Work and Kinetic Energy Work done by a constant force Work is a scalar quantity. No motion (s=0) → no work (W=0) cos Fs s F W s: [ W ] = newton·meter = N·m = J = joule (SI) [ W ] = dyne·cantimeter = dyn·cm = erg (CGS) J = 1 N · 1 m = 10 3 g 100 (cm/s 2 ) 100 cm = 10 7 erg cular cases: (i) φ = 90 0 → cos φ = 0 → W = 0 (no w (ii) φ = 180 0 → cos φ = -1 → W = - Fs ≤ 0 (negativ force net a is F F j j James Joule (1818 – 1889 s F F s
Work and Kinetic Energy. Work done by a constant force Work is a scalar quantity. No motion (s=0) → no work (W=0). Units: [ W ] = newton ·meter = N·m = J = joule (SI) [ W ] = dyne·cantimeter = dyn·cm = erg (CGS) 1 J = 1 N · 1 m = 10 3 g 100 (cm/s 2 ) 100 cm = 10 7 erg. - PowerPoint PPT Presentation
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Work and Kinetic EnergyWork done by a constant forceWork is a scalar quantity.No motion (s=0) → no work (W=0)
cosFssFW
Units: [ W ] = newton·meter = N·m = J = joule (SI) [ W ] = dyne·cantimeter = dyn·cm = erg (CGS) 1 J = 1 N · 1 m = 103 g 100 (cm/s2) 100 cm = 107 erg
Particular cases: (i) φ = 900 → cos φ = 0 → W = 0 (no work) (ii) φ = 1800 → cos φ = -1 → W = - Fs ≤ 0 (negative work)
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James Joule (1818 – 1889)sF
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Kinetic Energy and Work-Energy Theorem
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Work and Energy with Varying Force
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(1D-motion)
Fx =const → W = Fx (x2 – x1)Particular cases:
Fx = -k·x (Hooke’s law) → 2
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Work-Energy Theorem for 1D-Motion under Varying Forces
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KKKW 12is kinetic energy2
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Example 6.7: Air-track glider attached to springData: m=0.1 kg, v0=1.5m/s, k=20 N/m, μk = 0.47Spring was unstretched.Find: maximum displacement dSolution:
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Work-Energy Theorem for 3D-Motion along a Curve
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Units: [ P ] = [ W ] / [ T ] , 1 Watt = 1 W = 1 J / s1 horsepower = 1 hp = 550 ft·lb/s = 746 W = 0.746 kW
Related energy unit 1 kilowatt-hour = 1 kWh = (1000 J/s) 3600 s = 3.6·106 J = 3.6 MJ
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Power is a scalar quantity.
Power is the time rate at which work is done,or the rate at which the energy is changing.These rates are the same due to work-energytheorem.
James Watt(1736-1819), the developerof steam engine.
Exam Example 13: Stopping Distance (problems 6.31, 7.27)
x
v
0a
Data: v0 = 50 mph, m = 1000 kg, μk = 0.5 Find: (a) kinetic friction force fkx ;(b)work done by friction W for stopping a car;(c)stopping distance d ;(d)stopping time T;(e) friction power P at x=0 and at x=d/2;(f) stopping distance d’ if v0’ = 2v0 .
2 /2 , P(x=d/2) = P(x=0)/21/2 = -μkmgv0 /21/2 .(f) According to (c), d depends quadratically on v0 → d’ = (2v0)2/(2μkg) = 4d
Exam Example 14: Swing (example 6.8)Find the work done by each force if(a) F supports quasi-equilibrium or(b) F = const ,as well as the final kinetic energy K.
Solution:
(a) Σ Fx = 0 → F = T sinθ , Σ Fy = 0 → T cosθ = w = mg , hence, F = w tanθ ; K = 0 since v=0 .