Thermal energy need in Helsinki Metropolitan Area: Difference between revisions
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Global warming and changes in outdoor temperature. | Global warming and changes in outdoor temperature. | ||
=== Causality === | === Causality === | ||
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== Result == | == Result == | ||
{| {{prettytable}} | |||
| Total need of thermal energy | |||
| | |||
| | |||
| | |||
| | |||
| | |||
|---- | |||
| . | |||
| 2007 | |||
| 2013 | |||
| 2020 | |||
| 2025 | |||
| 2030 | |||
|---- | |||
| . | |||
| [GWh] | |||
| [GWh] | |||
| [GWh] | |||
| [GWh] | |||
| [GWh] | |||
|---- | |||
| Helsinki | |||
| 7475,857243 | |||
| 7535,83639 | |||
| 7605,812062 | |||
| 7655,794684 | |||
| 7705,777307 | |||
|---- | |||
| Vantaa | |||
| 2129,781022 | |||
| 2216,91573 | |||
| 2318,572889 | |||
| 2391,185146 | |||
| 2463,797402 | |||
|---- | |||
| Espoo | |||
| 2675,29203 | |||
| 2835,427889 | |||
| 3022,253058 | |||
| 3155,699607 | |||
| 3289,146156 | |||
|---- | |||
| Kauniainen | |||
| 179,0168745 | |||
| 183,554805 | |||
| 188,8490572 | |||
| 192,6306659 | |||
| 196,4122746 | |||
|---- | |||
| TOTAL | |||
| 12 459,95 | |||
| 12 771,73 | |||
| 13 135,49 | |||
| 13 362,92 | |||
| 13 655,13 | |||
|---- | |||
|} | |||
==See also== | ==See also== | ||
Revision as of 07:20, 20 April 2009
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Scope
Defines how thermal energy need will change in the future in Helsinki metropolitan area. Calculations are done by day degree method which is explained here .
Definition
Data
Consumption of district heating in Helsinki metropolitan area in year 2007 [1].
Building stock of Helsinki metropolitan area [2].
Helsinki Metropolitan area Council's (YTV) report of floor area and population changes in Helsinki metropolitan area to 2025 [3]
Global warming and changes in outdoor temperature.
Causality
Unit
GWh
Formula
Qh = U * A(Tin-Tout) * t where Qh = Heat flow from building to surroundings, U = Buildings overall heat transfer coefficient, A = Area about which the heat will go trough, Tin = Indoor temperature, Tout = Outdoor temperature and t = Time period of the transfer. Thermal energy what is needed for warm tap water can be calculated as Qw = cp,w * pw * qm,w * (Tw,warm - Tw,cold) * t where Qw = Thermal energy needed for warm tap water, pw = Water density, cp,w = Specific heat capacity for water, Tw,warm = Temperature of warm tap water and Tw,cold = Temperature of cold tap water. Other thermal energy leaks are estimated to be negligible. A city’s need of thermal energy in a year can be then estimated to be sum of single buildings need of thermal energy. Thus a city’s total need of thermal energy can be calculated as Qtotal = Qw + Qh where Qtotal = Year need of thermal energy in city, Qh = Heat flow from building to surroundings and Qw = Thermal energy needed for warm tap water.
Result
| Total need of thermal energy | |||||
| . | 2007 | 2013 | 2020 | 2025 | 2030 |
| . | [GWh] | [GWh] | [GWh] | [GWh] | [GWh] |
| Helsinki | 7475,857243 | 7535,83639 | 7605,812062 | 7655,794684 | 7705,777307 |
| Vantaa | 2129,781022 | 2216,91573 | 2318,572889 | 2391,185146 | 2463,797402 |
| Espoo | 2675,29203 | 2835,427889 | 3022,253058 | 3155,699607 | 3289,146156 |
| Kauniainen | 179,0168745 | 183,554805 | 188,8490572 | 192,6306659 | 196,4122746 |
| TOTAL | 12 459,95 | 12 771,73 | 13 135,49 | 13 362,92 | 13 655,13 |