Course detail

Balancing of Process and Energy Systems

FSI-KBP Acad. year: 2026/2027 Winter semester

Since balances represent a fundamental tool for process engineers, as well as for energy specialists, waste-management professionals, sustainability managers, and related roles, the aim of the course is to prepare students to use balances. The course also introduces students to typical situations in which balances are applied. In industrial processes, input materials and raw resources are transformed into final products and intermediates. This transformation requires energy, which must be utilized as efficiently as possible. However, some energy is inevitably lost or converted into low-grade waste heat that is difficult to exploit. Output streams may also include wastes in various forms, such as solid waste, liquid waste and wastewater, or gaseous emissions. Balances help describe and quantify how input streams are converted into output streams.

Performing a balance involves determining the flow rates, composition, and, where applicable, the temperatures of all streams at every point in the process. Students will be introduced to the fundamentals of mass and energy balances. Subsequent specialized courses in the study program build on this foundation. These courses further develop, practice, and apply balance-calculation skills, including the use of specialized (commercial) computational tools.

Language of instruction

Czech

Number of ECTS credits

5

Supervisor

doc. Ing. Martin Pavlas, Ph.D.

Department

Institute of Process Engineering

Entry knowledge

Knowledge from bachelor-level mathematics, physics, and thermodynamics is expected. Students will make use of their understanding of solving systems of linear equations and numerical methods for finding the solutions of nonlinear functions. The topic of unsteady-state balancing is also related to formulating differential equations and solving them.

Rules for evaluation and completion of the course

SEMINARS:
To receive course credit, students must participate regularly and actively in the exercises (which means no more than two excused absences), submit all assigned tasks, successfully pass the written tests, and complete a semester project carried out in small student groups. The project focuses on solving a selected example, allowing students to verify their understanding of balancing theory and demonstrate that the acquired knowledge can be applied to more complex problems. The criterion for earning the course credit is obtaining more than half of the total points available from the ongoing written tests.

Attendance at lectures is not formally monitored; however, completing the tasks in the exercises requires knowledge gained from the lectures.
EXAM:

The examination consists of three parts: a written test, computational problems, and an oral component.

  • Written test – This part assesses knowledge of the material covered in both lectures and exercises. The test contains 15 to 20 questions (the exact number may vary depending on the assignment). Questions may involve multiple-choice answers (A, B, C), simple calculations, or explanations of specific issues (sketches, descriptions, equations).
  • Computational problems – Students solve 2 to 3 calculation-based tasks, which may include solvability analysis, checking problem understanding, formulating balance equations, and, where required, solving them.
  • Oral part – Students explain selected slides from the presentations used during the semester.

Each part is assessed separately on a scale from A to F, and each part carries the same weight. A student must achieve at least an E in each part. An F is awarded if the student demonstrates less than half of the required knowledge (e.g., less than half of the points on the written test, solving none or only one of the computational problems, etc.). If a student receives an F in any part, they must repeat the entire examination. In all other cases, the final grade reflects the performance in each part.

Aims

After completing the course, students will:

  • Gain an overview of different types of balance problems, their complexity, and methods for constructing mass balances.
  • Learn that balancing is a general methodology based on the laws of conservation of mass, energy, and substances.
  • Be able to analyse balance problems in terms of the number of known and unknown variables, and formulate balance equations for cases involving mixing, splitting, and separating multiple material streams, both without chemical reactions and with simple reactions defined by a given conversion level.
  • Understand various ways of expressing energy balances for different types of systems.
  • Be able to solve simpler problems without computational tools or a computer, and solve selected cases with support from MS Excel.
  • Gain an understanding of how balancing relates to other methods used to evaluate projects from a sustainability perspective.
  • Understand how the EU Taxonomy influences the design of production technologies and processes.
  • Be able to apply balance-related knowledge to prepare data for non-financial reporting.
  • Be capable of creating basic Sankey diagrams as a visualization of material and energy flows.
  • Become familiar with the principles of greenhouse gas emissions reporting and understand key terminology in both English and Czech.
  • Gain orientation in mass-flow mapping and be able to visualize and inventory flows within basic systems.
  • Strengthen their ability to construct mass and energy balances for fundamental processes, including those that produce or utilize secondary raw materials as substitutes for primary resources.
  • Be able to distinguish different categories of environmental impacts across environmental compartments and identify the flows that may contribute to them.

Selected knowledge from the course can be tested in an e-learning module available in Czech.

The study programmes with the given course

Programme N-PRI-P: Process Engineering, Master's, compulsory

Type of course unit

 

Lecture

26 hours, optionally

Syllabus

1. week: Classification of balances and basic terminology
2. week: Mass balance of a steady state system (without chemical reactions and with chemical reactions)
3. week: Energy balance of a steady state system, procedures for calculating energy flows of selected process streams
4. week: Introduction to pipe networks, balance of processes with recycle or bypass, computer implementation of algorithms for the solution of balances
5. week: Introduction to economic process assessment in the pre-investment phase
6. week: Balance based on operating data (overdetermined system)
7. week: Environmental impact balances
8. week: Emissions dispersion calculation methods, emissions and immisions
9. week:  Balance of transient process, mass acculumation
10. week: Balances with phase change (gaseous-liquid, one and multi-components systems)
11. week: Balances with phase change (solid-liquid) and its use in energy-storage applications
12. week: Basics of balances of low-carbon energy producing technologies
13. week: Softwares for mass and energy balances

Computer-assisted exercise

26 hours, compulsory

Syllabus

Computer aided seminars. Solution of problems related to the lectured topics, based on information from the lectures.