FLIR A320 热像仪 容祺

OPTICAL GAS IMAGING Infrared Cameras for Gas Leak DetectionMAKE INVISIBLE GASES VISIBLESAVE LIVES, REVENUE, AND THE DAY A facility can have thousands of connections and fittings that require regular inspection, but the reality is less than one percent of these components will ever leak. Testing them all with a traditional “sniffer” takes a great deal of time and effort.From natural gas extraction to petrochemical operations and power generation, companies have saved more than $10 million annually in lost product by including FLIR optical gas imaging in their leak detection and repair (LDAR) programs.METHANE AND HYDROCARBONSScan thousands of connections for natural gas(methane) and other hydrocarbon leaks quickly and froma safe distance to avoid regulatory violations, fines, andlost revenue.SULFUR HEXAFLUORIDE (SF6)Scan substation circuit breakers for sulfur hexafluoride(SF6) leaks at a safe distance from high-voltage areas,without the need to shut down operations.HYDROGEN (CO2 TRACER GAS)Imaging the tracer gas, CO2, with an optical gas cameraallows operators of hydrogen-cooled generators toefficiently find hydrogen leaks.CARBON DIOXIDE (CO2)Prevent shut-downs by detecting carbon dioxide(CO2) leaks early in chemical production, manufacturing, andEnhanced Oil Recovery programs.CARBON MONOXIDE (CO)Protect workers and the environment from toxic levelsof carbon monoxide (CO) by pinpointing leaks quicklyand efficiently.REFRIGERANTSFind leaks early to avoid interruptions in operations,prevent the loss of perishable products, and limit theenvironmental impact of toxic refrigerants.SPOT HARD-TO-FIND CO2 LEAKSSEE HYDROCARBON LEAKS CLEARLY FIND LEAKS AT STEEL PLANTSFIND SF6 LEAKS EASILYDETECT R-124 COMPRESSOR LEAKSDETECT LEAKS FROM HYDROGEN-COOLED GENERATORSOptical gas imaging cameras give you the power to spot invisible gases as they escape, so you can find fugitive emissions faster and more reliably than with sniffer detectors. With a FLIR GF-Series camera, you can document gas leaks that leadto lost product, lost revenue, fines, and safety hazards.TRACK LEAKS TO THEIR SOURCEThe GF-Series optical gas imaging cameras can detect natural gas, SF6, and CO2 leaks quickly, accurately, and safely without the need to shut down systems, or the need for contact with the components. Gas leaks that are invisible to the naked eye look like smoke on infrared optical gas imaging cameras, making them easy to see – even from a distance.WITH FLIR OPTICAL GAS IMAGERS, YOU CAN:• Scan broad areas quickly, from a safe distance• Survey hard-to-reach connections and fittings• Improve compliance with environmental regulations• Check electro-mechanical systems for signs of failure, using temperature measurement capability A LEAKING PRESSURE GAUGECAPTURED GAS LEAKLEAK IS CLEARLY VISIBLE ON THE THERMAL IMAGEHANDHELD CAMERASWhen you need to survey large work areas for industrial gas or chemical leaks, a handheldoptical gas imaging camera can help you get the job done quickly and efficiently. Camerassuch as the GFx320, GF306, and GF346 allow you to check every component throughoutmultiple sites, and are ergonomically designed for comfortable, all-day use. These camerasalso offer features such as temperature calibration for improved contrast between the gascompound and the background scene.HELPFUL ACCESSORIESFLEXIBLE SYSTEMS THAT MEETYOUR CHANGING NEEDSNo other thermal imaging camera manufacturer offersa wider range of accessories than FLIR Systems.Hundreds of accessories are available to customize ourcameras for a wide variety of imaging and measurementapplications. From a comprehensive range of lenses,through LCD screens, to remote control devices,everything is available to tailor your camera to yourspecific application.FIXED CAMERASHave a need for continuous monitoring or automated leak detection in criticalareas? With thermal imaging cameras such as the G300a, G300pt, andA6604, you can constantly monitor vital gas pipelines and installations inremote or difficult to access zones. You will immediately see if a dangerousand costly gas leak appears. Monitoring is performed from a safe distancewithout the need to send technicians into potentially dangerous areas.GF-SERIES HANDHELD CAMERAS ARE IDEAL FOR:• Chemical processing plants• Manufacturing plants• Natural gas wellsites• Electrical substations• Power generatorsG300A, G300PT, AND THE A6604 CAMERASARE IDEAL FOR:• Offshore oil platforms• Natural gas processing plants• Biogas generation plants• Petrochemical facilities• High value well sites• Underground storage facilities• Critical pipeline crossingsVISIBLE IMAGE INFRARED IMAGE HIGH SENSITIVITY MODE Scan broad areas quickly, from a safe distanceThe FLIR GF304 detects refrigerant gas leaks without interrupting or shutting down operations. Most modern refrigerants are organofluorine compounds, and while they are not ozone-depleting, some blends contain Volatile Organic Compounds (VOCs). Refrigerants are used in a variety of systems, including food production, pharmaceutical storage, and air conditioning.• R 22• R 125• R 134A • R 143A• R 245fa • R 404A • R 407C • R 410A• R 417A • R 422A • R 507AThe FLIR GF306 detects sulfur hexafluoride (SF 6) – used to insulate high voltage circuit breakers – as well as the industrial refrigerant and fertilizer anhydrous ammonia (NH 3). SF 6 is a potent greenhouse gas, with a global warming potential that’s 22,000 times greater than CO 2 over a 100-year period. By detecting and repairing SF 6 leaks, energy producers can avoid costly damage to circuit breakers while protecting the environment.A/C COMPRESSOR - INFRARED IMAGEHIGH SENSITIVITY MODECOMMON SF 6 PLUMBING LEAKSF 6 LEAKING FROM CIRCUIT BREAKERGF304 CAMERAS ARE IDEAL FOR:• Food production, storage, and retail • Automotive production and repair • Air conditioning• Pharmaceutical production, transport, and storageGF306 CAMERAS ARE IDEAL FOR:• Utilities • Ammonia plants• Industrial refrigeration systemsFLIRGF306FLIRGF304REFRIGERANTSSULFER HEXAFLUORIDE AND AMMONIAGF306 DETECTS THE FOLLOWING GASES:GF304 DETECTS THE FOLLOWING REFRIGERANT GASES:• A cetic acid • A cetyl chloride • A llyl bromide • A llyl chloride • A llyl fluoride • A nhydrous ammonia • B romomethane • C hlorine dioxide • E thyl cyanoacrylate (superglue)• E thylene • F reon-12• H ydrazine • M ethylsilane• M ethyl ethyl ketone (MEK)• M ethyl vinyl ketone • P ropenal • P ropene • S ulfur hexafluoride • T etrahydrofuran • T richloroethylene • U ranyl fluoride • V inyl chloride • V inyl cyanideThe GFx320 and GF320 detect methane emissions from the production, transportation, and use of oil and natural gas. They allow you to survey large areas up to nine-times faster than with traditional gas sniffer methods. These OGI cameras also offer highly accurate temperature measurements, so inspectors can assess and improve thermal contrast between the gas cloud and the background.• M ethane • M ethanol • P ropane • B enzene • E thane • P ropylene • E thanol • P entane• 1-Pentene• I soprene• B utane• E thylbenzene• M EK• M IBK• T oluene• O ctane• H eptane• X ylene• E thylene• H exaneINTRINSICALLY SAFEThe FLIR GFx320 allows you to quickly detect and visualize fugitive natural gas emissions while maintaining safety inside hazardous locations. This Intrinsically Safe OGI camera is third-party certified for use in Class I Div II safety areas. The GFx320 is verified to meet sensitivity standards defined in the US EPA’s OOOOa methane rule and meets reporting requirements by tagging each recording withGPS data. By finding leaks and fixing them quickly, your company can protect the environment while avoiding product losses and the cost of regulatory fines.GFx320: SAFETY ZONE COMPLIANTAt offshore rigs, well sites, and production plants,there’s often a risk of gas collecting and ignitingwith a stray spark or hot surface. Working in theseareas requires special clothing and equipment – if it’spossible at all.The oil and gas industry has long awaited a gasdetection solution such as the GFx320, because itsIntrinsically Safe designation allows the user to workconfidently and focus on the job at hand.THE GFx320 HAS THE FOLLOWINGCERTIFICATIONS:ATEX/IECEx, Ex ic nC op is IIC T4 Gc II 3 GANSI/ISA-12.12.01-2013, Class I Division 2CSA 22.2 No. 213, Class 1 Division 2THE GFx320 AND GF320 ARE IDEAL FOR:• O ffshore platforms• L iquid natural gas shipping terminals• O il refineries• N atural gas wellheads and processing plants• C ompressor stations• B io-gas and power generation plantsMETHANE LEAK AT NATURAL GAS FACILITY SITENATURAL GAS LEAK ON COMPRESSOR VALVEVENTING STORAGE TANK PRESSURE RELIEF VALVEMETHANE & HYDROCARBONS FLIR GFx320FLIR GF320THE GFx320/GF320 DETECT MORETHAN 400 GASES, INCLUDING:NEW!The GF343 lets you see CO2 leaks quickly and accurately, whether the gas is the result of a production process, part of an Enhanced Oil Recovery program, or being used as a tracer gas for hydrogen. CO2 is a primary greenhouse gas, with emissions resulting not only from the combustion of fossil fuels but also from industrial processes, oil production, and manufacturing. Reliable non-contact CO2 detection allows plants to inspect equipment while it is still online in the course of normal operations, avoiding unplanned outages. It also helps keep operations safe while moving towards carbon-neutral capture and storage operations.The FLIR GF346 exposes invisible, odorless carbon monoxide (CO) emissions from a safe distance. CO leaking from vent stacks or pipes can be deadly, especially if the gas is allowed to collect in an enclosed area. The GF346 can quickly scan broad areas and pinpoint even small leaks from several meters away, increasing worker safety and protecting the environment.• A cetonitrile• A cetyl cyanide • A rsine• B romine isocyanate • B utyl isocyanide • C hlorine isocyanate • C hlorodimethylsilane • C yanogen bromide • D ichloromethylsilane • E thenone• E thyl thiocyanate• G ermane• H exyl isocyanide• K etene• M ethyl thiocyanate• N itrous oxide• S ilanevSPOT HARD-TO-FIND CO2 LEAKSSEE MORE WITH HIGH SENSITIVITY MODE (HSM)VENTING FROM BLAST FURNACELEAKING FLANGEGF343 CAMERAS ARE IDEAL FOR:• Enhanced Oil Recovery programs• Hydrogen-cooled power generators• Carbon capture systems• Ethanol producers• Industrial tightness testingGF346 CAMERAS ARE IDEAL FOR:• Steel industry• Bulk chemicals manufacturing• Packaging systems• Petrochemical industryCARBON DIOXIDECARBON MONOXIDE FLIR GF343FLIR GF346GF346 DETECTS CARBON MONOXIDEAND THE FOLLOWING GASES:ImagingSpecifications GFx320GF320GF304GF306GF343GF346Primary Gas Seen Methane (CH4)Methane (CH4)Refrigerants Sulfur hexafluoride (SF6) / Ammonia (NH3)Carbon dioxide (CO2)Carbon monoxide (CO)Detector Type Cooled InSb Cooled InSb Cooled QWIP Cooled QWIP Cooled InSb Cooled InSb Spectral Range 3.2 – 3.4 µm 3.2 – 3.4 µm8.0 – 8.6 µm10.3 – 10.7 µm 4.0 – 4.4 µm 4.52 – 4.67 µm Resolution320 x 240320 x 240Total Pixels76,80076,800Hazardous Location Certifications ATEX/IECEx, Ex ic nC op is IIC T4 Gc II 3 G ANSI/ISA-12.12.01-2013, Class I Division 2 CSA 22.2 No. 213, Class 1 Division 2Thermal Sensitivity<15 mK at 30°C (86°F)<15 mK at 30°C (86°F)Accuracy±1°C (±1.8°F) for temperature range 0°C to 100°C (32°F to 212°F) or ±2% of reading for temperature range >100°C (>212°F)*±1°C (±1.8°F) for temperature range 0°C to 100°C (32°F to 212°F) or ±2% of reading for temperature range >100°C (>212°F)* Temperature Range-20°C to 350°C (-4°F to 662°F)–20°C to 250°C (–4°F to 482°F)-40°C to 500°C (-40°F to 932°F)Not calibrated for temperature measurement–20°C to 300°C (–4°F to 572°F) Lenses14.5° (38 mm), 24° (23 mm)Standard: 24° × 18°; Optional: 14.5°, 6°Standard: 24° × 18°; Optional: 14.5°Standard: 14.5° × 10.8°; Optional: 24°Standard: 24° × 18°; Optional: 14.5°Standard: 24° × 18°; Optional: 14.5°, 6°Zoom1-8x continuous digital zoom1-8x continuous digital zoomFocus Manual Auto and manual Auto and manualColor LCD Monitor 4.3 in., 800 x 480 pixels 4.3 in., 800 x 480 pixelsAdjustable Viewfinder Tiltable OLED, 800 x 480 pixels Tiltable OLED, 800 x 480 pixelsVideo Camera w/Lamp 3.2 MP 3.2 MPLaser Spot Activated by dedicated button Activated by dedicated buttonVideo Out HDMI HDMIAnalysisSpotmeters10*10*Area Boxes 5 (min./max./avg.)* 5 (min./max./avg.)*Profiles 5 (min./max./avg.)* 5 (min./max./avg.)*Delta T Delta temperature between measurement functions or reference temperature*Delta temperature between measurement functions or reference temperature*AnnotationGPS Location data automatically added to images Location data automatically added to imagesFile StorageRadiometric JPEG14-bit measurement data included14-bit measurement data includedRadiometric IR Video15 Hz direct to memory card15 Hz direct to memory cardMPEG Recording RTP/MPEG4RTP/MPEG4SPECIFICATIONS*GF343 is not calibrated for temperature measurement.NEW!INFRARED TRAINING CENTERThe Premier Infrared Camera User Educational & Training ResourceYour professionalism drives you to know everything you can about your business; that’s why you’ll want to get the most out of your GF-Series camera.FLIR cameras are easy to use and intuitive, but only expert training will give you the knowledge and skills to wringevery last bit of capability from your investment. An Infrared Training Center (ITC) certificate is proof of your expertise in operating your camera and interpreting the thermal information it provides.During the three-day ITC Optical Gas Imaging certification course, you’ll learn how to set up and operate FLIR GF-Series cameras, which gases these cameras can see, and how environmental conditions affect gas leak detection, all while earning 2.0 IACET CEUs. Training includes classroom instruction and lab time covering basic inspection procedures, permitting requirements, safety practices, and more.For full course descriptions, updated schedules, and more information,visit the itc website at: or call 1.866.872.4647.ITC COURSES PROVIDE:• I ndustry-leading, high-quality interactive instruction • T he most qualified international instructors • T he most extensive hands-on laboratories • I SO 9001-registered• O ptional online training coursesOTHER ITC COURSES INCLUDE:• OOOOa Fugitive Emissions Monitoring (U.S. Only)• Thermography Fundamentals • General Thermography Primer• Level I, Level II, and Level III Thermography • IR Electrical Inspection • IR Mechanical inspectionAttend classes at our training center, locally at one of our regional classes, or in your facility with our on-site service.THE PROFESSIONAL GUIDESEE OPTICAL GAS IMAGING IN ACTION, ACCESS CASE STUDIES, AND MUCH MOREGain a greater understanding of OGI technology and how it can help you find and repair gas leaks with FLIR’s content-rich iBook, Optical Gas Imaging: The Professional Guide. This guide provides an in-depth look at OGI and infrared, through technical explanations, videos, and animations. You’ll get expert tips for maximizing OGI surveys and see how different industries use OGI cameras to save time, money, and the environment.Get the iBook at /OGIFLIR TOOLS MOBILEIMPORT, PROCESS, AND SHARE DATA QUICKLY WITH THE FREE APPGet the word out straight from the field with FLIR Tools Mobile for Apple ® and Android ™. Connect your smartphone or tablet to your GF-Series camera, then use the app to transfer video from the camera, tack on more measurement spots, add text, change palettes, add notes, and generate a PDF. Email video and findings to colleagues and customers in no time. Upload to Dropbox or accounts, or use the app to display images on-site to those who need to know immediately.FLIR Tools Mobile also lets you stream live video from your GF-Series, plus take remote control of GF-Series functions, including focus, level, span, and many other modes. This functionality is perfect when you need to place the camera off on its own for monitoring or safety reasons, or need to share live imaging with others nearby.OPTICAL GAS IMAGING:Key Features:• W irelessly import images from the camera’s SD card • S tream live video• R emotely control & record images and video• A nalyze & tune radiometric images - measure temperatures • C reate PDF reports with text & custom logos• S hare images & reports using email, , or DropboxEquipment described herein may require US Government authorization for export purposes. Diversion contrary to US law is prohibited. Imagery for illustration purposes only. Specifications are subject to change without notice. For the most up-to-date specs, visit our website: . ©2017 FLIR Systems, Inc. All other brand and product names are trademarks of FLIR Systems, Incorporated. 17-2691-INS-OGI/OGI NASDAQ: FLIRBOSTONFLIR Systems, Inc. 9 Townsend West Nashua, NH 03063 USAPH: +1 866.477.3687PORTLANDCorporate Headquarters FLIR Systems, Inc.27700 SW Parkway Ave.Wilsonville, OR 97070USAPH: +1 866.477.3687EUROPE FLIR Systems Luxemburgstraat 22321 Meer BelgiumPH : +32 (0) 3665 5100HONG KONGFLIR Systems Co., Ltd Rm 1613-16, Tower II Grand Central Plaza 138 Shatin Rural Committee Road Shatin, New Territories Hong KongTEL: +852 2792 8955LATIN AMERICA FLIR Systems Brasil Av. Antonio Bardella, 320Sorocaba, SP 18052-852BrasilTEL: +55 15 3238 7080CANADAFLIR Systems, Ltd.920 Shelton Ct.Burlington, ON L7L 5K6CanadaPH: +1 800.613.0507call 866.477.3687 to speak with a FLIR Specialist.。

使用FLIR A320红外热像仪进行自动化质量控制，确保Ford Genk生产出性能卓越的汽车FLIR A系列红外热像仪：精确、可靠、免维护。

福特汽车公司于1903年由Henry Ford创立，最初是一家美国跨国公司。

福特使用精心设计的以流动装配线为代表的制造工序，引进了汽车大规模生产和工业劳动力的大规模管理方法。

到1914年，福特汽车的这些方法发展为“福特主义”，闻名世界。

福特集团目前是美国第二大汽车制造商，每年的汽车销量世界排名第四。

福特在世界各地拥有110个生产工厂，遍布于25个国家。

其中一个生产工厂位于比利时：Ford Genk。

Ford Genk现有员工10,000余名，产量占比利时汽车总生产量的60%之多。

FLIR A320红外热像仪是一款既实惠又精确的非接触式热成像和测温工具。

Ford Genk质量控制部负责人Arthur Knuysen查看测试结果。

可编程逻辑控制器(PLC)将红外热像仪的测量数据与预定义参数值进行比较。

Ford Genk装有三台FLIR A320红外热像仪，用于测试汽车前窗加热系统、后窗加热系统和空调系统。

标红处即红外热像仪的位置。

这台FLIR A320红外热像仪用于检查汽车前窗加热系统是否含有故障加热元件。

对每款配有前窗加热系统的车型而言，加热系统略有区别，因此测试更难进行。

Rato提供的汽车后窗控制系统不适用于该应用。

相反，FLIR A320红外热像仪可记录指定方形区域内的最大测温值和最小测温值，PLC将这些读数与预定义参数值进行比较。

自成立以来，福特集团一直针对生产问题寻求现代化工作和开发新自动化解决方案的方式。

近期的一个创新之举是为Ford Genk的产品测试中新添了FLIR红外热像仪。

每辆车均经过测试Ford Genk质量控制部负责人Arthur Knuysen解释道：“我们的产品测试旨在测试各种不同的汽车零部件。

测试范围包括抗振测试、斜坡试验、测试汽车标志的位置是否合理测试、雨刷测试、照明测试等等。

FLIR A325scThermal imaging camera for real-time analysis EXCELLENT IMAGE QUALITY AND THERMAL SENSITIVITYFLIR A325sc is equipped with an uncooled Vanadium Oxide (VoX) microbolometer detector that produces thermal images of 320 x 240 Pixels. These pixels generate crisp and clear detailed images that are easy to interpret with high accuracy. The FLIR A325sc will make temperature differences as small as 50 mK clearly visible.FAST DATA TRANSFERFLIR A325sc comes with a RJ-45 Gigabit Ethernet connection which supplies 14-bit 320 × 240 images at rates as high as 60 Hz.GIGE VISION™ STANDARD COMPATIBILITYGigE Vision allows fast image transfer using low cost standard cables up to 100 meters. With GigE Vision, hardware and software from different vendors can integrate seamlessly over gigabit ethernet connections.GENICAM™ PROTOCOL SUPPORTGenICam creates a common application programming interface (API) for cameras regardless of the interface technology or features implemented. Because the API for GenICam cameras will always be the same, cameras like the A325sc can be easily integrated into third party software.SOFTWAREFLIR A325sc camera works seamlessly with FLIR ResearchIR Max software enabling intuitive viewing, recording and advanced processing of the thermal data provided by the camera. A Software Developers Kit (SDK) is optionally available.MATHWORKS® MATLABControl and capture data directly into MathWorks ® Matlab software for advanced image analysis and processing.KEY FEATURES• Uncooled microbolometer: 320 x 240 pixels • Gigabit ethernet interface• Close-up and telephoto lenses available• ResearchIR max software included • Matlab compatibleVerification of PCBJet engineImaging SpecificationsSpecifications are subject to change without notice©Copyright 2014, FLIR Systems, Inc. All other brand and product names are trademarks of their respectiveowners. The images displayed may not be representative of the actual resolution of the camera shown. Images for illustrative purposes only. (Created 08/14) NASDAQ: FLIRPORTLANDCorporate Headquarters FLIR Systems, Inc.27700 SW Parkway Ave.Wilsonville, OR 97070USAPH: +1 866.477.3687BELGIUMFLIR Systems Trading Belgium BVBALuxemburgstraat 22321 Meer BelgiumPH: +32 (0) 3665 5100SWEDENFLIR Systems AB Antennvägen 6, PO Box 7376SE-187 66 Täby SwedenPH: +46 (0)8 753 25 00NASHUAFLIR Systems, Inc.9 Townsend West Nashua, NH 06063USAPH: +1 603.324.7611UKFLIR Systems UK 2 Kings Hill Avenue Kings HillWest Malling - Kent ME19 4AQUnited KingdomPH: +44 (0)1732 220 011Power Connector, Screw Terminal 2-pole: 10-30 VDC, <10W Gigabit Ethernet Port, 1000 mB,RJ-45 Connector: Control and image streamingDigital I/O Connector, Screw Terminal 6-pole:Digital Out: 2 outputs, opto-isolated, 10-30V supply, 100mA. Digital In: 2 inputs, opto-isolated, 10-30 V.。

KSF-320Gas Thermal Imaging CameraTYPICAL APPLICATIONS:»Electric Power Industry: Detect and visualize the SF6 and other harmful gases leaks and thermal imaging status from the insulation electrical equipments, ma-chines and high-voltage equipment switchgear; Failure diagnose.»Petrochemical Industry: oil pipeline check, material interface detection, heat leakage, insulation structure and power equipment detection.»Fire Protection: forest fire protection and latent fire source search, self-ignition prevention and detection of special material, electric fire precaution detect.»Medical Application: Accurately measures human body temperature and analyzes temperature field distribution.»Building Industry: humidity, air leakage and insulation defects detection.»Other Applications: Research and development industry, automation industry, and preventive maintenance, etc.FEATURES:»Cooled QWIP detector, sensitivity <0.025o C,pinpoint gas leaks location quickly, »SF6 Detection accuracy ≤ 0.001ml/s»Dual-application: Gas leakage detection and thermograph application, »Temperature range: -20~500o C,»Inspection without interrupted process, »Interchangeable lenses available, »Built-in 5.0 MP digital camera, »Folding and 270° rotatable displayGAS LEAKAGE DETECTION:SF6, Furan, NH3, MEK, Cyanoacrylate, Chlorine, Dioxide, Acetyl Chloride, Hydrazine, Allyl Bromide, Allyl Chloride, Vinyl, Allyl Fluorid, Methyl Bromide, EA, Tetrahydrofuran, Silane, Acetic Acid, Freon-12, Chloroethylene, Acrolein, Propylene, Acrylonitrile, Vinethene, Trichloroethylene, Uranium Fluoride, etc.OVERVIEWKSF-320 - Gas Thermal Imaging Camera is equipped with cooled detector (QWIP , NETD<25mk) to scan large areas rapidly and pinpoint the gas leaks location accurately, also monitors and inspects the equipments that are difficult to reach with contact measurement tools. It is a multifunctional device for gas leakage detection and thermograph applications. KSF-320 provides safe & efficient inspection at long distance without shutting systems down. Camera produces the crisp thermal image and accurate temperature reading of numerous objects to you, is also packed with SD card to store thermal images and voice annotation, forthe computer analysis.SPECIFICATIONSDetector DataDetector type Cooled QWIP Resolution320x256Pixel pitch30 μmSpectral range10.3～10.7μm, wave crest 10.55 μm Sensitivity/NETD<25mK～@ 30o CFOV/Min focus10°× 7.5° / 0.5m Standard20° x 15° / 0.25m Optional Spatial resolution (IFOV)0.55mrad (10°× 7.5°) Image PerformanceImage frequency60HzFocus ManualDigital zoom1~8 ContinousVisual camera 5.0 mega pixel Spotlight10cd/m2Image DisplayViewfinder0.6” color OLED,with magnification Image display5” , 270° tiltable LCD, 800×480 Auto image adjustment Linear or histogram based Manual image adjustment Level/SpanImage modesThermal image,visual image, High Sensitivity ModeMeasurementTemperature range-20o C~500o C Temperature accuracy±2o C or ±2% of reading Measuring calibration Auto/Manual Spotmeter10 moveable spotsArea 5 adjustable boxes with max/min/average tempLine profile Horizontal/verticalEmissivity correction Variable from 0.01~1.0, or correctthe emissivity by predefine values Alarm Voice and ColorColor palettes 12 palettes (incl. Iron, rainbow,black hot,white hot)Image adjustment Auto/Manual brightness andContrast adjustmentSet-up commands Date/Time, temperature unitso C/o F/o K, LanguageBackground temperature correction Automatic, base on inputbackground temperatureAtmospheric transmissivity correction Automatic, base on input reflection environment temperature, distance, relative humidity, atmospheric transmission and external opticalparametersMultiple language menu 10 languages (English, French,Italian, German, Spanish,Portuguese, Russian,Korean Japanese, SimplifiedChinese & Traditional Chinese)Image StorageDetector type8G Micro SD(2 pcs), 32G optionalIR image format Single frame, JPG format,16-bit measurement data includedVisual image formatSingle frame, JPG format, visualimages auto correlation withinfrared imagesStorage typeManual/Auto single frame imagestorage, continuous visible and IRimagePeriodic image storage10 seconds to 24 hoursVoice annotation40s voice annotation, stored asimage/videoVideo storageHigh definition video stored inSD card (MPEG-4/H.264 format),recording time up to 4 hour for per videoLaser PointerGrade/Type Class II, 1mW/635nm redPower SystemBattery Li-ion, chargeable and replaceableOperating time 2 hours continuous operating(Normal temperature)Charging system Intelligent charger,AC adapter or car adapterExternal power12VPower saving YesEnvironmental DataOperating temp. range-15o C~+40o CStorage temp. range-30o C~+60o CHumidity≤95% (non-condensation)Electromagnetic compatibilityEN61000-6-4 & EN61000-6-2FCC47CFR Part15 class AEN61000-4-8, L5IP level IP54 (IEC60529)Shock25G, IEC60068-2-29Vibration2G, IEC60068-2-6Physical DataCamera weight≤2.4 kg (incl. batteryand standard lens)Camera size (L×W×H)306mm × 140mm × 162mmData Communication InterfaceUCB Radiometric images transfer to andfrom PCVideo output CVBSAudio output YesPower YesSize of screw nut on tripod1/4”_20Gases DetectionSulfur Hexafluoride (SF6), Ammonia (NH3), Cyanoacrylate, chlorine dioxide,acetic acid, freon-12, methyl ethyl ketone(MEK), etc.PackingThermal imaging camera with Standard lens, 2 Batteries, Batter charger,Adapter, SD card, SD card reader, CD-ROM, Warranty extension card orRegistration card, Calibration certificate。

TECHNICAL NOTEIn the field of research and development (R&D) thermal imaging cameras are already an established tool for the evaluation of solar cells and panels. For these sophisticated measurements, usually high performance cameras with cooled detectors are used under controlled laboratory conditions.However, the use of thermal imaging cameras for solar panel evaluation is not restricted to the field of research. Uncooled thermal imaging cameras are currently being used more and more for solar panel quality controls before installation and regular predictive maintenance checkups after the panel has been installed. Because these affordable cameras are handheld and lightweight, they allow a very flexible use in the field.With a thermal imaging camera, potential problem areas can be detected and repaired before actual problems or failures occur. But not every thermal imaging camera is suited for solar cell inspection, and there are some rules and guidelines that needto be followed in order to perform efficient inspections and to ensure that you drawcorrect conclusions. The examples in this article are based on photovoltaic modules with crystalline solar cells; however, the rules and guidelines are also applicableto the thermographic inspection of thin-film modules, as the basic concepts of thermography are the same.PROCEDURES FOR INSPECTING SOLAR PANELS WITH THERMAL IMAGING CAMERAS During the development and production process, solar cells are triggered either electrically or by the use of flash lamps. This ensures that there is sufficient thermal contrast for accurate thermographic measurements. This method cannot be Thermal imaging cameras: a fast and reliable tool for testing solar panels.applied when testing solar panels in the field, however, so the operator must ensure that there is a sufficient energy input by the sun.To achieve sufficient thermal contrast when inspecting solar cells in the field, a solar irradiance of 500 W/m 2 or higher is needed. For the maximum result a solar irradiance of 700 W/m 2 is advisable. The solar irradiance describes the instantaneous power incident on a surface in units of kW/m 2, which can be measured with either a pyranometer (forglobal solar irradiance) or a pyrheliometer (for direct solar irradiance). It stronglydepends on location and local weather. Low outside temperatures may also increase thermal contrast.Quality assurance is of fundamental importance for solar panels. The failure-free operation of the panels is a prerequisite for efficient power generation, long life, and a high return on the investment. To ensure this failure free operation a fast, simple and reliable method to evaluate a solar panel's performance is required, both during the production process and after the panel has been installed. The use of thermal imaging cameras for solar panel evaluation offers several advantages. Anomalies can clearly be seen on a crisp thermal image and - unlike most other methods - thermal cameras can be used to scan installed solar panels during normal operation. Finally, thermal cameras also allow to scan large areas within a short time frame.Thermogram with level and span in automaticmode (above) and in manual mode (below).TECHNICAL NOTE predictive maintenance inspectionshighest when the camera is perpendicular, and decreases with an increasing angle. A viewing angle of 5–60° is a good compromise (where 0° is perpendicular).LONG DISTANCE OBSERVATIONS It is not always easy to achieve a suitable viewing angle during the measurement set-up. Using a tripod can provide a solution in most cases. In more difficult conditions it might be necessary to use mobile working platforms or even to fly over the solar cells with a helicopter. In these cases, the longer distance from the target can be advantageous, since a larger area can be seen in one pass. To ensure the quality of the thermal image, a thermal imaging camera with an image resolution of at least 320 × 240 pixels, preferably 640 × 480 pixels, should be used for these longer distances.The camera should also have an interchangeable lens, so the operator can switch to a telephoto lens for long distance observations, such as from a helicopter. It is advisable, however, to only use telephoto lenses with thermal imaging cameras that have a high image resolution. Low resolution thermal imaging cameras will be unable to pick up the small thermal details thatindicate solar panel faults in long distance measurements using a telephoto lens.LOOKING AT IT FROM A DIFFERENT PERSPECTIVE In most cases installed photovoltaic modules can also be inspected with a thermal imaging camera from the rear of amodule. This method minimizes interfering reflections from the sun and the clouds. In addition, the temperatures obtained at the back may be higher, as the cell is being measured directly and not through the glass surface.AMBIENT AND MEASUREMENT CONDITIONS When undertaking thermographic inspections, the sky should be clear since clouds reduce solar irradiance and also produce interference through reflections. Informative images can, however, be obtained even with an overcast sky, provided that the thermal imaging camera used is sufficiently sensitive. Calm conditions are desirable, since any airflow on the surface of the solar module will cause convective cooling and thus will reduce the thermal gradient. The cooler the air temperature, the higher the potential thermal contrast. Performing thermographic inspections in the early morning is an option.Another way to enhance thermal contrast is to disconnect the cells from a load, to prevent the flow of current, which allowsheating to occur through solar irradiance alone. A load is then connected, and the cells are observed in the heating phase.Under normal circumstances, however, thesystem should be inspected under standard operating conditions, namely under load. Depending on the type of cell and the kind of fault or failure, measurements under no-load or short-circuit conditions can provide additional information.MEASUREMENT ERRORSMeasurement errors arise primarily due to poor camera positioning and suboptimal ambient and measurement conditions. Typical measurement errors are caused by:• too shallow viewing angle • c hange in solar irradiance over time (due to changes in sky cover, for example)• r eflections (e.g., sun, clouds,surrounding buil d ings of greater height, measurement set-ups)• p artial shadowing (e.g., due to surrounding buildings or other structures).Thermal image made using a FLIR P660 cameraon a flight over a solar farm. (Thermogramcourtesy of Evi Müllers, IMM)In order not to draw false conclusions you need to hold the thermal imaging camera under a correct angle when inspecting solar panels.This thermal image shows large areas withelevated temperatures. Without more information, it is not obvious whether these are thermal anomalies or shadowing/reflections.Thermal image of the back of a solar module taken with a FLIR P660 camera. Its corresponding visual image is shown on the right.For more information visit or contact:FLIR Commercial Systems B.V.Charles Petitweg 214847 NW Breda - Netherlands Phone : +31 (0) 765 79 41 94Fax : +31 (0) 765 79 41 99e-mail :*************T 820228 {E N _u k }_ATECHNICAL NOTEWHAT CAN YOU SEE IN THE THERMAL IMAGEIf parts of the solar panel are hotter than others, the warm areas will show up clearly in the thermal image. Depending on the shape and location, these hot spots and areas can indicate several different faults. If an entire module is warmer thanusual that might indicate interconnection problems. If individual cells or strings of cells are showing up as a hot spot or a warmer ‘patchwork pattern’, the cause can usually be found either in defective bypass diodes, in internal short-circuits, or in a cell mismatch.Shadowing and cracks in cells show up as hot spots or polygonal patches in thethermal image. The temperature rise of a cell or of part of a cell indicates a defective cell or shadowing. Thermal images obtained under load, no-load, and short-circuit conditions should be compared. A comparison of thermal images of the front and rear faces of the module can also give valuable information. Of course, for correct identification of the failure, modules showing anomalies must also be tested electrically and inspected visually.CONCLUSIONSThe thermographic inspection of photovoltaic systems allows the fast localization of potential defects at the cell and module level as well as the detection of possible electrical interconnection problems. The inspections are carried out under normal operating conditions and do not require a system shut down.For correct and informative thermal images, certain conditions and measurement procedures should be observed:• a suitable thermal imaging camera with the right accessories should be used;• s ufficient solar irradiance is required (at least 500 W/m 2 – above 700 W/m 2 preferred);• t he viewing angle must be within the safe margins (between 5° and 60°);• s hadowing and reflections must be prevented.Thermal imaging cameras are primarily used to locate defects. Classification and assessment of the anomalies detected require a sound understanding of solar technology, knowledge of the system inspected, and additional electrical measurements. Proper documentation is, of course, a must, and should contain all inspection conditions, additional measurements, and other relevant information.Inspections with a thermal imagingcamera - starting with the quality control in the installation phase, followed by regular checkups - facilitate complete and simple system condition monitoring. This will help to maintain the solar panels' functionality and to extend their lifetime. Using thermal imaging cameras for solar panel inspections will therefore drastically improve the operating company’s return oninvestment.Table 1: List of typical module errors (Source: ZAE Bayern e.V , “Überprüfung der Qualität von Photovoltaik-Modulen mittels Infrarot-Aufnahmen” ["Quality testing in photovoltaic modules using infrared imaging”], 2007)These red spots indicate modules that are consistently hotter than the rest, indicating faulty connections.This hot spot within one solar cell indicates physical damage within the cell.This thermal image shows an example of the so-called ‘patchwork pattern’, which indicates that this panel has a defective bypass diode.。