India Advances Towards Low-Carbon Future with Strategic Shift to Hydrogen-Based DRI Production - ResearchAndMarkets.com

DUBLIN--(BUSINESS WIRE)--The "Pathways for a Low-Carbon Technologies for DRI Process in India - A Country Level Analysis: Focus on Hydrogen Production, Storage and Distribution and Technologies to be Integrated in current DRI process" report has been added to ResearchAndMarkets.com's offering.

Transitioning to a Low-Carbon Steel Industry

In a pivotal move to align with global decarbonization efforts, India's steel sector is steadily progressing towards the adoption of low-carbon technological pathways. The focus has now significantly shifted to integrating green hydrogen production within the Direct Reduced Iron (DRI) manufacturing process.

With stringent decarbonization imperatives and governmental mandates, India foresees adopting hydrogen-enriched processes in several pilot and early commercial-scale DRI operations by 2025.

Integrated Hydrogen Production and Infrastructure Development

India aims to escalate the production of green hydrogen, primarily utilizing renewable energy, to serve the large steelmaking clusters spread across the nation. This ambitious plan foresees a comprehensive development of the required infrastructure for hydrogen production, storage, and transportation to ensure that the steel industry's transition to low-carbon DRI production remains seamless and sustainable.

Market Dynamics and Strategic Industry Shifts

The Indian market is witnessing a trend toward hybrid DRI technologies, which will see hydrogen gradually blended with natural gas to lower carbon emissions. This strategy will pave the way for the adoption of 100% hydrogen-based DRI methods as the industry overcomes technical and economic barriers. The commitment to produce net-zero carbon steel is a significant driver of this transformative initiative, reinforcing India's determination to adopt environmentally responsible manufacturing practices.

Challenges and Opportunities

Despite the progress, challenges such as high production costs for hydrogen and the need for substantial infrastructure enhancements may temporarily impede rapid adoption. However, this transition presents substantial opportunities to leverage India's renewable energy potential, creating integrated green steel hubs that offer long-term economic and environmental benefits.

India's strategy to introduce low-carbon technologies in the DRI process signals a new era in the steel industry, where sustainability and innovation coalesce to achieve a greener future. The advancements in hydrogen production, storage, and distribution serve as a testament to India's commitment to reducing emissions and leading in the field of sustainable steel manufacturing.

Key Topics Covered:

1. Markets: Industry Outlook

1.1 Trends: Current and Future Impact Assessment

1.2 Supply Chain Overview

1.3 Regulatory Landscape

1.4 Stakeholder Analysis

1.5 Market Dynamics Overview

1.6 Infrastructure Requirements for Hydrogen storage and Transportation

1.6.1 Current infrastructure

1.6.2 Required Improvements

1.6.3 Hydrogen Production Plants

1.6.3.1 Analysis of Ongoing Production

1.6.3.2 Production Type and Installed Capacities

1.6.3.3 Upcoming Facilities and Key Technologies

1.6.3.4 Key Companies

1.6.3.5 Upcoming Technological Advancements

1.6.4 Companies Operating Compressed Hydrogen Transport Fleet

1.6.5 Hydrogen Refueling Station

1.6.6 Investment Analysis

2. India Hydrogen Storage & Transport Market by Application

2.1 India Hydrogen Storage & Transport Market by Hydrogen Type

2.1.1 Compressed Hydrogen Demand

2.1.2 Liquid Hydrogen

2.1.3 Others

3. India Hydrogen Storage & Transport Market by Products

3.1 India Hydrogen Storage & Transport Market by Compressed Hydrogen

3.1.1 By Storage

3.1.2 By Distribution

4. India Hydrogen Storage & Transport Market by Consumers

4.1.1 Hydrogen Demand Projection

4.1.1.1 Natural gas market in India: Historical and forecasted growth

4.1.1.2 Industries dependent on hydrogen

4.1.1.3 Identifying green hydrogen 'early adopter' sectors

4.1.1.4 Ongoing developments, tie-ups, and pilot projects

4.1.2 Hydrogen Demand by Region

5. Hydrogen and Natural Gas Based DRI Process

5.1 Technologies and Approaches

5.1.1 Commercially Available DRI Technologies

5.1.1.1 MIDREX Process

5.1.1.2 Energiron (Tenova HYL) Process

5.1.1.3 Other Gas-Based DRI Technologies

5.1.2 Hydrogen-Enriched Natural Gas (Blends)

5.1.2.1 Feasibility of H? Blending in Existing Plants

5.1.2.2 Case Studies on Hydrogen Blending

5.1.2.3 Challenges in Gas Composition Management

5.1.3 100% Hydrogen DRI (Green DRI)

5.1.3.1 Reaction Mechanism of Hydrogen Reduction

5.1.3.2 Process Design and Modifications for 100% H? Use

5.1.3.3 Commercial and Pilot-Scale Demonstrations

5.1.4 Emerging Concepts and Pilot Projects

5.1.4.1 HYBRIT (Sweden)

5.1.4.2 ArcelorMittal Hamburg (Germany)

5.1.4.3 SALCOS (Germany)

5.1.4.4 Thyssenkrupp's tkH2Steel Initiative

5.1.4.5 Primetals HYFOR Fluidized-Bed DRI

5.1.4.6 Hydrogen Plasma Smelting (SuSteel - Austria)

5.1.4.7 Other Global Hydrogen DRI Pilots

5.2 Key Process Modifications for Hydrogen Transition

5.2.1 Reforming vs. Direct Hydrogen Reduction

5.2.2 Heat Management in 100% Hydrogen Reduction

5.2.3 Gas Flow and Moisture Control in Hydrogen DRI

5.2.4 Materials and Safety Considerations in Hydrogen Systems

5.2.5 Carbon Content Management in Hydrogen-Based DRI

5.2.6 Iron Ore Quality Considerations

5.3 Comparative Analysis of Natural Gas, Hydrogen Blends, and Pure Hydrogen DRI

5.3.1 Energy Efficiency and CO? Reduction Potential

5.3.2 Technical Feasibility and Implementation Challenges

5.3.3 Economic Viability and Cost Considerations

6. Companies and Technology Providers

6.1 Leading DRI Technology Providers and Their Approaches

6.1.1 Midrex Technologies (Kobe Steel)

6.1.2 Tenova & Danieli (Energiron)

6.1.3 Primetals Technologies (HYFOR & Midrex Licensing)

6.1.4 Metso-Outotec and Circored Fluidized-Bed DRI

6.1.5 Other Global Technology Providers

6.2 Key Players in India's DRI Transition

6.3 Global Companies Not yet Operational in India

7. Regulatory and Economic Aspects

7.1 Regulations and Policies Driving Hydrogen/NG Use in DRI

7.2 Economic Feasibility and Infrastructure Challenges

7.2.1 Hydrogen Cost Analysis

7.2.2 Natural Gas Market and Supply Considerations

7.2.3 Capital Expenditure (Capex) and Investment Requirements

7.2.4 Hydrogen Supply Chain and Infrastructure Needs

7.2.5 Electricity Demand for Hydrogen DRI

7.2.6 Raw Material and Ore Supply Chain Considerations

7.2.7 Operating Costs and By-Product Utilization

7.3 Outlook and Future Trends

7.3.1 Projected Adoption of Hydrogen-Based DRI Worldwide vs India

7.3.2 India's Roadmap for Hydrogen Steelmaking

7.3.3 Technological Advancements in Hydrogen-Based Ironmaking

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