LETTER
OF TRANSMITTAL
Dear Mr. Blackstone,
Re:
Proposal for Implementation of Food Waste Recycling Technology in SIT Punggol
This letter is prepared in response to the
call for proposals regarding an engineering issue in
Singapore to improve the recyclability of food waste. In
this proposal, the team has identified that the new campus
at SIT@Punggol, can be a test-bed for exploring the potential
combination of technologies to further reduce food waste. This report
has been prepared with the intention of implementing a food waste recycling
machine that combines technologies of converting food waste into
by-products such as reusable water and fertilizers.
The report consists of a description of the
current machines using recycling technologies, the rationale behind the
proposed solutions, an evaluation of the benefits, and a detailed summary of
all related primary and secondary research. As we aim to reduce the overall
food wastage in Singapore, using SIT Punggol as a stepping stone, we have
provided information on the integration of using these technologies and an
analysis on how this machine can further reduce the amount of food wastage
being sent for incineration.
We would like to express our gratitude to
you for taking the time to read this proposal. Your consideration of our
suggestions in improving food waste practice in our future campus so as to help
reduce food waste and conserve the environment.
Yours
sincerely,
Angela
On behalf of Econopy
Civil Engineering programme
CVE1281 Effective Communication
PERSONAL STATEMENT
Angela Hwee Sook Yee
Angela, a student from Singapore Institute
of Technology (SIT), is currently pursuing her degree in Civil Engineering. She
studied Material Science as her diploma during her polytechnic years. She sees
the importance in recycling and reusing of materials and resources essential
for conservation. This project allows her to understand the need to recycle
food waste as well to value the importance of conserving food waste. Together
with her team members, she strives to improve the current food waste issue and implement
food waste recycling into their targeted platform. Angela has contributed in
the evaluation and conclusion of the proposal.
EXECUTIVE SUMMARY
This report was written in response to call
for engineering problem-solution proposals. It focuses on the waste recycling
technologies that are currently out in the market to combat the generation of
food waste and discusses its capabilities against one another. The complication
would be the difficulty to handle a overproduction of by-products and the
productive use of them. This may result in squandering of by-products which
reduces the tendency to use these machines which defeats the purpose of
improving the recyclability of food waste.
The objective of this report is to propose
to the planning committee of SIT Punggol a more sophisticated system that
improves and combines the technologies that are offered in the market
currently. The team proposes a solution that allows the waste recycling machine
to effectively produce the amount of by-products based on the input of the
user. This will effectively provide the sufficient volume
of fertilisers and reusable water so as to reduce the potential squander
of useful products.
1.
BACKGROUND
Figure 1: Food waste percentage (Source: National
Environment Agency 2015)
This report is prepared in response to the
call for proposals regarding an engineering issue in Singapore to improve the
recyclability of food waste.
As Singapore’s population continues to
grow, the amount of food disposal has been increasing at the incineration site.
To counter the issue on the rapid growth in food disposal, this team proposed
an idea to improve the situation of food disposal efficiency. Since the
recycling rate in Singapore has increased gradually to 14% from 2006 to
2016 (NEA, 2016), our goal is to design a machine that incorporates
the current food recycling machines starting from new campus at SIT
Punggol.
Our team feels the need to encourage and
focus into recycling food waste as it has not yet been well-established enough
in the current market due to certain factors. We believe that through the
integration and improvement of existing technology can we only be able to
further recycle food waste into reusable products.
As of now, two waste recycling technologies
are being used to produce two different byproducts. Currently, in the
market, there are various machines such as Westcom, BioHitech and
Eco-Wiz that recycle food waste into either fertilisers or
reusable water. However, the organisation is required
decide to between the two technologies to implement in their
premises. Our solution is to incorporate two of these
technologies into a single machine whereby the operator will select the
preferred mode for the output of the byproducts. This way, it will generate the
flexibility of installing the machine in a variety of facilities.
Evaluating the current technologies of
recycling food wastage, would help the planning community of SIT to understand
that there are such machines in the current market. Through the
implementation of a food waste recycling machine that decompose into two
different by-products, it would increase efficiency and flexibility. Finally,
food waste can both be recycled into fertilizers and reusable water.
2.
PROBLEM STATEMENT
Canteens at SIT Punggol campus should
integrate the current technologies of recycling food waste into a single
machine to increase the efficiency to produce high quality
fertilizers/reusable water as by-products. However, amongst all
the approaches in which food waste is decomposed, there has not been an
integration of technology that incorporates producing fertilisers and
reusable water as by-products in a single machine. Incorporating both
technologies into a single system, it will benefit the new SIT
campus canteen in adapting a food waste recycling habit that makes
full use of the reusable by-products.
3.
PURPOSE STATEMENT
This report proposes to the planning
committee of SIT Punggol an integration of waste recycling technologies into
one machine that can be implemented into SIT Punggol
campus’ canteens through the analysis of both technologies that
currently exists in the market.
4.
CURRENT IMPLEMENTATION
In the last 10 years, NEA (2016) stated
that food waste has been increasing from about 500,000 tonnes to
close to 700,000 tonnes in 2016. This increment of food waste is due
to two main factors. The increase in population and commercial activity.
Efforts has been taken place to reduce food waste. Starting from the source,
food wastage efforts has been carried out in terms of posters to encourage
buying what is only needed as food wastage due to expired foods were the main
contributors to food wastage. The next effort was to redistribute excess food
to food organizations through donations to reduce the need to throw
food waste when it passes the date of expiry. The last and least recommended
effort would be to dispose waste to waste-to-energy (WTE) plants to recover
energy from waste and to reduce them down to ten percent from its
original size to be disposed into incineration plants (NEA, 2018).
Food waste machines are implemented with
the main purpose to reduce the dependency of incineration plants and landfills.
Currently, there are two different types of food disposal technology that
breaks down food waste. One of which, breaks down the food waste
into fertilisers using anaerobic digestion, where
micro-organisms breaks down food waste without the presence of oxygen.
The other technology that produces reusable water uses a
process call aerobic digestion, where food waste is broken down in the
presence of oxygen. The fertilisers that are produced can then
be used for agriculture or any green spaces and the
reusable water can then be used for watering plants or cleaning of
premises.
4.1
WASTE TO FERTILISER RECYCLING
TECHNOLOGY
Figure 2: Food Waste Recycling Machine (Westcom)
Illustration 1: Mechanism of Food Waste into Fertilizers
According
to BioHiTech video entitled “The Science of Digestion” (2015),
these machines operate through the breakdown of food waste by micro-organism in
the system. As waste is introduced into the system, micro-organisms start to
feed and break down on food particles, ultimately reducing its size.
In this machine, rotating shafts would
mix the bio media (which houses micro-organism) as well as the food waste to
ensure homogeneous mix of materials. There is a heating
element that provides a warm condition for micro-organism
to thrive. Fertilisers are produced
as by-products through anaerobic conditions. As the chamber is
closed and sealed off, waste will first get its
water vapour evaporated off through an exhaust. According
to Ecoman FOODIE video entailed “How FOODIE works? Waste
decomposing process!” (2014), waste is then reduced by 70
percent. Ecoman FOODIE further stated that Micro-organisms will
further reduce the volume of the waste to 10 percent of its original volume,
turning it into useful fertiliser compost which can be used on
spaces.
4.2
WASTE TO LIQUID RECYCLING TECHNOLOGY
Figure 3: Ecodigester (Eco-Wiz)
Illustration 2: Mechanism of Food Waste into
Reusable Water
To produce waste water as a by-product, micro-organisms
need an aerobic condition and hence, air is introduced through inlets
(BioHiTech entitled “The Science of Digestion,” 2015). Food
waste are then broken down till it would be small enough to pass
through digester screens. According to Joe Liu video entailed
“Eco-Wiz Coporate Video,” (2016), a 2-step filtration system will then be used to remove grease
and certain microbials which may cause diseases or fermentation before it is
passed off as reusable water.
Similar to the technology mentioned
previously, rotating shafts would mix the bio media as well as the food waste
to ensure homogeneous mix of materials. However, there is a heater present to
evaporate the water content in food waste. Then, the leftover sludge produced
will pass through filter screens such as a grease filter and a microbial
treatment. This reusable water that can then be used around the school
premises.
5.
PROPOSED SOLUTION
Clients would often face
difficulty in deciding which machine works best on their specific environment they
are in due to the variance of by-products produced.
Most commercial companies prefer the food waste machine to produce reusable
water as they do not have green spaces and would prefer a full reduction of waste
to ultimately reduce manpower. Educational, eco-friendly parties may choose a
food waste machine to produce fertilizers as the compost produced would save
the company money. The compost can be applied on most soil media and hence its
versatility encourages more interested parties to use the product.
Combining the two respective
technologies together into a machine, increases the efficiency of
food waste recycling. With the
flexibility of functions in the
system, it allows the user to have the ability to
select the amount of fertiliser or reusable water produced from the
food waste. Loading the waste into the respective input of the machine,
fertilizer or liquid. Estimated time for food waste digestion will be
show on the digital panel of the machine. Overtime, the by-products will
be churned into bits and fine particles. The breaking own
of by-products will be ready after 24 hours. Leaving
it untouched for a prolonged time, the system will
be “smart” to shut down itself. This is to greatly save the
electricity cost from the power supply.
6.
METHODOLOGY
Before implementing a new type of
technology, our team had to fully understand the current efforts Singapore
is practicing tackling food waste. Our team decided to focus on the
food waste treatment system that organisations around the nation may
have adopted and further narrow down to the various technologies.
6.1
PRIMARY RESEARCH
Apart from conducting
research to determine the different types of waste recycling methods there are
available, Dr. Ng, who has a major in civil engineering and a PH.D. in water
microbiology studies. He agreed that having a waste recycling system that
produces fertilizers not only helps in reducing overall food waste
but justifies that the compost would be able to be stored and used for a later
date, increasing the flexibility in using the output. Moreover, the team
emailed the two main companies, ECOwiz and Westcom
Solutions, to acquire about the
prices and products. In addition to that, we conducted a survey
to review on the need of recycling food waste and
the importance to implement a technology that will be able
to satisfy the users need.
6.2 SECONDARY RESEARCH
Based on our observations, a food waste
treatment system under Westcom Solution is placed at the back of our school’s
canteen. The system converts the food waste to soil fertilizer. Our
team further researched on possible by-products that may be produced by the
treatment systems supplied by the other suppliers. According to Eco-wiz, one of
the suppliers, its webpage mentioned that its product, ecoDigester, could
convert solid food waste to reusable water. After further discussion among our
team, we conclude that these fertilizers and reusable water could be
used around the school premises itself.
7.
BENEFITS
These are the benefits that this
dual system can operate to increase the food waste recycling efficiency.
7.1 VERSATILITY
The main benefit for implementing the dual
digestion system is to fully expand the possibilities and further enhance the
versatility of the machine. Selecting the amount of by-products
needed, would further prompt the user to utilise the
machine and prevent an overproduction of by-products which may be
thrown due to its lack of use.
7.2 COST OF MANPOWER
These machines will also encourage savings
in the long run. According to Violia (2016), the cost of disposing a
large waste bin that is between 660 to 1100 kg, which carries a maximum
capacity of about 440 kg is $720.82. This would in turn provide savings of
$8,649.84 a year. Working out the initial costs of the machine, the turnover of
the cost of the machine will take roughly 4 years.
7.3 GOAL IN RECYCLING
The goal towards
recycling food is being taken place as
users can make use of this machine and collect
the by-products that they needed to. Moreover, this
practice will further prompt users to use this machine whenever they needed
to. This increases the percentage of food waste recycling at SIT Punggol
as a starting platform.
8.
EVALUATION
However, with potential benefits, there
ought to be challenges as well. Our team has evaluated the possible
challenges that can happen and making sure that they would not
overweigh the benefits.
8.1 MAINTENANCE
With the incorporation of both technologies,
there is a high maintenance to operate the system's
quality and functionality. To countermeasure this challenge, frequent
routine checks must be implemented to make sure the machine
faces no defects and difficulties. Therefore, proper instructions must be placed
near the machine to properly educate users on the operation
8.2 COST OF MACHINE
The estimated average cost of this system
is S$30,000 to S$50,000. Although this is very
costly, comparing with the cost in
manpower that was calculated within a year, this challenge
can be overlooked as it is only a one-time payment.
8.3 RESOURCE
As this machine relies vastly on
the usage of micro-organisms, there is a need to refill after the
product finishes in the machine. Additionally, the refill will depend
on how frequent the machine will be used during the months.
9.
CONCLUSION
In conclusion, our team proposes to
implement a technology which integrates two different types of technology that
produces soil fertilizers and reusable water into a single system or
machine. Having two different form of
by-products, reassures the school that there will not be an
overproduction of a certain type of by-product. These by-products can be
used around the school’s premises. For example, the
soil fertilisers can be used any agriculture around the vicinity and
the reusable water can be used to wash the canteen floors or toilets. Based on
our team’s research, this machine will have an estimated cost
of S$30,000 to S$50,000. This may be a huge sum; however, statistics have
shown that the cost saved from food
waste recycling will compensate for the estimated cost of the
proposed system.
We wish to implement this system
into SIT@Punggol university campus canteens as a test-bed for
innovation that improves overall food waste recycling in Singapore. Our team
sees the viable opportunity to create possibilities of reducing food waste
through the new Punggol campus.
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