AVR-M0603C120MTAAB

V o l t a g e P r o t e c t i o n D e v i c e s February 2022 RoHS REACH SVHC-Free Chip varistors ESD/Voltage protection devices AVR/SGNE series AVRM/AVR-M AVRL AVRH SGNE : Standard Type : Low Capacitance Type : High reliability Type : Low Clamp Type Cl Br Pb Halogen Free Lead Free (2/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors Overview of the AVR/SGNE series CHARACTERISTICS OF CHIP VARISTOR Varistors are voltage dependent nonlinear resistive elements with a resistance that decreases rapidly when the voltage is over the constant value. Varistors become zener diode of 2 serial connection and equivalent, and does not have polarity. CURRENT vs. VOLTAGE CHARACTERISTICS EQUIVALENT CIRCUIT OF CHIP VARISTORS 2 Zener Diodes A capacitance content CHIP VARISTORS FEATURE IEC61000-4-2 LEVEL4 compliant. Reliability characteristics evaluated based on AEC-Q200 condition. (Automotive products) High ESD withstanding voltage Small-sized products are available 125°C, 150°C Supported Current(A) 10–1 10–2 Zener diode /Vz:6.8V Positive direction 10–3 Chip varistor /V1mA:12V 10–4 10–5 –18 –14 –10 –6 –2 2 –10–5 6 10 14 18 –10–4 –10–3 Negative direction Fig.1 Internal structure of multilayer chip varistors –10–2 –10–1 ① Voltage(V) THE EFFECT OF THE VARISTOR Without varistor A malfunction and failure of electronic equipment ESD, Surge voltage Power line Signal line IC ② ⑤ ④ ③ With Varistor Suppress abnormal voltage by inserting varistor in a circuit ESD, Surge voltage Power line Signal line IC No. (1) (2) (3) (4) (5) Name Semiconductor ceramics Internal electrode(Pd) Ag Terminal electrode Ni Sn Insert a varistor between a line and ground : Chip varistor 20220209 / vpd_varistors_avr_en.fm (3/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors Overview of the AVR/SGNE series PART NUMBER CONSTRUCTION AVRM 1608 C LxW dimensions (mm) 0402 0.4x0.2 0603 0.6x0.3 1005 1.0x0.5 1608 1.6x0.8 2012 2.0×1.2 Series name AVR-M 390 C General structure 10 1A Series name LxW dimensions (mm) Maximum continuous voltage (V) 04 06 10 16 1A 1D 1E AVRH 10 Series name LxW dimensions (V) 1.0x0.5 SGNE 04 Series name LxW dimensions W L T B R50 1R1 3R3 6R8 Varistor voltage Structure code C General structure 270=27×100 270 390 101 04 06 10 (pF) 270 (mm) 1005 Capacitance C General structure Shape symbol (JIS) 0402 0603 1005 1608 2012 Capacitance tolerance (%) K M N T AAB Packaging style Company special symbol T B Taping Bulk F T A Capacitance tolerance (pF) Packaging style Company special symbol F G N ±1 ±2 ±0.3 ±10 ±20 ±30 T B Taping Bulk 150 N A 8 Varistor voltage tolerance (%) Packaging style Capacitance Capacitance tolerance ESD voltage amount IEC61000-4-2 (kV) Operating temperature limit (°C) K Varistor voltage (V) 080=8×100 080 8 270 27 L 0.40±0.02 0.60±0.03 1.00±0.05 1.60±0.10 2.00±0.20 Capacitance T (pF) ±10 080 Structure code N K 27 39 100 C (mm) 0.4x0.2 0.6x0.3 1.0×0.5 0.5 1.1 3.3 6.8 271 (pF) 271=27×101 221 220 271 270 Taping Bulk Varistor voltage tolerance (%) K ±10 M ±20 N ±30 3R3 10 20 25 C T B M Varistor voltage (V) 270=27×100 080 8 120 12 270 27 General structure Conductive paste compatible AVRL 0.4x0.2 0.6x0.3 1.0×0.5 1.6×0.8 Packaging style 270 Structure code C G T Varistor voltage tolerance (%) K ±10 M ±20 N ±30 C LxW dimensions (mm) 0603 0.6x0.3 1005 1.0x0.5 1608 1.6x0.8 2012 2.0×1.2 Series name Varistor voltage (V) 390=39×100 6R8 6.8 270 27 390 39 Structure code 1608 K T Taping B Bulk M Varistor voltage tolerance (%) K ±10 W 0.20±0.02 0.30±0.03 0.50±0.05 0.80±0.10 1.25±0.20 150=15×100 K ±10% A 25 4R7 150 500 M N Y ±20% ±30% ±0.13pF E 8 4.7 15 50 8 150 T 150 N 25 Packaging style Capacitance Capacitance tolerance ESD clamping voltage Average voltage (IEC61000-4-2, 8kV) T B T 0.20±0.02 0.30±0.03 0.50±0.05 0.80±0.10 0.70±0.20 Taping Bulk (pF) 150=15×100 6R8 4.7 150 15 N Y ±30% ±0.13pF B 0.07min. 0.1min. 0.1min. 0.2min. 0.2min. Please be sure to request delivery specifications that provide further details on the features and specifications of the products for proper and safe use. Please note that the contents may change without any prior notice due to reasons such as upgrading. 20220209 / vpd_varistors_avr_en.fm (4/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors Overview of the AVR/SGNE series TERMINOLOGY Item Varistor voltage (Breakdown voltage) Unit V1mA (V) Maximum continuous voltage Vdc (V) Clamping voltage Maximum energy Maximum peak current Capacitance 1 Vcl (V) E (Joule) Ip (A) C (pF) Chip varistor-terminal voltage when DC1mA was flowed DC voltage that is continuously applied between chip varistor terminals Terminal chip varistors leakage current-value: 50µA max. Voltage appearing across the varistor when a pulse current (8/20µs?1) of specified peak value is applied. Voltage between terminal chip varistors of the Specified peak current value of the impulse current (8/ 20µs1) is applied When applied specified peak impulse current-value current (10/1000µs2) once, maximum energy that electrical property of chip varistors be not deteriorated When applied impulse current (8/20µs1) once, maximum current that electrical property of chip varistors be not deteriorated Oscillator frequency 1kHz or 1MHz, capacitance between chip varistor-terminal in oscillator voltage 1Vrms 2 8/20µs test waveform 100% 90% 10/1000µs test waveform 100% 90% Current Current Description 50% 8µs 50% 10µs 20µs 1000µs Time Time Please be sure to request delivery specifications that provide further details on the features and specifications of the products for proper and safe use. Please note that the contents may change without any prior notice due to reasons such as upgrading. 20220209 / vpd_varistors_avr_en.fm (5/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors AVR/SGNE series Product characteristics list PRODUCT CHARACTERISTICS LIST Item V (1mA) C1kHz *C1MHz Vdc AVRL041E1R1NTA AVRM0402C120MT330N AVRM0402C6R8NT101N SGNE04C080MT150N25 AVRL061E1R1NTA AVRL061FR50ETA AVRM0603C080MT101N AVRM0603C120MT101N AVRM0603C120MT150N AVR-M0603C120MTAAB AVRM0603C200MT150N AVRM0603C6R8NT101N AVRM0603C6R8NT331N SGNE06C080MT150N25 SGNE06C270MT6R8G60 AVRL101A1R1NTA AVRL101E1R1NTB AVRL101D3R3FTA AVRL101D6R8GTA AVR-M1005C080MTAAB AVR-M1005C080MTABB AVR-M1005C080MTACB AVR-M1005C080MTADB AVR-M1005C120MTAAB AVR-M1005C120MTACC AVR-M1005C180MTAAB AVRM1005C270KT101N AVR-M1005C270MTAAB AVR-M1005C270MTABB AVRM1005C6R8NT101N AVRM1005C6R8NT331N SGNE10C080MT150N28 AVRH10C270KT150NA8 AVRH10C270KT350NA8 AVRH10C390KT500NA8 AVRH10C101KT4R7FA8 AVRH10C101KT1R1NE8 AVRH10C221KT1R5YA8 AVRL161A1R1NTA AVRL161A1R1NTB AVRL161D3R3FTA AVRL161D6R8GTA AVR-M1608C080MTAAB AVR-M1608C120MT2AB AVR-M1608C120MT6AB AVR-M1608C180MT6AB AVR-M1608C220KT2AB AVR-M1608C220KT6AB AVR-M1608C270MTABB AVR-M1608C270MTAAB AVR-M1608C270KTACB AVRM1608C270KT800M AVR-M1608C270KT2AB AVRM1608C270KT221M AVR-M1608C270KT6AB AVR-M1608G270KT6AB AVRM1608C390KT271N AVRM1608C560KT101M AVRM1608C720KT750M AVR-M2012C120MT6AB AVR-M2012C220KT6AB AVRM2012C330KT801N AVR-M2012C390KT6AB AVRM2012C560KT251M AVRM2012C720KT201M (V) 39(31.2 to 46.8) 12(9.6 to 14.4) 6.8(4.76 to 8.84) 8(6.4 to 9.6) 39(35.0 to 43.0) 140(112 to 168) 8(6.4 to 9.6) 12(9.6 to 14.4) 12.8(10.0 to 15.6) 12(9.6 to 14.4) 20(16 to 24) 6.8(4.76 to 8.84) 6.8(4.76 to 8.84) 8(6.4 to 9.6) 27(21.6 to 32.4) 90(79.6 to 110.4) 39(31.2 to 46.8) 27(21.6 to 32.4) 27(21.6 to 32.4) 8(6.4 to 9.6) 8(6.4 to 9.6) 8(6.4 to 9.6) 8(6.4 to 9.6) 12(9.6 to 14.4) 12(9.6 to 14.4) 18(14.4 to 21.6) 27(24.0 to 30.0) 27(21.6 to 32.4) 27(21.6 to 32.4) 6.8(4.76 to 8.84) 6.8(4.76 to 8.84) 8(6.4 to 9.6) 27(24.0 to 30.0) 27(24.0 to 30.0) 39(35.0 to 43.0) 100(90 to 110) 110(100 to 120) 220 (198 to 242) 90(79.6 to 110.4) 39(31.2 to 46.8) 27(21.6 to 32.4) 27(21.6 to 32.4) 8(6.4 to 9.6) 12(9.6 to 14.4) 12(9.6 to 14.4) 18(14.4 to 21.6) 22(19.8 to 24.2) 22(19.8 to 24.2) 27(21.6 to 32.4) 27(21.6 to 32.4) 27(24.0 to 30.0) 27(24.0 to 30.0) 27(24.0 to 30.0) 27(24.0 to 30.0) 27(24.0 to 30.0) 27(24.0 to 30.0) 39(35.0 to 43.0) 56(50.4 to 61.6) 72(64.8 to 79.2) 12(9.6 to 14.4) 22(19.8 to 24.2) 33(29.7 to 36.3) 39(35.0 to 43.0) 56(50.4 to 61.6) 72(64.8 to 79.2) (pF) 1.1(0.8 to 1.4)* 33(23.1 to 42.9) 100(70 to 130) 15(10.5 to 19.5) 1.1(0.8 to 1.4)* 0.5(0.3 to 0.7)* 100(70 to 130) 100(70 to 130) 15(10.5 to 19.5) 33(23.1 to 42.9) 15(10.5 to 19.5)* 100(70 to 130) 330(231 to 429) 15(10.5 to 19.5) 6.8(4.8 to 8.8)* 1.1(0.8 to 1.4)* 1.1(0.8 to 1.4)* 3.3(2.3 to 4.3)* 6.8(4.8 to 8.8)* 650(520 to 780) 100(55 to 145) 33(14 to 52) 480(384 to 576) 130(104 to 156) 460(276 to 644)* 120(72 to 168)* 100(70 to 130) 40(30 to 48) 15(10.5 to 19.5) 100(70 to 130) 330(231 to 429) 15(10.5 to 19.5) 15(10.5 to 19.5) 35(24.5 to 45.5) 50(35 to 65) 4.7(3.7 to 5.7)* 1.1(0.8 to 1.4)* 1.5(1.37 to 1.63)* 1.1(0.8 to 1.4)* 1.1(0.8 to 1.4)* 3.3(2.3 to 4.3)* 6.8(4.8 to 8.8)* 650(520 to 780) 400(320 to 480) 1050(840 to 1260) 600(480 to 720) 210(147 to 273) 560(392 to 728) 15(10.5 to 19.5) 30(21 to 39) 60(42 to 78) 80(64 to 96) 160(112 to 208) 220(176 to 264) 430(301 to 559) 430(301 to 559) 270(189 to 351) 100(80 to 120) 75(60 to 90) 1000(550 to 1450) 800(560 to 1040) 800(560 to 1040) 430(387 to 483) 250(200 to 300) 200(160 to 240) DC (V) 25 5.5 3.5 5.5 25 30 5.5 5.5 5.5 7.5 12 3.5 3.5 5.5 15 10 25 20 20 5.5 5.5 5.5 5.5 7.5 7.5 11 19 15 15 3.5 3.5 5.5 19 19 28 70 70 70 10 10 20 20 5.5 7.5 7.5 11 16 16 17 17 19 19 19 19 19 19 28 40 53 7.5 16 24 28 40 53 Clamping voltage 8/20µs Vcl (V) — 20(1A) 15(1A) 21(1A) — — 17(1A) 20(1A) 35(1A) 23(1A) 40(1A) 14(1A) 14(1A) 21(1A) 54(1A) — — 62(0.5A) 58(1A) 14(1A) 15(1A) 19(1A) 14(1A) 20(1A) 21(1A) 30(1A) 44(1A) 47(1A) 49(1A) 14(1A) 15(1A) 21V(1A) 52(2A) 52(2A) 72(2A) 190(1A) 190 (0.3A) 400 (0.5A) — — 62(0.5A) 58(1A) 15(2A) 20(2A) 20(2A) 30(2A) 37(2A) 34(2A) 52(2A) 52(2A) 54(2A) 53(2A) 42(2A) 52(2A) 42(2A) 42(2A) 69(2A) 113(2A) 135(2A) 20(5A) 38(5A) 59(5A) 62(5A) 113(5A) 142(5A) Maximum energy 10/1000µs E (J) — 0.005 0.01 0.005 — — 0.01 0.01 0.003 0.01 0.01 0.01 0.02 0.005 0.005 — — 0.01 0.01 0.04 0.02 0.01 0.04 0.05 0.01 0.06 0.06 0.04 0.05 0.02 0.008 0.01 0.02 0.02 0.02 0.03 0.01 0.01 — — 0.01 0.01 0.09 0.06 0.09 0.10 0.03 0.10 0.05 0.05 0.05 0.02 0.10 0.10 0.10 0.10 0.10 0.10 0.10 0.20 0.30 0.50 0.30 0.30 0.30 Maximum peak current 8/20µs Ip (A) — 1 4 1 — — 4 5 1 1 1 10 16 1 1 — — 0.5 1 25 3 1 25 10 24 16 4 47 1 10 24 19 2 8 15 1 0.3 0.5 — — 0.5 1 30 15 50 30 10 30 2 2 10 28 20 40 48 48 78 60 40 60 100 240 100 150 100 Operating temperature range (°C) –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +125 –40 to +125 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –40 to +85 –40 to +85 –40 to +125 –40 to +125 –40 to +85 –40 to +85 –40 to +85 –40 to +85 –40 to +125 –40 to +125 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –55 to +150 –40 to +85 –40 to +125 –55 to +150 –55 to +150 –55 to +150 –55 to +150 IEC61000-4-2 (Contact) 150pF/330 4kV (Level2) 8kV (Level4) 8kV (Level4) 8kV (Level4) 4kV (Level2) 4kV (Level2) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 4kV (Level2) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 25kV 25kV 25kV 25kV 8kV (Level4) 25kV 8kV (Level4) 4kV (Level2) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 8kV (Level4) 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 25kV 8kV (Level4) 25kV 25kV 25kV 25kV 25kV AEC-Q200 ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ ✔ Please be sure to request delivery specifications that provide further details on the features and specifications of the products for proper and safe use. Please note that the contents may change without any prior notice due to reasons such as upgrading. 20220209 / vpd_varistors_avr_en.fm (6/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors AVR/SGNE series  Electrostatic absorption characteristics DISCHARGE VOLTAGE WAVEFORM (EXAMPLE) 1800 1600 1400 1200 1000 800 600 400 200 0 –200 –50 WAVEFORM AT VARISTOR INSTALLATION Without Varistor Voltage(V) Voltage(V) WITHOUT VARISTOR, WAVEFORM AT VARISTOR INSTALLATION AVRH10C270KT150NA8 AVR-M1608C270KT6AB AVR-M1608C220KT6AB 0 50 100 150 Time(ns) 200 250 300 180 160 140 120 100 80 60 40 20 0 –20 –50 AVRH10C270KT150NA8 AVR-M1608C270KT6AB AVR-M1608C220KT6AB 0 50 100 150 Time(ns) 200 250 300 Test conditions 150pF/330 (IEC61000-4-2) Contact discharge, Charged voltage 8kV TEST CIRCUIT DIAGRAM Discharge gun Test sample 60dB attenuator ESD simulator 50Ω Oscilloscope I/O impedance: 50Ω Shield Discharge Point SMA Connector PCB ESD Simulator Chip Varistor Coaxial Cable Attenuator(60dB) 50Ω Oscilloscope 50Ω Please be sure to request delivery specifications that provide further details on the features and specifications of the products for proper and safe use. Please note that the contents may change without any prior notice due to reasons such as upgrading. 20220209 / vpd_varistors_avr_en.fm (7/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors Attention on a circuit board design Board design When attached to chip varistors, amount of silver used (fillet size) has direct impact on chip varistors after mounting. Thus, sufficient consideration is necessary. Set of land dimensions (1) As the stress rises in the chip varistors owing to the increase in silver, breakage and cracks will occur. Cause including crack, as caution on board land design, configure the shape and dimensions so that the amount of silver is appropriate. If you installed 2 or more parts in the Common Land, separated by a solder resist and special land of each component. C B (2) When peak levels panning-at soldering is excessive, by solder contraction stress, mechanical-thermal stress causes a Yasuku chip crack. In addition, when the peak level is underestimated, terminal electrode fixed strength is insufficient. This causes chip dropouts and may affect circuit reliability. Representative example of the panning of peak levels is shown in the following. Recommended silver dose Solder stress is increased, and it is easy for a crack to form. Solder volume overload Most large serving amount Minimum prime amount Decent solder volume Fixed strength is weak, and there is connection a problem and risk of loss. Solder volume deficit A Case and suggested protocol want to avoid Dimensions shape 0402 0603 1005 1608 2012 Symbol A 0.20 Nom. 0.25 to 0.35 0.30 to 0.50 0.60 to 0.80 0.90 to 1.20 B 0.15 to 0.21 0.20 to 0.30 0.35 to 0.45 0.60 to 0.80 0.70 to 0.90 C 0.18 to 0.20 0.25 to 0.35 0.40 to 0.60 0.60 to 0.80 0.90 to 1.20 Example Improvement example (land division) Cases to avoid Leads Chip Leads Solder Solder resist Lead wire and land of part discrete doubles up PCB Chassis Solder (ground solder) Solder resist Arrangements in the vicinity L1 L2 L2>L1 Land Arrangements of chip component's companion Excess solder Solder resist Land Missing solder Please be sure to request delivery specifications that provide further details on the features and specifications of the products for proper and safe use. Please note that the contents may change without any prior notice due to reasons such as upgrading. 20220209 / vpd_varistors_avr_en.fm (8/12) Voltage Protection Devices RoHS Directive Compliant Product Compatible with lead-free solders Chip varistors Attention on a circuit board design Arrangements of components (1) I was based on camber of substrate and suggested protocol of chip varistors arrangement, as stress does not join to the utmost is shown in following. (2) In payment near by board, depending on mount position of chip varistors, as mechanical stress varies, please refer to the following diagram. Substrate for flexural stress Substrate for flexural stress Adverse events Good example E D Perforation Perforation or slit C Perforation or slit B A Direction of surface solder Slit Solder the mountain fold as a Solder the mountain fold as a top. bottom. [Please review the italicized portion, as I am unsure what you mean to convey here.] Perforation or slit The order of A > B = C > D > E eases the stress. Perforation or slit Chip arrangements (direction) Mounted vertically to the per- Mounted horizontally to the foration and slit. perforation and slit. L1 Distance from perforation and slit portion L2 (L1