Improved cost models for optimizing CO2 pipeline configuration for point-to-point pipelines and simple networks

a b s t r a c t In this study, a new cost model is developed for CO2 pipeline transport, which starts with the physical properties of CO2 transport and includes different kinds of steel grades and up-to-date material and con- struction costs. This pipeline cost model is used for a new developed tool to determine the configuration leading to the lowest levelized costs for CO2 transport, for point-to-point pipelines as well as for simple networks on different types of terrain and for different time frames. The model optimizes inlet pressure, diameter, steel grade and number of pumping stations. Results show that gaseous CO2 transport can give lower levelized costs than liquid CO2 transport for point-to-point pipelines and for simple networks, if the CO2 is stored in a reservoir with a low required injection pressure, like depleted natural gas fields. However, for storage fields with a required injec- tion pressure of 8 MPa or higher (like aquifers), CO2 can be better transported in a liquid form. For onshore pipelines transporting liquid CO2, the optimal inlet pressure is 9-13 MPa and pumping sta- tions are installed roughly every 50-100 km. For offshore pipelines, pumping stations are not an option and the inlet pressure is determined by the length of the pipeline. The maximum inlet pressure is about 25 MPa and for even longer pipelines, a larger diameter is selected. The levelized costs (excluding initial compression) for transporting 100 kg/s (about 3 Mt/y) over 100 km are between 1.8 and 3.3D /t for liquid and 4.0-6.4D /t for gaseous CO2 transport. For larger mass flows the costs are decreasing, for instance transporting 200 kg/s (about 6 Mt/y) over 100 km are 1.2-1.8D /t for liquid and 3.0-3.8D /t for gaseous CO2 transport. Furthermore, results show that higher steel grades lead to lower investment costs for onshore pipelines transporting liquid CO2. Using X120 in the long term reduces the pipeline costs up to 17%. For gaseous CO2 transport, lower steel grades (like X42 and X52) are the best option. Also offshore pipelines do not benefit from the development of higher steel grades over time because the thickness should be at least 2.5% of the outer diameter. The results indicate that oversizing the pipeline, to transport CO2 from an additional source that is coming available later, is not always cost-attractive. This strongly depends on the time span of which further CO2 sources are available and on the mass flows. Oversizing appears earlier cost-attractive com- pared to two point-to-point pipelines if the source with the largest mass flow becomes available first.

[1]  Warren R. True 2003: Processing outside North America nearly grabs the lead , 2004 .

[2]  Eric Williams,et al.  Potential economies of scale in CO2 transport through use of a trunk pipeline , 2010 .

[3]  Feridun Esmaeilzadeh Simulation examines ice, hydrate formation in Iran separator centers , 2006 .

[4]  Otto Skovholt Co2 transportation system , 1993 .

[5]  Bahman ZareNezhad New correlation predicts flue gas sulfuric acid dewpoints , 2009 .

[6]  Jeannie Stell Catalyst prices, demand on the rise , 2005 .

[7]  M. Thring World Energy Outlook , 1977 .

[8]  Warren R. True,et al.  US pieline companies solidly profitable in 2002, scale back construction plans , 2003 .

[9]  Andrea Ramírez,et al.  Comparative assessment of CO2 capture technologies for carbon-intensive industrial processes , 2012 .

[10]  Dianne E. Wiley,et al.  Steady-state design of CO2 pipeline networks for minimal cost per tonne of CO2 avoided , 2012 .

[11]  Mike Sumrow Harsh environments, emerging technologies, organizational capacity to shape future of drilling , 2002 .

[12]  P. Cayrade Investments in Gas Pipelines and LNG Infrastructure: What impact on the security of supply? INDES Working Paper No. 3, 1 March 2004 , 2004 .

[13]  C. M. Spinelli Full Scale Investigation on Strain Capacity of High Grade Large Diameter Pipes , 2011 .

[14]  Kim Johnsen,et al.  DNV recommended practice: Design and operation of CO2 pipelines , 2011 .

[15]  Christopher E. Smith,et al.  Natural gas pipelines continue growth despite lower earnings; oil profits grow , 2010 .

[16]  Danièle Revel,et al.  IPCC Special Report on Renewable Energy Sources and Climate Change Mitigation , 2011 .

[17]  Us Congress,et al.  Title 49 - Transportation , 2014 .

[18]  Ivan S. Cole,et al.  Corrosion of pipelines used for CO2 transport in CCS: Is it a real problem? , 2011 .

[19]  Mo Mohitpour,et al.  Pipeline Transportation of Carbon Dioxide Containing Impurities , 2012 .

[20]  Li Zheng,et al.  Economic evaluation of CO2 pipeline transport in China , 2012 .

[21]  Robert H. Williams,et al.  Fischer-Tropsch Fuels from Coal and Biomass , 2008 .

[22]  Christopher E. Smith US oil carriers' 2006 net incomes rebound; or increases push up construction costs , 2007 .

[23]  Simon Bonini Is LNG a global commodity...yet , 2011 .

[24]  Rajesh J. Pawar,et al.  A dynamic model for optimally phasing in CO2 capture and storage infrastructure , 2012, Environ. Model. Softw..

[25]  R. Williams,et al.  Co-production of hydrogen, electricity and CO2 from coal with commercially ready technology. Part B: Economic analysis , 2005 .

[26]  Andrea Ramírez,et al.  Performance of simulated flexible integrated gasification polygeneration facilities, Part B: Economic evaluation. , 2012 .

[27]  K. A. Niederhoff,et al.  High-strength Large-diameter Pipe For Long-distance High-pressure Gas Pipelines , 2003 .

[28]  W. Wagner,et al.  A New Equation of State for Carbon Dioxide Covering the Fluid Region from the Triple‐Point Temperature to 1100 K at Pressures up to 800 MPa , 1996 .

[29]  Evangelos Tzimas,et al.  Optimised deployment of a European CO2 transport network , 2012 .

[30]  Warren R. True,et al.  US gas carriers see 2004 net jump; construction plans rebound , 2005 .

[31]  Zaoxiao Zhang,et al.  Optimization of pipeline transport for CO2 sequestration , 2006 .

[32]  Warren R. True,et al.  US construction plans slide; pipeline companies experience flat 2003, continue mergers , 2004 .

[33]  Jens Hetland,et al.  Cost Analysis of CO2 Transportation: Case Study in China , 2011 .

[34]  Christopher E. Smith US gas carriers' 2005 net incomes climb; construction costs plummet , 2006 .

[35]  Guntis Moritis Arrays prevent liyhtning strikes at production facilities , 2007 .

[36]  Christopher E. Smith Balloon network allows remote CP monitoring , 2008 .

[37]  Rickard Svensson,et al.  Transportation systems for CO2––application to carbon capture and storage , 2004 .

[38]  Donald R. Woods,et al.  Rules of Thumb in Engineering Practice , 2007 .

[39]  P. Cayrade,et al.  Investments in Gas Pipelines and Liquefied Natural Gas Infrastructure. What is the Impact on the Security of Supply? , 2004 .

[40]  Edward S. Rubin,et al.  An engineering-economic model of pipeline transport of CO2 with application to carbon capture and storage , 2008 .

[41]  Wim Turkenburg,et al.  A comparison of electricity and hydrogen production systems with CO2 capture and storage—Part B: Chain analysis of promising CCS options , 2007 .

[42]  Neeraj Gupta,et al.  A CO2-storage supply curve for North America and its implications for the deployment of carbon dioxide capture and storage systems , 2005 .

[43]  André Faaij,et al.  A state-of-the-art review of techno-economic models predicting the costs of CO2 pipeline transport , 2013 .

[44]  Ton Wildenborg,et al.  Designing a cost-effective CO2 storage infrastructure using a GIS based linear optimization energy model , 2010, Environ. Model. Softw..

[45]  Richard S. Middleton,et al.  A scalable infrastructure model for carbon capture and storage: SimCCS , 2009 .