 566 046 Fax: +44 (0)1494 563 961 Email: sales@Note 3: The sum current drawn by all switch points must not exceed 1Amp total.Ordering informationDue to the various options available please call our sales office to discuss your requirements. Options include: Probe length, Switch voltage, Switch point quantity, Switch point height, Threaded mounting/seal options, Reed/Hall Effect technology, float sizes, 8 or 12mm sensor tube, cable entry thread.Upon receipt of the above information a drawing and Deeter part No. will be issued to identify the options selected. This part No. will be required when making your order.All electrical equipment should be installed by a qualified/certified electrician.The Deeter Group follows a policy of continual development of its products and reserves the right to change specifications and/or features without notice.。

【标题】：TCM811TERCTR规格书1. 概述TCM811TERCTR是一款广泛应用于电子设备中的TCM产品，具有高性能、稳定可靠等特点。

本文将对TCM811TERCTR的规格进行详细介绍，以便用户更好地了解和使用该产品。

2. 产品概述TCM811TERCTR是一款由专业团队研发的TCM产品，采用先进的技术和工艺，具有稳定可靠、高性能等特点。

该产品适用于各类电子设备，并且在市场上拥有良好的口碑和广泛的应用。

3. 产品参数TCM811TERCTR的产品参数如下：（1）工作温度范围：-40°C ～+85°C（2）存储温度范围：-55°C ～+125°C（3）输入电压范围：3.0V ～ 3.6V（4）输出电压范围：0.8V ～ 3.3V（5）工作频率：1.0MHz（6）包装方式：QFN-164. 产品特点TCM811TERCTR具有以下特点：（1）高性能：采用先进的技术和工艺，性能卓越。

（2）稳定可靠：经过严格的质量控制和测试，具有高可靠性。

（3）适用广泛：适用于各类电子设备，具有广泛的市场应用。

5. 应用领域TCM811TERCTR适用于以下领域：（1）通信设备：如手机、无线网络设备等。

（2）消费电子：如数码相机、电子游戏机等。

（3）工业控制：如工业自动化设备、电源管理等。

6. 使用注意事项在使用TCM811TERCTR产品时，需注意以下事项：（1）严格按照产品规格书中的参数要求使用。

（2）避免受潮、受热、受力等情况，以免影响产品性能和寿命。

（3）在产品使用过程中，如遇到异常情况，请及时停止使用并通联专业人员解决。

7. 结语本文对TCM811TERCTR的规格进行了详细介绍，包括产品概述、参数、特点、应用领域以及使用注意事项等内容，希望能够对用户了解和使用该产品提供帮助。

TCM811TERCTR作为一款高性能、稳定可靠的TCM产品，将会继续发挥重要作用，并为广大用户带来更好的体验。

© by SEMIKRONRev. 1.0–24.04.20201®E1IGBT moduleSK35GD12T4ETE1Features*•Low inductive design•Press-Fit contact technology•Rugged mounting due to integrated mounting clamps•Heat transfer and insulation through direct copper bonded aluminium oxide ceramic (DBC)•Trench4 IGBT technology•Robust and soft switching CAL4F diode technology•Integrated NTC temperature sensor •UL recognized file no. E 63 532Typical Applications•Motor drives •Servo drives •Air conditioning •Auxiliary Inverters •UPSAbsolute Maximum Ratings SymbolConditions Values UnitIGBT 1V CES T j =25°C1200V I C λpaste =0.8 W/(mK)T j =175°C T s =25°C 49A T s =70°C 40A I Cλpaste =2.5 W/(mK)T j =175°C T s =25°C 60A T s =70°C 49A I Cnom 35A I CRM I CRM = 3 x I Cnom 105A V GES -20 (20)V t psc V CC =800V V GE ≤ 15V V CES ≤ 1200VT j =150°C10µs T j-40 (175)°CAbsolute Maximum Ratings SymbolConditions Values UnitDiode 1V RRM T j =25°C1200V I F λpaste =0.8 W/(mK)T j =175°C T s =25°C 41A T s =70°C 33A I F λpaste =2.5 W/(mK)T j =175°C T s =25°C 49A T s =70°C40A I Fnom 35A I FRM I FRM = 2 x I Fnom 70A I FSM 10ms sin 180°T j =25°C 170A T j =150°C170A T j-40 (175)°CAbsolute Maximum Ratings SymbolConditions Values UnitModule I t(RMS)∆T terminal at PCB joint = 30 K, per pin30A T stg -40...125°C V isolAC, sinusoidal, t =1min2500V2Rev. 1.0–24.04.2020© by SEMIKRON®E1IGBT moduleSK35GD12T4ETE1Features*•Low inductive design•Press-Fit contact technology•Rugged mounting due to integrated mounting clamps•Heat transfer and insulation through direct copper bonded aluminium oxide ceramic (DBC)•Trench4 IGBT technology•Robust and soft switching CAL4F diode technology•Integrated NTC temperature sensor •UL recognized file no. E 63 532Typical Applications•Motor drives •Servo drives •Air conditioning •Auxiliary Inverters •UPSIGBT 1V CE(sat)I C =35A V GE =15V chiplevel T j =25°C 1.85 2.10V T j =150°C 2.25 2.45V V CE0chiplevel T j =25°C 0.800.90V T j =150°C 0.700.80V r CEV GE =15V chiplevelT j =25°C 3034m ΩT j =150°C4447m ΩV GE(th)V GE = V CE , I C =1.2mA5 5.8 6.5V I CES V GE =0V,V CE =1200V, T j =25°C 1mA C ies V CE =25V V GE =0Vf =1MHz 1.95nF C oes f =1MHz 0.155nF C res f =1MHz0.115nF Q G V GE =-15V ... +15V 258nC R Gint T j =25°C 0Ωt d(on)V CC =600V I C =35AV GE =+15/-15V R G on =8ΩR G off =8Ωdi/dt on =825A/µs di/dt off =438A/µs dv/dt =4865V/µsT j =150°C 17ns t r T j =150°C 30ns E on T j =150°C 2.61mJ t d(off)T j =150°C 232ns t f T j =150°C 69ns E off T j =150°C 2.85mJ R th(j-s)per IGBT, λpaste =0.8 W/(mK)0.96K/W R th(j-s)per IGBT, λpaste =2.5 W/(mK)0.67K/WCharacteristics SymbolConditionsmin.typ.max.UnitDiode 1V F I F =35A chiplevel T j =25°C 2.30 2.62V T j =150°C 2.29 2.62V V F0chiplevel T j =25°C 1.30 1.50V T j =150°C 0.90 1.10V r F chiplevelT j =25°C 2932m ΩT j =150°C4043m ΩI RRM I F =35A di/dt off =825A/µs V GE =-15VV CC =600VT j =150°C 25A Q rr T j=150°C5.5µC E rr T j =150°C 2.27mJ R th(j-s)per Diode, λpaste =0.8 W/(mK) 1.34K/W R th(j-s)per Diode, λpaste =2.5 W/(mK)1K/W© by SEMIKRONRev. 1.0–24.04.20203®E1IGBT moduleSK35GD12T4ETE1Features*•Low inductive design•Press-Fit contact technology•Rugged mounting due to integrated mounting clamps•Heat transfer and insulation through direct copper bonded aluminium oxide ceramic (DBC)•Trench4 IGBT technology•Robust and soft switching CAL4F diode technology•Integrated NTC temperature sensor •UL recognized file no. E 63 532Typical Applications•Motor drives •Servo drives •Air conditioning •Auxiliary Inverters •UPSModule M s to heatsink 1.62.3Nm wweight25gCharacteristics SymbolConditionsmin.typ.max.UnitTemperature Sensor R 100T r =100°C493 ± 5%ΩB 100/125R (T)=R 100exp[B 100/125(1/T-1/T 100)]; T[K];3550 ±2%K4Rev. 1.0–24.04.2020© by SEMIKRON© by SEMIKRON Rev. 1.0–24.04.202056Rev. 1.0–24.04.2020© by SEMIKRON© by SEMIKRON Rev. 1.0–24.04.20207This is an electrostatic discharge sensitive device (ESDS), international standard IEC 60747-1, chapter IX.*IMPORTANT INFORMATION AND WARNINGSThe specifications of SEMIKRON products may not be considered as guarantee or assurance of product characteristics ("Beschaffenheitsgarantie"). The specifications of SEMIKRON products describe only the usual characteristics of products to be expected in typical applications, which may still vary depending on the specific application. Therefore, products must be tested for the respective application in advance. Application adjustments may be necessary. The user of SEMIKRON products is responsible for the safety of their applications embedding SEMIKRON products and must take adequate safety measures to prevent the applications from causing a physical injury, fire or other problem if any of SEMIKRON products become faulty. The user is responsible to make sure that the application design is compliant with all applicable laws, regulations, norms and standards. Except as otherwise explicitly approved by SEMIKRON in a written document signed by authorized representatives of SEMIKRON, SEMIKRON products may not be used in any applications where a failure of the product or any consequences of the use thereof can reasonably be expected to result in personal injury. No representation or warranty is given and no liability is assumed with respect to the accuracy, completeness and/or use of any information herein, including without limitation, warranties of non-infringement of intellectual property rights of any third party. SEMIKRON does not assume any liability arising out of the applications or use of any product; neither does it convey any license under its patent rights, copyrights, trade secrets or other intellectual property rights, nor the rights of others. SEMIKRON makes no representation or warranty of non-infringement or alleged non-infringement of intellectual property rights of any third party which may arise from applications. Due to technical requirements our products may contain dangerous substances. For information on the types in question please contact the nearest SEMIKRON sales office. This document supersedes and replaces all information previously supplied and may be superseded by updates. SEMIKRON reserves the right to make changes.8。

thermometer q-exactive focus 技术参数-概述说明以及解释1.引言1.1 概述Thermometer Q-Exactive Focus是一种高性能质谱仪，具有出色的分析性能和精准的数据获取能力。

该设备采用了最先进的技术，能够在复杂样品的分析中提供高分辨率和高灵敏度。

本文将对Thermometer Q-Exactive Focus的技术参数进行详细介绍，包括其在分析实验中的应用和性能特点。

通过深入了解该设备的技术指标，读者可以更好地了解其在科研领域中的应用范围和潜力。

通过本文的阐述，读者将对Thermometer Q-Exactive Focus这一先进的质谱仪有一个全面的了解，为其在实验室研究和数据分析中的应用提供一定的参考和指导。

1.2 文章结构:本文主要分为三个部分，分别为引言、正文和结论。

在引言部分，将对thermomter q-exactive focus 技术进行概述，介绍文章的结构和目的。

在正文部分，将详细介绍该技术的三个主要参数，包括技术参数一、技术参数二和技术参数三。

通过对这些参数的详细解读，读者将能够更加全面地了解该技术的特点和优势。

在结论部分，将对整篇文章进行总结，展望该技术未来的应用前景，并给出一些结束语，以便读者对该技术有一个更加清晰的认识。

1.3 目的本文旨在详细探讨thermometer q-exactive focus的技术参数，通过对其进行分析和解释，帮助读者更好地了解该设备的功能和性能特点。

通过深入了解其技术参数，读者可以更好地选择适合自己需求的仪器，并更好地利用它们在科研实验和实际应用中的优势。

此外，通过对技术参数的解读，可以帮助用户更加熟练地操作和维护该设备，确保其稳定和可靠性，从而为科研工作提供有力的支持和保障。

2.正文技术参数一部分的内容如下：2.1 技术参数一：Thermometer Q-Exactive Focus是一款高性能质谱仪，具有以下关键技术参数：1. 分辨率：Thermometer Q-Exactive Focus的分辨率可达到超过140,000，这意味着它能够准确分析样品中的不同成分，并在复杂样品矩阵中提供高分辨率的分析结果。

1、适用仪器：丹麦雷度米特AQT90免疫荧光分析仪2、测定方法：双抗夹心法免疫检测——使用时间分辨免疫荧光法检测标志物: 铕螯合物复合体 (独特的荧光物质)通过标记的铕螯合物对双抗夹心复合物检测铕螯合物在340 nm的波长光时会被激发作为响应,铕螯合物会发出616 nm的激发光通过测量光强得到被测物的浓度3、"4、采样要求：样本类型全血 (在22-25 °C时候，最多3 小时)血浆样本(在 2-8 °C时候，最多24小时, 或冷冻)抗凝EDTA 肝素锂D-dimer 检测: EDTA, 肝素锂, 或柠檬酸盐样本用量~2 mL 样本放入试管4、耗材配套产品测试卡每个项目的测试卡包含最多16个测试杯可根据客户需要，对仪器加载最多15个试剂卡。

--最多240个测试测试卡具有较长的机上稳定性2-8 摄氏度冷藏有长期的稳定性.测试卡具有阅读条码，仪器能自动录入测试卡信息。

确保最小的更换测试卡所需要的时间处理包所有参数试剂使用同样的处理包一个处理包包含200个测试的废弃物1个月的机上稳定期室温储存即插即用!5、定标、系统检查定标定标频率：每次更换新批号的试剂后必须定标定标分析执行N点定标，N值视参数而定，详见定标卡说明书仪器根据定标卡获得结果和出厂定义数据，得到仪器该批号测试卡的特异曲线只有该批次的定标卡通过测试，该批次的测试卡才能被仪器使用.。

系统检查：检查的目的是自动运行检测，保证所有检测步骤顺利进行测量特定的光强度校正水平整个检测过程中所需的机械传动吸样针是否已冲洗干净加热温度是否处于37 °C ± °C在样本检测前后进行光学单位检查光学装置的高压符合要求与分析仪内置的参比荧光样本进行衰减时间比对，不能超过所设定的厂家标准值范围!闪光灯强度不能超过所设定的厂家标准值的范围孵育时间是否符合要求振荡时间是否符合要求样本干燥前后检查干燥温度以及检查干燥气流吸样针穿刺是否到达样本管最多穿刺数所安装的软件是否正确每次测试的样本是否足够系统测定的红细胞比积是否符合要求。

Specifications Sheet Integritest® 5 InstrumentCatalog Number: IT5INS001Includes:• North American power cord• TTU International Power Cable, IP54• Male Staubli to 1.5" TC End Cap• Male Staubli to 3/4" TC End Cap• Inlet Tubing Assembly• Outlet Tubing Assembly• Internal Printer Paper (3 pack)• CE Declaration of Conformity• Certificate of Quality• Operator and Equipment Safety Guide• Quick-start GuideThe life science business of Merckoperates as MilliporeSigma in theU.S. and Canada.Power Cable:Please order your local power cable in addition to the instrument.Power Cord North America (included in IT5INS001)P83065 Power Cord Japan P83066 Power Cord Australia, NZ P83067 Power Cord UK, IE, HK, SG P83068 Power Cord Western Europe AT, BE, FR, FI, DE, GR, NO, NL, PL, PT, ES, SE P83069 Power Cable Argentina PWRCABLEAR Power Cable Brazil PWRCABLEBR Power Cable Switzerland PWRCABLECH Power Cable China PWRCABLECN Power Cable Denmark PWRCABLEDK Power Cable Italy PWRCABLEIT Power Cable South Korea PWRCABLEKR Power Cable Taiwan PWRCABLETW Power Cable South Africa, India, Pakistan PWRCABLEZAMaterials Of Construction• Polyurethane tubing• Stainless steel• Aluminum chassis• Solid state silicon device• Lithium battery• Copper wire• Piezo-electronic polymerThe flow path does not contain animal content.Design PropertiesPhysical CharacteristicsHeight: 9.1 inches (23.1 cm)Width: 15.4 inches (39.1 cm)Depth: 17.0 inches (43.2 cm)Weight: 10.5 kg2Hardware• Pressure regulators and sensors–Inlet pressure regulator (voltage controlled, 2 to 105 psig)–Tank Pressure Sensor (Gauge transducer, 0 to 102 psig)–Housing Pressure Sensor (Absolute transducer, 0 to 117 psia)• Internal tank (predetermined gas volume reference)–Stainless steel cylinder tank (500 cc nominal)UI Computer• Computer operating system: Windows® 10• Computer solid state drive ≥ 64GB nominal• Computer RAM: ≥ 4GB, shared with video• Computer CPU: AMD Embedded G-Series, 1.6 GHz or fasterUI Display• Tilt angle (screen face of system): 20° (stand down); 34° (stand up)• D isplay type: Color active matrix TFT LCD, LED backlighted, projected capacitive touch interface• Display size: 10.1 in nominal diagonal• Display resolution: 1024 × 600 pixels (WSVGA)• D isplay Viewing angle: ±45° typical (90° total), horizontal; –15° +35° typical (50° total), verticalPrinter• Printer type: Direct thermal• Print Speed Up to 5.2 Lines per Second• Serial data input• 3 in. Plain PaperTest Module Controller• Windows® CE operation systems• I/O board with built-in A/D and D/A convertersMain Power Supply• 100-240 Vac; 50/60Hz3Pneumatic Ports• Staubli male connector for pressure inlet supply• Rectus male connector for upstream filter connection• Female tube connector for pneumatic exhaustCommunication Ports• 2 USB communication• 1 RJ45 Ethernet portSoftware Design PropertiesUser role access rights• Operators: run tests, print reports, and sign reports• Supervisors: Operator + sign reports as the second electronic signature (optional)• Service: Operator + editing, settings, tools, and calibration• Instrument managers: Service + sign reports as the second electronic signature (optional)• Administrators: Instrument manager + Windows® accessMulti-Language UI Support• Chinese Simplified• English• French• German• Italian• Japanese• Korean• Portuguese• SpanishPerformance PropertiesOperationalThe instrument is designed to operate in a pharmaceutical manufacturing plant, including designed to support wet rooms and clean room standards for low particulate levels.• Ambient Temperature: 1 to 40 ºC.• Ambient Humidity: 50% at 40 ºC to 80% at 31 ºC non-condensing• Altitude: –80 to 2000 meters• A tmospheric pressure: Hardware has been designed so that atmospheric pressure fluctuation of ± 0.1 inches water does not provide a false positive test result.• Ingress Protection Rating: The instrument is compliant to IP54• Noise level: 24 dB average, 65 dB maximum during exhaust step at 1m from front of instrument4Non-Operational• Ambient Temperature: –20 to 60 ºC• Ambient Humidity: 10% to 90% non-condensing• Shipping Validation: meets ISTA 2A packaged products partial simulation testing requirements• External surfaces are compatible with the following sanitizing agents:–Hydrogen peroxide (3%)–Quaternary Ammonium Compounds (0.2%)–Formaldehyde (37%)–Alcohol (isopropyl alcohol) (70%)–Sodium Hypochlorite (NaOCl) (5.2%)–Sodium Hydroxide (NaOH) (2%)–Spor-Klenz®TestsTest accuracy (at standard and stable conditions):Diffusion Flow rates < 20 mL/min (water)± 1 mL/minFlow rates ≥ 20 mL/min (water)± 5%Flow rates < 20 mL/min (alcohol)± 2 mL/minFlow rates ≥ 20 mL/min (alcohol) ± 10%Bubble Point 5 – 90 psig ± 1 psigBubble Point Asymmetric 5 – 90 psig± 5 psigHydroCorr™ Test Flow rates < 0.4 mL/min ± 0.02 mL/minFlow rates ≥ 0.4 mL/min ± 5%Virus Diffusion Flow rates < 20 mL/min ± 2 mL/minFlow rates ≥ 20 mL/min± 10%Pressure Hold Pressure drops < 1 psig± 0.05 psigPressure drops ≥ 1 psig± 5%Test reproducibility (coefficient of variation, CV or standard deviation, sn-1):Diffusion Flow rates < 20 mL/min sn-1 ≤ 2 mL/minFlow rates ≥ 20 mL/min CV ≤ 10%Bubble Point 5 – 90 psig CV ≤ 10%HydroCorr™ Test Flow rates < 0.4 mL/min sn-1 ≤ 0.04 mL/minFlow rates ≥ 0.4 mL/min CV ≤ 10%Virus Diffusion Flow rates < 20 mL/min sn-1 ≤ 2 mL/minFlow rates ≥ 20 mL/min CV ≤ 10%Pressure Hold Pressure drops < 1 psi sn-1 ≤ 0.l psiPressure drops ≥ 1 psi CV ≤ 10%5The Integritest® 5 Instrument operates within the listed specifications for:Diffusion47 mm disks – 12 round × 30” systems Diffusion rate: 0.5 – 600 mL/minTest pressure: 5 – 95 psigBubble Point13 mm disks – 3 round × 30” systems Test pressure: 5 – 90 psig HydroCorr™ Test47 mm disks – 3 round × 30” systems Test pressure: 5 – 90 psigFlow rate: 0.01 – 10 mL/minVirus Diffusion25 mm disks – 12 round × 30” system Diffusion rate: 0.5 – 600 mL/minTest pressure: 5 – 95 psigPressure Hold0.1 – 100L without pre-pressurization Test pressure: 5 – 60 psig Operational RequirementsElectrical• 100-240 Vac; 50/60Hz• Fuse type 2A, 5×20 mmGas Supply• C lean dry air• Maximum inlet pressure: 120 psi• Minimum inlet pressure: 15 psi greater than the test pressure is recommendedSpare Part NumbersMale Staubli to 3/4" TC End Cap IT5SP0001 3/8" Barb Filter Test Accessory Kit IT5SP0002 Housing Interface Module (HIM) Assembly IT5SP0003 Housing Interface Module (HIM) Cleaning Fixture IT5SP0004 Adapter Kit, 9/16 HB, 5/8 HB, 1/4 NPTM IT5SP0005 Male Staubli to 1.5" TC End Cap IT5SP0006 TTU International Power Cable IT5SP0007 Inlet Tubing Assembly IT5SP0008 Outlet Tubing Assembly IT5SP0009 Calibration Token IT5SP0010 Fuse Glass 2A 250VAC 5×20MM IT5SP0012 Cover, Tube Storage IT5SP0013 F1 Filter Assembly, Water Trap IT5SP0014 Inline Pneumatic Filter Assy IT5SP0015 Ancillary material kit - Collection of all Power Cords, Hoses, etc. that comes standard with Integritest® 5 Instrument IT5SP0016 Packaging Kit - Spare Set of Shipping Boxes/Foam IT5SP0017 Transport Kit - Hard-shell-type carrying case IT5SP0018 Spare Part, Integritest Thermal Paper XIT4TPRTP3 Spare Tubing, 100 ft XITXSP1806Regulatory InformationCopyright information• M icrosoft® License agreement: The Integritest® 5 Instrument includes a Microsoft® license, which pertains to the Microsoft® operating system.Regulatory and Safety:• T he Integritest® 5 instrument was developed and validated according to GAMP5 Guidelines.• D esigned to support 21 CFR Part 11 compliance, the Integritest® 5 instrument captures electronic data and allows the data to be printed, but protects against access and manipulation by the end user. An Integritest®5 test report should be printed, signed and dated immediately after test completion and used for regulatory activities. Reports and signatures cannot be altered. By validating the system and implementing procedural controls, the Integritest® 5 instrument can be implemented and operated in compliance with FDA regulations.• This product is CE marked to self-declare compliance to the applicable European directives through the use of EN compliance standards. Please refer to the products Declaration Of Conformity for further details.• This product meets the electrical safety requirements for North America through the application of UL/CSA 61010-1 3rd edition for Electrical Equipment for Measurement, Control, and Laboratory Use - Part 1: General requirements. The product has also been evaluated to the international equivalent IEC 61010-1 3rd edition standard.• This device complies with part 15 of the FCC Rules. Operation is subject to the following two conditions: (1) This device may not cause harmful interference, and (2) this device must accept any interference received, including interference that may cause undesired operation. EMC part: CFR Title 47 Part 15 subpart B Class Afor USA; ICES-003, issue 5, Class A for Canada and IEC as certified according CB scheme (registration number DE3-30198) 61326-1:2013; EN55011 2009/2010 A1 class A for EU• This device is an unintentional radiator. Please be aware that changes or modifications not expressly approved by the party responsible for compliance could void the user's authority to operate the equipment.7© 2020 Merck KGaA, Darmstadt, Germany and/or its affiliates. All Rights Reserved. Merck, the vibrant M, Millipore, and Integritest are trademarks of Merck KGaA, Darmstadt, Germany or its affiliates. All other trademarks are the property of their respective owners. Detailed information on trademarks is available via publicly accessible resources.Lit. No. MK_SP5735EN Ver. 1.02018 - 1044901/2020For additional information, please visit . To place an order or receive technical assistance, please visit /contactPS Merck KGaAFrankfurter Strasse 250 64293 Darmstadt, Germany。

无线远程温湿度采集终端TSM-05TH技术规格书陕西拓普索尔电子科技有限责任公司（版本号V3.0）安全使用注意事项：●收到产品后请检查包装及外形是否完好，并核对型号是否与购买产品相符；●产品使用工作环境：-20~+70℃(温度)，0%~90%RH无结露(湿度)；●网络环境：CSQ≥12，并且可以正常通信；●安装时请保持安装区域清洁干净，并保持干燥，固定牢固；●安装后请勿强力拆卸，否则容易损坏产品；●请妥善保存全部原包装材料，以便出现问题时，使用包装材料将产品包装好，寄到厂家处理。

非原包装材料导致的运输途中的意外损坏，本公司不承担任何责任。

●本产品严禁开盖操作；●在安装本产品时，请远离高温易燃易爆区；●远离磁场干扰区域；●不能暴露安装在可能淋到雨的地方；●如产品出现非正常现象，请及时联系公司售后技术人员维修处理（对未经认可的修改或维修导致的问题，本公司不承担任何责任）。

为了安全使用本装置，请您在使用前务必详读本操作手册，在详读理解后，将其保管在指定场所，以备随时阅览。

目录第1章设备概要 (3)1.1前言 (3)1.2特点 (3)1.3技术参数 (4)第2章产品描述 (5)2.1产品外观 (5)2.2产品尺寸 (6)2.3屏幕尺寸 (6)第3章操作设备 (7)3.1数据采集及发送 (7)3.2远程设置参数 (7)3.3IoT平台界面...................................................................................错误！未定义书签。

第4章组网工作示意图. (8)第5章常见故障及解决方法 (9)第6章声明 (10)第1章设备概要1.1前言TSM-05TH无线远程温湿采集终端是一款锂亚电池供电、具有无线通讯功能的智能温湿度采集设备，主要应用领域是冷链运输、电讯电力机房、食品药品安全、化工医药、大型超市、供暖等场合进行温度、湿度监测，将设备的电量、信号强度、监测区域的温度信息、湿度信息告警信息等数据通过无线网络实时发送给监控中心，监控中心对数据进行存储、分析、查询、告警信息处理，实现信号无线传输、信息交互，无需现场布线，节省了人力及施工成本，帮助用户实现对监测区域温度、湿度及时、高效的监管。

上海贝特产品性能指标说明一、分支分配器指标一分支器 (BTT1XXE)项目参数分支损耗(dB)标称值06 08 10 12 14 16 18 20 典型值(允许偏差)5MHz ± 0.5 6.5 7.5 10.6 12.4 13.6 15.8 18.2 20.310MHz ± 0.5 6.5 7.5 10.6 12.4 13.8 15.8 18.2 20.350MHz ± 0.5 6.5 7.5 10.6 12.3 13.9 15.9 18.2 20.4750MHz ± 0.7 6.5 7.5 10.4 12.2 14.0 16.4 17.8 20.21000MHz ± 1.0 6.5 7.7 10.5 12.1 14.5 16.5 17.8 20.0插入损耗(dB)5MHz ≤ 2.6 ≤ 2.3 ≤ 1.5 ≤ 1.2 ≤ 1.1 ≤ 0.8 ≤ 0.7 ≤ 0.7 10MHz ≤ 2.6 ≤ 2.4 ≤ 1.4 ≤ 1.2 ≤ 1.0 ≤ 0.7 ≤ 0.6 ≤ 0.6 50MHz ≤ 2.6 ≤ 2.5 ≤ 1.4 ≤ 1.2 ≤ 0.9 ≤ 0.7 ≤ 0.6 ≤ 0.6 750MHz ≤ 3.0 ≤ 2.6 ≤ 1.5 ≤ 1.2 ≤ 1.0 ≤ 0.7 ≤ 0.7 ≤ 0.7 1000MHz ≤ 3.3 ≤ 2.8 ≤ 1.7 ≤ 1.6 ≤ 1.1 ≤ 0.9 ≤ 0.9 ≤ 0.9反向隔离(dB)5-10MHz ≥ 27 10-1000MHz ≥ 27反射损耗(dB)5-10MHz ≥ 16 10-1000MHz ≥ 18二分支器 (BTT2XXE)项目参数分支损耗(dB)标称值08 10 12 14 16 18 20 22 24 典型值( 允许偏差 )5MHz ± 0.5 7.0 10.5 11.8 14.0 16.0 17.8 19.8 22.1 24.010MHz ± 0.5 7.0 10.5 11.5 14.0 16.0 17.8 20.0 22.0 23.850MHz ± 0.5 7.0 10.5 11.5 13.8 16.0 17.9 20.0 22.0 23.8750MHz ± 0.7 7.4 10.7 11.9 13.8 16.0 17.9 20.8 22.4 24.01000MHz ± 1.0 7.8 10.8 12.0 13.6 16.0 18.5 20.8 22.4 24.0插入损耗(dB)5MHz ≤ 3.7 ≤ 2.6 ≤ 1.7 ≤ 1.3 ≤ 1.0 ≤ 1.0 ≤ 0.9 ≤ 0.8 ≤ 0.8 10MHz ≤ 3.5 ≤ 2.4 ≤ 1.5 ≤ 1.3 ≤ 1.0 ≤ 1.0 ≤ 0.7 ≤ 0.7 ≤ 0.7 50MHz ≤ 3.6 ≤ 2.5 ≤ 1.6 ≤ 1.3 ≤ 1.0 ≤ 0.9 ≤ 0.7 ≤ 0.7 ≤ 0.7 750MHz ≤ 3.9 ≤ 2.6 ≤ 1.7 ≤ 1.4 ≤ 1.2 ≤ 0.9 ≤ 0.8 ≤ 0.8 ≤ 0.7 1000MHz ≤ 4.2 ≤ 2.9 ≤ 2.1 ≤ 1.6 ≤ 1.4 ≤ 1.1 ≤ 1.0 ≤ 0.9 ≤ 0.9反向隔离(dB)5-10MHz ≥ 27 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 27 10-1000MHz ≥ 28三分支器 (BTT3XXE)项目参数分支损耗(dB)标称值10 12 14 16 18 20 22 24 典型值( 允许偏差 )5MHz ± 0.5 8.9 12.7 14.7 16.0 18.0 20.0 21.6 24.010MHz ± 0.5 8.6 12.7 14.7 16.0 18.0 20.0 21.6 24.050MHz ± 0.5 8.6 12.7 14.7 16.0 17.9 20.0 21.6 24.0750MHz ± 1.0 9.3 12.8 14.4 15.5 17.5 20.0 22.1 24.61000MHz ± 1.0 9.8 12.9 14.7 15.3 17.4 19.8 21.7 24.1插入损耗(dB)5MHz ≤ 3.7 ≤ 2.6 ≤ 1.8 ≤ 1.4 ≤ 1.2 ≤ 1.0 ≤ 0.8 ≤ 0.8 10MHz ≤ 3.5 ≤ 2.4 ≤ 1.8 ≤ 1.4 ≤ 1.2 ≤ 1.0 ≤ 0.7 ≤ 0.7 50MHz ≤ 3.6 ≤ 2.5 ≤ 1.8 ≤ 1.4 ≤ 1.2 ≤ 0.9 ≤ 0.7 ≤ 0.7 750MHz ≤ 3.9 ≤ 2.6 ≤ 2.2 ≤ 1.6 ≤ 1.2 ≤ 0.9 ≤ 0.8 ≤ 0.8 1000MHz ≤ 4.2 ≤ 3.0 ≤ 2.6 ≤ 1.8 ≤ 1.4 ≤ 1.1 ≤ 0.9 ≤ 0.9反向隔离(dB)5-10MHz ≥ 27 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 27 10-1000MHz≥ 28反射损耗(dB)5-10MHz ≥ 16 10-1000MHz≥ 18四分支器 (BTT 4XXE)项目参数分支损耗(dB)标称值10 12 14 16 18 20 22 24 典型值( 允许偏差 )5MHz ± 0.5 10.2 12.7 14.5 16.4 18.1 20.0 22.0 24.010MHz ± 0.5 10.0 12.5 14.4 16.2 18.0 20.0 22.0 23.850MHz ± 0.5 9.8 12.5 14.3 16.2 18.0 20.0 22.0 23.8750MHz ± 0.7 10.5 12.6 14.5 16.3 18.2 20.5 22.8 24.21000MHz ± 1.0 11.5 12.8 14.7 16.6 18.4 20.9 22.9 24.0插入损耗(dB)5MHz ≤ 3.6 ≤ 3.3 ≤ 2.2 ≤ 1.8 ≤ 1.4 ≤ 1.2 ≤ 0.9 ≤ 0.8 10MHz ≤ 3.5 ≤ 3.3 ≤ 2.2 ≤ 1.8 ≤ 1.3 ≤ 1.0 ≤ 0.8 ≤ 0.7 50MHz ≤ 3.6 ≤ 3.4 ≤ 2.1 ≤ 1.8 ≤ 1.3 ≤ 0.9 ≤ 0.8 ≤ 0.7 750MHz ≤ 3.9 ≤ 3.5 ≤ 2.4 ≤ 1.9 ≤ 1.5 ≤ 1.0 ≤ 0.8 ≤ 0.8 1000MHz ≤ 4.2 ≤ 3.7 ≤ 3.0 ≤ 2.3 ≤ 1.7 ≤ 1.3 ≤ 1.0 ≤ 0.9反向隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28五分支器 (BTT5XXE)项目参数分支损耗(dB)标称值12 14 16 18 20 22 24 典型值( 允许偏差 )5MHz ± 0.7 11.9 14.2 15.9 18.3 20.0 21.9 24.010MHz ± 0.7 11.8 14.0 15.9 18.2 20.0 21.8 24.050MHz ± 0.7 11.7 14.0 15.9 18.2 19.8 21.7 24.0750MHz ± 1.0 12.7 14.5 16.2 18.3 19.8 22.0 24.11000MHz ± 1.5 13.3 14.8 16.6 18.3 20.0 22.3 24.5插入损耗(dB)5MHz ≤ 3.7 ≤ 3.4 ≤ 2.1 ≤ 1.8 ≤ 1.2 ≤ 1.1 ≤ 0.9 10MHz ≤ 3.5 ≤ 3.3 ≤ 1.9 ≤ 1.8 ≤ 1.2 ≤ 1.0 ≤ 0.8 50MHz ≤ 3.5 ≤ 3.3 ≤ 1.8 ≤ 1.8 ≤ 1.2 ≤ 0.9 ≤ 0.8 750MHz ≤ 3.9 ≤ 3.6 ≤ 2.8 ≤ 2.0 ≤ 1.4 ≤ 1.0 ≤ 1.0 1000MHz ≤ 4.1 ≤ 3.8 ≤ 3.0 ≤ 2.4 ≤ 1.6 ≤ 1.3 ≤ 1.2反向隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28反射损耗(dB)5-10MHz ≥ 16 10-1000MHz ≥ 18六分支器 (BTT6XXE)项目参数分支损耗(dB)标称值12 14 16 18 20 22 24 典型值( 允许偏差 )5MHz ± 0.7 11.9 14.2 15.9 18.3 20.0 21.9 24.010MHz ± 0.7 11.8 14.0 15.9 18.2 20.0 21.8 24.050MHz ± 0.7 11.7 14.0 15.9 18.2 19.8 21.7 24.0750MHz ± 1.0 12.7 14.5 16.2 18.3 19.8 22.0 24.11000MHz ± 1.5 13.3 14.8 16.6 18.3 20.0 22.3 24.5插入损耗(dB)5MHz ≤ 3.7 ≤ 3.4 ≤ 2.1 ≤ 1.8 ≤ 1.2 ≤ 1.1 ≤ 0.9 10MHz ≤ 3.5 ≤ 3.3 ≤ 1.9 ≤ 1.8 ≤ 1.2 ≤ 1.0 ≤ 0.8 50MHz ≤ 3.5 ≤ 3.3 ≤ 1.8 ≤ 1.8 ≤ 1.2 ≤ 0.9 ≤ 0.8 750MHz ≤ 3.9 ≤ 3.6 ≤ 2.8 ≤ 2.0 ≤ 1.4 ≤ 1.0 ≤ 1.0 1000MHz ≤ 4.1 ≤ 3.8 ≤ 3.0 ≤ 2.4 ≤ 1.6 ≤ 1.3 ≤ 1.2反向隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28八分支器 (BTT8XXE)项目参数分支损耗(dB)标称值14 17 20 23 26 典型值( 允许偏差 )5MHz ± 0.7 13.4 16.7 20.2 23.0 25.610MHz ± 0.7 13.4 16.7 20.1 23.0 25.650MHz ± 0.7 13.2 16.7 20.0 23.0 25.6750MHz ± 1.5 14.2 17.4 20.4 23.6 25.71000MHz ± 1.5 15.0 17.7 20.6 23.9 26.0插入损耗(dB)5MHz ≤ 3.7 ≤ 2.6 ≤ 1.2 ≤ 1.1 ≤ 0.9 10MHz ≤ 3.5 ≤ 2.4 ≤ 1.2 ≤ 1.0 ≤ 0.8 50MHz ≤ 3.5 ≤ 2.5 ≤ 1.2 ≤ 0.9 ≤ 0.8 750MHz ≤ 3.9 ≤ 2.6 ≤ 1.4 ≤ 1.1 ≤ 1.0 1000MHz ≤ 4.2 ≤ 3.0 ≤ 1.8 ≤ 1.3 ≤ 1.2反向隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28相互隔离(dB)5-10MHz ≥ 28 10-1000MHz ≥ 28反射损耗(dB)5-10MHz ≥ 16 10-1000MHz ≥ 18二分配器 (BTS204E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 3.8 ≥ 27 ≥ 1610-50 ≤ 3.8 ≥ 28 ≥ 1850-750 ≤ 3.9 ≥ 28 ≥ 18750-1000 ≤ 4.2 ≥ 28 ≥ 18三分配器 (BTS306E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 5.7 ≥ 27 ≥ 1610-50 ≤ 5.5 ≥ 28 ≥ 1850-750 ≤ 6.2 ≥ 28 ≥ 18750-1000 ≤ 6.6 ≥ 28 ≥ 18四分配器 (BTS408E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 7.2 ≥ 27 ≥ 1610-50 ≤ 7.0 ≥ 28 ≥ 1850-750 ≤ 7.8 ≥ 28 ≥ 18750-1000 ≤ 8.2 ≥ 28 ≥ 18四分配器 (BTS408EA)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 7.2 ≥ 27 ≥ 1610-50 ≤ 7.0 ≥ 28 ≥ 1850-750 ≤ 7.8 ≥ 28 ≥ 18750-1000 ≤ 8.2 ≥ 28 ≥ 18四分配器 (BTS408EB)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 7.2 ≥ 27 ≥ 1610-50 ≤ 7.0 ≥ 28 ≥ 1850-750 ≤ 7.8 ≥ 28 ≥ 18750-1000 ≤ 8.2 ≥ 28 ≥ 18五分配器 (BTS509E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 8.8 ≥ 27 ≥ 1610-50 ≤ 8.8 ≥ 28 ≥ 1850-750 ≤ 9.3 ≥ 28 ≥ 18750-1000 ≤ 10.0 ≥ 28 ≥ 18六分配器 (BTS610E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 8.9 ≥ 27 ≥ 1610-50 ≤ 8.8 ≥ 28 ≥ 1850-750 ≤ 9.9 ≥ 28 ≥ 18750-1000 ≤ 10.5 ≥ 28 ≥ 18八分配器 (BTS812E)频率范围（ MHz ）分配损耗（ dB ）隔离（ dB ）反射损耗（ dB ）5-10 ≤ 10.8 ≥ 27 ≥ 1610-50 ≤ 10.8 ≥ 28 ≥ 1850-750 ≤ 11.5 ≥ 28 ≥ 18750-1000 ≤ 12.5 ≥ 28 ≥ 18二、射频传输放大设备BTIA4000系列放大器技术指标特点：1,BTIA4000系列放大器是吸收了国外最新同类产品的长处，为有线电视系统研制的放大设备。

SmartLine简介作为SmartLine ®产品系列的成员，STF800是一种采用先进传感器技术的高性能单法兰变送器。

STF800变送器可以直接安装到设备法兰上，并有多种平法兰和凸法兰可供选择。

STF800可在多种差压测量中提供极高的测量精确度和稳定性。

SmartLine 系列还经过了充分测试，符合Experion ® PKS 标准，可提供最高水平的兼容性保证和集成能力。

SmartLine 产品可轻松满足差压测量应用的最苛刻的要求。

同类最佳的特性：● 校验量程的精度高达0.0375%● 每年的稳定性高达0.015%/满量程，保持10年● 自动静压和温度补偿● 高达100:1的量程比● 响应时间快达90ms ● 多种本地显示功能● 外部零位、量程和组态功能● 电源极性任意连接● 完善的自诊断功能●基于ANSI/NFPA 70-202和ANSI/ISA 12.27.0集成双重密封设计，可确保最高安全性● 世界一流的过压保护● 标准配置完全符合SIL2/3要求● 全模块设计●最长可提供15年保修量程和范围限制：型号量程上限URLKPa量程下限LRLKPa最大量程KPa 最小量程KPa STF828 100-1001001STF82F 100-1001001STF832 700-7007007STF83F700-7007007图1 STF800单法兰变送器有丰富现场业绩的传感器技术通讯/输出选项：●4-20mA dc●霍尼韦尔数字增强(DE)● HART ®(7.0 版本)●FOUNDATION™ Fieldbus所有压力变送器均可配备以上所列通讯协议。

描述SmartLine系列的压力变送器均基于高性能的传感器设计。

这一个传感器实际集成了多个传感器，将过程压力测量与静态压力(DP型号)及温度补偿测量相结合，从而实现了最佳的总体性能。

这一性能使得SmartLine成为几乎可以替代任何现有变送器的竞争产品。