Bio-Propane: Difference between revisions
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*The paper used a Chromium-Zinc Catalyst on a β-Zeolite Catalyst, which is luckily not too rare (ie no rare earth metals etc) | *The paper used a Chromium-Zinc Catalyst on a β-Zeolite Catalyst, which is luckily not too rare (ie no rare earth metals etc) | ||
= | =Internal Links= | ||
* | *[[EForFuel]] | ||
**A Project using [[P2X]] Technology and [[Formic Acid]] Fed [[Precision Fermentation]] to make Bio-Butane, with a goal of usage as [[Autogas]] | |||
*[[DME]] / [[DME Blending]] / [[DME-Propane Blending]] | |||
**While NOT the same, the similar storage conditions have lead some propane groups to propose blending DME into the propane as a means to reduce the [[Carbon Intensity]] of the fuel | |||
*[[Propane Storage Architecture]] | |||
= | =External Links= | ||
* | *[https://www.alkcon.com/biopropane/ Alkconn - Biopropane - ‘’Proprietary’’ Catalytic Methane->Propane Conversion] | ||
[[Category:Biofuel]] | [[Category:Biofuel]] [[Category: Bio-Petrochemistry]] | ||
Latest revision as of 02:33, 12 January 2026
Basics
- Difficult to do from a methane upgrading route, but this paper shows it is possible
- The paper used a Chromium-Zinc Catalyst on a β-Zeolite Catalyst, which is luckily not too rare (ie no rare earth metals etc)
Internal Links
- EForFuel
- A Project using P2X Technology and Formic Acid Fed Precision Fermentation to make Bio-Butane, with a goal of usage as Autogas
- DME / DME Blending / DME-Propane Blending
- While NOT the same, the similar storage conditions have lead some propane groups to propose blending DME into the propane as a means to reduce the Carbon Intensity of the fuel
- Propane Storage Architecture