8 results ·
● Live web index
P
pdf.wri.org
article
http://pdf.wri.org/ccs_guidelines.pdf
C C S G U I D E L I N E S 5 TABLE OF CONTENTS EXECUTIVE SUMMARY 8 GUIDELINES 12 Part 1 Introduction 19 Part 2 Capture 23 2.1 INTRODUCTION 23 2.2 TECHNOLOGY OVERVIEW 24 2.2.1 Capture from Power Plants 25 2.2.1.1 Post-Combustion Capture 27 2.2.1.2 Pre-Combustion Capture 28 2.2.1.3 Oxy-Fuel Combustion 28 2.2.2 Capture from Industrial Sources 29 2.2.3 Capture Economics 31 2.2.4 Managing Carbon Dioxide and Co-Constituents 32 Capture Guideline 1: Recommended Guidelines for CO2 Capture 35 2.3 NON-CO2 ENVIRONMENTAL IMPACTS 35 2.3.1 Air Emissions 37 2.3.1.1 New Source Performance Standards and New Source Review 38 2.3.2 Water Use 39 2.3.3 Solid Waste 40 Capture Guideline 2: Recommended Guidelines for Ancillary Environmental Impacts from CO2 40 Part 3 Transport 41 3.1 INTRODUCTION 41 3.1.1 Developing CO2 Pipeline Infrastructure for CCS 42 3.1.2 CO2 Pipeline Operating Experience 42 3.2 PIPELINE DESIGN AND OPERATIONS 43 3.2.1 Pipeline CO2 Composition 43 3.2.2 Pipeline Operating Temperature and Pressure 44 3.2.3 Pipeline Design 45 Transport Guideline 1: Recommended Guidelines for Pipeline Design and Operation 47 C C S G U I D E L I N E S 6 3.3 PIPELINE SAFETY AND INTEGRITY 47 3.3.1 Pipeline Safety Regulations 47 3.3.2 Comparative Safety of CO2 Pipelines 47 3.3.3 Environmental Health and Safety 47 3.3.4 Addressing Potential Public and Environmental Concerns 48 Transport Guideline 2: Recommended Guidelines for Pipeline Safety and Integrity 48 3.4 CO2 PIPELINE SITING REGULATION 49 3.4.1 Siting of CO2 Pipelines 49 Transport Guideline 3: Recommended Guidelines for Siting CO2 Pipelines 50 3.5 PIPELINE ACCESS AND TARIFF REGULATION 51 Transport Guideline 4: Recommended Guidelines for Pipeline Access and Tariff Regulation 52 Part 4 Storage 53 4.1 INTRODUCTION 53 4.1.1 Terminology 53 4.1.2 Organization of the Storage Guidelines 54 4.1.3 Carbon Storage Performance Expectations 54 4.1.4 Implications of Potential Deployment Pathways 55 4.1.4.1 CO2 Sources 56 4.1.4.2 CO2 Transport 56 4.1.4.3 Reservoir Types and Project Sizes 56 4.1.5 Identification of
L
library.ctr.utexas.edu
research
https://library.ctr.utexas.edu/ctr-publications/0-7231-p1.pdf
25 4 Executive Summary This report provides guidance to the Texas Department of Transportation (TxDOT) on the potential implementation of Carbon Capture, Utilization, and Storage (CCUS) technologies in transportation infrastructure projects. Table 1: Overview of companies providing active or emerging CCUS capabilities to organizations within Texas Company Technology Focus Texas Presence/Projects CarbonCure Technologies CO₂ mineralization in concrete Active in Austin and Matagorda Blue Planet Systems CO₂-to-aggregate synthetic limestone Exploring U.S. infrastructure pilots; no public Texas site yet Solidia Technologies CO₂-cured concrete Has demonstrated interest in working with DOTs; no TX deployment confirmed Heirloom Carbon Direct air capture (DAC) Partner in DAC hubs in Texas (with 1PointFive) 1PointFive (Oxy Low Carbon Ventures) DAC and storage Operator of South Texas DAC Hub; major player in carbon storage infrastructure Svante Point-source solid sorbent capture Pilot project carbon capture plant in Texas announced in 2024 Legend 13 2.3. In summary, while these transport and storage projects are not explicitly designed for TxDOT or infrastructure-related carbon capture, they are foundational to enabling CCUS across the construction materials supply chain.
D
downloads.regulations.gov
official
https://downloads.regulations.gov/EPA-HQ-OAR-2025-0124-0041/attachment_4.pdf
Please refer to the following chapters for responses specific to those issues: • Chapter 1: General Background • Chapter 2: Legal Issues • Chapter 3: Consideration of Costs • Chapter 4: Carbon Capture, Transportation, and Sequestration/Storage • Chapter 5: Hydrogen Co-firing / Blending • Chapter 6: Natural Gas Co-firing • Chapter 7: Standards for New Gas-fired Combustion Turbines • Chapter 8: Emission Guidelines for Existing Fossil Fuel-fired Steam EGUs • Chapter 9: Emission Guidelines for Existing Fossil Fuel-fired Combustion Turbines • Chapter 10: Applicability Requirements • Chapter 11: State Plans • Chapter 12: ACE Rule Repeal • Chapter 13: Statutory and Executive Orders • Chapter 14: Regulatory Impact Analysis • Chapter 15: Rule Text • Chapter 16: Other Topics ii CHAPTER 4 – CARBON CAPTURE, TRANSPORTATION, AND SEQUESTRATION/STORAGE Table of Contents CHAPTER 4 – CCS: Carbon Capture, Transportation, and Sequestration/Storage ............1 4.1 CCS - Adequately Demonstrated ....................................................................................3 4.1.1 CCS General Statements ....................................................................................
N
netl.doe.gov
official
https://netl.doe.gov/carbon-capture/industrial
Furthermore, NETL is addressing challenges with the application of carbon capture, utilization and storage (CCUS) to steam methane reforming (SMR) and
E
eenews.net
news
https://www.eenews.net/articles/the-complete-guide-to-ccs-and-the-epa-power-p…
CCS typically refers to technology that grabs carbon dioxide from a power plant or industrial emitter and then stores the gas underground. He and others point to the long use of CCS in industries like fertilizer production and natural gas processing, where it is cheaper to capture carbon than in a power plant. New gas plants with CCS technology licensed by Net Power LLC, which has pitched itself as the “McDonald’s of power generation,” will come modularized, said Danny Rice, the incoming CEO of the company, in an interview. “EPA must consider that over 70% of captured carbon from CCS projects is used to extract more fossil fuels [through] EOR, a process that perpetuates fossil fuel use and in turn, adds to the climate crisis,” Victoria Bogdan Tejeda, an attorney with the Center for Biological Diversity, said in comments on the EPA rule.
P
pubs.acs.org
article
https://pubs.acs.org/doi/10.1021/acs.est.4c05484
We present methods and insights for the design of CO 2 capture, transport, and storage systems for industrial facilities with a case study focus on Louisiana.
C
carboncaptureready.betterenergy.org
article
https://carboncaptureready.betterenergy.org/wp-content/uploads/2024/05/TX_202…
• There are 683 eligible facilities in Texas for the 45Q tax credit, with the potential ability to capture nearly 334 million metric tons of CO2 annually if retrofitted with carbon capture technology. Sector Annual Emissions 12,500 tCO2 13.2 MtCO2 05 0 100 mi CAPTURE AND STORAGE POTENTIAL As the state with the highest emissions in the nation, Texas has immense potential to build on its established leadership in the carbon capture field and expand its use of carbon management technologies to reduce emissions.
S
sciencedirect.com
article
https://www.sciencedirect.com/science/article/pii/S2214629623002748
We describe six general principles to guide the development of large-scale commercial CCS infrastructure to bridge the reduction gap by capitalizing on these