UB05 MATERIALS AND FINISHES FOR FLOORS AND EXTERIOR WALLS<\/h2><\/div><\/p>\nSelection of materials by thermal and water balances<\/h4>\n
<\/div><\/div>[\/vc_column_inner][vc_column_inner width=”1\/3″][vc_single_image image=”24438″ img_size=”medium” alignment=”right”][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_text_separator title=”” color=”custom” border_width=”4″ accent_color=”#fae699″][vc_column_text]Aim<\/strong><\/p>\nTo select materials, finishes and claddings to be used in the flooring and in the exterior vertical walls considering the effect they may have on
\nthe immediate environment due to their albedo, absorption-emissivity, permeability and texture.<\/p>\n
Why?<\/strong><\/p>\n40 % of the materials used in the European Union are intended for the construction and maintenance of built environments. It is therefore
\nessential that they are durable, need little maintenance, can be reused, recycled or recovered, are non-toxic or harmless, have less energy
\nincorporated in their production and come from areas close to the place of use, so that the energy and pollutants associated with their transport are reduced. To do this, their technical documentation and product declarations must be verified.
\nIn addition, the materials used in horizontal and vertical surfaces depending on the characteristics of their finish or cladding have an effect on
\nurban microclimates and specifically influence both the thermal balance and the water balance of the urban space.
\nUrban climates are an example of artificial mesoclimates. In cities, this phenomenon is called heat island because of variations in temperature,
\nwind speed and pollution compared to the immediate environment. Some of the reasons for this have to do with: the roughness of the urban area, which reduces natural convection; the reduction in the average albedo of surfaces, the heating of urban roads, the emission of pollutants by traffic and air-conditioning systems, the reduction in the percentage of green cover and the increase in the average impermeability of grounds, which alter water cycles and deprive the city of a natural cooling factor.
\nAlthough no direct data are available for medium-sized cities, comparisons can be made with the climate of rural areas surrounding the urban
\nnucleus (Landsberg, 1970) as shown in the table in this sheet.<\/p>\n
How?<\/strong><\/p>\n\u25ba Thermal balance<\/strong>
\nShort-wave solar radiation (direct and diffuse) reflected by the hard surfaces (pavement and building fa\u00e7ades) and long-wave radiation from the sky reach urban spaces. Albedo or reflectivity is the percentage of solar radiation that any surface reflects compared to the radiation that it receives. Being a percentage, it is a non-dimensional parameter and is measured as a number per one. Since the three coefficients that characterise a surface from the point of view of radiation reception (reflectivity, absorptivity and transmissivity) add up to one, the albedo value makes it possible not only to know the capacity of a material to reflect solar radiation, but also, discounting the energy transmitted, the amount of heat energy it is capable of absorbing.
\nThe overall albedo of an urban area also depends on the overall texture of the urban fabric. Some urban configurations involve a greater number of multiple reflections and absorptions which, although the surfaces involved are reflective, can result in a low global urban albedo (ERELL et al, 2010).
\nTherefore, materials should be selected taking into account their ability to reflect the incident radiation. Thus, these general recommendations can be made:
\n\u2022 In spaces where comfort is desired in situations of underheating in winter, using materials with a lower albedo is recommended to accumulate energy or increase surface temperature.
\n\u2022 If adequate spaces are required for situations of overheating in summer, materials with a higher albedo should be selected to avoid heat accumulation on urban surfaces, mainly those in direct contact with citizens.
\n\u2022 When the parameter to be handled is exclusively the colour of the materials, please note that materials with darker colours have a lower albedo than materials with lighter colours. That is, dark materials reflect less incident radiation, so they absorb more energy and accumulate heat within, absorbing it and transferring it to the surrounding environment depending on the temperature of the material and the air. In contrast, lighter colour materials reflect a higher proportion of the incident radiation. Thus, their surface temperature will be lower because they absorb less energy. Therefore, the colours of the materials should be guided by\u00a0the analysis of climatic needs for heat gains or for their reduction.
\n\u2022 The colours of the materials should be chosen in terms of their emissivity and absorption. Thus, dark materials absorb most of the incident solar radiation, while lighter-coloured materials absorb less because they reflect a large part of the incident solar radiation.
\n\u2022 Urban spaces with very rough surface finishes are warmer because the materials are more capable of absorbing energy. Besides, rough materials decrease wind speed and urban areas with protruding surfaces and rough materials decrease natural convection.
\n\u2022 Therefore, depending on the need for natural ventilation or reduction of the influence of the wind determined by the climatic study in each case, more or less smooth materials and surfaces should be chosen.
\n\u2022 If there is no direct sunlight in winter and no shade in summer, materials with low thermal inertia are recommended. However, when there is direct sunlight in winter and shade in summer, materials with high thermal inertia are recommended, as they will accumulate heat in winter and coolness in summer, working as a buffer against temperature fluctuations
\nwhen heat is exchanged by convection with the air.
\n\u25ba Water balance<\/strong>
\nSealing the ground alters the natural characteristics of the land because it interrupts the natural water cycle by reducing the moisture content in the urban environment. It also causes an increase in ambient temperature and a decrease in air quality. Dry urban surfaces, such as asphalts on roads and streets, channel excess radiant energy during the day by storing that heat or exchanging it with the environment by convection and increasing the air temperature. When there is a supply of moisture on surfaces, that excess energy, instead of becoming a noticeable heat that heats the air, it will be latent heat that is not transferred to the air, since the energy is used to evaporate the water. This is what happens with natural grounds, they are more humid than water-proof surfaces, which makes cooling the surrounding air possible due to evaporation.<\/p>\nIn the warm summer months, water can be used to reduce the surface temperature of the walls. This cooling can be approached in two different ways: by favouring the evaporation of water on surfaces or increasing the transfer of heat to the ground under the floors by circulating water underneath.<\/p>\n
By combining the use of water with porous materials, the reduction in the transfer of heat from the materials to the air is due to the evaporation of the water, which will remain in the materials for a longer time than if they were compact.
\nPermeable materials hold water when it seeps into the ground for a longer period of time. This increases humidity in urban environments (HERN\u00c1NDEZ, Agust\u00edn: Manual de dise\u00f1o bioclim\u00e1tico urbano).[\/vc_column_text][\/vc_column][vc_column width=”1\/3″ css=”.vc_custom_1548800623319{background-color: #fdfae4 !important;}”][vc_text_separator title=”street\/building SCALE INTERVENTION” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_single_image image=”24687″ img_size=”full” alignment=”center”][vc_text_separator title=”ISSUES AFFECTED” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_gallery type=”image_grid” images=”23817,23899,23824,23820,23826,23907,23902,23821,23908,23819,23818,23897″ onclick=”custom_link” custom_links=”https:\/\/www.saulverez.com,https:\/\/www.concellodelugo.com” img_size=”52×52″][vc_text_separator title=”SUITABLE FOR COMBINING WITH OTHER SOLUTIONS” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_gallery type=”image_grid” images=”25569,25570,25520,25532″ onclick=”custom_link” img_size=”150×55″ custom_links=”http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ub02-orientation-of-buildings\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ub03-direct-sunlight-in-open-spaces\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ev02-urban-forest\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ev04-pocket-garden\/,”][vc_text_separator title=”MEASURING ELEMENTS” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Indicator<\/strong>
\nReduction of heat gain from surfaces exposed to direct solar radiation
\nin the warmer months and increase of heat gain in the cooler
\nmonths.
\nUnit<\/strong>
\nAlbedo = Per cent of reflected radiation \/ Per cent of incident
\nradiation
\nMinimum goal<\/strong>
\nFor summer locations:
\nSurfaces in direct sunlight for more than 6 hours: albedo \u2265 0.3 0
\nSurfaces in direct sunlight for 2 to 6 hours: albedo \u2265 0.15
\nFor winter locations:
\nSurfaces in direct sunlight only: albedo < 0.30
\nDesirable goal<\/strong>
\nFor summer locations:
\nSurfaces in direct sunlight for more than 6 hours: albedo \u2265 0.4 0
\nSurfaces in direct sunlight for 2 to 6 hours: albedo \u2265 0.20
\nFor winter locations:
\nSurfaces in direct sunlight only: albedo < 0.20
\nMeasure method \/ Formula<\/strong>
\nA: Albedo. The values of albedo must be provided by the manufacturer
\nmaterial or, if not, calculated or approximated by the design team
\nthrough specific manuals.[\/vc_column_text][vc_text_separator title=”planning level” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Building construction project
\nUrban planning[\/vc_column_text][vc_text_separator title=”Agents involved” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Planning Design team
\nCouncil arquitect
\nReal estate developers[\/vc_column_text][vc_text_separator title=”Possible actions promoted by the administration” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Drafting of building regulations in accordance with this strategy.[\/vc_column_text][vc_text_separator title=”What should we consider for its implementation?” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Creating open spaces adapted to the climate of the place is closely related to the position of the building. Therefore, it is essential to study the ordinance considering optimising the position of buildings with that of open spaces at the same time.[\/vc_column_text][vc_text_separator title=”EXAMPLES” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Heat Island Group LNLB ![\"\"](\"http:\/\/www.lugobiodinamico.eu\/catalogo\/wp-content\/uploads\/2019\/02\/Enlace-web-150x150.png\")
<\/a><\/p>\n
Selection of materials by thermal and water balances<\/h4>\n
<\/div><\/div>[\/vc_column_inner][vc_column_inner width=”1\/3″][vc_single_image image=”24438″ img_size=”medium” alignment=”right”][\/vc_column_inner][\/vc_row_inner][vc_empty_space][vc_text_separator title=”” color=”custom” border_width=”4″ accent_color=”#fae699″][vc_column_text]Aim<\/strong><\/p>\n To select materials, finishes and claddings to be used in the flooring and in the exterior vertical walls considering the effect they may have on Why?<\/strong><\/p>\n 40 % of the materials used in the European Union are intended for the construction and maintenance of built environments. It is therefore How?<\/strong><\/p>\n \u25ba Thermal balance<\/strong> In the warm summer months, water can be used to reduce the surface temperature of the walls. This cooling can be approached in two different ways: by favouring the evaporation of water on surfaces or increasing the transfer of heat to the ground under the floors by circulating water underneath.<\/p>\n By combining the use of water with porous materials, the reduction in the transfer of heat from the materials to the air is due to the evaporation of the water, which will remain in the materials for a longer time than if they were compact.
\nthe immediate environment due to their albedo, absorption-emissivity, permeability and texture.<\/p>\n
\nessential that they are durable, need little maintenance, can be reused, recycled or recovered, are non-toxic or harmless, have less energy
\nincorporated in their production and come from areas close to the place of use, so that the energy and pollutants associated with their transport are reduced. To do this, their technical documentation and product declarations must be verified.
\nIn addition, the materials used in horizontal and vertical surfaces depending on the characteristics of their finish or cladding have an effect on
\nurban microclimates and specifically influence both the thermal balance and the water balance of the urban space.
\nUrban climates are an example of artificial mesoclimates. In cities, this phenomenon is called heat island because of variations in temperature,
\nwind speed and pollution compared to the immediate environment. Some of the reasons for this have to do with: the roughness of the urban area, which reduces natural convection; the reduction in the average albedo of surfaces, the heating of urban roads, the emission of pollutants by traffic and air-conditioning systems, the reduction in the percentage of green cover and the increase in the average impermeability of grounds, which alter water cycles and deprive the city of a natural cooling factor.
\nAlthough no direct data are available for medium-sized cities, comparisons can be made with the climate of rural areas surrounding the urban
\nnucleus (Landsberg, 1970) as shown in the table in this sheet.<\/p>\n
\nShort-wave solar radiation (direct and diffuse) reflected by the hard surfaces (pavement and building fa\u00e7ades) and long-wave radiation from the sky reach urban spaces. Albedo or reflectivity is the percentage of solar radiation that any surface reflects compared to the radiation that it receives. Being a percentage, it is a non-dimensional parameter and is measured as a number per one. Since the three coefficients that characterise a surface from the point of view of radiation reception (reflectivity, absorptivity and transmissivity) add up to one, the albedo value makes it possible not only to know the capacity of a material to reflect solar radiation, but also, discounting the energy transmitted, the amount of heat energy it is capable of absorbing.
\nThe overall albedo of an urban area also depends on the overall texture of the urban fabric. Some urban configurations involve a greater number of multiple reflections and absorptions which, although the surfaces involved are reflective, can result in a low global urban albedo (ERELL et al, 2010).
\nTherefore, materials should be selected taking into account their ability to reflect the incident radiation. Thus, these general recommendations can be made:
\n\u2022 In spaces where comfort is desired in situations of underheating in winter, using materials with a lower albedo is recommended to accumulate energy or increase surface temperature.
\n\u2022 If adequate spaces are required for situations of overheating in summer, materials with a higher albedo should be selected to avoid heat accumulation on urban surfaces, mainly those in direct contact with citizens.
\n\u2022 When the parameter to be handled is exclusively the colour of the materials, please note that materials with darker colours have a lower albedo than materials with lighter colours. That is, dark materials reflect less incident radiation, so they absorb more energy and accumulate heat within, absorbing it and transferring it to the surrounding environment depending on the temperature of the material and the air. In contrast, lighter colour materials reflect a higher proportion of the incident radiation. Thus, their surface temperature will be lower because they absorb less energy. Therefore, the colours of the materials should be guided by\u00a0the analysis of climatic needs for heat gains or for their reduction.
\n\u2022 The colours of the materials should be chosen in terms of their emissivity and absorption. Thus, dark materials absorb most of the incident solar radiation, while lighter-coloured materials absorb less because they reflect a large part of the incident solar radiation.
\n\u2022 Urban spaces with very rough surface finishes are warmer because the materials are more capable of absorbing energy. Besides, rough materials decrease wind speed and urban areas with protruding surfaces and rough materials decrease natural convection.
\n\u2022 Therefore, depending on the need for natural ventilation or reduction of the influence of the wind determined by the climatic study in each case, more or less smooth materials and surfaces should be chosen.
\n\u2022 If there is no direct sunlight in winter and no shade in summer, materials with low thermal inertia are recommended. However, when there is direct sunlight in winter and shade in summer, materials with high thermal inertia are recommended, as they will accumulate heat in winter and coolness in summer, working as a buffer against temperature fluctuations
\nwhen heat is exchanged by convection with the air.
\n\u25ba Water balance<\/strong>
\nSealing the ground alters the natural characteristics of the land because it interrupts the natural water cycle by reducing the moisture content in the urban environment. It also causes an increase in ambient temperature and a decrease in air quality. Dry urban surfaces, such as asphalts on roads and streets, channel excess radiant energy during the day by storing that heat or exchanging it with the environment by convection and increasing the air temperature. When there is a supply of moisture on surfaces, that excess energy, instead of becoming a noticeable heat that heats the air, it will be latent heat that is not transferred to the air, since the energy is used to evaporate the water. This is what happens with natural grounds, they are more humid than water-proof surfaces, which makes cooling the surrounding air possible due to evaporation.<\/p>\n
\nPermeable materials hold water when it seeps into the ground for a longer period of time. This increases humidity in urban environments (HERN\u00c1NDEZ, Agust\u00edn: Manual de dise\u00f1o bioclim\u00e1tico urbano).[\/vc_column_text][\/vc_column][vc_column width=”1\/3″ css=”.vc_custom_1548800623319{background-color: #fdfae4 !important;}”][vc_text_separator title=”street\/building SCALE INTERVENTION” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_single_image image=”24687″ img_size=”full” alignment=”center”][vc_text_separator title=”ISSUES AFFECTED” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_gallery type=”image_grid” images=”23817,23899,23824,23820,23826,23907,23902,23821,23908,23819,23818,23897″ onclick=”custom_link” custom_links=”https:\/\/www.saulverez.com,https:\/\/www.concellodelugo.com” img_size=”52×52″][vc_text_separator title=”SUITABLE FOR COMBINING WITH OTHER SOLUTIONS” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_gallery type=”image_grid” images=”25569,25570,25520,25532″ onclick=”custom_link” img_size=”150×55″ custom_links=”http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ub02-orientation-of-buildings\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ub03-direct-sunlight-in-open-spaces\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ev02-urban-forest\/,http:\/\/www.lugobiodinamico.eu\/catalogo\/en\/proyectos\/ev04-pocket-garden\/,”][vc_text_separator title=”MEASURING ELEMENTS” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Indicator<\/strong>
\nReduction of heat gain from surfaces exposed to direct solar radiation
\nin the warmer months and increase of heat gain in the cooler
\nmonths.
\nUnit<\/strong>
\nAlbedo = Per cent of reflected radiation \/ Per cent of incident
\nradiation
\nMinimum goal<\/strong>
\nFor summer locations:
\nSurfaces in direct sunlight for more than 6 hours: albedo \u2265 0.3 0
\nSurfaces in direct sunlight for 2 to 6 hours: albedo \u2265 0.15
\nFor winter locations:
\nSurfaces in direct sunlight only: albedo < 0.30
\nDesirable goal<\/strong>
\nFor summer locations:
\nSurfaces in direct sunlight for more than 6 hours: albedo \u2265 0.4 0
\nSurfaces in direct sunlight for 2 to 6 hours: albedo \u2265 0.20
\nFor winter locations:
\nSurfaces in direct sunlight only: albedo < 0.20
\nMeasure method \/ Formula<\/strong>
\nA: Albedo. The values of albedo must be provided by the manufacturer
\nmaterial or, if not, calculated or approximated by the design team
\nthrough specific manuals.[\/vc_column_text][vc_text_separator title=”planning level” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Building construction project
\nUrban planning[\/vc_column_text][vc_text_separator title=”Agents involved” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Planning Design team
\nCouncil arquitect
\nReal estate developers[\/vc_column_text][vc_text_separator title=”Possible actions promoted by the administration” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Drafting of building regulations in accordance with this strategy.[\/vc_column_text][vc_text_separator title=”What should we consider for its implementation?” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Creating open spaces adapted to the climate of the place is closely related to the position of the building. Therefore, it is essential to study the ordinance considering optimising the position of buildings with that of open spaces at the same time.[\/vc_column_text][vc_text_separator title=”EXAMPLES” color=”custom” style=”dotted” border_width=”2″ accent_color=”#fae699″][vc_column_text]Heat Island Group LNLB <\/a><\/p>\n
![\"\"](\"http:\/\/www.lugobiodinamico.eu\/catalogo\/wp-content\/uploads\/2019\/02\/Enlace-web-300x300.png\")
<\/a>[\/vc_column_text][\/vc_column][\/vc_row][vc_row][vc_column][vc_single_image image=”25381″ img_size=”full”][\/vc_column][\/vc_row]<\/p>\n","protected":false},"excerpt":{"rendered":"