اللجنة العلمية للميكانيك 223

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Example 2

Example 2
5 / Acceleration Analysis & Graphical Method

5 / Acceleration Analysis & Graphical Method
EXAMPLE 6.6 FORCES ACTING ON A PIPE BEND A 1 m–diameter pipe bend shown in the diagram is carrying c

EXAMPLE 6.6 FORCES ACTING ON A PIPE BEND A 1 m–diameter pipe bend shown in the diagram is carrying c
EXAMPLE 6.4 WATER DEFLECTED BY A VANE A water jet is deflected 60° by a stationary vane as shown in

EXAMPLE 6.4 WATER DEFLECTED BY A VANE A water jet is deflected 60° by a stationary vane as shown in

EXAMPLE 6.7 WATER FLOW THROUGH REDUCING BEND Water flows through a 180° reducing bend, as shown. The

EXAMPLE 6.7 WATER FLOW THROUGH REDUCING BEND Water flows through a 180° reducing bend, as shown. The
EXAMPLE 6.4 Momentum Equation Applied to a Nozzle The sketch shows air flowing through a nozzle. The

EXAMPLE 6.4 Momentum Equation Applied to a Nozzle The sketch shows air flowing through a nozzle. The
Ch6 Momentum Equation

Ch6 Momentum Equation
6.10 A horizontal water jet at 20°C impinges on a vertical-perpendicular plate. The discharge is 0.5

6.10 A horizontal water jet at 20°C impinges on a vertical-perpendicular plate. The discharge is 0.5
EXAMPLE 6.1 THRUST OF ROCKET The sketch below shows a 40 g rocket, of the type used for model rocket

EXAMPLE 6.1 THRUST OF ROCKET The sketch below shows a 40 g rocket, of the type used for model rocket
Example The water velocity in the channel shown in the figure has a velocity distribution across the

Example The water velocity in the channel shown in the figure has a velocity distribution across the
Conservation of mass

Conservation of mass
Example: Consider the steady flow in a water pipe joint shown in the diagram. The areas are: A₁=0.2

Example: Consider the steady flow in a water pipe joint shown in the diagram. The areas are: A₁=0.2

Example: A tank has a hole in the bottom with a cross-sectional area of 0.0025 m². The cross-section

Example: A tank has a hole in the bottom with a cross-sectional area of 0.0025 m². The cross-section
Reynolds Transport Theorem RTT

Reynolds Transport Theorem RTT
EXAMPLE 5.4 MASS ACCUMULATION IN A TANK A jet of water discharges into an open tank, and water leave

EXAMPLE 5.4 MASS ACCUMULATION IN A TANK A jet of water discharges into an open tank, and water leave
EXAMPLE 5.8: A 120 cm pipe is in series with a 60 cm pipe. The speed of the water in the 120 cm pipe

EXAMPLE 5.8: A 120 cm pipe is in series with a 60 cm pipe. The speed of the water in the 120 cm pipe
Control Volume Approach

Control Volume Approach
CH5 Control volume approach and continuity principle (5.1 Rate of flow)

CH5 Control volume approach and continuity principle (5.1 Rate of flow)
Example Water flows in a channel that has a slope of 30°. If the velocity is assumed to be constant,

Example Water flows in a channel that has a slope of 30°. If the velocity is assumed to be constant,
Example Air that has a density of 1.24 kg/m^3 flows in a pipe with a diameter of 30 cm at a mass rat

Example Air that has a density of 1.24 kg/m^3 flows in a pipe with a diameter of 30 cm at a mass rat
Example 17.4 The pendulum in Fig. 17–7 is suspended from the pin at O and consists of two thin rods

Example 17.4 The pendulum in Fig. 17–7 is suspended from the pin at O and consists of two thin rods
Example 17.3 If the plate shown in Fig. 17–6a has a density of 8000 kg/m^3 and a thickness of 10 mm

Example 17.3 If the plate shown in Fig. 17–6a has a density of 8000 kg/m^3 and a thickness of 10 mm
Example 17.1 Determine the moment of inertia of the cylinder about the z axis. The density of the ma

Example 17.1 Determine the moment of inertia of the cylinder about the z axis. The density of the ma
Paraller axis theorem

Paraller axis theorem
Ch17 : Kinetics of rigid body force and acceleration 17.1 (Mass moment of inertia)

Ch17 : Kinetics of rigid body force and acceleration 17.1 (Mass moment of inertia)
Example 16.17 The collar C in Fig. 16–30a moves downward with an acceleration of 1 m/s^2. At the ins

Example 16.17 The collar C in Fig. 16–30a moves downward with an acceleration of 1 m/s^2. At the ins
Example 16.14 The rod AB shown in Fig. 16–27a is confined to move along the inclined planes at A and

Example 16.14 The rod AB shown in Fig. 16–27a is confined to move along the inclined planes at A and
Example 16.8 The link is guided by two block A and B, which move in the fixed slots. If the velocity

Example 16.8 The link is guided by two block A and B, which move in the fixed slots. If the velocity
Example 16.6 The link is guided by two block A and B, which move in the fixed slots. If the velocity

Example 16.6 The link is guided by two block A and B, which move in the fixed slots. If the velocity
Ch16 Kinematics of a rigid body 16.5,16.7 (Relative motion analysis : Velocity & acceleration)

Ch16 Kinematics of a rigid body 16.5,16.7 (Relative motion analysis : Velocity & acceleration)