Author_Institution :
New Jersey Inst. of Technol., Newark, NJ, USA
Abstract :
Sustainable green engineering design and manufacturing are changing every aspect of our life. This is because the climate is changing and customers are demanding sustainable green products and processes. Since many methods, designs and systems have to be changed, this is a complex field of integrated science and engineering, and we are only at the beginning. Sustainable green engineering has already attracted a wide area of research topics, including all aspects of energy management in every process step throughout the system´s lifecycle, renewable energy creation and storage, all sorts of waste reduction methods, new approaches to risk analysis and customer requirements analysis, new biodegradable materials, sustainable non-toxic manufacturing processes and machinery, new levels of optimization in control systems, advanced digital design/manufacturing system simulation methods, sustainability statistics, human and machine error prevention, reuse, recycling, and others. In this paper we offer an overview, as well as some methodology and concrete results.
Keywords :
biodegradable materials; climate mitigation; customer services; environmental factors; product life cycle management; recycling; renewable energy sources; risk analysis; sustainable development; waste reduction; biodegradable materials; control systems; customer requirements analysis; digital design-manufacturing system; energy management; energy storage; greener enterprises; human error prevention; machine error prevention; optimization; recycling; renewable energy creation; risk analysis; sustainability statistics; sustainable enterprises; sustainable green engineering design; sustainable green products; sustainable machinery; sustainable non-toxic manufacturing processes; system lifecycle; waste reduction methods; Design engineering; Design methodology; Energy management; Energy storage; Green products; Manufacturing; Material storage; Power engineering and energy; Renewable energy resources; Risk analysis; σ22 is the average square deviation from y0 of values under y0; σ22 is the average square deviation from y0 of values upper y0; A1 is the loss of defective under (y0−Δ1); A2 is the loss of defective upper (y0+Δ2); Loss function: L(y) =kσ2; intelligent Sustainable Enterprise Engineering (iSEE:Green);
