Actions

Types of Motion

From DT Online

Revision as of 08:44, 8 July 2017 by DT Online (talk | contribs)
(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)
Linear Motion
  • Linear Motion is simply motion in a straight line. A measurement of speed will provide its magnitude (i.e. how fast) but the term velocity gives both speed and direction (i.e. it is a vector quantity)
LinearMotionArrow.png
Rotational Motion
  • Rotational Motion is motion around the circumference of a circle - like the drum of a tumbler dryer or washing machine. Rotational speed is normally measured in revolutions per minute (i.e. rpm) but Angular Velocity is usually measured in Radians per Second (a complete revolution = 2π radians).
RotationalMotionArrow.png
Reciprocating Motion
  • Reciprocating Motion is continuous linear motion and reversing in a straight line (e.g. as the motion of a piston in a Crank and Slider mechanism).
ReciprocatingMotionArrow.png
Oscillating Motion
  • Oscillating Motion is like the motion of a swing or pendulum swinging from side to side. The ends of levers exhibit Oscillating Motion and this arc of movement has to be allowed for in the design of Linkages otherwise the mechanism may jam or sieze.


  • James Watt overcame this problem by inventing a Parallel Motion linkage for use in his early steam engines. This enabled the swinging end of a pivoted beam connect to the straight up and down motion of the piston rod
OscillatingMotionArrow.png

Linear and Rotational Motions may maintain a constant speed, or velocity, or may accelerate and slow down (i.e. decelerate or retard). Both Reciprocating and Oscillating Motions however, by their nature, must accelerate and decelerate during each cycle of operation (i.e. as the movement reverses). The pattern of acceleration (or deceleration) may exhibit different characteristics according to design requirements as follows:


Constant Velocity (CV)
  • Constant Velocity occurs when a moving object continues to cover the same distance in equal periods of time - a metre in every second of time (ms−1 in the SI metric system) or a mile every hour (mph) for example.
  • Constant Velocity is represented on a graph of distance against time, in a Displacement Diagram for example, by a straight sloping line
CV.png
Uniform Acceleration and Retardation (UAR)
  • Uniform Acceleration and Retardation describes the movement of a ball thrown in the air for example. This motion is repesented by a parabola on the graph.
UAR.png
Simple Harmonic Motion (SHM)
  • Simple Harmonic Motion is defined as the projection of a point on the diameter as it moves around a circle with uniform angular velocity.
  • It is the motion of a pendulum or bouncing spring and provides a very smooth transition between acceleration and retardation.
  • Simple Harmonic Motion is plotted on the graph using a Sine Curve.
SHM.png