Hydrogen Catalyst
Steam Methane Reforming: The most cost effective process for Hydrogen production.
production roadmap
- Pre-reforming stage to break down heavy hydrocarbon
- Primary Syngas (Hydrogen+CO) generation via Steam methane reforming stage at temperature above 700C to form syngas
- Further hydrogen generation via water-gas shift reaction stage from steam and CO at temperatures below 400C
- Hydrogen concentration increased with removal of CO2 via pressure swing adsorption (carbon capture stage)
- CDTi can provide honeycomb substrate based solution for all stages to maximize hydrogen production performance and reactor foot print
Hydrogen Catalyst
Steam Methane Reforming: The most cost effective process for Hydrogen production.
production roadmap
- Pre-reforming stage to break down heavy hydrocarbon
- Primary Syngas (Hydrogen+CO) generation via Steam methane reforming stage at temperature above 700C to form syngas
- Further hydrogen generation via water-gas shift reaction stage from steam and CO at temperatures below 400C
- Hydrogen concentration increased with removal of CO2 via pressure swing adsorption (carbon capture stage)
CDTi can provide honeycomb substrate based solution for all stages to maximize hydrogen production performance and reactor foot print
VOC Control
Utilizing our unique portfolio of diverse catalytic technology, CDTi provides off the shelf and customs solutions for Catalytic Thermal Oxidizers and other means of VOC control in Industrial applications. Applicable industries include Bakeries, Breweries, Chemical Production, Water/ Soil Remediation, Pharmaceutical and many more. Catalyst formulations include Metal Oxides and Noble Metals.
VOC Control
Utilizing our unique portfolio of diverse catalytic technology, CDTi provides off the shelf and customs solutions for Catalytic Thermal Oxidizers and other means of VOC control in Industrial applications. Applicable industries include Bakeries, Breweries, Chemical Production, Water/ Soil Remediation, Pharmaceutical and many more. Catalyst formulations include Metal Oxides and Noble Metals.
NOx Abatement
Ceramic media with catalyst wash coat has for many years been a preferred method for NOx destruction. CDTi offers non- precious metal formulations with industry leading performance across all temperature ranges. Our patented technology is licensed by global OEM's due to these unique characteristics.
NOx Abatement
Ceramic media with catalyst wash coat has for many years been a preferred method for NOx destruction. CDTi offers non- precious metal formulations with industry leading performance across all temperature ranges. Our patented technology is licensed by global OEM's due to these unique characteristics.
Transition from bead/pellet to honeycomb substrates
Traditional pellet and bead catalysts are heavy, flow restrictive, and are prone to attrition leading to loss of catalyst function and durability all while taking up large volume of the reactor without providing the maximum amount of catalyst surface you can achieve in comparison to currently available technologies.
Automotive industry have already addressed the issue decades ago with use of high surface area substrate commonly referred to as honeycomb substrate.
Honeycomb monolith substrates have replaced the bead based catalytic converters in the automotive industry to take advantage of:
- higher geometric surface area per catalyst volume
- lower flow restriction to gas flow
- resistance to catalyst attrition while in use
| Applications | Substrate Designs | CDTi Solutions |
|---|---|---|
| Industrial reaction (EX: Steam Reforming, Water Gas Shift, etc) | Honeycomb, metallic foam, etc. | |
| Emission treatment (EX: Oven Exhaust, VOC, etc) | Ceramic, metallic, mesh, etc. | |
| Non-catalyst applications (EX: Carbon Capture, Pressure Swing Adsorption, etc) | Application Specific Designs (Flow through, wall flow, etc) |