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'''Environmental Engineering''' is a broad science devoted to pollution or contamination of resources. Much of it deals with preventing further contamination by application of chemical engineering and mechanical engineering principles to destroy or remove the contaminants before they get into the environment. A good example of this is air pollution control, where special burner designs, and scrubbers are used to remove Sulfur Dioxide and Nitrous Oxides, yes, and even Carbon Dioxide from combustion gasses prior to their release into the environment.
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Water pollution control relies heavily on chemistry, microbiology, biology and civil engineering. In some cases, as little as 0.0001% or less of a noxious substance can ruin a resource such as water. Example:  Sewage contamination of 10 parts per million, (1% = 10,000 ppm)can spoil a water resource such as a lake. The maintenance of drinking water is even more restrictive because the limits of many contaminants are significantly less than one part per billion. (One part per billion is the equivalent of one second in 31.688 years, or 31 years, 8.5 months.)
'''Environmental engineering''' is a broad [[science]] devoted to remediation of all forms of [[pollution]].<ref>{{cite book|author=Danny D. Reible|title=Fundamentals of Environmental Engineering |publisher=CRC Publishers|year=1998|id=ISBN 1-56670-047-7}}</ref><ref name=Mihelcic>{{cite book |author=James R. Mihelcic, Martin T. Auer, and others |title=Fundamentals of Environmental Engineering |publisher=John Wiley |year=1999|id=ISBN 0-471-24313-2}}</ref><ref>{{cite book|author=Sangeeta Madan and Pankaj Madan (Editors)|title=Global Encyclopaedia of Environmental Science Technology and Management|edition=1st Edition|publisher=Global Vision Publishing House|year=2009|id=ISBN 81-8220-267-1}}</ref> Much of it deals with preventing pollution by application of [[civil engineering]] and [[chemical engineering]] principles to destroy or remove the pollutants before they get into the [[natural environment]] ([[air]], [[water]] and [[land]] resources).


The working definition of environmental engineering has been broadened over the past few years to encompass drainage and hydrology design work and the development of drainage plans and stream flow and flood zones from developed areas. Part of this expansion also involves the area of property risk assessment evaluation and restoration and remediation of various types of contaminated environments including soils and waterways.
A formal definition of environmental engineering might be that it is a field in which one applies the basic fundamentals of [[mathematics]], [[physics]], [[chemistry]] and [[biology]] to the protection of human health and the natural environment.<ref name=Mihelcic/>


[[Category:CZ Live]]
== Environmental engineering work areas ==
[[Category:Engineering Workgroup]]
 
Environmental engineering involves wastewater management and treatment, air pollution control, recycling, solid waste disposal, radiation protection and public health issues. It also includes studies on the environmental impact of proposed construction projects.
 
Environmental engineers perform hazardous-[[waste management]] studies to evaluate the impact of such hazards, advise on their treatment and containment, and develop regulations to prevent hazardous waste problems. Environmental engineers also design municipal water supply and [[Wastewater treatment|industrial wastewater treatment]] systems<ref>{{cite book | author=Beychok, Milton R. | title=[[Aqueous Wastes from Petroleum and Petrochemical Plants]] | edition=1st Edition | publisher=John Wiley & Sons | year=1967 | id= [[Library of Congress Control Number|LCCN]] 67019834}}</ref><ref>{{cite book|author=Tchobanoglous, G., Burton, F.L., and Stensel, H.D.|title=Wastewater Engineering (Treatment Disposal Reuse) / Metcalf & Eddy, Inc.|edition=4th Edition|publisher=McGraw-Hill Book Company|year=2003|id=ISBN 0-07-041878-0}}</ref> as well as being concerned with issues such as the effects of [[acid rain]], [[ozone depletion]], water pollution and air pollution from [[Automobile emissions control|automobile exhausts]] and industrial sources.<ref>{{cite book|author=Turner, D.B.|title=[[Workbook of Atmospheric Dispersion Estimates]]|edition=2nd Edition|publisher=CRC Press|year=1994|id=ISBN 1-56670-023-X}} [http://www.crcpress.com/shopping_cart/products/product_detail.asp?sku=L1023&parent_id=&pc= www.crcpress.com]</ref><ref>{{cite book|author=Beychok, M.R.|title=[[Fundamentals of Stack Gas Dispersion]] |edition=4th Edition|publisher=author-published|year=2005|id=ISBN 0-9644588-0-2}}</ref>
 
At many universities, Environmental Engineering programs are offered within either the Department of Civil Engineering or the Department of Chemical Engineering. Environmental "civil" engineering programs focus on hydrology, water resources management, bioremediation, and water treatment plant design. Environmental "chemical" engineering programs, on the other hand, focus on environmental chemistry, advanced air and water treatment technologies and separation processes.
 
The working definition of environmental engineering has been broadened over the past few years to encompass drainage and hydrology design work and the development of drainage plans and stream flow and flood zones from developed areas. Part of this expansion also involves the restoration and remediation of various types of contaminated environments including soils and waterways.
 
==History of environmental engineering==
 
Many ancient civilizations constructed sewer systems in some cities. The Romans constructed aqueducts to prevent drought and to provide a clean supply of water for the city of Rome. In the 15th century, [[Bavaria]] restricted the development and degradation of the alpine countryside that was the region's source of water.
 
Modern environmental engineering began in [[London, United Kingdom|London]] in the mid-19th century with the construction of a major sewer network for central London which was instrumental in relieving the city from cholera epidemics, while beginning the cleansing of the Thames river.<ref>D.P. Smith. "Sir Joseph William Bazalgette (1819-1891): Engineer to the Metropolitan Board of Works". ''Transactions of the Newcomen Society'', 1986-87, Vol. 58.</ref>
 
The field began to emerge as a separate engineering discipline during the middle the 20th century in response to widespread public concern about water and pollution and increasingly extensive degradation of the natural environment. The introduction of drinking water treatment and sewage treatment in industrialized countries reduced waterborne disease deaths to relative rarities.
 
In many cases, as societies grew, actions were undertaken to achieve certain environmental benefits which had longer-term impacts that reduced other environmental qualities.  A major example was the widespread application of [[DDT]] to control agricultural pests in the years following [[World War II]]. While agricultural crop yields increased dramatically, thus reducing world hunger substantially and controlling the incidence of [[malaria]] better than it had ever been, the effect of DDT on the reproductive systems of numerous species resulted in bringing those species almost to the brink of extinction. The story of DDT as related in [[Rachel Carson]]'s "[[Silent Spring]]" is considered to be the beginning of the modern environmental movement and the development of the modern field of environmental engineering.<ref>{{cite book|author=Rachel Carson|title=Silent Spring|edition=1st Edition|publisher=Houghton Mifflin|year=1962|id=}}</ref>
 
== Example applications ==
 
A good example is the control of air pollution from [[combustion]] sources such as the [[flue gas]]es from the combustion of fuels in [[furnace]]s  where special burner designs are used to remove [[nitrogen oxides]] and [[flue gas desulfurization]] systems are used to remove [[sulfur dioxide]] from the combustion flue gases. Currently, a great deal of research and development is being devoted to the removal, capture and disposal of [[carbon dioxide]] from flue gases.
 
[[Water pollution]] control relies heavily on [[chemistry]], [[microbiology]], [[biology]], [[chemical engineering]] and [[civil engineering]]. In some cases, as little as 0.0001% or less of a noxious substance can contaminate a resource such as water. For example, sewage contamination of 10 parts per million (1% = 10,000 [[ppm]]) can contaminate a water resource such as a lake. The maintenance of drinking water quality is even more restrictive because the limits of many contaminants are significantly less than one part per billion (one part per billion is the equivalent of one second in 31.688 years, or 31 years, 8.5 months).
 
== References ==
 
{{reflist}}[[Category:Suggestion Bot Tag]]

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Environmental engineering is a broad science devoted to remediation of all forms of pollution.[1][2][3] Much of it deals with preventing pollution by application of civil engineering and chemical engineering principles to destroy or remove the pollutants before they get into the natural environment (air, water and land resources).

A formal definition of environmental engineering might be that it is a field in which one applies the basic fundamentals of mathematics, physics, chemistry and biology to the protection of human health and the natural environment.[2]

Environmental engineering work areas

Environmental engineering involves wastewater management and treatment, air pollution control, recycling, solid waste disposal, radiation protection and public health issues. It also includes studies on the environmental impact of proposed construction projects.

Environmental engineers perform hazardous-waste management studies to evaluate the impact of such hazards, advise on their treatment and containment, and develop regulations to prevent hazardous waste problems. Environmental engineers also design municipal water supply and industrial wastewater treatment systems[4][5] as well as being concerned with issues such as the effects of acid rain, ozone depletion, water pollution and air pollution from automobile exhausts and industrial sources.[6][7]

At many universities, Environmental Engineering programs are offered within either the Department of Civil Engineering or the Department of Chemical Engineering. Environmental "civil" engineering programs focus on hydrology, water resources management, bioremediation, and water treatment plant design. Environmental "chemical" engineering programs, on the other hand, focus on environmental chemistry, advanced air and water treatment technologies and separation processes.

The working definition of environmental engineering has been broadened over the past few years to encompass drainage and hydrology design work and the development of drainage plans and stream flow and flood zones from developed areas. Part of this expansion also involves the restoration and remediation of various types of contaminated environments including soils and waterways.

History of environmental engineering

Many ancient civilizations constructed sewer systems in some cities. The Romans constructed aqueducts to prevent drought and to provide a clean supply of water for the city of Rome. In the 15th century, Bavaria restricted the development and degradation of the alpine countryside that was the region's source of water.

Modern environmental engineering began in London in the mid-19th century with the construction of a major sewer network for central London which was instrumental in relieving the city from cholera epidemics, while beginning the cleansing of the Thames river.[8]

The field began to emerge as a separate engineering discipline during the middle the 20th century in response to widespread public concern about water and pollution and increasingly extensive degradation of the natural environment. The introduction of drinking water treatment and sewage treatment in industrialized countries reduced waterborne disease deaths to relative rarities.

In many cases, as societies grew, actions were undertaken to achieve certain environmental benefits which had longer-term impacts that reduced other environmental qualities. A major example was the widespread application of DDT to control agricultural pests in the years following World War II. While agricultural crop yields increased dramatically, thus reducing world hunger substantially and controlling the incidence of malaria better than it had ever been, the effect of DDT on the reproductive systems of numerous species resulted in bringing those species almost to the brink of extinction. The story of DDT as related in Rachel Carson's "Silent Spring" is considered to be the beginning of the modern environmental movement and the development of the modern field of environmental engineering.[9]

Example applications

A good example is the control of air pollution from combustion sources such as the flue gases from the combustion of fuels in furnaces where special burner designs are used to remove nitrogen oxides and flue gas desulfurization systems are used to remove sulfur dioxide from the combustion flue gases. Currently, a great deal of research and development is being devoted to the removal, capture and disposal of carbon dioxide from flue gases.

Water pollution control relies heavily on chemistry, microbiology, biology, chemical engineering and civil engineering. In some cases, as little as 0.0001% or less of a noxious substance can contaminate a resource such as water. For example, sewage contamination of 10 parts per million (1% = 10,000 ppm) can contaminate a water resource such as a lake. The maintenance of drinking water quality is even more restrictive because the limits of many contaminants are significantly less than one part per billion (one part per billion is the equivalent of one second in 31.688 years, or 31 years, 8.5 months).

References

  1. Danny D. Reible (1998). Fundamentals of Environmental Engineering. CRC Publishers. ISBN 1-56670-047-7. 
  2. 2.0 2.1 James R. Mihelcic, Martin T. Auer, and others (1999). Fundamentals of Environmental Engineering. John Wiley. ISBN 0-471-24313-2. 
  3. Sangeeta Madan and Pankaj Madan (Editors) (2009). Global Encyclopaedia of Environmental Science Technology and Management, 1st Edition. Global Vision Publishing House. ISBN 81-8220-267-1. 
  4. Beychok, Milton R. (1967). Aqueous Wastes from Petroleum and Petrochemical Plants, 1st Edition. John Wiley & Sons. LCCN 67019834. 
  5. Tchobanoglous, G., Burton, F.L., and Stensel, H.D. (2003). Wastewater Engineering (Treatment Disposal Reuse) / Metcalf & Eddy, Inc., 4th Edition. McGraw-Hill Book Company. ISBN 0-07-041878-0. 
  6. Turner, D.B. (1994). Workbook of Atmospheric Dispersion Estimates, 2nd Edition. CRC Press. ISBN 1-56670-023-X.  www.crcpress.com
  7. Beychok, M.R. (2005). Fundamentals of Stack Gas Dispersion, 4th Edition. author-published. ISBN 0-9644588-0-2. 
  8. D.P. Smith. "Sir Joseph William Bazalgette (1819-1891): Engineer to the Metropolitan Board of Works". Transactions of the Newcomen Society, 1986-87, Vol. 58.
  9. Rachel Carson (1962). Silent Spring, 1st Edition. Houghton Mifflin.