1. Co- and Poly- generation Martin Hannemann Andi Prah Nuri Feichtinger Paul Polterauer

2. The Co-generation Concept Co-generation is often referred to as a technology. ▫Actually co-generation is a principle that describes how energy, which is produced as a natural bi- product of the electricity production process, is captured and turned into useful heat. This process is also known under the shortcut “CHP”, which means Combined Heat and Power.

4. Examples for CHP Plants Co-generation is applicable to all situations where electricity is produced by thermal combustion Co-generation systems are a modern way to reach very high energy efficiency ▫maximize fuel savings and avoid CO2 emissions. Most common types of CHPs are: ▫Steam and Gas turbines Fast evolving technology ▫Fuel Cells, Combustion Engines

5. Efficiency of Co- generation Backpressure steam turbine units are characterized by high thermal efficiencies up to 90% and a moderate electricity generation efficiency of 15% to 25%. Gas turbine heat recovery units show a thermal efficiency of 75% - 80%. In case post-firing is applied, thermal efficiency reaches close to 100%. Thermal efficiency of combined gas/steam cycle systems reaches and sometimes exceeds 50%.

6. Scale of Co- generation Decentralization ▫Mirco CHP  usually less than 5 kWe in a house or small business  electricity can be used within the home or business or, sold back into the electric power grid ▫A high overall energy conversion efficiency ▫Low maintenance requirements ▫Very low noise and vibration levels ▫Very low emissions of NOx, COx, SOx and particulates.

7. Centralization ▫Disctrict Heating  It centralizes the source of heat and electricity into a single source  + lower investment costs  + higher efficiency  + lower operation and maintenance cost  + higher reliability  + more design flexibility  + less energy is wasted  + more space for home owners

8. Economic Aspects The majority of early adoptions of decentralized energy technology were not good investments under reasonable assumptions. There is a minimum treshhold for a positive NPV on investment of about 160kWe Bigger scale plants yield a better profit ratio

9. Environmental Aspects +environmental benefits by making use of waste heat and waste products -Air pollution is a concern any time fossil fuels or biomass are burned +New cogeneration plants often have to meet higher environmental standards -High initial cost of cogeneration facilities located in urban areas +Decentralized CHP units eliminate the energy loss of a distribution system -Some CoGen systems do not capture as much waste heat as others or cant make use of it due to their location

10. Polygeneration Polygeneration describes an integrated process which has three or more outputs

11. Classification of polygeneration

12. Trigeneration most popular form of polygeneration combine heat, cooling and power find application wherever the demand for heat, cold and power occurs ▫Comercial ▫Office ▫Hospital…

13. Efficiency of Trigeneration The main advantage is the efficient usage of fuel. This leads to saving fuels and money and also less greengas will be produced. A reduction of fuel consumption will raise the energy security of countries. Trigeneration systems support the usage of local energy sources like biomass, biogas, or biofuels.

14. Economy The profitability depends on various factors and certain conditions. Austria supports CHP biomass plants connected to local heating networks. (15% to 35% of the investment cost) In the United Kingdom there is a VAT discount exist from 17.5% to 5% for micro CHP installations. The investments are very sensitive for fuel unit cost, and fuel prices are very variable.

15. Perspectives E.g. The potential of trigeneration technology application in the food industry in Europe was evaluated at approximately 16 TWhe per year. The most significant barriers of using the potential of trigeneration systems are: ▫ a product of market conditions ▫mainly unfavorable electricity and gas prices ▫uncertainty over future market conditions

16. These barriers need to be removed. In order to stimulate the market there is also the task of technology development, the trigeneration needs to be more reliable, efficient and flexible.