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기타 참고사항

1. Understand the basic concepts of fluid mechanics
2. Specify the various types of fluid flow problems encountered in practice
3. Model engineering problems and solve them in a systematic manner
4. Equipped with a working knowledge of accuracy, precision, and significant digits
5. Recognize the importance of dimensional similarity in engineering calculations

1. Have a working knowledge of the basic properties of fluid
2. Have a working knowledge of viscosity and the consequences of the frictional effects it causes in fluid flow
3. Calculate the capillary rises and drops due to the surface tension effect

1. Determine the variation of pressure in a fluid at rest
2. Calculate the forces exerted by a fluid at rest on plane or curved submerged surfaces
3. Analyze the rigid-body motion of fluids in containers during linear acceleration or rotation

1. Fluid Kinematics deals with the motion of fluids without considering the forces and moments which create the motion.
2. Items discussed in this Chapter.
- Material derivative and its relationship to Lagrangian and Eulerian descriptions of fluid flow.
- Flow visualization.
- Plotting flow data.
- Fundamental kinematic properties of fluid motion and deformation.
- Reynolds Transport Theorem

1. This chapter deals with 3 equations commonly used in fluid mechanics
- The mass equation is an expression of the conservation of mass principle.
- The Bernoulli equation is concerned with the conservation of kinetic, potential, and flow energies of a fluid stream and their conversion to each other.
- The energy equation is a statement of the conservation of energy principle.

1. Fluid flow problems can be analyzed using one of three basic approaches: differential, experimental, and
integral (or control volume).
2. In Chap. 5, control volume forms of the mass and energy equation were developed and used.
3. In this chapter, we complete control volume analysis by presenting the integral momentum equation.
- Review Newton's laws and conservation relations for momentum.
- Use RTT to develop linear and angular momentum equations for control volumes.
- Use these equations to determine forces and torques acting on the CV.

1. Understand dimensions, units, and dimensional homogeneity
2. Understand benefits of dimensional analysis
3. Know how to use the method of repeating variables
4. Understand the concept of similarity and how to apply it to experimental modeling

1. Have a deeper understanding of laminar and turbulent flow in pipes and the analysis of fully developed flow
2. Calculate the major and minor losses associated with pipe flow in piping networks and determine the pumping power requirements
3. Understand the different velocity and flow rate measurement techniques and learn their advantages and disadvantages

1. Understand how the differential equations of mass and momentum conservation are derived.
2. Calculate the stream function and pressure field, and plot streamlines for a known velocity field.
3. Obtain analytical solutions of the equations of motion for simple flows.

1. Appreciate why approximations are necessary, and know when and where to use.
2. Understand effects of lack of inertial terms in the creeping flow approximation.

3. Understand superposition as a method for solving potential flow.
4. Predict boundary layer thickness and other boundary layer properties.

1. Have an intuitive understanding of the various physical phenomena such as drag, friction and pressure drag, drag reduction, and lift.
2. Calculate the drag force associated with flow over common geometries.
3. Understand the effects of flow regime on the drag coefficients associated with flow over cylinders and spheres
4. Understand the fundamentals of flow over airfoils, and calculate the drag and lift forces acting on airfoils.

1. Understand how flow in open channels differs from flow in pipes
2. Learn the different flow regimes in open channels and their characteristics

1. Predict if hydraulic jumps are to occur during flow, and calculate the fraction of energy dissipated during hydraulic jumps
2. Learn how flow rates in open channels are measured using sluice gates and weirs