Introduction to Traffic Signal Phasing

Abstract Aerobic granular sludge (AGS) comprises an aggregation of microbial cells in a tridimen sional matrix, which is able to remove carbon, nitrogen and phosphorous as well as other pollutants in a single bioreactor under the same operational conditions. During the past decades, the feasibility of implementing AGS in wastewater treatment plants (WWTPs) for treating sewage using fundament tally sequential batch reactors (SBRs) has been studied. However, granular sludge technology using SBRs has several disadvantages. For instance, it can present certain drawbacks for the treatment of high flow rates; furthermore, the quantity of retained biomass is limited by volume exchange. Therefore, the development of continuous flow reactors (CFRs) has come to be regarded as a more competitive option. This is why numerous investigations have been undertaken in recent years in search of different designs of CFR systems that would enable the effective treatment of urban and industrial wastewater, keeping the stability of granular biomass. However, despite these efforts, satisfactory results have yet to be achieved. Consequently, it remains necessary to carry out new technical approaches that would provide more effective and efficient AGS-CFR systems. In particular, it is imperative to develop continuous flow granular systems that can both retain granular biomass and efficiently treat wastewater, obviously with low construction, maintenance and exploitation cost. In this review, we collect the most recent information on different technological approaches aimed at establishing AGS-CFR systems, making possible their upscaling to real plant conditions. We discuss the advantages and disadvantages of these proposals and suggest future trends in the application of aerobic granular systems. Accordingly, we analyze the most significant technical and biological implications of this innovative technology.

Introduction  This document was created based on research and the experience of Huyett staff. Invaluable technical information, including statistical data contained in the tables, is from the 26th Edition Machinery Handbook, copyrighted and published in 2000 by Industrial Press, Inc. of New York, NY. Steel making information and flowcharts were produced with information from the website of The American Iron and Steel Institute (AISI) 1140 Connecticut Ave., NW, Suite 705 Washington, D.C. 20036. Many technical definitions are from “Everything You Always Wanted to Know About Steel. . . A Glossary of Terms and Concepts,” Summer 1998 Courtesy of Michelle Applebaum, Managing Director. Copyright 2000, Salomon Smith Barney Inc. Other glossary definitions are taken from “Cutting Tool Engineering” (ISSN:0011-4189) Copyright by CTE Publications Inc. 107 W. Van Buren, Ste. 204, Chicago, IL 60605. Information regarding differences of steel grades and their properties came from the McMaster-Carr Supply Company website at www.mcmaster.com, copyright 2003 by the McMaster-Carr Supply Company. Much basic and helpful information about steel properties and usage came from Metallurgy FAQ v 1.0 Copyright 1999 Drake H. Damerau, All rights reserved, at Survivalist Books. This document is provided to customers, vendors, and associates of G.L. Huyett for technical information relating to the manufacture and sale of non-threaded industrial fasteners. As such, this document is not a design standard, design guide, or otherwise. G.L. Huyett in not engaged in part and product design, because of the unknown uses of parts made or distributed by the company. Designs must be produced and tested by our customers for individual and commercial use. As such, Huyett assumes no liability of any kind, implied or expressed, for the accuracy, scope, and completion of the information herein 

Abstract: The primary purpose of this project is to investigate the engineering design process and use it to design a disposable water bottle for mass production that is aesthetically pleasing, structurally sound, market appropriate and financially viable. It is the intention that the water bottle, complete with branding, will go on sale in the Australian market. In the past decade bottled water has grown to become a major seller in the Australian beverage market. With many resources spent on the marketing and sales of a disposable water bottle, this project endeavor's to design a bottle tailored to its target demographic from the ground up. Largely in depth survey research from select focus groups within a target demographic will assure the accuracy of the specifications and the direct relevance to the intended consumer. An engineering design approach ensures that the bottle will not only be rigorously designed to heavily researched specifications but also computationally tested to guarantee the success of the completed product.