Module Manual
Master
Energy and Environmental Engineering
Cohort: Winter Term 2015
Updated: 12th December 2016
Content
The TUHH Master study programme in Energy and Environmental Engineering prepares the graduates for leading roles in the energy producing and consuming industry, for undertaking environmental protection tasks or for independent research activities. The Master programme is characterised by its scientific orientation, focus building and acquisition of effective and structured interdisciplinary work methods. The focal points of the syllabus relate closely with the research subjects of the participating TUHH Institutes from the Mechanical Engineering, Process Engineering and Civil Engineering Faculties. This reflects the close link between research and teaching and ensures that the contents of the lectures always remain up to date. It also offers possibilities for contributing work to the research of the TUHH, for example within the framework of study projects, seminar themes or the project course. The key points of the Master degree syllabus are linked with the core contents of the Bachelor degree forming the first step in this consecutive degree pair.
After successful graduation the graduates are in position to interpret in depth methods and techniques from the core competencies of thermodynamics, fluid mechanics and process engineering. They also possess well-founded knowledge in energy engineering and environmental engineering, encompassing both conventional and renewable energy sources. The theoretical skills are complemented by practical assignments within laboratory courses and seminars. The graduates are in a position to utilise specialist methods and tools to draw whole process balances and design their process components.
Through the qualifications obtained in the study they can strike an energetically and economically optimum in the operation of energy systems, without neglecting resource protection, sustainability or cost effectiveness. The graduates are able to focus on the aims of a project, an enterprise or even the society as a whole and develop optimal solution strategies for the operation of plants. They are also able to assess the environmental impact and choose measures for mitigating the environmental risks.
The interpersonal skills obtained during the Bachelor study are deepened and refined further in the Master study programme. The graduates are then capable to undertake responsibility for team work, structure it, perform self-sufficiently and timely their own sub-tasks and convey the overall results in the most suitable for the end-user manner. They can independently analyse a specialist theme, present it using appropriate media and describe it within a treatise obeying the rules of good scientific practice.
At the end, the graduates are competent to independently plan and perform successfully time and resource limited research, using the knowledge and skills obtained during the study, and assume responsibility for the results.
This facilitates the entry of the graduates in activities in industry or Research & Development.The Master course in Energy and Environmental Engineering aims at preparing the students for addressing successfully energy and environmental problems. The curriculum combines wide specialised process engineering and mechanical engineering syllabuses with a scientific education specialisation. The degree is focused at the requirements of the ensuing professional praxis, as these emerge from the technical, economic, ecologic and societal developments. In addition, the students must choose compulsory elective lectures within the three specialisation paths available. In this selection you may choose to place the focus either on Environmental Technology, on Renewable Energies or on Conventional Energy Systems without, however, neglecting the other two subject areas.
As basis qualification and on the basis of compulsory lectures become all graduates deep and extensive engineering knowledge in the fundamental subject areas of transport processes and fluid mechanics. The theoretical knowledge is supplemented by a related to real life practical laboratory course. This laboratory course covers subjects from both energy systems and environmental technology.
A further key aspect within the basis qualification for the degree are technical communication skills. These are cultivated within the framework of the Seminar in Energy and Environmental Engineering, a course that strengthens the “soft skills” of the graduates and prepares them for independent working.
The technical content of the basis qualification is complemented by a number of non-technical supplementary courses as well as compulsory elective Business & Management lectures. These widen the horizon and expertise of the graduates with qualifications which are important for a successful subsequent entry into the profession.
Module M0523: Business & Management |
Module Responsible | Prof. Matthias Meyer |
Admission Requirements | None |
Recommended Previous Knowledge | None |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
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Skills |
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Personal Competence | |
Social Competence | |
Autonomy |
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Workload in Hours | Depends on choice of courses |
Credit points | 6 |
Courses |
Information regarding lectures and courses can be found in the corresponding module handbook published separately. |
Module M0524: Nontechnical Elective Complementary Courses for Master |
Module Responsible | Dagmar Richter |
Admission Requirements | None |
Recommended Previous Knowledge | None |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The Non-technical Elective Study Area imparts skills that, in view of the TUHH’s training profile, professional engineering studies require but are not able to cover fully. Self-reliance, self-management, collaboration and professional and personnel management competences. The department implements these training objectives in its teaching architecture, in its teaching and learning arrangements, in teaching areas and by means of teaching offerings in which students can qualify by opting for specific competences and a competence level at the Bachelor’s or Master’s level. The teaching offerings are pooled in two different catalogues for nontechnical complementary courses. The Learning Architecture consists of a cross-disciplinarily study offering. The centrally designed teaching offering ensures that courses in the “non-technical department” follow the specific profiling of TUHH degree courses. The learning architecture demands and trains independent educational planning as regards the individual development of competences. It also provides orientation knowledge in the form of “profiles”. The subjects that can be studied in parallel throughout the student’s entire study program - if need be, it can be studied in one to two semesters. In view of the adaptation problems that individuals commonly face in their first semesters after making the transition from school to university and in order to encourage individually planned semesters abroad, there is no obligation to study these subjects in one or two specific semesters during the course of studies. Teaching and Learning Arrangements provide for students, separated into B.Sc. and M.Sc., to learn with and from each other across semesters. The challenge of dealing with interdisciplinarity and a variety of stages of learning in courses are part of the learning architecture and are deliberately encouraged in specific courses. Fields of Teaching are based on research findings from the academic disciplines cultural studies, social studies, arts, historical studies, communication studies and sustainability research, and from engineering didactics. In addition, from the winter semester 2014/15 students on all Bachelor’s courses will have the opportunity to learn about business management and start-ups in a goal-oriented way. The fields of teaching are augmented by soft skills offers and a foreign language offer. Here, the focus is on encouraging goal-oriented communication skills, e.g. the skills required by outgoing engineers in international and intercultural situations. The Competence Level of the courses offered in this area is different as regards the basic training objective in the Bachelor’s and Master’s fields. These differences are reflected in the practical examples used, in content topics that refer to different professional application contexts, and in the higher scientific and theoretical level of abstraction in the B.Sc. This is also reflected in the different quality of soft skills, which relate to the different team positions and different group leadership functions of Bachelor’s and Master’s graduates in their future working life. Specialized Competence (Knowledge) Students can
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Skills |
Professional Competence (Skills) In selected sub-areas students can
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Personal Competence | |
Social Competence |
Personal Competences (Social Skills) Students will be able
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Autonomy |
Personal Competences (Self-reliance) Students are able in selected areas
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Workload in Hours | Depends on choice of courses |
Credit points | 6 |
Courses |
Information regarding lectures and courses can be found in the corresponding module handbook published separately. |
Module M0540: Transport Processes |
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Module Responsible | Prof. Michael Schlüter |
Admission Requirements | none |
Recommended Previous Knowledge | All lectures from the undergraduate studies, especially mathematics, chemistry, thermodynamics, fluid mechanics, heat- and mass transfer. |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students are able to:
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Skills |
The students are able to:
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Personal Competence | |
Social Competence |
The students are able to discuss in international teams in english and develop an approach under pressure of time. |
Autonomy |
Students are able to define independently tasks, to solve the problem "design of a multiphase reactor". The knowledge that s necessary is worked out by the students themselves on the basis of the existing knowledge from the lecture. The students are able to decide by themselves what kind of equation and model is applicable to their certain problem. They are able to organize their own team and to define priorities for different tasks. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Oral exam |
Examination duration and scale | |
Assignment for the Following Curricula |
Bioprocess Engineering: Core qualification: Compulsory Energy and Environmental Engineering: Core qualification: Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Process Engineering: Core qualification: Compulsory |
Course L0104: Multiphase Flows |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | EN |
Cycle | WiSe |
Content |
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Literature |
Brauer, H.: Grundlagen der Einphasen- und Mehrphasenströmungen. Verlag Sauerländer, Aarau, Frankfurt (M), 1971. |
Course L0105: Reactor Design Using Local Transport Processes |
Typ | Problem-based Learning |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | EN |
Cycle | WiSe |
Content |
In this Problem-Based Learning unit the students have to design a multiphase reactor for a fast chemical reaction concerning optimal hydrodynamic conditions of the multiphase flow. The four students in each team have to:
This exposé will be used as basis for the discussion within the oral group examen of each team. |
Literature | see actual literature list in StudIP with recent published papers |
Course L0103: Heat & Mass Transfer in Process Engineering |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | EN |
Cycle | WiSe |
Content |
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Literature |
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Module M0542: Fluid Mechanics in Process Engineering |
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Module Responsible | Prof. Michael Schlüter |
Admission Requirements | none |
Recommended Previous Knowledge |
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Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students are able to describe different applications of fluid mechanics in Process Engineering, Bioprocess Engineering, Energy- and Environmental Process Engineering and Renewable Energies. They are able to use the fundamentals of fluid mechanics for calculations of certain engineering problems. The students are able to estimate if a problem can be solved with an analytical solution and what kind of alternative possibilities are available (e.g. self-similarity in an example of free jets, empirical solutions in an example with the Forchheimer equation, numerical methods in an example of Large Eddy Simulation. |
Skills |
Students are able to use the governing equations of Fluid Dynamics for the design of technical processes. Especially they are able to formulate momentum and mass balances to optimize the hydrodynamics of technical processes. They are able to transform a verbal formulated message into an abstract formal procedure. |
Personal Competence | |
Social Competence |
The students are able to discuss a given problem in small groups and to develop an approach. |
Autonomy |
Students are able to define independently tasks for problems related to fluid mechanics. They are able to work out the knowledge that is necessary to solve the problem by themselves on the basis of the existing knowledge from the lecture. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 180 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Core qualification: Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Process Engineering: Core qualification: Compulsory |
Course L0106: Applications of Fluid Mechanics in Process Engineering |
Typ | Recitation Section (large) |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | DE |
Cycle | WiSe |
Content | The Exercise-Lecture will bridge the gap between the theoretical content from the lecture and practical calculations. For this aim a special exercise is calculated at the blackboard that shows how the theoretical knowledge from the lecture can be used to solve real problems in Process Engineering. |
Literature |
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Course L0001: Fluid Mechanics II |
Typ | Lecture |
Hrs/wk | 2 |
CP | 4 |
Workload in Hours | Independent Study Time 92, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | DE |
Cycle | WiSe |
Content |
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Literature |
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Module M1036: Practical Course on Energy and Environmental Engineering |
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Module Responsible | Prof. Alfons Kather |
Admission Requirements |
None |
Recommended Previous Knowledge |
“Gas and Steam Power Plants“ |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The module aims at consolidating the knowledge obtained in the Bachelor degree of Energy and Environmental Engineering. Target is the application of methods and techniques for the analysis and evaluation of test results in the praxis. By performing laboratory experiments the students are exposed to the taking of reliable measurements in real plant, as well as to the reporting and quality assurance of the measurement results. From the parameters being monitored they conclude on the quantitative key figures of the test facility. The students formulate subsequently a laboratory report with the conclusions and the critical evaluation of the rig. Within the framework of this team work the students learn to analyse and evaluate the plant and the chemical phenomena tested. By means of presentations in some experiments of the test procedures followed and the results obtained, accompanied by discussion and critical results’ evaluation, practice the students technical communication and professional argumentation. |
Skills |
The participants must take within the group responsibility for partial aspects of the practical course, which in case of inadequate fulfilment may have negative consequences for the whole group. In this manner the teamwork and communication abilities of the participants are cultivated and their ability to undertake leadership responsibilities strengthened. In addition, the participants are trained in the compilation of test transcripts and the analysis and critical evaluation of measurements, taken partially at large energy systems. In this way they are exposed to a plant scale relevant for the later profession. Out of the need to prepare laboratory transcripts on the experiments the students practice written technical communication skills. In the framework of certain experiments the students must also use presentation skills, to present technical aspects of the tests performed and discuss them technically. In this process it is expected that students exercise an analytic and critical way of thinking. |
Personal Competence | |
Social Competence |
The organising together with the test analysis and the preparation of the transcript for the experiment in direct responsibility strengthen the social competence of the participants within the group. The definition of the solution methodologies and the splitting to sub-problems takes place in teamwork. For the preparation of the joint transcript and the reaching of the final conclusions over the experiment performed, communication as well as teamworking abilities are essential. |
Autonomy |
Each student must contribute to the selection of the transcript author(s) and to the planning and timely performance of the analysis and evaluation of the results. The short presentations of the results for certain experiments are, in turn, direct personal contributions of the students. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written elaboration |
Examination duration and scale | Submission of transcript and debriefing (120 min) incl. questioning of the students |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Core qualification: Compulsory |
Course L1386: Practical Course on Energy and Environmental Engineering |
Typ | Laboratory Course |
Hrs/wk | 6 |
CP | 6 |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Lecturer | Dozenten des SD M, Dozenten des SD V |
Language | DE |
Cycle | SoSe |
Content |
In the Practical Course on Energy Systems the following experiments are offered:
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Literature |
Skripte werden für jeden Versuch zur Verfügung gestellt. |
Module M1120: Seminar energy and environmental engineering |
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Courses | ||||||||
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Module Responsible | Prof. Alfons Kather |
Admission Requirements | None |
Recommended Previous Knowledge |
Basic lectures in: Heat Transfer, Gas-Steam Power Plants. The participation in the introductory session is mandatory. |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students, based on a literature survey, learn to study in detail a subject theme from the disciplines of Energy and Environmental Engineering and deliver afterwards a summary presentation to an audience of specialists. Environmental issues and their multidisciplinary linkages are preferred, when selecting the thematic area of these studies. Through their own written contribution the students communicate an overview over the subject and practice technical writing. With the discussion the students practice scientific debating on a specialised subject matter. |
Skills |
The students can, when working on a technical topic not familiar to them:
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Personal Competence | |
Social Competence |
The students practice a critical assessment of the literature in a predefined specialised theme and learn to give presentations on their own technical sub-topic tailored to their public and discuss with the audience. When attending technical presentations, the students can formulate questions to other speakers and participate in the ensuing discussion. The fulfilment of the tasks combines independent work with group and teamwork. |
Autonomy |
The students can, guided by instructors, critically reflect on their learning and work status, and write a scientific report. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written elaboration |
Examination duration and scale | According to the participation in group discussions and an individual presentation + Written report. |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Core qualification: Compulsory |
Course L1456: Seminar energy and environmental engineering |
Typ | Seminar |
Hrs/wk | 6 |
CP | 6 |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Lecturer | Prof. Alfons Kather |
Language | DE |
Cycle | WiSe |
Content |
- Introductory lecture with choice of the subject, fixing the dates, etc. - Literature Survey on the subject of the talk - Preparing the presentation with a software tool like Powerpoint - Oral presentation (15 minutes) and discussion (10 minutes) |
Literature |
In this specialisation path three Modules must be chosen out of a number of compulsory selective lectures covering a wide spectrum of practically relevant aspects of both Energy Systems and Environmental Technology. With the chosen Modules the student can focus in Energy Systems, Environmental Technology or even a combination of both subject areas.
On the one hand the graduates obtain further extensive knowledge over key aspects of Energy Systems – both conventional as well as renewable. On the other hand, they become in-depth coverage of environmental engineering aspects relating to solid wastes handling and wastewater technology. This includes also the sustainable utilisation of resources, so that an environmentally friendly energy generation can occur.
The curriculum is further complemented by lectures in thematically relevant subjects. These encompass solid particle technology, wastewater analysis and membrane technology, which play a fundamental role in Energy Systems and Environmental Engineering.
The specialisation path is rounded up with participation in a process design project, in which the students learn how to work together for solving a complex process engineering problem and how to use specialised tools for designing processes. They also experience what obstacles may be faced and difficulties tackled, whilst designing a process.Module M0801: Water Resources and -Supply |
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Module Responsible | Prof. Mathias Ernst |
Admission Requirements |
None |
Recommended Previous Knowledge |
Knowledge of water management and the key processes involved in water treatment. |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students will be able to outline key areas of conflict in water management, as well as their mutual dependence for sustainable water supply. They will understand relevant economic, environmental and social factors. Students will be able to explain and outline the organisational structures of water companies. They will be able to explain the available water treatment processes and the scope of their application. |
Skills |
Students will be able to assess complex problems in drinking water production and establish solutions involving water management and technical measures. They will be able to assess the evaluation methods that can be used for this. Students will be able to carry out chemical calculations for selected treatment processes and apply generally accepted technical rules and standards to these processes. |
Personal Competence | |
Social Competence |
Working in a diverse group of specialists, students will be able to develop and document complex solutions for the management and treatment of drinking water. They will be able to take an appropriate professional position, for example representing user interests. They will be able to develop joint solutions in teams of diverse experts and present these solutions to others. |
Autonomy |
Students will be in a position to work on a subject independently and present on this subject. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 60 min (chemistry) + presentation |
Assignment for the Following Curricula |
Civil Engineering: Specialisation Structural Engineering: Elective Compulsory Civil Engineering: Specialisation Geotechnical Engineering: Elective Compulsory Civil Engineering: Specialisation Coastal Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Water and Environmental Engineering: Specialisation Water: Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0311: Chemistry of Drinking Water Treatment |
Typ | Lecture |
Hrs/wk | 2 |
CP | 1 |
Workload in Hours | Independent Study Time 2, Study Time in Lecture 28 |
Lecturer | Dr. Klaus Johannsen |
Language | DE |
Cycle | WiSe |
Content |
The topic of this course is water chemistry with respect to drinking water treatment and water distribution Major topics are solubility of gases, carbonic acid system and calcium carbonate, blending, softening, redox processes, materials and legal requirements on drinking water treatment. Focus is put on generally accepted rules of technology (DVGW- and DIN-standards). Special emphasis is put on calculations using realistic analysis data (e.g. calculation of pH or calcium carbonate dissolution potential) in exercises. Students can get a feedback and gain extra points for exam by solving problems for homework. Knowledge of drinking water treatment processes is vital for this lecture. Therefore the most important processes are explained coordinated with the course “ Water resources management“ in the beginning of the semester. |
Literature |
MHW (rev. by Crittenden, J. et al.): Water treatment principles and design. John Wiley & Sons, Hoboken, 2005. Stumm, W., Morgan, J.J.: Aquatic chemistry. John Wiley & Sons, New York, 1996. DVGW (Hrsg.): Wasseraufbereitung – Grundlagen und Verfahren. Oldenbourg Industrie Verlag, München, 2004. Jensen, J. N.: A Problem Solving Approach to Aquatic Chemistry. John Wiley & Sons, Inc., New York, 2003. |
Course L0312: Chemistry of Drinking Water Treatment |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 2 |
Workload in Hours | Independent Study Time 46, Study Time in Lecture 14 |
Lecturer | Dr. Klaus Johannsen |
Language | DE |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0402: Water Resource Management |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Mathias Ernst |
Language | DE |
Cycle | WiSe |
Content |
The lecture provides comprehensive knowledge on interaction of water ressource management and drinking water supply. Content overview:
- User and Stakeholder conflicts - Wasserressourcenmanagement in urbane Gebieten - Rechtliche Aspekte, Organisationsformen Trinkwasserversorgungsunternehmen. - Ökobilanzierung, Benchmarking in der Wasserversorgung |
Literature |
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Course L0403: Water Resource Management |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Mathias Ernst |
Language | DE |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M1037: Nuclear Power Plants and Steam Turbines |
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Module Responsible | Prof. Alfons Kather |
Admission Requirements |
None |
Recommended Previous Knowledge |
For the part "Steam Turbines":
For the part "Basics of Nuclear Power Plants" knowledge of:
is required |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
After successful completion of the part "Steam Turbines" of the module the students must be in a position to:
In the part of the module "Basics of Nuclear Power Plants" the students gain an overview of the safety requirements for the design, construction and operation of nuclear power plants. Students of various study programmes, who wish to specialize in the filed of nuclear power engineering in future, are introduced to the special requirements of the nuclear power technology, which are important for the perception of this field. After successful completion of this part of the module the students acquire the following skills:
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Skills |
In the part of the module "Steam Turbines" the students learn the fundamental approaches and methods for the design and operational evaluation von komplex plant and gain confidence in seeking optimisations. In the part of the module "Basics of Nuclear Power Plants" the students:
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Personal Competence | |
Social Competence |
In the part of the module "Steam Turbines" the students learn:
In the part of the module "Basics of Nuclear Power Plants" the students learn to:
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Autonomy |
In the part of the module "Steam Turbines" the students learn the independent working of a complex thema whilst considering various aspects. They also learn how to carry independently single functions in a system combination. In the part of the module "Basics of Nuclear Power Plants" the students become the ability to gain independently knowledge and transfer it also to new problem solving. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 180 min |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Theoretical Mechanical Engineering: Specialisation Energy Systems: Elective Compulsory |
Course L1286: Steam Turbines in Renewable and Conventional Applications |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Christian Scharfetter |
Language | DE |
Cycle | WiSe |
Content |
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Literature |
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Course L1287: Steam Turbines in Renewable and Conνentional Applications |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Christian Scharfetter |
Language | DE |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L1283: Basics of Nuclear Power Plants |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Uwe Kleen |
Language | DE |
Cycle | WiSe |
Content |
The lecture is supplemented by solving example exercises and is accompanied by an excursion. |
Literature |
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Course L1285: Basics of Nuclear Power Plants |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Uwe Kleen |
Language | DE |
Cycle | WiSe |
Content |
The lecture is supplemented by solving example exercises and is accompanied by an excursion. |
Literature |
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Module M0949: Resources Oriented Sanitation Systems |
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Module Responsible | Prof. Ralf Otterpohl |
Admission Requirements |
None |
Recommended Previous Knowledge |
Basic knowledge of the global situation with rising poverty, soil degradation, lack of water resources and sanitation |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students can describe resources oriented wastewater systems mainly based on source control in detail. They can comment on techniques designed for reuse of water, nutrients and soil conditioners. Students are able to discuss a wide range of proven approaches in Rural Development from and for many regions of the world. |
Skills |
Students are able to design low-tech/low-cost sanitation, rural water supply, rainwater harvesting systems, measures for the rehabilitation of top soil quality combined with food and water security. Students can consult on the basics of soil building through “Holisitc Planned Grazing” as developed by Allan Savory. |
Personal Competence | |
Social Competence | |
Autonomy |
Students are in a position to work on a subject and to organize their work flow independently. They can also present on this subject. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written elaboration |
Examination duration and scale | During the course of the semester, the students work towards five mile stones. The work includes presentations and papers. Detailed information can be found at the beginning of the smester in the StudIP course module handbook. |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation General Process Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Environmental Engineering: Specialisation Water: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Water: Elective Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0941: Rural Development in Different Climates |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Ralf Otterpohl |
Language | EN |
Cycle | WiSe |
Content |
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Literature |
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Course L0942: Resources Oriented Sanitation: High and Low-Tech Options |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Prof. Ralf Otterpohl |
Language | EN |
Cycle | WiSe |
Content |
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Literature |
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Course L0504: Resources Oriented Sanitation: High - and Low - Tech Options |
Typ | Laboratory Course |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Holger Gulyas |
Language | EN |
Cycle | WiSe |
Content |
- Construction of urine-diverting toilets - Comparison of stored and fresh urine: ammonia concentration - Comparison of stored and fresh urine: alkalinity |
Literature |
Skript Steven A. Esrey, Jean Gough, Dave Rapaport, Ron Sawyer, Mayling Simpson-Hébert, Jorge Vargas and Uno Winblad: Ecological Sanitation, SIDA, Stockholm 1998, http://www.ecosanres.org/pdf_files/Ecological_Sanitation.pdf |
Module M0512: Use of Solar Energy |
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Courses | ||||||||||||||||||||
|
Module Responsible | Prof. Martin Kaltschmitt |
Admission Requirements | none |
Recommended Previous Knowledge | none |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
With the completion of this module, students will be able to deal with technical foundations and current issues and problems in the field of solar energy and explain and evaulate these critically in consideration of the prior curriculum and current subject specific issues. In particular they can professionally describe the processes within a solar cell and explain the specific features of application of solar modules. Furthermore, they can provide an overview of the collector technology in solar thermal systems. |
Skills |
Students can apply the acquired theoretical foundations of exemplary energy systems using solar radiation. In this context, for example they can assess and evaluate potential and constraints of solar energy systems with respect to different geographical assumptions. They are able to dimension solar energy systems in consideration of technical aspects and given assumptions. Using module-comprehensive knowledge students can evalute the economic and ecologic conditions of these systems. They can select calculation methods within the radiation theory for these topics. |
Personal Competence | |
Social Competence |
|
Autonomy |
Students can independently exploit sources and acquire the particular knowledge about the subject area with respect to emphasis fo the lectures. Furthermore, with the assistance of lecturers, they can discrete use calculation methods for analysing and dimensioning solar energy systems. Based on this procedure they can concrete assess their specific learning level and can consequently define the further workflow. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 3 hours written exam |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Renewable Energy: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Renewable Energies: Core qualification: Compulsory Theoretical Mechanical Engineering: Specialisation Energy Systems: Elective Compulsory |
Course L0018: Collector Technology |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Agis Papadopoulos |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Course L0015: Solar Power Generation |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Martin Schlecht, Dietmar Obst |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Course L0016: Radiation and Optic |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Volker Matthias |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Course L0017: Radiation and Optic |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Steffen Beringer |
Language | DE |
Cycle | SoSe |
Content |
Applications of stages of calculation within the radiation gauge. |
Literature | siehe Vorlesungsscript |
Module M0513: System Aspects of Renewable Energies |
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Courses | ||||||||||||||||||||
|
Module Responsible | Prof. Martin Kaltschmitt |
Admission Requirements | none |
Recommended Previous Knowledge | none |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students are able to describe the processes in energy trading and the design of energy markets and can critically evaluate them in relation to current subject specific problems. Furthermore, they are able to explain the basics of thermodynamics of electrochemical energy conversion in fuel cells and can establish and explain the relationship to different types of fuel cells and their respective structure. Students can compare this technology with other energy storage options. In addition, students can give an overview of the procedure and the energetic involvement of deep geothermal energy. |
Skills |
Students can apply the learned knowledge of storage systems for excessive energy to explain for various energy systems different approaches to ensure a secure energy supply. In particular, they can plan and calculate domestic, commercial and industrial heating equipment using energy storage systems in an energy-efficient way and can assess them in relation to complex power systems. In this context, students can assess the potential and limits of geothermal power plants and explain their operating mode. Furthermore, the students are able to explain the procedures and strategies for marketing of energy and apply it in the context of other modules on renewable energy projects. In this context they can unassistedly carry out analysis and evaluations of energie markets and energy trades. |
Personal Competence | |
Social Competence | |
Autonomy |
Students can independently exploit sources , acquire the particular knowledge about the subject area and transform it to new questions. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 3 hours written exam |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Renewable Energy: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Renewable Energies: Core qualification: Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory |
Course L0021: Fuel Cells, Batteries, and Gas Storage: New Materials for Energy Production and Storage |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Fröba |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Course L0019: Energy Trading |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Michael Sagorje, Jörg Seidel |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
Course L0020: Energy Trading |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Michael Sagorje, Jörg Seidel |
Language | DE |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0025: Deep Geothermal Energy |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Ben Norden |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Module M0721: Air Conditioning |
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Courses | ||||||||||||
|
Module Responsible | Prof. Gerhard Schmitz |
Admission Requirements | none |
Recommended Previous Knowledge | Technical Thermodynamics I, II, Fluid Dynamics, Heat Transfer |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students know the different kinds of air conditioning systems for buildings and mobile applications and how these systems are controlled. They are familiar with the change of state of humid air and are able to draw the state changes in a h1+x,x-diagram. They are able to calculate the minimum airflow needed for hygienic conditions in rooms and can choose suitable filters. They know the basic flow pattern in rooms and are able to calculate the air velocity in rooms with the help of simple methods. They know the principles to calculate an air duct network. They know the different possibilities to produce cold and are able to draw these processes into suitable thermodynamic diagrams. They know the criteria for the assessment of refrigerants. |
Skills |
Students are able to configure air condition systems for buildings and mobile applications. They are able to calculate an air duct network and have the ability to perform simple planning tasks, regarding natural heat sources and heat sinks. They can transfer research knowledge into practice. They are able to perform scientific work in the field of air conditioning. |
Personal Competence | |
Social Competence |
The students are able to discuss in small groups and develop an approach.
|
Autonomy |
Students are able to define independently tasks, to get new knowledge from existing knowledge as well as to find ways to use the knowledge in practice. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 60 min |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Elective Compulsory Energy Systems: Specialisation Marine Engineering: Elective Compulsory Aircraft Systems Engineering: Specialisation Aircraft Systems Engineering: Elective Compulsory Aircraft Systems Engineering: Specialisation Cabin Systems: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Theoretical Mechanical Engineering: Specialisation Energy Systems: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory |
Course L0594: Air Conditioning |
Typ | Lecture |
Hrs/wk | 3 |
CP | 5 |
Workload in Hours | Independent Study Time 108, Study Time in Lecture 42 |
Lecturer | Prof. Gerhard Schmitz |
Language | DE |
Cycle | SoSe |
Content |
1. Overview 1.1 Kinds of air conditioning systems 1.2 Ventilating 1.3 Function of an air condition system 2. Thermodynamic processes 2.1 Psychrometric chart 2.2 Mixer preheater, heater 2.3 Cooler 2.4 Humidifier 2.5 Air conditioning process in a Psychrometric chart 2.6 Desiccant assisted air conditioning 3. Calculation of heating and cooling loads 3.1 Heating loads 3.2 Cooling loads 3.3 Calculation of inner cooling load 3.4 Calculation of outer cooling load 4. Ventilating systems 4.1 Fresh air demand 4.2 Air flow in rooms 4.3 Calculation of duct systems 4.4 Fans 4.5 Filters 5. Refrigeration systems 5.1. compression chillers 5.2Absorption chillers |
Literature |
|
Course L0595: Air Conditioning |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Gerhard Schmitz |
Language | DE |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M0749: Waste Treatment and Solid Matter Process Technology |
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Courses | ||||||||||||||||
|
Module Responsible | Prof. Kerstin Kuchta |
Admission Requirements | none |
Recommended Previous Knowledge |
Basics of
|
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students can describe current issue and problems in the field of thermal waste treatment and particle process engineering. The industrial application of unit operations as part of process engineering is explained by actual examples of waste incineration technologies and solid biomass processes. Compostion, particle sizes, transportation and dosing, drying and agglomeration of renewable resources and wastes are described as important unit operations when producing solid fuels and bioethanol, producing and refining edible oils, electricity , heat and mineral recyclables. |
Skills |
The students are able to select suitable processes for the treatment of wastes or raw material with respect to their characteristics and the process aims. They can evaluate the efforts and costs for processes and select economically feasible treatment concepts. |
Personal Competence | |
Social Competence |
Students can
|
Autonomy |
Students can independently tap knowledge of the subject area and transform it to new questions. They are capable, in consultation with supervisors, to assess their learning level and define further steps on this basis. Furthermore, they can define targets for new application-or research-oriented duties in accordance with the potential social, economic and cultural impact. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 120 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Renewable Energies: Specialisation Bio energies: Elective Compulsory Process Engineering: Specialisation Chemical Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0052: Solid Matter Process Technology for Biomass |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Werner Sitzmann |
Language | DE |
Cycle | SoSe |
Content | The industrial application of unit operations as part of process engineering is explained by actual examples of solid biomass processes. Size reduction, transportation and dosing, drying and agglomeration of renewable resources are described as important unit operations when producing solid fuels and bioethanol, producing and refining edible oils, when making Btl - and WPC - products. Aspects of explosion protection and plant design complete the lecture. |
Literature |
Kaltschmitt M., Hartmann H. (Hrsg.): Energie aus Bioamsse, Springer Verlag, 2001, ISBN 3-540-64853-4 Bundesministerium für Ernährung, Landwirtschaft und Verbraucherschutz, Schriftenreihe Nachwachsende Rohstoffe, Fachagentur Nachwachsende Rohstoffe e.V. www.nachwachsende-rohstoffe.de Bockisch M.: Nahrungsfette und -öle, Ulmer Verlag, 1993, ISBN 380000158175 |
Course L0320: Thermal Waste Treatment |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Kerstin Kuchta, Dr. Joachim Gerth, Dr. Ernst-Ulrich Hartge |
Language | EN |
Cycle | SoSe |
Content |
|
Literature |
Thomé-Kozmiensky, K. J. (Hrsg.): Thermische Abfallbehandlung Bande 1-7. EF-Verlag für Energie- und Umwelttechnik, Berlin, 196 - 2013. |
Course L1177: Thermal Waste Treatment |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 2 |
Workload in Hours | Independent Study Time 46, Study Time in Lecture 14 |
Lecturer | Dr. Ernst-Ulrich Hartge, Dr. Joachim Gerth |
Language | EN |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M0906: Molecular Modeling and Computational Fluid Dynamics |
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Courses | ||||||||||||||||
|
Module Responsible | Prof. Michael Schlüter |
Admission Requirements | None |
Recommended Previous Knowledge |
|
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
After successful completion of the module the students are able to
|
Skills |
The students are able to:
|
Personal Competence | |
Social Competence |
The students are able to
|
Autonomy |
The students are able to:
|
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Oral exam |
Examination duration and scale | 1h examen in teams |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Bioprocess Engineering: Specialisation B - Industrial Bioprocess Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation Chemical Process Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation General Process Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Theoretical Mechanical Engineering: Core qualification: Elective Compulsory Process Engineering: Specialisation Chemical Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory |
Course L1375: Computational Fluid Dynamics - Exercises in OpenFoam |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Michael Schlüter |
Language | EN |
Cycle | SoSe |
Content |
|
Literature | OpenFoam Tutorials (StudIP) |
Course L1052: Computational Fluid Dynamics in Process Engineering |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Michael Schlüter |
Language | EN |
Cycle | SoSe |
Content |
|
Literature |
Paschedag A.R.: CFD in der Verfahrenstechnik: Allgemeine Grundlagen und mehrphasige Anwendungen, Wiley-VCH, 2004 ISBN 3-527-30994-2. Ferziger, J.H.; Peric, M.: Numerische Strömungsmechanik. Springer-Verlag, Berlin, 2008, ISBN: 3540675868. Ferziger, J.H.; Peric, M.: Computational Methods for Fluid Dynamics. Springer, 2002, ISBN 3-540-42074-6
|
Course L0099: Statistical Thermodynamics and Molecular Modelling |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Dr. Sven Jakobtorweihen |
Language | EN |
Cycle | SoSe |
Content |
|
Literature |
Daan Frenkel, Berend Smit: Understanding Molecular Simulation, Academic Press M. P. Allen, D. J. Tildesley: Computer Simulations of Liquids, Oxford Univ. Press A.R. Leach: Molecular Modelling – Principles and Applications, Prentice Hall, N.Y. D. A. McQuarrie: Statistical Mechanics, University Science Books T. L. Hill: Statistical Mechanics , Dover Publications |
Module M0847: Analytical Methods and Treatment Technologies for Wastewaters |
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Courses | ||||||||||||
|
Module Responsible | NN |
Admission Requirements | none |
Recommended Previous Knowledge | Fundamental knowledge in chemistry and physics (knowledge acquired at school) |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge | The students know some non-biological processes for the treatment of water and wastewater as well as the fundamentals of mass transfer which is essential for many treatment processes. They have knowledge about analytical procedures which can be applied even without the availability of a laboratory and which are useful for evaluating the performance of (waste)water treatment processes and the assessment of surface water quality in an economically feasible way. |
Skills | The students are able to select suitable processes for the treatment of wastewaters with respect to their characteristics. They can evaluate the efforts and costs for analytical procedures for the characterization of waters/wastewaters and select economically feasible analytical procedures. |
Personal Competence | |
Social Competence | The students have the competence to plan and to perform wastewater analyses together with colleagues in small groups and to efficiently distribute the respective tasks within the group. |
Autonomy | The students are capable to make their own decisions with respect to the selection of suitable water/wastewater treatment processes as well as economically feasible analytical procedures for water/wastewater characterization. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Oral exam |
Examination duration and scale | 30 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Environmental Engineering: Specialisation Water: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Water: Elective Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering: Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0505: Low-Cost Procedures for Water and Wastewater Analysis |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | NN |
Language | EN |
Cycle | WiSe |
Content |
1 Introduction 2 Costing of wastewater and water analyses 3 Parameters routinely measured in municipal wastewater effluents 4 Surrogate parameters 5 Field methods 6 Basic laboratory instruments and equipment 6.1 Balances 6.2 Volumetric dosing instruments 6.3 Photometer 6.3.1 General 6.3.2 Principle of photometry 6.3.3 Elements of a photometer 6.4 Deionised water supply 6.5 Safety equipment 7 Inorganic parameters 7.1 Inorganic parameters by probes/electrodes 7.1.1 Dissolved oxygen 7.1.1.1 Polarographic measurement of dissolved oxygen 7.1.1.2 Optical probe for measuring dissolved oxygen utilising luminescence quenching of oxygen 7.1.1.3 Titrimetric determination of dissolved oxygen 7.1.2 pH 7.1.3 Alkalinity 7.1.4 Electric conductivity/salinity 7.2 Nitrogen and phosphorus compounds (nutrients) 7.2.1 Colorimetric methods without expensive instruments 7.2.2 Reflectometric methods 7.2.3 Photometric methods 8 Particles in water and wastewater 9 Organic sum parameters 9.1 Overview 9.2 Chemical Oxygen Demand: Why to avoid COD analyses by the dichromate method? 9.3 TOC cuvette tests 9.4 Absorption of UV light (254 nm) as a surrogate parameter for COD 9.5 Volatile Solids as surrogate for COD 9.6 Biological oxygen demand 10 Microbiological parameters determined in a low-cost way 11 Toxicity toward activated sludge |
Literature | Skript auf StudIP |
Course L0482: Physico-Chemical Water Treatment |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | NN |
Language | EN |
Cycle | WiSe |
Content |
- Stripping - Ozonation |
Literature |
Physical-Chemical Treatment of Water and Wastewater, A.P. Sincero, G.A. Sincero, CRC Press, Boca Raton 2003; |
Module M0900: Examples in Solid Process Engineering |
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Courses | ||||||||||||||||||||
|
Module Responsible | Prof. Stefan Heinrich |
Admission Requirements | None |
Recommended Previous Knowledge | Knowledge from the module particle technology |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge | After completion of the module the students will be able to describe based on examples the assembly of solids engineering processes consisting of multiple apparatuses and subprocesses. They are able to describe the coaction and interrelation of subprocesses. |
Skills | Students are able to analyze tasks in the field of solids process engineering and to combine suitable subprocesses in a process chain. |
Personal Competence | |
Social Competence | Students are able to discuss technical problems in a scientific manner. |
Autonomy | |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 120 minutes |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Renewable Energies: Specialisation Bio energies: Elective Compulsory Renewable Energies: Specialisation Bio energies: Elective Compulsory Process Engineering: Specialisation Chemical Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering: Elective Compulsory |
Course L0431: Fluidization Technology |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Stefan Heinrich |
Language | EN |
Cycle | WiSe |
Content |
Introduction: definition, fluidization
regimes, comparison with other types of gas/solids reactors |
Literature |
Kunii, D.; Levenspiel, O.: Fluidization Engineering. Butterworth Heinemann, Boston, 1991. |
Course L1369: Practical Course Fluidization Technology |
Typ | Laboratory Course |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Stefan Heinrich |
Language | EN |
Cycle | WiSe |
Content |
Experiments:
|
Literature |
Kunii, D.; Levenspiel, O.: Fluidization Engineering. Butterworth Heinemann, Boston, 1991. |
Course L0955: Technical Applications of Particle Technology |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Werner Sitzmann |
Language | DE |
Cycle | WiSe |
Content | Unit operations like mixing, separation, agglomeration and size reduction are discussed concerning their technical applicability from the perspective of the practician. Machines and apparatuses are presented, their designs and modes of action are explained and their application in production processes for chemicals, food and feed and in recycling processes are illustrated. |
Literature | Stieß M: Mechanische Verfahrenstechnik I und II, Springer - Verlag, 1997 |
Course L1372: Exercises in Fluidization Technology |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Stefan Heinrich |
Language | EN |
Cycle | WiSe |
Content |
Exercises and calculation examples for the lecture Fluidization Technology |
Literature |
Kunii, D.; Levenspiel, O.: Fluidization Engineering. Butterworth Heinemann, Boston, 1991. |
Module M0904: Process Design Project |
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Courses | ||||||||
|
Module Responsible | Dozenten des SD V |
Admission Requirements | none |
Recommended Previous Knowledge |
|
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
After the students passed the project course successfully they know:
|
Skills |
After passing the Module successfully the students are able to:
|
Personal Competence | |
Social Competence |
The students are able to discuss in international teams in english and develop an approach under pressure of time. |
Autonomy |
Students are able to define independently tasks, to get new knowledge from existing knowledge as well as to find ways to use the knowledge in practice. They are able to organize their own team and to define priorities. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Project |
Examination duration and scale | |
Assignment for the Following Curricula |
Bioprocess Engineering: Core qualification: Compulsory Chemical and Bioprocess Engineering: Core qualification: Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Process Engineering: Core qualification: Compulsory |
Course L1050: Process Design Project |
Typ | Projection Course |
Hrs/wk | 6 |
CP | 6 |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Lecturer | NN |
Language | DE |
Cycle | WiSe |
Content |
In the Process Design Project the students have to design in teams an energy or process engineering plant by calculating and designing single plant components. The calculation of costs as well as the process safety is another important aspect of this course. Furthermore the approval procedures have to be taken into account. |
Literature |
Module M0802: Membrane Technology |
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Courses | ||||||||||||||||
|
Module Responsible | Prof. Mathias Ernst |
Admission Requirements |
None |
Recommended Previous Knowledge |
Basic knowledge of water chemistry. Knowledge of the core processes involved in water, gas and steam treatment |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students will be able to rank the technical applications of industrially important membrane processes. They will be able to explain the different driving forces behind existing membrane separation processes. Students will be able to name materials used in membrane filtration and their advantages and disadvantages. Students will be able to explain the key differences in the use of membranes in water, other liquid media, gases and in liquid/gas mixtures. |
Skills |
Students will be able to prepare mathematical equations for material transport in porous and solution-diffusion membranes and calculate key parameters in the membrane separation process. They will be able to handle technical membrane processes using available boundary data and provide recommendations for the sequence of different treatment processes. Through their own experiments, students will be able to classify the separation efficiency, filtration characteristics and application of different membrane materials. Students will be able to characterise the formation of the fouling layer in different waters and apply technical measures to control this. |
Personal Competence | |
Social Competence |
Students will be able to work in diverse teams on tasks in the field of membrane technology. They will be able to make decisions within their group on laboratory experiments to be undertaken jointly and present these to others. |
Autonomy |
Students will be in a position to solve homework on the topic of membrane technology independently. They will be capable of finding creative solutions to technical questions. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 90 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Bioprocess Engineering: Specialisation B - Industrial Bioprocess Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation Chemical Process Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation General Process Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Environmental Engineering: Specialisation Water: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Water: Elective Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering: Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0399: Membrane Technology |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Prof. Mathias Ernst |
Language | EN |
Cycle | WiSe |
Content |
The lecture on membrane technology supply provides students with a broad understanding of existing membrane treatment processes, encompassing pressure driven membrane processes, membrane application in electrodialyis, pervaporation as well as membrane distillation. The lectures main focus is the industrial production of drinking water like particle separation or desalination; however gas separation processes as well as specific wastewater oriented applications such as membrane bioreactor systems will be discussed as well. Initially, basics in low pressure and high pressure membrane applications are presented (microfiltration, ultrafiltration, nanofiltration, reverse osmosis). Students learn about essential water quality parameter, transport equations and key parameter for pore membrane as well as solution diffusion membrane systems. The lecture sets a specific focus on fouling and scaling issues and provides knowledge on methods how to tackle with these phenomena in real water treatment application. A further part of the lecture deals with the character and manufacturing of different membrane materials and the characterization of membrane material by simple methods and advanced analysis. The functions, advantages and drawbacks of different membrane housings and modules are explained. Students learn how an industrial membrane application is designed in the succession of treatment steps like pre-treatment, water conditioning, membrane integration and post-treatment of water. Besides theory, the students will be provided with knowledge on membrane demo-site examples and insights in industrial practice. |
Literature |
|
Course L0400: Membrane Technology |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 2 |
Workload in Hours | Independent Study Time 46, Study Time in Lecture 14 |
Course work | Students can voluntarily hand in solutions to exercises. They can gather extra points with the handed-in solutions. The students are given more detailed information at the beginning of the course. |
Lecturer | Prof. Mathias Ernst |
Language | EN |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0401: Membrane Technology |
Typ | Laboratory Course |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Course work | Compulsory report: Students hand in a report about the carried out experiments. |
Lecturer | Prof. Mathias Ernst |
Language | EN |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M1294: Bioenergy |
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Courses | ||||||||||||||||||||||||
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Module Responsible | Prof. Martin Kaltschmitt |
Admission Requirements | None |
Recommended Previous Knowledge | none |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students are able to reproduce an in-depth outline of energy production from biomass, aerobic and anaerobic waste treatment processes, the gained products and the treatment of produced emissions. |
Skills |
Students can apply the learned theoretical knowledge of biomass-based energy systems to explain relationships for different tasks, like dimesioning and design of biomass power plants. In this context, students are also able to solve computational tasks for combustion, gasification and biogas, biodiesel and bioethanol use. |
Personal Competence | |
Social Competence | |
Autonomy |
Students can independently exploit sources with respect to the emphasis of the lectures. They can choose and aquire the for the particular task useful knowledge. Furthermore, they can solve computational tasks of biomass-based energy systems independently with the assistance of the lecture. Regarding to this they can assess their specific learning level and can consequently define the further workflow. |
Workload in Hours | Independent Study Time 82, Study Time in Lecture 98 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 3 hours written exam |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy and Environmental Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Elective Compulsory International Management and Engineering: Specialisation II. Renewable Energy: Elective Compulsory Renewable Energies: Core qualification: Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory |
Course L0061: Biofuels Process Technology |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Oliver Lüdtke |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
|
Course L0062: Biofuels Process Technology |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Oliver Lüdtke |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
Skriptum zur Vorlesung |
Course L1767: Thermal Utilization of Biomass |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Martin Kaltschmitt |
Language | DE |
Cycle | WiSe |
Content |
Goal of this course is it to discuss the physical, chemical, and biological as well as the technical, economic, and environmental basics of all options to provide energy from biomass from a German and international point of view. Additionally different system approaches to use biomass for energy, aspects to integrate bioenergy within the energy system, technical and economic development potentials, and the current and expected future use within the energy system are presented. The course is structured as follows:
|
Literature |
Kaltschmitt, M.; Hartmann, H. (Hrsg.): Energie aus Biomasse; Springer, Berlin, Heidelberg, 2009, 2. Auflage |
Course L1769: World Market for Agricultural Commodities |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Thomas Mielke |
Language | EN |
Cycle | WiSe |
Content | |
Literature |
Course L0010: Sustainable Mobility |
Typ | Lecture |
Hrs/wk | 2 |
CP | 1 |
Workload in Hours | Independent Study Time 2, Study Time in Lecture 28 |
Lecturer | Dr. Karsten Wilbrand |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
|
In this specialisation path three Modules must be chosen out of a number of compulsory selective lectures covering a wide spectrum of aspects of Energy Systems with practical professional relevance. Training in this specialisation path is concentrated mainly on electricity generation from conventional and renewable energy sources, encompassing electricity distribution too.
Module M0742: Thermal Engineering |
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Courses | ||||||||||||
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Module Responsible | Prof. Gerhard Schmitz |
Admission Requirements | none |
Recommended Previous Knowledge | Technical Thermodynamics I, II, Fluid Dynamics, Heat Transfer |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students know the different energy conversion stages and the difference between efficiency and annual efficiency. They have increased knowledge in heat and mass transfer, especially in regard to buildings and mobile applications. They are familiar with German energy saving code and other technical relevant rules. They know to differ different heating systems in the domestic and industrial area and how to control such heating systems. They are able to model a furnace and to calculate the transient temperatures in a furnace. They have the basic knowledge of emission formations in the flames of small burners and how to conduct the flue gases into the atmosphere. They are able to model thermodynamic systems with object oriented languages. |
Skills |
Students are able to calculate the heating demand for different heating systems and to choose the suitable components. They are able to calculate a pipeline network and have the ability to perform simple planning tasks, regarding solar energy. They can write Modelica programs and can transfer research knowledge into practice. They are able to perform scientific work in the field of thermal engineering. |
Personal Competence | |
Social Competence |
The students are able to discuss in small groups and develop an approach. |
Autonomy |
Students are able to define independently tasks, to get new knowledge from existing knowledge as well as to find ways to use the knowledge in practice. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 60 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Compulsory Energy Systems: Specialisation Marine Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Product Development, Materials and Production: Core qualification: Elective Compulsory Renewable Energies: Core qualification: Compulsory Theoretical Mechanical Engineering: Specialisation Energy Systems: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory |
Course L0023: Thermal Engineering |
Typ | Lecture |
Hrs/wk | 3 |
CP | 5 |
Workload in Hours | Independent Study Time 108, Study Time in Lecture 42 |
Lecturer | Prof. Gerhard Schmitz |
Language | DE |
Cycle | WiSe |
Content |
1. Introduction 2. Fundamentals of Thermal Engineering 2.1 Heat Conduction 2.2 Convection 2.3 Radiation 2.4 Heat transition 2.5 Combustion parameters 2.6 Electrical heating 2.7 Water vapor transport 3. Heating Systems 3.1 Warm water heating systems 3.2 Warm water supply 3.3 piping calculation 3.4 boilers, heat pumps, solar collectors 3.5 Air heating systems 3.6 radiative heating systems 4. Thermal traetment systems 4.1 Industrial furnaces 4.2 Melting furnaces 4.3 Drying plants 4.4 Emission control 4.5 Chimney calculation 4.6 Energy measuring 5. Laws and standards 5.1 Buildings 5.2 Industrial plants |
Literature |
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Course L0024: Thermal Engineering |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Gerhard Schmitz |
Language | DE |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M0511: Electricity Generation from Wind and Hydro Power |
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Courses | ||||||||||||||||||||
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Module Responsible | Dr. Joachim Gerth |
Admission Requirements | none |
Recommended Previous Knowledge |
Thermodynamics, Fluid Mechanics, Fundamentals of Fluid Flow Engines |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
By ending this module students can explain in detail knowledge of wind turbines with a particular focus of wind energy use in offshore conditions and can critical comment these aspects in consideration of current developments. Furthermore, they are able to describe fundamentally the use of water power to generate electricity. The students reproduce and explain the basic procedure in the implementation of renewable energy projects in countries outside Europe. |
Skills |
Students are able to apply the acquired theoretical foundations on exemplary water or wind power systems and evaluate and assess technically the resulting relationships in the context of dimensioning and operation of these energy systems. They can in compare critically the special procedure for the implementation of renewable energy projects in countries outside Europe with the in principle applied approach in Europe and can apply this procedure on exemplary theoretical projects. |
Personal Competence | |
Social Competence |
Students can discuss scientific tasks subjet-specificly and multidisciplinary within a seminar. |
Autonomy |
Students can independently exploit sources in the context of the emphasis of the lecture material to clear the contents of the lecture and to acquire the particular knowledge about the subject area. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 3 hours written exam |
Assignment for the Following Curricula |
Civil Engineering: Specialisation Structural Engineering: Elective Compulsory Civil Engineering: Specialisation Geotechnical Engineering: Elective Compulsory Civil Engineering: Specialisation Coastal Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Renewable Energy: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Product Development, Materials and Production: Specialisation Product Development: Elective Compulsory Product Development, Materials and Production: Specialisation Production: Elective Compulsory Product Development, Materials and Production: Specialisation Materials: Elective Compulsory Renewable Energies: Core qualification: Compulsory Water and Environmental Engineering: Specialisation Environment: Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0014: Renewable Energy Projects in Emerged Markets |
Typ | Project Seminar |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Andreas Wiese |
Language | DE |
Cycle | SoSe |
Content |
|
Literature | Folien der Vorlesung |
Course L0013: Hydro Power Use |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Stephan Heimerl |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
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Course L0011: Wind Turbine Plants |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Dr. Rudolf Zellermann |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
Gasch, R., Windkraftanlagen, 4. Auflage, Teubner-Verlag, 2005 |
Course L0012: Wind Energy Use – Focus Offshore |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Martin Skiba |
Language | DE |
Cycle | SoSe |
Content |
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Literature |
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Module M0641: Steam Generators |
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Courses | ||||||||||||
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Module Responsible | Prof. Alfons Kather |
Admission Requirements |
None |
Recommended Previous Knowledge |
Knowledge in Thermodynamics, Heat Transfer, Fluid Mechanics and Steam Power Plants |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students outline the steam thermodynamics and the technical types of steam generators. They are in a position to describe the basic principles of steam generators and highlight the combustion and fuel supply aspects of fossil-fuelled power plants. They can perform thermal design calculations and conceive the water-steam side, as well as determine the constructive details of the steam generator. The students can describe and evaluate the operational behaviour of steam generators and explain these also in the context of adjoining subjects. |
Skills |
The students will be able, using detailed knowledge on the calculation, design and construction of steam generators linked with a wide theoretical and methodical foundation, to understand the main design and construction aspects of steam generators. Through problem definition and formulation, modelling of processes and training in the solution methodology for partial problems they obtain a good overview of this key component of the power plant. Within the framework of the exercise the students obtain the ability to draw the balances and dimension the steam generator and its components. For this purpose small but close to reality tasks are solved, to highlight aspects of the design of steam generators. |
Personal Competence | |
Social Competence |
An excursion within the framework of the lecture is planned for those students that are interested. In this come the students in direct contact with the whole subject field of gas and steam generators. Through discussions with the plant personnel they obtain an overview of the daily operation problems and their solution approach. |
Autonomy |
The students assisted by the tutors will be able to develop alone basic calculations covering partial aspects of the steam generator. In this manner the theoretical and practical knowledge from the lecture is consolidated and the potential effects from different process schemata and boundary conditions highlighted. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 120 min |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Energy Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Elective Compulsory Energy Systems: Specialisation Marine Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory |
Course L0213: Steam Generators |
Typ | Lecture |
Hrs/wk | 3 |
CP | 5 |
Workload in Hours | Independent Study Time 108, Study Time in Lecture 42 |
Lecturer | Prof. Alfons Kather |
Language | DE |
Cycle | SoSe |
Content |
|
Literature |
|
Course L0214: Steam Generators |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Alfons Kather |
Language | DE |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M1000: Combined Heat and Power and Combustion Technology |
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Courses | ||||||||||||
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Module Responsible | Prof. Alfons Kather |
Admission Requirements |
None |
Recommended Previous Knowledge |
Knowledge in Thermodynamics incl. Combustion Calculations, Heat Transfer and Fluid Mechanics |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students outline the thermodynamic and chemical fundamentals of combustion processes. From the knowledge of the characteristics and reaction kinetics of various fuels they can describe the behaviour of premixed flames and non-premixed flames, in order to describe the fundamentals of furnace design in gas-, oil- and coal combustion plant. The students are furthermore able to describe the formation of NOx and the primary NOx reduction measures and evaluate the impact of regulations and allowable limit levels. The students present the layout, design and operation of Combined Heat and Power plants and are in a position to compare with each other district heating plants with back-pressure steam turbine or condensing turbine with pressure-controlled extraction tapping, CHP plants with gas turbine or with combined steam and gas turbine, and district heating plants with motor engine. They can explain and analyse aspects of combined heat, power and cooling (CCHP) and describe the layout of the key components needed. Through this specialised knowledge they are able to evaluate the economical and ecological significance of district CHP plants, as well as their economics. |
Skills |
Using thermodynamic calculations and considering the reaction kinetics the students will be able to determine interdisciplinary correlations between thermodynamic and chemical processes during combustion. This then enables quantitative analysis of the combustion of gaseous, liquid and solid fuels and determination of the quantities and concentrations of the exhaust gases. In this module the first step toward the utilisation of an energy source (combustion) to provide usable energy (electricity and heat) is taught. An understanding of both procedures enables the students to do holistic considerations of energy utilisation. Examples taken from the praxis, such as the energy supply within the TUHH and the district heating network of Hamburg will be used, to highlight the potential from electricity generation plants with simultaneous heat extraction. Within the framework of the exercises the students will first learn to calculate the energetic and mass balances of combustion processes. Moreover the students will gain a deeper understanding of the combustion processes by the calculation of reaction kinetics and fundamentals of burner design. In order to perform further analyses they will familiarise themselves to the specialised software suite EBSILON ProfessionalTM. With this tool small and close to reality tasks are solved on the PC, to highlight aspects of the design and balancing of heating plant cycles. In addition CHP will also be considered in its economic and social contexts. |
Personal Competence | |
Social Competence |
Especially during the exercises the focus is on communication with the teaching person. By this the students are animated to reflect on their existing knowledge and to ask specific questions for improving their knowledge level. |
Autonomy |
The students assisted by the tutors will be able to develop simulation models independently and run scenario analyses as well as estimating calculations. In this manner the theoretical and practical knowledge from the lecture is consolidated and the potential effects from different process arrangements and boundary conditions are highlighted. |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 120 min |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Energy Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Compulsory Energy Systems: Specialisation Marine Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Theoretical Mechanical Engineering: Specialisation Energy Systems: Elective Compulsory |
Course L0216: Combined Heat and Power and Combustion Technology |
Typ | Lecture |
Hrs/wk | 3 |
CP | 5 |
Workload in Hours | Independent Study Time 108, Study Time in Lecture 42 |
Lecturer | Prof. Alfons Kather |
Language | DE |
Cycle | SoSe |
Content |
In the subject area of "Combined Heat and Power" covers the following themes:
whereas the subject of Combustion Technology includes:
|
Literature |
Bezüglich des Themenbereichs "Kraft-Wärme-Kopplung":
und für die Grundlagen der "Verbrennungstechnik":
|
Course L0220: Combined Heat and Power and Combustion Technology |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Alfons Kather |
Language | DE |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M1235: Electrical Power Systems I |
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Courses | ||||||||||||
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Module Responsible | Prof. Christian Becker |
Admission Requirements | none |
Recommended Previous Knowledge |
Fundamentals of Electrical Engineering |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students are able to give an overview of conventional and modern electric power systems. They can explain in detail and critically evaluate technologies of electric power generation, transmission, storage, and distribution as well as integration of equipment into electric power systems. |
Skills |
With completion of this module the students are able to apply the acquired skills in applications of the design, integration, development of electric power systems and to assess the results. |
Personal Competence | |
Social Competence |
The students can participate in specialized and interdisciplinary discussions, advance ideas and represent their own work results in front of others. |
Autonomy |
Students can independently tap knowledge of the emphasis of the lectures. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 90 - 150 minutes |
Assignment for the Following Curricula |
General Engineering Science (German program, 7 semester): Specialisation Electrical Engineering: Elective Compulsory Electrical Engineering: Core qualification: Elective Compulsory Energy and Environmental Engineering: Specialisation Energy Engineering: Elective Compulsory Energy Systems: Specialisation Energy Systems: Elective Compulsory Energy Systems: Specialisation Energy Systems: Elective Compulsory General Engineering Science (English program, 7 semester): Specialisation Electrical Engineering: Elective Compulsory Computational Science and Engineering: Specialisation Engineering Sciences: Elective Compulsory Renewable Energies: Core qualification: Compulsory Renewable Energies: Core qualification: Compulsory |
Course L1670: Electrical Power Systems I |
Typ | Lecture |
Hrs/wk | 3 |
CP | 4 |
Workload in Hours | Independent Study Time 78, Study Time in Lecture 42 |
Lecturer | Prof. Christian Becker |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
K. Heuck, K.-D. Dettmann, D. Schulz: "Elektrische Energieversorgung", Vieweg + Teubner, 9. Auflage, 2014 A. J. Schwab: "Elektroenergiesysteme", Springer, 3. Auflage, 2012 R. Flosdorff: "Elektrische Energieverteilung" Vieweg + Teubner, 9. Auflage, 2005 |
Course L1671: Electrical Power Systems I |
Typ | Recitation Section (large) |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Christian Becker |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
K. Heuck, K.-D. Dettmann, D. Schulz: "Elektrische Energieversorgung", Vieweg + Teubner, 9. Auflage, 2014 A. J. Schwab: "Elektroenergiesysteme", Springer, 3. Auflage, 2012 R. Flosdorff: "Elektrische Energieverteilung" Vieweg + Teubner, 9. Auflage, 2005 |
In this specialisation path three Modules must be chosen out of a number of compulsory selective lectures covering a wide spectrum of aspects of Environmental Engineering with practical professional relevance. Training in this specialisation path is concentrated mainly on the environmental protection of soil, water and air. An extensive overview of the various technical solutions in these areas is offered, to prepare the graduates for a successful subsequent entry into the profession of Environmental Engineer.
Module M0830: Environmental Protection and Management |
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Courses | ||||||||||||||||
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Module Responsible | NN |
Admission Requirements | none |
Recommended Previous Knowledge |
|
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The students are able to describe the basics of regulations, economic instruments, voluntary initiatives, fundamentals of HSE legislation ISO 14001, EMAS and Responsible Care ISO 14001 requirements. They can analyse and discuss industrial processes, substance cycles and approaches from end-of-pipe technology to eco-efficiency and eco-effectiveness, showing their sound knowledge of complex industry related problems. They are able to judge environmental issues and to widely consider, apply or carry out innovative technical solutions, remediation measures and further interventions as well as conceptual problem solving approaches in the full range of problems in different industrial sectors. |
Skills |
Students are able to assess current problems and situations in the field of environmental protection. They can consider the best available techniques and to plan and suggest concrete actions in a company- or branch-specific context. By this means they can solve problems on a technical, administrative and legislative level. |
Personal Competence | |
Social Competence |
The students can work together in international groups. |
Autonomy |
Students are able to organize their work flow to prepare themselves for presentations and contributions to the discussions. They can acquire appropriate knowledge by making enquiries independently. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 90 min |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory Environmental Engineering: Core qualification: Compulsory International Production Management: Specialisation Management: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Water: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Energy: Elective Compulsory Product Development, Materials and Production: Specialisation Product Development: Elective Compulsory Product Development, Materials and Production: Specialisation Production: Elective Compulsory Product Development, Materials and Production: Specialisation Materials: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Compulsory Water and Environmental Engineering: Specialisation Cities: Compulsory |
Course L0502: Integrated Pollution Control |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Stephan Köster |
Language | EN |
Cycle | WiSe |
Content |
The lecture focusses on:
|
Literature |
Course L0387: Health, Safety and Environmental Management |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Hans-Joachim Nau |
Language | EN |
Cycle | WiSe |
Content | Objectives of and benefit from HSE management From dilution and end-of-pipe technology to eco-efficiency and eco-effectiveness Behaviour control: regulations, economic instruments and voluntary initiatives Fundamentals of HSE legislation ISO 14001, EMAS and Responsible Care ISO 14001 requirements Environmental performance evaluation Risk management: hazard, risk and safety Health and safety at the workplace Crisis management |
Literature | C. Stephan: Industrial Health, Safety and Environmental Management, MV-Verlag, Münster, 2007/2012 (can be found in the library under GTG 315) |
Course L0388: Health, Safety and Environmental Management |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Hans-Joachim Nau |
Language | EN |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M0902: Wasterwater Treatment and Air Pollution Abatement |
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Courses | ||||||||||||
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Module Responsible | Dr. Ernst-Ulrich Hartge |
Admission Requirements | |
Recommended Previous Knowledge |
Basic knowledge of biology and chemistry basic knowledge of solids process engineering and separation technology |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
After successful completion of the module students are able to
|
Skills |
Students are able to
|
Personal Competence | |
Social Competence | |
Autonomy | |
Workload in Hours | Independent Study Time 124, Study Time in Lecture 56 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 90 min |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Chemical and Bioprocess Engineering: Specialisation General Process Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory Environmental Engineering: Specialisation Waste and Energy: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Water: Elective Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Compulsory Water and Environmental Engineering: Specialisation Cities: Compulsory |
Course L0517: Biological Wastewater Treatment |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Dr. Joachim Behrendt |
Language | DE/EN |
Cycle | WiSe |
Content |
Charaterisation of Wastewater |
Literature |
Gujer, Willi |
Course L0203: Air Pollution Abatement |
Typ | Lecture |
Hrs/wk | 2 |
CP | 3 |
Workload in Hours | Independent Study Time 62, Study Time in Lecture 28 |
Lecturer | Dr. Ernst-Ulrich Hartge |
Language | EN |
Cycle | WiSe |
Content |
In the lecture methods for the reduction of emissions from industrial plants are treated. At the beginning a short survey of the different forms of air pollutants is given. In the second part physical principals for the removal of particulate and gaseous pollutants form flue gases are treated. Industrial applications of these principles are demonstrated with examples showing the removal of specific compounds, e.g. sulfur or mercury from flue gases of incinerators. |
Literature |
Handbook of air pollution prevention and control, Nicholas P. Cheremisinoff. - Amsterdam [u.a.] : Butterworth-Heinemann, 2002 |
Module M0703: Soil and Groundwater Contamination |
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Courses | ||||||||||||||||
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Module Responsible | Prof. Wilfried Schneider |
Admission Requirements |
None |
Recommended Previous Knowledge |
Groundwater hydrology, Hydromechanics |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge | The students are able to analyse contamination in soils and groundwater. They are able to create remediation concepts as monitored attenuation and pump and treat. |
Skills |
The students are able to analyse contaminations in soils and groundwater using special engineering methods. They can do transport modelling in the unsaturated zone, estimations of groundwater pollution and analyse the impacts of remediation measures. They can forecast die distribution, mobility and remediation of non aquaous phase liquids in soil and groundwater. |
Personal Competence | |
Social Competence | The students are able to prepare complex contamination issues in teamwork and are able to find remediation measures. |
Autonomy | none |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | Klausur 60 min; Referat 15 min; |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0547: Contamination and Remediation |
Typ | Project Seminar |
Hrs/wk | 3 |
CP | 3 |
Workload in Hours | Independent Study Time 48, Study Time in Lecture 42 |
Lecturer | Prof. Wilfried Schneider |
Language | DE |
Cycle | SoSe |
Content | Processing of a complex soil and groundwater contamination site. Students perform analyses of data to detect the contamination and to analyse the groundwater hazard and to develop a concept for remediation of the damage. |
Literature | entfällt |
Course L0545: NAPL in Soil and Groundwater |
Typ | Lecture |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Wilfried Schneider |
Language | DE |
Cycle | SoSe |
Content | concept of capillarity, multi phase distribution in poraus media, residual saturation, rellative permeability, infiltration of NAPL into the subsurface, vertical distribution of LNAPL, specific volume |
Literature |
Charbeneau, R.J. (2000): Groundwater Hydraulics and pollutant Transport |
Course L0546: NAPL in Soil and Groundwater |
Typ | Recitation Section (small) |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Wilfried Schneider |
Language | DE |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Module M0874: Wastewater Systems |
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Courses | ||||||||||||||||||||
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Module Responsible | Prof. Ralf Otterpohl |
Admission Requirements | None |
Recommended Previous Knowledge |
Knowledge of wastewater management and the key processes involved in wastewater treatment. |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
Students are able to outline key areas of the full range of treatment systems in waste water management, as well as their mutual dependence for sustainable water protection. They can describe relevant economic, environmental and social factors. |
Skills |
Students are able to pre-design and explain the available wastewater treatment processes and the scope of their application in municipal and for some industrial treatment plants. |
Personal Competence | |
Social Competence | |
Autonomy |
Students are in a position to work on a subject and to organize their work flow independently. They can also present on this subject. |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 120 min |
Assignment for the Following Curricula |
Civil Engineering: Specialisation Structural Engineering: Elective Compulsory Civil Engineering: Specialisation Geotechnical Engineering: Elective Compulsory Civil Engineering: Specialisation Coastal Engineering: Elective Compulsory Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Process Engineering: Specialisation Environmental Process Engineering: Elective Compulsory Process Engineering: Specialisation Process Engineering : Elective Compulsory Water and Environmental Engineering: Specialisation Water: Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Compulsory |
Course L0934: Wastewater Systems - Collection, Treatment and Reuse |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Ralf Otterpohl |
Language | EN |
Cycle | SoSe |
Content |
•Understanding the global situation with water and wastewater •Regional planning and decentralised systems •Overview on innovative approaches •In depth knowledge on advanced wastewater treatment options for different situations, for end-of-pipe and reuse •Mathematical Modelling of Nitrogen Removal •Exercises with calculations and design |
Literature |
Henze, Mogens: George Tchobanoglous, Franklin L. Burton, H. David Stensel: |
Course L0943: Wastewater Systems - Collection, Treatment and Reuse |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Prof. Ralf Otterpohl |
Language | EN |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0357: Advanced Wastewater Treatment |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Joachim Behrendt |
Language | DE |
Cycle | SoSe |
Content |
Survey on advanced wastewater treatment reuse of reclaimed municipal wastewater Precipitation Flocculation Depth filtration Membrane Processes Activated carbon adsorption Ozonation "Advanced Oxidation Processes" Disinfection |
Literature |
Metcalf & Eddy, Wastewater Engineering: Treatment and Reuse, McGraw-Hill, Boston 2003 Wassertechnologie, H.H. Hahn, Springer-Verlag, Berlin 1987 Membranverfahren: Grundlagen der Modul- und Anlagenauslegung, T. Melin und R. Rautenbach, Springer-Verlag, Berlin 2007 Trinkwasserdesinfektion: Grundlagen, Verfahren, Anlagen, Geräte, Mikrobiologie, Chlorung, Ozonung, UV-Bestrahlung, Membranfiltration, Qualitätssicherung, W. Roeske, Oldenbourg-Verlag, München 2006 Organische Problemstoffe in Abwässern, H. Gulyas, GFEU, Hamburg 2003 |
Course L0358: Advanced Wastewater Treatment |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Lecturer | Dr. Joachim Behrendt |
Language | DE |
Cycle | SoSe |
Content |
Aggregate organic compounds (sum parameters) Industrial wastewater Processes for industrial wastewater treatment Precipitation Flocculation Activated carbon adsorption Recalcitrant organic compounds |
Literature |
Metcalf & Eddy, Wastewater Engineering: Treatment and Reuse, McGraw-Hill, Boston 2003 Wassertechnologie, H.H. Hahn, Springer-Verlag, Berlin 1987 Membranverfahren: Grundlagen der Modul- und Anlagenauslegung, T. Melin und R. Rautenbach, Springer-Verlag, Berlin 2007 Trinkwasserdesinfektion: Grundlagen, Verfahren, Anlagen, Geräte, Mikrobiologie, Chlorung, Ozonung, UV-Bestrahlung, Membranfiltration, Qualitätssicherung, W. Roeske, Oldenbourg-Verlag, München 2006 Organische Problemstoffe in Abwässern, H. Gulyas, GFEU, Hamburg 2003 |
Module M0857: Geochemical Engineering |
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Courses | ||||||||||||||||
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Module Responsible | Dr. Joachim Gerth |
Admission Requirements | none |
Recommended Previous Knowledge |
Fundamentals of inorganic/organic chemistry and biology |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
With the completion of this module students acquire profound knowledge of biogeochemical processes, the fate of pollutants in soil and groundwater, and techniques to deposit contaminated waste material. They are able to describe in principle the behaviour of chemicals in the environment. Students can explain and report the approach to remediate contaminated sites. |
Skills |
With the completion of this module students can apply the acquired theoretical knowledge to model cases of site pollution and critically assess the situation technically and conceptually. They are able to draw comparisons on different remediation strategies and techniques. Model projects can be devised and treated. |
Personal Competence | |
Social Competence |
Students can discuss technical and scientific tasks within a seminar subject specific and interdisciplinary . |
Autonomy |
Students can independently exploit sources , acquire the particular knowledge of the subject and apply it to new problems. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 2 hours |
Assignment for the Following Curricula |
Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory Environmental Engineering: Core qualification: Elective Compulsory Water and Environmental Engineering: Specialisation Water: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0906: Contaminated Sites and Landfilling |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Joachim Gerth, Dr. Marco Ritzkowski |
Language | EN |
Cycle | SoSe |
Content |
The part Contaminated Sites gives an introduction into different scales of pollution and identifies key pollutants. Geochemical attenuation mechanisms and the role of organisms are highlighted affecting the fate of pollutants in leachate and groundwater. Techniques for site characterization and remediation are discussed including economical aspects. The part Landfilling is introduced by discussing fundamental aspects and the worldwide situation of waste management. The lecture highlights transformation processes in landfill bodies, emissions of gases and leachate, and the long-term behaviour of landfill sites with measures of aftercare. |
Literature |
1) Waste Management. Bernd Bilitewski; Georg Härdtle; Klaus Marek (Eds.), ISBN: 9783540592105 , Springer Verlag 3) Natural attenuation of fuels and chlorinated solvents in the subsurface. Todd H. Wiedemeier(Ed.), ISBN: 0471197491 Lesesaal 2: US - Umweltschutz, Signatur USH-844 |
Course L0907: Contaminated Sites and Landfilling |
Typ | Recitation Section (large) |
Hrs/wk | 1 |
CP | 2 |
Workload in Hours | Independent Study Time 46, Study Time in Lecture 14 |
Lecturer | Dr. Joachim Gerth, Dr. Marco Ritzkowski |
Language | EN |
Cycle | SoSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0904: Geochemical Engineering |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Dr. Joachim Gerth |
Language | EN |
Cycle | SoSe |
Content |
As an introduction cases are presented in which geochemical engineering was used to solve environmental problems. Environmentally important minerals are discussed and methods for their detection. It is demonstrated how solution equilibria can be modified to eliminate elevated concentrations of unwanted species in solution and how carbon dioxide concentration affects pH and the dissolution of carbonate minerals. Modifications of redox conditions, pH, and electrolyte concentration are shown to be effective tools for controlling the mobility and fate of hazardous species in the environment. |
Literature |
Geochemistry, groundwater and pollution. C. A. J. Appelo; D. Postma Leiden [u.a.] Balkema 2005 Lehrbuchsammlung der TUB, Signatur GWC-515 |
Module M0519: Particle Technology and Solid Matter Process Technology |
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Courses | ||||||||||||||||
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Module Responsible | Prof. Stefan Heinrich |
Admission Requirements | None |
Recommended Previous Knowledge | Basic knowledge of solids processes and particle technology |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge | After completion of the module the students will be able to describe and explain processes for solids processing in detail based on microprocesses on the particle level. |
Skills | Students are able to choose process steps and apparatuses for the focused treatment of solids depending on the specific characteristics. They furthermore are able to adapt these processes and to simulate them. |
Personal Competence | |
Social Competence |
Students are able to present results from small teamwork projects in an oral presentation and to discuss their knowledge with scientific researchers. |
Autonomy | |
Workload in Hours | Independent Study Time 96, Study Time in Lecture 84 |
Credit points | 6 |
Examination | Written exam |
Examination duration and scale | 90 minutes |
Assignment for the Following Curricula |
Bioprocess Engineering: Specialisation A - General Bioprocess Engineering: Elective Compulsory Bioprocess Engineering: Specialisation B - Industrial Bioprocess Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory International Management and Engineering: Specialisation II. Process Engineering and Biotechnology: Elective Compulsory Materials Science: Specialisation Nano and Hybrid Materials: Elective Compulsory Process Engineering: Core qualification: Compulsory |
Course L0050: Advanced Particle Technology II |
Typ | Lecture |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Stefan Heinrich |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
Schubert, H.; Heidenreich, E.; Liepe, F.; Neeße, T.: Mechanische Verfahrenstechnik. Deutscher Verlag für die Grundstoffindustrie, Leipzig, 1990. Stieß, M.: Mechanische Verfahrenstechnik I und II. Springer Verlag, Berlin, 1992. |
Course L0051: Advanced Particle Technology II |
Typ | Recitation Section (small) |
Hrs/wk | 1 |
CP | 1 |
Workload in Hours | Independent Study Time 16, Study Time in Lecture 14 |
Course work | A problem-based learning task is set at the beginning over the semester in StudIP. The students can work on the task during the semester under supervision of a tutor. Presenting their results with a poster, they can gain 5-10 extra points for the exam (100 points in total). |
Lecturer | Prof. Stefan Heinrich |
Language | DE |
Cycle | WiSe |
Content | See interlocking course |
Literature | See interlocking course |
Course L0430: Experimental Course Particle Technology |
Typ | Laboratory Course |
Hrs/wk | 3 |
CP | 3 |
Workload in Hours | Independent Study Time 48, Study Time in Lecture 42 |
Course work | Compulsory report: The students have to write five reports (one report for each experiment) with 5 to 10 pages. |
Lecturer | Prof. Stefan Heinrich |
Language | DE |
Cycle | WiSe |
Content |
|
Literature |
Schubert, H.; Heidenreich, E.; Liepe, F.; Neeße, T.: Mechanische Verfahrenstechnik. Deutscher Verlag für die Grundstoffindustrie, Leipzig, 1990. Stieß, M.: Mechanische Verfahrenstechnik I und II. Springer Verlag, Berlin, 1992. |
Module M0619: Waste Treatment Technologies |
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Courses | ||||||||||||
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Module Responsible | Prof. Kerstin Kuchta |
Admission Requirements | none |
Recommended Previous Knowledge | chemical and biological basics |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
The module aims possess knowledge concerning the planning of biological waste treatment plants. Students are able to explain the design and layout of anaerobic and aerobic waste treatment plants in detail, describe different techniques for waste gas treatment plants for biological waste treatment plants and explain different methods for waste analytics. |
Skills |
The students are able to discuss the compilation of design and layout of plants. They can critically evaluate techniques and quality control measurements. The students can recherché and evaluate literature and date connected to the tasks given in der module and plan additional tests. They are capable of reflecting and evaluating findings in the group. |
Personal Competence | |
Social Competence |
Students can participate in subject-specific and interdisciplinary discussions, develop cooperated solutions and defend their own work results in front of others and promote the scientific development in front of colleagues. Furthermore, they can give and accept professional constructive criticism. |
Autonomy |
Students can independently tap knowledge from literature, business or test reports and transform it to the course projects. They are capable, in consultation with supervisors as well as in the interim presentation, to assess their learning level and define further steps on this basis. Furthermore, they can define targets for new application-or research-oriented duties in accordance with the potential social, economic and cultural impact. |
Workload in Hours | Independent Study Time 110, Study Time in Lecture 70 |
Credit points | 6 |
Examination | Project |
Examination duration and scale | Elaboration and presentation (15-25 minutes in groups), successful participation at Praktikum |
Assignment for the Following Curricula |
Civil Engineering: Specialisation Structural Engineering: Elective Compulsory Civil Engineering: Specialisation Geotechnical Engineering: Elective Compulsory Civil Engineering: Specialisation Coastal Engineering: Elective Compulsory Energy and Environmental Engineering: Specialisation Environmental Engineering: Elective Compulsory Environmental Engineering: Core qualification: Compulsory International Management and Engineering: Specialisation II. Energy and Environmental Engineering: Elective Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Specialisation Energy: Elective Compulsory Water and Environmental Engineering: Specialisation Environment: Elective Compulsory Water and Environmental Engineering: Specialisation Cities: Elective Compulsory |
Course L0328: Waste and Environmental Chemistry |
Typ | Laboratory Course |
Hrs/wk | 2 |
CP | 2 |
Workload in Hours | Independent Study Time 32, Study Time in Lecture 28 |
Lecturer | Prof. Kerstin Kuchta |
Language | DE/EN |
Cycle | WiSe |
Content |
The participants are divided into groups. Each group prepares a transcript on the experiment performed, which is then used as basis for discussing the results and to evaluate the performance of the group and the individual student. In some experiments the test procedure and the results are presented in seminar form, accompanied by discussion and results evaluation. Experiments ar e.g. Screening and particle size determination Fos/Tac AAS Chalorific value |
Literature | Scripte |
Course L0318: Biological Waste Treatment |
Typ | Problem-based Learning |
Hrs/wk | 3 |
CP | 4 |
Workload in Hours | Independent Study Time 78, Study Time in Lecture 42 |
Lecturer | Prof. Kerstin Kuchta |
Language | EN |
Cycle | WiSe |
Content |
|
Literature |
Module M-002: Master Thesis |
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Courses | ||||
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Module Responsible | Professoren der TUHH |
Admission Requirements |
|
Recommended Previous Knowledge | |
Educational Objectives | After taking part successfully, students have reached the following learning results |
Professional Competence | |
Knowledge |
|
Skills |
The students are able:
|
Personal Competence | |
Social Competence |
Students can
|
Autonomy |
Students are able:
|
Workload in Hours | Independent Study Time 900, Study Time in Lecture 0 |
Credit points | 30 |
Examination | according to Subject Specific Regulations |
Examination duration and scale | see FSPO |
Assignment for the Following Curricula |
Civil Engineering: Thesis: Compulsory Bioprocess Engineering: Thesis: Compulsory Chemical and Bioprocess Engineering: Thesis: Compulsory Computer Science: Thesis: Compulsory Electrical Engineering: Thesis: Compulsory Energy and Environmental Engineering: Thesis: Compulsory Energy Systems: Thesis: Compulsory Environmental Engineering: Thesis: Compulsory Aircraft Systems Engineering: Thesis: Compulsory Global Innovation Management: Thesis: Compulsory Computational Science and Engineering: Thesis: Compulsory Information and Communication Systems: Thesis: Compulsory International Production Management: Thesis: Compulsory International Management and Engineering: Thesis: Compulsory Joint European Master in Environmental Studies - Cities and Sustainability: Thesis: Compulsory Logistics, Infrastructure and Mobility: Thesis: Compulsory Materials Science: Thesis: Compulsory Mechanical Engineering and Management: Thesis: Compulsory Mechatronics: Thesis: Compulsory Biomedical Engineering: Thesis: Compulsory Microelectronics and Microsystems: Thesis: Compulsory Product Development, Materials and Production: Thesis: Compulsory Renewable Energies: Thesis: Compulsory Naval Architecture and Ocean Engineering: Thesis: Compulsory Ship and Offshore Technology: Thesis: Compulsory Theoretical Mechanical Engineering: Thesis: Compulsory Process Engineering: Thesis: Compulsory Water and Environmental Engineering: Thesis: Compulsory |