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Best Practice Guidance for Effective Methane Drainage and Use at Coal Mines
Activities of the Ad Hoc Group of Experts on CMM with respect to mine safety
Item 6 of the AgendaGeneva, 12‐13 October 2009
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Principal findings
Report outline
Finalisation
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Reduce underground explosion risk
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Explosions
• Devastating explosion events killing 100 – 200 miners and more have occurred in 21st Century
• All coal mining countries affected but scale and frequency differs
• Fatalities/Mt: 1.25 China, 0.037 USA, 0.0 NSW Australia
• Explosions are preventable – gas dilution, layer prevention, gas capture, gas transport, ignition sources
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Explosive mixtures are unavoidable
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Coal seam >95% CH4
Open goaf 15% ‐ 5% CH4
Airway <2% CH4
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Regulatory and risk control
• Technology alone not enough
• Site specific treatment ‐ risk assessment
• Involve stakeholder most at risk – workers
• Non prescriptive rules except where physical constraint eg explosive limits
• Strong enforcement essential
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Climate change
• 2020: 793Mt CO2 released; 95% from underground
• 70‐80% VAM; remainder drained gas and coal product emissions
• Cost to economy not yet borne by mining
• Technology exists which can virtually eliminate methane emissions
• High opportunity cost barrier: but utilisation attractive with high gas/power price plus high carbon price or high emission penalty
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CMM projects are “additional”
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0
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0 10 20 30 40 50 60
Revenue US$/t
Specific emission m3/t
Power
CERs
Total
US$50/t
US$30/t
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Gas drainage
• Many technologies but principles common
• Drainage reduces accident risk and hence mining cost
• Reduces ventilation costs (double airflow, x8 more power)
• Allows increased coal production
• Post drainage – capture gas before excessive dilution so can use
• Captured gas can be used or flared to reduce emissions at low cost
• Drainage of gas at low concentration is dangerous, inefficient and can be avoided
0
100
200
300
400
500
600
0 20 40 60 80 100 120
Power kW
Airflow m3/s
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De‐stressing zone from which gas released above a longwall
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Effective post drainage captures gas where released
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Gas drainage options – high permeability coal
No coal seams in roof and floor (+150;‐40m)
• Pre‐drainage of worked seam essential if gassy
• Post‐drainage of no benefit
Many coal seams in roof and floor (+150;‐40m)
•Pre‐drainage of worked seam effective•Post‐drainage also needed if gassy
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Gas drainage options – low permeability coal
No coal seams in roof and floor (+150;‐40m)
• Pre‐drainage of worked seam ineffective
• Post‐drainage of no benefit• Ventilation solutions only, coal
production rate limited
Many coal seams in roof and floor (+150;‐40m)•Pre‐drainage of worked seam ineffective alone•Post‐drainage essential if gassy – may include floor boreholes
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Main conclusions
• Global application of the accumulated knowledge on methane occurrence, prediction, control and management could virtually eliminate explosion risks in coal mines.
• There is a strong business case for installing and operating high efficiency gas drainage systems
• Methane emissions from underground coal mines can virtually be eliminated using existing technology
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Report outline
1. Executive Summary
2. Introduction
3. Fundamentals of gas control
4. Occurrence, release & prediction of gas emissions
5. Mine ventilation
6. Methane drainage
7. Methane utilisation and abatement
8. Cost & economic Issues
9. Conclusions
10. Case studies (5 studies)
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Report conclusions
• The global economy, will continue to be dependent on energy from coal for the foreseeable future.
• Coal extraction will become increasingly challenging as shallow reserves are exhausted and deeper and more gassy seams are mined.
• Climate change impacts will lead to greater restrictions on coal mining activities and societies will increasingly demand and expect safer working conditions.
• This guidance is considered a starting point for devising strategy and evolving programs to support the necessary safety and practice improvements from which all mining countries can benefit.
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Report conclusions continued
• Technologies now exist that will allow coal mines to maximize gas capture for utilization.
• There is a strong business case for installing and operating high efficiency gas drainage systems.
• Elimination of virtually all mine‐mouth emissions through oxidation of the un‐captured methane that escapes into the ventilation air is now feasible.
• This high level of emission control only becomes financially viable when supported by a market that assigns a value through carbon credits to environmental protection.
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Case Studies
• VAM Case Studies (Megtec or Biothermica)
• Upgrading Technology (Molecular Gate)
• High performance longwall operations in areas with high gas emissions –Germany
• Achieving planned coal production from a gassy, retreat longwall with severe strata stress and a spontaneous combustion prone coal seam – UK
• High performance longwall operations in areas with high gas emissions –Australia
• Development of a CMM power co‐generation and emission abatement scheme – China
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Molecular Gate Unit for 2.5 MM SCFD
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Case Studies: Longwall with Y‐shaped, ventilation design and drainage boreholes in the roof and the
floor behind the longwall
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Finalising draft
• Omissions – contractor safety, use of gas storage tanks, environmental regulations on utilisation and destruction?
• Standardising terms – differences between Australian, US, UK and European usage
• Corrections – factual errors, differences of opinion
• Illustrations – simple, clear, relevant – illustrator needed
• Photos – invite submissions, fully attributed and no copyright issues
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