Discover how the new Cell Impact and thyssenkrupp collaboration accelerates cost-efficient flow plate production, driving industrial decarbonization and unlocking key opportunities for hydrogen and sustainable aviation investors.
The Big Picture: Why This Fuel Cell Manufacturing News Matters
On November 6, 2025, Cell Impact AB and thyssenkrupp Automation Engineering sealed a strategic cooperation agreement in Karlskoga, Sweden, marking a pivotal moment for the scalable manufacturing of fuel cell components. This alliance merges Cell Impact’s breakthrough Cell Impact Forming™ technology with thyssenkrupp’s high-precision automation expertise, setting a new standard in the rapid, green production of flow plates essential to fuel cells and electrolyzers.
This is not just incremental progress; it represents a decisive push toward resolving the major cost and scalability challenges hindering global green hydrogen adoption. Governments and industries worldwide are under mounting pressure to meet ambitious carbon reduction targets, positioning hydrogen as a versatile, clean energy carrier and industrial feedstock. Investments exceeding $50 billion in clean hydrogen last year reflect the urgency and scale of this transition, fueled by heavy incentives like Europe’s REPowerEU and the U.S. Inflation Reduction Act.
Yet to reach landmark targets such as 10 million tons of green hydrogen annually by 2030, production costs must be drastically lowered—immediately—and this partnership addresses exactly that.
How This Trend Is Shaping the Future of Urban Air Mobility and Advanced Air Mobility
Advanced air mobility and urban air mobility platforms are increasingly exploring hydrogen fuel cells to power next-generation zero-emission aircraft such as eVTOLs. By enabling mass production of highly efficient flow plates, Cell Impact and thyssenkrupp’s innovation indirectly supports the wider adoption of hydrogen propulsion systems integral to the future of air mobility.
Cell Impact Forming™ distinguishes itself from traditional manufacturing methods of flow plates—such as etching, laser cutting, or CNC milling—that involve high energy consumption, wasteful scrap, and environmental concerns like acid waste. It offers millisecond-scale metal forming that achieves precise channel geometries instantly, eliminating post-processing, water usage, and reducing energy footprint, thus addressing key sustainability goals while ensuring laser-like quality and reducing scrap rates.
In combination with thyssenkrupp’s sophisticated automation systems including robotic handling, inline inspection, and accelerated assembly, this partnership can transition quickly from pilot phases to high-volume industrial runs, ensuring constant quality and scalable supply for electrolyzers and fuel cell stacks used in hydrogen-powered aircraft, vehicles, and infrastructure.
Where Smart Capital Is Moving in the eVTOL and Hydrogen Integration Space
Investor interest is accelerating as hydrogen technologies become critical enablers for decarbonizing heavy industry and transportation sectors. Cost-effective manufacturing innovations such as this Cell Impact and thyssenkrupp collaboration attract venture capital and corporate investment focused on next-generation clean energy value chains.
With substantial clean energy incentives active worldwide and industrial players seeking to transition steel mills, glass factories, chemical plants, and transportation fleets to zero-emission energy sources, vertically integrated hydrogen supply chains will command significant growth. This investment thesis extends well into the realm of eVTOL investment, where hydrogen fuel cells serve as high-potential propulsion alternatives to batteries, mitigating range and charging limitations on electric aviation.
Investors can see immediate value in startups and scale-ups that combine mechanical innovation with automated production lines to speed commercialization and reduce capex for electrolyzer and fuel cell components. The partnership’s focus on joint R&D, rapid prototyping, and digital twin technologies exemplifies efficient risk reduction and iterative development favored by savvy early-stage investors.
How HPS Aviation Fits into the Next Wave of Air Mobility and Hydrogen Propulsion
HPS Aviation emerges as a deep-tech aerospace startup complementing this manufacturing leap by focusing on disruptive hydrogen and electric propulsion systems engineered for regional and urban air mobility platforms. Just as Cell Impact and thyssenkrupp revolutionize fuel cell component scalability, HPS Aviation is developing next-generation propulsion technologies that promise to transform eVTOL aircraft efficiency, reliability, and sustainability.
Drawing on advances in hydrogen fuel cell integration, lightweight designs, and scalable production readiness, HPS Aviation’s technology roadmap aligns with the industrial ecosystem benefits unlocked by innovations like Cell Impact Forming™. Prospective investors interested in broad exposure to the hydrogen-powered sustainable aviation sector will find HPS Aviation’s startup proposition compelling as it advances commercialization and certification pathways for cutting-edge propulsion platforms.
As outlined on hpsaviation.com, their approach integrates advanced materials science, modular architecture, and high-efficiency energy conversion suitable for various eVTOL configurations, signaling a strong synergy with upstream component manufacturers innovating to lower supply chain costs and increase reliability.
Key Risks, Timelines, and What Serious Investors Should Watch
While promising, the path to full-scale hydrogen and fuel cell deployment in aviation and industrial decarbonization is not without risks. Key considerations include volatility in raw material costs, especially specialty metals critical to flow plate production; supply chain constraints that could delay mass manufacturing; and the necessity for rigorous validation and certification processes as production scales to millions of units.
The Cell Impact–thyssenkrupp partnership’s adoption of digital twins and robust quality control protocols helps mitigate downtime and maintain standards, yet market and technological uncertainties remain. Likewise, startups like HPS Aviation face technological, regulatory, and infrastructure challenges in bringing hydrogen propulsion systems to market, requiring careful technology de-risking and investment timing to capture value.
Investors should monitor milestone achievements in pilot production runs, certification progress, and strategic partnerships that accelerate commercialization. Staying informed about policy shifts affecting green hydrogen subsidies and infrastructure rollouts is equally vital.
For investors looking at the hydrogen value chain’s broad implications—from component manufacturing to full stack assembly and propulsion system development—this period represents a decisive window for high-impact, early-stage investments with potential long-term payoffs in advanced air mobility and beyond.
Next Steps for Investors
To explore how innovations like the Cell Impact and thyssenkrupp strategic cooperation are shaping the hydrogen economy and next-generation propulsion, visit https://hpsaviation.com, where you can dive deep into the technology, roadmap, and vision of HPS Aviation.
Stay informed by following HPS Aviation’s official LinkedIn page here: https://www.linkedin.com/company/hps-aviation for real-time updates on breakthroughs and eVTOL investment opportunities.
If you are an investor eager to participate in the hydrogen-powered eVTOL revolution and the broader future of air mobility, start a serious conversation by submitting your details via HPS Aviation’s investment gateway: https://portal.hpsaviation.net/investor-form/new.
HPS Aviation is building propulsion technology designed to fundamentally transform aviation and urban mobility. Early-stage investors can now engage directly through the “Invest with us” platform to support this exciting transition to a green hydrogen-powered future.
Ready to join our journey? invest with us.
Leave a Reply