Decentralized utilization of wasted organic material in urban areas: A case study in Hong Kong

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Decentralized utilization of wasted organic material in urban areas: A case study in Hong Kong. / Pleissner, Daniel.
In: Ecological Engineering, Vol. 86, 01.01.2016, p. 120-125.

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@article{2e69341f1632486592ad4ae1292ca5a1,
title = "Decentralized utilization of wasted organic material in urban areas: A case study in Hong Kong",
abstract = "Urban areas, characterized as areas with a high population density, generate large amounts of liquid and solid waste streams. Without proper treatment, these waste streams accumulate in the environment of urban areas and may lead to serious environmental problems. Contrarily, waste streams and particularly wasted organic materials contain valuable compounds, which can be biologically and/or chemically converted into products to cover the economic needs of urban areas. In this study, a concept is presented that contributes to treatment and utilization of wasted organic material in a way to (1) avoid environmental problems, (2) exploit its potential and (3) establish a recycling. In this context, technical aspects, such as hydrolysis, waste reduction, integration in urban structures and recycling of wasted organic matter, were discussed. An example of waste utilization is given based on the organic waste stream generated by a common building in Hong Kong with 640 residents. The 640 residents would generate more than 250 kg of wet organic waste per day, which can be biologically hydrolyzed using decentralized processes on site. The hydrolysis of 250 kg wet organic waste would result in the production of 33 kg glucose, 15 kg lipids, 0.6 kg free amino nitrogen and 0.2 kg phosphate, which can be used as nutrients in biotechnological processes or feedstocks in chemical reactions for the production of food, feed, chemicals and materials. Recycling of organic matter is not only a sustainable waste treatment, but contributes to the economy and self-sufficiency of urban areas in resource supply.",
keywords = "Organic waste reduction, Organic waste recycling, Decentralized process, Urban areas, Sustainability, Chemistry",
author = "Daniel Pleissner",
year = "2016",
month = jan,
day = "1",
doi = "10.1016/j.ecoleng.2015.11.021",
language = "English",
volume = "86",
pages = "120--125",
journal = "Ecological Engineering",
issn = "0925-8574",
publisher = "Elsevier B.V.",

}

RIS

TY - JOUR

T1 - Decentralized utilization of wasted organic material in urban areas

T2 - A case study in Hong Kong

AU - Pleissner, Daniel

PY - 2016/1/1

Y1 - 2016/1/1

N2 - Urban areas, characterized as areas with a high population density, generate large amounts of liquid and solid waste streams. Without proper treatment, these waste streams accumulate in the environment of urban areas and may lead to serious environmental problems. Contrarily, waste streams and particularly wasted organic materials contain valuable compounds, which can be biologically and/or chemically converted into products to cover the economic needs of urban areas. In this study, a concept is presented that contributes to treatment and utilization of wasted organic material in a way to (1) avoid environmental problems, (2) exploit its potential and (3) establish a recycling. In this context, technical aspects, such as hydrolysis, waste reduction, integration in urban structures and recycling of wasted organic matter, were discussed. An example of waste utilization is given based on the organic waste stream generated by a common building in Hong Kong with 640 residents. The 640 residents would generate more than 250 kg of wet organic waste per day, which can be biologically hydrolyzed using decentralized processes on site. The hydrolysis of 250 kg wet organic waste would result in the production of 33 kg glucose, 15 kg lipids, 0.6 kg free amino nitrogen and 0.2 kg phosphate, which can be used as nutrients in biotechnological processes or feedstocks in chemical reactions for the production of food, feed, chemicals and materials. Recycling of organic matter is not only a sustainable waste treatment, but contributes to the economy and self-sufficiency of urban areas in resource supply.

AB - Urban areas, characterized as areas with a high population density, generate large amounts of liquid and solid waste streams. Without proper treatment, these waste streams accumulate in the environment of urban areas and may lead to serious environmental problems. Contrarily, waste streams and particularly wasted organic materials contain valuable compounds, which can be biologically and/or chemically converted into products to cover the economic needs of urban areas. In this study, a concept is presented that contributes to treatment and utilization of wasted organic material in a way to (1) avoid environmental problems, (2) exploit its potential and (3) establish a recycling. In this context, technical aspects, such as hydrolysis, waste reduction, integration in urban structures and recycling of wasted organic matter, were discussed. An example of waste utilization is given based on the organic waste stream generated by a common building in Hong Kong with 640 residents. The 640 residents would generate more than 250 kg of wet organic waste per day, which can be biologically hydrolyzed using decentralized processes on site. The hydrolysis of 250 kg wet organic waste would result in the production of 33 kg glucose, 15 kg lipids, 0.6 kg free amino nitrogen and 0.2 kg phosphate, which can be used as nutrients in biotechnological processes or feedstocks in chemical reactions for the production of food, feed, chemicals and materials. Recycling of organic matter is not only a sustainable waste treatment, but contributes to the economy and self-sufficiency of urban areas in resource supply.

KW - Organic waste reduction

KW - Organic waste recycling

KW - Decentralized process

KW - Urban areas

KW - Sustainability

KW - Chemistry

UR - http://www.scopus.com/inward/record.url?scp=84947733950&partnerID=8YFLogxK

U2 - 10.1016/j.ecoleng.2015.11.021

DO - 10.1016/j.ecoleng.2015.11.021

M3 - Journal articles

VL - 86

SP - 120

EP - 125

JO - Ecological Engineering

JF - Ecological Engineering

SN - 0925-8574

ER -