AI is moving from data centers into the physical world. Drones, satellites, robots, electric aircraft, defense systems, and distributed data infrastructure all need energy systems that are safe, compact, intelligent, and certifiable. KULR brings its energy and power platform to the markets where power density, safety, reliability, and thermal control are mission-critical — and the same integrated platform underlies all five, so engineering compounds across them.
Space and defense are the reference standards for KULR's platform. These are environments where batteries must operate through thermal extremes, vibration, radiation, and qualification requirements that leave little margin for failure. The discipline required to serve them informs the rest of the platform: battery architecture, thermal safety, propagation resistance, and reliability engineering developed here become proof points for every other market KULR serves.
KULR ONE Space was selected to power NARA Space's payload flying aboard NASA's Artemis II mission — the first crewed Artemis flight around the Moon. The deployment validates KULR's battery architecture in deep-space crewed environments where thermal performance and safety margin are non-negotiable.
Discuss a Space or Defense Program →KULR is powering the ARGO Space mission with its flight-qualified battery platform, extending its space heritage to commercial orbital applications. Each mission qualification datapoint strengthens KULR's standing as the reference energy architecture for space robotics and autonomous platforms.
Discuss a Space or Defense Program →The Low Altitude Economy is the expanding class of drones, UAVs, and unmanned systems operating below roughly 1,000 meters across defense, counter-drone, logistics, agriculture, inspection, public safety, and electric aviation. Every aircraft in this market is, at its core, a battery-powered flying computer: it must carry compute, sensors, communications, and energy in a compact, lightweight system that delivers high power safely across the full mission profile.
Bank of America projects the Low Altitude Economy to exceed $200 billion globally by 2045, and 2026 is an inflection year as NDAA-compliant US drone supply becomes a national priority. KULR ONE Air is built for that environment, combining high-performance battery architecture, thermal safety, and scalable manufacturing for UAV and UAM applications, with KULR VIBE adding rotor vibration mitigation for rotorcraft and electric aviation.
Discuss a UAV or Drone Program →AI compute is moving into two environments with a shared power problem. On the ground, inference is moving closer to where data is generated — telecom facilities, commercial real estate, edge sites, and distributed infrastructure. In orbit, AI infrastructure will rely on autonomous systems that operate, inspect, repair, and remain powered without technician access. In both, compute depends on energy systems engineered for power density, safety, and reliability.
The global AI inference market is projected to exceed $255 billion by 2030, and a growing share of that compute is moving to the edge, closer to the data and the load. KULR ONE MAX is designed for high-power, propagation-resistant battery backup at the rack and the edge, supported by KULR's thermal-management and safety heritage.
Discuss an Edge or AI Data Center Deployment →Telecom and distributed-infrastructure operators need reliable DC backup power without the capital burden, lifecycle risk, and operational overhead of owning and maintaining battery systems themselves. KULR's Energy as a Service model delivers mission-critical DC power as a managed service: KULR provides the battery systems, safety architecture, monitoring, and lifecycle management, and the operator pays for guaranteed power rather than hardware.
The Energy as a Service model lowers operational burden, provides clearer lifecycle planning, delivers performance accountability, and offers a managed pathway from lead-acid to lithium-ion infrastructure — so operators can plan around guaranteed power rather than managing battery assets themselves.
Discuss an Energy as a Service Engagement →Robotics is physical AI in motion. Unlike software-only AI, robots must carry their own intelligence and their own energy. They must deliver burst power for dynamic movement, manage heat inside compact enclosures, operate safely around people, and stay reliable through repeated physical interaction with the world. That makes the energy system one of the defining layers of robotics performance.
McKinsey projects the general-purpose robotics market to grow from under $1 billion in 2025 to roughly $370 billion by 2040, with Japan targeting approximately 30% of the global market by that year. McKinsey's supply-chain analysis identifies battery packs and thermal / cooling systems as part of the humanoid hardware stack, with differentiation moving toward pack architecture, thermal behavior, uptime strategy, and safety — the architecture layer, not the cell.
KULR's role sits at that architecture layer: integrating advanced cells, pack design, thermal management, safety engineering, and battery intelligence into complete systems for demanding robotic applications. Robots need compact, high-power energy; battery safety matters because they operate near people; thermal control is critical in enclosed, mobile platforms; and the BMS can become a natural intelligence layer for monitoring, diagnostics, and predictive maintenance.
Discuss a Robotics Power Program →The same integrated platform underlies all five markets, so engineering compounds across them.