Environmental engineering

Contents

1.             Introduction
1.2        History
1.3        News & Achievement 
1.4        Companies Of Environment Engineering
1.5        University of E&R

2.             Ecosystem

2.1                Nutrient Cycle

2.2                Energy Flow

2.3                Ecosystem Services

3.             Environment Risk

3.1                Hazards

3.2                Environment Hazard

3.3                Environment Risk

4.             Water Pollution

4.1                Main Pollutants

4.2                Waste water Treatment

5.             Solid Waste Management

5.1                Waste properties

5.2                Solid Waste System                                  

6.             Air Pollution

6.1                Composition of Air

6.2                Transport of Air

6.3                Air pollutants

6.4                Emission Estimation and Control

7.             Noise Pollution

7.1                Sources of Noise

7.2                Physical Properties of Noise

7.3                Health Effect

8.             Water Supply

8.1                Water Demand

8.2                Water Availability

8.3                Water Treatment

Introduction

Environmental engineering is the integration of sciences and engineering principles to improve the natural environment, to provide healthy water, air, and land for human habitation and for other organisms, and to clean up pollution sites. Environmental engineering can also be described as a branch of applied science and technology that addresses the issue of energy preservation, production asset and control of waste from human and animal activities. Furthermore, it is concerned with finding plausible solutions in the field of public health, such as waterborne diseases, implementing laws which promote adequate sanitation in urban, rural and recreational areas. It involves waste water management and air pollution control, recycling, waste disposal, radiation protection, industrial hygiene, environmental sustainability, and public health issues as well as a knowledge of environmental engineering law. It also includes studies on the environmental impact of proposed construction projects.

Environmental engineers study the effect of technological advances on the environment. To do so, they conduct studies on hazardous-waste management to evaluate the significance of such hazards, advise on treatment and containment, and develop regulations to prevent mishaps. Environmental engineers also designmunicipal water supply and industrial wastewater treatment systems as well as address local and worldwide environmental issues such as the effects of acid rain, global warming, ozone depletion, water pollution and air pollution from automobile exhausts and industrial sources.

At many universities, environmental engineering programs follow either the department of civil engineering or the department of chemical engineering at engineering faculties. Environmental "civil" engineers focus on hydrology, water resources management, bioremediation, and water treatment plant design. Environmental "chemical" engineers, on the other hand, focus on environmental chemistry, advanced air and water treatment technologies and separation processes.

Additionally, engineers are more frequently obtaining specialized training in law and are utilizing their technical expertise in the practices of environmental engineering law.

The History Of ........

Everything seems new if you are ignorant of history" . With that as a preamble I would like to discuss with you our profession, the fields of sanitation and public health; the roots of today's field of Environmental Engineering. Our profession has had a long history and has long been associated with the medical fields. I want to share with you today how our profession developed and also the many contributions by the faculty and alumni of Washington University.

Early History

In early Egyptian Civilizations  excavations have been found, showing arrangements were made for the collection of rainfall as well as the use of copper pipe for the disposal of sewage. This dates from 3400-2450 B.C. Irrigation was also widely used later during the new Egyptian Empire 1580-1200 B.C.The Knossian or the Minoan civilization was located in the Aegean Sea on the Isle of Crete and flourished between 1850-1400 B.C. This island is now a part of Greece. Excavations have revealed evidence of devices for sanitation, ventilation, drainage and latrines. The Queen even had a bathtub.
In early Greek history, there are many instances of sanitation and medicine being used. Temples located near springs and woodlands hills were used as Sanatoria and health resorts. These can be seen today at Epidauros on the Peloponese peninsular in southern Greece. Today this still remains a beautiful place and has one of the world's finest acoustical (non-electric) theatres still in use seating 14,000 persons.
For protection, the Greek populace lived near fortified heights. These fortresses are referred to as Acropolises, and located throughout the Greek Empire. The most famous is the Acropolis in Athens, where the Parthenon is located. All of these areas required protected water supplies so that people could survive during long periods of siege. Water and waste disposal were thus a significant aspect in choosing proper location.

The Dark Age

With the fall of the Roman Empire around 400 AD, began the Dark Ages (2). Instead of water being boiled to make water pure it was "the age of Mysticism" where witches were boiled in water. Consequently, filth, pestilence, and plague came back and continued until the 18th century.

Age of Enlightenment

Sir Francis Bacon, an English philosopher  began writing a reorganization of all human knowledge including an "inductive method of modern experimental science." In 1627, a year after his death, his last book was published Sylva Sylarum or a "Natural History in Ten Centuries." This compendium of knowledge described the thousand experiments that he had recorded, ten of which pertained to the treatment of water, including percolation or filtration, boiling, distillation and clarification by coagulation. He also dispelled a popular belief of the Romans that sea water could be desalinated by moving water through soil. Bacon proved that a well, placed near the sea would get natural ground water from a high elevation rather than from the sea and that is why the water found in such wells were fresh water.

Environmental Improvements in the United States

In the United States in the early 1800s it can be said that hydraulic engineering was environmental engineering. As early communities grew they needed more water. Each area was different where a good quality and abundant supply of water could be found. For an example, the City of New York in 1832 retained Colonel De Witt Clinton, an Army Engineer and son of a former New York Governor, to develop the Water Resources Plan for the City. His plan was to dam the Croton River and water would be delivered to the City by a 40-mile aqueduct. By 1842, the City was receiving up to 95 million gallons per day of good quality water.

THE NEWS OF ENVIRONMENT 

2015 March 27: Antarctic Floating Ice Shelves, Glacial ‘Doorstops’, Melting Rapidly

Rainfall and rising lake levels near Dallas, Texas have caused officials to consider easing of water restrictions, and China‘s new environmental law has hit a couple of state-run refineries with fines. Antarctic ice shelves are melting rapidly, and farmers in India will soon be able to access satellite crop data via their cell phones. A wasteful-of-water welfare scam is spreading across Maine.

2015 March 26: Climate Change Slows Down the Atlantic Ocean

Melting ice in Greenland has hindered normal circulation of the Atlantic that brings heat north from the tropics. California residents don’t think their neighbors are doing enough to conserve water, and many citizens of Ireland may refuse to pay their water bills. Flooding has killed four and interrupted copper mining in northern Chile, and cholera will continue to hurt Haiti until the necessary water supply and sanitation improvements are made.

2015 March 20: $1 Billion in Emergency Funding for California Drought Announced

The United Nations has unveiled a report that demonstrates how lack of water access disproportionately affects women. California Governor Jerry Brown and top lawmakers have unveiled $US 1 billion in emergency drought spending. Kenya has started a national fund to improve water access, with government agencies, NGOs and businesses all participating. Finally, fighting in eastern Ukraine is taking its toll on drinking water supplies.

March 17: Many Health Centers Worldwide Lack Clean Water, Report Says

A report from global health organizations highlights the lack of safe water and sanitation at health centers. Rivers in a Vietnam province are down 80 percent due to drought, whileCalifornia considers stricter water conservation measures today. Alberta, Canadaintroduced stricter regulations to protect water from oil sands development, and scientists found that groundwater plays an important role in nutrient transfer in the Mediterranean Sea. Wet wipes are a growing problem in Australia’s wastewater treatment systems.

March 10: Global Drought Responses Hurt by Lack of Coordination

A United Nations official says better drought management and response requires better coordination between government agencies. Taiwan released plans for measures to combat its drought, while wine growers and miners contend with a severe drought in Chile. A new study suggests temperatures in the northern hemisphere could begin to rise quickly. Microbes in groundwater could be essential to cleaning up arsenic contamination, researchers in Oregon found.

The Achievements 

Water Supply & Distribution

Today, a simple turn of the tap provides clean water - a precious resource. Engineering advances in managing this resource - with water treatment, supply, and distribution systems - changed life profoundly in the 20th century, virtually eliminating waterborne diseases in developed nations, and providing clean and abundant water for communities, farms, and industries.

Health Technologies 

Advances in 20th century medical technology have been astounding. Armed with only a few instruments in 1900, medical professionals now have an arsenal of diagnostic and treatment equipment at their disposal. Artificial organs, replacement joints, imaging technologies, and biomaterials are but a few of the engineered products that improve the quality of life for millions. 

Air Conditioning & Refrigeration

Air conditioning and refrigeration changed life immensely in the 20th century. Dozens of engineering innovations made it possible to transport and store fresh foods, and to adapt the environment to human needs. Once luxuries, air conditioning and refrigeration are now common necessities which greatly enhance our quality of life.

Household Application  

Household appliances dramatically changed the 20th century lifestyle by eliminating much of the labor of everyday tasks. Engineering innovation produced a wide variety of devices, including electric ranges, vacuum cleaners, dishwashers, and dryers. These and other products give us more free time, enable more people to work outside the home, and contribute significantly to our economy. 

High Performance Of Materials 

From the building blocks of iron and steel to the latest advances in polymers, ceramics, and composites, the 20th century has seen a revolution in materials. Engineers have tailored and enhanced material properties for uses in thousands of applications. In aircraft, medical devices, computers, and other products, high-performance materials have a great impact on our quality of life.  

The Top 5 Companies In Environment Firms

1. CH2M Hill Ltd., Englewood, Colo.

CH2M Hill is an American engineering company that provides consulting, design, construction, and operations services for corporations, and federal, state, and local governments. The firm's headquarters is in Meridian, an unincorporated area of Douglas County, Colorado in the Denver-Aurora Metropolitan Area. The postal designation of nearby Englewood is commonly listed as the company's location in corporate filings and local news accounts. As of December 2013 CH2M Hill had approximately 26,000 employees and 2013 revenues totaled $5.88 billion. The firm is employee-owned, with an internal stock market that operates buy/sell events quarterly.

2. URS Corp., New York, N.Y.

 URS is a leading provider of engineering, construction, and technical services for public agencies and private sector companies around the world. The Company offers a full range of program management; planning, design and engineering; systems engineering and technical assistance; construction and construction management; operations and maintenance; management and operations; information technology; and decommissioning and closure services. URS provides services for federal, oil and gas, infrastructure, power, and industrial projects and programs.

3. Veolia North America, Chicago, Ill.2

Veolia Water North America, headquartered in Chicago, Ill., is the top private water services contractor in the United States. With $546 million in revenue from 166 government clients, it dominated the country’s water outsourcing market in 2009.3 Despite the company’s predominance, its track record includes privatization failures in communities large and small. After several of its largest contracts — including Indianapolis, New Orleans and Puerto Rico — ran into serious snags, Veolia was forced to reconsider its strategy for turning water provision into a private, profit-making venture.

4. Bechtel Corp., San Francisco, Calif.

Bechtel Corporation (Bechtel Group) is the largest construction and civil engineering company in the United States, ranking as the 4th-largest privately owned company in the United States. Its headquarters are in the South of Market, San Francisco. Operating activities such as civil infrastructure, mining, metals, oil, gas, chemical and power.

5.Tetra Tech Inc., Pasadena, Calif.

Tetra Tech provides mission- and safety-critical expertise to the Federal Aviation Administration’s (FAA) Air Traffic Organization, enterprise architecture support to NextGen, and IT support services, including business, process re-engineering, identity management, information security, and enterprise software development for FAA operations. In the aviation sector, Tetra Tech is a world leader in performance-based navigation (PBN) and navigation systems support, with credentials grounded in 27 years of support to the United States’ aerospace safety, scientific, homeland security, and national defense communities. Our experts provide a proactive, systematic approach to managing ground-based navigation aids, lighting systems, satellite navigation, PBN, aviation safety, and environmental management systems.

University Of E&R 

1. University of California--Berkeley

The College of Engineering at University of California--Berkeley has an application deadline of February 10. The application fee is $90 for U.S. residents and $110 for international students. Its tuition is full-time: $11,220 per year (in-state) and full-time: $26,322 per year (out-of-state). The 2014 Ph.D. student-faculty ratio is 5.6:1. The College of Engineering at University of California--Berkeley has 252 full-time faculty on staff.

Graduate students at the UC-Berkeley College of Engineering can complete an advanced degree in eight areas, including Industrial Engineering & Operations Research and Applied Science & Technology.

Earning a master’s in engineering typically takes two years at Berkeley, but students can also opt for the accelerated Berkeley Engineering Professional Master’s Program, which graduates students in just one year. All graduate students must also complete two minors, which can include fields outside of the College of Engineering.

The College of Engineering has about 40 research centers and institutes where students can get involved. Graduate students can live on campus. For a break from school work, students can explore nearby San Francisco or take a quick trip to local beaches. To travel in and around San Francisco, students can take the Bay Area Rapid Transit, which stops a block from campus.

Environmental engineers find ways to keep nature less polluted, while environmental health engineers try to halt harmful environmental effects on human health. These are the top graduate schools for environmental / environmental health engineering. Each school's score reflects its average rating on a scale from 1 (marginal) to 5 (outstanding), based on a survey of academics at peer institutions.

2. Stanford University

The application fee is $125 for U.S. residents and $125 for international students. Its tuition is full-time: $47,073 per year. The 2014 Ph.D. student-faculty ratio is 7.1:1. The School of Engineering at Stanford University has 241 full-time faculty on staff.

Attending graduate school at Stanford puts engineering students on a diverse campus near Silicon Valley. There are about 65 centers and labs across campus where students can get involved in research projects, and the many companies in Silicon Valley offer internship and learning opportunities for graduate students. About 3,300 graduate students are enrolled at the School of Engineering, more than 20 percent of whom are women.

Graduate degrees are offered in 10 areas, including Materials Science and Engineering and Aeronautics and Astronautics. Engineering students with broad interests can enroll in cross-school programs, like the Stanford Design Program, offered in conjunction with the School of Humanities and Sciences, or can get involved in campuswide initiatives like Bio-X, which draws from the multiple disciplines for research in the biology and medical fields.

Graduate students can live on campus, and, for trips abroad, can partake in the China Internship Program. The school puts on several programs specifically for graduate students throughout the year, including the Graduate Women’s Welcome and a student picnic each fall.

3. University of Illinois--Urbana-Champaign

The College of Engineering at University of Illinois--Urbana-Champaign has a rolling application deadline. The application fee is $50 for U.S. residents and $75 for international students. Its tuition is full-time: $17,126 per year (in-state); full-time: $30,848 per year (out-of-state); part-time: $11,418 per year (in-state); and part-time: $20,566 per year (out-of-state). The 2014 Ph.D. student-faculty ratio is 4.2:1. The College of Engineering at University of Illinois--Urbana-Champaign has 413 full-time faculty on staff.

Furthering its mission as a land-grant institution, the University of Illinois stresses research as a foundation of graduate engineering programs. There are more than 50 research centers and institutes, and the school has spent close to $200 million on research.

Students can pursue advanced degrees in more than 10 areas, including Financial Engineering and Nuclear, Plasma, & Radiological Engineering. The school’s biological and agricultural engineering programs are particularly highly ranked. Distance students can earn a master’s degree in engineering or computer science online, and some audit and professional courses are offered online as well.

There are about 2,700 graduate students at the College of Engineering, close to 20 percent of whom are women. The campus Technology Entrepreneur Center helps students become innovators and entrepreneurs, and a $30,000 prize is awarded annually to a student who has been most innovative with technology. Graduate students can live on the Urbana-Champaign campus. After graduation, the school’s Engineering Career Services Office aids students in their job searches.

4. Georgia Institute of Technology

The College of Engineering at Georgia Institute of Technology has a rolling application deadline. The application fee is $75 for U.S. residents and $75 for international students. Its tuition is full-time: $12,344 per year (in-state); full-time: $27,600 per year (out-of-state); part-time: $515 per credit (in-state); and part-time: $1,150 per credit (out-of-state). The 2014 Ph.D. student-faculty ratio is 4.2:1. The College of Engineering at Georgia Institute of Technology has 535 full-time faculty on staff.

Students at the Georgia Tech College of Engineering have extensive degree options. There are close to 20 areas to specialize in, from medical physics to aerospace engineering. Among many well regarded programs at the Tech Engineering, the industrial engineering and biomedical engineering programs are especially highly ranked.

Students can complete a master’s or a doctorate degree, and a handful of the master’s degree offerings include dual programs with universities abroad. The Dual Program in Electrical and Computer Engineering, for example, sends students to a partner school, like France’s Institut d’Electronique de Microelectronique et de Nanotechnologies, Germany’s TU-Munich, or the Korea Advanced Institute of Science and Technology. There are also several dual degree options through China’s Shanghai Jiao Tong University and Italy’s Politecnico di Torino.

Back in Atlanta, graduate students can live on campus. Students and faculty are often highly involved in research projects, and students can complete co-ops and volunteer work in nearby Atlanta and beyond. More than 65 percent of all Georgia Tech students graduate from the College of Engineering, and notable alumni include Maj. General Chuck Swannack (ret.), president and chief executive officer of U.S. Logisitics, Inc., and Nagesh Kukumoor, an environmental consultant-turned-Bollywood director, actor, producer, and writer.

5. University of Michigan--Ann Arbor

The College of Engineering at University of Michigan--Ann Arbor has a rolling application deadline. The application fee is $65 for U.S. residents and $75 for international students. Its tuition is full-time: $22,868 per year (in-state); full-time: $43,024 per year (out-of-state); part-time: $1,231 per credit (in-state); and part-time: $2,350 per credit (out-of-state). The 2014 Ph.D. student-faculty ratio is 4.3:1. The College of Engineering at University of Michigan--Ann Arbor has 358 full-time faculty on staff.

The University of Michigan College of Engineering has curriculums for master’s, doctoral, and interdisciplinary programs, and classes emphasize project-based learning. Prospective graduate students can get a feel for the College at the annual Engineering Graduate Symposium, held each November. For current graduate students, it’s a chance to present research projects, find faculty advisers, and hear from featured speakers.

Outside of class, engineering students can bond and relax at schoolwide events like the CoE Bowling Challenge and periodic luncheons. Each academic program coordinates its own student activities as well. Graduate students can get additional support through the Just ASK program, which stands for Alumni Sharing Knowledge. College alumni can volunteer to mentor current students, either in person or through mail, E-mail, or phone calls.

Graduate students can live in a designated residence area on the university campus, also home to faculty members, staff, and families. Space ranges from efficiency and economy units to three-bedroom apartments. The university is located in Ann Arbor, Mich., a bustling college town full of shopping, dining, and nightlife options.

    

2. Ecosystem

An ecosystem is a community of living organisms (plants, animals and microbes) in conjunction with the nonliving components of their environment (things like air, water and mineral soil), interacting as a system. These biotic and abiotic components are regarded as linked together through nutrient cycles and energy flows. As ecosystems are defined by the network of interactions among organisms, and between organisms and their environment, they can be of any size but usually encompass specific, limited spaces (although some scientists say that the entire planet is an ecosystem).

Energy, water, nitrogen and soil minerals are other essential abiotic components of an ecosystem. The energy that flows through ecosystems is obtained primarily from the sun. It generally enters the system through photosynthesis, a process that also captures carbon from the atmosphere. By feeding on plants and on one another, animals play an important role in the movement of matter and energy through the system. They also influence the quantity of plant and microbial biomasspresent. By breaking down dead organic matter, decomposers release carbon back to the atmosphere and facilitate nutrient cycling by converting nutrients stored in dead biomass back to a form that can be readily used by plants and other microbes.

   

                                    

2.1 Nutrient Cycle

A nutrient cycle (or ecological recycling) is the movement and exchange of organic and inorganic matter back into the production of living matter. The process is regulated by food web pathways that decompose matter into mineral nutrients. Nutrient cycles occur within ecosystems. Ecosystems are interconnected systems where matter and energy flows and is exchanged as organisms feed, digest, and migrate about. Minerals and nutrients accumulate in varied densities and uneven configurations across the planet. Ecosystems 

recycle locally, converting mineral nutrients into the production ofbiomass, and on a larger scale they participate in a global system of inputs and outputs where matter is exchanged and transported through a larger system of biogeochemical cycles.

                                   

2.2 Energy Flow

In ecology, energy flow, also called the calorific flow, refers to the flow of energy through a food chain. In an ecosystem, ecologists seek to quantify the relative importance of different component species and feeding relationships. The energy is passed on from trophic level to trophic level and each time about 90% of the energy is lost, with some being lost as heat into the environment (an effect of respiration) and some being lost as incompletely digested food. Therefore, primary consumers get about 10% of the energy produced by autotrophs, while secondary consumers get 1% and tertiary consumers get 0.1%. This means the top consumer of a food chain receives the least energy, as a lot of the food chain's energy has been lost between trophic levels. This loss of energy at each level limits typical food chains to only four to six links.

2.3 Ecosystem Services

Humankind benefits in a multitude of ways from ecosystems. Collectively, these benefits are known as ecosystem services. Ecosystem services are regularly involved in the provisioning of clean drinking water and the decomposition of wastes. While scientists and environmentalists have discussed ecosystem services implicitly for decades, the ecosystem services concept itself was popularized by the Millennium Ecosystem Assessment (MA) in the early 2000s.^[1] This grouped ecosystem services into four broad categories: provisioning, such as the production of food and water; regulating, such as the control of climate and disease; supporting, such as nutrient cycles and crop pollination; and cultural, such as spiritual and recreational benefits. To help inform decision-makers, many ecosystem services are being assigned economic values.

3. Environment Risk

The word 'risk' has two distinct meanings. It can mean in one context a hazard or a danger, that is, an exposure to mischance or peril. In the other context, risk is interpreted more narrowly to mean the probability or chance of suffering an adverse consequence, or of encountering some loss. Thus 'flood risk' can refer to the presence of a danger of flooding - a flood hazard, or more narrowly, a specific probability such as a 0.01 probability flood event (a lOa-year flood). Because the word 'risk' can be used in these different ways the term has led to some confusion. Three distinct views which emerged in the Tihany Workshop are recorded here because they reflect the present divergent state of informed scientific opinion.

    

3.1 Hazard

A hazard is a situation that poses a level of threat to life, health, property, or environment. Most hazards are dormant or potential, with only a theoretical risk of harm; however, once a hazard becomes "active", it can create an emergency situation. A hazardous situation that has come to pass is called an incident. Hazard and possibility interact together to create risk.  

                              

3.2 Environment Hazard

One school of thought sees risk as more or less synonymous with hazard; that is, an event or act which holds adverse consequences. In this view the degree of risk is related both to its probability and to the magnitude of its consequences.

3.3 Environment Risk As Probability

Another school of thought would like to retain the word risk to apply solely to probabilistic statements. This school defines 'environmental risk' as the probability value of an undesirable event and its consequences that arise from a spontaneous natural origin or from a human action (physical or administrative) that is transmitted through the environment. According to this view the difference between 'impact assessment' and 'risk assessment' is that impact assessments are concerned with events that are reasonably certain to occur, while risk assessment is concerned with events that may possibly occur. Upon closer inspection the difference between 'certain' and 'probabilistic' events appears not in the nature of the events themselves but in the human understanding and description of the processes involved.

4. Water Pollution

Water pollution is the contamination of water bodies (e.g. lakes, rivers, oceans, aquifers and groundwater). This form of environmental degradation occurs when pollutants are directly or indirectly discharged into water bodies without adequate treatment to remove harmful compounds. Water pollution affects the entire biosphere – plants and organisms living in these bodies of water. In almost all cases the effect is

 damaging not only to individual species and population, but also to the natural biological communities.

          

4.1 Main Pollutants

Perhaps the overriding theme of these definitions is the ability of the environment toabsorb and adapt to changes brought about by human activities. In one word, environmental pollution takes place when the environment cannot process and neutralize harmful by-products of human activities (for example, poisonous gas emissions) in due course without any structural or functional damage to its system. In fact, “the due course” itself may last many years during which the nature will attempt to decompose the pollutants; in one of the worst cases – that of radioactive pollutants – it may take as long as thousands of years for the decomposition of such pollutants to be completed. Pollution occurs, on the one hand, because the natural environment does not know how to decompose theunnaturally generated elements (i.e., anthropogenic pollutants), and, on the other, there is a lack of knowledge on the part of humans on how to decompose these pollutants artificially.

Why does pollution matter?

It matters first and foremost because it has negative impacts on crucial environmental services such as provision of clean air and clean water (and many others) without which life on Earth as we know it would not exist.

4.2 Waste Water Treatment

Wastewater treatment broadly describes water treatment preparing water no longer needed or suitable for its most recent use for return to the water cycle with minimal environmental issues. Wastewater treatment is distinguished from water treatment by focus on disposal rather than use. Water reclamation implies avoidance of disposal by use of wastewater as a raw water supply. Treatment means removing impurities from water being treated; and some methods of treatment are applicable to both water and wastewater. Production of waste brine, however, may discourage wastewater treatment removing dissolved inorganic solids from water by methods like ion exchange, reverse osmosis, and distillation.

                            

                             

5. Solid Waste Management

Waste management is the "generation, prevention, characterization, monitoring, treatment, handling, reuse and residual disposition of solid wastes".^[1] There are various types of solid waste including municipal (residential, institutional, commercial), agricultural, and special (health care, household hazardous wastes, sewage sludge).^[1] The term usually relates to materials produced by human activity, and the process is generally undertaken to reduce their effect on health, the environment or aesthetics.

            

5.1 Waste Properties

Solid waste management option depend on physical and chemical characteristic of the waste. Waste generation rates are expressed in mass unit (kg / m³ ) instead of volume unit. This is because waste densities vary greatly among the wastes with different compaction with different stages in waste system ( collection, storage and disposal ). The moisture content of solid waste is                                  

Moisture content = mass of moisture / total mass of waste

and the dry mass weight can be found as

dry mass = total mass waste ( 1 – moisture content )

5.2 Solid Waste System

5.2.1 Landfill

Disposal of waste in a landfill involves burying the waste and this remains a common practice in most countries. Landfills were often established in abandoned or unused quarries, mining voids or borrow pits. A properly designed and well-managed landfill can be a hygienic and relatively inexpensive method of disposing of waste materials. Older, poorly designed or poorly managed landfills and open dumps can create a number of adverse environmental impacts such as wind-blown litter, attraction of vermin, and generation of liquid leachate. Another common product of landfills is gas (mostly composed of methane and carbon dioxide), which is produced from anaerobic breakdown of organic waste. This gas can create odor problems, kill surface vegetation and is a greenhouse gas.

Design characteristics of a modern landfill include methods to contain leachate such as clay or plastic lining material. Deposited waste is normally compacted to increase its density and stability and covered to prevent attracting vermin (such as mice or rats). Many landfills also have landfill gas extraction systems installed to extract the landfill gas. Gas is pumped out of the landfill using perforated pipes and flared off or burnt in a gas engine to generate electricity.                  

                                            

5.2.2 Recycling

Recycling is a resource recovery practice that refers to the collection and reuse of waste materials such as empty beverage containers. The materials from which the items are made can be reprocessed into new products. Material for recycling may be collected separately from general waste using dedicated bins and collection vehicles, a procedure called kerbside collection. In some communities, the owner of the waste is required to separate the materials into various different bins (e.g. for paper, plastics, metals) prior to its collection. In other communities, all recyclable materials are placed in a single bin for collection, and the sorting is handled later at a central facility. The latter method is known as "single-stream recycling

The most common consumer products recycled include aluminium such as beverage cans, copper such as wire, steel from food and aerosol cans, old steel furnishings or equipment, polyethylene and PET bottles, glassbottles and jars, paperboard cartons, newspapers, magazines and light paper, and corrugated fiberboardboxes.

PVC, LDPE, PP, and PS (see resin identification code) are also recyclable. These items are usually composed of a single type of material, making them relatively easy to recycle into new products. The recycling of complex products (such as computers and electronic equipment) is more difficult, due to the additional dismantling and separation required.

The type of material accepted for recycling varies by city and country. Each city and country has different recycling programs in place that can handle the various types of recyclable materials. However, certain variation in acceptance is reflected in the resale value of the material once it is reprocessed.

                                         
  

5.2.3 Sustainability

The management of waste is a key component in a business' ability to maintaining ISO14001 accreditation. Companies are encouraged to improve their environmental efficiencies each year by eliminating waste through resource recovery practices, which are sustainability-related activities. One way to do this is by shifting away from waste management to resource recovery practices like recycling materials such as glass, food scraps, paper and cardboard, plastic bottles and metal.

                             

                          

6. Air Pollution

Air pollution is the introduction of particulates, biological molecules, or other harmful materials into the Earth's atmosphere, causing disease, death to humans, damage to other living organisms such as food crops, or the natural or built environment. Air pollution may come from anthropogenic or natural sources.

The atmosphere is a complex natural gaseous system that is essential to support life on planet Earth. Stratospheric ozone depletion due to air pollution has been recognized as a threat to human health as well as to the Earth's ecosystems.

Indoor air pollution and urban air quality are listed as two of the world's worst toxic pollution problems in the 2008Blacksmith Institute World's Worst Polluted Places report. According to the 2014 WHO report, air pollution in 2012 caused the deaths of around 7 million people worldwide.

               

                   

6.1 Composition of Air

 Air is mainly composed of nitrogen, oxygen, and argon, which together constitute the major gases of the atmosphere. Water vapor accounts for roughly 0.25% of the atmosphere by mass. The concentration of water vapor (a greenhouse gas) varies significantly from around 10 ppmv in the coldest portions of the atmosphere to as much as 5% by volume in hot, humid air masses, and concentrations of other atmospheric gases are typically provided for dry air without any water vapor.^[4] The remaining gases are often referred to as trace gases,^[5] among which are the greenhouse gases such as carbon dioxide, methane, nitrous oxide, and ozone. Filtered air includes trace amounts of many other chemical compounds. Many substances of natural origin may be present in locally and seasonally variable small amounts as aerosols in an unfiltered air sample, including dust of mineral and organic composition, pollen and spores, sea spray, and volcanic ash. Various industrial pollutants also may be present as gases or aerosols, such as chlorine (elemental or in compounds), fluorine compounds and elemental mercury vapor. Sulfur compounds such as hydrogen sulfide and sulfur dioxide (SO₂) may be derived from natural sources or from industrial air pollution.

                                  

                

6.2 Transport of Air

Movement of air is caused by temperature or pressure differences and is eperienced as wind. Where there are differences of pressure between two places, a pressure gradient exists, across which air moves: from the high-pressure region to the low-pressure region. This movement of air however, does not follow the quickest straight-line path. In fact, the air moving from high to low pressure follows a spiralling route, outwards from high pressure and inwards towards low pressure. This is due to the rotation of the Earth beneath the moving air, which causes an apparent deflection of the wind to the right in the Northern Hemisphere, and to the left in the Southern Hemisphere. The deflection of air is caused by the Coriolis force. Consequently, air blows anticlockwise around a low-pressure centre (depression) and clockwise around a high-pressure centre (anticyclone) in the Northern Hemisphere. This situation is reversed in the Southern Hemisphere.

Wind caused by differences in temperature is known as convection or advection. In the atmosphere, convection and advection transfer heat energy from warmer regions to colder regions, either at the Earth surface or higher up in the atmosphere. Small-scale air movement of this nature is observed during the formation of sea and land breezes, due to temperature differences between seawater and land. At a much larger scale, temperature differences across the Earth generate the development of the major wind belts. Such wind belts, to some degree, define the climate zones of the world.

Air temperature is generally higher at ground level due to heating by the Sun, and decreases with increasing altitude. This vertical temperature difference creates a significant uplift of air, since warmer air nearer the surface is lighter than colder air above it. This vertical uplift of air can generate clouds and rain. Sometimes air from warmer regions of the world collides with air from colder regions. This air mass convergence occurs in the mid-latitudes, where the warm air is forced to rise above the colder air, generating fronts and depression.

6.3 Air Pollutants

An air pollutant is a substance in the air that can have adverse effects on humans and the ecosystem. The substance can be solid particles, liquid droplets, or gases. A pollutant can be of natural origin or man-made. Pollutants are classified as primary or secondary. Primary pollutants are usually produced from a process, such as ash from a volcanic eruption. Other examples include carbon monoxide gas from motor vehicle exhaust, or the sulfur dioxide released from factories. Secondary pollutants are not emitted directly. Rather, they form in the air when primary pollutants react or interact. Ground level ozoneis a prominent example of a secondary pollutant. Some pollutants may be both primary and secondary: they are both emitted directly and formed from other primary pollutants.

Major primary pollutants produced by human activity include:

·         Sulfur oxides (SO_x) - particularly sulfur dioxide, a chemical compound with the formula SO₂. SO₂ is produced by volcanoes and in various industrial processes. Coal and petroleum often contain sulfur compounds, and their combustion generates sulfur dioxide. Further oxidation of SO₂, usually in the presence of a catalyst such as NO₂, forms H₂SO₄, and thus acid rain. This is one of the causes for concern over the environmental impact of the use of these fuels as power sources.

·         Nitrogen oxides (NO_x) - Nitrogen oxides, particularly nitrogen dioxide, are expelled from high temperature combustion, and are also produced during thunderstorms by electric discharge. They can be seen as a brown haze dome above or a plume downwind of cities. Nitrogen dioxide is a chemical compound with the formula NO₂. It is one of several nitrogen oxides. One of the most prominent air pollutants, this reddish-brown toxic gas has a characteristic sharp, biting odor.

·         Carbon monoxide (CO) - CO is a colorless, odorless, toxic yet non-irritating gas. It is a product byincomplete combustion of fuel such as natural gas, coal or wood. Vehicular exhaust is a major source of carbon monoxide.

                     

6.4 Emission Estimation and Control

Air pollutant emission factors are representative values that people attempt to relate the quantity of a pollutant released to the ambient air with an activity associated with the release of that pollutant. These factors are usually expressed as the weight of pollutant divided by a unit weight, volume, distance, or duration of the activity emitting the pollutant (e.g., kilograms of particulate emitted per tonne of coal burned). Such factors facilitate estimation of emissions from various sources of air pollution. In most cases, these factors are simply averages of all available data of acceptable quality, and are generally assumed to be representative of long-term averages.

There are 12 compounds in the list of POPs. Dioxins and furans are two of them and intentionally created by combustion of organics, like open burning of plastics. The POPs are also endocrine disruptors and can mutate the human genes.

7. Noise Pollution

 Noise pollution or noise disturbance is the disturbing or excessive noise that may harm the activity or balance of human or animal life. The source of most outdoor noise worldwide is mainly caused by machine sand transportation systems, motor vehicles, aircraft, and trains. Outdoor noise is summarized by the word environmental noise. Poor urban planning may give rise to noise pollution, since side-by-side industrial and residential buildings can result in noise pollution in the residential areas.

Indoor noise can be caused by machines, building activities, and music performances, especially in some workplaces. Noise-induced hearing loss can be caused by outside (e.g. trains) or inside (e.g. music) noise.

High noise levels can contribute to cardiovascular effects in humans, a rise in blood pressure, and an increase in stress and vasoconstriction, and an increased incidence of coronary artery disease. In animals, noise can increase the risk of death by altering predator or prey detection and avoidance, interfere with reproduction and navigation, and contribute to permanent hearing loss.

                            

         
7.1 Soruces of Noise

Broadly speaking, the noise pollution has two sources, i.e. industrial and non- industrial. The industrial source includes the noise from various industries and big machines working at a very high speed and high noise intensity. Non- industrial source of noise includes the noise created by transport/vehicular traffic and the neighbourhood noise generated by various noise pollution can also be divided in the categories, namely, natural and manmade. Most leading noise sources will fall into the following categories: roads traffic, aircraft, railroads, construction, industry, noise in buildings, and consumer products.

7.1.1 Road Traffic Noise

In the city, the main sources of traffic noise are the motors and exhaust system of autos , smaller trucks, buses, and motorcycles. This type of noise can be augmented by narrow streets and tall buildings, which produce a canyon in which traffic noise reverberates.

                                    

7.1.2 Construction Noise

The noise from the construction of highways, city streets, and buildings is a major contributor to the urban scene . Construction noise sources include pneumatic hammers, air compressors, bulldozers, loaders, dump trucks (and their back-up signals), and pavement breakers.

7.1.3 Industry Noise

Although industrial noise is one of the less prevalent community noise problems, neighbours of noisy manufacturing plants can be disturbed by sources such as fans, motors, and compressors mounted on the outside of buildings Interior noise can also be transmitted to the community through open windows and doors, and even through building walls. These interior noise sources have significant impacts on industrial workers, among whom noise- induced hearing loss is unfortunately common

                               

7.2 Physical Properties of Noise

 Frequency: The period of a sound is the duration of one cycle of its motion. Its frequency is the number of cycles that occur within a second. Frequency is measured in Hertz (abbreviated Hz). The period and frequency of a sound are reciprocally related (i.e., period = 1/frequency).

The phase of a sound is the instantaneous amplitude at a given point in time. The entire cycle of a sound wave is divided into 360 equal parts called degrees. Phase is thus a measure of time with respect to frequency or period.

Human beings can perceive frequencies from about 20 Hz up to about 18,000 Hz (18 KHz), the limit varying with the individual (aging causes loss of high frequency detection).

 Intensity: Sound intensity is a measurement of the amount of power of a sound at a given location. It is measured in decibels (abbreviated dB), which is a measurement of the ratio between the power of a given sound and a reference sound. The formula for calculating the intensity of a sound I is:

I = 10 log (I/I₀)

7.3 Health Effect

Noise pollution effects both health and behavior. Unwanted sound (noise) can damage psychological health. Noise pollution can cause hypertension, high stress levels, tinnitus, hearing loss, sleep disturbances, and other harmful effects.

Sound becomes unwanted when it either interferes with normal activities such as sleeping, conversation, or disrupts or diminishes one’s quality of life.

Chronic exposure to noise may cause noise-induced hearing loss. Older males exposed to significant occupational noise demonstrate more significantly reduced hearing sensitivity than their non-exposed peers, though differences in hearing sensitivity decrease with time and the two groups are indistinguishable by age 79. A comparison of Maaban tribesmen, who were insignificantly exposed to transportation or industrial noise, to a typical U.S. population showed that chronic exposure to moderately high levels of environmental noise contributes to hearing loss.

High noise levels can contribute to cardiovascular effects and exposure to moderately high levels during a single eight-hour period causes a statistical rise in blood pressure of five to ten points and an increase in stress, and vasoconstriction leading to the increased blood pressure noted above, as well as to increased incidence of coronary artery disease.

Noise pollution also is a cause of annoyance. A 2005 study by Spanish researchers found that in urban areas households are willing to pay approximately four Euros per decibel per year for noise reduction.

                           

             

8. Water Supply

Water supply is the provision of water by public utilities, commercial organisations, community endeavors or by individuals, usually via a system of pumps and pipes. Irrigation is covered separately.

                   

     

8.1 Water Demand

Water resources are sources of water that are useful or potentially useful. Uses of water includeagricultural, industrial, household, recreational and environmental activities. The majority of human uses require fresh water.

97 percent of the water on the Earth is salt water and only three percent is fresh water; slightly over two thirds of this is frozen in glaciers and polar ice caps.^[1] The remaining unfrozen freshwater is found mainly as groundwater, with only a small fraction present above ground or in the air.

Fresh water is a renewable resource, yet the world's supply of groundwater is steadily decreasing, with depletion occurring most prominently in Asia and North America, although it is still unclear how much natural renewal balances this usage, and whether ecosystems are threatened. The framework for allocating water resources to water users (where such a framework exists) is known as water rights.

                                          

8.2 Water Availability

As water supplies are stressed by growing populations, the impacts of climate change and greater competition of resources, the need to leverage innovative technologies and alternative water supplies continues to grow. The challenge for many is matching the quality of water with its intended use.
Many water systems use treated wastewater for irrigation or industrial uses where water does not need to be of drinking water quality. Some water systems treat wastewater to drinking water standards and store it underground before withdrawing it as a source of drinking water.

This page provides information and resources about approaches that water systems can use to address current and anticipated variability of source water quality and quantity. 

8.3 Water Treatment

The first documented use of sand filters to purify the water supply dates to 1804, when the owner of a bleachery in Paisley, Scotland, John Gibb, installed an experimental filter, selling his unwanted surplus to the public. The first treated public water supply in the world was installed by engineer James Simpson for the Chelsea Waterworks Company in London in 1829. The practice of water treatment soon became mainstream, and the virtues of the system were made starkly apparent after the investigations of the physician John Snow during the1854 Broad Street cholera outbreak demonstrated the role of the water supply in spreading the cholera epidemic.

The Metropolis Water Act introduced regulation of the water supply companies in London, including minimum standards of water quality for the first time. The Act "made provision for securing the supply to the Metropolis of pure and wholesome water", and required that all water be "effectually filtered" from 31 December 1855. This legislation set a worldwide precedent for similar state public health interventions across Europe.

Permanent water chlorination began in 1905, when a faulty slow sand filter and a contaminated water supply led to a serious typhoid fever epidemic in Lincoln, England. Dr. Alexander Cruickshank Houston used chlorination of the water to stem the epidemic. His installation fed a concentrated solution of chloride of lime to the water being treated. The first continuous use of chlorine in the United States for disinfection took place in 1908 at Boonton Reservoir (on the Rockaway River), which served as the supply for Jersey City, New Jersey. Desalination appeared during the late 20th century, and is still limited to a few areas.

This is the example for Environmental Engineering -