from the fiber include MDF board, stuffing for car seats, and bedding for medical use. Just one of the mills built to process waste fiber generates pre‐tax profits of approximately M$12.5 million (about $3 million) (Malaysian Ringgit ~ $0.24).
1.12 Constraints and Challenges
The implementation of Zero Emissions faces constraints and challenges, as well as new opportunities. For example, the use of dissipative materials poses a design challenge: If solvents and flocculants are no longer to be used, what would it be replaced? Chemical manufacturers need to work with design engineers to arrive at an understanding of the constraints of separation technologies so that manufacturing any material without emissions is difficult, but working with chemicals is particularly challenging because of the need to develop nontoxic materials that are also biodegradable. Two possible solutions are biological.
Biopolymers are an outgrowth of chemurgy, the division of applied chemistry that deals with industrial utilization of organic raw materials, especially from agro‐business. These substances, complex molecules formed in biological systems, can replace toxic, dissipative materials currently used as adhesives, absorbents, lubricants, soil conditioners, cosmetics, drug delivery vehicles, and textile dissipative. Substitutes for toxic materials and mechanical processes to substitute for dissipative materials are aspects of the same principle.
Enzymes are natural catalysts that speed up chemical reactions without being consumed in the process. They function best in mild conditions, so their use requires up to one‐third less energy than many synthetic chemicals; paradoxically, this lower need for energy can be an obstacle in a system that still rewards large‐scale energy use with reduced rates. Enzymes are especially useful in systems designed to reduce or eliminate dissipative losses.
There is also a need for a taxonomy of environmental technologies that clarifies opportunities for fast developing, generic processes to address such recurring problem as process large streams of contaminated water from various processes and oxidation in air. Chemical engineering and related professions ought to be able to make rapid advances in such areas.
Many of the industries in the investment recovery or “decomposer niche” are hard put to compete against large‐scale facilities that produce materials from virgin materials. More recently, however, economies of scale for resource extractors and processors, along with cheap energy supplies, have been introduced almost everywhere in the world. For example, economies of scale have enabled chemical companies to produce plastics at a price that other manufacturers, as well as the individual consumer, can afford.
1.12.1 The Challenges in Industrial Environmental Management
We need to educate and train current generation engineers, managers, business owners, and policy makers with the skills and knowledge they need to be our champion stewards of environmental management and expert on lean manufacturing of major industries demonstrating ZDZE operations. Engineers have always faced design constraints. Historically, these constraints were the laws of physics, availability of materials, and energy. Modern engineers still face the limitation of the laws of physics but have been granted larger amounts of energy and a wide variety of materials. Modern society has added design parameters that include safety, durability, convenience, regulatory compliance, attractiveness, and price.
A true engineer does not view regulation as an obstruction, but rather as a design constraint like efficiency and durability. The goal has always been to develop the optimal design within given constraints, whether they are the laws of nature or society. Unfortunately, the actions of our modern society have placed undue burdens on nature. Nature's ability to absorb excessive amounts of pollutants and stressors while still providing critical services of acceptable water quality, clean air, food, and biodiversity is limited.
Industrial ecology is Western society's response to meeting the challenge of sustainable development. To manufacturers falls the challenge of attaining Zero Emissions. They in turn pass this directive to their engineers. To engineers, the advance of technology has meant increasing degrees of freedom with regard to design. The collective body of knowledge and our harnessing of materials and energy has been the source of these freedoms. Safety was the first man‐made design constraint that society imposed under the name of social good. Engineers responded to meet the challenge. Now society recognizes the need to impose a design parameter of Zero Emissions. Engineers will meet this challenge and accept it as they have the laws of physics – as a given.
1.12.2 Codes of Ethics in Engineering
Codes of ethics state the moral responsibilities of engineers as seen by the profession, and as represented by a professional society. Because they express the profession's collective commitment to ethics, codes are enormously important, not only in stressing engineers' responsibilities but also the freedom to exercise them.
Codes of ethics play at least eight essential roles: serving and protecting the public, providing guidance, offering inspiration, establishing shared standards, supporting responsible professionals, contributing to education, deterring wrongdoing, and strengthening a profession's image (also see Appendix J).
1.13 The Structure of the Book
1.13.1 What Is in the Book?
Chapter 1: This chapter addresses why industrial environmental management is important! Environmental management is a very crucial part of human well‐being that needs to be deeply considered. Formulated design seeks to steer the development process to take advantage of opportunities, avoid hazards, mitigate problems, and prepare people for unavoidable difficulties by improving adaptability and resilience. It is a process concerned with human–environment interactions, and seeks to identify: what is environmentally desirable; what are physical, economic, social and technological constraints to achieving that process; and what are the most feasible options. Actually, there can be no concise universal definition of environmental management; however, it can be briefly summarized as supporting sustainable development; demanding multidisciplinary and interdisciplinary or even holistic approaches; it should integrate and reconcile different development viewpoints, co‐ordinate science, engineering, technology, social, policy making, and planning; state proactive processes; timescales and concerns ranging from local to global issues; and one stresses stewardship rather than exploitation while dealing with a world affected by humans.
In other perspectives, environmental management can be explained as methods of ways when dealing issues due to the importance of the need to improve environmental stewardship by integrating ecology, policy making, planning, and social development. The goals include sustaining and (if possible) improving existing resources; preventing and overcoming environmental problems; establishing limits; founding and nurturing institutions that effectively support environmental research, monitoring, and management resources; warning of threats and identifying positive change opportunities; (where possible) improving quality of life; and finally, identifying new technology or policies that are useful.
Chapter 2: The objective of this chapter is to introduce the genesis of world environmental problems and to provide an overview of the history behind present environmental laws and regulations of pollution in various countries and continents.
Engineers in all disciplines practice a profession that must obey rules governing their professional conduct and ethics. One important set of rules that all engineers should be aware of is environmental statues, which are laws enacted by US Congress and governments of other countries around the world.
Environmental law, also known as environmental
