F72/F75 Series Low Profile and HiCV Conformal Coated Chip FEATURES • Compliant to the RoHS2 directive 2011/65/EU • SMD Conformal • Small and low profile LEAD-FREE COMPATIBLE COMPONENT APPLICATIONS • Smartphone • Mobile phone • Wireless module • Hearing aid F72 CASE DIMENSIONS: millimeters (inches) Code EIA Code EIA Metric F75 H B D B D A B D* 2824 7260-20 7.20±0.30 (0.283±0.012) 6.00±0.30 (0.236±0.012) 2.00 Max. (0.079 Max) 1.30±0.40 (0.051±0.016) 3.80±0.60 6.20 (0.150±0.024) (0.244) R 2824 7260-15 7.20±0.30 (0.283±0.012) 6.00±0.30 (0.236±0.012) 1.20±0.30 (0.047±0.012) 1.30±0.40 (0.051±0.016) 3.80±0.60 6.20 (0.150±0.024) (0.244) C 2813 7132-28 7.10±0.30 (0.280±0.012) 3.20±0.30 (0.126±0.012) 2.50±0.30 (0.098±0.012) 1.30±0.30 (0.051±0.012) 3.60±0.60 6.00 (0.142±0.024) (0.236) D 2914 7343-31 7.30±0.30 (0.287±0.012) 4.30±0.30 (0.136±0.012) 2.80±0.30 (0.110±0.012) 1.30±0.40 (0.051±0.016) 3.90±0.60 6.40 (0.153±0.024) (0.252) R 2824 7260-38 7.20±0.30 (0.283±0.012) 6.00±0.30 (0.236±0.012) 3.50±0.30 (0.138±0.012) 1.30±0.40 (0.051±0.016) 3.80±0.60 6.20 (0.150±0.024) (0.244) U 2813 7132-20 7.10±0.30 (0.280±0.012) 3.20±0.30 (0.126±0.012) 2.00 Max. (0.079 Max) 1.30±0.30 (0.051±0.012) 3.60±0.60 6.00 (0.142±0.024) (0.236) L F75 Case Dimensions W W Solder electrode H M A L W F72 Case Dimensions H A L *D dimension only for reference HOW TO ORDER F72 1A 107 M R ⵧ AQ2 Type Rated Voltage Capacitance Code pF code: 1st two digits represent significant figures, 3rd digit represents multiplier (number of zeros to follow) Tolerance K = ±10% M = ±20% Case Size See table above Packaging See Tape & Reel Packaging Section Single Facing Electrode F75 1C 157 M D ⵧ AQ2 Type Rated Voltage Capacitance Code pF code: 1st two digits represent significant figures, 3rd digit represents multiplier (number of zeros to follow) Tolerance K = ±10% M = ±20% Case Size See table above Packaging See Tape & Reel Packaging Section Single Facing Electrode TECHNICAL SPECIFICATIONS Category Temperature Range: Rated Temperature: Capacitance Tolerance: Dissipation Factor: ESR 100kHz: Leakage Current: Capacitance Change By Temperature 72 -55 to +125°C +85°C ±20%, ±10% at 120Hz Refer to next page Refer to next page After 1 minute’s application of rated voltage, leakage current at 20°C is not more than 0.01CV or 0.5μA, whichever is greater. After 1 minute’s application of rated voltage, leakage current at 85°C is not more than 0.1CV or 5μA, whichever is greater. After 1 minute’s application of derated voltage, leakage current at 125°C is not more than 0.125CV or 6.3μA, whichever is greater. +15% Max. at +125°C +10% Max. at +85°C -10% Max. at -55°C 051216 F72/F75 Series Low Profile and HiCV Conformal Coated Chip CAPACITANCE AND RATED VOLTAGE RANGE (LETTER DENOTES CASE SIZE) F72 F75 Capacitance µF Code 33 336 47 476 68 686 100 107 150 157 220 227 330 337 470 477 680 687 1000 108 1500 158 4V (0G) Rated Voltage 6.3V (0J) 10V (1A) R R R R R R* M M M R R R R R R R R R M M Capacitance µF Code 68 686 100 107 150 157 220 227 330 337 470 477 680 687 1000 108 1500 158 2200 228 16V (1C) R R R M M Available Ratings *Codes under development – subject to change 4V (0G) C C/D D D/R R R Rated Voltage 6.3V (0J) 10V (1A) C C/D D R/U C C/D D/U D/R/U* R/U* 16V (1C) C C D R Please contact to your local AVX sales office when these series are being designed in your application. RATINGS & PART NUMBER REFERENCE F72 F75 AVX Part No. Rated Case Capacitance Voltage Size (μF) (V) F720G107MRC F720G157MRC F720G227MRC F720G337MRC R R R R 100 150 220 330 F720J686MRC F720J107MRC F720J157MRC F720J227MRC F720J337MRC F720J108MMCAQ2 F720J158MMCAQ2 R R R R R M M 68 100 150 220 330 1000 1500 F721A476MRC F721A686MRC F721A107MRC F721A157MRC F721A227MRC F721A477MMCAQ2 F721A687MMCAQ2 F721A108MMCAQ2 R R R R R M M M 47 68 100 150 220 470 680 1000 F721C336MRC F721C476MRC F721C686MRC F721C227MMCAQ2 F721C337MMCAQ2 R R R M M 33 47 68 220 330 DCL (μA) 4 Volt 4 4.0 4 6.0 4 8.8 4 13.2 6.3 Volt 6.3 4.3 6.3 6.3 6.3 9.5 6.3 13.9 6.3 20.8 6.3 63.0 6.3 95.0 10 Volt 10 4.7 10 6.8 10 10.0 10 15.0 10 22.0 10 47.0 10 68.0 10 200 16 Volt 16 5.3 16 7.5 16 10.9 16 35.2 16 52.8 100kHz RMS *1 DF ESR @ 120Hz @ 100kHz Current ΔC/C (mA) (%) (Ω) (%) 20ºC 8 10 12 12 0.70 0.70 0.70 0.70 463 463 463 463 * * * * 6 8 10 12 12 30 45 0.75 0.70 0.70 0.70 0.70 0.14 0.14 447 463 463 463 463 1118 1118 * * * * * ±15 ±20 6 6 8 10 12 30 35 45 0.80 0.75 0.70 0.70 0.70 0.14 0.14 0.14 433 447 463 463 463 1118 1118 1118 * * * * * ±15 ±20 ±20 6 6 6 12 45 0.90 0.80 0.75 0.20 0.20 408 433 447 935 935 * * * ±20 ±20 * In case of capacitance tolerance ± 10% type, “K” will be put at 9th digit of type numbering system *1: ΔC/C Marked “*” Item Damp Heat Temperature cycles Resistance soldering heat Surge Endurance 051216 AVX Part No. Rated Case Capacitance Voltage Size (μF) (V) F750G337MCC F750G477MCC F750G477MDC F750G687MDC F750G108MDC F750G108MRC F750G158MRC F750G228MRC C C D D D R R R 330 470 470 680 1000 1000 1500 2200 F750J227MCC F750J337MCC F750J337MDC F750J477MDC F750J477MUC F750J687MDC F750J687MRC F750J108MRC C C D D U D R R 220 330 330 470 470 680 680 1000 F751A157MCC F751A227MCC F751A227MDC F751A337MDC F751A477MRC F751A477MUCAQ2 C C D D R U 150 220 220 330 470 470 F751C686MCC F751C107MCC F751C157MDC F751C227MRC C C D R 68 100 150 220 DCL (μA) 4 Volt 4 13.2 4 18.8 4 18.8 4 27.2 4 40.0 4 40.0 4 60.0 4 88.0 6.3 Volt 6.3 13.9 6.3 20.8 6.3 20.8 6.3 29.6 6.3 29.6 6.3 42.8 6.3 42.8 6.3 63.0 10 Volt 10 15.0 10 22.0 10 22.0 10 33.0 10 47.0 10 94.0 16 Volt 16 10.9 16 16.0 16 24.0 16 35.2 100kHz RMS *1 DF ESR @ 120Hz @ 100kHz Current ΔC/C (mA) (%) (Ω) (%) 20ºC 10 14 14 18 24 24 30 45 0.15 0.12 0.12 0.12 0.12 0.12 0.12 0.07 856 957 1118 1118 1118 1443 1443 1890 * * * * * * * * 10 10 10 14 15 18 18 24 0.20 0.15 0.15 0.12 0.10 0.12 0.12 0.12 742 856 1000 1118 1049 1118 1443 1443 * * * * * * * * 10 10 10 10 14 30 0.22 0.20 0.20 0.15 0.12 0.15 707 742 866 1000 1443 856 * * * * * ±20 10 10 10 10 0.22 0.22 0.22 0.20 707 707 826 1118 * * * * * In case of capacitance tolerance ± 10% type, “K” will be put at 9th digit of type numbering system F72 All Case (%) ±10 ±5 ±5 ±5 ±10 *1: ΔC/C Marked “*” Item Damp Heat Temperature cycles Resistance soldering heat Surge Endurance F75 All Case (%) ±10 ±5 ±5 ±5 ±10 73 F72/F75 Series Low Profile and HiCV Conformal Coated Chip QUALIFICATION TABLE TEST Damp Heat (Steady State) Temperature Cycles Resistance to Soldering Heat Surge Endurance Shear Test Terminal Strength 74 F72/75 series (Temperature range -55ºC to +125ºC) Condition At 40°C, 90 to 95% R.H., 500 hours (No voltage applied) Capacitance Change ........... Refer to page 73 (*1) Dissipation Factor ................ Initial specified value or less Leakage Current .................. Initial specified value or less At -55°C / +125°C, 30 minutes each, 5 cycles Capacitance Change ........... Refer to page 73 (*1) Dissipation Factor ................ Initial specified value or less Leakage Current .................. Initial specified value or less 10 seconds reflow at 260°C, 10 seconds immersion at 260°C. Capacitance Change ........... Refer to page 73 (*1) Dissipation Factor ................ Initial specified value or less Leakage Current .................. Initial specified value or less After application of surge voltage in series with a 33Ω resistor at the rate of 30 seconds ON, 30 seconds OFF, for 1000 successive test cycles at 85ºC, capacitors shall meet the characteristic requirements in the table above. Capacitance Change ........... Refer to page 73 (*1) Dissipation Factor ................ Initial specified value or less Leakage Current .................. Initial specified value or less After 2000 hours’ application of rated voltage at 85°C, capacitors shall meet the characteristic requirements in the table above. Capacitance Change ........... Refer to page 73 (*1) Dissipation Factor ................ Initial specified value or less Leakage Current .................. Initial specified value or less After applying the pressure load of 5N for 10±1 seconds horizontally to the center of capacitor side body which has no electrode and has been soldered beforehand on a substrate, there shall be found neither exfoliation nor its sign at the terminal electrode. Keeping a capacitor surface-mounted on a substrate upside down and supporting the substrate at both of the opposite bottom points 45mm apart from the center of capacitor, the pressure strength is applied with a specified jig at the center of substrate so that the substrate may bend by 1mm as illustrated. Then, there shall be found no remarkable abnormality on the capacitor terminals. 051216