CMS80002 Institutional Affiliation: Sustainable Home Report

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This report, focusing on environmental sustainability in construction, analyzes the development of sustainable homes with net-zero energy. It examines the importance of adhering to sustainable construction strategies, especially in the face of increasing populations and housing demands. The report delves into low/zero-carbon design technologies, including the selection of sustainable construction materials and innovative construction processes. It also discusses the management of operative energy consumption, the choice of renewable energy systems, and the importance of recycling and reuse in construction. The paper emphasizes the need for a holistic approach that considers the entire lifecycle of a building, from design and construction to operation and demolition, to minimize environmental impact and promote resource efficiency. The report highlights the role of legislation and strategic planning in achieving carbon emission reduction targets, as well as the integration of renewable energy sources and efficient energy management practices. The conclusion emphasizes the use of environmentally friendly products, low-energy construction techniques, and the reduction of CO2 emissions during construction processes.

CMS80002
INSTITUTIONAL AFFILIATION
ENVIRONMENTAL SUSTAINABILITY IN CONSTRUCTION
DEVELOPMENT OF SUSTAINABLE HOME WITH NET ZERO ENERGY
STUDENT NAME
STUDENT REGISTRATION ID
DATE OF SUBMISSION

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ENVIRONMENTAL SUSTAINABILITY IN CONSTRUCTION
SUMMARY
The public and private developers need to comply with the strategies that contain policies
to ensure sustainable construction. The success of the implementation of the strategic plan for
2050 in the United Kingdom requires technology, materials, and Building Regulations. There is a
great need to house more people as the population is constantly increasing and there is need to
manage the housing to ensure everyone gets decent housing (Halliday, 2008). The paper seeks to
analyze how the zero-carbon design technologies are implemented and the factors that could
affect its implementation.
INTRODUCTION
The domestic sector in the United Kingdom account for a large percentage of the energy
consumption (Barrett, et al, n.d.). The major energy consumers are space and water heating as
opposed to lighting and electrical appliances. Some statistics prove that the older a building is the
poorer its energy performance. When the space heating is saved, there is a significant scope for
energy efficiency improvements. The structure, construction process and the occupancy process
are deemed environmentally responsible and resource efficient in sustainable construction. The
practice is maintained throughout the building’s entire life cycle from the site location, to design,
construction, operation, maintenance, renovation, and demolition. The main aim of green
construction is to have development that satisfies the needs of the current population without
affecting the ability of future generations to meet their own needs (Abidin, 2010). Construction is
considered sustainable if it enhances living, working and leisure environment for the population,
consumes minimum energy as well as generating minimum waste over its life cycle. Such a
construction integrates with the natural environment and ensures the use of renewable resources
where possible. Green construction avoids causing permanent damage to the natural environment
by demolitions and consumption of a large amount of resources. It is rather considered
unsustainable when it causes unnecessary waste of energy, water or materials due to short life,
poor design, inefficiency or the low standard construction techniques (Ortiz, et al, 2009).
LOW/ZERO-CARBON DESIGN TECHNOLOGY
The zero or low carbon design technologies seek to introduce high standards of fabric energy
efficiency so as to reduce the energy demand and to incorporate low carbon energy technologies
to reduce the carbon emissions from heat and power generation. The projects require a huge
investment in the carbon-saving infrastructure deployment in the construction of residential and
commercial sites (John, et al, 2005).
1. Selection of low carbon construction materials
The aim of the sustainable construction is to reduce wastage and carbon emissions while
ensuring that the natural resources are maintained for the future generations. The zero carbon
design technologies implemented usually seek to reduce the need for energy as well as utilize

the available energy efficiently. Some of the non-depletable natural energy sources are used
such as the wind and solar energy. Biomass is a form of bio-energy that is obtained from the
wood fuel, energy crops or the wood waste, agricultural residues of the biological
components (Matthews, et al, 2012).
2. Innovative construction process
The designers such as the architects and the engineers are responsible for the design of a
building that optimizes the electrical, heating, and cooling loads. The construction depends
highly on the selection of specific materials to use and reduce the loads. This is achieved by
the design and utilization of free energy gains or the passive gains and the specification of
mechanical and electrical equipment and systems that satisfy the energy loads. The designs
should aim at creating a more commercially viable zero carbon home by orienting it for
maximum solar gain and renewable energy generation. The designs seek to conserve all the
resources and ensure that the structure is self-sufficient. The use of large windows on the
sides of residential buildings, plantation to cover the open lands or even on the walls of
buildings gives an ecological feel. The use of efficient water gutter system to collect rain
water for reuse in house chores. Another design approach is the installation of solar heaters
on the rooftops to conserve electricity when hot water is required (Ilha, et al, 2009).
3. Management of operative energy consumption and consumption behavior
The life cycle assessment is a very resourceful tool for assessing environmental performance
and sustainable development. One of the key ways to manage the zero carbon in sustainable
construction is to involve it in legislation. It should be stated as a mandatory target as well as
have a strategic plan to eliminate the carbon emissions to the highest level by the year 2050
in the UK and in 2030 in the USA. The international community needs to embrace the move
to ensure that the environment is protected. There are several decisions that need to be made
when considering the sustainable construction such as the increase of profit margins, green
credentials, and business opportunities (Kukudia, et al, 2004).
4. Choice of renewable energy systems
The choice of renewable energy systems is highly dependent on the construction site. The
site could be located in a region where the solar energy is abundant or where there is a lot of
wind. In the urban areas, there is a lot of waste materials that can be converted to biomass
which is another suitable form of energy especially for small energy requirements such as
heating and cooking.
5. Recycle and reuse
Many building are coming up with designs that conserve the natural resource provided. The
key concern on lighting is achieved by ensuring that the building is well lit and no electricity
is used for lighting during the day. During the night, there can be solar energy, wind energy,
or hydropower. Water is another key resource in construction and residential setups. Rain
water can be collected and used for the wash areas and toilets. The greywater can be used to
irrigate, water the open areas or even in washing cars (Ugwu, 2006).

DISCUSSION AND CONCLUSION
To reduce the carbon footprint during construction, the operational team needs to use products
that cause minimal harm to the environment. These materials need to be energy efficient in terms
of their manufacture, distribution, use and disposal. The paper broadly discusses the
environmentally friendly alternatives such as the use of low energy forms of construction as well
as being mindful of processes that could cause emission of CO2.
REFERENCE LIST
Halliday, S. Sustainable Construction; Butterworth Heinemann: London, UK, 2008.
Barrett, P.S.; Sexton, M.G.; Green, L. Integrated delivery systems for sustainable construction.
Build. Res. Inf, 27, 397–404.
Abidin, N.Z. Investigating the awareness and application of sustainable construction concept by
Malaysian developers. Habitat Int. 2010, 34, 421–426.
Ortiz, O.; Castells, F.; Sonnemann, G. Sustainability in the construction industry: A review of
recent developments based on LCA Constr. Build. Mater. 2009, 23, 28–39.
Ortiz, O.; Pasqualino, J.C.; Castells, F. Environmental performance of construction waste:
Comparing three scenarios from a case study in Catalonia, Spain. Waste Manag. 2010, 30, 646–
654.
John, G.; Clements-Croome, D.; Jeronimidis, G. Sustainable building solutions: A review of
lessons from natural world. Build. Environ. 2005, 40, 319–328.
Bainbridge, D.A. Sustainable building as appropriate technology. In Building without Borders:
Sustainable Construction for the Global Village; Kennedy, J., Ed.; New Society Publishers:
Gabriola Island, Canada, 2004; pp. 55–84.
Ugwu, O.O.; Kumaraswamy, M.M.; Wong, A.; Ng, S.T. Sustainability appraisal in infrastructure
projects (SUSAIP) Part 1. Development of indicators and computational methods. Autom.
Construct. 2006, 15, 239–251.
Matthews, E.; Amann, C.; Fischer-Kowalski, M.; Huttler, W.; Kleijn, R.; Moriguchi, Y.; Ottke,
C.; Rodenburg, E.; Rogich, D.; Schandl, H.; Schutz, H.; van der Voet, E.; Weisz, H. The Weight
of Nations: Material Outflows from Industrial Economies; World Resources Institute:
Washington, DC, USA, 2000; Available online: http://pdf.wri.org/weight_of_nations.p (accessed
on 24 May 2009) Buildings 2012, 2 148
Ilha, M.S.O.; Oliveira, L.H.; Gonçalves, O.M. Environmental assessment of residential buildings
with an emphasis on water conservation. Build. Serv. Eng. Res. Technol. 2009, 30, 15–26.
Kukadia, V.; Hall, D.J. Improving Air Quality in Urban Environments: Guidance for the
construction Industry; Building Research Establishment (BRE) Bookshop, CRC Ltd.: London,
UK, 2004.