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Abstract: , example #2. The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , pre-arc I2t, however, requires clarification. The proper design for pre-arc I2t is presented by way of , state current. In order to design for current pulses, the concept of fuse pre-arc Joule integral, I2t , I2t-I). I2t expresses the amount of energy required to actuate the fuse. Total I2t expresses the total AVX
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smd t05 0.5A FUSE
Abstract: actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A , pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , pre-arc I2t, however, requires clarification. The proper design for pre-arc I2t is presented by way of , order to design for current pulses, the concept of fuse pre-arc Joule integral, I2t, must be understood AVX
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F1206B F0603C trapezoidal pulse F0805B F1206A F0612D
Abstract: = 1.8 x 10-4 A2sec Joule integral within 7.7 usec without actuation. According to the I2t graph on , According to the I2t graph on page 6, the 0.5A fuse should be chosen for this application, see Figure 3c , pre-arc I2t, however, requires clarification. The proper design for pre-arc I2t is presented by way of , of fuse pre-arc Joule integral, I2t, must be understood. Fuse current rating is defined by the , currents is specified by I2t-t curves (or I2t-I). I2t expresses the amount of energy required to actuate -
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F0402E F0603E
Abstract: actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A , Fig. 2b. Triangular pulse, example #2. The pulse duration is 3 msec. In the I2t graph on page 6 , 0.5A/div 5A/div Fig. 3b. Trapezoidal pulse, example #3. According to the I2t graph on page 6, the , (TYPICAL) 100 10 1 2.00A 1.75A 1.50A 1.25A 1.00A Pre-Arc I2t, A2sec 10-1 10-2 10-3 , 1 Pre-Arc I2t, A2sec 10-1 10-2 2.00A 1.75A 1.50A 1.25A 1.00A 0.75A 0.50A 0.375A 0.25A 0.20A AVX
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SMD fuse 110 F02402G E143842 F0402G E141069
Abstract: actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A , pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , I2t, A2sec 1 10-1 10-2 10-3 0.75A 0.50A 0.375A 0.25A 0.20A 10-4 10-5 0 , PRE-ARC JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 Pre-Arc I2t, A2sec 1 AVX
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SMD fuse 4A MMC 103 ceramic capacitor rf-microwave components diode smd ED 56a diode on mobo 1601 lcd appl
Abstract: , example #2. The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 1.50A 1.25A 1.00A Pre-Arc I2t, A2sec 10-1 10-2 10-3 10-4 0.75A 0.50A 0.375A 0.25A , JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 1 Pre-Arc I2t, A2sec 10-1 , factor of pre-arc I2t, however, requires clarification. The proper design for pre-arc I2t is presented by AVX
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Abstract: without actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for , . The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is , . Trapezoidal pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 3.00 220 4.00 220 6.00 260 10 200 12.5 Pre-Arc I2t @ 50A A2-sec 0.00005 0.0003 0.008 , JOULE INTEGRALS VS CURRENT FOR SIZE 0402 (TYPICAL) 100 10 Pre-Arc I2t, A2sec 1 10-1 10-2 AVX
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smd fuse d FUSE SMD 0603 1R75 smd fuse p smd fuse 15 fuse smd 6a
Abstract: I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A fuse, which is , . In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x 10-3A2sec for the 0.5A , According to the I2t graph on page 6, the 0.5A fuse should be chosen for this application, see Figure 3c , (TYPICAL) 100 100 0 10 1 0 -1 PreArc I2t, A2sec 10 -2 10 2.0A 0 1.5A , 1 Pre-Arc I2t, A2sec 1.75A 10-1 1.5A 1.25A 10-2 1.0A 10 -3 0.75A 0.5A AVX
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smd fuse 1206 SMD Capacitor types smd fuse x FUSE SMD b1 fuse
Abstract: without actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for , . The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is , . Trapezoidal pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 1.00A Pre-Arc I2t, A2sec 1 10-1 10-2 10-3 0.75A 0.50A 0.375A 0.25A 0.20A 10-4 , FUSE PRE-ARC JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 Pre-Arc I2t AVX
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Fuse 0.5A rf&microwave product SMD CAPACITORS 106 E F1206A0R50FWTR FUSE 2A SMT Triangle Microwave GA S-ACCU5M804-C
Abstract: integral within 7.7 sec without actuation. According to the I2t graph on page 6, pre-arcing Joule integral , . In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x 10-3A2sec for the 0.5A , According to the I2t graph on page 6, the 0.5A fuse should be chosen for this application, see Figure 3c , Current (within 5 sec) A 0.125 0.155 0.1875 0.250 0.312 0.375 0.500 Pre-Arc I2t @10xIRATED A2-sec (typ , INTEGRALS VS CURRENT 10 200 mA 1 150 mA 125 mA 100 mA 10 -1 Pre-Arc I2t, A2sec 10 -2 75 mA 10 -3 AVX
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electronic passive components catalog fuse smd code L fuse smd code Y suface 0603 S-ACCU5M612-C
Abstract: I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A fuse, which is , . In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x 10-3A2sec for the 0.5A , According to the I2t graph on page 6, the 0.5A fuse should be chosen for this application, see Figure 3c , 1.00A Pre-Arc I2t, A2sec 1 10-1 10-2 10-3 0.75A 0.50A 0.375A 0.25A 0.20A 10-4 , FUSE PRE-ARC JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 Pre-Arc I2t AVX
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F1206A1R50FWTR F1206A1R25FWTR F1206A1R00FWTR F1206A0R75FWTR F1206A0R37FWTR F1206A0R25FWTR S-ACCU00M0501-C
Abstract: I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A fuse, which is , . In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x 10-3A2sec for the 0.5A , According to the I2t graph on page 6, the 0.5A fuse should be chosen for this application, see Figure 3c , 0.1875 0.250 0.312 0.375 0.500 Pre-Arc I2t @10xIRATED A2-sec (typ) 2 x 10-6 2 x 10-6 4 x 10-6 , JOULE INTEGRALS VS CURRENT 10 200 mA 1 150 mA 125 mA 10 -1 Pre-Arc I2t, A2sec 100 mA AVX
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glass fuse color code
Abstract: integral within 7.7 usec without actuation. According to the I2t graph on page 6, pre-arcing Joule , application, see Figure 1c. The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule , . Trapezoidal pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 1.00A Pre-Arc I2t, A2sec 1 10-1 10-2 10-3 0.75A 0.50A 0.375A 0.25A 0.20A 10-4 , FUSE PRE-ARC JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 Pre-Arc I2t AVX
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F1206A0R20FWTR smd fuse 32 S-ACCU10M599-C
Abstract: . According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A fuse, which , is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x 10-3A2sec for , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 0.1875 0.250 0.312 0.375 0.500 Pre-Arc I2t @10xIRATED A2-sec (typ) 2 x 10-6 2 x 10-6 4 x 10-6 , mA 125 mA 100 mA 75 mA 1 62 mA 10-1 Pre-Arc I2t, A2sec 10-2 50 mA 10-3 AVX
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F0603G S-ACCU0M1213-C
Abstract: actuation. According to the I2t graph on page 6, pre-arcing Joule integral is 2.3x10-4 A2sec for the 0.5A , pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule integral for 3 msec pulse is 4 x , pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , Drop @IRATED mV (max.) 250 Fusing Current (within 5 sec) A 0.312 Pre-Arc I2t @10xIRATED , 2.50 3.00 4.00 5.00 6.00 0.50 1.00 2.00 3.00 4.00 6.00 10 12.5 Pre-Arc I2t @ 50A AVX
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4560 pre amp fuse smd code x fuse smd color code fuse smd code D fuse smd code t fuse smd code e
Abstract: integral within 7.7 usec without actuation. According to the I2t graph on page 6, pre-arcing Joule , application, see Figure 1c. The pulse duration is 3 msec. In the I2t graph on page 6, prearcing Joule , . Trapezoidal pulse, example #3. According to the I2t graph on page 6, the 0.5A fuse should be chosen for this , 1.00A Pre-Arc I2t, A2sec 1 10-1 10-2 10-3 0.75A 0.50A 0.375A 0.25A 0.20A 10-4 , FUSE PRE-ARC JOULE INTEGRALS VS. PRE-ARC TIME FOR SIZE 1206 (TYPICAL) 100 10 Pre-Arc I2t AVX
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5B smd transistor data transistor SMD 6b thermal Fuse 2 amp 46 fuse smd fuse table F1206B1R50FWTR
Abstract: current Inrush current included included Check with the I2t characteristics graph. Does the , includes a pulse, surge, or inrush-current, use the I2t graph and check that the ICP will not deteriorate , current in the end. Test: With pulse current: I2t = 1.752×20 = 61 (A2 · ms) at 20ms (See graph 2 , wave form I2t = 1/3 · Im2 · t). I2t = 1/3 × 32A × 1ms = 3 (A2 · ms) Plotting test: 10000 Graph 2 , necessary. 4) Minimal breaking point dispersion. (See the graph in 3-2 Breaking Current Dispersion -
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ICP-N38 N50 Fuse Fuse n25 ICP-N25 ICPN5 ICP-N70 E107856
Abstract: current Inrush current included included Check with the I2t characteristics graph. Does the , includes a pulse, surge, or inrush-current, use the I2t graph and check that the ICP will not deteriorate , current in the end. Test: With pulse current: I2t = 1.752×20 = 61 (A2 · ms) at 20ms (See graph 2 , wave form I2t = 1/3 · Im2 · t). I2t = 1/3 × 32A × 1ms = 3 (A2 · ms) Plotting test: 10000 Graph 2 , applied. No derating is necessary. 4) Minimal breaking point dispersion. (See the graph in 3-2 Breaking ROHM
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ICP-S
Abstract: Characteristics 106 104 Cat. No. UP600K 1 1 2 2 UP700K 105 20 I2t (A2s) Joule , 10 2 2 105 Ratio of I2t 1.0 0.9 0.8 0.7 0.6 0.5 0.4 -20 20 40 60 , fuse fits the relationship below. I2t of fuse breakage > I2t of rush current / resistance to rush current *2 UP UPK *2 Rush resistance coefficient: Select the 10 5 value from the graph to the left Daito Communication Apparatus
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AC100 RUSH 3400A2 8000A2 AC100200V
Abstract: 1 1Clearing Current within 1 minute 2 10 at 10% max. rated current 3 I2t t10ms I2 Joule , 10-1 10-2 -1 10 3A I2t (A2s) Joule integral 104 DC 250V 1,500A P430 Physical , 103 104 Ratio of I2t Ratio of I2t 1.0 0.9 0.8 0.7 0.6 105 Repeat numbers to , relationship below. I2t of fuse breakage > I2t of rush current / resistance to rush current *2 Please , : Select the 10 5 value from the graph to the left. Cat. No. -20 P403P413 1-3 Daito Communication Apparatus
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200A2 PL4150 200VA p42sb 12A2 pl4100 FUSES P450 FUSES P435 PL475 130A2 PL4100 400A2
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