Physics Test F.Sc 1 Chapter #06 Fluid Dynamic 1. When fluid is incompressible then A. When fluid is incompressible then B. flow of the fluid is straight line C. density of the fluid is constant D. volume of the fluid is constant 2. When body moves with terminal velocity the accereration in the body become A. zero B. maximum C. variable D. infinite 3. Terminal velocity is A. uniform B. maximum C. uniform and maximum
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Turbine group member’s duties Team MLP (Tesla turbine) Caleb Fonner * Head of stress analysis * Head of materials analysis Norman Hilliard * Head of fluid system analysis * Helped with stress analysis Jake Schirber * Power * Helped with stress analysis Brian Tiefenthaler * Pro E/CAD designer * Helped with fluid analysis * Helped with stress analysis * Project Discussion The Tesla turbine for MARE 451 Senior Design Capstone Project 1 has been broken up
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Conceptual Physics 11th Edition Chapter 14: GASES © 2010 Pearson Education‚ Inc. This lecture will help you understand: • • • • • • • The Atmosphere Atmospheric Pressure The Barometer Boyle’s Law Buoyancy of Air Bernoulli’s Principle Plasma © 2010 Pearson Education‚ Inc. The Atmosphere Atmosphere • Ocean of air • Exerts pressure The Magdeburghemispheres demonstration in 1654 by Otto von Guericke showed the large magnitude of atmosphere’s pressure. © 2010
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INTRODUCTION TO AERONAUTICS: A DESIGN PERSPECTIVE CHAPTER 3: AERODYNAMICS AND AIRFOILS “Isn’t it astonishing that all these secrets have been preserved for so many years just so that we could discover them!!” Orville Wright 3.1 DESIGN MOTIVATION The Physics of Aerodynamic Forces Figure 3.1 shows a cross section view of an aircraft wing. A wing cross section like this is called an airfoil. Lines drawn above and below the airfoil indicate how the air flows around it. The
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25++ ---25++ -25 25 100 --50 -----50 ---50 -50 --100 Total 125 100 50 150 125 150 25 25 750 Engineering Mathematics – III* Manufacturing 202041 Process-I Computer Aided 202042 Machine Drawing* 202043 Thermodynamics* 202044 Material Science 202045 Fluid Mechanics Workshop Practice 202046 II 202047 Soft Skills Total of Semester – I 207002 + Under Oral head‚ examination should be based on term work completed during practical and theory syllabus ++ Term work marks should be based on term work completed
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series and parallel 2. To show shut off point of pump in series and parallel ABSTRACT / INTRODUCTION Pump is a general term for any fluid machine; used to transfer and add energy to fluid in a system‚ either at the same level or to a new height. There are some fundamental parameters used to determine the performance of a pump. The mass flow rate of fluid is the obvious primary pump performance parameter and for incompressible flow‚ it is more common to use volume flow rate rather than mass
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B.E Chemical Engineering Syllabus ENGINEERING MATHEMATICS – III Sub Code Hrs/ Week Total Hrs. : : : 10MAT31 04 52 IA Marks Exam Hours Exam Marks PART-A UNIT-1 Fourier series Convergence and divergence of infinite series of positive terms‚ definition and illustrative examples* Periodic functions‚ Dirichlet’s conditions‚ Fourier series of periodic functions of period and arbitrary period‚ half range Fourier series. Complex form of Fourier Series. Practical harmonic analysis. 7 Hours UNIT-2 Fourier
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Supervisor: Prof. Dr. -Ing. habil. Kai Sundmacher Faculty of Process Systems Engineering Otto-von-Guericke University‚ Magdeburg‚ Germany and Max-Planck Institute for Dynamics of Complex Technical Systems Magdeburg‚ Germany October 2010 ACKNOWLEDGEMENTS I would like to express my gratitude to Max Planck Institute for dynamics of complex technical systems and Otto-von-Guericke University-Magdeburg for providing financial support and facilities for this project. I wish to thank my thesis adviser
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behavior. Fluid Pressure-Volume-Temperature and phase behavior. Pump equipment performance specifications. An examination of fluid dynamics within a centrifugal pump provides appreciation for the need to analyze the pump “one stage at a time.” The importance of individual pump testing is also identified. This paper focuses on the three ESP products in the csLIFT suite‚ csSubmersible‚ csSubsAnalysis‚ and csSubsDesign. Methods are proposed by which the pump‚ motor‚ producing formation‚ and fluids are considered
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Laws of Motion Bernoulli’s Principle In fluid dynamics‚ Bernoulli’s principles states that an increase in the speed of the fluid corresponds to a decrease in pressure of the same fluid. Similarly‚ the decrease in pressure corresponds to a loss in the potential energy of the fluid. The principle is applicable to various types of fluids‚ which leads to Bernoulli’s equation. There are different types of Bernoulli’s equation depending on the nature of fluid in use. The principle is valid for most compressible
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