ENVR E9Z07 - Bio-Energy 2

Module Details

Module Code: ENVR E9Z07
Full Title: Bio-Energy 2
Valid From:: Semester 1 - 2019/20 ( June 2019 )
Language of Instruction:English
Duration: 1 Semester
Credits:: 7.5
Module Owner:: Wayne Doherty
Departments: Unknown
Module Description: This module provides students with a detailed knowledge of how energy can be generated from waste residues and biomass and to give students awareness and knowledge of associated legislation, policies, traditional approaches and emerging technologies.
 
Module Learning Outcome
On successful completion of this module the learner will be able to:
# Module Learning Outcome Description
MLO1 Appraise the role of incineration in waste management and energy generation and be able to describe the incineration and heat recovery process
MLO2 Examine the potential pollutants of air, land and water that are associated with incineration and recognise the necessity for pollution prevention and control requirements
MLO3 Compare the types of biomass fuel suitable for use with reciprocating engines and explain the modifications needed to enable the reciprocating engine to utilise biomass fuels effectively
MLO4 Critically evaluate various complete processes for the conversion of biomass to electricity or CHP and give examples of actual plants
MLO5 Assess the financial/economic performance of a biomass-to-energy plant
Pre-requisite learning
Module Recommendations
This is prior learning (or a practical skill) that is strongly recommended before enrolment in this module. You may enrol in this module if you have not acquired the recommended learning but you will have considerable difficulty in passing (i.e. achieving the learning outcomes of) the module. While the prior learning is expressed as named DkIT module(s) it also allows for learning (in another module or modules) which is equivalent to the learning specified in the named module(s).
No recommendations listed
 
Module Indicative Content
Waste-to-Energy
Municipal Solid Waste – quantity, composition, properties. Waste Management – methods, policy. Conversion Technologies – moving grate technology and alternative tech., operating parameters, boiler design, plant efficiency, ash handling. Emissions. Case Studies – Real WtE Plants.
Gasification
Gasification Theory and Chemical Reactions. Gasifier Performance Calculation. Plasma Gasification Waste-to-Energy. Dual Fluidised Bed Biomass Gasifier Technologies – FICFB, MILENA, BioHPR, Silvagas, IHI TIGAR, Pyrox. Gas Cleaning and Conditioning. Product Gas Applications: SNG, ORC, Stirling Engine, Fuel Cells. Plant Case Studies.
Pyrolysis
The Pyrolysis Process – focus on fast pyrolysis. Bio-oil – composition, properties, quality issues and standards. Fast Pyrolysis Technologies – bubbling fluidised bed, circulating fluidised bed, rotating cone, ablative, auger/screw. Plant Case Studies.
Pollution and Emission Control
EU Directives and Emission Limit Values (ELVs). Pollution and Emission Control Technologies – wet, semi-dry and dry flue gas treatment, particulate/dust removal technologies, scrubber technologies, SOx and NOx control, dioxin control, gasification product gas cleaning.
Engines
Engine Basics – nomenclature, octane and cetane numbers, 2 and 4 stroke engines. Otto Cycle: Spark Ignition (SI) Engines. Diesel Cycle: Compression Ignition (CI) Engines. CI vs SI Engines. Biofuels in Engines – liquid biofuels, gaseous biofuels, fossil fuel Compressed Natural Gas (CNG) & Liquefied NG (LNG), operating characteristics and modifications required.
Bioenergy Project Economics/Finance
Bankability of Energy Projects. Criteria in Assessing a Bioenergy Project. Ensuring a Successful Project & Lessons Learned. Spreadsheet Models.
Module Assessment
Assessment Breakdown%
Course Work30.00%
Final Examination70.00%
Module Special Regulation
 

Assessments

Full Time On Campus

Course Work
Assessment Type Continuous Assessment % of Total Mark 30
Marks Out Of 0 Pass Mark 0
Timing n/a Learning Outcome 1,2,4,5
Duration in minutes 0
Assessment Description
Laboratory practicals and an industrial site visit will serve to reinforce the material covered in lectures.
Students will be assessed through the use
of written reports, practical evaluations
and/or class tests.
No Project
No Practical
Final Examination
Assessment Type Formal Exam % of Total Mark 70
Marks Out Of 0 Pass Mark 0
Timing End-of-Semester Learning Outcome 1,2,3,4,5
Duration in minutes 0
Assessment Description
End-of-Semester Final Examination
Reassessment Requirement
A repeat examination
Reassessment of this module will consist of a repeat examination. It is possible that there will also be a requirement to be reassessed in a coursework element.

DKIT reserves the right to alter the nature and timings of assessment

 

Module Workload

Workload: Full Time On Campus
Workload Type Contact Type Workload Description Frequency Average Weekly Learner Workload Hours
Lecture Contact No Description Every Week 2.00 2
Practical Contact No Description Every Week 0.50 0.5
Independent Study Non Contact No Description Every Week 9.50 9.5
Total Weekly Learner Workload 12.00
Total Weekly Contact Hours 2.50
This module has no Part Time On Campus workload.
 
Module Resources
Recommended Book Resources
  • van Loo & Koppejan. (2008), Biomass Combustion & Co‐firing, Earthscan.
  • Spliethoff H.. (2010), Power generation from solid fuels, Springer.
  • Basu. (2013), Biomass Gasification, Pyrolysis and Torrefaction - Practical Design and Theory, 2nd. Elsevier.
  • Robert C Brown et al.. (2017), Fast Pyrolysis of Biomass - Advances in Science and Technology.
  • Kalogirou. (2018), Waste-to-Energy Technologies and Global Applications, CRC Press.
  • Buekens. (2013), Incineration Technologies, Springer.
  • Rogoff & Screve. (2011), Waste-to-Energy: Technologies and Project Implementation, Elsevier.
  • Niessen. (2010), Combustion and Incineration Processes: Applications in Environmental Engineering, CRC Press.
  • Young G.. (2010), MUNICIPAL SOLID WASTE TO ENERGY CONVERSION PROCESSES, Wiley.
  • K.A. Subramanian. (2018), Biofueled Reciprocating Internal Combustion Engines, CRC Press.
  • Cengel & Boles. (2014), Thermodynamics an engineering approach, 8th. McGraw-Hill.
  • DGS & Ecofys. (2005), Planning and Installing Bioenergy Systems: A guide for installers, architects and engineers, James & James.
This module does not have any article/paper resources
Other Resources