- to know the basic laws of heat conduction, radiant and convective heat transfer, boiling and condensation heat transfer;
- to know the methods of heat-mass exchange augmentation in heat exchangers;
- to be able to use the bases of systems approach, equations of mathematical physics for problem setting and solution in heat exchanger engineering;
- to be aware of the issues of steady and transient heat conduction;
- to be aware of the possible consequences of heat exchanger miscalculation.

prerequisites
• Higher Mathematics;
• Physics;
• Engineering Thermodynamics;
co-requisites
• Boiler Units of Heat Power Engineering Units;
• Boiler Units of Thermal Power Plants;
• Turbines of Thermal Power Plants;
• Heat Engines of Industrial Enterprises.

Basic types of transmission of warmth. A heat-conducting is at the stationary mode and maximum terms of the first family. Processes of heat transfer. Non-stationary heat-conducting. Bases of theory of convective heat exchange. Heat emission is in case of motion of liquid in channels. Heat emission is at a force transversal washing of pipe and bunch of pipes. Heat emission is for the changes of the aggregate state of substance. Effulgent heat exchange. Basic laws of caloradiance.

1. Heat-mass exchange in examples and problems: Study guide /M.M. Chepurnyi, N.V. Rezydent. – Vinnytsia: VNTU, 2011. – 128 p.
2. Heat transfer // Konstantynov S.M. – Kyiv: Politekhnika i pres, 2005. – 305 p.
3. Thermal engineering // Drahanov B.Kh., Dolinskyi A.A., Mishchenko A.V. et al. – Kyiv: Lybid, 2005. – 360 p.
4. Heat-mass exchange // Labay V.Y. College textbook. – Lviv: Triada Plius, 2004. – 260 p.
5. Heat-mass exchange (theoretical framework and basis of design) // Pohorielov A.I. Manual for graduate students. 2nd edition. – Lviv: “Novyi Svit – 2000”, 2004. – 144 p.

• formative assessment (30%): written reports on laboratory works, recitation;
• summative assessment (70%, examination): control activities.

- to know the basic laws of heat-conducting, radial and convective heat exchange, heat exchange at boiling and condensation;
- to know the methods of intensification of heat-mass exchange in heat exchange machines.
- to be able to calculate the geometric dimensions of heat loss and heat elements of the network, which consists of heat exchangers, heating and boiler.

prerequisites
• Higher Mathematics;
• Physics;
• Engineering Thermodynamics;
co-requisites
• Boiler Units of Heat Power Engineering Units;
• Boiler Units of Thermal Power Plants;
• Turbines of Thermal Power Plants;
• Heat Engines of Industrial Enterprises.

Coursework consists of three interrelated parts (sections): - Calculation of geometric dimensions of heat exchangers and heat losses; - Calculation of heat losses of heating mains; - Approximate calculation of the geometric dimensions of the boiler and heat losses.

1. Heat-mass exchange in examples and problems: Study guide /M.M. Chepurnyi, N.V. Rezydent. – Vinnytsia: VNTU, 2011. – 128 p.
2. Heat transfer // Konstantynov S.M. – Kyiv: Politekhnika i pres, 2005. – 305 p.
3. Thermal engineering // Drahanov B.Kh., Dolinskyi A.A., Mishchenko A.V. et al. – Kyiv: Lybid, 2005. – 360 p.
4. Heat-mass exchange // Labay V.Y. College textbook. – Lviv: Triada Plius, 2004. – 260 p.
5. Heat-mass exchange (theoretical framework and basis of design) // Pohorielov A.I. Manual for graduate students. 2nd edition. – Lviv: “Novyi Svit – 2000”, 2004. – 144 p.

• recitation (30%);
• summative assessment (70%, credit): defense of сoursework.