Essay on Construction Waste and municipal solid waste 175 words APA two references each

BEM 3601, Waste Management 1 Cou rse Learning Outcomes for Unit IV Upon completion of this unit, students should be able to: 2. Describe the major categories of waste . 2.1 Descr ibe the components of nonhazardous industrial waste . 2.2 Identify the factors that contribute to the amount of construction waste produced . 4. Characterize the components and chemical and physical properties of municipal solid waste (MSW) . 4.1 Describe th e chemical and physical properties of incinerator ash . 4.2 Identify the contribution of plastic waste to the MSW stream . 6. Discuss waste disposal techniques and technologies . 6.1 Explain the concept of industrial symbiosis and how it can reduce the amoun t of nonhazardous industrial waste . 6.2 Describe how a cyclic rather than a linear approach to design and construction can reduce construction waste . 6.3 Analyze the pros and cons of thermal waste treatment . 6.4 Discuss the four main categories of plastic solid waste recycling techniques . Reading Assignment Chapter 14: Reusing Nonhazardous Industrial Waste Across Business Clusters Chapter 15 : Construction Waste Chapter 16 : Thermal Waste Treatment Chapter 17 : Thermochemical T reatment of Plastic Solid Waste Unit Lesson When we, as human, use materials in our everyday life (eating, drin king, building, buying, selling ) we produce a variety of waste products. Think about it . T here are billions of us on this earth. We produce waste in astronomical amounts. What happens to this waste? Does it magically disappear once we are done with it?

Not hardly. Depending on the type of waste, it must be disposed of somehow, in ways that do not endanger us. Non -hazardous Industrial Waste (NHIW) According to the Environmental Protection Agency (EPA), 7.6 billion tons of industrial solid waste are generat ed by American industrial facilities each year. This waste consists of “organic chemicals, inorganic chemicals, primary iron and steel, plastics and resin manufacturing, stone, clay, glass and concrete, pulp and paper, food and kindred products ( U.S . EPA , 2012). UNIT IV STUDY GUIDE Reusing and Treating Waste BEM 3601, Waste Management 2 UNIT x STUDY GUIDE Title The first step in managing such a large and varied waste stream is to encourage more efficient production of goods. As you learned in Unit I, tools such as life cycle assessment help to reduce the amount of waste generated in the first place. Anoth er way we can reduce the non -hazardous industrial w aste (NHIW ) stream is through industrial symbiosis. Industrial symbiosis occurs when one manufacturer’s waste becomes another manufacturer’s raw material. Industrial symbiosis is part of the study of indu strial ecology that examines the flow of materials and energy through systems at different scales : from products to factories , all the way up to national and global levels (Osmani, 2011). We can use the concepts of industrial ecology and symbiosis to creat e more efficient and sustainable industries and reduce the amount of NHIW that is sent to landfills and incinerators each year. Construction Waste One estimate of construction waste states that 30% of what is brought to a construction site to be used as building materials ends up as waste (Fishbein, 1998). Not only does this waste create environmental issues but also it adds unnecessary costs to the project. A significant percentage of this waste (33%) is a result of architects not taking waste minimizat ion into account during the design process (Osmani, 2011). Programs such as Leadership in Energy & Environmental Design (LEED) are encouraging construction project teams to take a construction project’s environmental impact into consideration. John Deere , an agricultural care company, constructed a marketing and sales center that was awarded a LEED Gold rating in June 2012. To achieve such a status, many recycling and reuse projects were incorporated into the construction process. For example, the team us ed waste from the construction site to provide energy for the cement manufacturing process. Metal went to scrapyards for recycling, and sheetrock went to a plant that recycles wallboard (Cox, 2013). Thermal Waste Treatment An alternative to landfilling w aste, incineration i nvolves burning waste materials to oxidize organic compounds. As a result of this burning, t he ash from incinerators can contain heavy metals , and the flue gases can contain harmful organic and inorganic compounds. The chemical and phy sical characteristics of a waste determine how it should be treated. The goal of the treatment is to make the chemical compounds in the waste less mobile and less toxic (Vallero, 2011). A testing procedure called the toxicity characteristic leaching proced ure (TCLP) is performed on the incinerator ash to assess the level of leach ability of the metals. If the ash does not pass the TCLP test, it must be disposed of in a hazardous waste landfill. Therefore, although incineration reduces the total volume of the waste, contaminants can be concentrated in the ash. Thermochemical Treatment of Plastic Solid Waste Pla stic is ubiquitous in our every day lives ; therefore, so is plastic waste. According to the EPA in 2010, approximately 12% of municipal solid waste (MS W), or 31 million tons , was plastic waste (ACC , Gershman, Brickner & Bratton, Inc. 2013). Plastic has a high energy value . T he plastic can be either recycled or the stored energy in the plastic can be recovered. In re -extrusion and mechanical recycling, scrap plastic is used to manufacture plastic products of similar material. Thermochemical treatments such as gasification and pyrolysis produce fuels. Gasification produces syngas, which can be used to create synthetic natural gas, and pyrolysis produces a synthetic liquid fuel that is comparable to crude oil ( ACC, Gershman, Brickner, & Bratton, 2013). BEM 3601, Waste Management 3 UNIT x STUDY GUIDE Title References American Chemistry Council, Gershman, Brickner & Bratton, Inc. (2013). Gasification of non -recycled plastics from municipal solid waste in the United States (GBB/12038 -01). Retrieved from http://plastics.americanchemistry.com/Sustainability -Recycling/Energy -Recovery/Gasification -of-Non - Recycled -Plastics -from -Municipal -Solid -W aste -in-the -United -States.pdf Cox , C. (2013). Turning waste into gold. Environmental Design & Construction , 16 (7), 16 -19. Fishbein, B. K. (1998). Building for the future: Strategies to reduce construction and demolition waste in municipal projects . New York, NY: Inform . Osmani, M. (2011). Construction waste. In T. M. Letch er, & D. A. Vallero (Eds.), Waste: A handbook for management (pp. 207 -21 8). Burlington, MA: Academic Press. Vallero, D. (2011). Thermal waste treatment. In T. M. Letcher, & D. A. Vallero (Eds.), Waste: A handbook for management (pp. 219 -231). Burlington, MA: Academic Press. U.S. Environmental Protection Agency (2012). Guide for industrial waste management . Retrieved from http://www.epa.gov/epawaste/nonhaz/industrial/guide/index.htm