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Mechanical Engineering

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    Machining Types

    • Milling: Rotating tool removes material from stationary workpiece.
    • Turning: Stationary tool removes material from rotating workpiece.
    • Drilling: Rotating drill bit creates holes in the workpiece.

    Cutting Geometry

    image of cutting geometry (slide 16)

    • Terms: Rake angle \( \alpha \), Shear angle \( \phi \), Chip thickness \( t_c \), Depth of cut \( t_o \), Length of shear plane \( l_s \)
    • Chip ratio: \( r = \frac{t_o}{t_c} \)
    • Shear angle: \( \tan \phi = \frac{r \cos \alpha}{1 - r \sin \alpha} \)

    Cutting Forces

    image of cutting forces (slide 18/19)

    Friction angle \( \beta \), Coefficient of friction \( \mu = \tan \beta \), Resultant \( R \)

    Tool-Chip Interface

    • Friction force \( F = R \sin \beta \)
    • Normal Force \( N = R \cos \beta \)

    Vertical & Horizontal

    • Thrust force \( F_t = R \sin(\beta - \alpha) \)
    • Cutting force \( F_c = R \cos(\beta - \alpha) \)

    Shear Plane

    • Normal force \( N_s = R \sin(\beta - \alpha + \phi) \)
    • Shear force \( F_s = R \cos(\beta - \alpha + \phi) \)
    • Shear Stress \( T = \frac{F_s}{A_s} = \frac{R \cos(\beta - \alpha + \phi) \sin\phi}{w t_0} \)

    *box

    To minimize the shear stress, differentiate with respect to the shear plane angle \( \phi \) and set the derivative equal to zero:

    $$ \frac{d}{d\phi}\left(\cos(\beta - \alpha + \phi)\sin\phi\right) $$

    Differentiation with Respect to phi

    $$ 0 = \frac{d}{d\phi}\left(\frac{R}{w t_o}\cos(\beta - \alpha + \phi)\sin\phi\right) $$
    $$ \frac{d}{d\phi}\left(\cos(\beta - \alpha + \phi)\sin\phi\right) $$
    Applying the product rule:
    $$ 0 = \cos(\beta - \alpha + \phi)\cos\phi - \sin(\beta - \alpha + \phi)\sin\phi $$
    Rearranging terms:
    $$ \sin(\beta - \alpha + \phi)\sin\phi = \cos(\beta - \alpha + \phi)\cos\phi $$
    Dividing both sides:
    $$ \tan(\beta - \alpha + \phi) = \frac{\cos\phi}{\sin\phi} = \cot\phi $$
    Using identity:
    $$ \tan(\beta - \alpha + \phi) = \tan(90^\circ - \phi) $$
    Equating arguments:
    $$ \beta - \alpha + \phi = 90^\circ - \phi $$
    Solving for phi:
    $$ \boxed{\phi = 45^\circ - \frac{\beta}{2} + \frac{\alpha}{2}} $$
    This proves: Increase in rake angle (\( \alpha \)) and decrease in friction angle (\( \beta \))
    • higher shear angle
    • lower shear plane area
    • less force needed
    • lower power and temperature
    $$ P = u_t MRR = 1.64 \text{ hp} $$
    $$ F_c = \frac{P}{V} = 349 \text{ lbf} $$
    $$ t = \frac{l}{fN} = 0.25 \text{ min} $$

    Example Problem (Metric)

    • \( l = 150 \) mm
    • \( D_i = 10 \) mm, \( D_f = 8 \) mm
    • \( N = 400 \) rpm
    • Feed speed = \( 200 \) mm/min
    • \( u_t = 2.8 \) N\( \cdot \)m/mm\( ^3 \)
    $$ f = 0.5 \text{ mm/rev}, \quad D_{avg} = 9 \text{ mm} $$
    $$ MRR = 5650 \text{ mm}^3/\text{min} $$
    $$ t = 0.75 \text{ min} $$
    $$ P = 264 \text{ W}, \quad T = 6.3 \text{ N}\cdot\text{m} $$

    Drilling

    Terms: bit diameter \( D \), feed (len/rev) \( f \), drill speed (rev/time) \( N \)

    • \( MRR = \frac{\pi D^2}{4} f N \)

    Recommended drilling speeds and feed rates (insert chart from slide 70)

    Example Problem

    • \( D = 15 \) mm
    • \( f = 0.1 \) mm/rev
    • \( N = 500 \) rpm
    $$ MRR = 8840 \text{ mm}^3/\text{min} $$
    $$ P = 58.9 \text{ W}, \quad T = 1.13 \text{ N}\cdot\text{m} $$

    Tool Life

    Terms: cutting speed \( V \), tool life \( t \), constants \( n \) and \( C \)

    • Taylor equation: \( Vt^n = C \)

    Example Problem

    $$ Vt^{0.2} = C $$

    If \( V \) is reduced by 30%

    $$ \frac{t_2}{t_1} = \left(\frac{1}{0.7}\right)^5 \approx 6 $$
    Tool life increases by approximately 6 times.

    Surface Roughness

    • Depends on feed rate, tool geometry, and material
    • Finishing operations improve surface quality

    Surface Tolerances (insert chart from slide 80)

    Machining Economics

    *Callout: Maximizing production rate minimizes cutting time per unit.

    Terms: total time per unit product for operation \( t_c \), part handling time per part \( t_h \), machining time per part \( t_m \), tool change time \( t_t \), number of pieces cut in one tool life \( n_p \)

    • Total cycle time: \( t_c = t_h + t_m + \frac{t_t}{n_p} \)

    Terms: cost rate for operator and machine \( C_o \), cost of part handling time \( C_o t_h \), cost of tool change time \( \frac{C_o t_t}{n_p} \), cost per cutting edge \( C_t \), tooling cost \( \frac{C_t}{n_p} \)

    • Total cost per unit product for operation: \( C_c = C_o t_h + C_o t_m + \frac{C_o t_t}{n_p} + \frac{C_t}{n_p} \)

    Design Advisor

    Recommended vs. Avoided Design Aspects.