Helsinki energy consumption

Many pieces of data on this page came originally from Building stock in Helsinki, worked by the Decision analysis and risk management 2015 course.

Question

How much is energy consumed and to what purposes in Helsinki?

Answer

Rationale

U values based on overall data

The total heat consumption by district-heated buildings is 6921.65 GWh in 2013 (see below). We can derive the total energy efficiency value expressed as W /m² /K for floor area and temperature difference between indoors and outdoors. The typical energy efficiency calculations (using the so called U value) assume that outdoor 17 °C is thermoneutral and lower values require heating. The total floor area of district-heated buildings is 38990000 m² in 2015 according to the Helsinki energy decision 2015 model. The annual average temperature in Helsinki is 4.8 °C [1] and during heating season Sep-May 1.4 C (Opasnet data). Therefore the energy efficiency value (approximate U value) is

Failed to parse (Missing <code>texvc</code> executable. Please see math/README to configure.): U = \frac{6921.65 GWh/a /(24 h / d \times 365 d/a)}{38990000 m^2 (17 K - 4.8 K)} = 1.661 \frac{W}{m^2 K}

The annual average ambient temperature is 2.5 °C in Kuopio (Ambient temperature in Urgenche cities). Therefore, we could use hourly temperature data from Kuopio if we add the temperature difference 2.3 K. Graphs of the data.

## This is code is Op_en7317/temperatures [[Helsinki energy consumption]]
library(OpasnetUtils)

ta <- opbase.data("Op_en6315", subset = "2014-5/2015")
hours <- as.character(ta$Date)

if(!exists("server")) {
	dates <- data.frame(
		EN = c("Jan", "Feb", "Mar", "Apr", "May", "Jun", "Jul", "Aug", "Sep", "Oct", "Nov", "Dec"), 
		FI = c("Tammi", "Helmi", "Maalis", "Huhti", "Touko", "Kesä", "Heinä", "Elo", "Syys", "Loka", "Marras", "Joulu")
	)
	for(i in 1:nrow(dates)) {
		hours <- gsub(dates$EN[i], dates$FI[i], hours)
	}
}

hours <- as.POSIXct(strptime(hours, format = "%Y-%b-%d %H:%M:%S"))
hours <- hours + as.difftime(as.character(ta$Time), format = "%H:%M")

# Adjust temperature data: 2.3 C is the average difference between Kuopio and Helsinki
hours <- data.frame(Time = hours, Result = as.numeric(as.character(ta$Result)) + 2.3)
hours <- hours[!is.na(hours$Result) , ]
hours$Date <- as.POSIXct(strptime(format(hours$Time, "%Y-%m-%d"), format = "%Y-%m-%d"))
hours <- hours[hours$Time >= as.POSIXct("2014-03-01 00:00:00") & hours$Time < as.POSIXct("2015-03-01 00:00:00") , ]

days <- aggregate(hours["Result"], hours["Date"], FUN = mean)
days$Temperature <- cut(days$Result, breaks = seq(-30, 33, 3))
temperatures <- Ovariable("temperature", data = aggregate(days["Result"], days["Temperature"], FUN = mean))
temperdays <- Ovariable("temperdays", data = aggregate(days["Result"], days["Temperature"], FUN = length))

objects.store(temperatures, temperdays)
cat("Objects temperature, temperdays stored.\n")

#ggplot(hours, aes(x = Time, y = Result))+geom_line() + geom_point(data = days, aes(x = Date, y = Result, colour = "Daily mean", size = 2))
#ggplot(hours, aes(x = Time, y = Result))+geom_point()

Energy parametres of buildings

Description of parametres:

• Wall Insulation: Building outside walls with a thermal transmission coefficient < 0.5(W/(m²*k)
• High efficient glazing: Building outside windows with a thermal transmission coefficient < 1(W/(m²*k
• Efficient lighting: Building with lighting technology with an efficiency of >75lumen/Watt
• Demand oriented lighting: Buildings with a lighting regulation that controls the presents of users and/or the incident sun light to dim or shut off the lighting to save electricity.
• Efficient Motors: Buildings that are equipped with pressure regulated variable speed drives for heating circulation pumps or ventilation drives.
• Building Remote Monitoring: Buildings with metering and remote evaluation of energy demand, so that an professional engineer can evaluate the energy demand and the need for maintenance and improvement measures
• Building Performance Optimization: Buildings with an optimization contract, where an professional engineer can start maintenance and improvement measures
• Demand controlled ventilation: Buildings with a ventilation regulation that controls the air quality (e.B.CO2) to slow down or shut off the ventilation when it is not needed to save electricity.
• Heat and Cold Recovery in ventilation: Buildings where the heat/cold of the exhaust air is recovered by a heat exchanger to precondition the fresh air to save energy for cooling/heating.
• Room Automation HVAC: Buildings where the heating/ventilation/Air Condition demand is regulated to the demand of every single room to prevent energy demand for not used rooms.

Notes

Data from:

• CyPT Data collection - To Jouni
• Default Building Data - Helsinki
• Energy performance class A in building automation www.siemens.com [2]

The numbers found are not reliable but most of the high technology buildings such as insulated walls, windows.... are started to build from 10 to 15 years ago, so if we could find the building area in the year 2000, we could subtract that from the building area in Helsinki at the moment and get the building area which is built during these 10-15 years and they are high tech building areas with regard to 2 % renovation rate and rebuilding which is on going every year which should be added to the total amount.

Technical notes: Sheets 5_Input Residential, 6.0_Input Non Residential, 6.2_Input Public Admin. Priority 1. Auxiliaries PPT.

Energy demand

Notes

• Data from Climate policies Helsinki additional data
• We went through the data mentioned above and also the files given in Climate policies Helsinki data but could not find the data for cooling, heating:infiltration, heating:other, heating:warm water:other and electricity:ventilation:residential.
• Total estimated amount of energy needed for cooling 23504480 kWh/a (whole Helsinki). Based on [3] 14332 GWh/a for housing (total energy demand minus traffic 18 % [4] and [5] 2 % of total energy demand of housing used for cooling. Total floor area of Helsinki needed (table 1).

Technical notes: Sheets 5_Input Residential, 6.0_Input Non Residential, 6.2_Input Public Admin. Priority 1. Auxiliaries: see table.

Efficiency increase

Changes in energy efficiency of different energy sinks.

• Cooling 2 % /a
• Warm water heating 1.1 % /a in residential buildings
• General improvement: 0.6 % /a: Estimated 3 % of houses renovated/year and 20 % increase in energy efficiency when renovated. [6] Data apart from 0.6% values from Climate policies Helsinki additional data
• The presentation about tables 4 and 5 PresentationHW9

Technical notes: Sheets 5_Input Residential, 6.0_Input Non Residential, 6.2_Input Public Admin. Priority 3. Auxiliaries Excel.

Heating parameters of buildings

Notes

• Data used: Unit heat consumption of buildings in Finland.
• Data Climate policies Helsinki additional data only contained 0.00 for all the parameters.
• EU legislation value for U-value of windows in the document below was 1.0, so we used it for building buildings and the past years' values for the non-residential buildings. We assumed this will be the new residential buildings to be within the legislative value. ^{[1] [2] [3]}
• HW9 table 6 presentation: Helsinki Building Stock

Technical notes: Sheets 5_Input Residential, 6.0_Input Non Residential, 6.2_Input Public Admin. Priority 3. Auxiliaries: see table.

Values derived from Unit heat consumption of buildings in Finland (these could be used to update Table 6):

Consumption statistics

See also

• Helsingin parhaat energiatehokkuuskäytännöt -työryhmän loppuraportti (2011-2013)

Keywords

References

Related files