Carbon Capture, Utilization, and Storage
Green hydrogen visual
Bio Green Hydrogen

Methane pyrolysis and low-carbon hydrogen.

The deck explains how methane pyrolysis creates zero-emission hydrogen while producing valuable carbon byproducts.

Positioning

Bio green hydrogen is framed as an affordable, sustainable route for hydrogen production.

Feedstock base

Sources of methane include biomass and agricultural residue, cattle dung and livestock waste, municipal solid waste, and industrial streams such as press mud and wastewater treatment plants.

Methane pyrolysis

Heating methane to about 1,200°C without oxygen to split it into hydrogen and solid carbon.

Zero CO2 emissions

The process avoids carbon dioxide emissions entirely, unlike grey hydrogen.

Carbon byproducts

Solid carbon black is highlighted as a valuable output for industrial applications.

At a glance

The hydrogen pathway here is defined by a waste-based methane input, a pyrolysis conversion step, and a dual-value output.

Feedstock Methane from biomass and waste
Process Methane pyrolysis at high heat
Output Hydrogen plus valuable carbon
Benefits

Efficiency, zero CO2, and carbon-negative potential.

The deck’s benefits section emphasizes lower energy use, useful carbon outputs, and a carbon intensity pathway that can become negative when biogas is used.

Energy efficient

The deck claims the process requires about 3x less energy than green hydrogen, with potential for 7x efficiency.

Valuable byproducts

Solid carbon black is presented for tires, plastics, coatings, and batteries.

Carbon-negative potential

Using biogas can reduce carbon intensity to -5.22 kg CO2e/kg.

Carbon Credits

Approved methodology and market applications.

The presentation says the methodology has received formal approval from a European registry, giving the project a transparent framework for quantification, monitoring, verification, and premium pricing.

Formal approval

The methodology is described as approved within a reputed European registry.

Market applications

Hydrogen for fuel cells and industrial processes, carbon black for tyres and construction, and carbon removal credits for ESG compliance.

Commercial confidence

The deck says the framework supports corporate buyers, government agencies, and financial institutions.

Process Flow

A vertically integrated route from biomass to markets.

The process combines biomass cultivation, biomethane, methane pyrolysis, digestate treatment, and market placement.

01

Biomass cultivation

Napier grass cultivation through contract farming establishes the feedstock base.

02

Biomethane plant

Anaerobic digestion, biogas production, and purification prepare methane for the next stage.

03

Methane pyrolysis

The reactor produces hydrogen and carbon black with zero direct CO2 emissions.

04

Storage and markets

Type IV hydrogen storage, carbon credits, and byproduct sales complete the revenue story.

Technical Highlights

Production process and compact system data.

The deck includes a production sequence and a schematic with compact footprint, low manpower, and high conversion efficiency.

Methane feed and pressure reduction

Biomethane from local CBG manufacturers is pressure-reduced before entering the reactor.

Heating and reactor operation

The gas is electrically heated to roughly 1080-1120°C, splitting methane into hydrogen and carbon.

Separation and analysis

Carbon is collected and cooled while hydrogen passes through filtration and analysis.

Safety and automation

The system is fully automated with interlocks and remote monitoring.

Schematic notes

Compact, efficient, and scalable.

Footprint

Approximately 2.5m x 2.5m x 6m with low power demand and minimal manpower.

Conversion

Indirect heating fluidized bed reactor, N330 carbon black catalyst, 1000-1100°C, and 1.6-1.8 second reaction time.

Performance

98.5% conversion efficiency, cloud-based IoT integration, full automation, and zero discharge.

Operating note

The deck lists low power usage at 40 KWH and one person per shift for manpower.

Contact

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