Hovogen offers comprehensive integrated solutions that include teams, technology, and equipment for Sinopec. They manufacture large-scale electrolysis hydrogen production systems, which were utilized in hydrogen refueling stations during the Beijing Winter Olympics.

Hovogen has supplied a customized 5-cubic meter hydrogen production unit to Tripod Nano Tech in Taiwan through OEM. This system is designed for their semiconductor production line, providing a reliable source of high-purity hydrogen essential for manufacturing processes, thereby enhancing efficiency and quality in semiconductor fabrication.

Xian Jiaotong University and Gree Electric are collaborating on a small-scale off-grid solar hydrogen project. This initiative uses solar energy to power an electrolyzer, producing hydrogen from water and promoting sustainable energy solutions for remote areas.

On-site hydrogen production system for a factory, significantly reducing gas costs compared to purchasing bottled hydrogen. This on-demand H2 production system enhances efficiency and lowers operational expenses. It features real-time remote monitoring, improving safety and operational effectiveness for the enterprise.

Focuses on the development of PEM technology for hydrogen production, specifically for use in fuel cells. The initiative aims to enhance the efficiency of hydrogen generation while ensuring high purity levels suitable for fuel cell applications. By leveraging PEM technology, the project seeks to promote clean energy solutions and support the broader adoption of hydrogen fuel cells in various industries.

Project focuses on providing an on-site hydrogen supply system for the chemical vapor deposition (CVD) diamond manufacturing process. By ensuring a reliable and efficient hydrogen source, the project aims to enhance the quality and consistency of CVD diamond production. This approach not only improves operational efficiency but also reduces costs associated with hydrogen transportation and storage.

This project focuses on developing a large-scale on-site hydrogen production system with a capacity of 5 Nm³. It is designed for efficient integration with the factory's existing hydrogen production line, ensuring seamless operation and enhanced productivity. By implementing this system, the project aims to provide a reliable hydrogen supply, reduce costs, and promote sustainable energy practices while optimizing the overall production process.

The MOCVD (Metal-Organic Chemical Vapor Deposition) Ultra-Pure Hydrogen Supply Project focuses on providing high-purity hydrogen (99.999%) to support MOCVD processes in semiconductor and materials research. This project is essential for ensuring the quality and reliability of thin film deposition, which is critical for the fabrication of advanced electronic devices. 

The project combines 500 kW PV power, a 50 Nm³/h PEM electrolyzer, and a 250 kW/500 kWh battery storage system to meet an R&D center's energy needs. The system converts solar energy into hydrogen via electrolysis, stores it, and generates electricity using PEM fuel cells. Excess energy is stored for nighttime or peak use, solving local PV grid integration challenges and providing a sustainable energy solution.

The SAF synthesis process demonstration research project at East China Normal University employs Hovogen's hydrogen production equipment to advance sustainable aviation fuel development. Utilizing efficient water electrolysis, the system generates high-purity hydrogen, which is integrated with renewable energy sources to significantly reduce carbon emissions. This innovative approach not only enhances production efficiency but also supports the aviation industry's transition towards sustainability.

Our company has provided a complete set of hydrogen production and pressurization equipment for a university project focused on renewable energy research. The hydrogen will be utilized in fuel cell experiments and energy storage studies, enabling researchers to explore innovative solutions for sustainable energy. 

Xian Jiaotong University is developing a project that combines PEM hydrogen production with electrochemical pressurization. This approach efficiently splits water into hydrogen and oxygen while increasing hydrogen pressure, enhancing production efficiency and promoting renewable energy solutions.

Sinopec is conducting a research project on integrated hydrogen production and storage equipment. The project aims to develop an efficient system that combines hydrogen production, storage, and transportation technologies. This innovative approach enhances the utilization efficiency and safety of hydrogen energy, supporting the commercialization of hydrogen and the development of renewable energy.

 We provide customized hydrogen production equipment with a capacity of 10Nm³ for our clients in the United States. This solution is optimized based on the specific requirements of the client's project, ensuring that the equipment operates smoothly and safely in their environment.

This project focuses on the application of ultra-pure hydrogen with a purity of 99.99999% in materials laboratories. The high purity level is crucial for various experimental processes, ensuring accurate results and preventing contamination. This project aims to enhance research capabilities in material science, particularly in areas requiring precise chemical reactions and analyses.

The project aims to provide stable and ultra-pure hydrogen (99.999%) to research institutions, enhancing their capabilities in material science and chemical engineering. By integrating solid oxide fuel cell (SOFC) technology, this project supports high-precision experiments and fosters innovation in the development of new materials and clean energy solutions. 

10Nm³ Multi-Energy Complementary Wind-Solar Power Demonstration Project combines wind and solar energy systems to create a synergistic power generation model. By leveraging the complementary nature of wind and solar resources, the project ensures a more stable and efficient energy supply, addressing intermittency challenges. 

This project produces 1000 Nm³/h of hydrogen using off-grid wind power. Wind turbines generate electricity to power electrolyzers, splitting water into hydrogen and oxygen. The hydrogen can be stored for use in vehicles, industry, or energy storage. The off-grid design ensures energy independence and sustainability.