Remote controlled imaging apparatus for a high-temperature environment

A test tunnel at Yucca Mountain is to be equipped with a mobile camera system, which can record images both at infrared and visible wavelengths at an ambient temperature to 300 degrees Centigrade (300{dollar}\sp\circ{dollar}C). This measurement is to be taken over the entire 50 meter length of the tunnel. The imaging apparatus consists of a remote section equipped with cameras, pan unit and wireless communication units, all of which must be designed to operate at 300{dollar}\sp\circ{dollar}C for up to 60 minutes. The remote sensing section is to be controlled from a computer system located outside the high-temperature zone. The project comprises the design, acquisition, fabrication, and integration of all equipment components. Application software with a Graphical User Interface (GUI) is to be developed so as to enable remote control and monitoring of the measurement and observation process; In this thesis a description of the design and installation of the camera, rail and control system is presented. Furthermore a number of experimental runs were performed, and the results are evaluated. Recommendations for improvements of the current system, and possible future designs are presented

Balloon-borne three-meter telescope for far-infrared and submillimeter astronomy

The scientific objectives, engineering analysis and design, results of technology development, and focal-plane instrumentation for a two-meter balloon-borne telescope for far-infrared and submillimeter astronomy are presented. The unique capabilities of balloon-borne observations are discussed. A program summary emphasizes the development of the two-meter design. The relationship of the Large Deployable Reflector (LDR) is also discussed. Detailed treatment is given to scientific objectives, gondola design, the mirror development program, experiment accommodations, ground support equipment requirements, NSBF design drivers and payload support requirements, the implementation phase summary development plan, and a comparison of three-meter and two-meter gondola concepts

Mechatronic design of an Explosive Ordnance Disposal Robot

Thesis (Master)--Izmir Institute of Technology, Mechanical Engineering, Izmir, 2005Includes bibliographical references (leaves: 55-56)ix, 58 leavesThis study concerns with the design of an Explosive Ordnance Disposal (EOD) Robot which is controlled in task space and with the combined sensor system the robot is capable of autonomous navigation. The robot is composed of 4 different gripping apparatus attached to a 4 degree of freedom manipulator arm which is controlled in task space and a mobile platform which provides the mobility of the EOD robot in the operation field. Since the manipulator arm of the robot is controlled in task space apart from the control system of current EOD robots, the explosive ordnance disposal task which requires high precision and dexterity can be accomplished much faster and more accurate.In addition to improvements in the control system, a combined sensory system named VS-GPS is designed for autonomous navigation of the EOD robot by combining vision system, sonar system and GPS to operate in outdoor fields. In order to achieve the most feasible sensor system, all combinations of most common five conventional sensor systems are evaluated, and VS-GPS is found to be the most effective combined sensor system design.Design of the EOD robot and sensor system includes the solid modeling of the robot using a computer program, Solidworks, strength analysis, mathematical modeling of manipulator arm and evaluation of conventional sensor systems for an optimum combination of sensor systems especially for autonomous outdoor navigation of the robot

Balloon-borne three-meter telescope for far-infrared and submillimeter astronomy

This is the second Semiannual Report submitted under Grant NAGW-509 for the development of a Balloon-Borne Three-Meter Telescope for Far-Infrared and Submillimeter Astronomy. It covers the period 1 March 1984 through 31 August 1984. This grant covers work at the Smithsonian Astrophysical Observatory (SAO), University of Arizona (UA) and the University of Chicago (UC). SAO is responsible for program management, the gondola structure including the attitude control and aspect systems, mechanical systems, and telemetry and command systems; the UA is responsible for optics design and fabrication; the UC is responsible for determining provisions for focal-plane instrumentation. SAO and the UA share responsibility for the ground support data and control computer

USML-1 Glovebox experiments

This report covers the development of and results from three experiments that were flown in the Materials Science Glovebox on USML-1: Marangoni convection in Closed Containers (MCCC), Double Float Zone (DFZ), and Fiber Pulling in Microgravity (FPM). The Glovebox provided a convenient, low cost method for doing simple 'try and see' experiments that could test new concepts or elucidate microgravity phenomena. Since the Glovebox provided essentially one (or possibly two levels of confinement, many of the stringent verification and test requirements on the experiment apparatus could be relaxed and a streamlined test and verification plan for flight qualification could be implemented. Furthermore, the experiments were contained in their own carrying cases whose external configurations could be identified early in the integration sequence for stowage considerations while delivery of the actual experiment apparatus could be postponed until only a few months before flight. This minimized the time fluids must be contained and reduced the possibility of corrosive reactions that could ruin the experiment. In many respects, this exercise was as much about developing a simpler, cheaper way of doing crew-assisted science as it was about the actual scientific accomplishments of the individual experiments. The Marangoni Convection in Closed Containers experiment was designed to study the effects of a void space in a simulated Bridgman crystal growth configuration and to determine if surface tension driven convective flows that may result from thermal gradients along any free surfaces could affect the solidification process. The Fiber Pulling in Microgravity experiment sought to separate the role of gravity drainage from capillarity effects in the break-up of slender cylindrical liquid columns. The Stability of a Double Float Zone experiment explored the feasibility of a quasi-containerless process in which a solidifying material is suspended by two liquid bridges of its own melt

Chemical spray pyrolysis of Tl-Ba-Ca-Cu-O high-T(sub c) superconductors for high-field bitter magnets

The deposition of Tl-Ba-Ca-Cu-O thick films by spray pyrolyzing a Ba-Ca-Cu-O precursor film and diffusing thallium into the film to form the superconducting phase is examined. This approach was taken to reduce exposure to thallium and its health and safety hazards. The Tl-Ba-Ca-Cu-O system was selected because it has very attractive features which make it appealing to device and manufacturing engineering. Tl-Ba-Ca-Cu-O will accommodate a number of superconducting phases. This attribute makes it very forgiving to stoichiometric fluctuations in the bulk and film. It has excellent thermal and chemical stability, and appears to be relatively insensitive to chemical impurities. Oxygen is tightly bound into the systems, consequently there is no orthorhombic (conductor) to tetragonal (insulator) transition which would affect a component's lifetime. More significantly, the thallium based superconductors appear to have harder magnetic properties than the other high-Tc oxide ceramics. Estimates using magnetoresistance measurements indicate that at 77 K Tl2Ba2CaCu2O10 will have an upper critical field, H(sub c2) fo 26 Tesla for applied fields parallel to the c-axis and approximately 1000 Tesla for fields oriented in the a-b plane. Results to date have shown that superconducting films can be reproducibly deposited on 100 oriented MgO substrates. One film had a zero resistance temperature of 111.5 K. Furthermore, x ray diffraction analysis of the films showed preferential c-axis orientation parallel to the plane of the substrate. These results have now made it possible to consider the manufacture of a superconducting tape wire which can be configured into a topology useful for high-field magnet designs. The research which leads to the preparation of these films and plans for further development are reviewed

MAXIMA: A balloon-borne cosmic microwave background anisotropy experiment

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