日本费加罗FIGARO氨气传感器 TGS826

费加罗可燃气体传感器
经过市场40余年运用的历史发展，气体传感器和气体报警器都得到了持续的改进。

因此，如今的气体报警器可以做到免维护运行，质保期可达5年。

通过使用内置过滤器来提高传感器耐久性以及防止气体引起误报警的方法已经成为标准做法。

 所有费加罗可燃气体传感器的家用气体报警器都有一个内置过滤器。

过滤材料的使用量满足欧洲标准中设计所要求的响应时间（≤30s）。

 费加罗可燃气体传感器还具有一下特点：
 每一只传感器，都在严控温湿度的条件下生产制造，对使用对象气体就行100%全检。

 有可追溯的制造记录，传感器的制造记录可以通过生产批号进行追溯。

 面向精准客户要求，费加罗推出了LPM2610,NGM2611,CGM6812等几款预校准模块，这些模块出厂前已经经过严格控制条件下的预校准。

 4.符合ROHS与REACH标准。

费加罗气体传感器符合限制有害物质指令（ROHS）以及化学品注册，评估，授权和限制令（REACH）等环保规范。

 
 低功耗。

费加罗持续致力于研究低功耗的传感器，由于传感器芯片的小型化，TGS2610/2611的功耗仅有280mw。

 长寿命。

TGS6810/6812传感器的预期寿命在10年左右。

TGS2602 空气污染、臭味检测用特点： 应用：・低功耗 ・空气清新机、换气扇控制 ・对VOC 、氨气、硫化氢有高灵敏度 ・脱臭器控制・长寿命、低成本 ・室内空气监视器・可利用简单电路下图是典型的香烟烟雾灵感度特性。

香烟的根数是约10平米的房间吸烟情况下的数值。

这里的纵轴也用传感器电阻比Rs/Rs(Air)来表示， 这里的Rs ､Rs(Air)定义如下： Rs ＝香烟的烟雾存在时的传感器电阻值 Rs(Air) ＝清洁大气中的传感器电阻值 香烟灵敏度特性：敏感素子由集成的加热器以及在氧化铝基板上形成的金属氧化物半导体构成。

当可检知的气体存在时，空气中该气体的浓度越高，传感器的电导率就越高。

使用简单的电路就可以将这种电导率的变化变换为与气体浓度对应的输出信号。

TGS2602不仅对香烟的烟雾或烹调臭味有很高的灵敏度，而且对硫化氢、VOC 、氨气有高灵敏度。

这种传感器是利用相对值检知来实现更接近人类感觉的控制，即以空气清洁的时候为基准，通过传感器电阻值比空气清洁时变化了多少来检测空气的污染程度。

下图是典型的灵敏度特性，全部是在标准试验条件下得出的结果。

（请看背面） 纵轴以传感器电阻比Rs/Rs(Air)表示，Rs ､Rs(Air)的定义如下： Rs ＝各种浓度气体中的传感器电阻值Rs(Air)＝清洁大气中的传感器电阻值灵敏度特性：规格： 结构及尺寸：型 号 TGS2602素子类型 26系列 标准封装 金属 对象气体氢气、酒精等检测范围 1 ～10 ppm标准回路加热器电压 VH 5.0±0.2V DC/AC 回路电压 VC 5.0±0.2V DC Ps 15mW ≦ 负载电阻 RL 可变Ps 15mW ≦标准试验加热器电阻 RH59 Ω（室温）加热器电流 IH 56mA 加热器功耗 PH 280mW VH ＝5.0V DC/AC 传感器电阻Rs10～100 K Ω（空气中） 灵敏度(Rs 的变化率)0.15～0.5Rs(乙醇：10 )Rs(Air)标准试验试验气体条件 20±2℃，65±5％RH 回路条件 VC ＝5.0±0.2V DCVH ＝5.0±0.2V DC/AC试验前预热时间 96小时以上功耗（Ps ）值可用下式计算： 传感器电阻（Rs ），可根据VOUT测定值，用下式计算：为提高性能，本规格书将不事先预告而变更。

日本费加罗Figaro氧气传感器广州南创陈工FIGARO是一家专业生产半导体气体传感器的公司，1962年发明全球第一款半导体产品，目前全球第一。

FIGARO的产品远销38个国家，在多个国家设立了分支机构或办事处，生产基地遍布美洲、东欧、中国等地；并在中国设立了广州南创传感器事业部，可为用户的实验和生产提供最佳的服务与解决方案。

半导体气体传感器采用金属氧化物半导体烧结工艺，对被检测的检测气体具有灵敏度高、响应时间短、成本低、长期稳定性好等优点。

我们的产品包括可燃气体、有毒气体、空气质量、一氧化碳、二氧化碳、氨气、汽车尾气、酒精等传感器元件、传感模块等，以及各种气体传感器的配套产品。

目前已经被广泛应用于家用燃气报警器、工业有毒气体报警器、空气清新机、换气空调、空气质量控制、汽车尾气检测、蔬菜大棚、酒精检测、孵化机械等。

日本费加罗Figaro氧气传感器KE-25KE-50信息日本费加罗Figaro氧气传感器KE-25KE-50性能：测量范围：0-100％O2精度：氧气传感器KE-25：±1％（全量程）；氧气传感器KE-50：±2％（全量程）工作温度：5～40℃储存温度：-20～＋60℃响应时间：KE-25：14±2秒；KE-50：60±5秒初始输出：KE-25：10.0–15.5mv；KE-50：47.0-65.0mv期望寿命：KE-25：5年；KE-50：10年日本费加罗Figaro氧气传感器KE-25KE-50特性：长寿命（KE-25-5年，KE-50-10年）不受CO2，CO，H2S，NOx，H2影响低成本，在常温下工作信号输出定，无需外部电源不需加热以上日本费加罗Figaro氧气传感器技术参数以《OIML60号国际建议》92年版为基础，最新具体变化可查看《JJG669—12FIGARO广州南创传感器事业部检定规程》产品特性描述：氧气传感器KE-25KE-50属于半导体气体传感器不受CO2，CO，H2S，NOx，H2影响，氧气传感器KE-25KE-50低成本在常温下工作信号输出定，无需外部电源不需加热；精度氧气传。

Applications:Features:TGS 832-A00 - for the detection of ChlorofluorocarbonsThe figure below represents typical sensitivity characteristics, all data having been gathered at standard test conditions (see reverse side of this sheet). The Y-axis is indicated as sensor resistance ratio (Rs/Ro) which is defined as follows: Rs = Sensor resistance of displayed gases at various concentrations Ro = Sensor resistance at 100ppm of R-134a The figure below represents typical temperature and humidity dependency characteristics. Again, the Y-axis is indicated as sensor resistance ratio (Rs/Ro), defined as follows: Rs = Sensor resistance at 100ppm of R-134a at various temperatures/humidities Ro = Sensor resistance at 100ppm of R-134a at 20°C and 65% R.H.The sensing element of Figaro gas sensors is a tin dioxide (SnO 2) semiconductor which has low conductivity in clean air. In the presence of a detectable gas, the sensor's conductivity increases depending on the gas concentration in the air. A simple electrical circuit can convert the change in conductivity to an output signal which corresponds to the gas concentration.The TGS 832-A00 has high sensitivity to refrigerant gases commonly used in air conditioning systems and refrigerators such as R-134a, R-404a, R-407c, and R-410.TGS832-A00 has a gas diffusion hole in the sensor cap as well as in the sensor base. By using the sensor with a suction pump, response speed can be accelerated, making it suitable for portable gas leakage checkers.* Portable and fixed installation refrigerant leak detectors* High sensitivity to refrigerant gases * Quick response * Long term stability* Uses simple electrical circuitTemperature/Humidity Dependency:Sensitivity Characteristics:1.21.0Structure and Dimensions:1 Sensing Element: SnO2 is sintered to form a thick film on the surface of an alumina ceramic tubewhich contains an internal heater.2 Sensor Cap 3 Sensor Base: Nylon 664 Flame Arrestor: 100 mesh SUS316 double gauzeStandard Circuit Conditions:Pin Connection and Basic Measuring Circuit:The numbers shown around the sensor symbol in the circuit diagram at the right correspond with the pin numbers shown in the sensor's structure drawing (above). When the sensor is connected as shown in the basic circuit, output across the Load Resistor (V RL ) increases as the sensor's resistance (Rs) decreases, depending on gas concentration.Sensor Resistance (Rs) is calculated by the following formula:Power dissipation across sensor electrodes (Ps) is calculated by the following formula:Standard Test Conditions:TGS 832 complies with the above electrical characteristics when the sensor is tested in standard conditions as specified below:Test Gas Conditions: 20°±2°C, 65±5%R.H.Circuit Conditions: V C = 10.0±0.1V (AC or DC), V H = 5.0±0.05V (AC or DC), R L = 10.0kΩ±1%Preheating period before testing: More than 7 days Electrical Characteristics:Basic Measuring Circuit:REV: 10/12Rs = ( -1) x R LV CV RLPs =V C 2 x Rs(Rs + R L )217 ± 0.59.516.5±0.56.5±0.51.0±0.563425145˚45˚um : mm。

TGS681x 气体传感器是采用独一无二的失效保护理念设计而成的非常独特的催化燃烧式传感器。

本手册提供了关于使用费加罗的独特催化型传感器TGS6810和TGS6812的气体检测器在设计和制造方面的重要技术建议。

目 录概要.....................................................................................................................................2电路设计 基本电路................................................................................................................2 传感器故障............................................................................................................3 加热过程中的报警预防......................................................................................3 报警延迟电路.......................................................................................................3印刷电路板和壳体设计 传感器的位置依赖性...........................................................................................3 快速响应之壳体设计 (4)制造工艺 传感器操作和保管...............................................................................................4 印刷电路板装配...................................................................................................4 传感器装配............................................................................................................4 预热...................................................................................................4 校正........................................................................................................................5 最终装配................................................................................................................6 气体调校................................................................................................................6 成品的保管 (6)采用TGS681x的可燃气体检测器应用手册重要提示：费加罗传感器的使用条件将因不同客户的具体运用不同而不同。

Technical Information for Methane Gas SensorsThe Figaro 2600 series is a new type thick f ilm metal oxide semiconductor, screen printedgas sensor which o f f ers miniaturization and lower power consumption. The TGS2611displays high selectivity and sensitivity to methane.PageSpecificationsFeatures.....................................................................................2Applications...................................................................2Structure...................................................................................2Basic Measuring Circuit................................................................2Circuit & Operating Conditions.....................................................3Specifications.......................................................................................3Dimensions.......................................................................................3Basic Sensitivity CharacteristicsSensitivity to Various Gases..........................................................4Temperature and Humidity Dependency......................................5Heater Voltage Dependency...................................................................6Cautions on Sensor Power Consumption.................................................6Gas Response..............................................................................................7Initial Action....................................................................................7Long Term Characteristics....................................................................8ReliabilityCorrosion Test..........................................................................................9Ignition Test....................................................................................9Effect of Air Flow..............................................................................9Heater Resistance Durability........................................................10HMDS Test............................................................................................11Lighter Gas Exposure Test..........................................................................11Cautions (12)See also Technical Brochure ‘Technical Information on Usage of TGS Sensors for Toxic and Explosive Gas Leak Detectors’.a n I S O 9001 a n d 14001 c o m p a n yIMPORTANT NOTE: OPERATING CONDITIONS IN WHICH FIGARO SENSORS ARE USED WILL VARY WITH EACH CUSTOMER’S SPECIFIC APPLICATIONS.FIGARO STRONGLY RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WHEN CUSTOMER’S TARGET GASES ARE NOT LISTED HEREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH A SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.Both TGS2611-C00 and -E00 are UL recognized components in accordance with the requirements of component recognition testing has confirmed long term stability in 60ppm of methane; other characteristics shown in this brochure have not been confirmed by UL as part of component recognition.TGS2611 is available in two different models with different external housings but identical sensitivity to methane gas. TGS2611-C00 possesses small size and quick gas response, making it suitable for gas leakage checkers, while TGS2611-E00 uses filter material in its housing to eliminate the influence of interference gases such as alcohol, resulting in highly selective response to methane gas. Both models are capable of meeting the requirements of EN50194 and UL1484.1. Specifications1-1 Features*High selectivity to methane*Low power consumption*Small size*Long life and low cost*Uses simple electrical circuit1-2 Applications* Residential gas alarms* Portable gas detectors* Gas leak detectors for gas appliances1-3 StructureFigure 1 shows the structure of TGS2611. Using thick film techniques, the sensing material (SnO2) is printed on electrodes (noble metal) which have been printed onto an alumina substrate. One electrode is connected to pin No.2 and the other is connected to pin No.3. The sensor element is heated by RuO2 material printed onto the reverse side of the substrate and connected to pins No.1 and No.4.Lead wires are Pt-W alloy and are connected to sensor pins which are made of Ni-plated Ni-Fe 50%.The sensor base is made of Ni-plated steel. The caps of both TGS2611-C00 and TGS2611-E00 are stainless steel. The upper opening in both caps is covered with a double layer of 100 mesh stainless steel gauze (SUS316). The TGS2611-E00 utilizes a charcoal filter inside the cap for reducing the influence of interference gases.1-4 Basic measuring circuitFigure 2 shows the basic measuring circuit. Circuit voltage (Vc) is applied across the sensor element which has a resistance (Rs) between the sensor’s two electrodes and the load resistor (R L) connected in series. When DC is used for Vc, the polarity shown in Figure 2 must be maintained. The Vc may be applied intermittently. The sensor signal (V RL) is measured indirectly as a change in voltage across the R L. The Rs is obtained from the formula shown at the right.Fig. 1 - Sensor structureVc - V RLV RLRs = x R LFormula to determine RsFig. 2 - Basic measuring circuitNOTE: In the case of V H, there is no polarity, so pins 1 and 4 can be considered interchangeable. However, in the case of V C, when used with DC power, pins 2 and 3 must be used as shown in theFigure above.TGS2611-E00Sensingelement1-5 Circuit & operating conditionsThe ratings shown below should be maintained at all times to insure stable sensor performance:1-6 Specifications NOTE 1Mechanical Strength:The sensor shall have no abnormal findings in its structure and shall satisfy the above electrical specifications after the following performance tests:Withdrawal Force - (pin from base) Vibration - Shock -withstand force of 5kg in each directionfrequency-1000cycles/min.,total amplitude-4mm, duration-one hour, direction-verticalacceleration-100G, repeated 5timesNOTE 1: Sensitivity characteristics are obtained under the following standard test conditions:(Standard test conditions)Temperature and humidity: 20 ± 2˚C, 65 ± 5% RH Circuit conditions:Vc = 5.0±0.01V DCV H = 5.0±0.05V DC R L = 10.0k Ω ± 1%Preheating period: 7 days or more under standard circuit conditions.1-7 DimensionsFig. 3 - Sensor dimensionsAll sensor characteristics shown in this brochure represent typical characteristics.Actual characteristics vary from sensor to sensor and from production lot to production lot. The only characteristics warranted are those shown in the Specification table above.TGS2611-C00 TGS2611-E00Pin connection: 1: Heater2: Sensor electrode (-) 3: Sensor electrode (+) 4: Heater2-1 Sensitivity to various gasessensor resistance in 5000ppm of methane (Ro).sensitivity to methane.and with a matched R Lvoltage (V RL) change as shown in Figure 5. NOTE:calibration is required for each sensor (for Toxic and Explosive Gas Leak Detectors’).under various ambient conditionsTable 1 - Temperature and humidity dependency(typical values of Rs/Ro for Fig. 6)Table 1 shows a table of values of the sensor’s resistance ratio (Rs/Ro) under the same conditions as those used to generate Figure 6.Figure 7 shows the sensitivity curve for TGS2611 to methane under several ambient conditions. While temperature may have a large influence on absolute Rs values, this chart illustrates the fact that effect on the slope of sensor resistance ratio (Rs/Ro) is not significant. As a result, the effects of temperature on the sensor can easily be compensated.For economical circuit design, a thermistor can be incorporated to compensate for temperature (for additional information on temperature compensation in circuit designs, please refer to the Technical Advisory ‘Technical Information on Usage of TGS Sensors for Toxic and Explosive Gas Leak Detectors’).2-3 Heater voltage dependencyratio according to variations in heater voltage (V typical characteristics shown in this brochure.2-4 Cautions on sensor power consumptionFigure 9relationship is referred to as V-I characteristics.basic measuring circuit (see Figure 2and can be calculated according as follows:Ps =where :R L : Load resistor value (k Ω)V RL : Sensor output voltage (v)Vc : Circuit voltage (v)Ps : Power consumption (mW)Vc 2/(4 x R L damage to the sensor due to Joule heat.minimum R L voltage.Table 2 - Minimum suggested R L valuesV RL x (Vc-V RL )R L2-7 Long-term characteristics3000ppm of ethanol.were powered under standard test conditions. 1000ppm of iso-butane.to a stable level within three days of energizing.As the charts presented in this section illustrate, the sensor shows stable long term characteristics.3. Reliability3-1 Corrosion testFigure 15 shows the effect on TGS2611 of corrosivegases specified in Item 43.15 of the UL 1484 standard.Sensor resistance prior to corrosive gas exposure wasmeasured. Unenergized sensors were then placedinto an environment of 23˚±2˚C and 95%RH. In thisenvironment, two separate tests were conducted: onein 0.1% H2S, the other in a combination of 0.5% SO2and 1.0% CO2, with each test exposure lasting 10days. After this exposure, the sensor was re-energized in normal air prior to measuring sensorresistance after removal from corrosive gases.As this data would suggest, sensor characteristics aretemporarily influenced by exposure to corrosive gasconcentrations specified by Sec. 43.15 of UL 1484,TGS2611 has been successfully tested against theignition test requirements of the UL1484 standard.The sensor did not initiate ignition of a propaneFigure 16 shows how the sensor signal (V RL) isaffected by air flow. The test procedure involvessituating the sensor in an air stream of 3.1 meters persecond, with the air flow vertical/horizontal to theflameproof stainless steel double gauze of theThe decrease in sensor signal shown in Figure 16resulted from the decrease in sensor elementtemperature caused by the air flow. As a result, directFig. 16 - Effect of air flow on TGS2611-C00Fig. 17 - Test procedure for heater durability3-4 Heater resistance durabilityFigure 17 illustrates the procedure for testing the effects of excess voltage applied to the heater. Heater resistance was measured while the heater was unpowered and at room temperature.The results of this test are shown in Figure 18 which shows the change in resistance of the heater when various heater voltages (rather than the standard 5.0V) are applied in the absence of gases.As this section demonstrates, the heater shows good durability against increased heater voltage.However, since excessive heater voltage will cause the sensor’s heater resistance to drift upwards,excessive heater voltage should still be avoided.standard circuit conditions. After returning the sensorexposure as shown in Figure 20.The result of the above test is shown in Fig. 20. A 10% iso-butane exposure for 60 seconds appears to cause an increase in Rs in gas. Furthermore, sensor to its original value after energizing in normal air.may cause a permanent change in the sensor’sdone, it must be carefully administered to avoid sensor damage.NOTE: To achieve the optimal level of accuracy in gas detectors, each TGS2611 sensor should be individually calibrated by matching it with a load resistor (R L) in an environment containing the target gas concentration for alarming (refer to Fig. 2).For the convenience of users, TGS2611 is classified into 24 groups according to the each sensor’s Rs in methane. ID numbers marked on the sensor’s body indicate the sensor’s grouping. Individual sensor calibration can be eliminated by matching the sensor with the recommended R L for each sensor ID. However, because group calibration is used instead of individual calibration, an average of 10% less accuracy would result for detectors using group calibration. Please refer to “Application Notes for TGS2611” for more information.4 Cautions on Usage of Figaro Gas Sensors4-1 Situations which must be avoided1) Exposure to silicone vaporsIf silicone vapors adsorb onto the sensor’s surface, the sensing material will be coated, irreversibly inhibiting sensitivity. Avoid exposure where silicone adhesives, hair grooming materials, or silicone rubber/putty may be present.2) Highly corrosive environmentHigh density exposure to corrosive materials such heater material.3) Contamination by alkaline metalsSensor drift may occur when the sensor is contaminated by alkaline metals, especially salt water spray.4) Contact with waterSensor drift may occur due to soaking or splashing the sensor with water.5) FreezingIf water freezes on the sensing surface, the sensing material would crack, altering characteristics.6) Application of excessive voltageIf higher than specified voltage is applied to the sensor or the heater, lead wires and/or the heater may be damaged or sensor characteristics may drift, even if no physical damage or breakage occurs. 7) Operation in zero/low oxygen environment TGS sensors require the presence of around 21% (ambient) oxygen in their operating environment in order to function properly and to exhibit characteristics described in Figaro’s product literature. TGS sensors cannot properly operate in a zero or low oxygen content atmosphere.8) Excessive exposure to alcoholIF TGS2611-E00 is exposed to high concentrations of alcohol (such as 10,000ppm or more) for a long period of time, the filter may become saturated. In this case,Figaro USA Inc. and the manufacturer, Figaro Engineering Inc. (together referred to as Figaro)reserve the right to make changes without notice to any products herein to improve reliability,functioning or design. Information contained in this document is believed to be reliable. However, Figaro does not assume any liability arising out of the application or use of any product or circuit describedherein; neither does it convey any license under its patent rights, nor the rights of others.Figaro's products are not authorized for use as critical components in life support applications wherein a failure or malfunction of the products may result in injury or threat to life.the sensor would show a lower resistance in alcohol than that indicated in Figure 4a.4-2 Situations to be avoided whenever possible 1) Water condensationLight condensation under conditions of indoor usage should not pose a problem for sensor performance.However, if water condenses on the sensor’s surface and remains for an extended period, sensor characteristics may drift.2) Usage in high density of gasSensor performance may be affected if exposed to a high density of gas for a long period of time,regardless of the powering condition.3) Storage for extended periodsWhen stored without powering for a long period, the sensor may show a reversible drift in resistance according to the environment in which it was stored.The sensor should be stored in a sealed bag containing clean air; do not use silica gel. Note that as unpowered storage becomes longer, a longer preheating period is required to stabilize the sensor before usage .4) Long term exposure in adverse environmentRegardless of powering condition, if the sensor is exposed in extreme conditions such as very highhumidity, extreme temperatures, or high contamination levels for a long period of time, sensor performance will be adversely affected.5) VibrationExcessive vibration may cause the sensor or lead wires to resonate and break. Usage of compressed air drivers/ultrasonic welders on assembly lines may generate such vibration, so please check this matter.6) ShockBreakage of lead wires may occur if the sensor is subjected to a strong shock.7) SolderingIdeally, sensors should be soldered manually.However, wave soldering can be done under the following conditions:a) Suggested flux: rosin flux with minimal chlorine b) Speed: 1-2 meters/min.c) Preheating temperature: 100±20˚C d) Solder temperature: 250±10˚Ce) Up to two passes through wave soldering machine allowedResults of wave soldering cannot be guaranteed if con-ducted outside the above guidelines since some flux vapors may cause drift in sensor performance similar to the effects of silicone vapors.。

TGS2602 用于空气污染物检测的气体传感器* 对VOC 与气味有高灵敏度* 低功耗* 对污染空气有高灵敏度* 使用寿命长* 应用电路简单* 体积小特点:应用:敏感素子由集成的加热器以及在氧化铝基板上的金属氧化物半导体构成。

如果空气中存在对象检测气体，该气体的浓度越高传感器的电导率也会越高。

仅用简单的电路，就可以将电导率的变化转换成与该气体浓度相对应的信号输出。

TGS2602对低浓度气味的气体具有很高的灵敏度，这样还可以对办公室与家庭环境中的废弃物所产生的氨、硫化氢等气体进行检测。

该传感器还对木材精加工与建材产品中的VOC 挥发性气体如甲苯有很高的灵敏度。

由于实现了小型化，加热器电流仅需56mA ，外壳采用标准的TO-5金属封装。

下图所示为典型的灵敏度特性曲线，均在我公司的标准试验条件下（参见背面）测出。

纵坐标表示传感器电阻比 Rs/Ro ，Rs 与Ro 的定义如下：Rs = 各种浓度气体中的传感器电阻值下图所示为受温度、湿度影响的典型特性曲线。

纵坐标表示传感器电阻比 Rs/Ro ，Rs 与Ro 的定义如下：Rs = 传感器在清洁空气中各种温/湿度下的电阻值Ro= 传感器在清洁空气中， 温/湿度为20°C / 65% R.H.时的电阻值灵敏度特性:温/湿度特性:重要提示: 费加罗传感器的使用条件将因不同客户的具体运用不同而不同。

费加罗强烈建议在使用前咨询我们的技术人员，尤其是当客户的检测对象气体不在列表范围时，对于未经费加罗专业测试的任何使用，费加罗不承担任何责任。

* 空气清新机控制* 通风控制* 空气质量监测* VOC 监视器* 气味监视器R s /R oR s /R o规格:结构以及尺寸:管脚连接: 1: 加热器2: 传感器电极 (-) 3: 传感器电极 (+) 4: 加热器功耗值（P S ）可通过下式求出：传感器电阻（R S ）可根据V OUT （V RL ）的测定值用下式求出：(V C - V RL )2R SV C V RLR S = (- 1) x R L P S =在此产品规格书中所显示的都是传感器的典型特性，实际的传感器特性因产品不同而不同，详情请参阅各传感器唯一对应的规格表。

Applications:Features:TGS 4160 - for the detection of Carbon DioxideThe figure below represents typical sensitivity characteristics of TGS4160. The Y-axis is indicated as ∆EMF which is defined as follows:∆EMF=EMF1 - EMF2where EMF1=EMF in 350 ppm CO 2EMF2=EMF in listed gas concentrationThe figure below shows typical humidity dependency for an energized sensor. Again, the Y-axis is indicated as ∆EMF which is defined as follows:∆EMF=EMF1 - EMF2whereEMF1=EMF in 350 ppm CO 2 EMF2=EMF in 1000ppm CO 2* Air quality control* CO 2 control in agricultural applications * CO 2 monitoringThe TGS4160 is a hybrid sensor unit composed of a carbon dioxide sensitive element and a thermistor. A wide range of 350~50,000ppm of carbon dioxide can be detected by TGS4160, making it ideal for usage in a variety of applications.The CO 2 sensitive element consists of a solid electrolyte formed between two electrodes, together with a printed heater (Pt) substrate. By monitoring the change in electromotive force (EMF) generated between the two electrodes, it is possible to measure CO 2 gas concentration.Adsorbent (zeolite) is filled between the internal cover and the outer cover for the purpose of reducing the influence of interference gases.TGS4160 exhibits a linear relationship between ∆EMF and CO 2 gas concentration on a logarithmic scale. The sensor displays good long term stability and shows excellent durability against the effects of high humidity.* High selectivity to CO 2* Low dependency on humidity * Long life地址：广东省深圳市龙华新区牛栏前大厦Ｃ５０７ 网址：ｗｗｗ．ｓｉｎｇｏａｎ．ｃｏｍ ｗｗｗ．ｓｉｎｇｏａｎ．ｃｏｍ．ｃｎ ｗｗｗ．ｓｈｅｎｇｕｏａｎ．ｃｏｍ蒋小姐：１３４　２８７６　２６３１ 电话：８６　７５５－８５２５８９００Structure and Dimensions:Basic Measuring Circuit:The TGS4160 sensor requires heater voltage (V H ) input. The heater voltage is applied to the integrated heater in order to maintain the sensing element at a specific temperature which is optimal for sensing. Electromotive force (EMF)of the sensor should be measured using a high impedance (> 100 G Ω) operation-al amplifier with bias current < 1pA (e.g.Texas Instruments' model #TLC271).Since the solid electrolyte type sensorSpecifications:functions as a kind of battery, the EMF value itself would drift using this basic measuring circuit. However, the change of EMF value (∆EMF) shows a stable relationship with the change of CO 2concentration. Therefore, in order to obtain an accurate measurement of CO 2, a special microprocessor for signal processing should be used with TGS4160. Figaro can provide a special evaluation sensor module (AM-4) for TGS4160.Sensing Element Structure:Bottom view(u/m = mm)Green DotBottom View (Sensor Element)A: Lead wiresSide view (Sensor Element)B : Pt Heater F : Sealing Glass E : Counter Electrode (Anode)C : Solid ElectrolyteD : Sensing Electrode (Cathode)EMFVHTGS41601364I BIAS < typ. 1pAGND25ThermistorThermistorOperational amplifier +-深圳市深国安电子科技有限公司地址：广东省深圳市龙华新区牛栏前大厦Ｃ５０７ 网址：ｗｗｗ．ｓｉｎｇｏａｎ．ｃｏｍ ｗｗｗ．ｓｉｎｇｏａｎ．ｃｏｍ．ｃｎ ｗｗｗ．ｓｈｅｎｇｕｏａｎ．ｃｏｍ蒋小姐：１３４　２８７６　２６３１ 电话：８６　７５５－８５２５８９００。

Sensitivity characteristics (typical values under std.test conditions)Response time (typical)The GS Oxygen Sensor KE series (KE-25 and KE-50) is a unique galvanic cell type oxygen sensor which was developed in Japan in 1985. Its most notable features are long life expectency, excellent chemical durability, and it is not influenced by CO 2. The KE series oxygen sensor is ideal to meet the ever-increasing demand for oxygen monitoring in various fields such as combustion gas monitoring, the biochemical field, medical applications, domestic combustion appliances, etc.Features:* Long lifeKE-25 - 5 years / KE-50 - 10 years in ambient air * Virtually no influence from CO 2, CO, H 2S, NOx, H 2* Low cost* Operates in normal ambient temperatures * Stable output signal* No external power supply required for sensoroperation* No warmup time is requiredGS Oxygen SensorsApplications:* Medical - Anesthetic instruments, respirators,oxygen-enrichers* Biotechnology - Oxygen incubators* Food industry - Refrigeration, greenhouses* Safety - Air conditioners, oxygen detectors, firedetectorsREV: 08/03SpecificationsNotes:1) When calibrated at both 0% and 100% of O 2, accuracy in the range from 0-100% O 2 shall be within ±1% of full scale for KE-25 and ±2% of full scale for KE-50.2) Va = output voltage at 21% O 2 V 0 = output voltage at 0% O 2V 100 = output voltage at 100% O 23) Va = output voltage at 25˚C V H = output voltage at 40˚C V L = output voltage at 5˚C4) Sensors should be used under conditions where the air exchange is greater than 200~300ml per minute in order to obtain the response speed as specified in Table 1.22.7±0.5KE-25/KE-50 standard versionKE-25F1 (w/o flange)KE-25F3 (threaded top)KE-25F4 (O-ring top)22.7±0.522.7±0.5。

PRODUCT INFORMATIONApplications:Features:TGS 8100 - for the detection of Air ContaminantsThe figure below represents typical sensitivity characteristics, all data having been gathered at standard test conditions (see reverse side of this sheet). The Y-axis is indicated as sensor resistance ratio (Rs/Ro) which is defined as follows: Rs = Sensor resistance in displayed gases at various concentrationsRo = Sensor resistance in fresh air The figure below represents typical temperature and humidity dependency characteristics. Again, the Y-axis is indicated as sensor resistance ratio (Rs/Ro), defined as follows: Rs = Sensor resistance in fresh air at various temperatures/humidities Ro = Sensor resistance in fresh airat 20°C and 65% R.H.* Indoor air quality monitors * Air cleaners* Ventialtion control* Kitchen range hood controlThe sensing element is comprised of a sensing chip and an integrated heater formed on a silicon substrate using MEMS technology, and a metal-oxide semiconductor layer formed on the sensing chip. The device is housed in a surface-mount ceramic package. Due to miniaturization of the sensing chip, TGS 8100 requires a heater power consumption of only 15mW, and is suitable for low-power equipment and battery-operated instruments. In the presence of detectable gas, sensor conductivity increases depending on gas concentration in the air. A simple electrical circuit can convert the change in conductivity to an output signal which corresponds to the gas concentration.The TGS 8100 has high sensitivity to low concentrations of gaseous air contaminants such as cigarette smoke and cooking odors. By utilizing the change ratio of sensor resistance from the resistance in clean air as relative response, human perception of air contaminants can be simulated and practical air quality control can be achieved.* Surface mount package * Low power consumption* High sensitivity to cigarette smoke, cookingodors, and gaseous air contaminants* Long life * Low costTemperature/Humidity Dependency:Sensitivity Characteristics:0.010.11101101001000Gas concentration (ppm)IMPORTANT NOTE: OPERATING CONDITIONS IN WHICH FIGARO SENSORS ARE USED WILL VARY WITH EACH CUSTOMER’S SPECIFIC APPLICATIONS. FIGARO STRONGLY RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WHEN CUSTOMER’S TARGET GASES ARE NOT LISTED HEREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.Structure and Dimensions:The value of power consumption (P S ) can be calculated by utilizing the following formula:P S = Sensor resistance (Rs) is calculated witha measured value of Vout by using the following formula:R S = - R L Specifications: (tentative)V C x R L Vout(V C - Vout)2R S All sensor characteristics shown in this brochure represent typical characteristics. Actualcharacteristics vary from sensor to sensor. The only characteristics warranted are those in the Specification table above.Side viewu/m = mmPin connections: 1: Heater2: Sensor electrode (-) 3: Sensor electrode (+) 4: Heater。

使用 TGS 传感器进行有毒及爆炸性气体泄漏检测的技术资料。

I S O 9001企业费加罗 TGS 传感器是厚膜金属氧化物半导体型的。

它成本低、寿命长, 利用简单电路即可对待检测气体具有良好的敏感特性。

尤其适合应用在有毒和爆炸性气体的泄漏检测器上。

页工作原理……………………………………………………….. 2传感器特性 .氧气分压的影响……………………………………….…... 3 气敏特性……………………………………………….…... 3 传感器响应…………………………………………….…... 3 初始动作………………………………………………….... 4 温湿度影响…………………………………………….…... 4 长期稳定性…………………………………………….…... 4 加热电压影响………………………………………….…... 4 传感器使用注意事项…………………………………………... 5 回路负载电阻(RL ………………………………………………. 6 信号处理……………………………………………….…... 6 温度补偿回路…………………………………………….... 7 加热器突入电流……………………………………….…... 8 传感器加热器断路检测回路………………………….. ….8 防止初始动作报警……………………………………….... 8 蜂鸣器延迟回路………………………………………….... 8 检测器设计回路…………………………………………………….…... 9 检测器外壳…………………………………………….…... 9 样机评审测验…………………………………………….... 9 检测器制造生产设备传感器 /检测器预通电设备…………………….. 10 气体测试箱……………………………………... 10 工厂环境………………………………………... 10 制造工艺传感器贮存............................................. 10 传感器预通电.......................................... 10 PCB 装配................................................ 10 传感器装配............................................. 10 PCB 预通电............................................. 10 浓度设定................................................ 11 最终装配................................................ 11 最终装配的预通电.................................... 11 气体测试 (11)重新设定................................................ 11 最终成品的贮存....................................... 11 质量控制.. (11)2003年 6月再版 11. 工作原理TGS 气体传感器的敏感材料是金属氧化物 , 最具代表性的是 SnO 2。

费加罗传感器广州南创陈工FIGARO是一家专业生产半导体气体传感器的公司，1962年发明全球第一款半导体产品，目前全球第一。

FIGARO的产品远销38个国家，在多个国家设立了分支机构或办事处，生产基地遍布美洲、东欧、中国等地；并在中国设立了广州南创传感器事业部，可为用户的实验和生产提供最佳的服务与解决方案。

半导体气体传感器采用金属氧化物半导体烧结工艺，对被检测的检测气体具有灵敏度高、响应时间短、成本低、长期稳定性好等优点。

我们的产品包括可燃气体、有毒气体、空气质量、一氧化碳、二氧化碳、氨气、汽车尾气、酒精等传感器元件、传感模块等，以及各种气体传感器的配套产品。

目前已经被广泛应用于家用燃气报警器、工业有毒气体报警器、空气清新机、换气空调、空气质量控制、汽车尾气检测、蔬菜大棚、酒精检测、孵化机械等。

费加罗传感器KE-25KE-50信息费加罗传感器KE-25KE-50性能：测量范围：0-100％O2精度：氧气传感器KE-25：±1％（全量程）；氧气传感器KE-50：±2％（全量程）工作温度：5～40℃储存温度：-20～＋60℃响应时间：KE-25：14±2秒；KE-50：60±5秒初始输出：KE-25：10.0–15.5mv；KE-50：47.0-65.0mv期望寿命：KE-25：5年；KE-50：10年费加罗传感器KE-25KE-50特性：长寿命（KE-25-5年，KE-50-10年）不受CO2，CO，H2S，NOx，H2影响低成本，在常温下工作信号输出定，无需外部电源不需加热以上费加罗传感器技术参数以《OIML60号国际建议》92年版为基础，最新具体变化可查看《JJG669—12FIGARO广州南创传感器事业部检定规程》产品特性描述：氧气传感器KE-25KE-50属于半导体气体传感器不受CO2，CO，H2S，NOx，H2影响，氧气传感器KE-25KE-50低成本在常温下工作信号输出定，无需外部电源不需加热；精度氧气传。

日本费加罗催化燃烧可燃气体传感器TGS6812 Technical Information for Hydrogen Gas SensorsThe Figaro TGS6812 catalytic type gas sensor can detect levels of hydrogen up to 100%LEL. This sensor features high accuracy, good d urability and stability, quick response, and linear output. This sensor can detect hydrogen as well as methane and LP gas, making it an excellent solution for monitoring gas leakage from stationary fuel cell systems which transform combustible gases into hydrogen.P a g e Basic Information and SpecificationsFeatures (2)Applications (2)Structure..........................................................................2 Basic Measuring Circuit....................................................2 Circuit & Operating Conditions.. (3)Specifications (3)Dimensions...............................................................................3Typical Sensitivity Characteristics Sensitivity to Various Gases................................................4 Temperature Dependency...........................................................4 Humidity Dependency...........................................................4 Heater Voltage Dependency.............................................5 Gas Response....................................................................................5 Initial Action........................................................................5Reliability Long Term Characteristics.............................................................6 Durability to Hydrogen.......................................................................6 Durability to Sulphur Dioxide...........................................................6 Durability toNitrogen Dioxide.........................................................7 Durability to HMDS....................................................................7 Effects of Air Flow.............................................................................7Cautions (8)a n I S O 9001 c o m p a n yIMPORTANT NOTE: OPERATING CONDITIONS IN WHICH FIGARO SENSORS ARE USED WILL VARY WITH EACH CUSTOMER’S SPECIFIC APPLICATIONS. FIGARO STRONGLY RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WH EN CUSTOMER’S TARGET GASES ARE NOT LISTED H EREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH A SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.1. Basic Information and Specifications 1-1 Features* Linear output * Compact size* Small sensitivity to alcohol* Sensitive to hydrogen, methane, and LP gas * Meets RoHS requirements 1-2 Applications* Hydrogen and combustible gas leak detectors for fuel cell applications1-3 StructureFigure 1 shows the structure of TGS6812. The sensor is comprised of two elements: element (D) which is sensitive to combustible gases, and a reference element (C) which does not have sensitivity to combustible gases. The sensing element (D) is made of alumina doped with catalysts, while the reference element (C) is made of alumina. Both coils are made of Pt wire,and the wires of both elements (D) and (C) are connected to nickel pins No. 2 & 3 and No. 1 & 4 respectively. The sensor base and cap are made of reinforced Polybutylene Terephthalate (PBT). The upper opening in the cap is covered with a double layer of 100 mesh stainless steel gauze (SUS316). The TGS6812 utilizes a zeolite filter inside the cap for reducing the influence of interference gases.1-4 Basic measuring circuitThe T GS6812 i s c omprised o f t wo e lements: 1) e lement (D) which is sensitive to combustible gases and 2) a reference element (C) which is not sensitive to combustible gases. These elements are installed into a “Wheatstone Bridge”. A variable resistor should be adjusted so that the bridge will produce a stable baseline signal when in an environment free of combustible gases. When combustible gases are present, they will be combusted on the detecting element, causing its temperature to rise. Accordingly the resistance of this element will increase. This results in an “out-of-balance” signal across the bridge and a corresponding change in output voltage which can be measured.Fig. 1 - Sensor structureFig. 2 - Basic measuring circuitTop viewSide viewu/m = mmCapBottom viewBaseDetector sideCompensator side1-4 : Compensator 2-3 : Detector1-5 Circuit & operating conditionsThe ratings shown below should be maintained at all times to insure stable sensor performance:1-6 Specifications NOTE 1Mechanical Strength:The sensor shall have no abnormal findings in its structure and shall satisfy the above electricalspecifications after the following performance tests: Vibration - Drop test -frequency:10~150H z, accel-eration: 2G, duration:10 times, direction: three dimensions drop onto a cement floor from a height of 250mm, repeated 5 times NOTE 1:Sensitivity characteristics are obtained under the following standard test conditions:(Standard test conditions)Temperature a nd humidity: 20 ± 2?C, 65 ± 5% RH Circuit conditions:V H = 3.0±0.05V AC/DC Preheating period: 30 seconds or more under standard circuit conditions 1-7 Dimensions Fig. 3 - Sensor dimensionsAll sensor characteristics shown in this brochurerepresent typical characteristics. Actualcharacteristics vary from sensor to sensor andfrom production lot to production lot. The only characteristics warranted are those shown inthe Specification table above.-101020304050020*********Relative humidity (%RH)2-2 Temperature dependencyFigure 5 shows the temperature dependency of TGS6812 at 65%RH in 10%LEL of methane, LP gas, and hydrogen. Since the temperature dependency of element (D) is compensated by element (C), the temperature dependency of sensor output in the range from -10?C to +70?C is very small.2-3 Humidity dependencyFigure 6 shows the relative humidity dependencyof TGS6812 under constant temperature of 20?C in 10%LEL of methane, LP gas, and hydrogen. This data demonstrates that the humidity dependency of TGS6812 is negligible as humidity varies.Fig. 4 - TGS6812 sensitivity to various gasesFig. 6 - TGS6812 humidity dependency-10010203040502.902.953.003.05 3.10Operating voltage (V)2-4 Heater voltage dependencyFigure 7 shows the change in the sensor output according to variations in the heater voltage (V H ).Note that 3.0±0.1V as a heater voltage must be maintained because variance in applied heater voltage will cause the sensor’s characteristics to be changed from the typical characteristics shown in this brochure.2-5 Gas responseFigure 8 shows the change pattern of sensor output (Vout) for TGS6812 when the sensor is inserted 4000ppm of hydrogen.As these charts display, the sensor’s response speed to the presence of gas is extremely quick.2-6 Initial actionnormal air and later energized in clean air.warm-up process is called “Initial Action”.powering on, it is recommended that an initial delay circuit be incorporated into the detector’s design. This is esp ecially recommended for intermittent-operating devices such as portable gas detectors.Fig. 7 - Heater voltage dependencyFig. 8 - Gas responseFig. 9- Initial action-1010201020-101020period.3-2 Durability to hydrogenconcentration exposure to hydrogen gas. The measurement was taken, the sensor was exposed to 1% of H 2 for over 2000 hours. At each measurement point, the sensor was removed from H 2measuring sensor output.characteristics after exposure to high concentrations of hydrogen.3-3 Durability to sulphur dioxideFigure 12 shows the effect on TGS6812 of exposure to SO 2. The initial point of the graph shows the value of sensor output prior to SO 2 exposure. After the initial measurement was taken, the sensor was exposed to 25ppm of SO 2 for over 2400 hours in total. At each measurement point, the sensor was removed from SO 2 and energized in normal air for 10 hours prior to measuring the sensor output.The data demonstrates that TGS6812 shows stable characteristics after exposure to SO 2.Fig. 11 - Durability to hydrogenFig. 12 - Durability to SO 2-101020-101020characteristics after exposure to NO 2. 3-5 Durability to HMDSFigure 14 shows the effect on TGS6812 of exposure to HMDS.The initial point of the graph shows the value of sensor output prior to HMDS exposure. After the initial measurement was taken, the sensor was exposed to 10ppm of HMDS for one hour in total. At each measurement point, the sensor was removed from HMDS and energized in normal air for 1 hour prior to measuring the sensor output.This data demonstrates that TGS6812 shows stable characteristics after exposure to HMDS.3-6 Effects of Air FlowTable 1 shows how the sensor is affected by airflows (refer to Fig. 15 for illustration of airflows in Table 1). This data demonstrates that there is no significant influence on the sensor by an air flow of 3.1 meters/sec.Fig. 14 - Durability to HMDSFig. 15 - Air flow testing direction (ref. Table 1)Table 1 - Effects of air flow on output voltage4 Cautions on Usage of Figaro Gas Sensors4-1 Situations which must be avoided1) Exposure to silicone vaporsIf silicone vapors adsorb onto the sensor’s surface, the sensing material will be coated, irreversibly inhibiting sensitivity. Avoid exposure where silicone adhesives, hair grooming materials, or silicone rubber/putty may be present.2) Highly corrosive environmentHigh density exposure to corrosive materials such as H2S, SOx, Cl2, HCl, etc. for extended periods may cause corrosion or breakage of the lead wires or heater material.3) Contamination by alkaline metalsSensor drift may occur when the sensor is contaminated by alkaline metals, especially salt water spray.4) Contact with waterSensor drift may occur due to soaking or splashing the sensor with water.5) FreezingIf water freezes on the sensing surface, the sensing material would crack, altering characteristics.6) Application of excessive voltageIf higher than specified voltage is applied to the sensor, the lead wires and/or sensor elements may be damaged or sensor characteristics may drift, even if no physical damage or breakage occurs.7) Operation in zero/low oxygen environment TGS6812 requires the presence of a certain amount of oxygen in its operating environment in order to generate a combustion reaction of gas on the sensor’s surface. It cannot properly operate in a zero or low oxygen content atmosphere.8) Excessive exposure to alcoholIf TGS6812 is exposed to high concentrations of alcohol (such as 10,000ppm or more) for a long period, the filter may become saturated. In this case, the sensor would show a lower resistance in alcohol than indicated in Figure 4.9) VibrationExcessive vibration may result in zero drift or cause the sensor or lead wires to resonate and break. Usage of compressed air drivers/ultrasonic welders on assembly lines may generate such vibration, so tests should be conducted to verify that there will be no influence on sensor characteristics.10) ShockZero drift and breakage of lead wires may occur if the sensor is subjected to a strong shock. To avoid shock, please keep the sensor in the original packing foam during storage.4-2 Situations to be avoided whenever possible1) Water condensationLight condensation under conditions of indoor usage should not pose a problem for sensor performance.H owever, if water condenses on the sensor’s surface and remains for an extended period, sensor characteristics may drift.2) Usage in high density of gasSensor performance may be affected if exposed to a high density of gas for a long period of time, regardless of the powering condition.3) Storage for extended periodsWhen stored without powering for a long period, the sensor may show a reversible drift in resistance according to the environment in which it was stored. The sensor should be stored in a sealed bag containing clean air; do not use silica gel. Note that as unpowered storage becomes longer, a longer preheating period is required to stabilize the sensor before usage. 4) Long term exposure in adverse environment Regardless of powering condition, if the sensor is exposed in extreme conditions such as very high humidity, extreme temperatures, or high contamination levels for a long period of time, sensor performance will be adversely affected.5) SolderingIdeally, sensors should be soldered manually.H owever, wave soldering can be done under the following conditions:a) Suggested flux: rosin flux with minimal chlorineb) Speed: 1-2 meters/min.c) Preheating temperature: 100±20?Cd) Solder temperature: 250±10?Ce) Up to two passes through wave soldering machine allowed Results of wave soldering cannot be guaranteed if conducted outside the above guidelines since someFigaro USA Inc. and the manufacturer, Figaro Engineering Inc. (together referred to as Figaro) reserve the right to make changes without notice to any products herein to improve reliability , functioning or design. Information contained in this document is believed to be reliable. H owever, Figaro does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights, nor the rights of others.Figaro’s products are not authorized for use as critical components in life support applications wherein a failure or malfunction of the products may result in injury or threat to life.flux vapors may cause drift in sensor performance similar to the effects of silicone vapors.。

Technical Information for Combustible Gas SensorsFigaro TGS 8-series sensors are a type of sintered bulk metal oxide semiconductor wh ich offer low cost, long life, and good sensitivity to target gases while utilizing a simple electrical circuit. Th e TGS813 displays h igh selectivity and sensitivity to LP Gas and methane.PageSpecificationsFeatures..........................................................................2 Applications...................................................................2 Structure..........................................................................2 Basic measuring circuit....................................................2 Circuit & operating conditions.........................................3 Specifications..............................................................................3 Dimensions...............................................................................3Basic Sensitivity Characteristics Sensitivity to various gases................................................4 Temperature and humidity dependency............................5 Heater voltage dependency..........................................................6 Gas response....................................................................................6 Initial action........................................................................7 Long term characteristics.............................................................7Cautions . (8)See also Technical Brochure ‘Technical Information on Usage of TGSSensors for Toxic and Explosive Gas Leak Detectors’.IMPORTANT NOTE: OPERATING CONDITIONS IN WHICH FIGARO SENSORS ARE USED WILL VARY WITH EACH CUSTOMER’S SPECIFIC APPLICATIONS. FIGARO STRONGLY RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WH EN CUSTOMER’S TARGET GASES ARE NOT LISTED H EREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.a n I S O 9001 c o m p a n y1. Specifications 1-1 Features * General purpose sensor for a wide range of combustible gases* High sensitivity to LP gas and methane * Low cost * Long life* Uses simple electrical circuit1-2 Applications* Domestic gas leak detectors and alarms * Recreational vehicle gas leak detectors * Portable gas detectors1-3 StructureFigure 1 shows the structure of TGS813. This sensor is a sintered bulk semiconductor composed mainly of tin dioxide (SnO 2). The semiconductor material and electrodes are formed on an alumina ceramic tube. A heater coil, made of 60 micron diameter wire, is located inside the ceramic tube. Lead wires from the sensor electrodes are a gold alloy of 80 microns in diameter. Heater and lead wires are spotwelded to the sensor pins which have been arranged to fit a 7-pin miniature tube socket.The sensor base and cover are made of Nylon 66, conforming to UL 94H B (Authorized Material Standard). The deformation temperature for this material is in excess of 240˚C. The upper and lower openings in the sensor case are covered with a flameproof double layer of 100 mesh stainless steel gauze (SUS316). Independent tests confirm that this mesh will prevent a spark produced inside the flameproof cover from igniting an explosive 2:1 mixture of hydrogen/oxygen.1-4 Basic measuring circuitFigure 2 shows the basic measuring circuit for use with TGS813. Circuit voltage (Vc) is applied across the sensor element which has a resistance between the sensor’s two electrodes and the load resistor (R L ) connected in series. The sensor signal (V RL ) is measured indirectly as a change in voltage across the R L . The Rs is obtained from the formula shown at the right.Fig. 1 - Sensor structureFig. 2 - Basic measuring circuitVc- V RLV RLRs = x R LFormula to determine RsSensor elementFig. 3 - Sensor dimensions1-5 Circuit & operating conditionsThe ratings shown below should be maintained at all times to insure stable sensor performance:1-6 Specifications NOTE 1Mechanical Strength:The sensor shall have no abnormal findings in its structure and shall satisfy the above electrical specifications after the following performance tests:Withdrawal Force - Vibration - Shock -withstand force > 5kg in eachdirectionfrequency-1000c/min., totalamplitude-4mm, duration-one hour, direction-verticalacceleration-100G, repeated 5timesNOTE 1: Sensitivity characteristics are obtained under the following standard test conditions:(Standard test conditions)Temperature and humidity: 20 ± 2˚C, 65 ± 5% RH Circuit conditions:Vc = 10.0±0.1V AC/DC V H = 5.0±0.05V AC/DC R L = 4.0kΩ ± 1%Preheating period: 7 days or more under standard circuit conditions17ø±0.516.5±0.56.5±0.59.5ø1ø±0.0545˚45˚132645u/m:mm1-7 DimensionsTop viewSide viewBottom view2. Basic Sensitivity Characteristics 2-1 Sensitivity to various gasesFigure 4 shows the relative sensitivity of TGS813 to various gases. The Y-axis shows the ratio of the sensor resistance in various gases (Rs) to the sensor resistance in 1000ppm of methane (Ro).Using the basic measuring circuit illustrated in Figure 2, these sensitivity characteristics provide the sensor output voltage (V RL ) change as shown in Figure 5.NOTE :All sensor characteristics in this technical brochure represent typical sensor characteristics. Since the Rs or output voltage curve varies from sensor to sensor, calibration is required for each sensor (for additional information on calibration, please refer to the Technical Advisory ‘Technical Information on Usage of TGS Sensors for Toxic and Explosive Gas Leak Detectors’).12-2 Temperature and humidity dependencyFigure 6 shows the temperature and humidity dependency of TGS813. The Y-axis shows the ratio of sensor resistance in 1000ppm of methane under various atmospheric conditions (Rs) to the sensor resistance in 1000ppm of methane at 20˚C/65%RH (Ro).under various ambient conditionsTable 1 - Temperature and humidity dependency(typical values of Rs/Ro for Fig. 6)Table 1 shows a chart of values of the sensor’s resistance ratio (Rs/Ro) under the same conditions as those used to generate Figure 6.Figure 7 shows the sensitivity curve for TGS813 to methane under several ambient conditions. While temperature may have a large influence on absolute Rs values, this chart illustrates the fact that effect on the slope of sensor resistance ratio (Rs/Ro) is not significant. As a result, the effects of temperature on the sensor can easily be compensated.For economical circuit design, a thermistor can be incorporated to compensate for temperature (for additional information on temperature compensation in circuit designs, please refer to the Technical Advisory ‘Technical Information on Usage of TGS Sensors for Toxic and Explosive Gas Leak Detectors’).1010Rs (kΩ)102-6 Initial actionclean air.process is called “Initial Action”.circuit be incorporated into the detector’s design (TGS Sensors for Toxic and Explosive Gas Leak Detectors’). This is especially recommended for intermittent-operating devices such as portable gas detectors.2-7 Long-term characteristicsFigure 13 shows long-term stability of TGS813 as measured for more than 8 years. The sensor is first energized in normal air. Measurement for confirming sensor characteristics is conducted under ambient air conditions rather than in a temperature/humidity controlled environment. The cyclic change in sensitivity corresponds to the seasonal changes of temperature/humidity in Japan (peak T/H conditions occur in July, as corresponds with the sensitivity peaks in this chart ). The Y-axis represents the ratio of sensor resistance in 1000ppm of methane on the date tested (Rs) to sensor resistance in 1000ppm of methane at the beginning of the test period (Ro).As this chart illustrates, TGS813 shows stable characteristics over a very long period of time.Fig. 12 - Long term stability(Ro = Rs on day 1)3 Cautions3-1 Situations which must be avoided1) Exposure to silicone vaporsIf silicone vapors adsorb onto the sensor’s surface, the sensing material will be coated, irreversibly inhibiting sensitivity. Avoid exposure where silicone adhesives, hair grooming materials, or silicone rubber/putty may be present.2) Highly corrosive environmentHigh density exposure to corrosive materials such as H2S, SOx, Cl2, HCl, etc. for extended periods may cause corrosion or breakage of the lead wires or heater material.3) Contamination by alkaline metalsSensor drift may occur when the sensor is contam-inated by alkaline metals, especially salt water spray.4) Contact with waterSensor drift may occur due to soaking or splashing the sensor with water.5) FreezingIf water freezes on the sensing surface, the sensing material would crack, altering characteristics.6) Application of excessive voltageIf higher than specified voltage is applied to the sensor or the heater, lead wires and/or the heater may be damaged or sensor characteristics may drift, even if no physical damage or breakage occurs.7) Application of voltage on lead wiresOn six-pin type sensors, if a voltage is applied on the lead wires between pins 1 and 3 and/or pins 4 and 6, this would cause breakage of the lead wires.8) Operation in zero/low oxygen environment TGS sensors require the presence of around 21% (ambient) oxygen in their operating environment in order to function properly and to exhibit characteristics described in Figaro’s product literature. TGS sensors cannot properly operate in a zero or low oxygen content atmosphere.3-2 Situations to be avoided whenever possible1) Water condensationLight condensation under conditions of indoor usage should not pose a problem for sensor performance.H owever, if water condenses on the sensor’s surface and remains for an extended period, sensor characteristics may drift.2) Usage in high density of gasSensor performance may be affected if exposed to a high density of gas for a long period of time, regardless of the powering condition.3) Storage for extended periodsWhen stored without powering for a long period, the sensor may show a reversible drift in resistance according to the environment in which it was stored. The sensor should be stored in a sealed bag containing clean air; do not use silica gel. Note that as unpowered storage becomes longer, a longer preheating period is required to stabilize the sensor before usage. 4) Long term exposure in adverse environment Regardless of powering condition, if the sensor is exposed in extreme conditions such as very high humidity, extreme temperatures, or high contamination levels for a long period of time, sensor performance will be adversely affected.5) VibrationExcessive vibration may cause the sensor or lead wires to resonate and break. Usage of compressed air drivers/ultrasonic welders on assembly lines may generate such vibration, so please check this matter.6) ShockBreakage of lead wires may occur if the sensor is subjected to a strong shock.7) SolderingIdeally, sensors should be soldered manually. For soldering conditions of 8-series gas sensors, refer to Technical Advisory for Soldering 8-type Gas Sensors. 8) PolarityIf the polarity of Vc is reversed during powering, sensor characteristics may temporarily become unstable.15 24 36Figaro USA Inc. and the manufacturer, Figaro Engineering Inc. (together referred to as Figaro) reserve the right to make changes without notice to any products herein to improve reliability, functioning or design. Information contained in this document is believed to be reliable. H owever, Figaro does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights, nor the rights of others.Figaro’s products are not authorized for use as critical components in life support applications wherein a failure or malfunction of the products may result in injury or threat to life.。

１．安全注意事项２．使用注意事项３．部件名称及功能概述４．测试准备５．测试方法６．规格目次欢迎购买使用气体传感器评价试验箱（EC01），对此我们表示由衷的感谢！请在仔细阅读本操作使用说明书后正确使用本产品。

１１２４６８费加罗技研株式会社EC01（气体传感器评价试验箱）操作使用说明书(1)(2)(3)(4)1. 安全注意事项请务必遵守2. 使用注意事项本产品是一种简易型的试验箱。

使用时请仔细盖紧盖板不能留有缝隙。

如果要进行很精确的气体测试时，请选用比本产品气密性更高的试验箱。

测试时如果将类似于气体报警器这样体积较大的设备放入试验箱的话，可能因为试验箱的有效容积减少而导致气体浓度制备出现误差。

由于氨气、VOC 、有机溶剂蒸汽等吸附性很强的气体很容易吸附在试验箱的内壁之上，因此本产品不适用于这些气体的测试用途。

吸附于箱内壁的气体液化后，有可能导致试验箱内的气体浓度下降。

有必要对吸附性很强的气体进行测试时，请选用箱内壁采用了气体不容易附着材质的试验箱，或对箱内壁进行过涂层处理的试验箱。

如果已经向本试验箱内注入了吸附性很强的气体，为了在使用后去除附着的气体，请用酒精擦拭试验箱内部，然后对内部用洁净空气进行长时间换气等的妥善处置。

如果在高温、低温或极度的低湿度与高湿度的室内环境进行测试的话，气体传感器的测定值可能会受到影响。

请在测试前对各型号传感器规格进行确认。

本试验箱没有防爆设计。

请勿在对气体爆炸下限为(LEL) 50％以上浓度的可燃性气体进行测试时使用。

本试验箱无法保证绝对完全的密闭状态。

请勿在对可能危及人身安全的高浓度毒性气体进行测试时使用。

在用于对可燃性气体进行测试时请务必注意防火措施，同时试验箱向外排气时请在可以充分换气的场所进行。

而且，为确保安全，请考虑采取设置气体报警器等措施。

尤其是在用于对毒性气体进行测试的用途时，请务必在能够保证充分换气的场所进行。

另外出于安全考虑，将试验箱中的气体排出时请注意避免人员吸入的同时，请在室外或排风罩内进行操作。

TGS3830 用于检测氟利昂（CFC S ）的气体传感器* 低功耗* 对R-134a 灵敏度高* 对R-134a 响应极快特点:应用:* 便携式制冷剂泄漏检测仪TGS3830是费加罗采用新研发的金属氧化物的半导体气体传感器，主要用于检测氟利昂。

此传感器的敏感素子是一种二氧化锡（SnO 2）半导体，导电率低，其导电率将因空气中对象检测气体浓度的上升而上升。

一个简单的电路，即可将导电率的变化转变为对应气体浓度的输出信号。

而且，气敏珠非常微小，加热器的功耗仅需120mW 。

TGS3830对广泛运用于空调与冰箱制冷剂的R-12的最佳替代品R-134a 有极高的灵敏度，而且响应速度快，因此TGS3830是一款非常优秀的低成本便携式制冷剂泄漏报警器最理想的传感器。

下图所示在标准试验条件下（参见背面）测出具有代表性的灵敏度特性曲线。

纵坐标表示传感器电阻比 Rs/Ro ，Rs 与Ro 的定义如下：Rs = 各种浓度气体中的传感器电阻值Ro = 清洁空气中的传感器电阻值下图所示在100cc/min 条件下测出具有代表性的气体响应与重复曲线。

纵坐标表示传感器电阻比 Rs/Ro ，Rs 与Ro 的定义如下：灵敏度特性:气体响应与重复性:重要提示: 费加罗传感器的使用条件将因不同客户的具体运用不同而不同。

费加罗强烈建议在使用前咨询我们的技术人员，尤其是当客户的检测对象气体不在列表范围时，对于未经费加罗专业测试的任何使用，费加罗不承担任何责任。

Rs/RoRs = 各种浓度气体中的传感器电阻值Ro = 清洁空气中的传感器电阻值R s /R oR s /R oREV.08/16规格:结构以及尺寸:传感器电阻（R S ）可根据 V RS 的测定值用下式求出：V RS -0.5V H V C -V RSR S = () x R L 重要提示：此产品并没有设计、授权使用应用中的重要组成部分——生命支持，产品失效或故障任何一个因素都可能导致人身伤害或生命危险。

TGS822 有机溶剂蒸气检测用特点： 应用：・对乙醇等有机溶剂有高灵敏度 ・酒精检测器・长期稳定性优良 ・工厂、干洗店、半导体产业的 ・长寿命、低成本 有机溶剂检知 ・以简单电路即可使用费加罗气体传感器的气敏素子，使用在清洁空气中电导率低的二氧化锡(SnO2)。

当存在检知对象气体时，传感器的电导率随空气中气体浓度增加而增大。

使用简单的电路即可将电导率的变化，转换为与该气体浓度相对应的输出信号。

TGS822传感器对酒精、有机溶剂的灵敏度高，在酒精检测器等方面得到广泛应用。

相同特性的TGS823，采用了陶瓷底座，可以在200℃的高温气氛中使用。

下图是典型的灵敏度特性，全部是在标准试验条件下得出的结果。

（请看背面）纵坐标以传感器电阻比（Rs/Ro ）表示，Rs ，Ro 的定义如下：Rs ＝不同浓度气体中的电阻值 Ro ＝300ppm 乙醇中的电阻值灵敏度特性： 下图为受温度、湿度影响的典型曲线。

图中纵坐标也以传感器电阻比（Rs/Ro ）表示，这里的Rs ，Ro 定义如下：Rs=含300ppm 乙醇、各种温/湿度下的电阻值 Ro=含300ppm 乙醇、20℃65%R.H.下的电阻值温/湿度的影响：SUNSTAR传感与控制 0755-********SUNSTAR传感与控制/TEL:0755-********FAX:0755-********E-MAIL:**************规格： 结构及尺寸：型 号 TGS822 素子类型 8系列标准封装塑料、SUS 双重金属网对象气体 酒精、有机溶剂 检测范围50～5,000 ppm 加热器电压VH 5.0±0.2V DC/AC 回路电压 VC MAX 24VPs ≦15mW标准回路 条件负载电阻 RL 可变 Ps ≦15mW 加热器电阻RH 38±3.0 Ω（室温） 加热器功耗PH 660±55mWVH ＝5.0V传感器电阻Rs300ppm 乙醇中 1～10K Ω 标准试验 条件下的 电学特性灵敏度(Rs 的变化率)0.4±0.1Rs(EtOH:300ppm)Rs(EtOH:50ppm)试验气体条件20±2℃， 65±5％RH 回路条件 VC ＝10.0±0.1V DC/AC VH ＝5.0±0.05V DC/AC RL=10.0 K Ω±1%标准试验 条件预热时间7天以上功耗（Ps）值可用下式计算： 传感器电阻（Rs ），可用下式计算：管脚连接 1或3：传感器4或6：传感器2 ：加热器5 ：加热器SUNSTAR传感与控制 0755-********SUNSTAR传感与控制/TEL:0755-********FAX:0755-********E-MAIL:**************FIGAROApplications:Features:TGS 822 - for the detection of Organic Solvent VaporsThe figure below represents typical sensitivity char-acteristics, all data having been gathered at standard test conditions (see reverse side of this sheet). The Y-axis is indicated as sensor resistance ratio (Rs/Ro) which is defined as follows:The figure below represents typical temperature and humidity dependency characteristics. Again, the Y-axis is indicated as sensor resistance ratio (Rs/Ro), defined as follows:Rs = Sensor resistance at 300ppm of ethanol* High sensitivity to organic solvent vaporssuch as ethanol* High stability and reliability over a longperiod* Long life and low cost* Uses simple electrical circuit* Breath alcohol detectors* Gas leak detectors/alarms* Solvent detectors for factories, dry clean-ers, and semiconductor industriesThe sensing element of Figaro gas sensors is a tin dioxide (SnO 2) semiconductor which has low conductivity in clean air. In the presence of a detectable gas,the sensor's conductivity increases depending on the gas concentration in the air. A simple electrical circuit can convert the change in conductivity to an output signal which corresponds to the gas concentration.The TGS 822 has high sensitivity to the vapors of organic solvents as well as other volatile vapors. It also has sensitivity to a variety of combustible gases such as carbon monoxide, making it a good general purpose sensor. Also available with a ceramic base which is highly resistant to severe environments as high as 200°C (model# TGS 823).IMPORTANT NOTE: RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WHEN CUSTOMER’S TARGET GASES ARE NOT LISTED HEREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.SUNSTAR自动化/TEL:0755-********FAX:0755-********E-MAIL:**************Structure and Dimensions:1 Sensing Element:SnO 2 is sintered to form a thick film on the surface of an alumina ceramic tube which contains an internal heater.2 Cap:Nylon 663 Sensor Base:Nylon 664 Flame Arrestor:100 mesh SUS 316 double gauzePin Connection and Basic Measuring Circuit:The numbers shown around the sensor symbol in the circuit diagram at the right correspond with the pin numbers shown in the sensor's structure drawing (above). When the sensor is connected as shown in the basic circuit, output across the Load Resistor (V RL ) increases as the sensor's resistance (Rs) de-creases, depending on gas concentration.Sensor Resistance (Rs) is calculated by the following formula:Rs = (-1) x R LV CV RL Power dissipation across sensor electrodes (Ps) is calculated by the following formula:Ps = 2V C x Rs 2(Rs + R L )Basic Measuring Circuit:REV: 9/99when the sensor is tested in standard conditions as speci-fied below:Test Gas Conditions:20°±2°C, 65±5%R.H.Circuit Conditions:V C = 10.0±0.1V (AC or DC),V H = 5.0±0.05V (AC or DC),R L = 10.0k Ω±1%Preheating period before testing: More than 7 daysFor information on warranty, please refer to Standard Terms and Conditions of Sale of Figaro USA Inc.17 ± 0.59.516.5±0.56.5±0.51.0±0.563425145˚45˚um : mmSUNSTAR自动化/TEL:0755-********FAX:0755-********E-MAIL:**************TGS822TF 人工煤制气检测用特点： 应用：・对煤制气中的氢气和一氧化碳有高灵敏度 ・家庭用、业务用煤制气报警器 ・乙醇等有机溶剂的干扰小 ・便携式煤制气检知 ・长寿命、低成本 ・以简单电路即可使用费加罗气体传感器的气敏素子，使用在清洁空气中电导率低的二氧化锡(SnO2)。

Technical Information for Hydrogen Gas SensorsThe Figaro TGS6812 catalytic type gas sensor can detect levels of hydrogen up to 100%LEL. This sensor features high accuracy, good d urability and stability, quick response, and linear output. This sensor can detect hydrogen as well as methane and LP gas, making it an excellent solution for monitoring gas leakage from stationary fuel cell systems which transform combustible gases into hydrogen.P a g e Basic Information and SpecificationsFeatures..........................................................................2 Applications...................................................................2 Structure..........................................................................2 Basic Measuring Circuit....................................................2 Circuit & Operating Conditions.........................................3 Specifications..............................................................................3 Dimensions...............................................................................3Typical Sensitivity Characteristics Sensitivity to Various Gases................................................4 Temperature Dependency...........................................................4 Humidity Dependency...........................................................4 Heater Voltage Dependency.............................................5 Gas Response....................................................................................5 Initial Action........................................................................5Reliability Long Term Characteristics.............................................................6 Durability to Hydrogen.......................................................................6 Durability to Sulphur Dioxide...........................................................6 Durability to Nitrogen Dioxide.........................................................7 Durability to HMDS....................................................................7 Effects of Air Flow.............................................................................7Cautions (8)a n I S O 9001 c o m p a n yIMPORTANT NOTE: OPERATING CONDITIONS IN WHICH FIGARO SENSORS ARE USED WILL VARY WITH EACH CUSTOMER’S SPECIFIC APPLICATIONS. FIGARO STRONGLY RECOMMENDS CONSULTING OUR TECHNICAL STAFF BEFORE DEPLOYING FIGARO SENSORS IN YOUR APPLICATION AND, IN PARTICULAR, WH EN CUSTOMER’S TARGET GASES ARE NOT LISTED H EREIN. FIGARO CANNOT ASSUME ANY RESPONSIBILITY FOR ANY USE OF ITS SENSORS IN A PRODUCT OR APPLICATION FOR WHICH A SENSOR HAS NOT BEEN SPECIFICALLY TESTED BY FIGARO.1. Basic Information and Specifications 1-1 Features* Linear output * Compact size* Small sensitivity to alcohol* Sensitive to hydrogen, methane, and LP gas * Meets RoHS requirements 1-2 Applications* Hydrogen and combustible gas leak detectors for fuel cell applications1-3 StructureFigure 1 shows the structure of TGS6812. The sensor is comprised of two elements: element (D) which is sensitive to combustible gases, and a reference element (C) which does not have sensitivity to combustible gases. The sensing element (D) is made of alumina doped with catalysts, while the reference element (C) is made of alumina. Both coils are made of Pt wire, and the wires of both elements (D) and (C) are connected to nickel pins No. 2 & 3 and No. 1 & 4 respectively. The sensor base and cap are made of reinforced Polybutylene Terephthalate (PBT). The upper opening in the cap is covered with a double layer of 100 mesh stainless steel gauze (SUS316). The TGS6812 utilizes a zeolite filter inside the cap for reducing the influence of interference gases.1-4 Basic measuring circuitThe T GS6812 i s c omprised o f t wo e lements: 1) e lement (D) which is sensitive to combustible gases and 2) a reference element (C) which is not sensitive to combustible gases. These elements are installed into a “Wheatstone Bridge”. A variable resistor should be adjusted so that the bridge will produce a stable baseline signal when in an environment free of combustible gases. When combustible gases are present, they will be combusted on the detecting element, causing its temperature to rise. Accordingly the resistance of this element will increase. This results in an “out-of-balance” signal across the bridge and a corresponding change in output voltage which can be measured.Fig. 1 - Sensor structureFig. 2 - Basic measuring circuitTop viewSide viewu/m = mmCapBottom viewBaseDetector sideCompensator side<Pin connection>1-4 : Compensator 2-3 : Detector1-5 Circuit & operating conditionsThe ratings shown below should be maintained at all times to insure stable sensor performance:1-6 Specifications NOTE 1Mechanical Strength:The sensor shall have no abnormal findings in its structure and shall satisfy the above electricalspecifications after the following performance tests: Vibration - Drop test -frequency:10~150H z, accel-eration: 2G, duration:10 times, direction: three dimensions drop onto a cement floor from a height of 250mm, repeated 5 timesNOTE 1:Sensitivity characteristics are obtained under the following standard test conditions:(Standard test conditions)Temperature and humidity: 20 ± 2˚C, 65 ± 5% RH Circuit conditions:V H = 3.0±0.05V AC/DC Preheating period: 30 seconds or more under standard circuit conditions 1-7 DimensionsFig. 3 - Sensor dimensionsAll sensor characteristics shown in this brochurerepresent typical characteristics. Actualcharacteristics vary from sensor to sensor andfrom production lot to production lot. The onlycharacteristics warranted are those shown inthe Specification table above.-101020304050020*********Relative humidity (%RH)2-2 Temperature dependencyFigure 5 shows the temperature dependency ofTGS6812 at 65%RH in 10%LEL of methane, LP gas,and hydrogen. Since the temperature dependencyof element (D) is compensated by element (C), thetemperature dependency of sensor output in therange from -10˚C to +70˚C is very small.2-3 Humidity dependencyFigure 6 shows the relative humidity dependencyof TGS6812 under constant temperature of 20˚C in10%LEL of methane, LP gas, and hydrogen. Thisdata demonstrates that the humidity dependency ofTGS6812 is negligible as humidity varies.Fig. 4 - TGS6812 sensitivity to various gasesFig. 6 - TGS6812 humidity dependency-10010203040502.902.953.003.05 3.10Operating voltage (V)2-4 Heater voltage dependencyFigure 7 shows the change in the sensor output according to variations in the heater voltage (V H ).Note that 3.0±0.1V as a heater voltage must be maintained because variance in applied heater voltage will cause the sensor’s characteristics to be changed from the typical characteristics shown in this brochure.2-5 Gas responseFigure 8 shows the change pattern of sensor output (Vout) for TGS6812 when the sensor is inserted 4000ppm of hydrogen.As these charts display, the sensor’s response speed to the presence of gas is extremely quick.2-6 Initial actionnormal air and later energized in clean air.warm-up process is called “Initial Action”.powering on, it is recommended that an initial delay circuit be incorporated into the detector’s design. This is especially recommended for intermittent-operating devices such as portable gas detectors.Fig. 7 - Heater voltage dependencyFig. 8 - Gas responseFig. 9- Initial action-1010201020-101020period.3-2 Durability to hydrogenconcentration exposure to hydrogen gas. The measurement was taken, the sensor was exposed to 1% of H 2 for over 2000 hours. At each measurement point, the sensor was removed from H 2measuring sensor output.characteristics after exposure to high concentrations of hydrogen.3-3 Durability to sulphur dioxideFigure 12 shows the effect on TGS6812 of exposure to SO 2. The initial point of the graph shows the value of sensor output prior to SO 2 exposure. After the initial measurement was taken, the sensor was exposed to 25ppm of SO 2 for over 2400 hours in total. At each measurement point, the sensor was removed from SO 2 and energized in normal air for 10 hours prior to measuring the sensor output.The data demonstrates that TGS6812 shows stable characteristics after exposure to SO 2.Fig. 11 - Durability to hydrogenFig. 12 - Durability to SO 2-101020-101020characteristics after exposure to NO 2. 3-5 Durability to HMDSFigure 14 shows the effect on TGS6812 of exposure to HMDS. The initial point of the graph shows the value of sensor output prior to HMDS exposure. After the initial measurement was taken, the sensor was exposed to 10ppm of HMDS for one hour in total. At each measurement point, the sensor was removed from HMDS and energized in normal air for 1 hour prior to measuring the sensor output.This data demonstrates that TGS6812 shows stable characteristics after exposure to HMDS.3-6 Effects of Air FlowTable 1 shows how the sensor is affected by airflows (refer to Fig. 15 for illustration of airflows in Table 1). This data demonstrates that there is no significant influence on the sensor by an air flow of 3.1 meters/sec.Fig. 14 - Durability to HMDSFig. 15 - Air flow testing direction (ref. Table 1)Table 1 - Effects of air flow on output voltage4 Cautions on Usage of Figaro Gas Sensors4-1 Situations which must be avoided1) Exposure to silicone vaporsIf silicone vapors adsorb onto the sensor’s surface, the sensing material will be coated, irreversibly inhibiting sensitivity. Avoid exposure where silicone adhesives, hair grooming materials, or silicone rubber/putty may be present.2) Highly corrosive environmentHigh density exposure to corrosive materials such as H2S, SOx, Cl2, HCl, etc. for extended periods may cause corrosion or breakage of the lead wires or heater material.3) Contamination by alkaline metalsSensor drift may occur when the sensor is contaminated by alkaline metals, especially salt water spray.4) Contact with waterSensor drift may occur due to soaking or splashing the sensor with water.5) FreezingIf water freezes on the sensing surface, the sensing material would crack, altering characteristics.6) Application of excessive voltageIf higher than specified voltage is applied to the sensor, the lead wires and/or sensor elements may be damaged or sensor characteristics may drift, even if no physical damage or breakage occurs.7) Operation in zero/low oxygen environment TGS6812 requires the presence of a certain amount of oxygen in its operating environment in order to generate a combustion reaction of gas on the sensor’s surface. It cannot properly operate in a zero or low oxygen content atmosphere.8) Excessive exposure to alcoholIf TGS6812 is exposed to high concentrations of alcohol (such as 10,000ppm or more) for a long period, the filter may become saturated. In this case, the sensor would show a lower resistance in alcohol than indicated in Figure 4.9) VibrationExcessive vibration may result in zero drift or cause the sensor or lead wires to resonate and break. Usage of compressed air drivers/ultrasonic welders on assembly lines may generate such vibration, so tests should be conducted to verify that there will be no influence on sensor characteristics.10) ShockZero drift and breakage of lead wires may occur if the sensor is subjected to a strong shock. To avoid shock, please keep the sensor in the original packing foam during storage.4-2 Situations to be avoided whenever possible1) Water condensationLight condensation under conditions of indoor usage should not pose a problem for sensor performance.H owever, if water condenses on the sensor’s surface and remains for an extended period, sensor characteristics may drift.2) Usage in high density of gasSensor performance may be affected if exposed to a high density of gas for a long period of time, regardless of the powering condition.3) Storage for extended periodsWhen stored without powering for a long period, the sensor may show a reversible drift in resistance according to the environment in which it was stored. The sensor should be stored in a sealed bag containing clean air; do not use silica gel. Note that as unpowered storage becomes longer, a longer preheating period is required to stabilize the sensor before usage. 4) Long term exposure in adverse environment Regardless of powering condition, if the sensor is exposed in extreme conditions such as very high humidity, extreme temperatures, or high contamination levels for a long period of time, sensor performance will be adversely affected.5) SolderingIdeally, sensors should be soldered manually.H owever, wave soldering can be done under the following conditions:a) Suggested flux: rosin flux with minimal chlorineb) Speed: 1-2 meters/min.c) Preheating temperature: 100±20˚Cd) Solder temperature: 250±10˚Ce) Up to two passes through wave soldering machine allowed Results of wave soldering cannot be guaranteed if conducted outside the above guidelines since someFigaro USA Inc. and the manufacturer, Figaro Engineering Inc. (together referred to as Figaro) reserve the right to make changes without notice to any products herein to improve reliability , functioning or design. Information contained in this document is believed to be reliable. H owever, Figaro does not assume any liability arising out of the application or use of any product or circuit described herein; neither does it convey any license under its patent rights, nor the rights of others.Figaro’s products are not authorized for use as critical components in life support applications wherein a failure or malfunction of the products may result in injury or threat to life.flux vapors may cause drift in sensor performance similar to the effects of silicone vapors.。