2013r年滨州市继续教育复习题答案(正确率80%)

第50卷第5期2021年5月应用化工Applied Chemical IndusWyVoe.50No.5May2021 Ziegler-Natta催化体系下超高分子量聚辛烯的合成及其减阻应用李隆伟1，李东城1，唐萍1，赵巍2,王海S牛慧1，宾月珍1（1-大连理工大学化工学院高分子材料系，辽宁大连112024；2.中国石化大连石油化工研究院，辽宁大连116045）摘要:在Zieyler-OaLa催化体系TG//A1（i-Tu）3下合成超高分子量聚辛烯,探索了催化剂、溶剂、聚合温度、聚合时间对分子量的影响。

结果表明，优选合成高分子量聚辛烯的条件为:主催化剂相对单体浓度1.0mg/mL，助催化剂为三异丁基铝TIEA，A1-Ti比为80,溶剂为环己烷，单体与溶剂体积比为1：1.5，聚合温度为0t,聚合时间为48h,产物特性粘度能达到13.7dkg,在柴油中添加量为10mg/L时,减阻率16.7%,接近国外进口产品。

关键词:Zieyler-NaLa催化剂;聚辛烯;减阻剂漩转圆盘中图分类号:TQ317；O632文献标识码:A文章编号：1671-3206（2021）05-1315-05Synthesis of ultra-high moleciilar weight poly-a-octene byZnegeer1Na ea caeaeysnsandnesdrag reducenonappencaenonLI Long-Cei,LI Dong-cheng1,TANG Ping1,ZHA0Wei2,WANG Hai1,NIU Hui1,BIN Yue-zhen1(1.Department oZ Polymer Science and Enginee/ng,School oZ Chemical Enginee/ng,Dalian Undeoity of—6—20X00, Dalian112024,China；2.SINOPEC Dalian Research Institute oZ Petroleum and Petrochemicals,Dalian116045,China)Abstract:Poly-o-actena was synthesized by Zieyler-Oatty catalyst.The elects of catalyst,solvent,poly-meeoeatoon tempeeatueeand poeymeeoeatoon tomeon themoeecueaeweoghtoNthepeoductweeeoneestogated. Theeesuetshowed thatoptomaecondotoons oethesynthesosoNpoey---octenewoth uetea-hogh moeecueae weoghtweeeaso e o ws:theconcenteatoon oNthemaon cataeysteeeatoeetothemonomeewas1.0mgLmL,the ca-cytalysi was tcisobutyl aluminum(TINA),and the AUTi ratio was80;the solvent was cyclohexyna, and the volume ratio of monomer to solvent was1:1.5;the polyme/zation temperature G0t and the poeym*eoeatoon tom*wasconteo e d foe48h.Th*chaeact eostoc eoscosoty ofpeoduct each*d13.7dLLg. Th*deageductoon eat each*d16.7%wh*n th*addotoe*amountwas10mgLL.Key words:Ziegler-Natty catalyst;poly-o-actena；dog reduction agent；rotating disk目前Ziegler-Natty催化体系下，关于乙烯、丙烯聚合的研究较多（1O）,而更长链的超高分子量聚-烯炷研究较少,如己烯、辛烯、癸烯等。

硅氧烷蛋白质共聚物
刘钊
【期刊名称】《北京日化》
【年(卷),期】1996(000)001
【总页数】3页(P40-42)
【作者】刘钊
【作者单位】无
【正文语种】中文
【中图分类】TQ658.2
【相关文献】
1.1,3,5-三(甲基三氟丙基)环三硅氧烷/六甲基环三硅氧烷共聚物的合成与表征 [J], 杨波;赵柯;田军昊;包永忠;黄志明
2.以聚苯基倍半硅氧烷—聚二甲基硅氧烷嵌段共聚物为基础的硫化胶之性能 [J], 王惠中
3.氟硅氧烷-二甲基硅氧烷共聚物低温性能的研究 [J], 苏正涛;刘君;孔毅;王洪锐
4.苯基倍半硅氧烷-二甲基硅氧烷共聚物阻燃剂的制备与应用 [J], 梁广财;刘述梅;叶华;赵建青;张利萍
5.聚二甲基硅氧烷一苯基倍半硅氧烷共聚物及其弹性体：Ⅱ共聚物流动性和… [J], 胡春野;郭哲
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SZ-100Particle Size AnalyzerAN206 Using the SZ-100 Autotitrator to fi nd Isoelectric Point (IEP)The isoelectric point, IEP, of a colloidal system is determined automatically with the SZ-100 and Autotitrator from HORIBA Instruments. Zeta potential data as a function of pH is collected while the author is drinking coffee and writing support documents.IntroductionZeta potential is the charge on a particle at the shear plane. This value of surface charge is useful for understanding and predicting interactions between particles in suspension. A large magnitude (either positive or negative), that is, over about 25 mV, zeta potential is generally considered an indication that the particle suspension will be electrostatically stabilized. Zeta potential can be measured with the HORIBA SZ-100-Z shown in Figure 1.Figure 1: SZ-100 Nanoparticle AnalyzerZeta potential is a function of both the particle surface chemistry and the suspending medium chemistry (1). The ions that are at the particle surface and controlling surface potential are a function of the concentration and nature of the ions in the bulk liquid. In addition, the concentration of ions affects the distance over which charge effects persist. For example, a signifi cant amount of dissolved salt will shield the electrostatic interactions between particles. Some ions, known as specifi c ions will prefer to stick to the particle surface as the concentration of these ions increases. Examples of specifi c ions include H+ and polyvalent ions. In this work, the effect of H+ concentration on particle surface charge is studied. Other examples on the effect of various ion concentrations can be found in (2) and (3). T ypically, and for good reason, H+ concentration is discussed in terms of pH. pH has a strong effect on the surface charge of many types of particles. In addition, pH is a parameter that is often and readily changed in a formulation. For these reasons, the effect of pH on particle surface charge is often studied. One number that characterizes a surface is the isoelectric point, IEP, or point of zero charge, PZC, which refers to the conditions, often pH, at which the particle surface charge is zero. At pH values lower than the IEP, the particle surface charge is positive and at pH values higher than the IEP, the particle surface charge is negative. One rule of thumb for stable suspensions is to ensure that the pH is one full pH unit away from the IEP. Values of IEP are obtained by measuring the zeta potential as a function of pH and identifying the pH at which the zeta potential value crosses zero. In most cases this is achieved by interpolating the experimental data. T extbook values of IEP are often not useful for practical work since the value of IEP can change dramatically with even a small amount of impurity that is driven to the sample surface. IEP measurement results can also be affected by incomplete particle surface wetting or by the choice of surfactants. For example, adding TSPP to a metal oxide suspension will cause the IEP to shift to extremely low pH values or disappear altogether. For these reasons, IEP values are typically measured and that is a process that can be automated. The automation of isoelectric point measurement is achieved with the HORIBA Autotitrator accessory for theFigure 2:Autotitrator accessory for the SZ-100Page 2/2SZ-100 shown in Figure 2. The Autotitrator automatically adds acid or base to adjust the pH of the sample, records pH, and loads the sample into the graphite electrode cell in the SZ-100. Zeta potential is then determined and the cycle is automatically repeated for the next pH in the series.Materials and Methods Arti fi cial coffee creamer was diluted until slightly cloudy in DI water. Sample pH was automatically decreased to pH 2 and then increased stepwise with the HORIBA Autotitrator. Zeta potential was measured with the reusable graphite electrode cell in the HORIBA SZ-100Z nanoparticle analyzer. Sample pH was measured with the HORIBA 9621C temperature-compensated pH electrode. In this study, 100 mM nitric acid and 100 mM sodium hydroxide were used as the acid and base reagents respectively. The Autotitrator reagent containers include provision for molecular sieve treatment of incoming air that replaces removed titrant. The 5 mL burettes precisely deliver the reagents without bubbles eliminating the need for degassing. The smallest reagent dose that can be delivered manually is 0.0025 mL. The Autotitrator was set up in the software via a wizard type interface as shown in Figure 3 below. T he available manual mode was not used in this study.Figure 3: Screen Shot of Autotitratorsetup screen in the software.The pH probe was fi lled and calibrated using HORIBA standard solution set 101-S. After cleaning, it was held in place over the sample beaker with an integrated ring stand. The integrated stir plate mixed the sample as reagent was automatically delivered. When the target pH was reached, a peristaltic pump rinsed the zeta potential cell and delivered the sample for measurement. The zeta potential was measured in triplicate and pH monitored for drift during measurement. Then, the cycle was repeated for the next pH in the series.Results and DiscussionThe zeta potential of the coffee powder suspension as a function of pH is shown in Figure 3 below. From pH 2 to pH3, the zeta potential value of the coffee creamer emulsion increases. This is probably due to speci fi c shifts in the structure of the emulsion at low pH. From pH 3 to pH 11, the shape of the curve is the classical backwards S shape. At low pH, the particle charge is positive due to the large H + ion concentration. At high pH, the particle charge is negative due to the large OH- ion concentration. The obtained valueof the isoelectric point where the zeta potential crosses frompositive to negative is at pH 5. Finally, there is a decreasein the magnitude of the zeta potential between pH 11 and pH 13. This is either due to another structural shift in the emulsion or due to the shielding effect of the increased number of ions in the suspension. The main point of this plot is that the isoelectric point of this system is at pH 5.Figure 4: Screen shot of results of automatic titrationresults with the SZ-100 and Autotitrator.ConclusionsThe IEP of a suspension can be automatically determined using the HORIBA SZ-100 and the HORIBA Autotitrator. The IEP of this particular arti fi cial coffee creamer was found to be at pH 5.References(1) HORIBA Application Note AN195 “Isoelectric Point Determination”, available at /fi leadmin/uploads/Scienti fi c/Documents/PSA/AN195_app.pdf (2) HORIBA Application Note AN201 “Wastewater T reatment: Zeta Potential Analysis of Suspended Clay Solids”, available at /fi leadmin/uploads/Scienti fi c/Documents/PSA/Application_Notes/AN201_app.pdf(3) HORIBA Application Note AN202 “Zeta Potential Analysis of Re fi nery Wastewater and Its T reatment,” available at /fi leadmin/uploads/Scienti fi c/Documents/PSA/Application_Notes/AN202_app.pdf******************/scienti fi cUSA: (800) 446-7422 France:+33 (0)1 64 54 13 00 Japan: +81 (0)3 38618231T h i s d o c u m e n t i s n o t c o n t r a c t u a l l y b i n d i n g u n d e r a n y c i r c u m s t a n c e s - © H O R I B A I n s t r u m e n t s , I n c . 05/2012。

SmartLineTechnical InformationSTT850 SmartLine Temperature Transmitter Specification 34-TT-03-14, August 2023IntroductionPart of the SmartLine® family of products, the SmartLine STT850 is a high-performance temperature transmitter offering high accuracy and stability over a wide range of process and ambient temperatures. The SmartLine family is also fully tested and compliant with Experion ® PKS providing the highest level of compatibility assurance and integration capabilities. SmartLine easily meets the most demanding needs for temperature measurement applications.Best in Class Features:Industry-leading performanceo Digital Accuracy up to +/- 0.10 Deg C for RTD. oStability up to +/- 0.01% of URL per year for ten years. o 125 mSec update time for single input models. o250 mSec update time for dual input models.Reliable measuremento Built in Galvanic Isolation.oDifferential / Averaging / Redundant / Split Range measurements. o Dual Compartment Housing. o Sensor Break detection.o Comprehensive on-board diagnostic capabilities. o Full compliance to SIL 2/3 requirements. o Available with 15-year warranty.o Supports Namur 107 Extended Diagnostics (FF). o Supports Namur 89 Wire break.oDirect entry of Callendar-Van Dusen coefficients R 0, α, δ and β for calibrated RTD sensors (not available on DE units).Figure 1– Smartline STT850 TemperaturetransmitterLower Cost of Ownershipo Universal input o Dual sensor optiono Multiple local display capabilities o Modular constructiono External zero, span, & configuration capability o Polarity insensitive loop wiringoDigital Output Option (only available with HART)Communications/Output Options:o 4-20 mA dco Honeywell Digitally Enhanced (DE) o HART ® (version 7.0)oF OUNDATION™ Fieldbu s compliant to ITK 6.1.2All transmitters are available with the above listed communications protocols.DescriptionThe SmartLine Temperature Transmitter is designed and manufactured to deliver very high performance across varying ambient temperature. The total accuracy of the transmitter including the ambient temperature effect in harsh industrial environments, allows the STT850 to replace virtually any competitive transmitter available today.Unique Indication/Display OptionsThe STT850 modular design accommodates a basic alphanumeric LCD display or a unique advanced graphics LCD display with many unparalleled features.Standard LCD Display Featureso Modular (may be added or removed in the field).o0, 90,180, & 270-degree position adjustments.o Deg C, F, R, Kelvin, Milli volts, and Ohm measurement units.o 2 Lines 6 digits PV (9.95H x 4.20W mm), 8 Characters. o Device configuration and calibration through integral buttons or optional external buttons.o Up to 4 configurable display screens.o Configurable screen rotation timing (2 to 20 sec).o Write protect indication.o Critical fault indication.Advanced Graphics LCD Display Featureso Modular (may be added or removed in the field)o0, 90, 180, & 270-degree position adjustmentso Up to eight display screens with 3 formats are possible o Large PV (HART), PV with Bar Graph or PV with Trend Graph.o Configurable screen rotation timing (3 to 30 sec)o Provides instant visibility for diagnosticso Multiple language capability. (EN, GE, FR, IT, SP, RU, TR, CN & JP)Configuration ToolsIntegral Three Button Configuration OptionSuitable for all electrical and environmental requirements, SmartLine offers the ability to configure the transmitter and display via three externally accessible buttons when display option is selected. Zero or span capabilities are also optionally available via these buttons with or without the selection of a display option. Handheld ConfigurationSmartLine transmitters feature two-way communication and configuration capability between the operator and the transmitter. This is accomplished via Honeywell Versatilis, field-rated, next generation multiple communication configuration tool.The Honeywell Versatilis Handheld is capable of field configuring DE and HART Devices and can also be ordered for use in intrinsically safe environments.All Honeywell transmitters are designed and tested for compliance with the offered communication protocols and are designed to operate with any properly validated handheld configuration device.Personal Computer ConfigurationHoneywell’s SCT 3000 Configuration Toolkit provides an easy way to configure Digitally Enhanced (DE) instruments using a personal computer as the configuration interface.Field Device Manager (FDM) Software and FDM Express are also available for managing HART, DE & Fieldbus device configurations.DiagnosticsSmartLine transmitters all offer digitally accessible diagnostics which aid in providing advanced warning of possible failure events minimizing unplanned shutdowns, providing lower overall operational costsSystem Integrationo SmartLine communications protocols all meet the most current published standards for HART/DE/Fieldbus.o Integration with Honeywel l’s Exper ion PKS offers the following unique advantages.•Transmitter messaging•Maintenance mode indication•Tamper reporting (HART only)•FDM Plant Area Views with Health summaries•All STT850 units are Experion tested to provide the highest level of compatibility assuranceModular DesignTo help contain maintenance & inventory costs, all STT850 transmitters are modular in design supporting the user’s ability to replace temperature boards, add indicators or change electronic modules without affecting overall performance or approval body certifications. Each temperature board is uniquely characterized to provide in-tolerance performance over a wide rangeof application variations in temperature and due to the Honeywell advanced interface, electronic modules may be swapped with any electronics module without losing in-tolerance performance characteristics.Modular Featureso Replace Temperature/Terminal board/Lightning protection*o Exchange/replace electronics/comms modules*o Add or remove integral indicators*o Add or remove external configuration buttons*Field replaceable in all electrical environments (including IS) except flameproof without violating agency approvals.With no performance effects, Honeywell’s unique modula rity results in lower inventory needs and lower overall operating costs.Digital Output OptionAn optional Digital Output (open collector type) is available on HART transmitters which can be used to activate external equipment when preset Alarm Setpoints are reached. The Digital Output can be set to monitor two independent setpoints based upon the analog value of the PV or upon device status.The following Alarm Types are available:1. PV High2. PV Low3. Critical Diagnostic Active4. Redundant Input Active**5. PV Rate of Change Alarm*6. PV Deviation Alarm*Alarms can be configured as latching or non-latching. Alarm Blocking is also available which allows start-up without the alarm energizing until it first reaches the operating region. Alarm Hysteresis is configurable from 0 to 100% of PV range.The Digital Output functionality and status is also available over the HART communications link.* These Alarm Types are available as part of the Advanced Diagnostics option. Rate of Change monitors the rate at which the PV is changing, configurable as either increasing or decreasing. Deviation monitors the PV delta from a separately configurable Setpoint value.** Available only via Communications Status.See Wiring Diagrams on page 16.Performance Specifications1,321. Digital Accuracy is accuracy of the digital value accessed by the Host system and the handheld communicator.2. Total analog accuracy is the sum of digital accuracy and output D/A Accuracy.3. Output D/A Accuracy is applicable to the 4 to 20 mA Signal output.4. For TC inputs, CJ accuracy shall be added to digital accuracy to calculate the total digital accuracy.5. These input types are not available on DE units.6. Custom Callendar-van Dusen is not available for Pt25 sensors.Differential Temperature MeasurementSmartLine Temperature supports differential temperature measurements between any two types of sensors.When the loop current mode is set to "Differential" then the input range is from A to B for sensor 1 & 2 whereA = Sensor 1 Minimum - Sensor 2 MaximumB = Sensor 1 Maximum - Sensor 2 MinimumCallendar - van Dusen Algorithm (CVD)The easy-to-use Callendar - van Dusen (CVD) algorithm allows the use of calibrated Platinum RTD sensors to increase the overall system accuracy. Simply enable the algorithm and then enter the four CVD coefficients supplied with the calibrated RTD sensor into the transmitter.Digital Accuracy for differential temperature measurementIf both the inputs are similar the digital accuracy equals 1.5 times the worst-case accuracy of either sensor type.For mixed input types, the digital accuracy is the sum of sensor 1 and sensor 2 digital accuracies.EMC Confirmity (CE, Marine and SIL)The STT850 device is compliant with IEC compliance EN 61326-1: 2013, EN IEC 61326-1: 2021 (CE) ; IEC 60533: 2015 / IACS Req. 1991/Rev.8 2021 (Marine) and IEC 61326-3-1: 2017 (SIL)Performance specifications under EMC conditions (CE and Marine):HART/DE Transmitter: Worst case deviation < 0.1% of full span (for both Analog and Digital).Foundation Fieldbus Transmitter: Worst case deviation < 1°C.Performance under Rated Conditions – All Models (continued)Parameter DescriptionStray Rejection Common ModeAC (50 or 60 Hz): 120 dB (with maximum source impedance of 100 ohms) or ±1 LSB (least significant bit) whichever is greater with line voltage applied.DC: 120 dB (with maximum source impedance of 50 ohms) or a ±1 LSB whichever isgreater with 120 Vdc applied.DC (to 1 KHz): 50 dB (with maximum source of impedance of 50 ohms) or ±1 LSBwhichever is greater with 50 Vac applied.Normal ModeAC (50 or 60 Hz): 60 dB (with 100% span peak-to-peak maximum)Operating Conditions – All ModelsParameter ReferenceConditionRated Condition Operative Limits Transportation andStorage︒C ︒F ︒C ︒F ︒C ︒F ︒C ︒FAmbient Temperature1STT850 25±1 77±2 -40 to 85 -40 to 185 -40 to 85 -40 to 185 -55 to 120 -67 to 248 Humidity %RH 10 to 55 0 to 100 0 to 100 0 to 100Supply Voltage Load Resistance HART Models: 11.8 to 42.4 Vdc at terminals (IS versions limited to 30 Vdc) 0 to 1,400 ohms (as shown in Figure 2)DE Models: 13.8 to 42.4 Vdc at terminals (IS versions limited to 30 Vdc)0 to 1,300 ohms (as shown in Figure 2)FF Models: 9.0 to 32.0 Vdc at terminals1 LCD Display operating temperature -20︒C to +70︒C . Storage temperature -30︒C to 80︒C.For DE, RImax =35* (power Supply Voltage – 15)For HART, RImax = 45.6* (Power Supply Voltage – 11.8)Figure 2 - Supply voltage and loop resistance chart & calculations(not applicable for Fieldbus)Communications Protocols & DiagnosticsHART ProtocolVersion:HART 7Power SupplyVoltage: 11.8 to 42.4Vdc at terminalsLoad: Maximum 1400 ohms See figure 2Minimum Load: 0 ohms. (For handheld communications a minimum load of 250 ohms is required)IEC 61508 Safety Certified SIL 2 and SIL 3Honeywell Digitally Enhanced (DE)DE is a Honeywell proprietary protocol which provides digital communications between Honeywell DE enabled field devices and Hosts.Power SupplyVoltage: 13.8 to 42.4Vdc at terminalsLoad: Maximum 1300 ohms See Figure 2Foundation Fieldbus (FF)Power Supply RequirementsVoltage: 9.0 to 32.0 Vdc at terminalsSteady State Current: 20 mASoftware Download Current: 29 mAP = PermanentI = InstantiableThe AI function block allows the user to configure the alarms to HIGH-HIGH, HIGH, LOW, or LOW-LOW with a variety of priority levels and hysteresis settings.All available function blocks adhere to FOUNDATION Fieldbus standards. PID blocks support ideal & robust PID algorithms with full implementation of Auto-tuning. Link Active SchedulerTransmitters can perform as a backup Link Active Scheduler (LAS) and take over when the host is disconnected. Acting as a LAS, the device ensures scheduled data transfers typically used for the regular, cyclic transfer of control loop data between devices on the Fieldbus.Number of Devices/SegmentEntity IS model: 15 devices/segmentSchedule Entries45 maximum schedule entries50 maximum LinksNumber of VCR’s: 50 maxCompliance Testing: Tested according to ITK 6.1.2Physical LayerComply with IEC 61158 standardSoftware DownloadUtilizes Class-3 of the Common Software Download procedure as per FF-883 which allows any field devices to receive software upgrades from any host.STT850 Smart Temperature 9 Standard DiagnosticsSTT850 top-level diagnostics are reported as either critical or non-critical as listed below. All diagnostics are readable via the DD/DTM tools. All critical diagnostics will appear on the Standard and Advanced integral displays, and non-critical diagnostics will appear on the Advanced integral display.Critical Diagnostics- Sensor Module Fault- Communications Module Fault- Sensor Communications Fault- Input 1 Fault- Input 2 FaultNon Critical Diagnostics (for Advanced Display only)- Cal 1 Correct- Cal 2 Correct- Sensor Temperature- Sensor 1 Health- Sensor 2 Health- Input 1 Range- Input 2 Range- CJ Range- Input 1- Input 2- Input 1 TB5 (For RTD and Ohm types only)- Input 1 TB6 (for RTD and Ohm types only)- Input TB7 (Input 1 or 2, for RTD and Ohm types only)- Input 1 TB8 (for 4-Wire RTD and Ohm types only)- Input 2 TB8 (for RTD and Ohm types only)- Input 2 TB9 (for RTD and Ohm types only)- Factory Calibration- Loop Supply Voltage (not available on Fieldbus)- Communications Module Temperature- DAC Temperature Compensation (not available on Fieldbus)- Sensor Communications- Display Setup (not for Fieldbus)- Excess Delta Alert10 STT850 Smart Temperature Approval Certifications:Notes1.Operating Parameters:4-20 mA/DE/HART (Loop Terminal)Voltage= 11 to 42 Vdc Current= 4-20 mA Normal (3.8 – 23 mA Faults)FF (Loop Terminal)Voltage= 9 to 32 VDC Current = 30 mA2.Intrinsically Safe Entity Parametersa. Analog/DE/HART Entity ValuesTransmitter with Terminal Block Single (50086421-003), Dual (50086421-004) Input revision AA or DO(50086421-006) Option revision W or Laterb. Foundation Fieldbus Entity ValuesFISCO ValuesTransmitter with Terminal Block Single (50086421-009), or Dual (50086421-010) Input revision S or LaterFISCO ValuesNote: Transmitter with Terminal Block revision F or later, the revision is on the label that is on the module.Wiring DiagramsDE- Single InputWiring DiagramRTD Thermocouple,mV and OhmConnectionsDE- Dual Input WiringDiagram1Thermocouple andRTD Connections1 Not applicable forsingle input sensorHART/FF – Single Input Wiring Diagram RTD Thermocouple, mV and Ohm ConnectionsHART/FF – Dual Input Wiring DiagramRTD Thermocouple, mV and Ohm ConnectionsHART/FF Dual Input Wiring Diagram Remote C/J and Mixed Sensors ConnectionsDigital Output Connections for mA Load (HART only) Digital Output Connections for PLC Counting Input (HART only)Mounting & Dimensional DrawingsTRANSMITTER ENCLOSURE CAN BE ROTATED A TOTAL OF 90O FROM THE STANDARD MOUNTING POSITIONFigure 3 – STT850 housing- Horizontal Wall MountingFigure 4 – STT850 Angle Bracket Pipe Mount - Horizontal & VerticalFigure 5 - STT850 Pipe Mount housing - Horizontal & Vertical .STT850 Smart Temperature 21 Mounting & Dimensional DrawingsReference Dimensions:millimetersinchesFigure 6 – STT850 housing dimensions22 STT850 Smart Temperature The Model Selection Guide is subject to change and is inserted into the specification as guidance only.Model Selection GuideSTT850 Smart Temperature 2324 STT850 Smart TemperatureFor more informationTo learn more about SmartLine Temperature, visit https://Or contact your Honeywell Account ManagerProcess Solutions Honeywell1250 W Sam Houston Pkwy S Houston, TX 77042Honeywell Control Systems LtdHoneywell House, Skimped Hill Lane Bracknell, England, RG12 1EB34-TT-03-14 August 2023©2023 Honeywell International Inc.Shanghai City Centre, 100 Jungi Road Shanghai, China 20061https://Sales and ServiceFor application assistance, current specifications, pricing, or name of the nearest Authorized Distributor, contact one of the offices below.ASIA PACIFICHoneywell Process Solutions, (TAC) hfs-tac-*********************AustraliaHoneywell LimitedPhone: +(61) 7-3846 1255 FAX: +(61) 7-3840 6481 Toll Free 1300-36-39-36 Toll Free Fax: 1300-36-04-70China – PRC - Shanghai Honeywell China Inc.Phone: (86-21) 5257-4568 Fax: (86-21) 6237-2826SingaporeHoneywell Pte Ltd.Phone: +(65) 6580 3278 Fax: +(65) 6445-3033South KoreaHoneywell Korea Co Ltd Phone: +(822) 799 6114 Fax: +(822) 792 9015EMEAHoneywell Process Solutions, Phone: + 80012026455 or +44 (0)1202645583Email: (Sales)***************************or (TAC)*****************************AME RICA’SHoneywell Process Solutions, Phone: (TAC) 1-800-423-9883 or 215/641-3610(Sales) 1-800-343-0228Email: (Sales)*************************** or (TAC)*****************************Specifications are subject to change without notice.。