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certification:passive_house_categories:per [2015/03/11 16:26] – [Literature] bwuenschcertification:passive_house_categories:per [2015/09/12 18:25] (current) – [Site-specific PER factors] wfeist
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 ====== The PER sustainability assessment ====== ====== The PER sustainability assessment ======
  
-Which parameter can be used as a suitable indicator for the sustainability of buildings from an energy standpoint? The so-called PER factors (Primary Energy Renewable) were first introduced in the final presentation at last year’s International Passive House Conference, as future-oriented sustainability assessment criteria [Feist 2014]. With the new release of the Passive House Planning Package (PHPP version 9), PER is being introduced as a worldwide certification criteria for Passive Houses. This paper describes the methodology used to derive the factors integrated into the PHPP. +Which parameter can be used as a suitable indicator for the sustainability of buildings from an energy standpoint? The so-called PER factors (Primary Energy Renewable) were first introduced in the final presentation at last year’s International Passive House Conference, as future-oriented sustainability assessment criteria [Feist 2014]. With the new release of the Passive House Planning Package (PHPP version 9), PER is being introduced as a worldwide certification criteria for Passive Houses. This article describes the methodology used to derive the factors integrated into the PHPP. 
  
 ==== PER factors: The methodology ==== ==== PER factors: The methodology ====
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 The methodology used to derive PER factors is based on the ideas that have previously been published in [Feist 2013] and [Feist 2014]. The same approach was further developed, applied and analysed internationally. With an hourly resolution load profiles of the energy demand are simulated in the context of a future scenario - where the energy is supplied solely by renewable energy (RE) sources, including all necessary storage facilities (Figure 1). The individual calculations are based on climate data from various sources, the resulting PER factors describe how much more renewable energy must be supplied in order to cover the final energy consumed at the building, including all losses incurred along the way.  The methodology used to derive PER factors is based on the ideas that have previously been published in [Feist 2013] and [Feist 2014]. The same approach was further developed, applied and analysed internationally. With an hourly resolution load profiles of the energy demand are simulated in the context of a future scenario - where the energy is supplied solely by renewable energy (RE) sources, including all necessary storage facilities (Figure 1). The individual calculations are based on climate data from various sources, the resulting PER factors describe how much more renewable energy must be supplied in order to cover the final energy consumed at the building, including all losses incurred along the way. 
  
-{{:certification:passive_house_categories:per_formel_en.jpg?400|}}+{{:picopen:per_formel_en.jpg?400|}}
  
 The PER factor is determined by the simultaneity of available energy resources and the energy demand, as this dictates how much energy needs to be temporarily stored before it is used. Short-term storage can technically be achieved fairly efficiently, whilst longer term seasonal storage will always cause higher energy losses. Depending on the load profile, the energy demand will partially be covered (a) directly from the renewable supply, (b) with energy that has temporarily been buffered, or (c) with energy from a seasonal storage. As a logical consequence of the temporal correlations, heating – which occurs only during seasons with low RE availability – is highly energy intensive in the envisioned future supply chain. For cooling, on the other hand, a larger proportion of the associated energy demand can be used directly without need for temporary storage and losses. Load profiles that occur throughout the year (e.g. domestic electricity use, hot water) lie within these two extreme scenarios.  The PER factor is determined by the simultaneity of available energy resources and the energy demand, as this dictates how much energy needs to be temporarily stored before it is used. Short-term storage can technically be achieved fairly efficiently, whilst longer term seasonal storage will always cause higher energy losses. Depending on the load profile, the energy demand will partially be covered (a) directly from the renewable supply, (b) with energy that has temporarily been buffered, or (c) with energy from a seasonal storage. As a logical consequence of the temporal correlations, heating – which occurs only during seasons with low RE availability – is highly energy intensive in the envisioned future supply chain. For cooling, on the other hand, a larger proportion of the associated energy demand can be used directly without need for temporary storage and losses. Load profiles that occur throughout the year (e.g. domestic electricity use, hot water) lie within these two extreme scenarios. 
  
- +[{{:picopen:per_faktoren_infografik_en.jpg?700|Figure 1: Energy flowchart from the RE supply to the energy consumed at the building, including facilities for short-term and seasonal storage. }}]
-[{{:certification:passive_house_categories:per_faktoren_infografik_en.jpg?700|Figure 1: Energy flowchart from the RE supply to the energy consumed at the building, including facilities for short-term and seasonal storage. }}]+
  
 ===== Load profiles – Supply and Consumption ===== ===== Load profiles – Supply and Consumption =====
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 The modelled future energy supply network is based purely on electricity from renewable sources. Three different sources are taken into account: Photovoltaics, wind turbines and hydropower. Biomass needs to be treated differently in the calculations as it can easily be stored and used on a demand basis. In fact, all systems based on secondary energy (e.g. district heat) are taken into account independently of the supply network, directly in the PHPP, with appropriate parameters for the respective system.  The modelled future energy supply network is based purely on electricity from renewable sources. Three different sources are taken into account: Photovoltaics, wind turbines and hydropower. Biomass needs to be treated differently in the calculations as it can easily be stored and used on a demand basis. In fact, all systems based on secondary energy (e.g. district heat) are taken into account independently of the supply network, directly in the PHPP, with appropriate parameters for the respective system. 
  
-The hourly electricity production through solar power is calculated based on a photovoltaic system oriented toward the equator. The power output is calculated based on the solar radiation information from the respective climate data set, taking into account a tempe-rature-sensitive efficiency of the photovoltaic module. The model’s inclination is determined such that the highest possible annual energy yield is reached at the considered location. +The hourly electricity production through solar power is calculated based on a photovoltaic system oriented toward the equator. The power output is calculated based on the solar radiation information from the respective climate data set, taking into account a temperature-sensitive efficiency of the photovoltaic module. The model’s inclination is determined such that the highest possible annual energy yield is reached at the considered location. 
  
 The hourly electricity produced through wind energy is calculated based on a smoothed profile of hourly wind velocities. The same climate data set is used, in order to take account of local climatic correlations between wind and radiation or temperature. However, such localised wind data is rarely representative of the potential of wind energy in the surrounding region. The original wind velocity data is therefore calibrated based on long-term measured averages of the region [SSE] and extrapolated to a hub height of 150 m. The actual power output then depends on the turbine’s power curve, which is modelled with a specific power output of 380 W/m² and 200 W/m² for regions with strong and weak wind, respectively (based on [Mono et.al. 2014]). If the average wind speed at hub height is lower than 4 m/s, a significant development of wind energy in the area is unlikely for economic reasons. The contribution of wind energy to the total mix in the calculations is therefore limited to 0.5 % of the annual yield. Offshore wind energy is not considered at this stage – the calculations are slightly on the safe side in this regard. The hourly electricity produced through wind energy is calculated based on a smoothed profile of hourly wind velocities. The same climate data set is used, in order to take account of local climatic correlations between wind and radiation or temperature. However, such localised wind data is rarely representative of the potential of wind energy in the surrounding region. The original wind velocity data is therefore calibrated based on long-term measured averages of the region [SSE] and extrapolated to a hub height of 150 m. The actual power output then depends on the turbine’s power curve, which is modelled with a specific power output of 380 W/m² and 200 W/m² for regions with strong and weak wind, respectively (based on [Mono et.al. 2014]). If the average wind speed at hub height is lower than 4 m/s, a significant development of wind energy in the area is unlikely for economic reasons. The contribution of wind energy to the total mix in the calculations is therefore limited to 0.5 % of the annual yield. Offshore wind energy is not considered at this stage – the calculations are slightly on the safe side in this regard.
  
-Last but not least, the electricity produced from hydropower is taken into account based on the predicted contribution of this energy source to each country’s future total energy demand. The prediction for future hydropower generation id taken from [intpow 2009]. The future electricity demand is scaled for each country according to current and future population densities, current electricity consumption per capita and the vision of a “2000 Watt Society”. Within Europe it is assumed that countries with a hydropower surplus export part of this electricity. The profile of the hydropower electricity is fairly constant throughout the year and takes into account effects of rain, snow and glacial runoff. +Last but not least, the electricity produced from hydropower is taken into account based on the predicted contribution of this energy source to each country’s future total energy demand. The prediction for future hydropower generation is taken from [intpow 2009]. The future electricity demand is scaled for each country according to current and future population densities, current electricity consumption per capita and the vision of a “2000 Watt Society”. Within Europe it is assumed that countries with a hydropower surplus export part of this electricity. The profile of the hydropower electricity is fairly constant throughout the year and takes into account effects of rain, snow and glacial runoff. 
  
 ==== Electricity demand at the building ==== ==== Electricity demand at the building ====
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 All load profiles are smoothed ±4 hours in order to account for variations caused e.g. by different user behaviour.  All load profiles are smoothed ±4 hours in order to account for variations caused e.g. by different user behaviour. 
  
-[{{:certification:passive_house_categories:per_2_en.jpg?700|Figure 2: Top left: Load profile for one week of the household electricity and domestic hot water (cold water temperature for Mannheim, Germany, Winter). Top right and below: Exemplary useful energy profiles from different climates for heating, cooling and dehumidification. }}] +[{{:picopen:per_2_en.jpg?700|Figure 2: Top left: Load profile for one week of the household electricity and domestic hot water (cold water temperature for Mannheim, Germany, Winter). Top right and below: Exemplary useful energy profiles from different climates for heating, cooling and dehumidification. }}]
  
 ===== Site-specific PER factors ===== ===== Site-specific PER factors =====
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 It is further assumed that the seasonal storage has the required capacity to store exactly the amount of energy storage required over the course of the year (supply = demand + losses). One possibility of a working seasonal storage system is the conversion of RE electricity into methane, for which a conversion efficiency of 57 % is assumed. The re-conversion from gas into electricity in a CCTG plant is modelled with an efficiency of 50 %. Electricity consumed via the seasonal storage, therefore has an overall efficiency of only approx. 30 %. Finally, 5 % distribution losses are added for all electricity transmission via the electrical grid.  It is further assumed that the seasonal storage has the required capacity to store exactly the amount of energy storage required over the course of the year (supply = demand + losses). One possibility of a working seasonal storage system is the conversion of RE electricity into methane, for which a conversion efficiency of 57 % is assumed. The re-conversion from gas into electricity in a CCTG plant is modelled with an efficiency of 50 %. Electricity consumed via the seasonal storage, therefore has an overall efficiency of only approx. 30 %. Finally, 5 % distribution losses are added for all electricity transmission via the electrical grid. 
  
-[{{:certification:passive_house_categories:per_3_farbe_en.jpg?700|Figure 3: Example of hourly load profiles of RE electricity (cumulative) and electricity demand for a Passive House in Stuttgart. The left represents a week during winter with little RE availability, com¬pared to a week during summer on the right, with much higher RE supply. The two graphs below show the simultaneous storage level of the short-term storage. }}]+[{{:picopen:per_3_farbe_en.jpg?700|Figure 3: Example of hourly load profiles of RE electricity (cumulative) and electricity demand for a Passive House in Stuttgart. The left represents a week during winter with little RE availability, compared to a week during summer on the right, with much higher RE supply. The two graphs below show the simultaneous storage level of the short-term storage. }}]
  
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 For each of the load profiles the PER routine calculates the required RE supply to cover the total energy demand, plus all storage losses. The PER factor for the energy application in question then equates to the slope of the changing RE supply over the increase in energy demand (examples are shown in Figure 4). In some cases this can lead to factors below one, which would mean that less energy needs to be additionally generated than will be consumed. This is the case only if the additional energy demand balances out seasonal disparities and thus reduces the need for seasonal storage, e.g. additional cooling in a heating dominated climate.  For each of the load profiles the PER routine calculates the required RE supply to cover the total energy demand, plus all storage losses. The PER factor for the energy application in question then equates to the slope of the changing RE supply over the increase in energy demand (examples are shown in Figure 4). In some cases this can lead to factors below one, which would mean that less energy needs to be additionally generated than will be consumed. This is the case only if the additional energy demand balances out seasonal disparities and thus reduces the need for seasonal storage, e.g. additional cooling in a heating dominated climate. 
  
-[{{:certification:passive_house_categories:per_4_en.jpg?700|Figure 4: The PER factors are equivalent to the required additional RE supply for each kWh of a consumer’s additional energy demand. Examples are shown for domestic hot water, heating and cooling in Boise, US. }}]+[{{:picopen:per_4_en.jpg?700|Figure 4: The PER factors are equivalent to the required additional RE supply for each kWh of a consumer’s additional energy demand. Examples are shown for domestic hot water, heating and cooling in Boise, US. }}]
  
-[{{:certification:passive_house_categories:per_5_en.jpg?700|Figure 5: Exemplary PER factors for selected locations in different climate zones arctic, cool-temperate, warm and very hot. }}]+[{{:picopen:per_5_en.jpg?700|Figure 5: Exemplary PER factors for selected locations in different climate zones arctic, cool-temperate, warm and very hot. }}]
  
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 The PER factors to be used in the PHPP are thus not based on individual local calculations but rather on a combination via a global Fourier approximation of the results calculated for over 700 locations worldwide. In addition, the minimum value used in the PHPP is 1 (supply = demand). Figure 6 shows the average value and variation of the PER factor for space heating of all locations currently integrated into the PHPP.  The PER factors to be used in the PHPP are thus not based on individual local calculations but rather on a combination via a global Fourier approximation of the results calculated for over 700 locations worldwide. In addition, the minimum value used in the PHPP is 1 (supply = demand). Figure 6 shows the average value and variation of the PER factor for space heating of all locations currently integrated into the PHPP. 
  
-[{{:certification:passive_house_categories:per_6_en.jpg?500|Figure 6: PER factors for space heating for various locations integrated into the PHPP. Average value and variation. }}]+[{{:picopen:per_6_en.jpg?500|Figure 6: PER factors for space heating for various locations integrated into the PHPP. Average value and variation. }}]
  
 ===== Summary and Outlook ===== ===== Summary and Outlook =====
certification/passive_house_categories/per.1426087577.txt.gz · Last modified: 2015/03/11 16:26 by bwuensch