Industrial activities source

Hazardous Wastes Hazardous wastes are generated in hmited amounts throughout most industrial activities. In terms of generation, concern is with the identification of amounts and types ofhazardous wastes developed at each source, with emphasis on those sources where significant waste quantities are generated. 

During the forties and fifties, episodes of severe air pollution occurred In a number of urban and Industrial areas. They were responsible for 111 health and In some cases caused death among the populations concerned. As the scientific and public Information base on the adverse effects of urban air pollution Increased, so did public demand for control measures. As a result, many Industrial countries Introduced comprehensive air pollution control laws at various times from the mid-fifties onwards. Industrial response to these laws led to the application of control techniques which effectively reduced the emissions of some pollutants. However there are other sources and factors which can obscure the benefits of these control actions. For example, consider urban growth. In 1980 there were 35 cities with populations over 4 million. By the year 2000 this number will nearly double to 66, and by the 2025, this number will more than double to an estimated 135 (9). In developing countries, from 1980 to the year 2000, It Is estimated that twice as many people will live In cities of a total population of 1 million or more In Latin America (101 million to 232 million) and East Asia (132 million to 262 million). Three times as many people will live In cities of 1 million or more In South Asia (106 million to 328 million) and four times as many In Africa (36 million to 155 million) (10). Accompanying this rapid growth are Increases In Industrial activity... 

The unplanned growth of cities Is accompanied by Increased traffic, energy consumption. Industrial activity and pollution. Stationary sources such as power plants, emit most of the SO, and some of the SPH and NO,. Host of the CO and Pb and much of the particulate matter and Oj are emitted from mobile sources (cars, trucks, buses, planes, etc.). 

The BiodeNOx process is a novel process concept to reduce NO emissions from flue gases of stationary sources like power plants and other industrial activities [1]. The concept combines a wet chemicd absorption process with a novel biotechnological regeneration method. In the wet chemical absorption step, flue gas components are absorbed into an aqueous solution of Fe"(EDTA) (EDTA= ethylme-diamino-tetraacetic acid). The following reactions take place ... 

The purpose of chemical processes is not to make chemicals the purpose is to make money. However, the profit must be made as part of a sustainable industrial activity. Chemical processes should be designed as part of a sustainable industrial activity that retains the capacity of ecosystems to support both industrial activity and life into the future. Sustainable industrial activity must meet the needs of the present without compromising the needs of future generations. For chemical process design, this means that processes should use raw materials as efficiently as is economic and practicable, both to prevent the production of waste that can be environmentally harmful and to preserve the reserves of raw materials as much as possible. Processes should use as little energy as economic and practicable, both to prevent the buildup of carbon dioxide in the atmosphere from burning fossil fuels and to preserve reserves of fossil fuels. Water must also be consumed in sustainable quantities that do not cause deterioration in the quality of the water source and the long-term quantity of the reserves. Aqueous and atmospheric emissions must not be environmentally harmful, and solid waste to landfill must be avoided. 

Table 1 indicates primary pollutant sources and waste modes, and Table 2 indicates the primary and secondary sources and associated pollutants. The primary sources of soil contamination include land disposal of solid waste sludge and waste-water industrial activities and leakages and spills, primarily of petroleum products. The solid waste disposal sites include dumps, landfills, sanitary landfills, and secured landfills. 

Consequently, Europe has historically been a hotspot of environmental pressures because of the contamination caused by agricultural, municipal, and industrial activities and high population densities [5, 6], Such contamination has led to poor water quality in many European river basins [7-12], In addition, this pollution can cause the accumulation in river sediments of toxic compounds such as pesticides [13], surfactants [14], and alkyl polycyclic aromatic hydrocarbons (PAHs) [15], These can in turn act as a source to biota [16] and as a potential risk for entire ecosystems [17] if the compounds bioaccumulate, and thereby enter the food chain [18],... 

Freshwaters are an essential resource which must be available not only in the required quantity but also in a precise quality. Nevertheless, in the last years, this quality has been threatened as a consequence of the increasing industrial activity, population growth and agricultural practices. In fact, only less than 1% of the world s freshwater resources are readily available for human use, and even this resource is unevenly distributed among the countries. A lack of water to meet daily needs is a reality for many people around the world, and water scarcity already affects every continent. In the underdeveloped countries, water scarcity forces people to rely on unsafe sources of drinking water. In the developed countries, this problem is much less critical where contamination of drinking water is the adverse... 

CSB searched over 40 data sources for incidents that met its definition of a reactive incident (Section 2.1). The data search focused on recent incidents (since 1980) where the primary cause was related to chemical reactivity however, the 1980 cutoff is not intended to diminish the important lessons learned from prior incidents. The search covered both chemical manufacturing (i.e., raw material storage, chemical processing, and product storage) and other industrial activities involving bulk chemicals, such as... 

The economic viability of enhanced oil recovery with C02 flooding is limited to the cases where C02 is available at low cost. This is the case for the West-Texas fields, where C02 from natural sources is available, or at the Weyburn field in Canada, where C02 can be made available from the North Dakota Gasification Plant. Unlike the situation in the United States, almost the entire European oil production is located offshore. There, enhanced oil recovery activities would be more costly, simply resulting from the larger spatial extent of production units and the entire higher costs of offshore operations. Furthermore, there are no low-cost industrial C02 sources available in the closer vicinity of the North Sea oil fields, nor is there an infrastructure for C02 transport. 

The United Nations Framework Convention on Climate Change (UNFCCC) and the Kyoto Protocol, as such, have not foreseen C02 capture and storage as a means of emissions reduction. The UNFCCC defined emissions as, The release of greenhouse gases and/or their precursors into the atmosphere, (Article 1(4), UNFCCC, 1992). Consequently, C02 captured at source and stored outside the atmosphere is not an emission according to the definition in the Convention. Since industrial activity with CCS (and a theoretical 100% capture rate) does not create emissions according to the UNFCCC definition, one could interpret the action of C02 capture and storage as an emission reduction. Purdy and Macrory (2004) point out that this... 

In general, higher levels of phenol appear to be found in lakes and rivers that serve as water sources and discharge receivers for industrial and population centers, probably as a result of industrial activity and commercial use of phenol-containing products. For example, the presence of higher levels of phenol in the Delaware River near Philadelphia is the result of industrial effluents discharged into the sewer system (Sheldon and Hites 1979). 

Any excess 210Po radioactivity comes from other sources. Because of its volatility 210Po may be introduced directly into the atmosphere as a pollutant by burning coal and by various industrial activities, with possible contribution from the biosphere as well. 

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