Electrical, Specialty Fuses

Part Number	Description / PDF	Quantity
0LMF001.U Wickmann / Littelfuse	FUSE CARTRIDGE 1A 300VAC	0
KLKD006.H Wickmann / Littelfuse	FUSE CARTRIDGE 6A 600VAC/VDC	0
0LDC1800X Wickmann / Littelfuse	FUSE CARTRIDGE 1.8KA 600VAC/VDC	0
0CNN125E.V Wickmann / Littelfuse	FUSE STRP 125A 125VAC/80VDC BOLT	10
0BLF006.T Wickmann / Littelfuse	FUSE CARTRIDGE 6A 250VAC 5AG	0
PSR072FS0400Z Wickmann / Littelfuse	FUSE SQUARE 400A 1.3KVAC/1KVDC	4
KLDR01.6TXP Wickmann / Littelfuse	FUSE CRTRDGE 1.6A 600VAC/300VDC	0
PSR071UL0350Z Wickmann / Littelfuse	FUSE SQUARE 350A 1.3KVAC/1KVDC	3
0LDC800.X Wickmann / Littelfuse	FUSE CARTRIDGE 800A 600VAC/VDC	0
L15S020.T Wickmann / Littelfuse	FUSE CRTRDGE 20A 150VAC/VDC 5AG	0
PSR031DL0630Z Wickmann / Littelfuse	FUSE SQUARE 630A 700VAC/600VDC	2
SPXV010.L Wickmann / Littelfuse	FUSE CARTRIDGE 10A 1.5KVDC	150
CCMR035.T Wickmann / Littelfuse	FUSE CARTRIDGE 35A 600VAC/250VDC	2
0305.250M Wickmann / Littelfuse	FUSE BRD MNT 250MA 277VAC/VDC	0
L70QS700.X Wickmann / Littelfuse	FUSE CRTRDGE 700A 700VAC/700VDC	0
KLKR003.T Wickmann / Littelfuse	FUSE CARTRIDGE 3A 600VAC/300VDC	1250
KLKD03.5T Wickmann / Littelfuse	FUSE CARTRIDGE 3.5A 600VAC/VDC	640
FLNR500.X Wickmann / Littelfuse	FUSE CRTRDGE 500A 250VAC/125VDC	0
0SPF006.H Wickmann / Littelfuse	FUSE CARTRIDGE 6A 1KVDC 5AG	0
0LMF008.H Wickmann / Littelfuse	FUSE CARTRIDGE 8A 300VAC	0

Electrical, Specialty Fuses

1. Overview

Specialty fuses are precision-engineered circuit protection devices designed to safeguard electrical systems under specific abnormal conditions. Unlike general-purpose fuses, these devices offer tailored performance characteristics for specialized applications, including fast response times, high current interruption capabilities, and environmental resistance. Their importance in modern technology stems from their ability to protect sensitive electronics in critical systems such as medical devices, aerospace equipment, and renewable energy systems.

2. Main Types & Functional Classification

Type	Functional Features	Application Examples
Current-limiting Fuses	Interrupt fault currents within milliseconds using special fillers	Industrial motor drives, power distribution panels
Semiconductor Fuses	Maintain I2t values below 10A s for sensitive component protection	Variable frequency drives, battery management systems
Resettable Fuses (PTC)	Automatically reset after fault clearance	Consumer electronics, automotive circuits
High-voltage Fuses	Rated above 1kV with arc suppression technology	EV charging stations, grid-tied solar inverters
Time-delay Fuses	Withstand temporary current surges without tripping	Compressors, transformers, medical imaging equipment

3. Structure & Composition

Typical construction includes: - Ceramic or glass reinforced polymer housing - Silver-plated copper/zinc alloy contacts - Specialized fuse element with controlled melting points - Arc quenching materials (e.g., silica sand) - Temperature-compensated mechanical linkages

4. Key Technical Parameters

Parameter	Importance	Typical Range
Voltage Rating	Defines maximum operating voltage	32V-15kV
Current Rating	Determines normal operation threshold	0.1A-2000A
Response Time	Time to interrupt fault current	1ms-10s
I2t Let-through	Energy withstand capability	10-1000A s
Ambient Temperature Range	Operational environmental limits	-55 C to +125 C

5. Application Fields

Primary industries include: - Industrial automation (PLC systems, CNC machines) - Automotive (EV battery protection, ADAS systems) - Renewable energy (solar inverters, wind turbine controls) - Medical equipment (MRI scanners, patient monitors) - Telecommunications (base stations, data center UPS)

6. Leading Manufacturers & Products

Manufacturer	Representative Product	Key Features
Littelfuse	SSL Series	Surface-mount PTC for automotive applications
Bussmann	170M Series	Current-limiting semiconductor fuse
Eaton	XLP Plus	High-performance current-limiting fuse
TE Connectivity	Mini29	Compact automotive blade fuse

7. Selection Guidelines

Key considerations: 1. Determine circuit voltage/current requirements 2. Analyze fault current characteristics 3. Consider environmental factors (temperature, vibration) 4. Verify compliance with standards (UL/IEC) 5. Evaluate replacement accessibility 6. Calculate required breaking capacity

8. Industry Trends

Emerging developments: - Graphene-enhanced PTC materials for faster response - Integration with IoT-enabled condition monitoring - Miniaturization for 5G infrastructure applications - Environmental compliance with RoHS/REACH standards - Development of hybrid fuse-circuit breaker devices - Increased adoption in EV battery management systems