Waste management suppliers and experts need to foster a collaborative approach to find solutions to the challenges that confront governments and municipalities
Imagine your rubbish bin telling the municipal authorities when it is full and needs to be collected, and municipal waste collection operations being able to optimise their fleet’s fuel consumption according to this data, thanks to predefined schedules. This is not a far-fetched scenario thanks to the Internet of Things (IoT).
In the future, smart African cities will be able to achieve zero waste, improve services to citizens and reduce municipalities’ operational costs thanks to smarter, more efficient waste collection systems.
“The global technology revolution is transforming how we think about waste management,” says Aurecon’s Nick Mannie, client manager: government RSA. “The influx of people to the extended urban areas of poverty surrounding African cities and the [increased] consumption of products are only some of the things that are fuelling waste generation across the continent.”
With higher population growth rates and increasing consumer demands and consumption, a new connected approach is required. Global shaping of technology means that waste management practices and systems can be enhanced for government, service providers and consumers. A crucial part of this revolution is making sure that poor and developing countries also tap into the changes and trends in technology that are emerging in the waste management industry, as the population growth in developing countries — and in Africa specifically — is the largest in the world.
“The IoT can help us provide integrated, timeous and sustainable solutions. We’re moving towards creating a circular economy for waste management with the help of technology, which includes a cradle-to-cradle approach (modelling human industry on nature’s processes) as well as relooking at how we can reuse and recycle products, components and materials to reduce the use of natural resources,” says Mannie.
What a smart waste management strategy may look like in the future
Smart cities of the future will integrate technology, connectivity and communication to share data that can help with several waste management processes, such as optimising the routes that garbage disposal vehicles follow for waste collection and removal, together with automating operations through sensors on garbage bins signalling that collection is needed when the bins are full.
“The data that this automated process generates can transmit information in real time to a control centre to guide the driver on routes to take, collection points, bins to uplift, traffic situations, estimated time for collection, and provide analytical information on this process to determine the cost of waste collection per kilometre. After the bins are collected, then information on the waste types can be analysed to determine, for example, which bins need to go to recycling centres or to disposal sites. The information can be used to inform clients and provide clients with invoicing information simultaneously via the cloud. This is already happening on small scales in other parts of the world and it’s time for African countries to follow suit,” explains Mannie.
The challenge of more waste and new types of waste
Another challenge that waste management will face in the future includes the new waste streams that will be created as a result of a rise in GDP, increased connectivity and the use of electronic products and nanotechnologies. Not only is our population growing, but the evolution of digital technology means that our waste management strategies must change.
“We will need to start thinking about new waste treatment technologies and facilities, and we will need to arrange capital investment for this. Current landfills in Africa will not be able to accommodate these waste streams. It’s important to note that we won’t experience a leapfrog situation, as it will be impossible for municipalities to go from current landfilling situations to smart technologies too quickly. Proper assessment and evaluation of current landfills are needed, with step-by-step strategies on how we can move to smarter, sustainable waste management strategies for each situation,” says Mannie.
What’s being done globally?
Globally, the smart waste collection technology industry is still in its infancy, but the update of IoT-enabled sensors and smart bins are already gaining traction. The market is expected to grow from $57.6-million in 2016 to over $223-million in 2025, according to US market research company Navigant Research. Municipalities and city leaders are increasingly looking at ways to use smart city infrastructure to monitor operations and automate various processes such as traffic systems, street lighting and public safety. Waste collection is just one of the many opportunities that can be explored in greater depth on our continent.
In Helsinki, Finland, the world’s first robotic waste sorting plant is being piloted and tested. The robots can detect recyclables among the other rubbish. In Sharjah in the United Arab Emirates, 10 solar-powered rubbish bins with built-in Wi-Fi technology have been installed across the city.
Alternative waste treatment options
These are some of the alternative waste treatment options being utilised in the developed world that might be useful in Africa:
Mechanical biological treatment: this combines both mechanical and biological treatment methods and will be supported by a combination of pre-treatment sorting techniques as well as a selection of emission and quality control techniques.
Anaerobic digestion: the decomposition of organic waste in the absence of oxygen.
Incineration: the mass burning of waste to reduce its volume and enable the production of energy from heat.
In-vessel composting: a way of accelerating the composting process with an enclosed environment.
Open-windrow composting: Composting is the simplest form of biological treatment and is suitable for the treatment of some source-segregated biological or organic/putrescible waste streams. Windrows are long rows that the compost is arranged in; it is usually turned to improve porosity.
Clean material recovery facility: A clean material recycling facility is suitable for the processing of dry mixed recyclables that are separated at source.
Landfill gas to energy: Landfilling is the mass disposal of waste to land under controlled circumstances. Energy can be recovered from the waste through collection of gases resulting from natural decomposition of the waste.
Dirty material recovery facility: A dirty material recycling facility involves separating valuable materials from a mixed “dirty” waste stream.
Gasification: A thermal treatment wherein pre-treated waste is exposed to very high temperatures in an environment with little oxygen.
Pyrolysis: The thermal degradation of a substance at high temperatures in the absence of oxygen.
Plasma gasification: A variation on gasification which uses a plasma torch/arc to produce gas.
Mechanical heat treatment: A mechanical sorting combined with a thermal heat treatment processing.
Waste management suppliers and experts need to foster a collaborative approach to find solutions to the challenges that confront governments and municipalities.
“Government faces technical, financial, institutional and social restrictions that aren’t easy to overcome when considering the future of waste management. Raising awareness of the looming threats and developing finance schemes are some of the steps we need to take to move progress in the right direction,” concludes Mannie.