ICGOO在线商城 > 电路保护 > TVS - 变阻器,MOV > V18MLA1206NH
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V18MLA1206NH产品简介:
ICGOO电子元器件商城为您提供V18MLA1206NH由Littelfuse设计生产,在icgoo商城现货销售,并且可以通过原厂、代理商等渠道进行代购。 V18MLA1206NH价格参考。LittelfuseV18MLA1206NH封装/规格:TVS - 变阻器,MOV, 25V 150A Varistor 1 Circuit Surface Mount, MLCV 1206 (3216 Metric)。您可以下载V18MLA1206NH参考资料、Datasheet数据手册功能说明书,资料中有V18MLA1206NH 详细功能的应用电路图电压和使用方法及教程。
参数 | 数值 |
产品目录 | |
描述 | VARISTOR 22V 150A 1206 |
产品分类 | |
品牌 | Littelfuse Inc |
数据手册 | |
产品图片 | |
产品型号 | V18MLA1206NH |
rohs | 不受无铅要求限制 / 符合限制有害物质指令(RoHS)规范要求 |
产品系列 | MLA |
产品培训模块 | http://www.digikey.cn/PTM/IndividualPTM.page?site=cn&lang=zhs&ptm=25313 |
其它名称 | F3820CT |
包装 | 带卷 (TR) |
变阻器电压 | 22V |
封装/外壳 | 1206(3216 公制) |
最大AC电压 | 14VAC |
最大DC电压 | 18VDC |
标准包装 | 1 |
电流-浪涌 | 150A |
电路数 | 1 |
能量 | 0.40J |
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series MLA Varistor Series RoHS Description The MLA Series family of transient voltage surge suppression devices is based on the Littelfuse Multilayer fabrication technology. These components are designed to suppress a variety of transient events, including those specified in IEC 61000-4-2 or other standards used for Electromagnetic Compliance (EMC). The MLA Series is typically applied to protect integrated circuits and other components at the circuit board level. The wide operating voltage and energy range make the MLA Series suitable for numerous applications on power supply, control and signal lines. The MLA Series is manufactured from semiconducting Size Table ceramics, and is supplied in a leadless, surface mount package. The MLA Series is compatible with modern Metric EIA reflow and wave soldering procedures. 1005 0402 1608 0603 It can operate over a wider temperature range than Zener diodes, and has a much smaller footprint than plastic- 2012 0805 housed components. 3216 1206 Littelfuse Inc. manufactures other multilayer series 3225 1210 products. See the MLE Series data sheet for ESD applications, MHS Series data sheet for high-speed ESD Absolute Maximum Ratings applications, the MLN Series for multiline protection and • For ratings of individual members of a series, see device ratings and specifications table. the AUML Series for automotive applications. Continuous ML Series Units Steady State Applied Voltage: Features DC Voltage Range (V ) 3.5 to 120 V M(DC) AC Voltage Range (V ) 2.5 to 107 V • Halogen-Free and • Rated for surge M(AC)RMS RoHS compliant current (8 x 20µs) Transient: • Leadless 0402, • Rated for energy Non-Repetitive Surge Current, 8/20µs 4 to 500 A 0603, 0805, 1206 (10 x 1000µs) Waveform, (I ) TM and 1210 chip sizes • Inherent bi-directional Non-Repetitive Surge Energy, 0.02 to • Multilayer ceramic clamping J 10/1000µs Waveform, (W ) 2.5 construction TM • Standard low technology capacitance -55 to Operating Ambient Temperature Range (T ) ºC • -55°C to +125°C types available A +125 operating temp. range • ESD rated to IEC Storage Temperature Range (T ) -55 to ºC • Operating voltage 61000-4-2, Level 4: Air STG +150 range V = Discharge 15KV and M(DC) 5.5V to 120V Contact Discharge 8KV Temperature Coefficient (αV) of Clamping <0.01 %/º C Voltage (V ) at Specified Test Current C Applications Additional Information • Suppression of • Provides on-board inductive switching transient voltage or other transient protection for ICS events such as EFT and transistors and surge voltage at • Used to help achieve Datasheet Resources Samples the circuit board level electromagnetic • ESD protection for IEC compliance of 61000-4-2 (Level 4), end products MIL-STD-883 method • Replace larger surface 3015.7, and other mount TVS Zeners in industry specifications many applications (see also the MLE or MLN Series) © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Device Ratings and Specifications Maximum Ratings (125º C) Specifications (25ºC) Maximum Maximum Non- Maximum Non- Maximum Clamping Nominal Voltage Typical Continuous repetitive Surge repetitive Surge Voltage at 1A (or as at 1mA DC Test Capacitance Part Number Working Voltage Current (8/20µs) Energy (10/1000µs) Noted) (8/20µs) Current at f = 1MHz V V I W V V Min V Max C M(DC) M(AC) TM TM C N(DC) N(DC) (V) (V) (A) (J) (V) (V) (V) (pF) V3.5MLA0603N5 3.5 2.5 30 0.100 13.0 3.7 7.0 1270 V3.5MLA0805N 3.5 2.5 120 0.300 13.0 3.7 7.0 1760 V3.5MLA0805LN 3.5 2.5 40 0.100 13.0 3.7 7.0 1380 V3.5MLA1206N 3.5 2.5 100 0.300 13.0 3.7 7.0 5800 V5.5MLA0402N 5.5 4.0 20 0.050 21.0 7.1 10.8 220 V5.5MLA0402F8 5.5 4.0 20 0.050 21.0 7.1 10.8 220 V5.5MLA0402LN 5.5 4.0 20 0.050 39.0 15.9 21.5 70 V5.5MLA0402LF8 5.5 4.0 20 0.05 39 15.9 21.5 70 V5.5MLA0603N5 5.5 4.0 30 0.100 17.5 7.1 9.3 960 V5.5MLA0603LN4 5.5 4.0 30 0.100 17.5 7.1 9.3 450 V5.5MLA0603LF8 5.5 4.0 30 0.100 17.5 7.1 9.3 450 V5.5MLA0805N 5.5 4.0 120 0.300 17.5 7.1 9.3 1200 V5.5MLA0805LN 5.5 4.0 40 0.100 17.5 7.1 9.3 660 V5.5MLA1206N 5.5 4.0 150 0.400 17.5 7.1 9.3 2800 V9MLA0402N 9.0 6.5 20 0.050 30.0 11.0 16.0 120 V9MLA0402F8 9.0 6.5 20 0.050 30.0 11.0 16.0 120 V9MLA0402LN 9.0 6.5 4 0.020 35.0 11.0 16.0 33 V9MLA0402LF8 9.0 6.5 4 0.020 35.0 11.0 16.0 33 V9MLA0603N5 9.0 6.5 30 0.100 25.5 11.0 16.0 490 V9MLA0603LN4 9.0 6.5 30 0.100 25.5 11.0 16.0 360 V9MLA0603LF8 9.0 6.5 30 0.100 25.5 11.0 16.0 360 V9MLA0805LN 9.0 6.5 40 0.100 25.5 11.0 16.0 320 V12MLA0805LN 12.0 9.0 40 0.100 29.0 14.0 18.5 220 V14MLA0402N 14.0 10.0 20 0.050 39.0 15.9 21.5 70 V14MLA0402F8 14.0 10.0 20 0.050 39.0 15.9 21.5 70 V14MLA0603N 14.0 10.0 30 0.100 34.5 15.9 21.5 80 V14MLA0603F8 14.0 10.0 30 0.100 34.5 15.9 21.5 180 V14MLA0805N 14.0 10.0 120 0.300 32.0 15.9 20.3 360 V14MLA0805LN 14.0 10.0 40 0.100 32.0 15.9 20.3 200 V14MLA1206N 14.0 10.0 150 0.400 32.0 15.9 20.3 800 V18MLA0402N 18.0 14.0 20 0.050 50.0 22.0 28.0 40 V18MLA0402F8 18.0 14.0 20 0.050 50.0 22.0 28.0 40 V18MLA0603N 18.0 14.0 30 0.100 50.0 22.0 28.0 60 V18MLA0603F8 18.0 14.0 30 0.100 50.0 22.0 28.0 120 V18MLA0805N 18.0 14.0 120 0.300 44.0 22.0 28.0 260 V18MLA0805LN 18.0 14.0 40 0.100 44.0 22.0 28.0 170 V18MLA1206N 18.0 14.0 150 0.400 44.0 22.0 28.0 1030 V18MLA1210N 18.0 14.0 500 2.500 44.0 at 2.5 22.0 28.0 2500 V18MLA1812N7 18.0 14.0 1000 2.900 44.0 at 5 22.0 28.0 4050 V26MLA0603N 26.0 20.0 30 0.100 60.0 31.0 38.0 55 V26MLA0603F8 26.0 20.0 30 0.100 60.0 31.0 38.0 110 V26MLA0805N 26.0 20.0 100 0.300 60.0 29.5 38.5 110 V26MLA0805LN 26.0 20.0 40 0.100 60.0 29.5 38.5 90 V26MLA1206N 26.0 20.0 150 0.600 60.0 29.5 38.5 630 V26MLA1210N 26.0 20.0 300 1.200 60.0 at 2.5 29.5 38.5 1250 V30MLA0603N 30.0 25.0 30 0.100 74.0 37.0 46.0 45 V30MLA0603F8 30.0 25.0 30 0.100 74.0 37.0 46.0 90 V30MLA0805LN 30.0 25.0 30 0.100 72.0 37.0 46.0 85 V30MLA1206N 30.0 25.0 180 1.000 67.0 35.0 43.0 400 V30MLA1210N 30.0 25.0 280 1.200 68.0 at 2.5 35.0 43.0 685 V30MLA1210LN 30.0 25.0 220 0.900 68.0 at 2.5 35.0 43.0 500 © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Device Ratings and Specifications (Continue...) Maximum Ratings (125º C) Specifications (25ºC) Maximum Maximum Non- Maximum Non- Maximum Clamping Nominal Voltage Typical Continuous repetitive Surge repetitive Surge Voltage at 1A (or as at 1mA DC Test Capacitance Part Number Working Voltage Current (8/20µs) Energy (10/1000µs) Noted) (8/20µs) Current at f = 1MHz V V I W V V Min V Max C M(DC) M(AC) TM TM C N(DC) N(DC) (V) (V) (A) (J) (V) (V) (V) (pF) V30MLA1812N7 30.0 25.0 800 3.700 65.0 at 5 35.0 43.0 1900 V33MLA1206N 33.0 26.0 180 0.800 75.0 38.0 49.0 390 V38MLA1812N7 38.0 30.0 800 4.500 77.0 at 5 43.0 52.0 1450 V42MLA1206N 42.0 30.0 180 0.800 92.0 46.0 60.0 345 V45MLA1812N7 45.0 35.0 500 4.000 90.0 at 5 50.4 61.6 1200 V48MLA1206N 48.0 40.0 180 0.900 100.0 54.5 66.5 185 V48MLA1210N 48.0 40.0 250 1.200 105.0 at 2.5 54.5 66.5 400 V48MLA1210LN 48.0 40.0 220 0.900 105.0 at 2.5 54.5 66.5 380 V56MLA1206N 56.0 40.0 180 1.000 120.0 61.0 77.0 180 V60MLA1210N 60.0 50.0 250 1.500 130.0 at 2.5 67.0 83.0 230 V68MLA1206N 68.0 50.0 180 1.000 140.0 76.0 90.0 130 V85MLA1210N 85.0 67.0 250 2.500 180.0 at 2.5 95.0 115.0 160 V120MLA1210N 120.0 107.0 125 2.000 260.0 at 2.5 135.0 165.0 70 NOTES: 1 'L' suffix is a low capacitance and energy version; Contact your Littelfuse sales representative for custom capacitance requirements. 2 Typical leakage at 25ºC<25µA, maximum leakage 100µA at V ; for 0402 size, typical leakage <5µA, maximum leakage <20µA at V . M(DC) M(DC) 3 Average power dissipation of transients for 0402, 0603, 0805, 1206 and 1210 sizes not to exceed 0.03W, 0.05W, 0.1W, 0.1W and 0.15W respectively. 4 Item is available as 'R' packing option only. All 0402 size items available as 'R' packaging option only. See Packaging section for additional information. 5 Item is available in 'H','T'and 'A' packing option only. All 0805, 1206 and 1210 parts come as 'H','T'and 'A' packing option only. See Packaging section for additional information. 6. The typical capacitance rating is the discrete component test result. 7. Item is available in "T" packing option only. 8. Item is available in "R" packing option only, and lead free. © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Peak Current and Energy Derating Curve Peak Pulse Current Test Waveform for Clamping Voltage When transients occur in rapid succession, the average power dissipation is the energy (watt-seconds) per pulse 100 E U times the number of pulses per second. The power so L A developed must be within the specifications shown K V A on the Device Ratings and Specifications Table for the E P specific device. For applications exceeding 125°C ambient OF 50 T temperature, the peak surge current and energy ratings N E must be derated as shown below. RC PE 0 T E O1 TIME LU T1 A Figure 2 D V 100 T2 E T RA 80 OF 01 = Virtual Origin of Wave T 60 T = Time from 10% to 90% of Peak EN FTIG =U RREis 2e. TPiEmAeK =P U1L.2S5E xC TURRENT TEST WAVEFORM C 40 1 FOR CLAMPING VOLTAGE R T = Decay Time PE 20 E2xample - For an 8/20 µs Current Waveform: O1 = VIRTUAL ORIGIN OF WAVE 0 t = TI8MµEs F =RO TM1 1=0 %R TisOe 9 T0i%m OeF PEAK -55 50 60 70 80 90 100 110 120 130 140 150 t1 = V2IR0TµUsA L= F TR2O N=T D TIeMcEa =y 1T.2im5 xe t Figure 1 AMBIENT TEMPERATURE (oC) t2 = VIRTUAL TIME TO HALF VALUE (IMPULSE DURATION) FIGURE 1. PEAK CURRENT AND ENERGY EXAMPLE: DERATING CURVE FOR AN 8/20 s CURRENT WAVEFORM Limit V-I Characteristic for V5.5MLA0402 to V18MLA0402 Limit V-I Characteristic for V9MLA0402L 8 s = t1 = VIRTUAL FRONT TIME 20 s = t2 = VIRTUALM TLIMAE04 T0O2L Limit VI Curves MLA0402 Limit VI Curves HALF VALUE 100 100 Varistor Voltage (V) 10 VVVV5119.485MMMMLLLLAAAA0000444400002222 Varistor Voltage (V) 10 VV59.5MMLLAA00440022LL 1 1 1µA 10µA 100µA 1mA 10mA 1A 10A 100A 1µA 10µA 100µA 1mA 10mA 1A 10A 100A Figure 3 Current (A) Figure 4 Current (A) © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Limit V-I Characteristic for V3.5MLA0603 to V30MLA0603 Limit V-I Characteristic for V3.5MLA0805L to V30MLA0805L 1000 1000 V30MLA0805L V30MLA0603 V26MLA0805L V26MLA0603 V18MLA0805L V18MLA0603 100 V14MLA0805L Varistor Voltage (V)11000 V14MLA0603 V9MLA0603, V9MLA0603L Varistor Voltage (V) 10 V12MLA0805L V5.5MLA0603, V5.5MLA0603L V9MLA0805L V3.5MLA0603 V5.5MLA0805L V3.5MLA0805L 1 1 10µA 100µA 1mA 10mA 100mA 1A 10A 100A 10µA 100µA 1mA 10mA 100mA 1A 10A 100A Current (A) Figure 5 Current (A) Figure 6 FIGURE 5. LIMIT V-I CHARACTERISTIC FOR V3.5MLA0603 TO V30MLA0603 FIGURE 6. LIMIT V-I CHARACTERISTIC FOR V3.5MLA0805L TO V30MLA0805L Limit V-I Characteristic for V3.5MLA0805 to V26MLA0805 Limit V-I Characteristic for V3.5MLA1206 to V68MLA1206 1000 1000 V) Varistor Voltage (10100 VV2186MMLLAA00880055 Varistor Voltage (V)11000 VVVVVV654321886236MMMMMMLLLLLLAAAAAA111111222222000000666666 V14MLA0805 V14MLA1206 V5.5MLA1206 V5.5MLA0805 V3.5MLA1206 V3.5MLA0805 1 10µA 100µA 1mA 10mA 100mA 1A 10A 100A 1000A Current (A) 110µA 100µA 1mA 10mA 100mA 1A 10A 100A 1000A Current (A) Figure 7 FIGURE 7. LIMIT V-I CHARACTERISTIC FOR V3.5MLA0805 TO V26MLA0805 Figure 8 FIGURE 6. LIMIT V-1 CHARACTERISTIC FOR V3.5MLA1206 TO V68MLA1206 Limit V-I Characteristic for V18MLA1210 to V120MLA1210 1000 MAXIMUM CLAMPING VOLTAGE MAXIMUM LEAKAGE 100 Varistor Voltage (V) V120MLA1210 10 V85MLA1210 V60MLA1210 V48MLA1210, V48MLA1210L V30MLA1210, V30MLA1210L V26MLA1210 1 V18MLA1210 10µA 100µA 1mA 10mA 100mA 1A 10A 100A 1000A Figure 9 CURRENT (A) FIGURE 9. LIMIT V-I CHARACTERISTIC FOR V18MLA1210 TO V120MLA1210 © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Device Characteristics Clamping Voltage Over Temperature (V at 10A) C At low current levels, the V-I curve of the multilayer transient voltage suppressor approaches a linear (ohmic) 100 relationship and shows a temperature dependent effect. Aist ino ra b heilgohw r ethseis tmanacxeim mumod ewxo (rakpinpgro vaoclhtaingge ,1 t0h6eΩ sautp itpsr essor GE (V) V26MLA1206 A maximum rated working voltage). Leakage currents at LT O maximum rated voltage are below 100µA, typically 25µA; G V N for 0402 size below 20µA, typically 5µA. PI M A L C V5.5MLA1206 Typical Temperature Dependance of the Haracteristic Curve in the Leakage Region 100% 10 OF -60 -40 -20 0 20 40 60 80 100 120 140 GE IN PERCENT oAT 25C (%) FigureF IG11URE 12. (CVLCA AMTP 1IN0AGT) EVMOPLETRAAGTEU ROEV (EoCR) TEMPERATURE ESSOR VOLTA VALUE VNOM EEnneerrggyy dAisbssiopraptetido nw/iPtheina kt hCeu MrreLnAt SCearpieasb iisl ictyalculated PR by multiplying the clamping voltage, transient current P SU 25o 50o 75o 100o 125oC and transient duration. An important advantage of the 10% 1E-9 1E-8 1E-7 1E-6 1E-5 1E-4 1E-3 1E-2 multilayer is its interdigitated electrode construction within Figure 10 SUPPRESSOR CURRENT (ADC) the mass of dielectric material. This results in excellent FIGURE 10. TYPICAL TEMPERATURE DEPENDANCE OF THE CHARACTERISTIC CURVE IN THE LEAKAGE REGION current distribution and the peak temperature per energy absorbed is very low. The matrix of semiconducting grains Speed of Response combine to absorb and distribute transient energy (heat) (see Speed of Response). This dramatically reduces peak The Multilayer Suppressor is a leadless device. Its temperature; thermal stresses and enhances device response time is not limited by the parasitic lead reliability. inductances found in other surface mount packages. The response time of the Z O dielectric material is less As a measure of the device capability in energy and peak N than 1ns and the MLA can clamp very fast dV/dT events current handling, the V26MLA1206A part was tested with such as ESD. Additionally, in "real world" applications, multiple pulses at its peak current rating (3A, 8/20µs). At the associated circuit wiring is often the greatest the end of the test,10,000 pulses later, the device voltage factor effecting speed of response. Therefore, transient characteristics are still well within specification. suppressor placement within a circuit can be considered important in certain instances. Repetitive Pulse Capability Multilayer Internal Construction 100 PEAK CURRENT = 3A 8/20s DURATION, 30s BETWEEN PULSES FIRED CERAMIC DIELECTRIC E V26MLA1206 G A LT O V METAL ELECTRODES METAL END TERMINATION 10 DEPLETION 0 2000 4000 6000 8000 10000 12000 REGION Figure 13 NUMBER OF PULSES DEPLETION FIGURE 13. REPETITIVE PULSE CAPABILITY REGION Figure 12 GRAINS FIGURE 11. MULTILAYER INTERNAL CONSTRUCTION © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Lead (Pb) Soldering Recommendations The principal techniques used for the soldering of Reflow Solder Profile components in surface mount technology are IR Re-flow and Wave soldering. Typical profiles are shown on the right. 250 250 MAXIMUM TEMPERATURE The recommended solder for the MLA suppressor is 220500 MAXIMUM 22T33E00M°°CCPERATURE a 62/36/2 (Sn/Pb/Ag), 60/40 (Sn/Pb) or 63/37 (Sn/Pb). C200 MAXIMUM TEMPERATSUER44CE00O--88N00DS Littelfuse also recommends an RMA solder flux. E °CRE ° 210500 230°C AABBSOEOCVVEOE N1188D33S°°CC WTtipshor eoa raevrcvmceeoo sasimsdlo sslmtdhhheoeeorcn uipnkdlod,ge s a dbis s,epi bat rrheinliigehdtyi e dmt aohlytofe ssc gpttoea ensngatteerrkeor iatnlnleteu imtndohg.upe ses s trooraeftl dustehsrereei ns op gfdr otuphcereeo t scsoseo esldss.e r TEMPERATURTEMPERATUTEMPERATURE °C1111100550550000000 PPRREEHHPPPRREERAAEEETTHHH EEEZZAAOAOTTTNN DDEEDWWWEEELLLR<R<R<LLL222AAA°°°MMMCCCP/P/P/sss RRRAAAABSTTTOEEEE4CV0EO-8 N108D3S°C 500 PREHEAT ZONE When using a reflow process, care should be taken to 00 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 ensure that the MLA chip is not subjected to a thermal Figure 14 TIME (MINUTES) 0 TIME (MINUTES) gradient steeper than 4 degrees per second; the ideal 0 F 0IG.5U R E 1 1.04 . R E 1F.5L O W S2.O0 L D E 2R.5 P R O F3.I0L E 3.5 4.0 gradient being 2 degrees per second. During the soldering Wave SoldeFrI GPUroREfi l1e4. REFTLIMOEW ( MSIONLUDTEESR) PROFILE process, preheating to within 100 degrees of the solder's FIGURE 14. REFLOW SOLDER PROFILE peak temperature is essential to minimize thermal shock. 300 300 Once the soldering process has been completed, it is MAXIMUM WAVE 260°C still necessary to ensure that any further thermal shocks 223550000 MAXIMUM WAVE 260°C aprrein atevdo icdiercdu. iOt bnoea prdoss sbibelien gc areumseo ovef dth ferormma tl hseh oscokld iesr h ot E °CRE °C 222005000 MAXIMUM WAVE 260°C RU pteromcpeesrsa taunrde .s Tuhbeje bcoteadrd tso m cluesatn bineg a slloolwveendt sto a tc oroool mgr adually RATUERATE °C 112550000 SECOND PREHEAT EPR SECOND PREHEAT to less than 50º C before cleaning. TEMPTEMMPERATU 11100550000 FFIIRRSSTT PPRREEHHEEAASTTECOND PREHEAT E 15000 T FIRST PREHEAT 0 5000.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 Figure 15 TIME (MINUTES) TIME (MINUTES) 0 0.0 0F.5IGUR1.0E 15.1.W5AVE2 .S0OLD2.E5R PR3.O0FIL3E.5 4.0 4.5 Lead–free (Pb-free) Soldering Recommendations FIGURE 15. WATIVMEE S(MOILNDUTEERS P)ROFILE FIGURE 15. WAVE SOLDER PROFILE Littelfuse offers the Nickel Barrier Termination option (see Lead–free Re-flow Solder Profile "N" suffix in Part Numbering System for ordering) for the 300 300 MAXIMUM TEMPERATURE 260˚C, optimum Lead–free solder performance, consisting of a MAXIMUM TEMPERATURE 260˚C, TIME WITHIN 5˚C OF PEAK Matte Tin outer surface plated on Nickel underlayer, plated 232505000 T2200IM SSEEE WCCOOITNNHDDINSS 5MM˚CAA XXOIIFMM UUPEMMAK on Silver base metal. E °CRE °C222005000 MT20IAM SXEEI MWCUOITMNH DTINSE M5M˚PCAE XOR<R<RI33AAFMA˚˚ MMCCTUPU//PPEMssR ARREKAA 2TT6EE0˚C, 6600 >-- 112551007 ˚SSCEECC Tflhuex, pbruetf etrhreerde siso lad ewr iidse 9 s6e.5le/3c.t0io/0n. 5o f( SpnasAtgeCs ua)n wd iflthu xaens R MA ERATURPERATURE °C211505000 R<3A˚MC/Ps RATE 60 >>- 122511077 ˚˚SCCEC available with which the Nickel Barrier parts should be PMU compatible. TEMTEERAT111005000 PPRREEHHEEAATT ZZOONNEE P M 50 The reflow profile must be constrained by the maximums TE15000 PREHEAT ZONE in the Lead–free Reflow Profile. For Lead–free wave 0 5000 1.0 2.0 3.0 4.0 5.0 6.0 7.0 soldering, the Wave Solder Profile still applies. 0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 TIME (MINUTES) 0 TIME (MINUTES) Note: the Lead–free paste, flux and profile were used for 0 F I G U R1.E0 1 6 . L 2E.A0 D - F R 3E.E0 R E - F4L.0O W S O5.L0D E R P6.R0O F I L E7.0 evaluation purposes by Littelfuse, based upon industry Figure 16 FIGURE 16. LEAD-FTRIMEEE ( MRIEN-UFTLEOSW) SOLDER PROFILE standards and practices. There are multiple choices of all FIGURE 16. LEAD-FREE RE-FLOW SOLDER PROFILE three available, it is advised that the customer explores the optimum combination for their process as processes vary considerably from site to site. © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Product Dimensions (mm) PAD LAYOUT DIMENSIONS CHIP LAYOUT DIMENSIONS C E B NOTE D L W A NOTE : Avoid metal runs in this area, parts not recommended for use in applications using Silver (Ag) epoxNy OpaTsEte:. Avoid metal runs in this area. Parts not recommended for use in 1 2 a1p0p Slicizaetions using silver e1p2o0xy6 pSaisztee. 0805 Size 0603 Size 0402 Size Dimension IN MM IN MM IN MM IN MM IN MM A 0.160 4.06 0.160 4.06 0.120 3.05 0.100 2.54 0.067 1.70 B 0.100 2.54 0.065 1.65 0.050 1.27 0.030 0.76 0.020 0.51 C 0.040 1.02 0.040 1.02 0.040 1.02 0.035 0.89 0.024 0.61 D (max.) 0.113 2.87 0.071 1.80 0.043 1.10 0.040 1.00 0.024 0.60 0.020 0.50 0.020 0.50 0.020 -/+ 0.50 -/+ 0.015 0.4 0.010 0.25 E -/+0.010 -/+0.25 -/+0.010 -/+0.25 0.010 0.25 -/+0.008 -/+0.20 -/+0.006 -/+0.15 0.125 3.20 0.125 3.20 0.079 2.01 0.063 1.6 0.039 1.00 L -/+0.012 -/+0.30 -/+0.012 -/+0.30 -/+0.008 -/+0.20 -/+0.006 -/+0.15 -/+0.004 -/+0.10 0.100 2.54 0.060 1.60 0.049 1.25 0.032 0.8 0.020 0.50 W -/+0.012 -/+0.30 -/+0.011 -/+0.28 -/+0.008 -/+0.20 -/+0.060 -/+0.15 -/+0.004 -/+0.10 Part Numbering System V 18 MLA1206 X X X PACKING OPTIONS (see Packaging table for quantities) DEVICE FAMILY T: 13in (330mm) Diameter Reel, Plastic Carrier Tape Littelfuse TVS Device H: 7in (178mm) Diameter Reel, Plastic Carrier Tape R: 7in (178mm) Diameter Reel, Paper Carrier Tape MAXIMUMD C A: Bulk Pack WORKING VOLTAGE END TERMINATION OPTION MULTILAYER SERIES N, F or No letter: DESIGNATOR Nickel Barrier Option DEVICE SIZE: (Matte Tin outer surface, plated on Nickel underlayer 0201 = .024 inch x .012 inch (0.6 mm x 0.3 mm) plated on silver base metal) 0402 = .04 inch x .02 inch (1.0 mm x 0.5 mm) 0603 = .063 inch x .031 inch (1.6 mm x 0.8 mm) CAPACITANCE OPTION 0805 = .08 inch x .08 inch (2.0 mm x 1.25 mm) No Letter:Standard 1206 = .126 inch x .063 inch (3.2 mm x 1.6 mm) L:Low Capacitance Version 1210 = .126 inch x .1 inch (3.2 mm x 2.5 mm) *NOTES: 1 V120MLA1210 standard shipping quantities are 1000 pieces per reel for the "H" option and 4000 pieces per reel for "T" option. 2 V3.5 MLA0603, V5.5MLA0603 and V9MLA0603 only available in "H," "T" and "A" packing options. Packaging* Quantity Device Size 13” Inch Reel 7” Inch Reel 7” Inch Reel Bulk Pack ("T" Option) ("H" Option) ("R" Option) ("A" Option) 1812 4,000 N/A N/A N/A 1210 8,000 2,000 N/A 2,000 1206 10,000 2,500 N/A 2,500 0805 10,000 2,500 N/A 2,500 0603 10,000 2,500 4,000 2,500 0402 N/A N/A 10,000 N/A *(Packaging) It is recommended that parts be kept in the sealed bag provided and that parts be used as soon as possible when removed from bags. © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17
Metal-Oxide Varistors (MOVs) Surface Mount Multilayer Varistors (MLVs) > MLA Series Tape and Reel Specifications PRODUCT D0 P0 IDENTIFYING For T and H Pack Options: PLASTIC CARRIER TAPE LABEL P2 For R Pack Options: EMBOSSED PAPER CARRIER TAPE E F W K0 B0 EMBOSSMENT t1 D1 P1 A0 TOP TAPE NO8MmINmAL O1R7 383m0mmm DIA. REEL Dimensions in Millimeters Symbol Description 0402 Size 0603, 0805, 1206 & 1210 Sizes A Width of Cavity Dependent on Chip Size to Minimize Rotation. 0 B Length of Cavity Dependent on Chip Size to Minimize Rotation. 0 K Depth of Cavity Dependent on Chip Size to Minimize Rotation. 0 W Width of Tape 8 -/+0.2 8 -/+0.3 F Distance Between Drive Hole Centers and Cavity Centers 3.5 -/+0.05 3.5 -/+0.05 E Distance Between Drive Hole Centers and Tape Edge 1.75 -/+0.1 1.75 -/+0.1 P Distance Between Cavity Centers 2-/+0.05 4 -/+0.1 1 P Axial Drive Distance Between Drive Hole Centers & Cavity Centers 2 -/+0.1 2 -/+0.1 2 P Axial Drive Distance Between Drive Hole Centers 4 -/+0.1 4 -/+0.1 0 D Drive Hole Diameter 1.55 -/+0.05 1.55 -/+0.05 0 D Diameter of Cavity Piercing N/A 1.05 -/+0.05 1 T Top Tape Thickness 0.1 Max 0.1 Max 1 NOTES: • Conforms to EIA-481-1, Revision A • Can be supplied to IEC publication 286-3 Disclaimer Notice - Information furnished is believed to be accurate and reliable. However, users should independently evaluate the suitability of and test each product selected for their own applications. Littelfuse products are not designed for, and may not be used in, all applications. Read complete Disclaimer Notice at www.littelfuse.com/disclaimer-electronics. © 2017 Littelfuse, Inc. Specifications are subject to change without notice. Revised: 09/14/17