C7012紫外线传感器资料

紫外线消毒灯用到的芯片紫外线消毒灯是一种利用紫外线进行杀菌消毒的设备，常用于医疗、卫生、食品等领域。

在紫外线消毒灯中，芯片起到了至关重要的作用，它们可以控制消毒灯的工作模式、定时、功率等参数。

以下是一些可能用于紫外线消毒灯的芯片：1. 微控制器芯片：这是紫外线消毒灯的核心芯片之一，它负责控制整个消毒灯的工作流程。

微控制器芯片可以通过编程实现定时开关、功率调节、紫外线强度控制等功能。

常见的微控制器芯片包括STM32、Arduino 等。

2. 紫外线传感器芯片：用于检测紫外线的强度和波长。

这些芯片通常包含光敏元件，可以将紫外线转换为电信号，并将其发送给微控制器芯片进行处理。

紫外线传感器芯片可以帮助确保消毒灯的紫外线输出符合设定要求，提高消毒效果。

3. 电源管理芯片：负责为紫外线消毒灯提供稳定的电源。

这些芯片可以将输入的交流电转换为直流电，并根据需要调整电压和电流输出。

电源管理芯片还可以实现过载保护、短路保护等功能，确保设备的安全运行。

4. 通信芯片：用于实现紫外线消毒灯与其他设备之间的通信。

这些芯片可以支持无线通信协议或有线通信接口，以便将消毒灯连接到智能家居系统或远程监控平台。

5. 显示驱动芯片：用于驱动紫外线消毒灯的显示屏。

这些芯片可以控制显示屏的亮度、对比度和颜色，以便用户能够直观地了解消毒灯的工作状态和参数。

需要注意的是，不同的紫外线消毒灯可能会使用不同类型和规格的芯片，具体取决于设备的功能需求和设计要求。

此外，随着技术的不断发展，新的芯片和技术也在不断涌现，为紫外线消毒灯的性能提升和功能扩展提供了更多可能性。

总之，紫外线消毒灯中的芯片是实现设备智能化、高效化和安全化的关键。

通过合理选用和配置芯片，紫外线消毒灯可以更好地满足用户的需求，为人们的健康和生活质量提供保障。

PRODUCT DATA60-2398-10® U.S. Registered TrademarkCopyright © 2000 Honeywell • All Rights ReservedC7012A,C,E,F,GSolid State Purple Peeper® Ultraviolet Flame DetectorsAPPLICATIONThe C7012A,C,E,F,G Flame Detectors are solid-stateelectronic devices for sensing the ultraviolet radiation emitted during combustion of most carbon-containing fuels such as natural gas, LP gas, and oil.FEATURESAll models•Solid-state electronic circuitry provides low power consumption and high reliability.•Solid-state models directly replace previous models with vacuum electron tube circuitry.•Detectors can be mounted horizontally, vertically or at any angle. The self-checking C7012E,F models require faceplate alignment and have integral locatingreference points to assure proper shutter mechanism operation.•Ultraviolet radiation sensing tube and quartz viewing window are field replaceable.•Threaded conduit fitting and color-coded leadwires allow rapid electrical installation.•Two flame detectors can be wired in parallel to reduce nuisance shutdowns in difficult flame sighting applications.• A swivel mount is available to facilitate flame sighting.•Models are available with a -40°F (-40°C) rating.C7012A,C,G•Designed for use with Honeywell Flame Safeguard Controls using Honeywell Rectification (R7247A, R7289A, R7747A, R7847A1082) and Ampli-Checkª Rectification (R7247B, R7747B, R7847B1072) Flame Signal Amplifiers.•C7012G models available to meet BGC (British) and DIN (German) requirements.C7012E,F•Incorporate UV sensor tube checking feature; used with Honeywell Dynamic Self-Check (R7247C, R7747C, R7847C) Flame Signal Amplifiers.C7012A,E,GC7012C,FContentsApplication ........................................................................1Features ...........................................................................1Specifications ...................................................................2Ordering Information ........................................................2Installation ........................................................................4Adjustments and Checkout ..............................................11Troubleshooting ................................................................13Service .. (14)C7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS60-2398—102ORDERING INFORMATIONWhen purchasing replacement and modernization products from your TRADELINE® wholesaler or distributor, refer to the TRADELINE® Catalog or price sheets for complete ordering number.If you have additional questions, need further information, or would like to comment on our products or services, please write or phone:1.Your local Home and Building Control Sales Office (check white pages of your phone directory).2.Home and Building Control Customer RelationsHoneywell, 1885 Douglas Drive NorthMinneapolis, Minnesota 55422-4386 (800) 328-5111In Canada—Honeywell Limited/Honeywell Limitée, 35 Dynamic Drive, Scarborough, Ontario M1V 4Z9.International Sales and Service Offices in all principal cities of the world. Manufacturing in Australia, Canada, Finland, France, Germany, Japan, Mexico, Netherlands, Spain, Taiwan, United Kingdom, U.S.A.•Oscillating shutter interrupts ultraviolet radiation reaching UV sensor between 60 and 120 times per minute (10 times per minute with R7747C dynamic self-check amplifiers) to provide the UV sensor tube checking function. Amplifier circuitry components are checked from the microprocessor in the BCS 7700 or 7800 SERIES Control.•C7012E is available to meet BGC (British) and DIN (Germany) requirements.C7012A,E,G•Housing meets NEMA 4 enclosure standards (indoor, outdoor protection: rain-tight, dust-tight, hose-directed watertight).•Protective heat block built into mounting flange.•High pressure 50 psi (345 kPa) quartz viewing window, focusing lens, swivel mount and antivibration mounting accessories available.C7012C,F•Housing designed to be explosion-proof and Underwriters Laboratories Inc. listed for use inhazardous locations; Class 1, groups C and D; and Class 2, groups E, F, and G.•Viewing window rated for 100 psi (690 kPa).SPECIFICATIONSIMPORTANTThe specifications in this publication do not include normal manufacturing tolerances. Therefore, this unit may not exactly match the specifications listed. This product is tested and calibrated under closely controlled conditions, and minor differences inperformance can be expected if those conditions are changed.Models:C7012A Solid State Purple Peeper® Ultraviolet Flame Detector: For use in rectification type flame safeguard systems.C7012C Solid State Purple Peeper® Ultraviolet Flame Detector: Same as C7012A except with explosion-proof housing for use in hazardous locations.C7012E Self-Checking Solid State Purple Peeper® Ultraviolet Flame Detector: For use with R7247C, R7747C, and R7847C Dynamic Self-Check Amplifiers.C7012F Self-Checking Solid State Purple Peeper® Ultraviolet Flame Detector: Same as C7012E except withexplosion-proof housing for use in hazardous locations.C7012G Solid State Purple Peeper® Ultraviolet Flame Detector: Same as C7012A except designed to meet BGC (British) and DIN (German) requirements.Electrical Ratings:Voltage and Frequency:C7012A: Separate models for 100, 120, 208, or 240 Vac, all 50/60 Hz.C7012E: Separate models for 100, 120, 208, or240 Vac, all 50/60 Hz; also models for 110 or 220 volts, 50 Hz only.C7012C and F: 120 Vac, 50/60 Hz.C7012G: Models for 110, 220, or 240 volts, 50 Hz only.Power Consumption:C7012A,C and G: 2.5 watts maximum.C7012E and F: 7.0 watts maximum.Ambient Operating Temperature Ratings (Outside the Case):C7012A,C and G: 25°F to 175°F (-4°C to 79°C).C7012E and F: -20°F to 175°F (-29°C to 79°C).C7012A1160 and C7012E1120: -40°F to 175°F (-40°C to 79°C).Storage Temperature Ratings:-60°F to 175°F (-51°C to 79°C).Housing:C7012A,E and G: Violet, cast-aluminum cover; mounting flange (with heat block) and faceplate are separate to provide heat insulation and sealoff. Meets NEMA 4 enclosure requirements (indoor, outdoor protection;rain-tight, dust-tight, hose-directed water). Optional water jacket available for the C7012A,E,G.C7012C and F: Explosion-proof, two-piece, violet, cast aluminum.Pressure Rating Of Quartz Viewing Window:C7012A,E and G: 20 psi (138 kPa). Focusing lens:20 psi (138 kPa) rating or high pressure viewing window 50 psi (345 kPa) rating available; see Accessories section.C7012C and F: 100 psi (690 kPa).C7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS360-2398—10Mounting:C7012A and E: Mounting flange with either 3/4 or 1 inch NPT internal threads (depending on model) for attaching to sight pipe.C7012G: Mounting flange with 3/4 inch NPT internal threads for attaching to sight pipe.C7012C and F: Pipe union with 1 inch NPT internal threads for attaching to sight pipe.Wiring Connections:NEC Class 1 Color-Coded Leadwires:Length: 8 feet (2.4 meters).Number of Leadwires:C7012A and C: 4.C7012E and F: 6.C7012G: 5.NOTE:Models designed to meet DIN (German) andBGC (British) requirements have an additional yellow/green leadwire that is used as a separate ground wire.Threaded Leadwire Opening in Faceplate:C7012A and E: 1/2-14 NPSM internal threads for attaching conduit.C7012C and F: 1/2-14 NPT internal threads for attaching pipe.Dimensions: See Fig. 1 or 2.Weight:C7012A,E and G: Approximately 4.25 pounds (1.9 kg).C7012C and F: Approximately 14.5 pounds (6.6 kg).Serviceability:All Models: Field-replaceable viewing window and ultraviolet sensing tube.C7012E and F: Field-replaceable self-checking coil and shutter assembly.NOTE:The new 190971B Coil and Shutter Assembly canbe used on existing C7012 Detectors with electron tubes, but the old 120625B Coil and Shutter Assembly cannot be used on solid state C7012 Flame Detectors.Interchangeability:Solid State C7012A,C,E,F and G Purple Peeper¨ Ultraviolet Flame Detectors are interchangeable with similar models of earlier C7012 Flame Detectors.Approvals:Underwriters Laboratories Inc. Listed (120 Volt Models Only):C7012A and E (except C7012E1161 and E1278): File no. MP268.C7012C and F: For use in hazardous locations; Class 1, Groups C and D; Class 2, Groups E, F and G; File no. E34649.Canadian Standards Association Certified (120 Volt Models Only):C7012A and E: Master File LR95329-1.Factory Mutual Approved: A,C,E and F models, 14740.01.Industrial Risk Insurers: Acceptable.DIN: 220 volt models of European C7012E and G are designed to meet DIN requirements.British Gas Corporation: 110 and 240 volt models of European C7012E and G are designed to meet British Gas Corporation requirements.Replacement Parts:All Models:113228 Ultraviolet Sensing Tube.191286 Ultraviolet Sensing Tube for -40°F (-40°C) operation.C7012A,E and G:114372 Quartz Viewing Window; rated for 20 psi (138 kPa).32004080-001 Electronic Assembly (C7012A)192702 Electronic Assembly with Shutter (C7012E)114465 Gasket, silicone rubber; for installing viewing window (three required).120739 Gasket, fiber-neoprene; heat insulation and seal-off for mounting flange.C7012C and F:122037 Quartz Viewing Window; rated for 100 psi (690 kPa).C7012E and F:190971B Coil and Shutter Assembly for all models except 220V/50 Hz.Fig. 1. Dimensions of C7012A,E, and G in in. (mm).Fig. 2. Dimensions of C7012C and F in in. (mm).Accessories:All Models:118369 Bushing, galvanized iron, with 3/4 inch NPT internal threads on one end and 1 inch NPT external threads on the other end. For adapting a detector with 1 inch NPT internal threads (for mounting) to a 3/4 inch sight pipe, or to the pipe nipple and tee for connecting an air supply.MOUNTING FLANGE 1/2–14 NPSM LEADWIRESFACEPLATE3/4–14 NPTM1962B3-3/4(95)7-7/32(183)5-1/8 (130)3-7/16(87)5-1/4 (133)C7012A,C,E,F1/2–14 NPT 5(127)2(51)1(25)8(203)DIA.9 (229)2(51)2 (52)1161 (38)12 3 (76)LEADWIRESFACEPLATEPIPE UNION 1–11 1/2 NPT5/16–18 UNC –2B BY 7/16 (11) DEEPMOUNTING HOLES (2)M1963C7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS60-2398—104W136A Test Meter (includes 196146 Meter Connector Plug).117053 Meter Connector Plug (for older W136A models).118367A Swivel Mount.105172C Seal-off Assembly, for seal-off of 3/4 in. NPT pipe.204342 UV mirror with 3/4 in. NPT internal threads.C7012A,E and G:122748 Quartz Viewing Window, rated for 50 psi (345 kPa).124204 Quartz Focusing Lens, rated for 20 psi (138ÊkPa); for increasing the detector-sensed ultraviolet radiation.120934 Mounting Flange, aluminum, with 3/4 inch NPT internal threads for attaching to sight pipe.124198 Mounting Flange, aluminum, with 1 inch NPT internal threads for attaching to sight pipe.123539 Antivibration Mount.190105 Water Jacket.INSTALLATIONWhen Installing this Product...1.Read these instructions carefully. Failure to follow them could damage the product or cause a hazardous condition.2.Check the ratings given in the instructions and on the product to make sure the product is suitable for your application.3.Installer must be a trained, experienced flame safeguard service technician.4.After installation is complete, check out product operation as provided in these instructions.CAUTIONEquipment Damage Hazard.Sensing tube can fail to discriminate between flame conditions.Change sensing tube after 40,000 hours of continuous use.Appliances with burners that remain on continuously for24 hours or longer should use the C7012E,F Flame Detector and the R7247C, R7747C, or R7847C Amplifiers and associated controls.WARNINGElectrical shock hazard.Can cause serious injury or death.Disconnect power supply before beginning installation to prevent electrical shock and equipment damage. More that one disconnect can be involved.IMPORTANT1.Do not connect these detectors to non-Honeywell manufactured controls (primaries, programmers, multiburner systems, and burner management systems). Unsafe conditions could result.2.All wiring must be NEC Class 1 (line voltage).3.Voltage and frequency of the power supply con-nected to this detector must agree with the values marked on the detector.4.The detector must be sighted so it does not respond to ignition spark.5.On multiburner installations, each detector must respond only to the flame produced by the burner it is supervising.6.Do not connect more than two C7012 Flame Detectors in parallel.Proper flame detector installation is the basis of a safe and reliable flame safeguard installation. Refer also to the burner manufacturer instructions. Carefully follow the instructions for the best possible flame detection application.Basic RequirementsThe combustion flames of most carbon-based fuels emitsufficient ultraviolet radiation to enable the C7012 Solid State Purple Peeper ® Ultraviolet Flame Detector to prove thepresence of a flame in a combustion chamber. The detector is mounted outside the combustion chamber. Its mountingflange or union is threaded to one end of a sight pipe inserted through the wall of the combustion chamber. The ultraviolet sensing tube in the flame detector sights the flame through the pipe.When a flame is present, the UV tube in the C7012 senses the ultraviolet radiation emitted. The C7012 produces a signal that is sent to the amplifier in the flame safeguard control. The amplified signal pulls the flame relay into the control to allow proper operation of the system.Because it is necessary for the UV sensing tube to actually see the flame, it is best to locate the detector as close to the flame as physical arrangement, temperature, and otherrestrictions permit. These restrictions are described in detail in the following paragraphs.Determine LocationBefore beginning the actual installation, determine the best location for mounting the detector. Carefully consider the factors discussed in this section before deciding on the location.TemperatureInstall the C7012 where the ambient temperature (outside the case) stays within the ambient operating temperature ratings.To keep the C7012 below its maximum rating, it may benecessary to add additional insulation between the wall of the combustion chamber and the detector. A shield or screen can be added to reflect radiated heat away from the detector. If the detector continues to get too hot, cooling is necessary. Refer to the Sight Pipe Ventilation section. A 190105 Water Jacket is also available for cooling the C7012A,E,G Flame Detectors. See Accessories.Because of the slower cycle rate of the shutter when using the R7747C or R7847C Series 1-3 Amplifiers, additional heat is generated within the detector. Series 7 or later detectors are suggested for those applications.VibrationIf the C7012 is subject to excessive vibration, use a special 123539 Antivibration Mount for the C7012A,E or G. If you use this mount, install it before you position and sight the detector.C7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS560-2398—10ClearanceMake sure there is enough room to easily mount the sight pipe, detector and all required fittings, and to remove the detector for troubleshooting and servicing.Radiation Sources (Other Than Flame)Examples of radiation sources (other than flame) that could actuate the detection system:1.Ultraviolet sources:a.Hot refractory above 2300°F (1260°C).b.Spark:(1)Ignition transformers.(2)Welding arcs.(3)-Lightning.c.Welding flames.d.Bright incandescent or fluorescent artificial light.e.Solar radiation.f.Gas lasers.g.Sun lamps.h.Germicidal lamps.i.Bright flashlight held close to sensing tube.2.Gamma ray and X-ray sources:a.Diffraction analyzers.b.Electron microscopes.c.Radiographic X-ray machines.d.High voltage vacuum switches.e.High voltage condensers.f.High voltage coronas.g.Radioisotopes.Except under unusual circumstances, none of these sources except hot refractory and ignition spark would be present in or near the combustion chamber.The detector may respond to hot refractory above 2300°F (1260°C) if the refractory surface represents a significant percentage of the detector field of view. If the temperature of the hot refractory causes the flame relay (in the flame safeguard control) to pull in, re-aim the sight pipe so the detector views a cooler area of the refractory.Ignition spark is an intense source of ultraviolet radiation. When installing the detector, make sure it does not respond to ignition spark.Single Burner RequirementsThe detector must have an unobstructed view of a steady part of the flame it is supervising. This requires a proper sighting angle and minimized ultraviolet radiation attenuation effects. Supervising only one burner simplifies sighting requirements.Sighting Angle (Fig. 3)The first 30 percent of a flame closest to the burner nozzle (the flame root) emits the most ultraviolet energy. Also, if the detector sights the flame at an angle instead ofperpendicularly, it views more flame depth. Therefore, the best sighting angle is nearly parallel to the axis of the flame, permitting the detector to view a large portion of the first 30 percent of the flame closest to the burner nozzle, as illustrated in Fig. 3.Low angle sighting permits the detector to view a greater depth of flame, thus reducing the effects of instabilities in the flame pattern. Also, the environment near the burner nozzle is usually cleaner than at any other part of the combustion chamber. This provides a clearer line of sight and can keep the viewing window cleaner, thus reducing the maintenance required.Fig. 3. Detector sighting angle.NOTE:When possible, it is desirable to tilt the detector andsight pipe downward to prevent the buildup of soot in the pipe or on the viewing window.In most installations, the detector needs to respond to the pilot flame alone, then the pilot and main burner flame together, and finally the main burner flame alone. The detector must meet all sighting requirements that apply:Pilot flame alone —the smallest pilot flame that can be detected must be capable of reliably igniting the main burner.Pilot and main burner flame together —the detector must sight the junction of both flames.Main burner flame alone —the detector must sight the most stable part of the flame for all firing rates.Parallel Flame DetectorsShifting flame patterns, commonly encountered on burners with high turndown ratios, can require two parallel detectors to prove the flame at the highest and lowest firing rates and for modulation in between. In this case, one detector supervises the pilot (interrupted) and both detectors supervise the main burner flame. During the main burner run period, either detector is capable of maintaining system operation. A maximum of two C7012 Detectors can be connected in parallel.In addition to assuring more reliable flame detection, parallel detectors facilitate maintenance during burner operation.Each detector can be removed, in turn, without shutting down the supervised burner. However, a flame simulating failure occurring in the flame signal amplifier or in either detector causes a shutdown.FLAME DEPTH –ANGLE VIEWM1956DETECTOR IN GOOD SIGHTING POSITION (LOW ANGLE SIGHTING)UNBURNED FUELFLAME DEPTH –PERPENDICULAR VIEW BURNER NOZZLEDETECTOR IN POOR SIGHTING POSITIONC7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS60-2398—106Screening EffectsSmoke, oil mist, dirt and dust are masking agents thatattenuate the ultraviolet radiation that the flame emits. If they absorb too much radiation, the amount of ultraviolet radiation reaching the detector is reduced. The flame signal then can become too low to hold in the flame relay, resulting in burner shutdown.Diluting the contaminants can eliminate the problem. A strong flow of air through the sight pipe clears a viewing path through the attenuating material. Refer to the Sight Pipe Ventilation section.It is also desirable to sight the detector in an area containing fewer masking agents such as near the burner nozzle or near the entrance of the combustion air. Increasing the viewing area of the detector by shortening the sight pipe or by increasing the diameter of the sight pipe also reduces the attenuating effects of masking agents.Multiburner Requirements(Flame Discrimination)In addition to meeting the requirements for a single burner, a multiburner installation requires discrimination between flames. Flame discrimination can be defined as locating all flame detectors so that each detector responds only to the flame of the burner it is supervising.In multiple burner systems, not every detector can bepositioned so its line-of-sight does not intercept flames from other burners. For example, this situation occurs in front-fired boiler-furnaces having more than one row of burners, or in multilevel opposed-fired furnaces where the burners face each other.When planning such an installation, locate each flame detector so that it has the best possible view of the first 30 percent closest to the burner nozzle (the flame root) it is supervising, and the worst possible view of all other flames.Fig. 4 illustrates a critical detector application problem that requires flame discrimination. Flame discrimination isaccomplished for Detector A by repositioning it until the flame relay (in the flame safeguard control) does not respond to Flame B. Note that Detector A is aimed at the first 30 percent of Flame A where the ultraviolet radiation is most intense. It sights the tip of Flame B, but it is not aimed at the first 30 percent of Flame B where UV is intense. Detector A is repositioned to assure maximum response to Flame A while rejecting Flame B. Similarly, Detector B is positioned to assure maximum response to Flame B while rejecting Flame A.If you reposition a detector and still cannot achieve flame discrimination, try reducing the viewing area by increasing the length or decreasing the diameter of the sight pipe, or adding an orifice plate.Install the Sight Pipe (Fig. 5)After you have determined the location and sighting angle, select the sight pipe. A black iron pipe with a diameter of at least 1-1/2 in. (38 mm) is recommended. Do not use stainless steel or galvanized pipe because they reflect ultraviolet radiation internally and complicate aiming the pipe.Fig. 4. Example of flame discrimination problem (opposed-fired burners).Sight pipes with diameters 2 to 3 in. (51 to 76 mm) produce better results for horizontal rotary burners, which require wide viewing angles. A wide viewing angle can also be obtained by using a short sight pipe.Fig. 5. Typical mounting of C7012.Prepare Hole in Combustion Chamber WallCut or drill a hole of the proper diameter for the sight pipe inthe wall of the combustion chamber at the selected location. Flare the hole to leave room for small adjustments of the sighting angle. The taper of the hole should be about 1 in. for every 3 in. (25 mm for every 76 mm) of wall thickness.Mount Sight PipeThread one end of the pipe to fit the mounting flange, union, or required coupling. Cut the pipe to the desired length (as short as practical) and at an angle so it fits flush with the wall of the combustion chamber. Tack weld the pipe to the wall in a trial position. Do not weld the sight pipe permanently in place until after completing the Adjustments and Checkout procedures.M1957DETECTOR AFLAME A DETECTOR BFLAME B1CLOSE NIPPLE (3/4 in. FOR A C7012E; 1 in.FOR A C7012F.TEMPORARY TACK WELDCOMBUSTION CHAMBER WALLREDUCERBLACK IRON SIGHT PIPE (1-1/2 TO 3 in.[38 TO 76 mm] DIA.)REFRACTORY FLARED HOLE1IF VENTILATION OF THE SIGHT PIPE IS REQUIRED, ADD PIPE TEE, PERFORATED NIPPLE, OR OTHER SUITABLE DEVICE FOR VENTILATION.M6814C7012A,C,E,F ,G SOLID STATE PURPLE PEEPER® ULTRAVIOLET FLAME DETECTORS760-2398—10NOTE:If you use 118367A Swivel Mount and you arepositive about the location and sighting angle, you can permanently weld the pipe.Install FittingsIn some cases, the sight pipe will not directly fit the C7012 mounting flange or union. Also, it may be desirable ornecessary to ventilate the sight pipe. You may also want to use a swivel mount or an antivibration mount. Each of these cases can require additional fittings.ReducerFor sight pipes of larger diameter than the mounting flange connector or union, install a reducer as illustrated in Fig. 5. The reducer requires a close nipple with these external threads:C7012A or E: 3/4 or 1 in. NPT (depending on model).C7012C or F: 1 in. NPT.C7012G: 3/4 in. NPT.Sight Pipe VentilationIt may be necessary to ventilate the sight pipe to cool the detector or to clear a viewing path through UV radiation attenuating material.For a negative pressure combustion chamber, drilling a few holes in the section of the sight pipe outside of the combustion chamber allows air at atmospheric pressure to flow through the sight pipe and into the chamber. A perforated pipe nipple between the sight pipe and the detector can also be used.For a positive pressure combustion chamber, connect a supply of pressurized air from the burner blower to flowthrough the sight pipe and into the chamber. The air pressure must be greater than the chamber pressure.Swivel MountTo facilitate proper flame sighting, use 118367A Swivel Mount (order separately). The swivel mount requires a reducer of the proper size to mount it onto the sight pipe. It also requires a one-inch close nipple for mounting to a C7012 with a one-inch connector. (For 118367A Swivel Mount mounting details, refer to form 60-0361.)Antivibration Mount (C7012A,E, or G)The detector can withstand normal burner vibration. If the vibration is excessive, part no. 123539 Antivibration Mount is available for a C7012A,E or G. (For mounting details, see form 60-0361.) If you use this mount, install it before positioning and sighting the detector.Mount the Detector (Fig. 5-8)Mount the detector onto the sight pipe, reducer, or other fitting (see Fig. 5-8).The C7012A,C,G Flame Detectors do not have the oscillating shutter mechanism for checking the UV sensor so they can be mounted in any position suitable for the temperature environment.The C7012E,F Self-Checking Flame Detectors incorporate an oscillating shutter mechanism and, therefore, require special consideration for mounting positions other than vertically sighting downward or upward. The C7012E has notch and arrow indicators (see Fig. 6) on the faceplate to facilitatemounting. The notch and arrow must be vertically aligned with the notch in the up position and the arrow pointing downward (see Fig. 6). The C7012F must be mounted with the conduit opening located approximately 45 degrees below the horizontal (see Fig. 6).Fig. 6. C7012E,F mounting positions.IMPORTANTThe notch and arrow on the faceplate of the C7012E must be aligned in a vertical plane with the notch up and the arrow pointing downward .The C7012F housing must be mounted with the conduit opening approximately 45° below horizontal (see Fig. 6).To mount a C7012A,E or G (Fig. 7):1.The mounting flange has two pieces. Loosen (but do not remove) the three screws holding the flange together.2.Slightly rotate the detector so the slots in the back section of the mounting flange clear the screws in the front section; then separate the two sections.3.Screw the front section of the mounting flange onto the sight pipe, reducer, or other fitting.M6816C7012E, F CAN BE MOUNTEDHORIZONTALLY, VERTICALLY, OR AT ANY ANGLE IN BETWEENHORIZONTZAL PLANEVERTICAL PLANE90°90°111NOTCH IN FACEPLATE MUST BE UPHORIZONTZAL PLANENOTCH AND ARROW MUST ALWAYS BE ALIGNED IN A VERTICAL PLANE C7012E OR F MUST NOT BE ROTATED AROUND ITS AXISARROW ON FACEPLATE MUST BE POINTING DOWNWARD45°C7012F CONDUIT OPENING POSITION ADE IN U.S.A.MOUNT WITH ARROW DOWN1NOTE DOWNWARD POSITIONING OF CONDUIT OPENING.。

日盲紫外光电探测器结构日盲紫外光电探测器（Solar Blind Ultraviolet Photodetector）是一种能够在太阳能紫外线波段（200-280纳米）具有高响应度和低响应度的探测器。

它在紫外线波段的探测对于环境监测、军事侦查、卫星通信等领域都有重要的应用。

首先是光敏元件，它是日盲紫外光电探测器的核心部分，用于接收紫外光并产生电荷载流子。

常用的光敏元件有硅（Si）材料和氮化镓（GaN）材料的PIN结构二极管。

硅材料具有高响应度和低响应度的特点，但其长波边缘在280纳米左右，因此不能实现日盲性。

而氮化镓材料具有非常好的紫外光透过性，在200纳米以下具有低响应度，能够实现日盲特性。

其次是光学系统，它主要用于将入射的紫外光聚焦到光敏元件上，提高光信号接收效率。

光学系统通常由凸透镜和滤光片组成，凸透镜用于聚焦光线，滤光片用于屏蔽可见光和红外光。

进一步是电子信号处理系统，它主要用于放大和转换光敏元件产生的微弱电流信号。

电子信号处理系统通常由前置放大器、滤波器、放大器和模数转换器等组成。

前置放大器用于放大微弱电流信号，滤波器用于除去噪声和杂散信号，放大器用于进一步放大信号，模数转换器用于将模拟信号转换为数字信号。

最后是外壳保护，它用于保护整个光电探测器免受外界环境的干扰和损伤。

外壳通常采用金属材料制成，具有良好的导热性和机械强度，并可以有效地屏蔽外界干扰源。

总结来说，日盲紫外光电探测器的结构主要包括光敏元件、光学系统、电子信号处理系统和外壳保护。

光敏元件负责接收和产生电荷载流子，光学系统用于聚焦紫外光，电子信号处理系统用于放大和转换信号，外壳保护用于保护整个探测器。

这些部件的结合使得日盲紫外光电探测器能够高效地探测太阳能紫外线波段的信号。

一文读懂紫外线传感器人的五管是功能非常复杂、灵敏的“传感器”。

然而人的五官感觉大多只能对外界的信息作“定性”感知，而不能作定量感知。

而且有许多物理量人的五官是感觉不到的，例如对视觉可以感知可见光部分，对于频域更加宽的非可见光谱则无法感觉得到，象红外线和紫外线光谱，人类却是“视而不见”。

借助红外和紫外线传感器，便可感知到这些不可见光。

紫外线传感器紫外线传感器又叫紫外光敏管（简称紫外管），是一种利用光电子发射效应的光电管。

其特点是只响应300nm以下紫外辐射，具有高灵敏度、高输出、高响应速度等特性 , 并且抗干扰能力强、稳定可靠、寿命长、耗电少 , 因而在目前的安全防护、自动化控制方面有比较广泛的使用价值。

随着电子计算机的广泛应用, 为计算机服务的各类传感技术受到越来越多的重视。

紫外线传感器能检查到人感官觉察不到的紫外线 , 又能避免日光、灯光和其它常见光源的干扰, 对火陷的发现和熄火保护、特殊场所的光电控制都是很有用的。

紫外线传感器的结构分类目前国内外有使用价值的紫外管可以按阴极形状分为球形、丝形、平板形结构 , 均为二极管的电极结构形式 , 其外壳的形状和材料种类是为使用要求设计的 , 从工作状态上看 , 以电极形状分类进行分析较合适些。

1、丝状电极结构这类管子的电极一般是由两根或多根对称的金属丝组成 , 这是紫外管早期的一种结构形式 , 多用纯度高的钨丝或铂丝 , 距离较近的平行线是工作区。

由于紫外管完全靠电极表面的光电子发射效应 , 然后利用气体倍增获得较强的信号，其光谱响应范围取决于阴极材料的逸出功。

在光电子发射过程中，光子的波长越短能量越高 , 即使量很少也能激发电子克服逸出功飞出阴极表面。

能量低的光子即使数量很多也不能激发出阴极表面的电子。

在紫外管中对阴极材料表面纯度要求非常高，否则就会影响到光谱的范围而失去使用价值 , 采用对称的丝状结构是为了工艺处理的方便 , 尽可能避免其它物质对电极的污染。

紫外光电探测器
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一、产品简介
紫外光电探测器是根据客户需求定制一套的具有高线性度、特定时间相应特性的新型光电探测设备。

采用了大靶面、紫外相应增强的滨松硅光半导体芯片。

探测器具有信号幅度高，线性度一致性强，噪声低的特点，配合专用直流电源工作，特别适合极紫外193nm波长区域的激光信号检测。

产品主要技术指标：
成都诺为光科科技有限公司
***安全警告***
成都诺为光科科技有限公司
成都诺为光科科技有限公司
二、使用方法
(1) 按照图示方法完成探测器与电源连接。

信号输出
(2) 打开电源通道开关，绿色指示灯亮起，探测器开始工作。

光电信号通过SMA 接口进行输出。

用于枪击探测的紫外光传感器技术指标分析刘振吉;楚盛;杨永辉;刘金;袁小兵【摘要】利用一款标准的日盲型紫外探测传感器对枪击火焰进行了探测实验,结合紫外光传输特性,对实验数据进行分析,提出了探测枪击火焰紫外光谱的传感器技术指标.不考虑入射角度和响应时间的影响,1 km处要检测到步枪击发,传感器响应电流达到能明显检出的100 nA,则传感器的响应率和响应面积乘积至少达到0.002 AW-1m2.根据一种枪击探测装置原型方案,对紫外探测传感器的透光性、日盲特性、对紫外光的响应率、入射角和短路电流等技术指标进行了分析.采用分子束外延法制备了一种MgZnO紫外探测传感器,对其紫外光谱透光率、响应率和响应时间进行了测量,进一步优化性能后有望满足枪击探测要求.【期刊名称】《应用光学》【年(卷),期】2015(036)003【总页数】6页(P442-447)【关键词】紫外探测;火力探测;光响应率;MgZnO;日盲【作者】刘振吉;楚盛;杨永辉;刘金;袁小兵【作者单位】中国工程物理研究院计算机应用研究所,四川绵阳621900;中山大学物理科学与工程技术学院,广东广州510275;中国工程物理研究院计算机应用研究所,四川绵阳621900;中国工程物理研究院计算机应用研究所,四川绵阳621900;中国工程物理研究院计算机应用研究所,四川绵阳621900【正文语种】中文【中图分类】TN95;TP274引言在维和、反恐行动中，利用枪击探测系统及时探测到敌对分子的枪击火力点可以避免或减小其危害。

当前主流的枪击探测系统主要基于声学探测、红外探测或激光扫描探测，而这几类装备由于其实现原理及技术特点在实际应用中各自存在着无法克服的先天缺陷：声学探测受制于声速低于子弹速度，探测滞后；红外探测在白天受日光等环境的红外辐射影响大，虚警率高，而且红外探测器需要制冷，造成小型化困难；激光探测是主动扫描方式，枪手有可能在被发现之前已经开枪［1］。

紫外线传感器杀菌消毒原理解析紫外线传感器只对185～260nm狭窄范围内的紫外线进行响应，而对其它频谱范围的光线不敏感，利用它可以对火焰中的紫外线进行检测。

它是一个封闭且能透过紫外线的玻璃管，管内充满了一种特殊的气体。

玻璃管内部有一对由金属引线引出的电极——阳极和光电阴极，其中光电阴极由只对紫外线敏感的金属材料制成，在紫外线照射下发射光电子。

紫外线消毒杀菌用途很广，医院、学校、托儿所、电影院、公交车、办公室、家庭等，它能净化空气，消除霉味，水质消毒，此外还能产生一定量的负氧离子，经紫外线消毒的房间，空气特别清新。

在公共场合，经紫外线消毒，可避免一些病菌经空气传播或经物体表面传播。

是利用适当波长的紫外线能够破坏微生物机体细胞中的DNA（脱氧核糖核酸）或RNA（核糖核酸）的分子结构，造成生长性细胞死亡和（或）再生性细胞死亡，达到杀菌消毒的效果。

经试验，紫外线杀菌的有效波长范围可分为四个不同的波段：UV A（400～315nm）、UVB（315～280nm）、UVC（280～200nm）和真空紫外线（200～100nm）。

其中能透过臭氧保护层和云层到达地球表面的只有UV A和UVB部分。

就杀菌速度而言，UVC处于微生物吸收峰范围之内，可在1s之内通过破坏微生物的DNA结构杀死病毒和细菌，而UV A 和UVB由于处于微生物吸收峰范围之外，杀菌速度很慢，往往需要数小时才能起到杀菌作用，在实际工程的数秒钟水力停留（照射）时间内，该部分实际上属于无效紫外部分。

真空紫外光穿透能力极弱，灯管和套管需要采用极高透光率的石英，一般用半导体行业降解水中的TOC，不用于杀菌消毒。

因此，给排水工程中所说的紫外光消毒实际上就是指UVC消毒。

紫外光消毒技术是基于现代防疫学、医学和光动力学的基础上，利用特殊设计的高效率、高强度和长寿命的UVC波段紫外光照射流水，将水中各种细菌、病毒、寄生虫、水藻以及其他病原体直接杀死，达到消毒的目的。

紫外线传感器原理
紫外线传感器是一种用于监测环境中紫外线辐射强度的装置。

它基于紫外线与材料的相互作用原理进行工作。

紫外线传感器通常由紫外线敏感材料、光电二极管及信号处理电路组成。

紫外线敏感材料一般是一种半导体材料，它具有较高的吸收紫外线的能力，当紫外线照射到敏感材料上时，会激发出电子。

光电二极管负责将从敏感材料中激发出来的电子转化成电流信号。

信号处理电路将光电二极管输出的微弱电流信号放大，并将其转化为数字信号。

这些数字信号可以通过计算机或其他设备进行进一步的分析和处理。

在实际应用中，紫外线传感器可以用于测量紫外线辐射的强度。

由于紫外线对人体有一定的危害，因此紫外线传感器广泛应用于防晒霜、太阳镜、紫外线灯等产品的开发和质量控制中。

此外，紫外线传感器还可以用于紫外线杀菌、水质监测等领域。

总之，紫外线传感器通过紫外线与敏感材料之间的相互作用来实现对紫外线辐射强度的检测。

该技术在防晒产品、紫外线灯等领域有着广泛的应用。

紫外线传感器什么是紫外线传感器？紫外线传感器是一种用于检测紫外线辐射的设备。

它通常由光敏器件、信号处理器和数据传输模块组成。

紫外线传感器可以测量紫外线辐射的强度和频率，以便评估紫外线对人体或设备的影响。

紫外线传感器的原理紫外线传感器的原理基于光敏效应。

当紫外线照射到光敏器件上时，光敏器件会产生一定的电流。

这个电流的大小与照射到光敏器件上的紫外线的强度成正比。

信号处理器会将这个电流转换成数字信号，并将其传输给数据传输模块。

紫外线传感器的应用紫外线传感器在很多领域都有应用，如：太阳能电池板太阳能电池板需要长时间暴露在阳光下。

紫外线传感器可以帮助监测太阳能电池板受紫外线辐射的情况，以保障太阳能电池板的正常发电。

空气质量监测空气中的紫外线水平可以帮助监测大气污染和臭氧层的健康状况。

紫外线传感器可以用于测量空气中的紫外线水平，以便监测大气污染和臭氧层健康状况。

消毒设备细菌、病毒和其他微生物可以被紫外线消毒杀死。

紫外线传感器可以用于监测消毒设备的紫外线辐射强度，以确定消毒设备的消毒效果。

生命科学领域紫外线用于生命科学领域的DNA分析和紫外线照射细胞的实验。

紫外线传感器可以被用来监测紫外线的辐射水平，以确定实验的质量和减少实验中的风险。

紫外线传感器的局限性紫外线传感器可以被其他光源干扰。

例如，日光灯和其他形式的照明可以干扰紫外线传感器的测量值。

此外，紫外线传感器对不同类型的紫外线的敏感程度也不同。

结论紫外线传感器可以在许多应用中提供有用的数据。

尽管紫外线传感器具有一些局限性，但是在正确的环境下，它们可以提供有关紫外线辐射的详细信息，以便优化和改进相关应用。

紫外检测仪说明书1、原理紫外吸收检测器简称紫外检测器（ultraviolet detector，UVD），是基于溶质分子吸收紫外光的原理设计的检测器，其工作原理是Lambert-Beer定律，即当一束单色光透过流动池时，若流动相不吸收光，则吸收度A与吸光组分的浓度C和流动池的光径长度L成正比。

物理上测得物质的透光率，然后取负对数得到吸收度。

大部分常见有机物质和部分无机物质都具有紫外或可见光吸收基团，因而有较强的紫外或可见光吸收能力，因此UVD既有较高的灵敏度，也有很广泛的应用范围，是液相色谱中应用最广泛的检测器。

紫外检测器的波长范围是根据连续光源（氘灯）发出的光，通过狭缝、透镜、光栅、反射镜等光路组件形成单一波长的平行光束。

通过光栅的调节可得到不同波长。

波长范围应该是根据光源来确定的，不同光源波长范围也不一样。

光波根据光的传播频率不一样而划分的。

紫外的测量范围一般为0.0003---5.12（AUFS)，常用为0.005---2.0（AUFS)。

紫外光的范围一般指200-400 nm。

吸收度单位AU (absorbance unit) 是相当于多少伏的电压，范围的大小应该适中较好，实际工作中一般就需要1AU 左右。

核酸蛋白检测仪*工作原理所有紫外吸收检测器工作原理都是基于光的吸收定律---朗伯-比耳定律。

光源经220nm、254nm、280nm、340nm等干涉滤色片提供单色光作为检测核酸、蛋白、酶、多肽的光源。

具体工作原理正如该定律指出，当一束单色光(λ)辐射通过稀浓度物质溶液时，如果溶剂不吸收光，则液体的吸光度与吸光物质的浓度和光经过溶液的距离成正比。

其关系式为：A(λ)=a(λ)bcA=-LgT=Lg1/T核酸蛋白检测仪*操作步骤⑴、在仪器使用前，首先连接好所需配套仪器：层析柱、恒流泵、自动部分收集器、记录仪(色谱工作站)。

将各类插头与插座接妥(220V电源)。

⑵、按下检测仪ON电源开关，电源指示灯亮，说明整台仪器电源开始工作，然后观察光源指示灯，如果亮了，表示光源已开始工作，整台仪器可进入工作状态，将检测仪波长旋钮旋到所需波长刻度上，把量程旋钮拨到100%T档(仪器预热20分钟，待基线平直后可加样测试)。

A710/UVIR2双波长红紫外复合火焰探测器产品简介紫外线+双红外线（UV/IR2）火焰探测器采用对阳光不灵敏的紫外线传感器，外加两个窄带红外线传感器，可提供卓越的探测灵敏度，提高了对错误报警（光盲）的免疫力。

反应速度快，有高速分型。

除一般应用外，特别适用于铁路机车灭火、军用装甲车辆及舰船的爆炸压制。

性能特点内置高性能 32位微处理计算芯片1个日光盲紫外传感器和2个窄带IR传感器先进的智能算法和火焰危险判据能够更早的探测到小火，火焰响应速度快红外探视视角110度，紫外近视视角120度最佳地结合了火焰探测和抗误报警能力对于太阳光、人工光源、热辐射等干扰不会发生误报警可靠的系统故障自诊断功能可探测氢火焰和金属火焰适用于重工业应用场合防爆设计适合危险区域工业场所使用低维护成本，易于更新改进技术特性额定电压： DC24V 电压范围：DC18-30V视角范围：紫外视角120°，红外视角110°防爆型90°响应时间：<5S ( 0.7m*0.7m 汽油火 )<10S ( 0.3m*0.3m 汽油火 )<3S (氢火焰或金属火焰)储存温度：-40℃~85℃工作湿度：0~95%RH (不结露)防爆等级：Exdll CT6财务部工作总结、分析及计划报告范文[财务部工作总结、分析及计划报告范文]务部工作总结、分析及计划报告范文2009-12-10 10：25读者上传【大中小】【打印】【我要纠错】在上级财务部门的业务指导下，以年初支公司提出的工作思路为指导，以提高企业效益为核心，以增强企业综合竞争力为目标，以成本治理和资金治理为重点，全面落实预算治理，强基础，抓规范，实现了全年业务制度规范化，经营治理科学化，企业效益最大化，有力地推动了支公司财务治理水平的进一步提高，充分发挥了财务治理在企业治理中的核心作用，财务部工作总结、分析及计划报告范文。

现将2009年公司财务工作总结如下：一、主要指标完成情况1、固定费用：1-9月份累计完成##.5xxxx，完成进度计划的117.2xxxx，同比增长27.4xxxx，增加支出2312627.8 xxxx。

型号: SNUV-C2P1F2I24IEW
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功能说明
SNUV-C2P1F2I24IEW选用国外进口UV探头，结构紧凑，隔爆型设计，适用于船舶有防爆要求的压载水处理场合。

可以有效提高紫外杀菌设备的有效性，安全性。

与国外同类产品相比，有较高的性价比。

产品特征
● 进口UVC传感器，高稳定性。

● 良好的光谱响应范围，峰值响应光谱253.7nm
● 标准工业信号，4~20mA线性电流输出，便于工业应用
● 高测量精度，分辨率达10uW/cm2
● 较宽的工作温度范围: -20℃~+70℃,温漂系数: < -0.1%/℃
● 超低功耗，整机功耗< 0.5W
技术参数
传感器光谱响应曲线
使用说明
接线图 如图示：棕色— +24VDC，蓝色—Vout
使用时将探头部分正对所要检测的紫外灯管,外部接线连接到PLC ,MCU 等控制系统,完成模数转换即可完成对紫外线辐照强度的实时监控。

注意:不可随意拆卸整个探头和用力拉伸输出线,避免造成输出线受损。

外形尺寸。