Sustainable Design Part Four: Sustainable Materials

What is Sustainable Design? Part Four: Sustainable Materials The George and Kathy Dembroski Centre for Horticulture, Toronto Terri Meyer Boake BES, BArch, MArch, LEED AP Associate Director School of Architecture University of Waterloo Past President of the Society of Building Science Educators Member OAA Committee on Sustainable Built Environment

Presentation Summary In this presentation, we will discuss: Green/less harmful materials Sourcing materials Materials that retain heat (thermal mass) Materials that reject heat (insulation) The colour of materials Exterior materials Heat Island Effect Embodied Energy

Materials First! Aldo Leopold Legacy Centre, Wisconsin The Bird’s Nest, Beijing Materials need to be part of the very initial thoughts as a building is conceived. A building’s design is intrinsically linked to its materiality.

Material Choices When designing buildings we usually have a choice as to what material to specify Materials can be compared as being more or less harmful to the environment We should obviously choose less harmful materials We should use materials that use less energy We should use materials that make our buildings more efficient Materials should be both beautiful and enduring The George and Kathy Dembroski Centre for Horticulture, Toronto

Define “harmful”! Toxic to the environment Harvest endangers wildlife/removes habitat Harvest endangers/compromises local people Processing or manufacturing harms the environment Some materials are limited as a resource Some materials are not easy to reuse or recycle Some materials are energy intensive

Materials can be classed as either renewable or non-renewable Non renewable materials includes metals, and stones and items that “do not grow” Renewable materials include wood, straw, bamboo and other “growing” substances Renewable vs Non-Renewable

It is preferable to use renewable materials , but when it is not possible one can source: Recycled materials or materials with a significant recycled content: such as steel where a good percentage of the product is put back into the manufacture of goods at the “end of life” Reused materials: preferred as it is not necessary to put additional energy into remanufacturing the product Virgin vs. Recycled or Reused TOHU, Permanent Bigtop, Montreal

Durability Preference is almost always given to the use of more durable/long lasting materials It is expensive to have to replace windows, roofing materials and cladding Expense can be measured both in terms of dollars as well as energy (and associated greenhouse gas emissions) Caisse du Depots et Placements, Montreal

Embodied Energy Definition: Embodied energy is the energy associated with the harvesting/mining, manufacture, transportation and construction of a material Transportation energy is significant for ALL materials, even if they are of the renewable variety Materials with “high embodied energy” are less desirable from a sustainable perspective However, some high energy materials are irreplaceable for certain uses: concrete for its thermal mass ; aluminum for its durability , steel for its strength

Retain vs Reject Heat Materials can be classed as those that RETAIN HEAT and those that REJECT HEAT HEAT RETENTION is useful if we wish to store the free energy from the sun in the material HEAT REJECTION is also called INSULATION. INSULATING materials are used to retard the heat flow through the building envelope INSULATION at VERY HIGH LEVELS is essential in all elements of a cold climate building envelope THERMAL BRIDGES are points in the building envelope where there insulation is completely lacking THERMAL BRIDGES ARE TO BE AVOIDED as they result in heat loss and normally degradation of the building envelope at the point of breach (evidenced by condensation, mould, mildew or rust)

Insulation Different types perform different ways, as a function of their materiality and thickness. More is more… Some are less environmentally harmful than others. Soybean based spray Fiberglass batt Styrofoam R values of batt insulation Spray cellulose insulation Rigid fiberglass

Heat Storage Capacity of Materials The specific heat of materials is different than their ability to store this heat. This is referred to as their “ thermal mass ” or “ heat storage capacity ”. Thermal mass is the ability of a material to hold heat and slowly release it back into the environment giving a flywheel effect. We often make a choice, depending on the climate, if we need to store heat to have it released later in the day, when the sun is down and things have “cooled off”. Materials with a high thermal mass are helpful in the heating of building interiors in cold climates. We need to select materials with a high heat storage capacity but that are not conductors (like metal).

Thermal Mass IslandWood, Seattle Exposed concrete floors are becoming increasingly common in sustainable buildings. The concrete is both structural and acts as an excellent storage material for free solar energy that comes in through the windows. It can be made less harmful by replacing some of its cement content with “flyash” which is a waste product of the steel industry. The concrete can be stained with different colours if desired.

Microclimate and Site Materials Microclimate is the “mini climate zone” around your building as modified by local conditions. Things that naturally change your microclimate are : amount of sun received over the day wind and natural breezes The natural materials of the site Things that YOU select also change the microclimate : material choices: paving, roofing, wall materials and planting colour of materials In a cold climate select materials to INCREASE HEAT in the WINTER and DECREASE HEAT ABSORPTION in the SUMMER

Solar Access and Microclimate The micro climates in the backyards on either side of the walkway are different as a result of solar access, even though materially they are identical. Bain Avenue Coop, Toronto

The front of the house has more paving and less tree cover, which make it hotter. The black asphalt roof also raises the general heat level of the site. East elevation West elevation There are different microclimates on the front vs. the back of the house due to materials, amount of shade and orientation (sun).

The Effect of “Found” Site Natural Materials Natural materials and the natural site landscape and configuration will affect the heating or cooling potential of the site. Replacing natural “soft” materials with “hard or impervious” materials will increase the heat retention potential of the site. Pervious materials are preferred as they allow rainwater to be naturally cleaned and cycled without being directed into the storm and sanitary systems. Heat retention makes for a warm microclimate and can increase the cooling requirements of buildings in the summer months.

The Effect of Roofing Choices The choice of roofing material critically impacts heat retention. - Dark materials absorb heat, which is redirected to the urban atmosphere, where greenhouse gasses trap it in place. - Light materials reflect the heat (aka “ cool roofs ”). - Green roofs stay cool, produce oxygen and absorb rain water, reducing pressure on the sewer system.

Cool Roofs Theory Cool roof materials have two important surface properties: a high solar reflectance or albedo and a high thermal emittance . Solar reflectance is the percentage of solar energy that is reflected by a surface. Thermal emittance is defined as the percentage of energy a material can radiate away after it is absorbed. Vernacular architecture in hot climates normally finish roofs in light colours to reflect heat as well as to provide a clean surface for water collection.

Green Roofs Green roof technology started in Germany over 30 years ago. Proprietary systems are being looked at with some seriousness in Canada at this point. Green roofs reduce urban heat island effect and decrease carbon dioxide levels in the city. They also can provide a higher level of insulation (but not necessarily). Green roof treatments can cover the entire roof, or just a smaller part, depending on the requirements and limitations of the project. Vancouver Public Library Children’s Museum, Boston

Imagine the environmental benefit and resultant cooling if all of those roofs were either green roofs or cool roofs…. It would help to mitigate Urban Heat Island Effect.

The Effect of Paving Choices “ Paving” or the displacement of pervious, green surfaces, with hard surfaces, is a primary cause of negative changes to the local microclimate. Paving can not only cause heat retention, and overheat the urban environment, but it can also impact water runoff and absorption into the site. Paving selections need to simultaneously: Allow for water to be absorbed into the earth (pervious) Be durable for winter traffic conditions and snow removal Create a cool microclimate to prevent heat island effect

Phoenix, Arizona: shopping centre with (white) roof and pavement...

Permeable Paving Different materials are available that allow for a level of durability for traffic, yet also let water drain through. Issues of snow removal must be accounted for when choosing materials. Permeable concrete is also an option.

The Effect of Other Material Choices Other materials on site, whether they are chosen for walls or accessory structures, will affect the overall tendency of the site to retain heat and create a hot environment. Shading your walls will help to prevent heat gain. However, in very cold climates, where the sun angle is very low, material choice can be used TO hold heat in the building and warm up outside spaces.

Presentation Summary In this presentation, we discussed: Green materials Sourcing materials Materials that retain heat (thermal mass) Materials that reject heat (insulation) The colour of materials Exterior materials Heat Island Effect Embodied Energy

Sustainable Design Part Four: Sustainable Materials

Related slideshows

More Related Content

Sustainable Design Part Four: Sustainable Materials