Batteries/Fuel Cells
In the critical arena of energy storage, the emergence of Direct Atomic Layer Processing (DALP™) technology represents a transformative leap forward. Spearheading advancements in efficiency, capacity, and sustainability, DALP™ technology is reshaping the landscape of energy storage solutions. Its precision engineering and innovative approach to material development are key to addressing the escalating demands of a world transitioning towards renewable energy and sustainable practices. This technology stands at the forefront of revolutionizing energy storage, offering pragmatic, scientifically-grounded solutions pivotal for the future of energy management and environmental stewardship.
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Heavy Wire bonding wire from 100μm to 500μm
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Battery pack wire bonding
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Copper bonding with copper wire
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Coated bonding aluminum coated copper wire
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Insulated bonding insulated wires over soldering
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HB30 Heavy Wire Bonder with automatic Z- & Y- Axis is ideal for Battery Bonding
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Battery cell contacting system
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Contacting BMS/BMB
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Battery cell interconnection
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Voltage sensing
A secondary lithium ion battery consists of an anode, a cathode and an electrolyte (liquid or solid) separating both. While during charging and discharging cycles the electrons are shifted via the outer circuit from anode to cathode and vice versa, the electrolyte allows for the transfer of the ions into the cathode (discharging) or anode (charging). The potential difference between cathode and anode reflects the battery voltage. During this process films on both electrodes are formed at the interface between electrolyte and electrode. This can be beneficial for the stability or accelerate the degradation of the battery. The chemistry and the potentials can be characterized pretty well with (NAP)-XPS and HAXPES.
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Excellent seal ability with long lifespan
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Patented moisture and oxygen protective devices
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Strong resistance to organic solvents
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Can integrate with different vacuum heating/drying technologies
Manipulating or modification of materials at the nanoscale by thermal energy allows for the removal, conversion, and/or addition of matter at the nanoscale. By having access to high temperatures and GPa pressures, the world of material science possibilities is limited only by one’s imagination. From direct sublimation of organic materials to the nanocutting of transition metal dichalcogenides, NanoFrazor enables science at the cutting edge.