Issue link: http://uwashington.uberflip.com/i/193116
Modern accessible pedestrian systems require operations that can be easily and quickly customized to allow safe and reliable pedestrian access at signalized intersections. Without the ability to tune the pedestrian information for each intersection, pedestrians will be tempted to assume increased individual risks or are faced with confusing or conflicting directions resulting in unsafe actions. Our research seeks to provide direction and alert pedestrians of potential dangers in ways that are clear and quickly comprehended. The systems are intended for use by pedestrians possessing a wide range of physical and cognitive abilities. Pedestrian buttons are no longer a simple mechanical switch that indicates to the traffic controller that someone wants to cross the street. APS buttons are now verbal and vibra-tactile traffic signals. The immediate goals are: 1. Continue the development of the AAPS to unambiguously and accurately communicate the state of the visual traffic signals with a minimum of distraction. 2. Investigate new technologies for assisting pedestrians with limited physical and vision abilities to safely cross at signalized intersections. 3. Provide additional opportunities for intersection customization to improve safety for pedestrians at intersections. 4. Assess customization capabilities and recommend practices to help traffic agency engineers and technicians to determine when, how, and where to use the advanced customized operations. -• Project: Production of Renewable Diesel Fuel from Biologically Based Feedstocks • PI: Jon Van Gerpen (UI) Current petroleum-based transportation fuels are becoming increasingly expensive as petroleum is extracted from deeper waters, depleted fields, and politically unstable countries. In addition, these fossil fuels are identified as a significant source of CO2, which is responsible for global climate change. Alternative fuels produced from renewable biological sources are attractive options for displacing some of the petroleum-based fuels. The objective of the project is to develop a model process to produce hydrocarbon fuels from triglyceride feedstocks such as vegetable oils and animal fats. These hydrocarbons are miscible with conventional gasoline and diesel fuel. They are different from conventional biodiesel because they are not monoalkylesters, so they do not have the chemical composition required to comply with the ASTM specification for biodiesel. However, they still qualify for existing existing government incentive programs that are intended to reduce petroleum imports. In fact, the combination of federal excise credits and sale of Renewable Identification Numbers (RINs) has provided a total federal subsidy of $2.70/gallon for advanced biofuels. The renewable diesel fuel produced by this process will qualify as an advanced biofuel. The fuel has advantages over conventional biodiesel in that insoluble reaction products are not produced, the cold flow properties are better, and because oxygen has been removed, the energy density is higher. A secondary objective is to determine whether the production technology for these compounds, which has mainly been focused on large petroleum refining facilities, can be implemented on a smaller scale. If this can be done, existing biodiesel production facilities could retrofit their plants with this technology. The fuel is expected to be easier to integrate into the existing fuel infrastructure than biodiesel. Although the primary focus of this project is on fuels that can be added to the diesel fuel stream to displace petroleum, the technology is applicable to production of bio-based jet fuel and gasoline. We will be developing a pilot facility at the UI that can be used to further develop the technology and evaluate competing processes. Specifically, we will be optimizing the process conditions for the decarboxylation and catalytic cracking that will occur inside of the reactor and evaluating new approaches such as using methyl esters (biodiesel) as the feed for the reactor and using a diluents flow to control reaction temperature. We will also be educating a graduate student to enter the field of renewable fuels. -- 2012-2013 Annual Report 13