SWCE206.tex Optimal Policy with Partial Information in a Forward-Looking Model

美国品牌发布新一代防水材料
佚名
【期刊名称】《纺织装饰科技》
【年(卷),期】2017(000)001
【摘要】近日，美国Polartec品牌发布了为日本服装品牌提顿兄弟研发的新一代Polartecneoshell防水透气面料，这种面料具有柔软舒展的特性以及前所未有的
透气性，将主要应用于户外服装。

【总页数】1页(P24-24)
【正文语种】中文
【中图分类】TS941.2
【相关文献】
1.防水材料粘胶“新一代” [J], 赵文
2.新一代PMC聚合物水泥防水材料 [J], 刘媛
3.打造国际先进的新一代人工智能产业发展战略高地:《广东省新一代人工智能发
展规划》发布 [J],
4.河北建设工程材料设备推、限、禁目录发布，防水材料新列推广2种、限制1种、禁止2种 [J],
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因版权原因，仅展示原文概要，查看原文内容请购买。

SITE ASITE BIntroduction:Technical Specifications:Connectors Chassis:Power Supply C37.94Interface Specifications Optical Interface Specifications The is a ruggedized,sub-station-hardened converter that converts IEEE C37.94Multi-Mode signal to Optical Single-Mode Optical signal.The equipment is designed to extend IEEE C37.94multi-mode signals over extended single-mode optical fiber spans.The includes the clock synchronization and clock re-generation functions which allows it to transmit the IEEE C37.94multi-mode signal over very long single-mode optical fiber links of up to 90Miles /150Kms.VCL-2710is designed for use in point-to-point applications.The VCL-2710meets and complies with the IEC-61850-3,EMI,EMC,Surge and Temperature specifications making it suitable for sub-station installations to provide uninterrupted service even in the most demanding and harsh environments.The most common application of the VCL-2710is to allow the user to transmit the existing IEEE C37.94multi-mode interface over a single-mode optical fiber link without the need to install any additional multiplexers or transmission equipment,which would otherwise be required to inter-connect the IEEE C37.94Relays between near-end and the far-end substations.PowerTerminal Block,2-PIN Supply Connector IEEE C37.94Interface ST Connector Optical Interface SFP ModuleExternal Alarm Terminal Block,3-PIN ConnectorPower Supply Options 24V DC,range 9V DC ~36V DC (Internal)(Option)48V DC,range 18V DC ~76V DC (Option)Power Supply Options 110V DC and 220V DC.(External Adapters)Number of interfaces 1Tx,1Rxper card Standards IEEE C37.94Optical820nm /850nm Multi-Mode Optical Connector ST Optical TransmitterLED!VCL-2710,IEEE C37.94Multi-Mode to Single Mode VCL-2710,IEEE C37.94Multi-Mode to Single Mode Optical Converter DIN Rail Mounting.VCL-2710,IEEE C37.94Multi-Mode to Single Mode Optical ConverterRIONTELECOMNETWORKSApplication Diagram1Technical Specification:EnvironmentalEMI,EMC,Surge Withstand and other Compliances Compliance/Regulatory:Mechanical Specifications:Ordering Information(Base Unit):Operating Temperature-20C to+60CMaximum Operating95%R.H.,Non-Condensing Humidity HumidityMaximum Operating Up to3,000meters above seaLevel AltitudeOperation Complies with ETS300019Class3.2 Storage Temperature-40C to+70CStorage Complies with ETS300019Class1.2 Maximum Storage98%R.H.,Non-CondensingHumidityMaximum Storage Up to3,000meters abovesea level Altitude Transportation Complies with ETS300019Class2.3EN50081-2EN50082-2IEC60068-2-29IEC60068-2-6IEC60068-2-2IEC60068-2-78IEC60068-2-1IEC60068-2-14CISPR32/EN55022Class A(Conducted Emissionand Radiated Emission)IS9000(Part II Sec.1-4,Part III Sec.1-5,Part IV,Part14Sec.1-3)IEC60870-2-1IEC61000-4-5IEC61000-4-2IEC61000-4-4IEC61000-4-11GR-1089Surgeand Power ContactRoHSCE MarkingComplies to IEEE and IEC standardsComplies with FCC Part68and EMC FCC Part15and CISPR22Class AOperation ETS300019Class3.2Operation ETS300019Class3.2Transportation ETS300019Class2.3Width190.0MMHeight72.0MMDepth176.5MMWeight 1.5KGDIN Rail Mount VersionSupports:-1x C37.94Optical INPUT Interface[850nm,MM,ST connector]-1x C37.94protocol compliant OpticalOUTPUT Interface(Without SFP)-Management:Serial Interface(USB,RS-232)-Installation Kit:System Core Cables,MountingHardware,Documentation,User Manual-00!!!!!!!Part No.Description:[#Add Power Supply]VCL-2710VCL-2710,IEEE C37.94Multi-Mode to SingleMode Optical Converter-VCL-EMOD SFP Transceiver0262-C37Duplex LC,850nm,2Km,MM(Multi-Mode)VCL-EMOD SFP Transceiver0294-Duplex LC,1310nm,2Km,MM(Multi-Mode)VCL-EMOD SFP Transceiver,0193-Duplex LC,1310nm,15Km,SM(Single-Mode)VCL-EMOD SFP Transceiver,0194-Duplex LC,1310nm,40Km,SM(Single-Mode)VCL-EMOD SFP Transceiver,0217-Duplex LC,1550nm,80Km,SM(Single-Mode)VCL-EMOD SFP Transceiver,0402-Duplex LC,1550nm,120Km,SM(Single-Mode)VCL-EMOD SFP Transceiver,0171-Duplex LC,1550nm,150Km,SM(Single-Mode)[#Select SFP Option]C37C37C37C37C37C37Technical specifications are subject to changes without notice.All brand name and trademarks are the property of their respective owners.Revision–1.9,December20,2019Orion Telecom Networks Inc.VCL-2710,IEEE C37.94Multi-Mode to Single ModeOptical Converter#Power Supply:(Any One Option)DC0241x12~32V DC(24V DC nominal)Power Supply InputDC0481x40~60V DC(48V DC nominal)Power Supply InputOptional:VCL-EMOD0444-AC220External Power Supply-DIN Rail MountPower Supply(External)AC to DC Converter,DRL30-24-1,DIN Rail Mount:-Input:1x AC Input[90~240V AC,50-60Hz]-Output1x DC Output[24VDC~1.25A,30W]VCL-EMOD0444-DC220External Power Supply-DIN Rail MountPower Supply(External)-Input1x DC Input[110~250V DC]-Output1x DC Output[24VDC~1.25A,30W]DC to DC Converter,DRL30-24-1,DIN Rail Mount:#Select SFP option from below:。

Protective FinishesWorkmanship Standard – Level IDocument Number: WS-010Revision: 16Effective Date: 10/18/2023Point of Contact: Randy Thelen Title: Sr. Associate, Manufacturing EngineeringRequirements: N/ATABLE OF CONTENTSPURPOSE & SCOPE (1)WORKMANSHIP STANDARD (1)1.PAINT (1)2.CHEMICAL FILM(CLASS1A) (9)3.ANODIZE–ALL TYPES AND CLASS (11)4.OTHER PLATED SURFACE (14)5.PLATED TEFLON PARTS (17)RECORDS (20)DOCUMENT INFORMATION (21)PURPOSE & SCOPEThis Workmanship Standard details the workmanship acceptance criteria to be applied to L3 Communication Systems – West (CSW) products.This Workmanship Standard applies to finishes applied to for CSW products. This standard applies specifically to conditions occurring due to the application of the protective finish. WS-022, Cosmetic Surface Conditions of Assemblies provides standards for conditions which may occur during assembly processing and allows some conditions which result from the manufacturing assembly processes.WORKMANSHIP STANDARD1.PAINTThis section gives criteria for paint conditions that occur as a result of the painting process. For the purposes of workmanship standards, powder coat finishes are considered paint and shall be evaluated to thisdocument.NOTE: WS-022 provides standards for finish conditions resulting from assembly, handling and transportation processes and allows some conditions which result from the manufacturing assembly process.1.1.Viewing Distance/Angle1.1.1.When viewing product, orient the item so that it is facing you perpendicular to your line of site.Repeat this process for all surfaces: top back, bottom, front, and sides.1.1.2.Viewing distance/angle for small parts shall be viewed at approximately 24 inches from the object.1.1.3.Magnification shall not be used when inspecting for cosmetics. However, tools may be used for rootcause analysis.1.1.4.Viewing distance/angle for moderately large parts shall be viewed at three feet.1.2.Inspection RequirementsViewing requirements shall be complete by scanning the surface in a slow continuous manner. Wheninspecting for cosmetics, all visual judgments shall be made using specified lighting, viewing distance,angle of part as described. Color difference should be verified with a Spectrophotometer or color chips per AMS-STD-595.For paint flaw limitations see Table 1.Note : All visual outside surfaces such as doors, doorframes, holding panels, skins and covers shall not exceed the limitations of Table 1.Table 1: Paint Flaw LimitationsPits up to .04 in. diameter X .005 DeepForeign Particles up to .03 High X .03 Long User interface where systems are controlled or monitored while in use. Any surface with switches, buttons, or a display screen. 0per square foot 2 per square foot All surfaces, including egress panels and hour meters, which are not user interfaces as defined above.2 per square foot 6 per square foot1.3. Paint GlossIt is required that components be painted with the specified color and gloss. Due to process variables semi-gloss paints can vary in gloss beyond the limits in the military specifications and AMS-STD-595. Gloss is not a critical feature on products finished with semi-gloss paint at CSW. Variation in gloss in semi-gloss paint colors shall not be cause for rejection.1.4. Light SourceWhite, cool fluorescent office lighting that is uniform intensity between 70 and 120-foot candles. Note: All photos in this document are examples and intended to provide visual directive and are not specific to any part or program.1.4.1. Target• Smooth, uniform. Continuous film.• Color matches applicable specification.1.4.2.Acceptable•Acceptable imperfections in the surface under the paint may be visible through the paint finish.Note: The imperfections under the paint are not addressed in this document, only the fact that they are visible after paint. Surface imperfections under paint can be caused by machining marks, casting imperfections, etc. (see WS-004, Machining, Fabricated, & Additive Parts).1.4.3.Acceptable•A visible texture, with fully cured paint unlike wrinkling and orange peel.1.4.4.Acceptable•Marring and surface lighening due to handling is characteristic of Chemical Agent ResistantCoatings.1.4.5.Acceptable•Thick paint at the base of fins or deep cutouts where paint buildup is common.•This type of buildup may look like a blister but will not be soft or easily punctured and removed.1.4.6.Irregularities Under CoatingIrregularities such as nicks, dents, scratches, pits, grooves, and adhesive drips under the coating shall not be evaluated in this standard (see WS-004 and applicable print).1.4.7.Acceptable•Small discolorations and minor roughness, common on fins or deep recesses.1.4.8.Acceptable•Exposed substrate material of a through hole, threaded hole, and countersink. This condition occurs due to the powder coat masking process for the threaded holes.1.4.9.Defect•Paint peeled or chipped away from the substrate. Paint chipping away from base material or primer indicates adhesion failure.1.4.10.Defect•A raised area of paint that resembles a small bubble or blister. Blisters will move when proddedindicating adhesion failure.1.4.11.Defect•Where final paint film is required, primer or bare substrate material is exposed.Note: Areas which are specified as no-paint areas or overspray allowed areas may have uncoated surface showing on piece parts or assemblies.1.4.12.Defect•Fisheyes or crater-like circular areas that may vary in size and sometimes expose the underlyingsubstrate.1.4.13.Defect•Excessive inclusions, see criteria in Table 1.1.4.14.Defect•Fingerprints, bubble wrap marks, and other impressions due to handling or damage to paintduring the cure cycle.1.4.15.Defect•A wrinkled appearance that resembles the peel of an orange. The paint is soft with pin holes or fisheyes. The paint is wrinkling and lifting leaving voids underneath.•Pin holes appear as very small dots.1.4.16.Defect•Paint film is rough and uneven, possibly with tiny overspray specks of color.1.4.17.Defect•Runs that appear as drips.•This requirement does not apply to sealant or adhesive from a joint which may have a similarappearance and has been painted over. Sealant or adhesive runs should be evaluated to theapplicable workmanship standards document.Note: This is typically caused by applying too much paint to a vertical surface resulting in paint beginning to move.1.4.18.Defect•A sag in the paint that appears draped onto the surface, like curtains.•This requirement does not apply to sealant or adhesive from a joint which may have a similarappearance and has been painted over. Sealant or adhesive sags should be evaluated to theapplicable workmanship standards document.Note: This is typically caused by applying too much paint to a vertical surface resulting in paint beginning to move1.4.19.Defect•Solvent popping or bubbles that are generally clear and appear on the surface of the paint film.1.4.20.Defect•Uncured paint which may be tacky and unusually soft and malleable and may containimpressions.1.4.21.Defect•Paint film appears wrinkled and cracked after drying.1.5.Edges of Masking1.5.1.Target•Paint at the edge of masking should be smooth and even without any burrs.1.5.2.Acceptable• Paint edge falls within tolerance.Note: See 60056954 or 1000383796 for tolerance interpretation.1.5.3.Acceptable•When paint ends at a corner or edge, paint shall not extend past the corner as shown.1.5.4.Acceptable•Paint at edge of masking is less than 0.002” more than paint thickness.1.5.5.Defect•Paint at edge of masking is more than 0.002” more than paint thickness.1.5.6.Defect•Paint extends too high or past the corner or edge.2.CHEMICAL FILM (CLASS 1A)2.1.Target•Uniform appearance.•Continuous, smooth coating.•Color: yellow2.2.Acceptable•Streaking.•Discoloration or color variations.2.3.Defect•Powdery, loose film.•Contaminated film (oil residue, etc.).2.4.Chemical Film (Class 3)2.4.1.Target•Uniform appearance.•Continuous, smooth coating.•Color: clear.2.4.2.Acceptable•Streaking.•Discoloration or color variations.2.4.3.Defect•Powdery, loose film.•Oily residue or contamination.•Contaminated film.3.ANODIZE – ALL TYPES AND CLASS3.1.Target•Continuous, smooth adherent plating.3.2.Acceptable•Plating thickness within specified requirements.A. Small plating voids (not visible at next higher assembly).3.3.Acceptable•Minimal Plating Bleed out on uncoated surface.3.4.Acceptable•Visible but smooth continuous touch up.•Bleed out is excessive on uncoated surface.3.6.Defect•Anodize surface has been scratched, marred and/or damaged (bare metal exposed).•Plating thickness not within the specified requirements.•Surface is rough or pitted.•Small plating voids (visible at next higher assembly).3.7.Defect•Plating voids visible at next higher assembly.3.8.Defect•Touched up area has excessive texture and brush marks.•Surface touchup has exceeded 5 percent of the total anodized surface.•Color, gloss, and texture is different/mismatched between the part and the touchup surface andis clearly visible from a viewing distance of 24 inches.3.10.Defect•Substrate has been touched up with sharpie or any unapproved marker.3.11.Defect•Plating contact points visible at next higher assembly.3.12.Defect•Oily film or other contamination which cannot be removed by normal cleaning.•Exposed bare material.3.14.Defect•Anodize surface scratched, marred and/or damaged (bare metal exposed).4.OTHER PLATED SURFACEThis section addresses the visual properties of machined surfaces that have been plated. These surfaces shall be inspected using magnification no greater than 10X. When handling gold plated surfaces gloves shall be used to prevent contamination. The acceptance criteria for Metal Fabricated Parts and Assemblies are in WS-004.In the case of a discrepancy, the description or written criteria always takes precedence over the illustrations.4.1.Terms and Definitions:Blister – An area where the plating covers but does not adhere to the metal. A mound shapedprojection on a plated metal surface, caused by inclusion of gases or foreign material.Burr – Raised or sharp edge which occurs because of a machine process such as milling or punching.Burn - through/comet-tailing – Is a defect in the plated layer resulting from a base material inclusionthat is highlighted during subsequent ultrasonic cleaning.Flaking (Peeling) – An area where the plating covers but does not adhere to the substrate material.Gold Nodules – Localized build-up of plating protruding from the surface.Machine Mark – Marks that are made directly from a machine process such as milling or punching.Major – A measurable condition or attribute.Minor – A non-measurable condition or attributePit – A measurable depression or cavity below the surrounding surface.Scorch Mark – A burn that has discolored and/or changed the texture of a surface.Scratch – A surface grove with a measurable depth.Scuff – a surface abrasion with no measurable depth.•Uniform in appearance of color.•No particulate matter adhering to the surface.•Free of burrs or other protrusions.•Free of blisters, pits, machining marks, scratches, and scuffs.•Free of corrosion.•Free of burn-through or comet-tailing.•Free of flaking.•Free of gold nodules.•No exposed inner plating layers or exposed base metal.•Free of oily bleed-thru or other contamination.•Free of fingerprints.•Threaded holes are completely plated.4.3.Acceptable - Surface Appearance•Minor pits, machining marks, or scuffs that do not expose basis metal (Figure 2-1).•Discoloration or staining of gold (different sheens, tints, etc.) (Figure 2-2).•Blister(s) on surfaces that will receive a post-plating milling operation (not shown).•Scorch marks that do not expose base metal (not shown).•Watermarks (Figure 2-3).•Threaded holes are partially gold plated (Figure 2-4).Note: Threaded holes used to fixture the part during processing are not required to be gold plated.Figure 2-1 Figure 2-2Figure 2-3 Figure 2-4•Burrs or non-dimensioned (unexpected) protrusions (not shown).•Nodules (Figure 2-5).•Particulate/foreign matter (not shown).•Plated inclusions (not shown).•Oily bleed-thru (not shown) or other surface contamination (not shown).•Flaking or peeling (Figure 2-6).•Blisters (Figure 2-7).•Exposed inner plating layer or base metal (Figure 2-8).•Scratches (Figure 2-9).•Corrosion (Figure 2-10).•Burn-through/comet-tailing (Figures 2-11 and 2-12).•Fingerprints (Figure 2-13).•Major machine marks (not shown).•Pits (Figure 2-14).Figure 2-5 Figure 2-6 Figure 2-7Figure 2-8 Figure 2-9 Figure 2-10Figure 2-11 Figure 2-12 Figure 2-13Figure 2-145.PLATED TEFLON PARTSNote: Magnification is applicable to IPC 610, not to exceed 10X.5.1.Acceptable•Dent/ding does not exceed .020 in. depth.•Dent/ding does not exceed .125 in. diameter zone.Note: Reflector as shown is in carrying container.5.2.Acceptable•Multiple dents/dings are allowed within a .125 in. diameter zone. This is considered as onediameter zone.5.3.Acceptable•Dent/ding does not exceed allowable diameter zone.•Dent/ding no more than 2 places (diameter zones).•Grainy appearance finish.5.4.Defect•Dent/ding exceed allowable diameter zone.•Multiple dent/dings exceed the .125 in. diameter zone.5.5.Acceptable•Misregistration depression no greater than 10 percent of finger width.5.6.Defect•Misregistration depression exceeds 10 percent of the finger width.•Cracked plating.5.7.Acceptable•Plating void touch-up, not to exceed .020 in. height x .125 in. diameter zone. Touch-up appearsconvex.• Plating void touch-up, no more than 2 places.Note: Reflector as shown is in carrying container.5.8.Acceptable•Machine marks.•Nodules in center.5.9.Acceptable•Preferred Tetra EtchNote: Commercial Etching for Teflon (Black in Color)5.10.Acceptable•Void(s) no more than 2 places (void is through gold and silver plating).•Void is no greater than .030 in. diameter.•Void(s) in gold plating, silver plating is visible, does not exceed .030 in. diameter.5.11.Defect•Void(s) in gold or silver plating more than 2 places.•Void(s) exceed .030 in. diameter.5.12.Defect•Gold discoloration.5.13.Defect•Bleed out.RECORDSThere are no records associated with this document.END OF DOCUMENTWS-010, Rev. 16 – Page 21 of 21 Printed versions of this document are considered obsolete. DOCUMENT INFORMATIONResponsible Organization:Operations Function/Sub-function:Workmanship Standards Governing Document(s):Y-001 Quality Management System Subordinate Document(s):N/A Related Document(s): IS-003, Workmanship Acceptability of Electronic Assemblies P-047, Inspection W-018, Manufacturing Criteria WS-000, Workmanship Standards Introduction WS-002, IPC-A-610 Acceptance of Electronic Assemblies WS-022, Cosmetic Surface Conditions of AssembliesRelated Training: N/AApproval Requirements: Manager, Engineering Management Manager, Manufacturing EngineeringReview Requirements:Scientist, Mechanical Engineering Supervisors, Quality Management Associate Manager, Quality Management Revision History Summary Revision # Description of Change Date New – 11 Initial Release through revision 11 VAROUS 12 Added to Purpose and Scope - “WS-022 provides standards for assemblies and allows some conditions which result from the manufacturing assembly processes.” Deleted sub-sections for Cadmium Plating, Passivation, Powder Coated, and Cosmetic Imperfections of Systems, Trailers and Transit Cases. Updated sub-sections on Paint, Anodize, Other Plated Finishes and Plated Teflon Parts. 8/17/2016 NA Added records section. No revision upgrade necessary. 03/07/2017 13 Updated Purpose and Scope. Major revision to 4.1 and 4.2. Added WS-022 to list of related documents. 12/12/2017 14 Update logo and proprietary 05/04/2021 NA Updated point of contact. No revision upgrade necessary. 4/26/2022 15 Incorporated subsections (separate files) into this single document. 9/19/2022 16 Added “or color chips per AMS-STD-595” to section 1.2. 10/18/2023。

第41卷　第2期吉林大学学报(信息科学版)Vol.41　No.22023年3月Journal of Jilin University (Information Science Edition)Mar.2023文章编号:1671⁃5896(2023)02⁃0207⁃10需求侧响应下主动配电网优化调度收稿日期:2022⁃06⁃10基金项目:黑龙江省自然科学基金资助项目(LH2019E016)作者简介:高金兰(1978 ),女,山西运城人,东北石油大学副教授,主要从事电力系统运行与稳定㊁新能源发电研究,(Tel)86⁃136****6089(E⁃mail)jinlangao@㊂高金兰,孙永明,薛晓东,刁　楠,侯学才(东北石油大学电气信息工程学院,黑龙江大庆163318)摘要:针对电网运行中能量调度不佳的问题,首先基于需求侧响应不确定性特点,引入非经济因素以及消费心理学特征,建立需求侧响应模型;其次使用拉丁超立方抽样(LHS:Latin Hypercube Sampling)改善初始种群质量,引入正弦因子提高局部搜索能力,并实行变异操作优化全局搜索精度,以解决麻雀算法(SSA:Sparrow Search Algorithm)的早熟等问题;最后需求侧响应以电网运行成本和环境成本最小为目标建立主动配电网优化调度模型,并使用改进的麻雀算法进行求解㊂仿真结果验证了提出模型的准确性,算法的高效性,有效解决了能量调度不佳的问题㊂关键词:需求侧响应;改进麻雀算法;主动配电网;非经济因素中图分类号:TP302;TM734文献标志码:AOptimal Dispatch of Active Distribution Network under Demand Side ResponseGAO Jinlan,SUN Yongming,XUE Xiaodong,DIAO Nan,HOU Xuecai(School of Electrical and Information Engineering,Northeast Petroleum University,Daqing 163318,China)Abstract :Demand side response is an important means of active distribution network optimization scheduling.Aiming at the problem of poor energy scheduling in power grid operation,firstly,based on the uncertainty characteristics of demand side response,introducing non⁃economic factors and characteristics of consumer psychology,the active distribution network optimization is modeled with the minimum power grid operation cost and environmental cost as the objective function;secondly,aiming at the premature problem of sparrow algorithm,latin hypercube sampling is used to improve the initial population quality,sine factor is introduced to improve the local search ability of the algorithm,and mutation operation is implemented to optimize the global search accuracy of the algorithm;finally,the improved sparrow search algorithm is applied to the solution of the active power grid optimization model.The simulation results verify the accuracy of the proposed model and the efficiency of the algorithm,and effectively solve the problem of poor energy scheduling.Key words :demand side response;improved sparrow search algorithm;active distribution network;non⁃economic factors 0　引　言随着电力改革的深入发展,新的电力需求也随之而来㊂对分布式电源广泛接入电网带来的能量调度问题,主动配电网的提出对改善该问题是一个行之有效的手段[1]㊂需求侧响应技术是主动配电网的一种典型调度方式,可通过不同的定价措施以及政策导向引导用户改变用电习惯[2],可协调用户的负荷改善能力,调节整体的峰谷用电曲线,平衡各阶段用电器数量,其经济成本低㊁适用范围广㊂在主动配电网发展迅猛的今天,对需求侧响应技术的研究在改善用电质量㊁提升用户用电体验以及合理调配区域内有限电力资源方面有着重要意义㊂目前,对需求响应有许多学者进行相关研究㊂张智晟等[3]通过对不同时刻的电价信息响应程度进行负荷转移率的求解,将用户消费习惯与需求响应进行有效结合,通过实验证明了需求响应中考虑多种因素的重要性㊂许汉平等[4]主要应用政策激励进行需求响应,以整体能源的利用率㊁经济成本为优化目标,建立多方面调度模型㊂张超等[5]依据电力市场定义下,用电量以及电力价格的线性关系进行需求响应技术实施㊂在忽略储能成本的前提下,进行分布式能源㊁储能㊁电网等大规模功率交互条件下的综合优化㊂艾欣等[6]在直接负荷控制下进行整体的耦合系统优化模型建立,通过实验结果验证了需求响应能进行高低时段负荷调节,可有效缓解高峰时段用电压力,使负荷供需趋于平衡㊂朱超婷等[7]通过对电价弹性矩阵的建立进行负荷需求模拟,考虑用电量交互㊁需求响应成本等建立电网成本最低优化目标㊂上述研究并未考虑价格型响应在经济因素以外的影响,以及多种响应协调优化的情况㊂笔者在上述研究的基础上,引入非经济因素影响的电价型响应,以及攀比心理㊁从众心理影响的激励型响应,建立以经济㊁环境成本最小为目标的主动配电网优化模型㊂为精确求解模型,提出一种改进的麻雀算法,在基本算法中加入拉丁超立方抽样㊁正弦因子和变异操作㊂通过IEEE33节点算例,验证了笔者提出的模型和算法的准确性㊂1　需求侧响应1.1　价格型响应在消费心理学的描述中,价格的高低会影响消费者的选择㊂对电价而言,电价的差值大小和浮动范围都会影响需求响应的波动㊂用户的主观意愿在价格的影响下会频繁的改变,具有强烈的不确定性,其行为用曲线表示会有相应的上下限,定义为乐观曲线与悲观曲线[3],以不同时段的价格变化为基础,对应相应的负荷变化率,利用Logistic函数对负荷转移率进行描述如下:λpv(Δp pv)=a1+e-(Δp pv-c)/μ+b,(1)其中a为限制变化范围值;b为可变化参数;c为电价近似中间值;μ为调节参数;λpv为电价响应负荷转移率,Δp pv为电价差值㊂对不同响应区用户行为特征的负荷转移如下:λzpv=λmax pv+λmin pv2,0≤Δp pv≤a pv,λmin pv+λmaxpv+λmin pv2(1+m),a pv≤Δp pv≤b pv,λmax pv,Δp pv≥b pvìîíïïïïïï,(2)m=Δp pv-a pvb pv-a pv,(3)其中a pv㊁b pv分别为不同电价差分段点;λzpv为负荷峰谷转移率;λmax pv为最大峰谷转移率;λmin pv为最小峰谷转移率㊂同理,分别求出峰转平㊁平转谷的实际负荷转移率λzpf㊁λzfv㊂在需求侧响应过程中,用户并不只会从价格差值方面改变负荷大小㊂上述模型只能表示用户受经济因素影响进行相应决策,而实际电网运行过程中用户所面临的影响远远不止经济因素一种㊂在实际过程中,用户在价格差异的刺激下想要进行负荷转移,但存在由于条件限制没办法完成此操作的情况,如后续时间段有其他任务无法在当前时间段转移负荷,即各种非经济因素导致的约束㊂为符合实际负荷转移情况,笔者提出非经济因素影响的负荷转移曲线,并引入心理学特征,实际负荷转移曲线类似于倒S型曲线,其负荷转移概率(λfz)与非经济因素(f)关系如图1所示㊂图1可用公式表示为λfz=h(1+e1-l/f)-1,(4)其中h为基础系数;l为条件系数㊂802吉林大学学报(信息科学版)第41卷图1　负荷转移概率曲线Fig.1　Load transfer probability curve 综合考虑经济因素以及非经济因素对负荷转移概率的影响,可得用户响应的转移量Q t =-λzpf L p λfz -λzpv L p λfz ,t ∈T p ,λzpf L p λfz -λzfv L f λfz ,t ∈T f ,λzpv L p λfz +λzfv L f λfz,t ∈T v ìîíïïïï㊂(5)以及转移后负荷总量L t =L 0+Q t ,(6)其中λzpf 为峰转平时段转移率;λzfv 为平转谷时段转移率;L p ㊁L f 分别为峰㊁平时段原始平均负荷;T p ㊁T f ㊁T v 分别为峰㊁平㊁谷3时段,L 0为电价响应前负荷㊂1.2　激励型需求响应直接负荷控制(DLC:Direct Load Control)㊁可中断负荷(IL:Interruptible Load)激励响应适应条件简洁,应用较为广泛㊂二者均是与电力公司或电网管理部门提前签署的负荷控制协议㊂前者相对后者协议的自由度更高,并且没有IL 在不按照协议规定动作时的违约惩罚政策㊂1.2.1　直接负荷控制为在储能设备应用频繁的情况下充分发挥其双向交互的优势[8],签订DLC 协议的用户在满足基本的协议容量要求下,可在一定限度内通过储能设备人为增减响应程度㊂传统的激励型响应并未考虑人本身的不确定因素,为此笔者引入心理学中攀比心理以及从众心理因素,即在同一区域内用户签订相应供电协议后,会根据其他参与协议人数的变化在约定改变负荷期间进行相应变化㊂结合响应人群的心理特点,构建响应模型如下:D DLC =∑24t =1D DLC t +∑24t =1(E +t +E -t )α,(7)其中D DLC t 为DLC 协议响应量;D DLC 为响应后负荷;E +t ,E -t 为不同时间段增减负荷大小;α为响应系数㊂1.2.2　中断负荷在IL 规划中考虑违约协议部分,并依据上述心理学因素,在DLC 响应量变化时IL 也会随之变化,二者协同作用,建立中断负荷情况下的负荷响应模型如下:Q IL =∑24t =1(P IL,t -P wx,t ),P IL,t =rP wx,t {,(8)其中P IL,t 为IL 协议响应量;P wx,t 为中断响应未响应负荷;r 为违约响应系数㊂2　考虑需求侧响应的主动配电网优化模型2.1　目标函数目标函数包括经济与环境成本两部分,经济成本主要为储能维护㊁新能源发电㊁需求侧响应补偿和网络损耗成本,表达式为F 1=min ∑24t =1P x ,t C pvq +∑24t =1P bat,t C cn +∑24t =1P grid,t C g,t +B MG +B DLC +B IL +B []loss ,(9)其中P x ,t ㊁P bat,t ㊁P grid,t 分别为新能源出力㊁储能出力㊁向上级电网购电量;C pvq ㊁C cn ㊁C g,t 为相应成本系数;B DLC 为DLC 成本;B IL 为IL 成本;B loss 为网损成本;B MG 为燃气轮机运行成本㊂新能源设备出力情况:P x ,t =P pv,t +P wind,t ,(10)其中P pv,t ㊁P wind,t 分别为光伏㊁风机发电功率㊂燃气轮机运行成本:902第2期高金兰,等:需求侧响应下主动配电网优化调度B MG =∑24t =1P MG,t ηMG L p gas ,(11)其中ηMG 为效率;L 为热值;p gas 为气价;P MG,t 是燃气轮机功率㊂需求侧响应成本:B DLC =∑24t =1C DLCD DLC t +∑24t =1(E +t d +t +E -t d -t )α,(12)B IL =∑24t =1(C IL P IL,t -C wx P wx,t ),(13)其中C DLC 为DLC 补偿价格;d +t ㊁d -t 为增减负荷价格;C IL ㊁C wx 为IL 补偿价格㊁惩罚价格㊂网损成本:B loss =∑24t =1C g,t ∑Nj =1u j ,t ∑k ∈Ωj u k ,t G jk cos δjk ,t ,(14)其中N 为节点总数;u j ,t ㊁u k ,t 为t 时刻节点j ㊁k 电压幅值;G jk 为节点j ㊁k 间电导;Ωj 为以节点j 为首节点的尾节点集合;δjk ,t 为t 时刻节点j ㊁k 间电压相角差㊂环境成本即污染物处理成本最低,表达式为F 2=min ∑24t =1P grid,t W g C 1+∑24t =1P MG,t W MG C []2,(15)其中W g ㊁W MG 分别为向上级购买电量产生的污染物系数㊁燃气轮机污染系数;C 1㊁C 2为成本系数㊂2.2　动态权重调整主动配电网优化目标包括经济和环境成本两方面,可采用引入动态权重因子对综合成本进行实时优化[9]㊂对整个周期相同时间范围内的成本函数进行归一化处理,即可得到F 1(t )㊁F 2(t ),通过动态权重因子进行实时优化得到总目标函数:min f =∑24t =1[xF 1(t )+yF 2(t )],x =c 1+c 2F 1(t ),y =1-x ìîíïïïï,(16)其中x 为经济权重系数;y 为环境权重系数;c 1㊁c 2为变化因子㊂2.3　约束条件功率平衡约束为P MG +P pv +P wind +P bat +P grid =P load +P loss +P DR ,(17)其中P MG ㊁P pv ㊁P wind ㊁P bat ㊁P grid ㊁P load ㊁P loss ㊁P DR 分别为燃气轮机㊁光伏㊁风机㊁储能㊁上级电网传输㊁初始负荷㊁网损和需求响应功率㊂储能运行约束为E bat,t =E bat,t -1+(P c,t ηc -P d,t ηd )Δt ,(18)E min bat ≤E bat ≤E max bat ,(19)其中E max bat ㊁E min bat 分别为储能元件最大最小储量;E bat,t 为当前时刻储能元件储量;E bat,t -1为储能元件上一时刻余量;ηc ,ηd 分别为充放电效率;P c,t ㊁P d,t 分别为充放电功率㊂燃气轮机约束为P min ≤P MG ≤P max ,(20)其中P min ,P max 分别为燃气轮机出力上下限㊂除上述约束外,其他诸如节点电压约束等如文献[7]所描述㊂3　模型求解3.1　原始麻雀算法麻雀算法(SSA:Sparrow Search Algorithm)是对麻雀种群觅食过程中发生的一系列行为的分步012吉林大学学报(信息科学版)第41卷分析[10],具体原理如下㊂发现者位置更新:X t+1i,d=X t i,d exp-iαT()max,R2<S,X t i,d+Q L,R2≥Sìîíïïï,(21)其中X t i,d为第i只麻雀d维位置;T max为迭代次数上限值;α∈(0,1]为随机数;R2㊁S分别为危险值和正常值;Q为随机数;L为1×D的矩阵㊂跟随者位置更新:X t+1i,d=Q exp X t W i,d-X t i,diæèçöø÷2,i>n2,X t bi,d+X tb i,d-X t i,d A+L,其他ìîíïïïï,(22)其中X t Wi,d 为最差位置;X t bi,d为最好位置;A+=A T(A T A)-1,A为全为1或-1的矩阵㊂预警者位置更新:X t+1i,d=X t i,d+βX ti,d-X b t i,d,X t i,d+K X t i,d-X W t i,d(f i-f w)+æèçöø÷ε,ìîíïïïï(23)其中β为(0,1)的正态分布随机数;K为[-1,1]的随机数;f i为当前个体适应度;f g为最优个体适应度;f w为最差个体适应度㊂3.2　改进算法3.2.1　改善初始种群对智能算法,初始种群较差会对算法寻优过程产生一定负面影响,为避免由于初始种群造成局部最优现象,采用拉丁超立方抽样产生初始种群,具体步骤如下:1)确定一个初始种群规模T;2)将每一维量的可行区域分割成T个长度均一的区域,即H n个超立方体;3)建立矩阵B(H×n),其每行即为一个被抽到的超立方体;4)在不同抽中的超立方体中随机得到样本,即为初始种群的值㊂3.2.2　引入正弦权重系数为避免麻雀算法早熟现象,先引入粒子群算法的粒子移动概念,将跳跃到最优解的方式变为正常移动,并去除向原点收敛操作㊂再引入正弦变化的权重系数,具体如下㊂发现者:X t+1i,d=X t i,d(1+Q),R2<S,ωX t i,d+Q,R2≥S{㊂(24) 跟随者:X t+1i,d=ωX tb i,d+1D∑D d=1(K(X t b i,d-X t i,d))㊂(25) 权重系数:ω=ωmin+ωmax+ωmin2sinπt t()max,(26)其中ωmax为权重峰值;ωmin为权重谷值;t为当前迭代次数;t max为迭代次数峰值㊂对预警者改变跟随方式:X t+1i,d=X t i,d+β(X t i,d-X t bi,d),f i≠f g,X t i,d+β(X t Wi,d-X t bi,d),f i=f g{㊂(27)112第2期高金兰,等:需求侧响应下主动配电网优化调度3.2.3　变异操作变异操作能在一定程度上改善个体均一性,提升整体寻优效果[11⁃12]㊂在算法流程中引入变异概念对当前适应度最差的10%个体进行替换,并且按照自然进化的方式对变异概率进行合理变化,以平衡寻优进程,变异过程和概率为X new i ,d =X now i ,d +p m X now i ,d ,(28)p m =p max -∑N i =1(f i -f avg )2N p ,(29)其中X new i ,d 为变异后个体;X now i ,d 为变异前个体;P max 为变异频率上限;f i ㊁f avg 分别为个体的适应度㊁种群中所有个体的平均适应度;p 为变异频率调节参数㊂3.3　基于改进SSA 的主动配电网优化调度求解步骤依据主动配电网优化调度模型选取合适控制变量,麻雀个体位置的优劣代表目标函数的优化程度㊂通过麻雀群体避让天敌的行为进行位置更新,迭代到最优位置,即最佳优化调度结果,其流程图如图2所示,具体步骤如下:Step 1　输入主动配电网参数,包括新能源㊁储能设备等出力大小和负荷大小,以及分时电价㊁补偿价格等;Step 2　设置改进麻雀算法的初始数据,即迭代次数㊁权重系数㊁种群大小和变异概率等;Step 3　采用LHS 初始麻雀种群;Step 4　进行改进麻雀算法操作,根据粒子移动概念进行发现者㊁跟随者位置更新;在全维度进行警戒者位置更新;Step 5　判断是否进行终止操作,是则输出最优结果;Step 6　未达到截至条件,进行变异操作,将部分劣等个体进行变异,替代变异前个体,重新返回Step4进行循环,直至达到截至条件㊂图2　主动配电网优化调度流程图Fig.2　Optimal dispatching flow chart of active distribution network 4　算例分析4.1　仿真参数笔者采用修改后的IEEE33节点系统(见图3)验证整体模型的效果㊂节点17㊁18㊁24㊁25接入价格响应负荷;节点30㊁31㊁32接入激励响应用户;光伏接入节点15;风机接入节点4;燃气轮机接入节点21;储能设备接入节点23㊂DLC 补偿成本为0.3元/(kW㊃h),IL 的补偿成本为0.5元/(kW㊃h)㊂24h 的风光出力㊁负荷情况如图4所示,需求侧模型参数设置㊁区域内电价划分方式参照文献[13]㊂储能设备允许的SOC(State Of Charg)波动为0.2~0.9;燃气轮机的效率为0.85;光伏风机的维护成本为0.3元/(kW㊃h)㊂212吉林大学学报(信息科学版)第41卷图3　改进IEEE33节点图Fig.3　Improved IEE33node diagram 图4　主动配电网新能源出力、负荷曲线Fig.4　New energy output and load curve of active distribution network 4.2　仿真分析设置4种场景㊂场景1:电网不执行需求响应及优化㊂场景2:电网执行价格型需求响应㊂场景3:电网执行激励型需求响应㊂场景4:电网执行多种需求响应㊂场景1㊁4的总体调度情况如图5所示㊂图5　不同场景主动配电网优化调度图Fig.5　Optimal dispatching diagram of active distribution network in different scenarios 场景1中,在夜间时段以及用电器数量增加时,储能装置进行放电调节,在用电器数量减少以及新能源出力充足时进行充电调节,充分发挥其高发低储作用㊂燃气轮机在新能源出力不足及负荷升高时进行出力,减少相应的购电功率㊂在场景4中,需求侧响应技术的加入,在负荷高峰8⁃14h㊁20⁃23h 负荷相应减少,且部分负荷转移到1⁃6h㊂由于考虑环境成本以及动态优化条件,所以燃气轮机出力减少㊂对比场景1,场景4仅在20h㊁21h 燃气轮机工作㊂由图5可知,笔者提出的模型可有效调节不同阶段设备出力情况,合理实现一个周期内的总体调度㊂大电网㊁新能源发电以及储能设备协同作用,对区域内进行整体负荷供电㊂不同情况下需求侧响应前后负荷对比如图6㊁图7所示㊂可以看出3种情况均有削峰填谷效果,单一的需求响应在削峰填谷综合方面都有一定局限性㊂312第2期高金兰,等:需求侧响应下主动配电网优化调度图6　单一需求侧响应负荷变化曲线Fig.6　Response load curve of single demandside 图7　多种需求侧响应负荷变化曲线Fig.7　Response load change curves of multiple demand side 价格型响应下,7⁃11h 负荷减少约5%,12⁃14h几乎无变化,夜晚峰时段负荷减少约3%,谷时段1⁃7h 负荷提升3.3%㊂激励型响应下,夜晚峰时段负荷减少约5%,7⁃11h 几乎无变化,谷时段1⁃7h 负荷无升高㊂而综合两种响应模式所得结果在峰谷时段优于单一模式,峰时段均有5%以上负荷削减量,低谷时段负荷也有序上升㊂不同情况下的综合成本值如表1所示,与不进行需求侧响应相比,单一型需求响应以及多种需求响应结合可以通过响应措施进行负荷改变,使成本降低10%~20%㊂相比于场景1,场景4成本减少1242元,可有效降低整体的综合成本㊂表1　不同场景下成本情况 Tab.1　Cost under different scenarios 元场景1234经济成本4050.53791.83797.73109.6环境成本1756.31532.31425.11355.2总成本5706.85324.15222.84464.8 在调度周期内经济㊁环境权重变化情况如图8所示㊂在1⁃9h 经济权重递增趋势较大,从0.33递增到0.359,减少相应经济成本;17⁃21h 环境权重上升,对污染排放加以限制㊂对动态权重在一个调度周期内进行不间断调节,以减少整体成本㊂图8　动态权重变化图Fig.8　Dynamic weight change diagram 笔者分别采用灰狼优化算法(GWO:Grey Wolf Optimizer)㊁原始麻雀算法㊁鲸鱼优化算法412吉林大学学报(信息科学版)第41卷　图9　算法对比图　Fig.9　Algorithm comparison (WOA:Whale Optimization Algorithm)以及笔者的改进麻雀算法进行主动配电网优化,对比结果如图9所示㊂从图9中可看出,改进SSA 在整体迭代过程中稍优于其他算法㊂LHS㊁引入正弦权重㊁变异操作让算法中麻雀个体具备初始优势,在前期可达到较高的收敛速度;变异㊁正弦权重的引入可让其具备更好的全局寻优能力㊂对比发现,GWO 与WOA 前期收敛能力不强,原始SSA 的寻优速度与改进SSA 较为接近,但改进SSA 寻优精度更高㊂5　结　论笔者在考虑多种因素影响需求响应的基础上,构建主动配电网优化模型,采用改进麻雀算法进行求解,通过IEEE33算例进行仿真验证,证明了笔者模型㊁算法的准确性,结论如下:1)笔者提出的模型可有效实现主动配电网的优化调度,当需求响应加入运行时,可与其他设备进行协同优化,增加削峰填谷效果,配合动态权重因子的实时优化,可降低电网的整体成本;2)采用LHS㊁正弦因子㊁变异策略改进麻雀算法,可改善种群丰富程度,提高算法的收敛效果,与WOA㊁GWO㊁SSA 算法相比,改进的麻雀算法可以更好地进行主动配电网优化调度,有效降低综合成本㊂参考文献:[1]吕智林,廖庞思,杨啸.计及需求侧响应的光伏微网群与主动配电网双层优化[J].电力系统及其自动化学报,2021,33(8):70⁃78.LÜZ L,LIAO P S,YANG X.Bi⁃Level 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Spare parts list0463412001GB20201209Valid for:serial no.EMS215ic:612-xxx-xxxx;EMP 215ic:552-, 615-,643-,719-xxx-xxxx;EM215ic:623-,627-xxx-xxxxEMS215ic,EMP215ic,EM215icOrdering number Product Notes0558102239EMS215ic BobbinØ4-8in.(100-200mm).CSA/Bayonet 0558102240EMP215ic BobbinØ4-8in.(100-200mm).CSA/Bayonet 0558102436EM215ic BobbinØ4-8in.(100-200mm).CSA/Bayonet 0700300985EMP215ic BobbinØ100-200mm(4-8in.)CE,euro connection 0700300986EM215ic BobbinØ100-200mm(4-8in.)CE,euro connection 0700300988EMP215ic BobbinØ100–200mm(4–8in.)euro connection,forMiddle East0700300993EMP215ic BobbinØ100-200mm(4-8in.)CE,euro connection,for AustraliaSpare parts are to be ordered through the nearest ESAB agency.Kindly indicate type of unit,serial number, denominations and ordering numbers according to the spare parts list.Maintenance and repair work should be performed by an experienced person,and electrical work only by a trained e only recommended spare parts.TABLE OF CONTENTSSPARE PARTS (4)Housing (4)Connections including drive system (6)User interface (8)Control modules (10)WEAR PARTS-CSA (12)WEAR PARTS-CE (14)Rights reserved to alter specifications without notice.SPARE PARTSHousingC=Component designation in circuit diagramItem Qty Ordering no.Denomination Notes C 110558102397Side frame,left210558102398Side frame,right340558102399Handle410558102400Top handle52Screw610558102401Side panel,left CSA,with ESABlogo and weldingdecal10464581001Side panel,left CE,with ESABlogo and weldingdecal710558102402Front foot With decals810558102403Rear foot910558102404Side panel right CSA,with ESABlogo10464582001Side panel right CE,with ESABlogo1010558102406Hinge114Screw M4×8mm124Nut M4×0.7mm134Washer M41420558102407Hinge pin1510558 102 405Roller latch asssembly162Screw M6×180mm178Screw M6×20mm186Screw M4×10mm194Screw M6×20mm202Sex bolt M6218Nut M6Connections including drive systemC=Component designation in circuit diagramItem Qty Ordering no.Denomination Notes C 110558102408Wire feeder mechanism CSA,includingmotor and harness 10464583880Wire feeder mechanism CE,including motorand harness 21Screw M5×16mm310558102409Remote connection outletwith harness8-pin connector 42Nut M3×0.5mm510558102410Brake hub nut610558102411Brake hub kit710558102412Solenoid assembly withhoses With gas valve, hose clamps and hoses810558102413Bracket for solenoid valve92Screw M4×10mm 1010558102414Gas connector CSA 10464587880Gas connector CE 1110558102415Main supply switch1210558102416Circuit breaker1310558102417Current sensor141Screw M3×8mm 1520558102418OKC contact female1610558102419Polarity changeover cablecomplete1720558102420Fan+wire harness Including wireharness 1810558102421Fan protection foam1910464588880Euro connection withharnessCE only2010464589880EMI PCB assembly incl.wireharnessCE only2110558102442Warning pinch-shock label Not included inillustrationUser interfaceC=Component designation in circuit diagramEM215icItem Qty Ordering no.Denomination Notes C 110558102486User interface complete210558102423Knob encoder with retainingring310558102487WF Pot Assembly410558102440Knob,small520558102489WF Pot Knob610558102488Process Select KnobEMP215ic,EMS215icItem Qty Ordering no.Denomination Notes C 110558102422EMP215ic panel assembly CSA10464590880EMP215ic panel assembly CE10558102485EMS215ic panel assembly CSA220558102423Encoder for small knob310558102424Encoder for large knob410558102438Replaceable display lens520558102440Knob,small610558102441Knob,large710558102437EMP215ic lens assembly kit10558102484EMS215ic lens assembly kitControl modulesC=Component designation in circuit diagramItem Qty Ordering no.Denomination Notes CCSA110558102426PCB Power boardassemblyCE10464591880PCB Power boardassembly210558102427PCB Control boardCSAcompleteCE10464592880PCB Control boardcomplete310558102428Main transformer with NTC(3x)410558102429Output diode assembly510558102430Output inductor assembly610558102431PFC inductor assembly710558102432Strain relief assemblyassembly810558102433Mains cable complete CSA only910558102434Warning label Not included inillustrationSPARE PARTSWEAR PARTS-CSAItem Ordering no.Denomination Wire type Wire dimensions10558102326Wire outlet guide Fe/SS/FluxCored 0.030 in. / 0.035 in. /0.045 in.(0.8 mm / 0.9 mm / 1.2 mm)0558102327Wire outlet guide Fe/SS/FluxCored0.024 in.(0.6mm)20558102328Wire inlet guide Fe/SS/FluxCored 0.024 in. / 0.030 in. / 0.035 in. /0.045 in.(0.6 mm / 0.8 mm / 0.9 mm / 1.2 mm)30558102334Key-drive shaft N/A N/A47977036Feed roll“V”groove Fe/SS0.024 in./0.030 in.(0.6 mm / 0.8 mm)W4014800Feed roll“V”groove Fe/SS0.024 in./0.035 in.(0.6 mm / 0.9 mm)7977732Feed roll“V”knurled Flux Cored0.030 in./0.035 in.(0.8 mm / 0.9 mm)7044277Feed roll“V”knurledFlux Cored0.045 in.(1.1 mm)50558102329Locking knob(Wiretension)N/A N/A60558102518Locking knob forthe feed roll70558102331Pressure armcomplete assemblyN/A N/A 80558102330Screw N/A N/A 90558102333MIG gun lockingknobN/A N/AWEAR PARTS-CEItem Ordering no.Denomination Wire type Wire dimensions10558102460Wire outlet guidesteel Fe/SS/FluxCored1.0 mm – 1.2 mm(0.040 in. – 0.045 in.)0558102461Wire outlet guidesteel Fe/SS/FluxCored0.6 mm – 0.8 mm(0.023 in. – 0.030 in.)0464598880Wire outlet guideteflon Aluminium 1.0 mm–1.2 mm(0.040 in.–0.045 in.)20558102328Wire inlet guide Fe/SS/FluxCored 0.6 mm/0.8 mm/0.9 mm/1.2 mm (0.023 in./0.030 in./0.035 in./ 0.045 in.)30191496114Key-drive shaftcrescentN/A N/A40367556001Feed roll“V”groove Fe/SS/FluxCored 0.6 mm/0.8 mm(0.023 in./ 0.030 in.)0367556002Feed roll“V”groove Fe/SS/FluxCored 0.8 mm/1.0 mm(0.030 in./ 0.040 in.)0367556003Feed roll“V”groove Fe/SS/FluxCored 1.0 mm/1.2 mm(0.040 in./ 0.045 in.)0367556004Feed roll"U"groove Aluminium 1.0 mm/1.2 mm(0.040 in./0.045 in.)50558102329Locking knob(Wiretension)N/A N/A60558102518Locking knob for thefeed roll70558102331Pressure armcomplete assemblyN/A N/A80558102330Screw N/A N/A90558102459Euro adapterlocating screwN/A N/AFor contact information visit ESAB AB,Lindholmsallén9,Box8004,40277Gothenburg,Sweden,Phone+46(0)31509000 。

ZT‐2026Quick Start 1What’s in the Shipping Package?The shipping package showed contain the following items:2Preparing the Device1.Refer to Section 4. for details of how to configure the DIP switches of theZT-2000 I/O device.2.Install the ZT Configuration Utility on your Host PC to configure the ZT-2000coordinator. The utility can be founded on the CD in the\Napdos\ZigBee\ZT_Series\Utility folder, or downloaded from:/pub/cd/usbcd/napdos/zigbee/zt_series/utility3.Power Supply: Connect a power supply using a voltage range of +10 ~ +30 V DCCDANT‐124‐05 Quick StartZT‐2026 Device+Vs GNDIf any of these items are missing or damaged, please contact your local distributorfor more information. Save the shipping materials and cartons in case you need toship the module in the future.3 Setting up the ZT ‐2000 I/O Device3.1 Introduction to the ConfigurationParametersA. The “ZB PID” parameter is the group identity for a ZigBee network, and must be same for all devices in the same ZigBee network.B. The “Node ID” parameter is the individual identity of the specific ZigBee module, and must be unique for each device connected to the same ZigBee network.C. The “ZB Channel” parameter indicates the radio frequency channel, and must be set to the same value as other modules on the same ZigBee network.ZB Channel0x00 0x01 …… 0x0F Frequency (MHz)24052410……2480※ ZB channels 0x04, 0x09, 0x0E or 0x0F are recommended because they do not overlap with Wi-Fi frequency band.D. Protocol/Application Mode:When implementing custom programs based on different protocols, the following application mode(s) are recommended in order to ensure optimal performance.User Program Protocol ZT-2000 I/OZT-2550 ZT-2570 DCON DCON Transparent Transparent Modbus RTU Modbus RTU Transparent Modbus GatewayTransparent Modbus Gateway Modbus TCPModbus RTU------Modbus Gateway802.11b/g ZB Channel 802.11b/g ZB Channel 802.11b/g ZB Channel4 The Rotary Switch and DIP Switches The configuration of the ZT-2026 can be adjusted using a combination of the external rotary switch and the DIP switches. The ZT-2000 device should only be rebooted once the configuration is completed.ZT-2026123456789101112 Address LSB(Node ID)Address MSB(Node ID)ProtocolChecksumZB PIDZB ChannelType CodeONData FormatRotary Switch(Software Config.)1 2 3 …… F NoteAddress *Note1 01 02 03……0F Node ID *Note 1 0x0001 0x0002 0x003 ……0x000FMSB = 00 1 2 3 …… FAddress 10 111213……1F Node ID 0x0010 0x0011 0x0012 0x013 ……0x001FMSB = 1*Note 1：The “Address” and “Node ID” are defined via the %AANNTTCCFF command. In software configuration mode, the DIP switches for “Address”, “Data Format” and “Type Code”are ignored and can also be set via the %AANNTTCCFF and $AA7CiRrr commands.DIP SwitchNumber Item Status DescriptionOFFValid Address (Node ID) from 0x01 to 0x0F1 AddressMSBONValid Address (Node ID) from 0x10 to 0x1FOFF DCONProtocol2 ProtocolONModbus RTU ProtocolOFFDisabled (DCON Protocol)3 ChecksumON Enabled (DCON Protocol)OFF ZigBee Pan ID = 0x00004 ZBPIDON ZigBee Pan ID = 0x0001OFF ------5ON 0x08OFF ------6ON 0x04OFF ------7ON 0x02OFF ------8ZB ChannelON 0x01OFF Engineering Units Format9 DataFormatON HexadecimedFormatZT-2026SwitchPositionType CodeSwitchPositionTypeCodeSwitchPositionType Code0x08 0x09 0x0A0x0B 0x0C 0x0D0x07 0x1A5 Starting the ZT‐2000 I/O Device As the ZigBee network is controlled by the ZigBee Coordinator, the ZT-2550/ZT-2570 (ZigBee Coordinator) must be configured first. Refers to the documents shown below for full details of how to configure these devices.Once configuration of the ZigBee Coordinator has been completed, set the “Pan ID” and “RF Channel”values for the ZT-2000 I/O device to the same values as the network and then reboot the device.The module will automatically start to function on the ZigBee network using the default protocol.※ Documents/pub/cd/usbcd/napdos/zigbee/zt_series/document/zt-255x//pub/cd/usbcd/napdos/zigbee/zt_series/document/zt-257x/※ Configuration Utility(Used to configure the ZT-2000 I/O device Coordinator) /pub/cd/usbcd/napdos/zigbee/zt_series/utility/6 ExamplesConfiguring the ZT‐2550/ZT‐2570Configuring the ZT-2000 I/O Device123456789101112Number Item Status Description1 Address MSB OFF Address/Node ID is 01 (Rorary Switch=1)2 Protocol ON Use Modbus RTU Protocol3 Checksum OFF Disabled4 ZB PID OFF Pan ID=0x00005 ON 0x086 ON 0x047 ON 0x028ZB ChannelOFF ------ZigBee RF Channel = 0x0E9 Data Format OFF Engineering Units Format10 OFF11 OFF12Type CodeOFFAI Type Code = Type Code 8 (+/-10V)7 Communications TestingOnce the ZT-2000 I/O device has joined the ZigBee network, the signal quality can be confirmed by monitoring the status of the ZigBee Net LED indicators. If the LED indicator shows a steady light, communication with the ZT-2000 I/O device has been successfully established for data acquisition and control.ICP DAS also provides the “DCON Utility”, which can be used to simulate DCON/Modbus communication. This software can alse be used to verify the device settings and ZigBee I/O functions.※ The DCON Utility can be downloaded from:/pub/cd/8000cd/napdos/driver/dcon_utility/Simulating I/O channel operation via the DCON Utilityunch the DCON Utility and select the appropriate COM Port settings to connectto the ZigBee Coordinator (ZT-2550/ZT-2570).2.Click the “Search” button to start searching for ZT-2000 I/O devices connectedto the same ZigBee network.3.If any ZT-2000 I/O devices are found, they will be displayed in the device listwindows. Double-click the name of the module to start the operating platform. 1238 Troubleshooting(1)Technical Support.If you have any difficulties using your ZT-2000 series I/O device, please send a description of the problem to ******************Include the following items in your email:● A description or diagram of the current DIP switch positions.● A copy of the configuration file for the ZT-2000 coordinator. This file canbe obtained using the procedure outlined below and should be attached to youremail.a.Set the DIP switch of the ZT-255x device to the [ZBSET] position then rebootthe device. Launch the ZT Configuration Utility and select [Save Log] icon to save the configuration of the ZT-255x as a file.b.After clicking the [Save Log] icon, enter the “File Name” and the “FilePath” in the Windows “Save” dialog box. Once the configuration has been successfully saved, the following message will be displayed.。

Technical Specification SheetDocument No. 149-454July 1, 2013 Siemens Industry, Inc. Page 1 of 8PXC Compact SeriesFigure 1. PXC Compact Series Controllers(PXC-24 and PXC-36 shown.)DescriptionThe PXC Compact Series (Programmable Controller–Compact) is a high-performance Direct Digital Control(DDC) supervisory equipment controller, which is anintegral part of the APOGEE® Automation System.The PXC Compact Series offers integrated I/O basedon state-of-the-art TX-I/O™ Technology, whichprovides superior flexibility of point and signal types,and makes it an optimal solution for Air Handling Unit(AHU) control. The PXC Compact operates stand-alone or networked to perform complex control,monitoring, and energy management functions withoutrelying on a higher-level processor.The PXC Compact Series communicates with otherfield panels or workstations on a peer-to-peerAutomation Level Network (ALN) and supports thefollowing communication options:∙ Ethernet TCP/IP∙P2 RS-485The PXC Compact is available with 16, 24, or 36 pointterminations. Selected models in the Compact Seriesprovide the following options:∙Support for FLN devices.∙An extended temperature range for the control ofrooftop devices.∙Support for Island Bus, which uses TX I/Omodules to expand the number of pointterminations.Features∙DIN rail mounted device with removable terminalblocks simplifies installation and servicing.∙Proven program sequences to match equipmentcontrol applications.∙Built-in energy management applications and DDCprograms for complete facility management.∙Comprehensive alarm management, historicaldata trend collection, operator control, andmonitoring functions.∙Sophisticated Adaptive Control, a closed loopcontrol algorithm that auto-adjusts to compensatefor load/seasonal changes.∙Message control for terminals, printers, pagers,and workstations.∙Highly configurable I/O using Siemens state-of-the-art TX-I/O™ Technology.∙HMI RS-232 port, which provides laptopconnectivity for local operation and engineering.∙Extended battery backup of Real Time Clock.∙Persistent database backup and restore within thecontroller.∙Optional HOA (Hand/Off/Auto) module forswappable and configurable HOA capability.∙Optional extended temperature range for rooftop installation.∙Optional peer-to-peer communications over industry-standard 10Base-T/100Base-TX Ethernet networks.∙Optional support for FLN devices.∙Optional support for P1 Wireless FLN.∙Optional operation as a P1 FLN device with default applications.∙Optional support for Virtual AEM.∙PXM10T and PXM10S support: Optional LCD Local user interface with HOA (Hand-off-auto)capability and point commanding and monitoringfeatures.The Compact SeriesIn addition to building and system management functions, the Compact Series includes several styles of controllers that flexibly meet application needs.PXC-16The PXC-16 provides control of 16 points, including 8 software-configurable universal points.Point count includes: 3 Universal Input (UI), 5 Universal I/O (U), 2 Digital Input (DI), 3 Analog Output (AOV), and 3 Digital Output (DO).PXC-24The PXC-24 provides control of 24 points, including 16 software-configurable universal points.Point count includes: 3 Universal Input (UI), 9 Universal I/O (U), 4 Super Universal I/O (X), 3 Analog Output (AOV), 5 Digital Output (DO).PXC-36The PXC-36 provides control of 36 local points, including 24 software-configurable universal points. Point count includes: 18 Universal I/O (U), 6 Super Universal I/O (X), 4 Digital Input (DI), and 8 Digital Output (DO).The PXC-36 offers the flexibility of expanding the total point count through a self-forming island bus. With the addition of a TX-I/O Power Supply, up to 4 TX-I/O modules can be supported. For more information, see the TX-I/O Product Range Technical Specification Sheet (149-476). Available OptionsThe following options are available to match the application:Ethernet or RS-485 ALNSupport for APOGEE P2 ALN through TCP/IP orRS-485 networks.FLN Support∙The PXC-24 “F32” models support up to 32 P1 FLN devices when the ALN is connected toTCP/IP.∙The PXC-24 “F” models with an FLN license support up to 32 P1 FLN devices when the ALN isconnected to TCP/IP.∙The PXC-36 with an FLN license supports up to 96 P1 FLN devices when the ALN is connected toRS-485 or TCP/IP.∙ A Wireless FLN may also be used to replace the traditional P1 FLN cabling with wirelesscommunication links that form a wireless meshnetwork. Additional hardware is required toimplement the Wireless FLN.For more information about FLN support, contact your local Siemens Industry representative.P1 FLN OperationThe PXC-16 and PXC-24 can be configured as a programmable P1 FLN device. In the P1 FLN mode, the PXC Compact functions as an equipment controller with customized programming and default applications.Virtual AEM SupportThe Virtual AEM license allows the PXC Compact to connect an RS-485 APOGEE Automation Level Network or individual field panels to a P2 Ethernet network without additional hardware.Extended Temperature OperationThe "R" models of the PXC Compact Series support extended temperature operation, allowing for rooftop installations.Field Panel GOThe PXC-36 supports Field Panel GO.The Field Panel GO license provides a Web-based user interface for your APOGEE® Building Automation System. It is an ideal solution for small or remote facilities with field panels on an Ethernet Automation Level Network (ALN).Page 2 of 8 Siemens Industry, Inc.HardwareThe PXC Compact Series consists of the following major components:∙ Input/Output Points∙ Power Supply∙ Controller ProcessorInput/Output Points∙The PXC Compact input/output points perform A/D or D/A conversion, signal processing, pointcommand output, and communication with thecontroller processor. The terminal blocks areremovable for easy termination of field wiring.∙The Universal and Super Universal points leverage TX-I/O™ Technology from SiemensIndustry to configure an extensive variety of pointtypes.∙Universal Input (UI) and Universal Input/Output (U) points are software-selectable to be:- 0-10V input-4-20 mA input- Digital Input-Pulse Accumulator inputs-1K Ni RTD @ 32°F (Siemens, JohnsonControls, DIN Standard)-1K Pt RTD (375 or 385 alpha) @ 32°F-10K NTC Thermistor (Type 2 and Type 3) @ 77°F-100K NTC Thermistor (Type 2) @ 77°F-0-10V Analog Output (Universal Input/Output (U) points only)∙Super Universal (X) points (PXC-24 and PXC-36 only) are software-selectable to be:- 0-10V input-4-20 mA input- Digital Input-Pulse Accumulator inputs-1K Ni RTD @ 32°F (Siemens, JohnsonControls, DIN Standard)-1K Pt RTD (375 or 385 alpha) @ 32°F-10K NTC Thermistor (Type 2 and Type 3) @ 77°F-100K NTC Thermistor (Type 2) @ 77°F- 0-10V Analog Output-4-20 mA Analog Output-Digital Output (using external relay)∙Dedicated Digital Input (DI) points (PXC-16 and PXC-36 only) are dry contact status sensing. ∙Digital Output (DO) points are 110/220V 4 Amp (resistive) Form C relays; LEDs indicate the status of each point.∙All PXC Compact Series models support 0-10 Vdc Voltage Analog Output circuits.∙On PXC-24 and PXC-36 models, the Super Universal circuits may be defined as 4-20 mAcurrent AO.Power Supply∙The 24 volt DC power supply provides regulated power to the input/output points and activesensors. The power supply is internal to the PXCCompact housing, eliminating the need forexternal power supply and simplifying installationand troubleshooting.∙The power supply works with the processor to ensure smooth power up and power downsequences for the equipment controlled by the I/O points, even through brownout conditions. Controller Processor∙The PXC Compact Series includes amicroprocessor-based multi-tasking platform forprogram execution and communications with theI/O points and with other PXC Compacts and field panels over the ALN.∙ A Human Machine Interface (HMI) port, with a quick-connect phone jack (RJ-45), uses RS-232protocol to support operator devices (such as alocal user interface or simple CRT terminal), and a phone modem for dial-in service capability.∙ A USB Device port supports a generic serial interface for an HMI or Tool connection.∙The program and database information stored in the PXC Compact RAM memory is battery-backed. This eliminates the need for time-consuming program and database re-entry in theevent of an extended power failure.∙The firmware, which includes the operating system, is stored in non-volatile flash ROMmemory; this enables firmware upgrades in thefield.∙Brownout protection and power recovery circuitry protect the controller board from powerfluctuations.∙LEDs provide instant visual indication of overall operation, network communication, and lowbattery warning.Siemens Industry, Inc. Page 3 of 8Programmable Control with Application FlexibilityThe PXC Compact Series of high performance controllers provides complete flexibility, which allows the owner to customize each controller with the exact program for the application.The control program for each PXC Compact is customized to exactly match the application. Proven Powers Process Control Language (PPCL), a text-based programming structure like BASIC, provides direct digital control and energy management sequences to precisely control equipment and optimize energy usage.Global Information AccessThe HMI port supports operator devices, such as a local user interface or simple CRT terminal, and a phone modem for dial-in service capability. Devices connected to the operator terminal port gain global information access.Multiple Operator AccessMultiple operators can access the network simultaneously. Multiple operator access ensures that alarms are reported to an alarm printer while an operator accesses information from a local terminal. When using the Ethernet TCP/IP ALN option, multiple operators may also access the controller through concurrent Telnet sessions and/or local operator terminal ports.Menu Prompted, English Language Operator InterfaceThe PXC Compact field panel includes a simple, yet powerful, menu-driven English Language Operator Interface that provides, among other things:∙Point monitoring and display∙ Point commanding∙Historical trend collection and display for multiple points∙ Event scheduling∙Program editing and modification via Powers Process Control Language (PPCL)∙Alarm reporting and acknowledgment∙Continual display of dynamic information Built-in Direct Digital Control RoutinesThe PXC Compact provides stand-alone Direct Digital Control (DDC) to deliver precise HVAC control and comprehensive information about system operation. The controller receives information from sensors in the building, processes the information, and directly controls the equipment. The following functions are available:∙Adaptive Control, an auto-adjusting closed loop control algorithm, which provides more efficient,adaptive, robust, fast, and stable control than thetraditional PID control algorithm. It is superior interms of response time and holding steady state,and at minimizing error, oscillations, and actuatorrepositioning.∙Closed Loop Proportional, Integral and Derivative (PID) control.∙ Logical sequencing.∙Alarm detection and reporting.∙ Reset schedules.Built-in Energy Management ApplicationsThe following applications are programmed in the PXC Compact Series and require simple parameter input for implementation:∙Automatic Daylight Saving Time switchover∙ Calendar-based scheduling∙ Duty cycling∙ Economizer control∙Equipment scheduling, optimization andsequencing∙ Event scheduling∙ Holiday scheduling∙Night setback control∙Peak Demand Limiting (PDL)∙Start-Stop Time Optimization (SSTO)∙ Temperature-compensated duty cycling∙Temporary schedule overridePage 4 of 8 Siemens Industry, Inc.SpecificationsDimensions (L × W × D)PXC-16 and PXC-2410.7 in. × 5.9 in. × 2.45 in. (272 mm × 150 mm × 62 mm)PXC-3611.5 in. × 5.9 in. × 3.0 in. (293 mm × 150 mm × 77 mm) Processor, Battery, and MemoryProcessor and Clock SpeedPXC-16 and PXC-24: Motorola MPC852T, 100 MHzPXC-36: Motorola MPC885, 133 MHz MemoryPXC-16 and PXC-24: 24 MB (16 MB SDRAM, 8 MB Flash ROM)PXC-36: 80 MB (64 MB SDRAM, 16 MB Flash ROM) Battery backup of Synchronous Dynamic (SD) RAM (field replaceable)Non-rooftop Models: 60 days (accumulated),AA (LR6) 1.5 Volt Alkaline (non-rechargeable)Rooftop (Extended Temperature) Models: 90 days (accumulated),AA (LR6) 3.6 Volt Lithium (non-rechargeable) Battery backup of Real Time ClockNon-rooftop Models: 10 yearsRooftop (Extended Temperature) Models: 18 months CommunicationA/D Resolution (analog in)16 bitsD/A Resolution (analog out)10 bitsEthernet/IP Automation Level Network (ALN)10Base-T or 100Base-TX compliant RS-485 Automation Level Network (ALN)1200 bps to 115.2 Kbps RS-485 P1 Field Level Network (FLN) on selected models, license required4800 bps to 38.4 Kbps Human-Machine Interface (HMI)RS-232 compliant, 1200 bps to 115.2 Kbps USB Device port (for non-smoke control applications only)Standard 1.1 and 2.0 USB device port, Type B female connector.USB Host port on selected models (for ancillary smoke control applications only)Standard 1.1 and 2.0 USB host port, Type A female connector. ElectricalPower Requirements24 Vac ±20% input @ 50/60 HzPower Consumption (Maximum)PXC-16: 18 VA @ 24 VacPXC-24: 20 VA @ 24 VacPXC-36: 35 VA @ 24 Vac Siemens Industry, Inc. Page 5 of 8AC Power and Digital OutputsNEC Class 1 Power Limited Communication and all other I/ONEC Class 2 Digital InputContact Closure SensingDry Contact/Potential Free inputs onlyDoes not support counter inputs Digital OutputClass 1 Relay Analog Output0 to 10 VdcUniversal Input (UI) and Universal Input/Output (U)Analog InputVoltage (0-10 Vdc)Current (4-20 mA)1K Ni RTD @ 32°F1K Pt RTD (375 or 385 alpha) @ 32°F10K NTC Type 2 or Type 3 Thermistor @ 77°F100K NTC Type 2 Thermistor @ 77°FDigital InputPulse AccumulatorContact Closure SensingDry Contact/Potential Free inputs onlySupports counter inputs up to 20 HzAnalog Output (Universal Input/Output (U) points only)Voltage (0-10 Vdc) Super Universal (X)Analog InputVoltage (0-10 Vdc)Current (4-20 mA)1K Ni RTD @ 32°F1K Pt RTD (375 or 385 alpha) @ 32°F10K NTC Type 2 or Type 3 Thermistor @ 77°F100K NTC Type 2 Thermistor @ 77°FDigital InputPulse AccumulatorContact Closure SensingDry Contact/Potential Free inputs onlySupports counter inputs up to 20 HzAnalog OutputVoltage (0-10 Vdc)Current (4-20 mA)Digital Output (requires an external relay)0 to 24 Vdc, 22 mA max. Operating EnvironmentAmbient operating temperature32°F to 122°F (0°C to 50°C) Ambient operating temperature with rooftop (extended temperature) option-40°F to 158°F (-40°C to 70°C) Relative HumidityPXC-16 and PXC-24: 5% to 95%, non-condensingPXC-36: 5% to 95%, non-condensing Page 6 of 8 Siemens Industry, Inc.Mounting SurfacePXC-16 and PXC-24: Direct equipment mount, building wall, or structural memberPXC-36: Building wall or a secure structure Agency ListingsULUL864 UUKL (except rooftop models)UL864 UUKL7 (except rooftop models)CAN/ULC-S527-M8 (except rooftop models)UL916 PAZX (all models)UL916 PAZX7 (all models) Agency ComplianceFCC ComplianceAustralian EMC FrameworkEuropean EMC Directive (CE)European Low Voltage Directive (LVD) OSHPD Seismic CertificationProduct meets OSHPD Special Seismic Preapproval certification(OSH-0217-10) under California Building Code 2010 (CBC2010) andInternational Building Code 2009 (IBC2009) when installed within thefollowing Siemens enclosure part numbers: PXA-ENC18, PXA-ENC19,or PXA-ENC34. Ordering InformationPXC Compact SeriesProduct Number DescriptionPXC16.2-P.A PXC Compact, 16 point, RS-485 ALNPXC16.2-PE.A PXC Compact, 16 point, Ethernet/IP ALNPXC24.2-P.A PXC Compact, 24 point, RS-485 ALNPXC24.2-PE.A PXC Compact, 24 point, Ethernet/IP ALNPXC24.2-PR.A PXC Compact, 24 point, RS-485 ALN, rooftop optionPXC24.2-PER.A PXC Compact, 24 point, Ethernet/IP ALN, rooftop optionPXC24.2-PEF.A PXC Compact, 24 point, Ethernet/IP or RS-485 ALN. P1 FLN or Remote Ethernet/IP(Virtual AEM) option.PXC24.2-PEF32.A PXC Compact, 24 point, Ethernet/IP or RS-485 ALN. P1 FLN enabledPXC24.2-PERF.A PXC Compact, 24 point, Ethernet/IP or RS-485 ALN, rooftop option. P1 FLN or RemoteEthernet/IP (Virtual AEM) option.PXC36-PE.A PXC Compact, 36 point, Ethernet/IP or RS-485 ALN.PXC36-PEF.A PXC Compact, 36 point, Ethernet/IP or RS-485 ALN, Island Bus, P1 FLN.Siemens Industry, Inc. Page 7 of 8Information in this document is based on specifications believed correct at the time of publication. The right is reserved to make changes as design improvements are introduced. APOGEE and Insight are registered trademarks of Siemens Industry, Inc. Other product or company names mentioned herein may be the trademarks of their respective owners. © 2013 Siemens Industry, Inc.Siemens Industry, Inc. Building Technologies Division 1000 Deerfield Parkway Buffalo Grove, IL 60089-4513 USA+ 1 847-215-1000Your feedback is important to us. If you havecomments about this document, please send them to***************************************.Document No. 149-454Printed in USAPage 8 of 8Optional LicensesProduct Number DescriptionLSM-FLN License to enable FLN support on PXC-16 or PXC-24 “F”modelsLSM-VAEM License to enable Virtual AEM support when the ALN is connected to RS-485LSM-FLN36.A License to enable FLN support on model PXC36-PE.ALSM-FPGO License to enable Field Panel GO on models PXC36-PE.A and PXC36-PEF.ALSM-IB36.A License to enable the Island Bus on model PXC36-PE.ALSM-36.A License to enable both FLN and Island Bus support on model PXC36-PE.AAccessoriesProduct Number DescriptionPXM10S Controller mounted Operator Display module with point monitor and optional blue backlight PXM10T Controller mounted Operator Display modulePXA8-M 8-switchHOA(UL864)PXA16-M 16-switchHOA(UL864)PXA16-MR 16-switch HOA (extended temp, UL 916) with HMI cablePXA-HMI.CABLEP5 Serial cable required for HOA or PXM10T/S connection to non-rooftop variants ofthe 16-point and 24-point Compact Series (pack of 5)TXA1.LLT-P100 Labels for HOA and TX-I/O Modules, pack of 100, letter formatService Boxes and EnclosuresProduct Number DescriptionPXA-SB115V192VA PX Series Service Box —115V, 24 Vac, 50/60 Hz, 192 VAPXA-SB115V384VA PX Series Service Box— 115V, 24 Vac, 50/60 Hz, 384 VAPXA-SB230V192VA PX Series Service Box— 230V, 24 Vac, 50/60 Hz, 192 VAPXA-SB230V384VA PX Series Service Box —230V, 24 Vac, 50/60 Hz, 384 VAPXA-ENC18 18" Enclosure (Utility Cabinet) (UL Listed NEMA Type 1 Enclosure)PXA-ENC19 19” Enclosure (UL Listed NEMA Type 1 Enclosure)PXA-ENC34 34” Enclosure (UL Listed NEMA Type 1 Enclosure)DocumentationProduct Number Description553-104 PXC Compact Series Owner’s Manual125-1896 Powers Process Control Language (PPCL) User’s Manual。