Presentation is loading. Please wait.

Presentation is loading. Please wait.

Energy Analysis of Underground Coal Gasification with Simultaneous Storage of Carbon Dioxide Ali Akbar Eftekhari Hans Bruining x.

Published byDomenic Pierce Dennis Modified over 8 years ago

Similar presentations

Presentation on theme: "Energy Analysis of Underground Coal Gasification with Simultaneous Storage of Carbon Dioxide Ali Akbar Eftekhari Hans Bruining x."— Presentation transcript:

1 Energy Analysis of Underground Coal Gasification with Simultaneous Storage of Carbon Dioxide Ali Akbar Eftekhari Hans Bruining x

2 (Enriched) Air Water (Steam) CO, CO 2, H 2, H 2 O, CH 4, N 2 C + 2 H 2 O + CaO  CaCO 3 + 2 H 2 + 87.9 kJ/mol

3 Exergy Analysis of Energy Recovery Processes Recovery Process Energy Consumption CO 2 Capture and Storage Energy Source CO 2 Capture and Storage Recovery Process Energy Consumption CO 2 Capture and Storage Energy

4 Zero-emission recovery factor Coal (56%) Natural Gas (62%) Ref: Dellucci, 2003; Except the CCS data

5 UCG with mineral injection 5 High Temperature: CaCO3  CaO + CO 2 Volume Constraint:

6 Independent reactions Combustion  C + O 2  CO 2 + 393.77 kJ/mol Gasification  Global reaction C + 2 H 2 O + CaO  CaCO 3 + 2 H 2 + 87.9 kJ/mol  Boudouard reaction C + CO 2  2 CO – 172.58 kJ/mol  Shift reaction CO + H 2 O  CO 2 + H 2 – 41.98 kJ/mol  Methanation C + 2 H 2  CH 4 + 74.90 kJ/mol

7 Equilibrium relations y i : gas phase mole fraction P 0 : standard pressure (1 bar) P: system pressure K j : equilibrium constant of reaction j v i,j : stoichiometric coefficient of component i in reaction j Φ i : fugacity coefficient of component i in a gas mixture

8 Temperature constraint at P=80 bar Volume constraint

9 Optimum composition (O 2 injection) Composition (dry basis) H20.46 CO20.08 CO0.32 CH40.14 Higher heating value (MJ/m 3 )14.679 Lower heating value (MJ/m 3 )13.286

10 Process flow diagram (1) E gain E1E1 E2E2 E4E4 E3E3 E5E5 E CCS η = (E gain - (∑E i +E CCS ))/E Res E Res

11 From theory to practice Theoretical Practical Zero-emission (Sustainable)

12 Results of PFD (1) Theoretical, practical, and zero-emission recovery of coal energy (water to oxygen molar ratio of 3.2) Recovery factor (%)

13 Process flow diagram (2)

14 Sustainable recovery for other energy conversion processes

15 Conclusion In situ introduction of absorbent e.g. CaO is energetically expensive and with the current state of technology is not feasible Using naturally abundant minerals can improve the exergetic recovery of UCG process

16 Coal Zero-emission Recovery

17 Natural gas sustainable recovery

18 Formulation

19

20 Exergy? Energy = Exergy + Anergy Exergy is a portion of energy that potentially can be converted to mechanical work 1 kJ of Electricity = 1 kJ of Exergy + 0 kJ of Anergy 1 kJ of energy in hot water at 70 o C = 0.13 kJ Exergy + 0.87 Anergy Energy is conserved; Exergy is consumed

Download ppt "Energy Analysis of Underground Coal Gasification with Simultaneous Storage of Carbon Dioxide Ali Akbar Eftekhari Hans Bruining x."

Similar presentations

ME 525: Combustion Lecture 3

ME 525: Combustion Lecture 3
1 Energy consumption of alternative process technologies for CO 2 capture Magnus Glosli Jacobsen Trial Lecture November 18th, 2011.

1 Energy consumption of alternative process technologies for CO 2 capture Magnus Glosli Jacobsen Trial Lecture November 18th, 2011.
AE 427 THERMODYNAMIC CYCLE SIMULATION Prof.Dr. Demir Bayka.

AE 427 THERMODYNAMIC CYCLE SIMULATION Prof.Dr. Demir Bayka.
Review of Chemical Thermodynamics Combustion MECH 6191 Department of Mechanical and Industrial Engineering Concordia University Lecture #1 Textbook: Introduction.

Review of Chemical Thermodynamics Combustion MECH 6191 Department of Mechanical and Industrial Engineering Concordia University Lecture #1 Textbook: Introduction.
Combustion and Power Generation

Combustion and Power Generation
Heat of Reaction 1st Law Analysis of Combustion Systems

Heat of Reaction 1st Law Analysis of Combustion Systems
Thermochemistry.

Thermochemistry.
Energy From Chemical Reactions

Energy From Chemical Reactions
Standard Enthalpy (Ch_6.6) The heat change that results when 1 mole of a compound is formed from its elements at a pressure of 1 Atm.

Standard Enthalpy (Ch_6.6) The heat change that results when 1 mole of a compound is formed from its elements at a pressure of 1 Atm.
Capturing Carbon dioxide Capturing and removing CO 2 from mobile sources is difficult. But CO 2 capture might be feasible for large stationary power plants.

Capturing Carbon dioxide Capturing and removing CO 2 from mobile sources is difficult. But CO 2 capture might be feasible for large stationary power plants.
Striclty for educational purposes Final project in M.Sc. Course for teachers, in the framework of the Caesarea –Rothschild program of the Feinberg Grad.

Striclty for educational purposes Final project in M.Sc. Course for teachers, in the framework of the Caesarea –Rothschild program of the Feinberg Grad.
Joshua Condon, Richard Graver, Joseph Saah, Shekhar Shah

Joshua Condon, Richard Graver, Joseph Saah, Shekhar Shah
Combustion AND Emissions Performance of syngas fuels derived from palm shell and POLYETHYLENE (PE) WASTE VIA CATALYTIC STEAM GASIFICATION Chaouki Ghenai.

Combustion AND Emissions Performance of syngas fuels derived from palm shell and POLYETHYLENE (PE) WASTE VIA CATALYTIC STEAM GASIFICATION Chaouki Ghenai.
Thermochemistry.

Thermochemistry.
Input + Generation = Output + Consumption

Input + Generation = Output + Consumption
How would you sort these?

How would you sort these?
Stoichiometry II. Solve stoichiometric problems involving moles, mass, and volume, given a balanced chemical reaction. Include: heat of reaction Additional.

Stoichiometry II. Solve stoichiometric problems involving moles, mass, and volume, given a balanced chemical reaction. Include: heat of reaction Additional.
Energy Calculations PRACTICE PROBLEM #1:

Energy Calculations PRACTICE PROBLEM #1:
Lecture B. Day 4 Activities: Exothermic or endothermic? Objectives –Be able to identify exothermic and endothermic reactions based on temperature change.

Lecture B. Day 4 Activities: Exothermic or endothermic? Objectives –Be able to identify exothermic and endothermic reactions based on temperature change.
Reacting Mixtures and Combustion

Reacting Mixtures and Combustion

Similar presentations

Ads by Google