Type AFC, -55 C to 105 C SMT Aluminum Electrolytic Capacitors - Low Impedance, 105 C

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1 hip and SMT apacitors Type AF, -55 to 5 SMT Aluminum Electrolytic apacitors - Low Impedance, 5 Low Impedance and Long-Life for Filtering, Bypassing, Power Supply Decoupling Specifications Operating Temperature: Rated Voltage: apacitance: apacitance Tolerance: Leakage urrent: Ripple urrent Multiplier: Type AF apacitors are the choice for high-frequency filtering. At kz, most ratings can handle more than twice the ripple current of type AA. With solid performance at temperatures down to -55, Type AF has more than 9% capacitance retention at -2 and kz. With low impedance to beyond kz, it is ideal for higher power D/D converters. The vertical cylindrical cases make for easy automatic mounting and reflow soldering, and offer big savings and higher capacitance compared to tantalum capacitors. ighlights +5, Up to our Load Life apacitance Range: µ F to 5 µ F Voltage Range: 6.3 Vdc to 5 Vdc -55 to ,, 6, 25 & 5 Vdc. µf to 5 µf 2 z and +2. V or 3 µ +2, after two minutes (whichever is greater) Frequency 5/6 z 2 z kz kz kz Load Life: Dissipation Factor: +5 apacitance ± 2% DF: 2% of limit DL: % of limit AF Series Marking apacitance (µf) Voltage j = 6.3 Vdc E = 25 Vdc A = Vdc V = 35 Vdc = 6 Vdc = 5 Vdc ase Dimensions 22 F Line Ident. See Ratings Table Series Shelf Life: +5 apacitance ± 2% DF: 2% of limit DL: % of limit Outline Drawing D K.3 mm Max. A ase ode D ±.5 L A ±.2 (max) I (ref) W P (ref) K B , ± / , ± /-.2 D , ± /-.2 E ± ± /-.2 F 8..2 ± ± ±.2 G..2 ± ± ±.2 L P W I I.2 (58) , Fax (58) ORNELL DUBILIER Your Source For apacitor Solutions

2 Type AF, -55 to 5 SMT Aluminum Electrolytic apacitors - Low Impedance, 5 Ratings Table Part Numbering System Max. Max. Max. Max. Dissipation Impedance Ripple urrent ap atalog DL 2 5 ase Size (mm) Quantity µf Number (µa/2 2 z 2 2 kz ode D x L per Reel min) 2 (Ω) (Ω) (ma) 6.3 Vdc ( 8 Vdc Surge) 22 AF226M6B2T B 4x AF476M62T x5.4 AF7M6D6T D 6.3x AF227M6E6T E 8x AF337M6F24T F 8x.2 5 AF8M6G24T G x AF58M6G24T G x.2 5 Vdc (3 Vdc Surge) 33 AF336M2T x5.4 AF7ME6T E 8x6.2 5 AF57ME6T E 8x AF227MF24T F 8x AF477MG24T G x.2 5 AF8MG24T G x Vdc ( 2 Vdc Surge) AF6M6B2T B 4x AF226M62T x AF476M6D6T D 6.3x AF686M6E6T E 8x6.2 AF7M6E6T E 8x AF227M6G24T G x AF337M6G24T G x AF477M6G24T G x AF687M6G24T G x Vdc ( 3 Vdc Surge) 6.8 AF685M25B2T B 4x AF226M25D6T D 6.3x AF336M25D6T D 6.3x AF476M25E6T E 8x AF686M25F24T F 8x.2 5 AF7M25F24T F 8x AF227M25G24T G x AF337M25G24T G x AF477M25G24T G x Vdc (44 Vdc Surge) AF5M35B2T B 4x AF225M35B2T B 4x AF335M35B2T B 4x AF475M35B2T B 4x AF685M352T x5.4 AF6M352T x AF226M35D6T D 6.3x AF336M35E6T E 8x AF476M35E6T E 8x6.2 AF7M35G24T G x AF227M35G24T G x AF337M35G24T G x Vdc ( 63 vdc Surge) AF5M5B2T B 4x AF225M5B2T B 4x AF335M5B2T B 4x AF475M52T x5.4 AF6M5D6T D 6.3x AF226M5E6T E 8x AF336M5F24T F 8x AF476M5G24T G x.2 5 AF7M5G24T G x AF227M5G24T G x.2 5 AF 6 M 6 B 2T hip and SMT apacitors Type apacitance 5 =. µf apacitance Tolerance 6 = µf M = ±2% 7 = µf 8 = µf Voltage = Vdc 35 = 35 Vdc 6 = 6 Vdc 5 = 5 Vdc 25 = 25 Vdc ase ode Packaging Information 2 = arrier Tape Width (mm) T = Tape & Reel B = Bulk ORNELL DUBILIER Your Source For apacitor Solutions (58) , Fax (58)

3 hip and SMT apacitors Type AF, -55 to 5 SMT Aluminum Electrolytic apacitors - Low Impedance, 5 Typical Performance urves.2 apacitance vs. Temperature & Frequency Vdc (8 X.2 mm).4 apacitance vs. Temperature & Frequency Vdc ( X.2 mm) Ratio to 25, 2 z Value Ratio to 25, 2 z Value ,,,,, Frequency (z) Frequency (z) ESR vs. Temperature and Frequency Vdc (8 X.2 mm) ESR vs. Temperature and Frequency Vdc ( X.2 mm) Ratio to 25, 2 z Value Ratio to 25, 2 z Value ,,,,, Frequency (z).,,,,, Frequency (z) Impedance vs. Temperature and Frequency Vdc (8 X.2 mm) mm) Impedance vs. Temperature and Frequency Vdc ( X.2 mm) mm) Ratio to 25, 2 z Value Ratio to 25, 2 z Value ,,,,, Frequency (z).,,,,, Frequency (z).4 (58) , Fax (58) ORNELL DUBILIER Your Source For apacitor Solutions

4 Type AF SMT Aluminum Electrolytic apacitors - Low Impedance, 5 Typical Performance urves hip and SMT apacitors.2 apacitance vs. Temperature & Frequency 22 5 Vdc ( X.2 mm) 2 apacitance hange with Temperature (Typical Performance AF 2 z) Ratio to 25, 2 z Value ,,,,, Frequency (z) apacitance hange (%) 6.3 Vdc (6.3 X 5.4 mm) Vdc (6.3 X 5.4 mm) 5 Vdc (6.3 X 5.4 mm) Temperature ( ) ESR vs. Temperature and Frequency 22 5 Vdc ( X.2 mm).6 Dissipation Factor vs. Temperature (Typical Performance AF 2 z) Vdc (6.3 X 5.4 mm) Ratio to 25, 2 z Value D.F. (@2 z) Vdc (6.3 X 5.4 mm) 5 Vdc (6.3 X 5.4 mm) ,,,,, Frequency (z) Temperature ( ) Impedance vs. Temperature and Frequency 22 5 Vdc ( X.2 mm) apacitance hange vs Time (Typical Performance AF Series) Ratio to 25, 2 z Value ,,,,, Frequency (z) 55 apacitance hange (%) Vdc (4 x 5.4 mm) 47 6 Vdc ( 6.3 x 5.4 mm) 33 6 Vdc ( x.2 mm) 5,,5 2, Time (ours) ORNELL DUBILIER Your Source For apacitor Solutions (58) , Fax (58)

5 AVS, AA, AF, AFK, AD, AEB Tape and Reel Specifications Tape Specifications omponent Orientation Polarity Stripe (-) athode 4 ±..5 dia.75 ±..4 t ±.2 W ±.3 B ±.2 F ±. A ±.2 P (mm) ase ode W A B P F t A B D X E F G ±. 4.±..5±..5 D±.2.75±. F±. W±.3 S±. A±.5 ±.5 P±. B±.5 (mm) ase ode W A B D F P S J K L P R S U

6 AVS, AA, AF, AFK, AD, AEB Tape and Reel Specifications Reel Specifications E B R:. mm (.39 in.) D t A W ase ode A B D E W t A, B size 38±2 5 min 3.±.5 2.±.8 2.±.5 4± 3., D, E, X size 38±2 5 min 3.±.5 2.±.8 2.±.5 8± 3. F, G size 38±2 5 min 3.±.5 2.±.8 2.±.5 26± 3. J, K,, L size 33±2 5 min 3.±.5 2.±.8 2.±.5 34± 3. P, R, S, U size 33±2 5 min 3.±.5 2.±.8 2.±.5 46± 3. (mm) Land Pattern: B A B (mm) ase ode A B A B D E F G J, K L P R, U S

7 AVS, AA, AF, AFK, AD, AEB Reflow Solder & ase Dimensions Reflow Soldering Temperature Profile: Peak Temp. (see chart right) seconds Preheat 5 seconds maximum Maximum 2 (see chart right) ase Peak Max. Time ode Temp ( 2 (Sec.) A, B,, D, X 24 4 E, F, G, 23 3 J, K, L, P R, S, U Time Outline Drawing K.3 mm Max. A I D P I L W ase Dimensions (mm) ase ode D ±.5 L A ±.2 (max) I (ref) W P (ref) K A , ± /-.2 B , ± / , ± /-.2 D , ± /-.2 X ± ± /-.2 E ± ± /-.2 F 8..2 ± ± ±.2 G..2 ± ± ± ± ± ±.3 J ± ±.2 K ± ±.2 L ± ± ±.3 P ± ± ±.3 R ± ± ±.3 S ± ± ±.3 U ± ±.3 *5.8 +.,-.2 for AFK and AD Series

8 V-hip eaning and oating Guide eaning Below is a table discribing the usable solvents for cleaning a P board containing V-hips. Table Recommended Symtoms Solvent type Name Manufacturer use level of Damage Water Base Water Distilled Water None Alkaline Aqua eaner 2SEP Sanei 2 Pine Alpha ST-S Aralaw a Kasei Kogyo 2 ean-thru 75 2 None, though Surface active ean-thru 75L Kao orporation 2 marking ink agent ean-thru 7M 2 may fade Sun-elec B-2 Sanyo Kasei 2 DK be-clean W-579 Dai-Ichi Kogyo Seiyaku 2 Solvent Base Petroleum old-cleaner P3-375 enkel akusui 3 based Techno-cleaner 29 Seiwa Sangyo 3 hydrocarbon Axarel 32 Mitsui DF 3 Alcohol base Isopropyl Alcohol None Silicon base Techno-care FRW-7 3 None if used in Techno-care FRW-7 Toshiba orporation 3 combination (Techno-care FRV-) 3 ontains Asashi-clean AK-225AES Ashahi Glass 3 alogenated F's subject hydrocarbon to F4B-MS Dalkin Kogyo 3 environmental regulations Telpen base Telpen-cleaner E-7R Nippon Alpha Metals 3 swelled seal swellling on sealing rubber rinse and dry well after cleaning Use level Recommendation Number eaning is possible 2 eaning is possible (markings may fade) 3 eaning is possible (Use caution. and 2 are better choices) V-hips may be immersed for 5 minutes, safely, in Level &2 solvents. Use Level 3 solvents with caution. Do not use chlorine-based halogenated cleaning solvents, adhesives or coating agents. When halogenated chlorine-based solvents are used in the cleaning process, free clorine is liberated from the solvent. This chlorine causes corrosion and deterioration of the aluminum inside the capacitor Dangers of Free-hlorine : After the solvent dries, the chlorine remains on the capacitor seal, the chlorine slowly permeates into the capacitor element causing corrosion and damage that happens slowly. It may take some time before a failure is apparent. A representation of the chemical reaction is on the following page.

9 V-hip eaning and oating Guide Free-chlorine Diagram: Electrolysis reaction + (2) hlorosen + + = Dichloroethane Dicloroethylene Fig. Decomposed reaction of cleaning solvents (Free-chlorine) Reaction of Free-chlorine and Aluminum ombined free chlorine and hydrogen become hydrochloric acid, but it has high dissociation and most of it becomes chlorine ions. These chlorine ions react with the aluminum. The order of the reactions is represented below..) ydration of oxide film AlO3 + 32O > 2Al(O)3 2.) Reaction of hydrated oxide film and chlorine (Dissolution of film) Al(O)3 + 3 > Al3 + 32O 3.) Reaction of aluminum and hydrochloric acid (Dissolution of aluminum) Al + 3 > Al3 + 3/22 4.) Precipitation of aluminum hydroxide Al3 + 32O > Al(O)3 + 3 The entire reaction can be summerized as the following: Al + Al2O O > 2Al(O)3 + Al3 + Al3 + 3/2 Therefore the compounds produced by the reactions are aluminum hydroxide and hydrochloric acid from reaction #4; the hydrochloric acid is not consumed and acts as a catalyst.

10 V-hip eaning and oating Guide Table 2 Solvents that should not be used omposition Boiling Point ( ) ommon Name..-Trichloroethane 74. hlorosen Trichloroethylene 87.2 Trichlene Tetrachloroethylene 2. Perchloroethylene Additional eaning Notes:.) Solvents containing F s destroy the ozone layer and should be avoided to protect the global environment. 2.) To avoid solvent residue between the capacitor s seal and the P board, make sure the assembly is dried thoroughly immediately after cleaning. oating Below is a list of coatings that are safe for use with V-hips Table 3 Manufacturer Material oating Material Name itachi hemical Boxy Brown Acrylic Acrylic Taffi-4, Taffi-47 umi Seal B66 Urethane Urethane Taffi-54 umi Seal A27 Dow orning Silicon Perugan Z, Perugan Nihon Zeon Urethane Quinate System 6B Influence of oating Materials oating materials are typically used for insulation, waterproofing, dustproofing and rustproofing. When coating materials are selected there are factors to prevent internal corrosion (chlorine reaction with aluminum) while the capacitor is functioning. The following steps will help prevent this damage to the capacitor. A.) orrosion Reaction Avoid halogen solvents which permeate the capacitor s seal, releasing chlorine which reacts with the aluminum inside the capacitor. B.) Selecting a oating Material It is necessary to select a coating material that contains no chlorine. The coating consists of the main ingredient which could be urethane resin, acrylic resin or other polymer, a solvent and other additives such as flameproofing agents.

11 V-hip eaning and oating Guide The coating s solvent dries and diffuses into the rubber seal of the capacitor, therefore halogenated hydrocarbon solvents containing chloride should not be used. Similar to the solvent, additives can permeate into the capacitor through the rubber seal. Ingredients in many additives might not be listed, therefore use caution when choosing an additive..) Other oncerns Solvents and additives are subject to change without notice. Make sure ingredients are identified. Avoid coating a substrate after cleaning it with a halogenated hydrocarbon. The coating will prevent the remaining solvent from diffusing which may cause corrosion.