Difference between revisions of "Friction Block"

From UO Physics Demonstration Catalog

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{{NewDemo|subject=Mechanics|topic=Newton's Laws|file1=Friction_Blocks.gif}}
{{NewDemo|subject=Mechanics|topic=Newton's Laws|file1=Friction_Blocks.gif}}


Place masses on a wooden block and pull the block with a spring scale. A larger force is needed to get the block moving (static vs. kinetic friction). Add mass to show friction is dependant on the normal force. One block the center is hollowed out to show that friction is independent of contact surface area. Blocks with foam rubber and a rubber sheet are available to vary the coefficient of static friction.
Place masses on a wooden block and pull the block with a spring scale (or Force Probe connected to computer to plot Force vs Time). A larger force is needed to get the block moving (static vs. kinetic friction). Add mass to show friction is dependent on the normal force. One block the center is hollowed out to show that friction is independent of contact surface area. Blocks with foam rubber and a rubber sheet are available to vary the coefficient of static friction. Using the computer and Force Probe dramatically shows the difference between Static and Kinetic friction.


'''Location:'''
'''Location:'''

Revision as of 16:08, 20 April 2022

Return to Newton's Laws

Friction Blocks.gif

Description:

Place masses on a wooden block and pull the block with a spring scale (or Force Probe connected to computer to plot Force vs Time). A larger force is needed to get the block moving (static vs. kinetic friction). Add mass to show friction is dependent on the normal force. One block the center is hollowed out to show that friction is independent of contact surface area. Blocks with foam rubber and a rubber sheet are available to vary the coefficient of static friction. Using the computer and Force Probe dramatically shows the difference between Static and Kinetic friction.

Location:

  • Blocks: Dr. 4
  • Masses: Sh. A-4
  • Spring Scales: Dr. 10