Draft
2 technical writing report:
This
report responds to a call for proposal to recommend an engineering solution to
a specific problem in the built environment sector.
Cement
is inarguably the most used and crucial construction resource since civilizations
came into existence and more buildings that are bigger and taller will
inevitably be constructed in the future. Rodger (2018) states that most of our
concrete in the world is being used to construct buildings and that the main
ingredient of concrete is cement, whose production contributes to 8% of the
world’s carbon emissions, which is equivalent to 2.2 billion tons of carbon
dioxide per year.
According
to Climate & Clean Air Coalition (CCAC,n.d), the process of producing
bricks in kilns releases large amounts of pollutants such as sulphur dioxide
and black carbon into the atmosphere. These effects are not easily reversed and
will accumulate in the earth’s atmosphere much to the suffering of future
generations.
The
Intergovernmental Panel on Climate Change (IPCC) mentioned in their special
report that it is essential to maintain global temperature within 1.5 degree
celsius . A one-degree increment of global temperature can result in a drastic
increase of the atmospheric temperature.
Based
on National Oceanic and Atmospheric Administration (NOAA), the global
temperature in September 2009 was 0.62 degree celsius. Currently, the global
temperature is at 0.95 degree celsius. Despite it being under 1.5 degrees,
there was a 0.32 degree increase of global temperature within a decade.
Dr
Koh Poh Koon, Senior Minister of State for Trade and Industry, mentioned that
Singapore generated 52.5 million tonnes of greenhouse gases in 2017 which
contributed 0.11% of global emissions, that equates to 8,000 tonnes of CO2 per
capita in that year (Tan, 2019). According to Dr Muhammad Eeqmal Hassim, senior
research scientist with the MSS Centre for Climate Research Singapore (as cited
from Channel News Asia), with the rise of carbon emission, it will lead to an
increase of Singapore’s daily temperature from 35 to 37 degrees celsius.
The
most direct way Bricknology can contribute to the reduction of climate change
is through convincing BCA to adopt the idea of using mycelium bricks in Yio Chu
Kang private housing estate as a pilot programme. By implementing the use of
mycelium bricks as a pilot programme in Yio Chu Kang private housing estate,
the team hopes that Singapore could set an example to the world that mycelium
bricks can help in reducing the overall global greenhouse gas emissions
problem.
1.1
Current practices for Yio Chu Kang private housing
The
team had observed that the bricks used to build the internal structure of the
house in Yio Chu Kang private housing were made up of clay and concrete.
Clay
bricks
1.2
Problem Statement
Building
Construction Authority (BCA) to authorized the use of mycelium brick for all
future construction. However, BCA is not implementing the use of mycelium
bricks despite its potential.
1.3
Purpose Statement
The
purpose of this report is to convince Building & Construction Authority to
adopt the idea of using mycelium bricks and initiate a pilot project in Yio Chu
Kang private housing estate.
2.
Proposed Solution
The
team has referenced online research done for sustainable bricks and have decided
to propose a solution for BCA to consider:
2.1
Use mycelium bricks in place of conventional bricks
The
team conducted interviews with the construction supervisors and workers in Yio
Chu Kang private housing during a site visit. The team was told and observed
that bricks used in Yio Chu Kang private estate houses to build internal walls
were mainly by concrete and clay bricks.
The
production of making these bricks involve heating the bricks to high
temperatures which produces a high amount of CO2 as a by-product. It is
also noteworthy that the production of concrete and clay bricks produces a
ratio of 1 tonne of bricks to about 250kg of CO2 (Rathi, 2017).
Mycelium
bricks reduces the carbon emission of producing the same number of concrete or
clay bricks by a large margin.
3.
Advantages of mycelium bricks
3.1
Good physical capabilities
Mycelium
bricks is fifty six times per cubic meter lighter than your typical
conventional bricks. It is capable to withstand a high amount of compression force.In one such experiment,
the results are a mycelium brick that is 200,000 times more ductile than steel,
10,000 more rigid than brick while still able to support the weight of 50 cars
(Abrams, 2014)
As proven from architectural
structures, it is able to withstand external factors such as wind and rain.
3.2
Fire resistance
Although
mycelium does take a shorter time to ignite in comparison with clay and
concrete, the beauty about mycelium bricks is that the moment the outer layer
is burnt, a layer of char forms on the surface of the mycelium which actually
increases the flame resistance of the entire brick itself. This results in the
bricks actually being able to last longer in prolonged fires, maintaining its
structural integrity long enough so that the building does not collapse under
its own weight., leaving room for people to escape.
3.3
Good thermal insulation
Mycelium
insulation has way better R-value and EPS R- value as compared to conventional
insulation boards.It does not absorb heat as fast as the conventional boards.
It is also thinner and lighter which makes it easier for construction process.
3.4
Environmental effects
Mycelium
are 100% biodegradable and they can be found in abundance on the planet. It
does not release any volatile organic compounds. As it is made up of fungi,
people will get the misconception that overtime it will turn rotten and start
releasing foul smell and release harmful gases. Thus it will not release any
external harmful effects.
3.5
Resources and production
The
production of mycelium does not cost much as it uses bio-based materials and is
biologically grown. Even pieces of agricultural waste materials and
natural bio materials can be used to make mycelium bricks. It does not rely on
factories for producing mycelium bricks unlike conventional bricks. Thus hugely
reducing the use of artificial energy and the amount of CO2s to produce
mycelium.
4.
Disadvantages of mycelium bricks
4.1
Weak compressive strength
Mycelium
bricks can only withstand 30 psi whereas a concrete block can withstand 4000
psi to 10,000 psi. Mycelium bricks can not support as much weight as compared
to a normal concrete block.
4.2
Production
As
components of mycelium takes time to grow, it might take a few days to weeks to
be able to use it as a component to make the bricks. External factors such as
temperature and moisture might delay the growth of the components of mycelium.
4.3
Long term
As
mycelium bricks is very new to the line of production. It does not have much
credibility on how long it is able to last in residential and non residential
buildings. It might be the solution to replacing all conventional bricks but
who knows in fifty years in might crumble due to some problems. No matter how
much research and claims from experts that says it will last, it will only
remain as projections. The only thing we are able to fully trust is to wait
until it reaches its maximum brick lifespan.
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