LEIPOLE UKK6NB-600/35-95/2X25 Switch Terminal Block 35-95mm² Power Distribution
LEIPOLE UKK6NB-600/35-95/2X25 is a 1-in 2-out heavy-duty terminal block, compatible with 35–95mm² high-current input and 1.5–25mm² output wires. Featuring IP20 protection and CE & RoHS certification, it is widely applied for main line power branching in large-current industrial distribution occasions.
The LEIPOLE UKK6NB-600/35-95/2X25 adopts a one-input two-output shunt structure. It is designed for 35–95mm² super large cross-section main input wire and 1.5–25mm² branch output wire connection. With reinforced structure and excellent large-current conduction capability, it is suitable for main line two-circuit power branching in heavy-duty high-current industrial distribution systems.
Key Features & Advantages
IP20 protection degree for safe indoor electrical cabinet installation
1-in 2-out compact layout, simple structure and space-saving
High-quality conductive body, stable and reliable for super large current transmission
Heavy-duty modular design, easy installation and wiring operation
CE and RoHS certified for international industrial standard compliance
Applications
Low-voltage high-current distribution cabinets and heavy-duty switchgear assemblies
Heavy industry automation control cabinets and complete electromechanical supporting systems
Large mechanical equipment main power inlet line branching and circuit distribution
Industrial parks, large factory workshops high-current main line power distribution projects
Super commercial complexes and public buildings electrical main line shunting
New energy power station, energy storage system high-current power connection and distribution
Large industrial plant electrical renovation, high-power circuit upgrading and expansion
Metallurgy, chemical, environmental protection and heavy manufacturing industry electrical matching
Municipal engineering key infrastructure high-power power distribution supporting projects
Indoor heavy-duty modular control system and high-current two-circuit power distribution scenarios