No. P-KAB-00 DATE 007-0 PRODUCTS DATA SHEET UL/cUL approved File No.E70 RoHS COMPLIANT MICRO FUSE Type KAB LEAD FREE Size 608/0
Type KAB micro fuse is designed for circuit protection against excessive current in portable electronic equipment, electronic circuit around battery, etc. because the demand for high capacity batteries is increasing. Further miniaturization and low profile with extended rated range can be used for wider application. Also, the ecology design of Type KAB is gentle to the environment due to complete lead free. FEATURES. New type fuses developed by our original technology. They show no variation in fusing characteristics and have excellent fastblow capability.. Surface temperature rise is 75 C or less when applying rated current. This offers less influence on the peripheral units. 3. The fuses come in ultrasmall size 608 (.6 0.8 0.45 mm) and 0 (.0.5 0.5 mm). 4. Suitable for automatic mounting 5. Precise dimensions allows high-density mounting and symmetrical construction of terminals provide Self-Alignment. 6. Resistance to soldering heat : Reflow or flow soldering 0 seconds at 60 C 7. High accuracy carrier tape by using pressed pocket paper ensures excellent mounting. 8. LEAD-FREE and RoHS Compliant RATING Item Category Temperature Range Rated Current Rated Voltage Voltage Drop Insulation Resistance (between Terminals and Case) Fusing Characteristics Clearing Characteristics Rating -40 ~ +5 C.6 0.8 0. 0.5 0.35 0.4 0.5 0.63 0.8.0.5.6.0.5 3.5 4.0 5.0 6.3 A.0.5 0. 0.5 0.35 0.4 0.5 0.63 0.8.0.5.6.0.5 3.5 4.0 5.0 A 4 VDC, 3 VDC, 50 VDC Refer to CATALOG NUMBERS AND RATING 000 MΩ or more Fusing within min if the current is 00% of rated current. Breaking voltage : 4 V, 3 V or 50 V Breaking current : 50 A ORDERING INFORMATION K A B 3 0 0 N A 9 0 0 Type KAB Code 40 30 500 Voltage 4V 3V 50V Code 0 5 3 40 50 63 80 0 Rated current 0. A 0.5 A 0.35 A 0.4 A 0.5 A 0.63 A 0.8 A.0 A Code 3 6 0 5 3 40 50 63 Rated current.5 A.6 A.0 A.5 A 3.5 A 4.0 A 5.0 A 6.3 A Code NA Packaging type f80 Reel Code Case size Special product code 9.6 0.8 00 3.0.5 The special product code 00 indicates lead-free terminals.
CATALOG NUMBERS AND RATING Catalog number KAB 500 0 9 00 KAB 500 5 9 00 KAB 500 3 9 00 KAB 500 40 9 00 KAB 500 50 9 00 KAB 30 63 9 00 KAB 30 80 9 00 KAB 30 0 9 00 KAB 30 3 9 00 KAB 30 6 9 00 KAB 30 0 9 00 KAB 40 5 9 00 KAB 40 3 9 00 KAB 40 40 9 00 KAB 40 50 9 00 KAB 40 63 9 00 Case size.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8.6 0.8 Rated current A 0. 0.5 0.35 0.4 0.5 0.63 0.8.0.5.6.0.5 3.5 4.0 5.0 6.3 Internal resistance mω (Typical) 60 85 530 30 0 35 00 80 60 46 35 7 0 5 3 0 KAB 40 0 3 00.0.5 0. 740 KAB 40 5 3 00.0.5 0.5 80 KAB 40 3 3 00.0.5 0.35 800 KAB 40 40 3 00.0.5 0.4 440 KAB 40 50 3 00.0.5 0.5 60 KAB 40 63 3 00.0.5 0.63 75 KAB 40 80 3 00.0.5 0.8 0 KAB 40 0 3 00.0.5.0 90 KAB 40 3 3 00.0.5.5 67 KAB 40 6 3 00.0.5.6 48 KAB 40 0 3 00.0.5.0 36 KAB 40 5 3 00.0.5.5 8 KAB 40 3 3 00.0.5 3.5 KAB 40 40 3 00.0.5 4.0 6 KAB 40 50 3 00.0.5 5.0 0 For taping specification, the package code (NA) is entered in. One reel contains 5000 pcs. Voltage drop mv (Max.) 405 355 75 80 40 5 0 0 0 0 0 0 0 0 0 0 480 475 375 55 70 50 45 35 30 0 5 0 05 95 60 Rated voltage VDC 50 3 4 Breaking current A 50 4 50 DIMENSIONS P P L P P T W Main Body : Alumina ceramic Terminal : Tin plating Case size 608 0 Case code 9 3 L W T max..6 ± 0. 0.8 ± 0. 0.45.0 ± 0..5 ± 0. 0.5 (mm) P 0.3 ± 0. 0.3 ± 0. MARKING CONSTRUCTION Code : Rated current P : 0. A Q : 0.5 A R : 0.35 A S : 0.4 A T : 0.5 A U : 0.63 A V : 0.8 A :.0 A Code : Rated current W :.5 A X :.6 A :.0 A Y :.5 A 3 : 3.5 A 4 : 4.0 A 5 : 5.0 A 6 : 6.3 A Protective coating Body Fuse element Terminal Name Fuse element Body Protective coating Terminal Material Copper alloy Alumina ceramic Silicone resin Tin plating RECOMMENDED PAD DIMENSIONS STANDARD TEST BOARD a c a b Size 608 Size 0 a.0.4 b..65 c.0. (mm) 00 mm a mm 5 mm 33 mm Glass epoxy on one side Board thickness :.6 mm Copper layer : 35 µm Case size Size a 608. 0.5 (mm)
PERFORMANCE No. Item Performance Test method Temperature rise Temperature rise shall not exceed 75 C. Apply rated current. Current-carrying capacity Shall not open within hour. Apply rated current. 3 Clearing characteristics Arc shall not be continued. Breaking voltage : Rated voltage Marking shall be legible. Breaking current : 50 A 4 5 Voltage drop 6 Insulation resistance 000 MΩ or more 7 Fusing characteristics Electrode strength (Flexibility) 8 Shear test 9 Substrate bending test 0 Solderability Resistance to soldering heat Solvent resistance 3 Vibration 4 Shock 5 Thermal shock 6 Atomizing salt water 7 Moisture resistance 8 Load life 9 Stability Voltage drop is below the value specified in CATALOG NUMBERS AND RATING. Fusing within min. The dipped surface of the terminals shall be covered more than 95% with new solder. Marking shall be legible. Marking shall be legible. Apply rated current. Apply 00% of rated current. (Ambient temperature : 0 ~ 30 C) Insulation resistance between terminals and case (alumina ceramic) Board supporting width : 90 mm Bending speed : Approx. 0.5 mm/sec Duration : 30 sec Bending : 3 mm Applied force : 0 N (.04 kgf) Duration : 0 sec Tool : R0.5 Direction of the press : side face Supporting dimension :. mm (size 0) 0.8 mm (size 608) Applied force : 0 N (.0 kgf) Tool : R0.5 Direction of the press : thickness direction of product Dipping : 3 sec Temperature : 45 ± 5 C Solder : Sn 3Ag 0.5Cu alloy Dipping : 3 sec Temperature : 35 ± 5 C Solder : JIS Z 38 (solder) H60A, H60S, H63A Dipping ( cycle) Preconditioning : 00 ~ 50 C, 60 sec Temperature : 65 ± 3 C/6 ~ 7 sec Reflow soldering ( cycles) Preconditioning : ~ min, 80 C or less Peak : 60 C max, 5 sec Holding : 30 ~ 50 C, 30 ~ 40 sec Cooling : more than min Manual soldering Temperature : 400 ± 0 C Duration : 3 ~ 4 sec Measure after hour left under room temp. and humidity. Dipping rinse Solvent : Isopropyl alcohol Duration : 90 sec Frequency range : 0 ~ 55 ~ 0 Hz/min Vibration amplitude :.5 mm Duration : hours in each of XYZ directions (total : 6 hours) Peak value : 490 m/s (50 G) Duration : ms 6 aspects 3 times (total : 8 times) 55 ± 3 C : 30 min Room temperature : ~ 3 min or less 5 ± C : 30 min Room temperature : ~ 3 min or less Repeat above step for 0 cycles. Temperature : 35 ± C Concentration (weight ratio) : 5 ± % Duration : 4 hours Temperature : 85 ± 3 C Humidity : 85 ± 5% RH Duration : 000 hours Temperature : 85 ± C Applied current : Rated current 70% Duration : 000 hours Temperature : 5 ± C Duration : 000 hours
FUSING CHARACTERISTICS Size 608 Reference 00 0. A 0.5 A 0.35 A 0.4 A 0.5 A 0.63 A 0.8 A.0 A.5 A.6 A.0 A.5 A 3.5 A 4.0 A 5.0 A 6.3 A 0 0. 0.0 0.00 0.000 0. 0 00 Applied current (A) Size 0 00 0. A 0.5 A 0.35 A 0.4 A 0.5 A 0.63 A 0.8 A.0 A.5 A.6 A.0 A.5 A 3.5 A 4.0 A 5.0 A 0 0. 0.0 0.00 0.000 0. 0 00 Applied current (A)
I T T CHARACTERISTICS Reference Size 608 Joule integral (A s) 000 00 0 0. 6.3 A 5.0 A 4.0 A 3.5 A.5 A.0 A.6 A.5 A.0 A 0.8 A 0.63 A 0.5 A 0.4 A 0.35 A 0.5 A 0. A 0.0 0.00 0.000 0.000 0.00 0.0 0. 0 Size 0 Joule integral (A s) 000 00 0 0. 5.0 A 4.0 A 3.5 A.5 A.0 A.6 A.5 A.0 A 0.8 A 0.63 A 0.5 A 0.4 A 0.35 A 0.5 A 0. A 0.0 0.00 0.000 0.000 0.00 0.0 0. 0
DISTRIBUTION OF FUSING CHARACTERISTICS KAB 40 0 n : 58 pcs. 00 0 0. 0.0 0.00 0.000 0. 0 00 Applied current (A)
DISTRIBUTION OF FUSING TIME KAB 40 80 KAB 40 0 00% of rated current is applied. 00% of rated current is applied. 0. 0. 0.0 500% of rated current is applied. 0.0 500% of rated current is applied. 0.00 0.00 0.000 0 0 0 30 40 50 Number of pieces 0.000 0 0 0 30 40 50 Number of pieces KAB 40 3 KAB 40 6 00% of rated current is applied. 00% of rated current is applied. 0. 0. 0.0 500% of rated current is applied. 0.0 500% of rated current is applied. 0.00 0.00 0.000 0 0 0 30 40 50 Number of pieces 0.000 0 0 0 30 40 50 Number of pieces
DETERMINATION OF RATED VALUE AND SELECTION OF MICRO FUSE (TYPE KAB) Determine the rated value of the microfuse, and select the correct microfuse for your circuit. If you select the correct microfuse, safety of your circuit can be ensured. How to determine the rated value of the microfuse is described below : Flow for fuse selection. Measurement of circuit values using acute device. Calculation from operating current 3. Calculation from overload current 4. Calculation from inrush current 5. Final determination of rated value 6. Operation check using actual device Measure the circuit values, such as operating current of the circuit. From the obtained operating current and the category temperature, calculate the minimum rated value to determine the applicable fuse. From the obtained overload current, calculate the maximum rated value to determine the applicable fuse. From the inrush current, calculate the minimum rated value to determine the applicable fuse. From the calculation results of steps through 4, determine the rated value. After selecting the rating, confirm if the device works properly under the pre-determined conditions. Fuse selection. Measurement of circuit values using actual device Before determining the rated value of the fuse, preliminarily measure the following using the actual device. Operating current Using an oscilloscope or equivalents, measure the operating current of the circuit. Overload current Using an oscilloscope or equivalents, measure the overload current that needs to break the circuit. 3 Inrush current Using an oscilloscope or equivalents, measure the inrush current of the circuit at power-on or power-off. In addition, determine the number of inrush current applied. 4 Category temperature Measure the ambient temperature of the fuse circuit. EXAMPLE TO SELECT RATINGS OF TYPE KAB <Fuse selection> Effective operating current :. A Effective overload current : 6.0 A Inrush current waveform : Fig. A (Pulse width : ms, Wave height : 6.0 A) Numbers to withstand inrush current : 00,000 times Category temperature : 85 C ms 6.0A Fig. A : Inrush current waveform. Calculation from operating current Measurement of operating current Using an oscilloscope or equivalents, measure operating current (effective current) of the actual circuit. Example : Effective operating current =. A Derating qtemperature derating factor Using Fig. B, find the temperature derating factor correspond to the temperature. wrated derating factor Rated derating factor = 0.75 Use Formula to calculate the rated current of the fuse to be used for the circuit. Rated current of fuse Operating current/ (q w)... Formula Example : Category temperature = 85 C, Operating current =. A qtemperature derating factor = 0.90 (Refer to Fig. B.) wrated derating factor = 0.75 Calculation using Formula : Rated current./ (0.90 0.75) =.78 A Derating factor 40 Fig. B 0 00 80 60 40 0 KAB temperature derating 0-50 -5 0 5 50 75 00 5 Temperature ( C) The above calculation result shows that the fuse with rated current of.78 A or more should be selected for this circuit. Type KAB with rated current of.0 A or more can be selected.
3. Calculation from overload current 3 Measurement of overload current Using an oscilloscope or equivalents, measure the overload current that needs to break the circuit. Example : Effective overload current = 6.0 A 3 Calculation from overload current Determine the rated current so that the overload current can be times larger than the rated current. Use Formula to calculate the rated current of the fuse. Rated current of fuse Overload current/.0... Formula Example : Overload current = 6.0 A Use Formula to calculate the rated current. Rated current 6.0/.0 = 3.0 A The above calculation result shows that the fuse with rated current of 3.0 A or less should be selected for this circuit. Type KAB, with rated current of.5 A or less can be selected. 4. Calculation from inrush current 4 Measurement of inrush current waveform Using an oscilloscope or equivalent, measure the waveform of the inrush current of the actual circuit. 4 Creation of approximate waveform Generally, the waveform of inrush current is complicated. For this reason, create the approximate waveform of inrush current as shown on Fig. C to simplify calculation. ms 6A 4 3 Calculation of I t of inrush current Calculate I t (Joule integral) of the approximate waveform. The formula for this calculation depends on the approximate waveform. Refer to Table A. Example : Pulse applied = ms, Peak value = 6.0 A, Approximate waveform = Triangular wave Since the approximate waveform is a triangular wave, use the following formula for calculation I t of rush current = /3 Im t... Formula 3 (Im : Peak value, t : Pulse applying time) Use Formula 3 to calculate the I t of the rush current : I t = /3 6 6 0.00 = 0.0 (A s) Fig. C : Inrush current waveform Red line : Actual measurement waveform Black line : Approximate waveform JOULE-INTEGRAL VALUES FOR EACH WAVEFORM Table A Name Sine wave ( cycle) Waveform 0 Im t I t Im t Name Trapezoidal wave Waveform 0 t t t3 Im 3 I t Im t + Im ( t t ) + 3 Im ( t 3 t ) Sine wave (half cycle) 0 t Im Im t Various wave 0 t I I I I t + 3 ( I I ) t Triangular wave 0 t Im 3 Im t Various wave 0 t t t3 I I 3 t +{ 3 ( I I ) I I + } ( t ) + 3 I t ( t 3 t ) I Rectangular wave 0 t Im Im t Charge/ discharge waveform i (t) = Im e -t/ Im 0.368 Im Im 0 -t Following formula is generally used for calculation of I t as i(t) equal to current. I t t = 0 i (t)dt
4 4 Search of load ratio qset up the number of cycles to withsand. (generally 00,000 times) wobtain the load ratio from Pulse resistance characteristics. (Fig. D) Example : 00,000 times is required against inrush current applied. Determine the load ratio using Fig. D. If the rated current is 0. ~.0 A : 30% or less If the rated current is.5 ~ 4.0 A : 6% or less If the rated current is 5.0 ~ 6.3 A : % or less PULSE RESISTANCE CHARACTERISTCS 000000 00000 Fig. D Numbers of pulse resistance (cycle) 0000 000 00 0. A ~.0 A.5 A ~ 4.0 A 5.0 A ~ 6.3 A 0 0 0 0 30 40 50 60 70 80 90 00 Load ratio (%) 4 5 Calculation from Joule integral and load ratio Use Formula 4 to calculate the standard I t for the fuse to be used. Standard I t of fuse > (I t of inrush current/load ratio)......formula 4 Example : I t of pulse = 0.0 A s, Required load ratio = 30% (at 0. ~.0 A Fuse), 6% (at.5 ~ 4.0 A Fuse) or % (at 5.0 ~ 6.3 A Fuse) Example of.0 A Fuse : Use Formula 4 to calculate the standard I t of fuse. Standard I t of fuse > 0.0/0.3 = 0.04 (A s) The standard I t of the fuse should be 0.04 (A s) or more. Since the rush pulse applied is ms, obtain the intersection of ms (horizontal axis) and 0.04 A s (vertical axis) from Fig. E (refer to the arrow shown on Fig. E). Fig. E shows the Joule integral curves for size 608. For size 0, use the Joule integral curves for the size. Select a fuse whose curve is above the intersection. Type KAB, with rated current of.6 A or more should be selected. 5. Final determination of rated value Determine the rated current of the microfuse. The rated current should meet all the above calculation results. Example :.0 A and.5 A meet the all requirements. 6. Operation check using actual device After selecting the rating, confirm if the device works properly under the pre-determined conditions. JOULE INTEGRAL VS. FUSING TIME Joule integral (A s) 000 00 0 0. 0.0 0.00 Joule Integral Curves for size 608 0.000 0.000 0.00 0.0 0. 0 Fig. E 6.30 A 5.00 A 4.00 A 3.5 A.50 A.00 A.60 A.5 A.00 A 0.80 A 0.63 A 0.50 A 0.40 A 0.35 A 0.5 A 0.0 A
Application Notes for Micro Fuse. Circuit Design Micro Fuse should be designated only after confirming operating conditions and the Micro Fuse performance characteristics. When determining the rated current, be sure to observe the following items : () Micro Fuse should always be operated below the rated current (the value considered in the temperature derating rate) and voltage specifications. () Micro Fuse should always be operated below the rated voltage. (3) Micro Fuse should be selected with correct rated value to be fused at overload current. (4) When Micro Fuse are used in inrush current applications, please confirm sufficiently inrush resistance of Micro Fuse. (5) Please do not apply the current exceeding the breaking current to Micro Fuse. (6) Use Micro Fuse under the condition of category temperature. (7) Micro Fuse should not be used in the primary power source. Micro Fuse should be selected by determining the operating conditions that will occur after final assembly, or estimating potential abnormalities through cycle testing.. Assembly and Mounting During the entire assembly process, observe Micro Fuse body temperature and the heating time specified in the performance table. In addition, observe the following items : () Mounting and adjusting with soldering irons are not recommendable since temperature and time control is difficult. In case of emergency for using soldering irons, be sure to observe the conditions specified in the performance table. () Micro Fuse body should not have direct contact with a soldering iron. (3) Once Micro Fuse mounted on the board, they should never be remounted on boards or substrates. (4) During mounting, be careful not to apply any excessive mechanical stresses to the Micro Fuse. 3. Solvents For cleaning of Micro Fuse, immersion in isopropyl alcohol for 90 seconds (at 0 ~ 30 C liquid temp.) will not be damaged. If organic solvents (Pine Alpha TM, Techno Care TM, Clean Through TM, etc.) will be applied to the Micro Fuse, be sure to preliminarily check that the solvent will not damage the Micro Fuse. 4. Ultrasonic Cleaning Ultrasonic cleaning is not recommended for Micro Fuse. This may cause damage to the Micro Fuse such as broken terminals which results in electrical characteristics effects, etc. depending on the conditions. If Ultrasonic cleaning process must be used, please evaluate the effects sufficiently before use. 5. Caution During Usage () Micro Fuse with electricity should never be touched. Micro Fuse with electricity may cause burning due to the Micro Fuse high temperature. Also, in case of touching Micro Fuse without electricity, please check the safety temperature of Micro Fuse. () Protective eyeglasses should always be worn when performing fusing tests. However, there is a fear that Micro Fuse will explode during test. During fusing tests, please cover particles not to fly outward from the board or testing fixture. Caution is necessary during usage at all times. 6. Environmental Conditions () Micro Fuse should not be operated in acid, alkali, or active gas atmosphere. () Micro Fuse should not be vibrated, shocked, or pressed excessively. (3) Micro Fuse should not be operated in a flammable or explosive atmosphere. (4) After mounting Micro Fuse on a board, covering Fuses with resin may affect to the electric characteristics of the Micro Fuse. Please be sure to evaluate it in advance. 7. Emergency In case of fire, smoking, or offensive odor during operation, please cut off the power in the circuit or pull the plug out. 8. Storage () Micro Fuse should be stored at room temperature (-0 C ~ +40 C) without direct sunlight. Direct sunlight may cause decolorization and deformation of the exterior and taping. Also, there is a fear that solderability will be remarkably lower in high humidity. () If the products are stored for an extended period of time, please contact Matsuo Sales Department for recommendation. The longer storage term causes packages and tapings to worsen. If the products are stored for longer term, please contact Matsuo Sales Department for advice. (3) The products in taping, package, or box should not be given any kind of physical pressure. Deformation of taping or package may affect automatic mounting. 9. Disposal When Micro Fuse are disposed of as waste or scrap, they should be treated as industrial waste. Micro Fuse contain various kinds of metals and resins. 0. Samples Micro Fuse received as samples should not be used in any products or devices in the market. Samples are provided for a particular purpose such as configuration, confirmation of electrical characteristics, etc. Please feel free to ask our sales department for more information on the Micro Fuse. Overseas Sales Dep. : USA : 5-3, 3-Chome, Sennari-cho, Toyonaka-shi, Osaka 56-8558, Japan Matsuo Electronics of America, Inc. 34 Main Street, Suite 00, Huntington Beach, CA 9648 Tel : 06-633-0883 Tel : 74-969-49 Head Office : 5-3, 3-Chome, Sennari-cho, Toyonaka-shi, Osaka 56-8558, Japan Tel : 06-633-087 Fax : 06-633-090 Fax : 74-960-649 Fax : 06-633-386 URL : http://www.ncc-matsuo.co.jp/ The specifications on this catalog are subject to change without prior notice. Please inquire of our Sales Department to confirm the specifications prior to use.