| Image | Part Number | Description / PDF | Quantity | Rfq |
|---|---|---|---|---|
 |
OptiFuse |
GLASS-5X20MM (UL), MEDIUM 3.15A |
6670 |
|
 |
OptiFuse |
GLASS FUSE-5X20MM (UL), FAST 7A |
394 |
|
 |
OptiFuse |
CERAMIC - 6.3X32MM, SLOW 250MA |
802 |
|
 |
OptiFuse |
CERAMIC-5X20MM (IEC), FAST 1.25A |
4000 |
|
 |
OptiFuse |
FUSE AUTO 5A 32VDC BLADE MICRO |
1196 |
|
 |
OptiFuse |
UL CLASS M FUSE, FAST ACTING 10A |
23 |
|
 |
OptiFuse |
GLASS FUSE-6.3X32MM, SLOW 375MA |
380 |
|
 |
OptiFuse |
THRU HOLE FUSE, TIME DELAY 630MA |
1950 |
|
 |
OptiFuse |
GLASS - 5X20MM (IEC), SLOW 3.15A |
4065 |
|
 |
OptiFuse |
GLASS-5X20MM (UL), MEDIUM 700MA |
1970 |
|
 |
OptiFuse |
FUSE AUTO 500MA 80VDC BLADE MINI |
0 |
|
 |
OptiFuse |
CERAMIC FUSE-6.3X32MM, SLOW 12A |
6881 |
|
 |
OptiFuse |
REGULAR (ATO/ATC), 80V 10A - UL |
459 |
|
 |
OptiFuse |
GLASS FUSE - 5X15MM, FAST 3.5A |
3500 |
|
 |
OptiFuse |
FUSE AUTO 5A 80VDC BLADE MICRO |
0 |
|
 |
OptiFuse |
THRU HOLE FUSE,FAST ACTING 800MA |
656 |
|
 |
OptiFuse |
FUSE AUTO 15A 32VDC BLADE MINI |
960 |
|
 |
OptiFuse |
FUSE AUTO 30A 32VDC BLADE MAX |
1947 |
|
 |
OptiFuse |
CLASS M FUSE, TIME DELAY 750MA |
0 |
|
 |
OptiFuse |
UL CLASS M FUSE, FAST ACTING 15A |
54 |
|
Fuses are electrical safety devices that protect circuits from overcurrent conditions. As the oldest and most widely used circuit protection technology, fuses operate by breaking the circuit when current exceeds specified limits. Their importance in modern electronics spans from consumer devices to industrial machinery, preventing damage from short circuits, overloads, and fault conditions while ensuring system reliability and safety.
| Type | Functional Features | Application Examples |
|---|---|---|
| Miniature Cartridge Fuses | Compact glass/ceramic body, fast-acting response | Power supplies, consumer electronics |
| Time-Delay Fuses | Withstands temporary current surges, slow-blow characteristics | Motors, transformers, switch-mode power supplies |
| High-Breaker Fuses | Handles extreme fault currents (>10kA), ceramic construction | Industrial equipment, HVAC systems |
| Surface-Mount Fuses | Miniaturized SMD packaging for PCB integration | Smartphones, medical devices |
| Resettable Fuses (PTC) | Polymer-based self-resetting functionality | USB ports, battery protection circuits |
Typical fuse construction includes: - Enclosure: Glass, ceramic, or plastic housing (dimensions standardized as 5x20mm, 6.3x32mm) - Fusible Element: Calibrated wire or etched metal strip (silver, copper, or alloy materials) - Filling Material: Sand/quartz for arc suppression in high-current models - Contact Terminals: Metal caps or surface-mount pads for electrical connection Modern designs incorporate laser-welded elements and precision-calibrated response mechanisms.
| Parameter | Description | Importance |
|---|---|---|
| Rated Current (In) | Max normal operating current (0.1-250A range) | Determines circuit protection threshold |
| Voltage Rating | Max circuit voltage (32V-1000V DC/AC) | Ensures safe arc interruption |
| Breaking Capacity | Fault current interruption capability (10A-300kA) | Prevents catastrophic failure |
| Response Time | 0.1ms (fast-acting) to 10s (time-delay) | Matches load characteristics |
| Trip Characteristic Curve | I2t let-through energy rating | Coordinates with upstream devices |
Key industries include: - Consumer Electronics: Mobile devices, home appliances - Automotive: Battery management systems, EV charging circuits - Industrial: Motor drives, PLC systems - Telecommunications: Base station power supplies, data center infrastructure - Renewable Energy: Solar inverters, wind turbine converters
| Manufacturer | Representative Product | Key Features |
|---|---|---|
| Littelfuse | 440 Series Ceramic Fuses | 1000V rating, 300kA breaking capacity |
| Bussmann | FWS-6 Class CC | Time-delay protection for industrial motors |
| TE Connectivity | Mini5Fuse | SMD 5x10mm package for space-constrained designs |
| Mitsubishi Electric | BF Series High-Rupture | 3-phase power system protection |
Key considerations: 1. Match rated current/voltage with circuit parameters 2. Coordinate breaking capacity with system fault levels 3. Select response time per load type (e.g., inrush current in motors) 4. Consider environmental factors (temperature, vibration) 5. Verify regulatory certifications (UL/IEC standards) Example: Selecting a 5x20mm F1A 250V fuse with 1500A breaking capacity for a 120W power supply.
Emerging developments include: - Miniaturization: Sub-2mm SMD fuses for wearable devices - Smart integration: IoT-enabled fuses with real-time monitoring - Material innovation: Biodegradable polymer enclosures - High-voltage specialization: 1500V DC fuses for photovoltaic systems - Hybrid solutions: Combined fuse-circuit breaker architectures