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Robot Physics: Part 1

Robot Physics: Part 1. By: Danica Chang and Pavan Datta Team 115. Topics:. Velocity Acceleration Force Friction/Traction Work Power Torque. Δ D istance Time. Velocity. Velocity is how fast an object is moving (in a certain direction) Speed is just how fast an object is moving

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Robot Physics: Part 1

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  1. Robot Physics: Part 1 By: Danica Chang and Pavan Datta Team 115

  2. Topics: • Velocity • Acceleration • Force • Friction/Traction • Work • Power • Torque

  3. Δ Distance Time Velocity • Velocity is how fast an object is moving (in a certain direction) • Speed is just how fast an object is moving • Average Velocity =

  4. Acceleration • Acceleration is the change in velocity over time (in a certain direction) • Average Acceleration = Δ Velocity Time • Gravitational Acceleration = 32.19ft/s2 • If at 12:00PM you are traveling North in a car at 50mph and at 12:01PM you are still traveling North, but this time at 70mph then what is your acceleration? Average acceleration = vfinal – vinitial = Time 70m/h – 50m/h 1/60 h = Average acceleration = 1200mile/h2 *Note: The reason hours is in the denominator and not minutes is keep the units consistent. In maintaining consistency of unit, minutes must be converted to hours

  5. Force and Power • Force is how hard something is pushing or being pushed • Force = Mass x Acceleration • Gravitational Acceleration Constant = 31.58m/s2 • Power is the rate at which work is done • Mechanical Power = Speed X Force

  6. Fgravity = mg = 100lbs (32.19ft/s2) = 3219 lb*ft/sec 100 lbs (mass) Fnormal = 3219 lb*ft/sec Types of Forces Normal Force: a force exerted by one object on another in a direction perpendicular to the surface of contact . Gravitational Force Normal Force Gravitational Force: a force exerted by by the earth on an object, which is equal to mass times gravitational acceleration.

  7. Friction Force and Traction • Traction is the amount of force an object can transmit to a surface, the force before the wheels slip. • Friction Force = μ X Normal Force • Normal Force (Fn): weight of object (unless on a sloped surface) • Coefficient of Friction (μ): how much 2 surfaces resist sliding. (μ is pronounced mu)

  8. Fgravity = mg = 100lbs (32.19ft/s2) = 3219 lb*ft/sec Force ( 10 lb*ft/sec) 100 lbs (mass) Friction Force Ffriction= μ x Fn Fnormal = 3219 lb*ft/sec Types of Forces Frictional Force: a resistive force that opposes the relative motion of two contacting surfaces (that are either moving past each other, or at rest with respect to each other) • Friction Force = Friction Coefficient x Normal Force • F = μ x FN • μstatic = .4 • μkinetic = .3 *Note: Friction force is independent of the amount of surface area. • it depends on Coefficient of • Friction (μ) and Normal Force • - Simplifies to:  it depends on the type of Surface and Mass of object

  9. Friction Example • You push a box across a carpet floor. If the box weighs 20 kg and the force required to push is 10 N, what is the friction coefficient? Force = μ X weight 10 N = μ X 20 kg μ = .5

  10. Work • Work = Force X Distance • Example 2: A box weighs 130 lbs and must be moved 10 ft. The coefficient of friction between the floor and the box is .5 . How much work must be done?? 130 lbs μ =.5 10 ft

  11. 10 ft Work Force = μ X weight = .5*130 Force = 65 lbs so… Work = Force * Distance Work = 65 * 10 = 650 ft lbs 130 lbs W=650 ft lbs μ =.5

  12. Work 8 lbs Example 3: The arm weighs 10 lbs and moves 3 ft vertically. The mechanism that contains the balls weighs 5 lbs. The balls weigh 3 lbs. The mechanism and balls move 6 ft vertically. How much work was done in total? 6ft Work = F1 X D1 + F2 X D2 = 10 lbs X 3 ft + 8 lbs X 6 ft = 30 + 48 = 78 ft lbs 3 ft

  13. Distance Torque • Torque is a measure of rotational force • Torque = Force X Distance • Distance is measured from the force to the point of rotation. Center of Gravity is where the force of gravity is motor Force = weight

  14. Torque vs. Speed • Power = Torque X Angular Velocity • Torque is a force (rotational force) • Angular Velocity is rotational speed • There is only a certain amount of power available. • This means: • If there is lots of Torque (strong), it has lower velocity (slow) • If it is has high velocity(really fast), it has less Torque (weak) • Try and have a good balance of speed and torque

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