Buildings represent the largest potential for energy savings. Insulation is a key strategy to reduce building energy demand and achieve low energy buildings. Proper insulation works by reducing heat transfer through conduction, convection, and radiation. The appropriate insulation material depends on the building type, design, climate, and mechanical requirements. High quality insulation installed correctly can significantly reduce heat loss and energy use over the lifetime of the building.
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Insulation Technologies and Materials
1. Insulation Technologies and Materials
IEA - Building Envelope Technologies and Policies Workshop
Thursday 17 & Friday 18 November 2011, Paris
Shpresa Kotaji, Huntsman Environmental Affairs Manager
Oliver Loebel, PU Europe Secretary General
2. Buildings represent the biggest energy
saving potential
Estimated energy saving potential (%) 2020
24% 25%
Residential
buildings
53% !
Commercial
buildings
Manufacturing
industry
Transport
23% 28%
Source: COM(2006)545 final, 2006
3. Strategies for building energy saving
Trias Energetica: the most sustainable energy is saved energy
1 Reduce the demand for energy by avoiding
heat losses and implementing energy-saving
measures
2 Use sustainable sources of
energy instead of finite fossil
fuels
3 Produce and use
fossil energy as
efficiently as
possible
4. How to reduce building energy demand ?
Housing Commercial buildings
Many buildings e.g. deep-plan
air-conditioned offices will
have higher ventilation/cooling
energy compared to heating
5. 4 Steps to Low Energy Buildings
1. 2. 3. 4.
Orientation Insulation + Controlled Efficient
Compact Airtightness ventilation lighting +
appliances
heat
reclaimed
from
ventilation air
Typical modern Airtight house with
house, 1 ac/h at MHVR to achieve
natural pressure 0.5 ac/h,70% eff
(2000 Standard) (LowHeat Standard)
A+++
Sun Rose
Percentage of solar energy from different Ventilation
directions (45o inclined plane) - London
heat loss
Source: XCO2 - Insulation guide for Sustainability
6. How building insulation works
Un-insulated wall Insulated wall
Low density material Fibrous
with complex solid
paths reduces
Convection conduction
Conduction Cellular
Radiation
Air gaps with Cellular or fibrous
reflective and structure of trapped
low-emissivity gas pockets reduces
surfaces block convection.
radiation
Inside Outside Inside Outside
7. The types of insulation materials
and heat loss rate
Classification of insulation materials
Fibrous Cellular
Mineral
‘inorganic’
The key equation relating U-value
(heat loss rate) to lambda (thermal
Oil-derived conductivity) and thickness (d)
‘organic synthetic’
Plant / animal
‘organic natural’
W/m · K
W/m2 · K
m
Note: highly approximate,
issues like thermal bridging
must be considered
9. 4 steps to insulation solution selection
In new build and renovation
10. 1. Design for low thermal conductivity
Insulation thickness at same U-value
1. Target low U-value designs
2. Consider any thickness
Polyurethane restriction (especially in
renovation)
11. Step 2. Choose fit for purpose solutions
and quality products
Typical Pitched Walkable Walls Ground
applications roofs flat roofs floor Choice might be restricted due to
• climate/exposure
Polyurethane – Wind, flood, rain …
EPS • mechanical properties requirements
– Walkability
XPS • thickness restriction
Glass wool
Quality and performance testing
Stone wool • Prefer material with certified declared
thermal properties according to
Cellulose standards (e.g. CE marking, ASTM…)
Hemp
Ensure insulation can be applied
Ensure right ancillary materials are used to secure proper
function
Choose quality product with certified declared properties
12. Step 3. Design for durability and low
failure risk
Installation risks: all materials are vulnerable to poor installation
leaving gaps or physical deterioration (compression). Good
workmanship is essential
Condensation: can reduce
thermal resistance and
damage building fabric
Vapour permeability
Air movement at surface:
presents risk of
can cause convection heat
condensation
loss
Leakiness - air Ageing: any degradation
escaping carries to material or to thermal
heat away resistance from quoted
values over the lifetime,
including settlement or
compression
Inside Outside
Ensure proper installation
Ensure proper detailing to avoid premature
performances losses
13. Step 4. Design for reduced building
embodied environmental impacts
1°optimise building 2°reduced embodied impact if that does
energy-in-use not compromise in-use performance
AP Energy use Cool continental
Acidification Energy use Temperate Oceanic
Energy use Temperate Mediterranean
Construction materials
POCP Insulation materials
Photochemical
energy
ozone formation
EP
Eutrophication
ODP
Ozone depletion
GWP Normalized to EU citizen
Global warming
0 2 4 6 8 10 12
Normalised environmental impact EU citizen
Designing for low energy Insulation choice itself has
increases the relative limited impact on the
embodied impact, but… building embodied impacts
15. Highly insulated low energy houses
today’s technologies, available across the regions
16. Conclusions
Almost half of our energy is used in buildings
Today’s high performance insulation and thermal design can dramatically
reduce heat losses – solutions are already available and applied across all
regions, both in new build and renovation
The choice of the most appropriate insulation product has to be decided
on a case-by-case basis as it largely depends on the building type and
design and climate zone
The following principles must be respected when specifying insulation
products for low energy buildings:
Firstly design the building for low thermal losses
Then, choose insulation products and solutions fit for the applications
and, following this, ensure the longevity of the thermal performance over the
lifetime of the building through choosing quality materials with certified
performance levels.
Finally, the environmental performance of suitable insulation products
should be determined using an overall life cycle methodology
There is an increasing trend to develop factory-made durable high quality
building envelope elements combining high insulation level, high air-
tightness and fast erection speed
17. Thank you for your attention
While all the information and recommendations in this publication are to the best of our knowledge, information and belief accurate at the date of
publication, nothing herein is to be construed as a warranty, express or otherwise. In all cases, it is the responsibility of the user to determine the
applicability of such information.