Energy efficient construction and trainig practices - 1 Basics

Energy Efficient Construction and
Training Practices: Basics
The sole responsibility for the content of this publication lies with the authors. It does not necessarily
reflect the opinion of the European Union. Neither the EASME nor the European Commission are
responsible for any use that may be made of the information contained therein.

Energy and moisture of building site
• Introduction
• Heat transfer
• Humidity and condensation point
• Correlation between heat and moisture

Construction site heating
The construction site is heated to:
1) increase the firmness of the concrete
2) dry the structures
3) create good working conditions

Three ways of
heat transfer
Convection
in air or smoke
Radiation
for example
windows
Conduction
through the structures
Speculation: Why are the floors of old houses often cold?

Three ways of
heat transfer
Answer: Warm air rises. If the roof is not tight, the
warm air rises to the roof space and the cold air
flows into the room from windows and door gaps.

Thermal transmittance (U-value) represents
the capacity of heat insulation of different
structural elements. The smaller the U-value,
the better the heat insulation.
In the 1970s and 1980s huge steps were taken in energy efficiency.
Building regulation year
-1969 1969- 1976- 1978- 1985- 10/2003- 2008- 2010- 2012-
W/(K·m²) Warm rooms
Exterior wall 0.81 0.81 0.4 0.35 0.28 0.25 0.24 0.17 0.17
Ground supported floor 0.47 0.47 0.4 0.4 0.36 0.25 0.24 0.16 0.16
Crawlway floor 0.47 0.47 0.4 0.4 0.4 0.2 0.2 0.17 0.17
Base floor adjacent to
outdoors
0.35 0.35 0.35 0.29 0.222 0.16 0.16 0.09 0.09
Roof 0.47 0.47 0.35 0.29 0.22 0.16 0.15 0.09 0.09
Door 2.2 2.2 1.4 1.4 1.4 1.4 1.4 1 1.0
Window 2.8 2.8 2.1 2.1 2.1 1.4 1.4 1 1.0

Year
Building
regulation U-
value[W/Km2
]
Thickness of
insulation
Insulation
layers
U-value of
structure
[W/Km2
]
1976 0.4 100 0.37
1978 0.35 125 0.32
1985 0.28 150 0.27
2003 0.25 175 125 + 50 0.22
2007 0.24 175 125 + 50 0.22
2010 0.17 205 30 + 125 + 50 0.17
2012 0.17 205 30 + 125 + 50 0.17
Examples of wall structures from
different years – mineral wool
insulation

Example
• Area 1.0 m x 2.1 m = 2.1 m2
• Temperature difference 36 K
• Total heat transfer coefficient = 1 W/Km2
=2.1m2 x 36K x 1W/Km2 x 24h = 1.8kWh
How much heat is conducted through the door from 1980s in a day?
=2.1m2 x 36K x 1.4W/Km2 x 24h = 2.5 kWh
Calculate how much heat is conducted during the day through a one-
metre wide door. The inside temperature is 21 oC and outside
temperature is -15 oC.

Example
Area 120 m2
The improvement in total heat transfer coefficient 0.15–0.09 = 0.06 W/Km2
The difference of needed heating energy
= 120 m2 x 0,06W/Km2 x 3878Cod x 24 h/d= 670118 Wh=670 kWh
Saving 0,12 €/kWh x 670 kWh = 80 €
What would be the saving if original level was from 1985 (0,22 W / Km2 )?
The improvement of total heat transfer coefficient 0.22–0.09 = 0.13 W/Km2
The difference of heating energy needed
= 120m2 x 0.3W/Km2 x 3878Cod x 24h/d = 1452 kWh
Saving 0.12€/kWh x 1452 kWh = 174 €
What about in a 1960s house?
Answer: 630 € in a year
Calculate: How much money can be saved in a year by insulating 120 m2 of
the roof from the building regulation level of 2008 to the present level?
• Heating degree day value in Helsinki is 3878 Cod.
• The price of energy is 0.12 €/kWh.

I II III IV V VI VII VIII IX X XI XII Year
Maarianha
mina
592 567 551 406 216 34 3 17 135 308 432 542 3803
Vantaa 682 640 586 376 146 16 2 21 158 348 497 625 4097
Helsinki 647 612 566 383 153 11 1 12 125 316 464 588 3878
Pori 677 633 585 389 181 26 3 25 171 352 497 622 4161
Turku 663 625 575 377 161 19 2 18 149 338 486 608 4021
Tampere 724 675 612 400 176 28 5 34 192 382 529 667 4424
Lahti 726 677 610 395 159 20 4 31 191 383 528 668 4392
Lappeenra
nta
759 699 621 403 165 22 5 28 184 386 546 692 4510
Jyväskylä 785 721 646 440 206 40 10 56 227 414 569 718 4832
Vaasa 719 666 619 424 214 29 5 35 192 377 526 663 4469
Kuopio 812 741 653 445 198 31 7 38 194 400 571 735 4825
Joensuu 826 753 665 456 216 39 10 47 215 416 589 752 4984
Kajaani 864 777 695 479 251 57 17 75 245 441 618 785 5304
Oulu 824 742 677 465 249 47 9 55 224 423 593 749 5057
Sodankylä 946 838 760 548 345 106 49 136 316 523 722 891 6180
Ivalo 923 819 755 557 377 146 69 147 318 523 722 875 6231
Heating degree days 1981-2010

Air humidity and condensation point
Example:
• In December the temperature
is -20 oC outside.
• The roof work is slightly behind
schedule.
• The roof insulation is not
installed.
• The heating has been just
turned on.
The floor slab is still cold. Air
reaches condensation point.

Basic terms
• Absolute humidity is the total amount of water vapour present
in a cubic metre of air.
• The maximum limit of absolute humidity is saturated humidity.
It defines how much water vapour the air can contain at a
certain temperature. Hot air can contain more water vapour
than cold air.
• The condensation point (condensation point temperature) is
the temperature at which saturated humidity is reached.
• Relative humidity defines what percentage of the saturated
humidity of the current temperature is absolute humidity.

Condensation point
Question
When can the condensation point be reached inside a structure?
When is the condensation point harmful and when is it not?
Harmful: In winter, to the inner surface of the external leaf of a sandwich element. When the
ventilation works, the condensation is harmless.
Harmless: The under surface of a sheet metal roof when underlay is under the sheet metal.
Temperature [C]
Absolutehumidity[g/m3]
In the picture air humidity
has condensed on the
cold wall.
The curve illustrates the highest amount of
air humidity at different temperatures.

Drying
• Water evaporation binds energy.
• About 10% of site energy consumed in concrete work goes to
the evaporation of water.
• Evaporated water is transferred to outdoor air through
ventilation. Heating the ventilation accounts for half the total
energy consumption.
• Concrete needs to dry several weeks before it is possible to
start coating work.
• Drying must be slow in the early stage in order to avoid season
cracks.
• The plastic shield on the concreting and curing slow down the
drying proper.
• Proper drying significantly affects the energy consumption and
ensures the quality and the schedule of construction.

Example
• While making concrete,
about 180 litres of water is
used per cube of concrete.
• 60-70 litres of water
combine with concrete. At
balance level, concrete
contains 30-40 litres of
water.
• There are 70-90 litres of
water to be evaporated.
• Evaporated water amounts
to 70-90 litres.
600 litres
How much water evaporates from a slab 80 mm thick and 100 m2
wide?

Question
How much energy is consumed by water
evaporating from a concrete cube?
• Evaporated water = 80 litres
• The heat of evaporation = = 2260 kJ/kg
80 kg x 2260 kJ/kg = 180800 kJ =180.8 MJ =
50 kWh
(0.12 € /kWh x 50 kWh = 6 €)

Moisture movement in a building
element without a vapour barrier
+ -

Moisture movement in a building
element with installed vapour
barrier
+ -

Moisture proofing
Question:
• How is the vapour barrier
installed in the corners of
a building?
• Draw a horizontal section
of the corner.+-
Vapour barrier

Construction moisture can be released by
seepage, by evaporation or, in the worst
case, by mechanical drying.
For example, freezing water in the
insulation of a sandwich element can ruin
the building materials when it melts.
The structures must be designed in a way
that they dry by ventilation.
The structures should stay dry during
installation work. The ventilation systems
of a structure must be made properly.

Mollier diagrams show that:
 when outdoor temperature is less than 0 °C, the cube of air consists of max 5 grams of water vapour.
 When the temperature inside the building site is 15 °C and RH 80 %, the cube of air consists of 10
grams of water vapour.
 when the air exchanges in the site is 10 000 rm3 per hour, the exiting water amount is 50 litres.
The effect of ventilation on site conditions
Diagram of
planning the
building site
ventilation and
temperature :
www.tut.fi/site
0
5
10
15
20
25
30
35
-20 -15 -10 -5 0 5 10 15 20 25 30
Temperature [C ]
o
100 %
80 %
60 %
40 %
20 %
Absolutehumidity[g/m3]

Raising the temperature of concrete by 10
degrees almost always halves the drying time
regardless of the drying circumstances
By using heating cables and an infra dryer the heat is focused
where it is specially needed.

An inch is
enough for
ventilation
Don’t heat
us!

09/07/2015
Working order of crawling space!
• How the wind shield board
(5) should be installed to the
Soffit?
• The shielding board must
be resistant to water.
• Notice that the shielding
board must cover all timber
structures.
• The floor and junctions
must be made airtight.

• A breathable construction does not mean air
movement; it is about the ability of materials to absorb
and release vapour.
• According to current thinking, the construction needs to
be airtight and good indoor air is achieved by
ventilation.
• Who wants to breath the air flowing through old
structures?
Discuss in pairs:
Air-tight construction or breathable construction?

Do you know that
burning 33 kg of gasoline
produces over 53 kg
water vapour!
10 L
3 L
10 L10 L10 L
10 L

The good practices and principles required for the energy efficient building have been
included in the teaching material. The writers are not responsible for their suitability to
individual building projects as such. The individual building projects have to be made
according to the building design of the targets in question.

Energy efficient construction and trainig practices - 1 Basics

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Energy efficient construction and trainig practices - 1 Basics