Association for Environment Conscious Building

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The Association for Environment Conscious Building (AECB) is the leading[ citation needed ] network for sustainable building professionals in the United Kingdom. Membership of the AECB includes local authorities, housing associations, builders, architects, designers, consultants and manufacturers. The association was founded in 1989 to increase awareness within the construction industry of the need to respect, protect, preserve and enhance the environment and to develop, share and promote best practice in environmentally sustainable building.

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Low-carbon building

While the AECB recognises that all aspects of sustainability are important, it believes that climate change threatens to overwhelm its members' achievements in other areas. It is therefore currently focusing on trying to help reduce carbon emissions related to domestic and non-domestic buildings in the UK (around 50% of UK CO2 emissions excluding flying relate to buildings). The association believes that the Government's target of a 60% reduction in CO2 emissions by 2050 is too little, too late, and that a reduction of at least 85% is required to meet the challenges of climate change.

Low-carbon standards

To promote low-carbon building, the association has developed three advanced energy standards, in order to provide three steps to low energy and low carbon buildings achievable by the UK over the next 40 years. These standards are largely based on the methodology and principles underlying the German Passivhaus movement, developed by the Passivhaus Institut, and are also informed by American, Canadian, Scandinavian and European energy standards and various successful energy efficient building programmes. The standards themselves lie at the centre of a developing education and training programme which the AECB has called the 'Carbon Literate Design and Construction Programme' (CLP).

The AECB standards are : the New Building Standard, Retrofit Standard 1 and Retrofit Standard 2.

The AECB has aimed these Standards at those wishing to create high-performance buildings using widely available technology at little or no extra cost. It estimates that these low-risk options, will reduce overall CO₂ emissions by 70% compared with the UK average for buildings of each type a result it feels is highly significant given the relative ease and low cost with which these standards could be met.

The AECB, believing that rigorous alternative approaches based on successful overseas' experience for sustainable design and construction have a complementary place alongside UK government initiatives, has been lobbying for the Government's Code for Sustainable Homes to be aligned with its CLP, or at least for the CLP (despite its methodological and base-line measuring differences) to be treated as an alternative official route for effectively designing and delivering low energy and low carbon buildings. The AECB has taken the stance of inviting the design and construction industry to judge for itself, based on actual real world performance of the resulting buildings, which low carbon design codes and programmes best deliver genuinely low energy and low carbon performance cost effectively.

Low Energy Buildings Database

A guiding principle of the AECB is to focus on what really works in practice, to deliver buildings with genuinely improved environmental performance. The AECB established the Low Energy Buildings Database with the support of the Technology Strategy Board [1] to show people what could actually be achieved in reality, as opposed to what people hoped they might achieve when developing the design. The database draws on the collective experience of AECB members, and now also the team’s involved in the Retrofit for the Future projects, [2] and shares that learning. Almost uniquely, this database gives an honest account to anyone planning a low energy building of what can be achieved, along with a detailed account of how it has been done.

The database includes information on both refurbishment and new build projects, in both the domestic and non-domestic sectors. The database shows the performance of each building, in both figures and clearly presented graphs. Design intention can easily be compared with built reality, and projects can easily be compared with each other. For each project you can see detailed design strategies, descriptions and illustrations of the building type, the measures taken and technologies employed. As the monitoring figures accumulate, the database will offer increasing numbers of well-illustrated and robust benchmarks for the energy and carbon performance levels that can be achieved, across a wide range of building types.

Less is More

On 30 January 2012 the AECB released its report Less is More: Energy Security after Oil [3] which was published at the end of an unprecedented fifteen years in UK energy policy history. It began with the formal acceptance of the need for a climate change policy by the last Conservative Government in 1997[ citation needed ] and culminated with the Climate Change Act 2008 and the 4th Carbon Budget. [4] Less is More is a significant new contribution to the debate and offers an alternative to the emerging orthodoxy of large-scale electrification of heat and road transport as a way to achieve or beat the UK's 2050 CO2 emissions target. This is based on more vigorous and systematic pursuit of energy efficiency throughout the economy; on technologies such as large-scale solar heat, piped to urban buildings; a road and air transport system synthesising liquid fuels in part from renewable electricity, supplementing the biofuel resource; a small electricity supply system, supplied largely by despatchable sources, assisting with network security; and the more vigorous pursuit of carbon dioxide (CO2) sequestration options, particularly in the biosphere.

Less is More contends that an electric future is more costly and could be slower to deliver significant CO2 reductions than the alternatives. Vigorous pursuit of energy efficiency, plus biosequestration, plus more focus on UK energy uses and the characteristics of energy systems, sets the stage for significantly cheaper and more secure energy supply options. Less-electric futures appear to have the capacity to deliver CO2 reductions both more cheaply and more quickly than more-electric. Cumulative emissions to 2050 are at least as important as emissions in the year 2050. The report highlights key areas for technology, product and supply chain development. They include piped heat, which is a mature technology in several of Britain's continental neighbours, and heats over 60% of Danish buildings, but remains uncommon in the UK. They include high-performance insulation systems that could significantly reduce losses in heat storage and distribution systems at all scales, along with renewable fuel production. Heat networks play a systematic role in the scenario, opening up access to large-scale solar, geothermal and waste heat resources at lower costs than new electricity sources and reducing the risk that the UK will be unable to keep the lights on.

Less is More contains a critique of the dysfunctionality of UK energy markets. The authors note that water is supplied by vertically-integrated and regulated local monopolies, which have access to capital at near-public sector interest rates, especially if they are debt-funded. They pose the question of why such arrangements cannot be used again in the energy sector, paralleling as it happens the situation with some private US utilities and with utilities in Denmark. The report does not offer the prospect of an easy path to energy independence and decarbonisation. It makes it very clear that all options pose acute difficulties. But it warns policy-makers not to reject technologies just because they appear difficult without making sober comparisons with the reality of the other technologies under consideration. [5]

Other AECB Resources

The AECB followed up Less is More with the Post-Fossil Fuel Building Construction and Materials report and continues to publish original material, training courses and podcasts. In 2022, it launched its own free magazine "Setting the Standard" which contains original commentary, analysis and thought pieces from the world of sustainable, green building.

See also

Related Research Articles

Energy conservation is the effort to reduce wasteful energy consumption by using fewer energy services. This can be done by using energy more effectively or changing one's behavior to use less service. Energy conservation can be achieved through efficient energy use, which has a number of advantages, including a reduction in greenhouse gas emissions and a smaller carbon footprint, as well as cost, water, and energy savings.

<span class="mw-page-title-main">Heat recovery ventilation</span> Method of reusing thermal energy in a building

Heat recovery ventilation (HRV), also known as mechanical ventilation heat recovery (MVHR), is an energy recovery ventilation system that operates between two air sources at different temperatures. It's a method that is used to reduce the heating and cooling demands of buildings. By recovering the residual heat in the exhaust gas, the fresh air introduced into the air conditioning system is preheated, and the fresh air's enthalpy is reduced before it enters the room, or the air cooler of the air conditioning unit performs heat and moisture treatment. A typical heat recovery system in buildings comprises a core unit, channels for fresh and exhaust air, and blower fans. Building exhaust air is used as either a heat source or heat sink, depending on the climate conditions, time of year, and requirements of the building. Heat recovery systems typically recover about 60–95% of the heat in the exhaust air and have significantly improved the energy efficiency of buildings.

<span class="mw-page-title-main">Sustainable energy</span>

Energy is sustainable if it "meets the needs of the present without compromising the ability of future generations to meet their own needs." Most definitions of sustainable energy include considerations of environmental aspects such as greenhouse gas emissions and social and economic aspects such as energy poverty. Renewable energy sources such as wind, hydroelectric power, solar, and geothermal energy are generally far more sustainable than fossil fuel sources. However, some renewable energy projects, such as the clearing of forests to produce biofuels, can cause severe environmental damage.

<span class="mw-page-title-main">Green building</span> Structures and processes of building structures that are more environmentally responsible

Green building refers to both a structure and the application of processes that are environmentally responsible and resource-efficient throughout a building's life-cycle: from planning to design, construction, operation, maintenance, renovation, and demolition. This requires close cooperation of the contractor, the architects, the engineers, and the client at all project stages. The Green Building practice expands and complements the classical building design concerns of economy, utility, durability, and comfort. Green building also refers to saving resources to the maximum extent, including energy saving, land saving, water saving, material saving, etc., during the whole life cycle of the building, protecting the environment and reducing pollution, providing people with healthy, comfortable and efficient use of space, and being in harmony with nature Buildings that live in harmony. Green building technology focuses on low consumption, high efficiency, economy, environmental protection, integration and optimization.’

<span class="mw-page-title-main">Carbon Trust</span> UK non-profit climate change consultancy

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<span class="mw-page-title-main">Low-energy house</span> House designed for reduced energy use

A low-energy house is characterized by an energy-efficient design and technical features which enable it to provide high living standards and comfort with low energy consumption and carbon emissions. Traditional heating and active cooling systems are absent, or their use is secondary. Low-energy buildings may be viewed as examples of sustainable architecture. Low-energy houses often have active and passive solar building design and components, which reduce the house's energy consumption and minimally impact the resident's lifestyle. Throughout the world, companies and non-profit organizations provide guidelines and issue certifications to guarantee the energy performance of buildings and their processes and materials. Certifications include passive house, BBC - Bâtiment Basse Consommation - Effinergie (France), zero-carbon house (UK), and Minergie (Switzerland).

<span class="mw-page-title-main">Passive house</span> Type of house

Passive house is a voluntary standard for energy efficiency in a building, which reduces the building's ecological footprint. It results in ultra-low energy buildings that require little energy for space heating or cooling. A similar standard, MINERGIE-P, is used in Switzerland. The standard is not confined to residential properties; several office buildings, schools, kindergartens and a supermarket have also been constructed to the standard. The design is not an attachment or supplement to architectural design, but a design process that integrates with architectural design. Although it is generally applied to new buildings, it has also been used for refurbishments.

<span class="mw-page-title-main">Zero-energy building</span> Energy efficiency standard for buildings

A Zero-Energy Building (ZEB), also known as a Net Zero-Energy (NZE) building, is a building with net zero energy consumption, meaning the total amount of energy used by the building on an annual basis is equal to the amount of renewable energy created on the site or in other definitions by renewable energy sources offsite, using technology such as heat pumps, high efficiency windows and insulation, and solar panels.

Domestic housing in the United Kingdom presents a possible opportunity for achieving the 20% overall cut in UK greenhouse gas emissions targeted by the Government for 2010. However, the process of achieving that drop is proving problematic given the very wide range of age and condition of the UK housing stock.

Various energy conservation measures are taken in the United Kingdom.

The Energy Technologies Institute (ETI) was a public-private partnership between global energy and engineering companies and the UK Government that was established in the United Kingdom in 2007. The government set up the ETI following an announcement in the 2006 budget speech. The purpose of the ETI is to “accelerate the development, demonstration and eventual commercial deployment of a focused portfolio of energy technologies, which will increase energy efficiency, reduce greenhouse gas emissions and help achieve energy and climate change goals”. The institute works with a range of academic and commercial bodies.

The Code for Sustainable Homes was an environmental assessment method for rating and certifying the performance of new homes in United Kingdom. First introduced in 2006, it is a national standard for use in the design and construction of new homes with a view to encouraging continuous improvement in sustainable home building. In 2015 the Government in England withdrew it, consolidating some standards into Building Regulations.

<span class="mw-page-title-main">Low-carbon economy</span> Economy based on energy sources with low levels of greenhouse gas emissions

A low-carbon economy (LCE) or decarbonised economy is an economy based on energy sources that produce low levels of greenhouse gas (GHG) emissions. GHG emissions due to human activity are the dominant cause of observed climate change since the mid-20th century. Continued emission of greenhouse gases will cause long-lasting changes around the world, increasing the likelihood of severe, pervasive, and irreversible effects for people and ecosystems. Shifting to a low-carbon economy on a global scale could bring substantial benefits both for developed and developing countries. Many countries around the world are designing and implementing low-emission development strategies (LEDS). These strategies seek to achieve social, economic, and environmental development goals while reducing long-term greenhouse gas emissions and increasing resilience to the effects of climate change.

The 2000-watt society is an environmental vision, first introduced in 1998 by the Swiss Federal Institute of Technology in Zürich, which pictures the average First World citizen reducing their overall average primary energy usage rate to no more than 2,000 watts by the year 2050, without lowering their standard of living.

<span class="mw-page-title-main">Efficient energy use</span> Energy efficiency

Efficient energy use, sometimes simply called energy efficiency, is the process of reducing the amount of energy required to provide products and services. For example, insulating a building allows it to use less heating and cooling energy to achieve and maintain a thermal comfort. Installing light-emitting diode bulbs, fluorescent lighting, or natural skylight windows reduces the amount of energy required to attain the same level of illumination compared to using traditional incandescent light bulbs. Improvements in energy efficiency are generally achieved by adopting a more efficient technology or production process or by application of commonly accepted methods to reduce energy losses.

<span class="mw-page-title-main">Allan Jones (engineer)</span> British mechanical engineer

Allan Jones MBE, is an engineer who pioneered Combined Heat and Power (CHP), renewable energy and fuel cell systems in the United Kingdom and Australia from 1990 to the present.

<span class="mw-page-title-main">Green retrofit</span> Climate-smart building renovations

A green retrofit is any refurbishment of an existing building that aims to reduce the carbon emissions and environmental impact of the building. This can include improving the energy efficiency of the HVAC and other mechanical systems, increasing the quality of insulation in the building envelope, implementing sustainable energy generation, and aiming to improve occupant comfort and health.

A Deep energy retrofit can be broadly categorized as an energy conservation measure in an existing building also leading to an overall improvement in the building performance. While there is no exact definition for a deep energy retrofit, it can be defined as a whole-building analysis and construction process, that aims at achieving on-site energy use minimization in a building by 50% or more compared to the baseline energy use making use of existing technologies, materials and construction practices. Such a retrofit reaps multifold benefits beyond energy cost savings, unlike conventional energy retrofit. It may also involve remodeling the building to achieve a harmony in energy, indoor air quality, durability, and thermal comfort. An integrated project delivery method is recommended for a deep energy retrofit project. An over-time approach in a deep energy retrofitting project provides a solution to the large upfront costs problem in all-at-once execution of the project.

DERs are projects that create new, valuable assets from existing residences, by bringing homes into alignment with the expectations of the 21st century

The United Kingdom is committed to legally binding greenhouse gas emissions reduction targets of 34% by 2020 and 80% by 2050, compared to 1990 levels, as set out in the Climate Change Act 2008. Decarbonisation of electricity generation will form a major part of this reduction and is essential before other sectors of the economy can be successfully decarbonised.

Sustainable refurbishment describes working on existing buildings to improve their environmental performance using sustainable methods and materials. A refurbishment or retrofit is defined as: “any work to a building over and above maintenance to change its capacity, function or performance’ in other words, any intervention to adjust, reuse, or upgrade a building to suit new conditions or requirements” [7]. Refurbishment can be done to a part of a building, an entire building, or a campus [5]. Sustainable refurbishment takes this a step further to modify the existing building to perform better in terms of its environmental impact and its occupants' environment.

References

  1. "Technology Strategy Board - stimulating UK innovation - innovateuk". Archived from the original on 8 February 2014. Retrieved 27 January 2014.
  2. "Contractor License Bond Pros - General Liability Insurance and Surety Bonds". Contractor License Bond Pros - General Liability Insurance and Surety Bonds.
  3. Ll, AECB PO Box 32. "Less is More : Energy Security after Oil".
  4. "The Fourth Carbon Budget Review - part 2: the cost effective path to the 2050 target".
  5. Extract from Foreword by Prof. Robert Lowe Deputy Director and Prof. Tadj Oreszczyn, Director Energy Institute, UCL