Course Catalogue

Civil Engineering and Built Environment

To develop the student's understanding of the principles of heat transfer, thermodynamics and general engineering and the application of these principles to sustainable and energy efficient design and operation of building engineering systems, plant and equipment. To enable students to utilise appropriate mathematical methods to solve mechanical engineering problems.

Outline Syllabus:Convection: mathematical analysis of heat transfer taking place in free and forced convection processes. Use of dimensional analysis techniques and dimensionless groups, Grashof, Nusselt, Reynolds, Prandtl numbers. Heat exchangers: Identification of modes of heat transfer within building services equipment and applications; heat exchanger construction, characteristics, fluid flow paths, pressure drop, design, types and classification. Radiation: Reflectivity, transmissivity, absorptivity, emissivity for different surfaces. Wave characteristics and parameters associated with electromagnetic radiation. Asymmetric radiation and discomfort asymmetry. Heating and cooling loads: Analysis and longhand calculation of building heating and cooling loads, compliance with legislation and energy efficiency standards. Use of thermal analysis software to determine heating and cooling loads. Psychrometrics: psychrometric properties of air, psychrometric cycles for heating and cooling processes, evaluation of cooling and heating plant duties. Thermodynamic cycles: Use of T-S and p-H diagrams to show commonly encountered thermodynamic cycles. Performance analysis of practical thermodynamic cycles, comparison with the Carnot cycle. Refrigeration: vapour compression and absorption refrigeration cycles, refrigerants, compressors, condensers, evaporators. Appropriate engineering mathematics associated with the solution of problems in electrical engineering.

Module Overview:
The aim of this module is to develop your understanding of the principles of heat transfer, thermodynamics and general engineering and the application of these principles to sustainable and energy efficient design and operation of building engineering systems, plant and equipment. The module will enable you to utilise appropriate mathematical methods to solve mechanical engineering problems.

Additional Information:This module is designed to run in semester 1 alongside the complementary Electrical Engineering for Buildings module to provide students with the necessary grounding in the underpinning principles of mechanical engineering, heat transfer, thermodynamics and fluid mechanics, so that they may undertake the appropriate Design Project module in semester 2. In this module, the knowledge learning outcomes are K1, K2, K3, K4, K5, K7, the behaviours learning outcomes are B1, B6, B7 and the skills learning outcomes are S1, S2, S3, S7, S8.