THE DISPLAY® METHODOLOGY

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The poster generation tool uses a calculation instrument to calculate the information shown on the Display® poster. In the following, a detailed description is given on how this calculation instrument determines the characteristic values and how the classification of the building is made. An extensive list of all used conversion factors is presented in the appendix.

Figure 20: structure of the calculation tool

Conversion of Final Energy into Primary Energy and calculation of CO2 Emissions

The General Approach

Starting from the final energy consumption data the Display® calculation instrument uses conversion factors to calculate the equivalent primary energy consumption. For this conversion it applies the cumulative energy use factors. These factors describe the overall primary energy consumption which is linked with the creation or use of a product or a service, including all preproduction chains (extraction + transport + transformation) but without primary energy that is used as materials such as wood for the construction of a building or petrol for synthetic material. Furthermore, the energy utilised for the disposal (i.e. passive energy contained in the materials) is not taken into account. Since there is not a widely used abbreviation in for this factor in English so far we use the German abbreviation KEV in this users’ guide. Contrary to the cumulative energy use factors the cumulative energy demand (CED) factors that are defined in the German guideline VDI 4600 include the amount of primary energy that is used as materials and that is reflected in the lower heating value of the product. They also take into account the energy input for the disposal.

The German Institute for Applied Ecology (Öko-Institut) has developed the life-cycle analysis program and database GEMIS. This program is capable of calculating the cumulative energy (KEV) use factors for a variety of different energy sources and processes. On the basis of the processes linked to a service or a product the program also generates the greenhouse gas emissions related to the production or consumption of a product, given in kg of CO2 equivalents per kWh of energy. Since the respective conversion factor takes into account the sum of all greenhouse gas emissions on the chain of energy transformation it is cumulative, too. As already mentioned in chapter 2 the term CO2 emissions is used for means of simplification to express these greenhouse gas emissions.

The Display® calculation instrument uses conversion factors based on the GEMIS program, but produced by different sources:
The conversion factors for the energy sources gas, fuel, and coal result from a GEMIS version 4., calculations made by the Institute for Housing and Environment (IWU) Darmstadt, Germany. They are also used for the certificate of residential buildings developed by the German Energy Agency (dena). The factors for wood, the production of hot water by a solar thermal collector, and for the production of photovoltaic electricity in the building are taken from the ProBas database which is run by the Umweltbundesamt. This data source is also used to provide most of the factors for the national electricity mixes. The conversion factors that are used for district heat by default are also taken from a GEMIS version 4.14 calculation made by the IWU.

Currently, the calculation instrument distinguishes only between one value for district heating networks with and one without cogeneration plants. It is intended to provide more precise conversion factors for the specified type of plant in the future. However, it is already possible to enter individual factors which are more adapted to the local situation by specifying the distribution of the energy sources consumed in the different heating production plants. This distribution is necessary in order to calculate the correct distribution of the different energy sources (Fossil, Nuclear, and Renewable).

There are different system boundaries for conversion factors that are used. For gas, fuel oil, and coal the system boundary is the transfer point of the building, including the heat generator. The conversion factors for wood do not include transport and the heat generator. Concerning all different utilisations of electricity, the conversion factors only include the generation of electricity. They do not take into account the transport of electricity or transformation processes in the building of the consumer. For the use of a solar thermal collector, the conversion factor takes into account the energy input up to the transfer point of heat at the outlet of the device. Further devices that are necessary to run the heating system are not included. The system boundaries are valid for energy conversion factors as well as for the CO2 emission factors. In order to calculate the contribution of different energy sources (Fossil, Nuclear, Renewable) to the overall energy mix used in the building it is necessary to know the composition of the national energy mix for the production of electricity. For this purpose the Monthly Electricity Survey in its version from October 2003 that is published by the International Energy Agency (IEA) is used.

6.1.2 Local weather Correction

As the energy consumption of a building depends on the climate conditions and since these climate conditions vary for one certain geographic region over the years, the consumption data has to be corrected for the local climate. Otherwise, it would not be possible to compare the results of the calculation instrument for one building in the different reference years.
In order to include a weather correction factor the final energy that is used for space heating is multiplied by the weather correction factor. After this step, the total climate corrected final energy consumption of the corresponding energy source is multiplied with the specific CED or KEV factor. The result is the associated primary energy consumption.
Thus, a weather correction factor larger than one that represents a relatively mild winter simulates an increase in the amount of energy consumption of the building. This is necessary as the building would have consumed more energy under average climate circumstances. As a result, the different energy consumption ratios are comparable over the years.
The local climate correction factor comes from the comparison between the average of the winter temperature for the reference year and the average for the winter period over a long period fixed by the country (for example 30 years in France, 20 years in Germany). It’s also possible to calculate this factor from the degree days (DD): average DD (+- 20 years) / reference year DD.
Two assumptions are made in case you have not entered the exact contribution of one energy source to space or heating purposes which means that data has been entered only in the total field:

  • In case there are entries in the total field for electricity and at the same time for other energies or energy sources (gas, fuel oil, coal, district heating, wood) the whole amount of electricity is assumed to be used for other purposes other than space heating whereas the other energies or energy sources are assumed to be solely for space heating purposes.
  • If there is no entry other than electricity, a percentage of 70% is assumed to be used for space heating. The rest is assumed to be used for all other purposes and this energy consumption is not taken into account for the weather correction.

Please note that the weather correction that is applied in the Display® calculation instrument does not take into account climatic differences between two different geographic zones.

However, to make buildings situated in different climatic zones comparable, it is necessary to apply a specific classification scheme to each corresponding climatic zone. In order to keep the classification scheme concise and not too complicated the Display® calculation instrument uses an identical classification scheme for all participating cities. By applying such a uniform classification scheme, the results show in which buildings huge improvements can still be made. It is known that, if national classification schemes were used, buildings that were formerly well-classified could be graded harsher than with this uniform classification scheme. Therefore, the Display® classification scheme is a scheme where good ratings are rather hard to obtain. Please note that thermal solar energy is always linked with water heating.

6.1.3 Non-Electrical Energy Consumption

The calculation instrument automatically takes the CED and KEV factors for the energy sources gas, fuel, coal and wood.

If the building disposes of a solar thermal collector, its production of hot water will be converted into primary energy. In order to ensure the simplicity of the calculation instrument it is assumed that a flat-plate collector is used.
If there is a cogeneration unit in the building the calculation instrument assumes that either natural gas, fuel oil (diesel) or biogass is used.

Furthermore, having subtracted the amount of gas that the cogeneration unit consumed for producing electricity, the remaining amount of gas is taken into account for weather correction although it still includes a certain amount of gas that is used for providing hot water. If the gas used for the supply with hot water does not make up a substantial part of the overall gas consumption the variations can be neglected. However, in case of a significant demand for hot water, e.g. in school buildings containing a swimming pool or a gymnasium, this procedure is not appropriate and falsifies the classification of the building. This deficiency will be removed in the future.
Concerning district heating, the calculation instrument uses standard factors which are appropriate to the district heating network that you have specified the distribution of the energy sources. If you have entered individual factors the Display® team will check if these factors meet the requirements.

6.1.4 Electricity Consumption

Since there are a lot of suppliers offering electricity that is produced using very different energy sources the calculation instrument cannot take into account every possibility. It implements four possibilities:

  • The first possibility is to purchase conventional electricity. Hereby conventional electricity signifies that it is purchased with supply contracts that do not contain an agreement about the contribution of specific primary energy sources to the overall energy mix. Therefore, it can be assumed that this electricity is composed similarly to the national electricity production. For this purpose the data were obtained from the results of the GEMIS version 4.3 calculation published by the Öko-Institut.

The possibility to specify the global mix of the electricity production is used for the distribution of the energy sources (Fossil, Nuclear, and Renewable).

Example C: Falk Comprehensive School
150.000 kWh of electricity were used for other purposes than space heating. Since no weather correction is necessary this value is directly multiplied by the corresponding CED factor which depends on the country. It amounts to 2,90 for Germany. Therefore, the primary energy consumption needed to provide 150.000 kWh of electricity for the example school building comes to 435.000 kWh.

The purchase of “green” electricity means that it is provided by using supply contracts that define a certified “green” energy mix. The calculation instrument assumes that wind power and hydro energy each contribute 50 % to the overall energy mix since both are the most frequently used renewable energy sources for the production of electricity. The specific factors are sourced from GEMIS version 4.13 calculation made by the IWU.

If the building is equipped with photovoltaic panels for which a production of a certain amount of electricity has been declared the calculation instruments assumes that the system consists of polycrystalline silicon. As this is by far the most widely used technique, this simplification will normally not result in a false calculation. The conversion factors were obtained from the ProBas database.

In case of a cogeneration unit in the building the calculation instruments takes into account the possibility of supplementary electricity fed into the grid. However, there are no further credits given for this extra electricity. The justification for this proceeding is that the corresponding amount of electricity should normally already be rated at the point where it is finally consumed. The following example gives a detailed description of the calculation process for a cogeneration unit in the building.

Example B: Cogeneration unit in the building
In the form sheet on the page “Details about energies and their consumption” you have entered the information that your cogeneration unit in the building has produced 100 000 kWh of electricity and that 10 000 kWh have been fed into the grid. Therefore, 90 000 kWh are produced and used within the building. In order to obtain the gas consumption that was used for the production of electricity the calculation tool assumes an efficiency of the plant of 85 %. Starting with this factor the instrument calculates the overall gas consumption for the cogeneration unit i.e. 100 000/0.85 = 117 647 kWh gas. This figure is then subtracted from the from the total gas consumption of the building in order to calculate the amount that was necessary to heat the building i.e. 300 000 – 117 647 = 182 350. This figure is then multiplied by the climatic correction factor.The quantity of gas used to produce the 90 000 kWh = 105 880 i.e. 90 000/0.85 is then added to the previous climatic corrected total i.e. 182 350 X CC. This final total is further multiplied by the primary energy conversion factor for natural gas and CO2 conversion factor.

6.1.5 CO2 Emissions

Compared to the calculation of primary energy consumption the C02 emissions are treated in a similar way. For each energy source they are calculated on the basis of the climate corrected final energy consumption. The conversion factors depend on the energy sources and in case of electricity additionally on the country.

Example C: Falk Comprehensive School
With a CO2 emission factor of 0,2537 kg/kWh for natural gas and the climate corrected final energy consumption of 220.000 kWh the CO2 emissions come to 55.814 kg. As the conversion factor for conventional electricity in Germany is 0,6249 kg/kWh and the electricity consumption adds up to 150.000 kWh the CO2 emissions make 93.735 kg. All in all the CO2 emissions add up to 149.549 kg.

6.2 Calculation of the Ratios and Applying the Classification Scheme

The primary energy ratio is calculated by dividing the overall primary energy consumption per year by the gross internal floor area. The CO2 ratio and the water ratio are determined in an analogous way, whereas in the case of water the unit is converted from m3 to l. . An exception is made for swimming pools, where the water ratio is expressed in l/users. Afterwards, the building is placed in the classification scheme, depending on the calculated ratios and the declared type of the building. Detailed information on the classification scheme is given in appendix 1.

Example C: Falk Comprehensive School
The total primary energy consumption adds up to 692.400 kWh/year. Dividing by the surface area of the building of 5.000 m2 results in a primary energy ratio of 138 kWh/m2/year. According to the classification scheme this primary energy ratio corresponds to class B. Dividing the CO2 emissions by the surface of the building makes a CO2 ratio of 30 kg/m2/year. That is why the school building is placed in class C for CO2 emissions. The water consumption of the building is 902 m3/year which corresponds to 902.000 l/year. From this follows that the water ratio is 180 l/m2/year) and that the buildings water consumption is class B.

6.3 Specification of the Contribution of Different Energy Sources

The calculation instrument divides the energy sources into the three categories fossil, nuclear, and renewable. Hereby, the following assignments are used:

  • Fossil:
    • gas, fuel oil, coal,
    • district heating (fossil fuels incl. waste incineration),
    • electricity (conventional: fossil fuels)
  • Nuclear:
    • electricity (conventional: nuclear power)
  • Renewable:
    • wood, solar (thermal),
    • district heating (biomass, solar [thermal]),
    • electricity (conventional: renewable sources), electricity (PV)

For the school building of example C almost all of these values are already available, except for the contribution of different primary energy sources to the overall energy mix used for the production of conventional electricity. The calculation instrument takes the data published in the Monthly Electricity Survey in October 2003 by the IEA which shows the contribution of primary energy sources in the three categories for a certain country. The further proceedures are described in example C.

Example C: Falk Comprehensive School
The school building in this example has consumed 150.000 kWh of electricity that were purchased by using an electricity contract that does not specify a certain contribution of different energy sources to the overall energy mix. The primary energy consumption related to the use of electricity amounts to 435.000 kWh. Since the school building is situated in Germany, 66 % of the primary energy used to produce electricity comes from fossil fuels, 30 % is nuclear, and 4 % is renewable. Consequently, 287.100 kWh of electricity is produced using fossil fuels, 130.500 kWh using nuclear, and 17.400 kWh using renewable energy sources. These results are added to the primary energy consumption previously calculated. In the category of fossil energy sources 250.800 kWh of primary energy have been used for space heating. Therefore, a total amount of 532.575 kWh of primary energy is coming from fossil energy sources. The figures for nuclear and renewable energy remain the same. Therefore, a total of 544.500 kWh of primary energy consumption for the school building is fossil, 130.500 kWh is nuclear, and 17.400 kWh is renewable. Their sum equals the overall primary energy consumption amounting to 692.400 kWh. In conclusion, the percentages showing the contribution of different energy sources to the overall energy consumption in the building are: 78 % for fossil energy, 19 % for nuclear energy, and 3 % for renewable energy. Figure 14 shows the corresponding extract of the Display® poster. Figure 21: Extract of the Display® poster showing the contribution of different energies to the overall primary energy mix.

6.4 Visualising Savings Achieved by Getting into a Higher Class

In order to visualise possible savings that can be achieved by changing the performance of the building by one class in the corresponding category the Display® poster shows three elements of comparison.
The first step for depicting possible savings is to calculate the amount of necessary savings in order to achieve the next best class. Afterwards these savings are compared to the annual primary energy consumption per year of an average single family house, the CO2 emission of a car going once around the earth and the water consumption of a shower.
Please note that this is calculated following the ranking scheme:

  • If the building is classed in a certain category in one of the following rank [C, D, E, F], the improvement of the ratio corresponds to one whole class, e. g. not only the next five points that would lift the building into a higher class in a certain category.
  • If the building is already ranked in a certain category the rank B or G, the calculation of the savings that are achieved by lifting the building from class B to class A or from class G to class F is based on the current distance up to the threshold value.
  • If the building has already achieved class A in a certain category the text “Class A already achieved.” is shown on the poster.
Example C: Falk Comprehensive School
An improvement by one whole class in the category of annual primary energy consumption equals a reduction of the primary energy ratio by 65 kWh per m2 and per year. Depending on the floor area of the building this implies different amounts of primary energy savings, e.g. a building with a surface of 5.000 m2 that improves by one class would save a primary energy consumption of 325.000 kWh per year. This amount is now compared to the annual primary energy consumption of an average family house. Consequently, this building could reduce its annual primary energy consumption by an amount equal to the average annual consumption of 8 family houses .Concerning the CO2 emissions an improvement by one whole class equals the reduction of the CO2 emissions by 13 kg of CO2 equivalents per m2 per year. Therefore, a building of 5.000 m2 that moves up one class contributes to a saving of CO2 emissions by 65.000 kg of CO2 equivalents. Compared to the CO2 emissions of a medium petrol car going once around the earth this corresponds to a tour 8 times around the earth.Regarding the water consumption, an improvement by one class implies a reduction of the water ratio by 125 l per m2 per year. However, since the example building has already achieved class B with its water ratio of 180 l per m2 and year, the improvement by one class implies the reduction of the ratio up to the threshold value of 125 l per m2 and year. For the example building this reduction of 80 l per m2 and year means a saving of 400.000 l per year. Compared to an average shower the savings come to 13 333 showers . If the building had to improve by one whole class and not just by the distance to the threshold value it would save 500.000 l which comes to 16 667 showers. Please note, that the calculated values of comparison are rounded to whole numbers. If the result is less than one it is rounded up to one. An extract of the corresponding section on the Display® poster in shown in figure 15.

Figure 22: Extract of the Display® poster visualising savings achievable by improving the performance of a building

Persönliche Werkzeuge