Sustainable Urban Development

We guarantee an original paper free from Plagiarism.

Order a Similar Paper Order Different Paper

We got you covered for the whole semester.


Table of Contents

Write about Sustainable Urban Development.



Retrofitting is crucial for reducing energy consumption.

Retrofitting has been an overlooked benefit, and people continue to suffer losses from the higher cost.

Retrofitting is becoming more popular in Sydney as people are trying to make a difference and improve their lives.

Particularly, UTS is the most important area of concern.

Retrofitting green roofing is essential. This involves taking care of many issues that can add to the cost of the institution.

Retrofitting energy efficient lighting is essential to address the rising cost of campus lighting. In the end, this has resulted in higher school fees.

Effective lighting can reduce all lighting costs.

It is vital that the institution recycles building garbage to increase cost savings.

In addition, when the state’s water supply is in danger during the summer, waste water recycling may be more useful to help foresee greater accomplishments.

But, a detailed analysis of retrofitting green roofs or energy efficient lights to urban areas will reveal more information about sustainable urban development.

Green Roofing

Green roofing is essential for the protection of the environment and its inhabitants.

The installation of grass or other green plants on the roof is one way to achieve green roofing. (William and al., 2016, 4).

Green roofing has also been used in other cases such as when the roofs are painted with green paints.

However, experts and researchers were not happy with this approach. This led to the creation of a single type of green roof: growing plants.

This roof acts as a cushion to absorb heat and reduces heating.

Green roofing is a necessity at the University of technology Sydney due to the rising challenges.

First, there are only a few doors in the building, which makes it hard for staff and students to use. (Mitchell and Ross 2016, 49).

The problem cannot be solved by buying expensive doors. It can only be solved by using the natural plantations in the surrounding environment.

The doors are now installed at a fraction of the cost.

The campus has been looking at ways to increase the cooling units for the buildings from levels one to six (Wilkinson, Castiglia 2016/16).

The sophisticated equipment required to cool cooling systems can be very costly to install and manage.

Research has revealed that nearly every room in a home has cooling systems.

It is also possible to reduce the cost of cooling equipment by having a green roof.

Green roofing continues to attract attention because it reduces cooling.

Heating is usually required to warm rooms in winter.

This is the time when students, lecturers, as well as other staff members, tend to wear heavy clothes.

This could be replaced by the use of additional heating devices that can provide enough warmth for the people to carry out their daily duties.

The complicated process of involving heating equipments can cause campus to suffer unnecessary and large losses (Hawken (2015), 54).

It is because I needed to use a lot power to propel the machines.

The green roofing prevents heavy metals from rainwater.

Research has shown that acid rain can be caused by air pollution.

This can lead to the corrosion of roofs, and walls.

The acid rain can cause roofing to become corroded, and this causes rust that allows for the cooling of the rooms.

The green roof acts like a heat absorber and helps to provide heat throughout the day.

Energy-efficient Lighting

Retrofitting energy efficient lighting is another area of concern.

The UTS has a reputation for being an enabling lighting system. It determines how learning, research and other activities will be conducted.

Retrofitting the efficient lights involves all lighting materials necessary to supply sufficient light to the rooms.

Since long, the University of Technology in Sydney has used bulbs for lighting (Wilkinson, Feitosa (2015), 1082).

In fact, there has been an increase in lighting in rooms which has significantly impacted the institution’s expenses.

It is clear that lighting can be improved using cost-friendly strategies while still providing enough light to the buildings.

The UTS four level is the main room with efficient lighting. It is made possible by the addition of the atrium (Wilkinson Ghosh and Lindsay 2014, 15).

Other rooms are darkened by low-quality lighting.

You can reduce your costs by installing energy saving bulbs.

To ensure electricity is not being used during class time, it is important to install more atriums.

The installation of light sensors in rooms will improve the energy efficiency. This will allow it to be detected when lighting is most necessary.

This will ensure that the building is lit only when it is necessary.

Light emissive windows are a great way to save electricity.

It is important to use light controls so that the only rooms being lit should be those that are used. (Wilkinson 2014, 68).

The translucent lights emissive windows are another option that can be used to provide sufficient lighting to allow for proper cooking.

The reason is that most of the processes used in cooking and heating water depend on electrical energy. This can lead to high electricity bills.

Long-term goal

Installing a green roof is a long-term goal. It aims to have such roofing on all levels of the UTS building.

The process of installing green roofing is procedural. It is the outcome of all short term goals (Mitchell, Ross 2016,47).

This will help to lower costs while reaping the benefits.

To make it possible for green roof tomination, the cooling and heating equipment should be removed.

To ensure maximum profit, all cooling and heating equipment should be completely sold (Wilkinson Ghosh and Page 2013, 110).

This will save the power that these machines use.

It will also be a way to pay for all the costs associated with installing the green roof.

Retrofitting UTS buildings with an efficient lighting system is part of the long-term strategy. It will be the time that renovations are likely to complete.

The entire UTS building must be re-roofed with translucent roofing (Sankaran Abeysuriya Gray, Kachenko, 2015 333).

Dark sensing tools that can detect light should be installed throughout the building in order to prevent it from being lit during daylight hours.

The building could also be made translucent by removing the walls and replacing them in the future with light emissive glasses.

To reduce costs even at night, energy saving lighting will be used throughout the building.

Short Term Goal

In order to retrofit the green roofing strategy, the UTS building six-level one must be reduced. This will allow for the implementation of the plan for the section.

However, not all roofs are suitable for green living plants (Wilkinson. et al. 2014).

This means that the plan requires specific roofs to support it.

Because of this, the plan cannot be implemented to impact the entire UTS building.

Costs are a major concern as it is costly to invest in a plan which is not financially viable.

If you invest in the green roofing plan short-term, there will be test results to show whether or not it can be expanded to the next level (Panahian Ghosh, Ding, 2017, 168).

It is important to eliminate cooling machines from level one in order to determine if the green roof can provide a reliable cooling environment.

It is worth noting that three cooling machines are required for a level. Only one is removed, and the cost-benefit analysis is done.

As time passes, the remaining coolants are removed and cooling responsibility transferred to green roofs. (Wlkinson.Stoller. Ralph. Hamdorf, 2016,78).

If the plan proves to be worthwhile, the implementation of the plan proceeds to level 2 and the trend continues.

The invention can also include heating the room in winter with green roofing.

Green roofing can be used in winter, provided that the test results are set at level 1.

Because it acts as an absorber of heat, heating equipment should also be evaluated in the level one.

You can accomplish the short-term goal by turning off the lights in all rooms that are not being used.

This is crucial for determining the savings that are achieved from the plan.

Although it doesn’t make sense to light empty rooms, electricity bills continue to rise (Abeysuriya Fam, Mitchell, 2013, 2188).

A light emissive window and door can be used to enhance a short term plan.

This plan can’t be assumed to have been implemented quickly. These materials aren’t expensive but must be used in smaller parts.

Installing translucent roofs is a great way to retrofit.

All of the above-mentioned materials, including light emissive windows, doors, and roofs, are fixed so that daylight in the occupied rooms is decreased during the day. This reduces the possibility of wasting energy and reducing expenses.

Another way to achieve the short term goal is by using this perspective.

This can be achieved by using energy-saving lighting.

This is dependent on the bulb being used and its energy saving abilities.

Some bulbs can be used to light the room, while also emitting heat (McLellanet and al. 2015, 140).

It is therefore important to include a short-term plan. Compare it with the functionality and heat providing machines and the green roof.

It is important to prioritize which option is most cost-effective.


Based on the $15/kwh price projection, we assume that 50 million people used electricity from 2014 to 2016.


It is expected that retrofitting the building will save 70% on annual costs.



The details of the possible retrofit of the UTS building, and its levels, have been effectively highlighted.

It is clear that energy consumption can cause an increase in school fees.

In addition, productivity is affected when the costs outweigh the savings.

UTS is in a better place to ensure that it utilizes all retrofitting methods. This will allow for continued savings and encourage other development strategies.

In addition to the savings, long-term planning will enhance the building’s aesthetics in terms of glassed walls and green roof.

UTS will help to realize its visions by carrying out retrofitting activities.


Abeysuriya K. Fam D. and Mitchell C.

Trialling urine diversion for Australia: technical and sociological learnings.

Water Science and Technology 68 (10), pp. 2186-2194.

The new Chinatown: Sydney’s Southern CBD.

Landscape Architecture Australia, (146), page 54.54-55

McLellan B., Florin N.., Giurco D. Giurco T., Kishita Y. Itaoka K., and Tezuka T.

Decentralised energy futures: The changing emissions reduction landscape.

Procedia CIRP 29: pp.138 – 143.

Mitchell, C., and Ross, K. (2016).

Findings and Recommendations.


Mitchell, C. and Ross K., 2016.

Governance of local sanitation: How do you design governance for long-lasting service?


Panahian M.Ghosh S. and Ding G. 2017.

Assessment of carbon emission reduction potential in a multi-unit residential building in Sydney.166-170

Sankaran S.; Abeysuriya K.; Gray J. and Kachenko A., 2015.

Mellow yellow: A systems-thinking approach to research on sustainable sewage management.

Systems Research and Behavioral Science. 32(3). pp. 331-343.

Wilkinson S. and Feitosa R.C. 2015

Retrofitting homes with lightweight green roof technology.

Wilkinson S.Ghosh S. and Lindsay P. (2014).

Urban food production in Sydney CBD rooftops.

Urban food production on Sydney CBD rooftops.13-17

Wilkinson S.; Lamond J.; Proverbs D.G. Sharman L.; Heller A. and Manion J., 2015.

Technical considerations for green roof retrofits for stormwater attenuation within the Central Business District.

Structural Survey. 33(1). pp. 36-51.

Castiglia Feitosa (R.), November 2016.

Assessment of the thermal performance and retrofitted lightweight green roofing and walls in Sydney, Rio de Janeiro.

SBE16 International High Performance Built Environments Conference.14-22

Transformation of the commercial property market with green roof retrofit and subleases for urban agriculture production.

In Re-engineering The City: Transitions To Urban Sustainability 2020-2050 Conference.

Wilkinson S.J.Ghosh, S., and Page L. (2013). September.

Options for green roof retrofits and urban food production within the Sydney CBD.

Proceedings of RICS COBRA Conference. New Delhi, India (Vol.

Wilkinson S.J. Osmond P. Heller A. Heller A. Manion J. Sumich M. Sharman L., 2014 June

The green roofs of Sydney are being promoted to the community.

ZEMCH International Conference 2014.

ZEMCH Network.38-41

William, R. Goodwell A., Richardson M., Richardson M.V., Kumar P. and Stillwell A.S. 2016,

A cost-benefit and environmental analysis of green roofing options.

Ecological Engineering, 95. pp. 1-9.

Wlkinson S., Stoller P., Ralph P. and Hamdorf B., 2016.

Feasibility for Algae Building Technology at Sydney.

Feasibility for Algae Building Technology to be used in Sydney.74–87

Hello, this question is here because we've worked on this and other similar assignments. If you don't know the answer, you can ask us for help. We guarantee an original paper free from Plagiarism.

Order a Similar Paper Order Different Paper

You can trust us with any of your assignments. We got you covered for the whole semester. We dedicate one writer to do all your assignments