Stud.IP Uni Oldenburg
University of Oldenburg
05.02.2023 20:49:13
pre042 - Water and Biomass Energy
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Module label Water and Biomass Energy
Modulkürzel pre042
Credit points 6.0 KP
Workload 180 h
180 Stunden
Institute directory Institute of Physics
Verwendbarkeit des Moduls
  • Master's Programme Engineering Physics (Master) > Schwerpunkt: Renewable Energies
  • Master's Programme Environmental Modelling (Master) > Mastermodule
  • Sustainable Renewable Energy Technologies (Master) > Mastermodule
Zuständige Personen
Wark, Michael (Prüfungsberechtigt)
Holtorf, Hans-Gerhard (Prüfungsberechtigt)
Pehlken, Alexandra (Prüfungsberechtigt)
Knipper, Martin (Prüfungsberechtigt)
Torio, Herena (Prüfungsberechtigt)
Wark, Michael (Module responsibility)
Holtorf, Hans-Gerhard (Module responsibility)
Skills to be acquired in this module

After the completion of the module students should be able to

-       critically evaluate and compare two Renewable Energy conversion processes which allow
         continuous power supply on demand (hydropower and biomass energy)

-       confront those systems to a Renewable Energy conversion process with intermittent output
        (marine power)

-       discuss extreme situations in Renewable Energy systems’ source and transfer such situations
        to other Renewable Energy systems

-       analyse various system components and their interconnections within a complex Renewable
        Energy supply system,

-       evaluate the Renewable Energy supply systems’ operational size and efficiency,

-       critically evaluate non-technical impact and side effects when implementing renewable
        energy supply systems

-      understand the basic chemical background of bioenergy-related materials, systems and

Module contents

Biomass Energy (Lecture - 90 h workload)

      Energy mix overview; gas, heat, electricity, Pros and Cons, of biomass,

      Chemical composition of biomass: sugar, cellulose, starch, fats, oils, proteins, lignin,

      Natural photosynthesis in plants: chemical storage of solar energy; general mechanisms,

      Chemistry and Biology (microorganism) of Biogas Technology,

      Conversion processes of biomass: classification, main pathways,

      Introduction to catalysis used in biomass conversion,

      Chemical fuels (chemical energy storage) from biomass,

      Routes to platform chemicals and separation processes,

      Technology concepts for bioenergy usage,

      Introduction into economical and legal constraints.


Hydro and Marine Power (Lecture + Excursion - 90 h workload)

      Revision of hydraulic basics and their application to hydro and marine power.

      Hydropower and marine power resources and their representation

      Technological and economical state of the art.

-       Description of such systems’ components, their characteristics, their interaction in a system,
        their main features and their challenges


Biomass Energy

     IEA (2019), Renewables 2019, IEA, Paris
       2019Fagerström, A., Al Seadi, T., Rasi, S., Briseid, T, (2018).

     The role of Anaerobic Digestion and Biogas in the Circular Economy. Murphy, J.D. (Ed.) IEA
        Bioenergy Task 37, 2018: 8

-       IEA (2020), Outlook for biogas and biomethane: Prospects for organic growth, IEA, Paris

-       International Finance Corporation. 2017. Converting Biomass to Energy: A Guide for
        Developers and Investors. Washington, DC ©
        /10986/28305 License: CC BY-NC-ND 3.0 IGO.

-       Cushion, Elizabeth, Adrian Whiteman, and Gerhard Dieterle. Bioenergy development: issues
         and impacts for poverty and natural resource man-agement

-       Pehlken, A., Wulf, K., Grecksch, K., Klenke, T., Tsydenova, N.; More Sustainable Bioenergy by
        Making Use of Regional Alternative Biomass?, Sustainability 2020, 12(19), 7849;

-       Schlögl, Robert (2013). Chemical energy storage (Elektronische Ressource ed.). Berlin [u.a.]:
         De Gruyter.

-       Sackheim, G.I., Lehman, D.D.: Chemistry for the Health Sciences
         (8th edition), Prentice Hall, 1998

-       Chemistry – General, Organic and Biological, Pearson International Edition (2nd edition), 2007

-       Alonso, D.M., Bond, J.Q., Dumesic, J.A., Catalytic conversion of biomasses to biofuels, Green
        Chem. 12, 2010, 1493-1513


Hydro and Marine Power

-       Charlier R.H., (2009) Ocean Energy: Tide and Tidal Power.

-       Chtrakar P (2005) Micro-hydropower design aids manual: Small Hydropower Promotion
         Project, Mini Grid Support Programme. 107p.

-       Croockewit J (2004) Handbook for developing micro hydro in British Columbia: BChydro. 69

-       Giesecke J, Heimerl S, Mosonyi E (2014) Wasserkraftanlagen: Springer Vieweg. XXVI, 940 p.

-       Inversin AR (1986) Micro-hydropower sourcebook: NRECA International Foundation.

-       Meder K (2011) Environment Assessment and Watershed Action Planning related to GIZ ECO
        MHP Projects: Field Manual. GIZ. 24 p.

-      Pelikan B (2004) Guide on how to develop a small hydropower plant. European Small
       Hydropower Association ESHA. 151 p.

Penche C (1988) Layman's handbook on how to develop a small hydro site; Commission E,
-      Rodriguez L, Sánchez T (2011) Designing and building mini and micro hydropower schemes - a
       practical guide; Action P, editor: Practical Action Publishing Ltd. xxii, 359 p.


Language of instruction English
Duration (semesters) 1 Semester
Module frequency Wintersemester
Module capacity unlimited
Reference text

Within the lecture Hydro and Marine Power an excursion to a hydropower plant and the catchment area will be offered. The duration of this excursion will be in total 5 hours.

It is recommended to know the basics of photosynthesis.
Modullevel / module level MM (Mastermodul / Master module)
Modulart / typ of module Pflicht / Mandatory
Lehr-/Lernform / Teaching/Learning method
Vorkenntnisse / Previous knowledge Basics of
- Hydrodynamics
- Mechanical Engineering
- Electrical Engineering
- Recommended: Basic knowledge of General Chemistry
Form of instruction Comment SWS Frequency Workload of compulsory attendance
Lecture 2 SoSe oder WiSe 28
Seminar 2 SoSe oder WiSe 28
Präsenzzeit Modul insgesamt 56 h
Examination Prüfungszeiten Type of examination
Final exam of module
End of Winter Semester
Written Exam and active participation