Rubber Band Force Constant

If i assume that i could also rotate this one.

Rubber band force constant.

In this case the linear function fitting the straight part of the data gives a spring constant of 17 38 n m. Individual 4 carbon backbone units are forced into rotational conformations that have longer end to end distances and this restricts the number of conformations states that are thermally accessible. The rubber band that stretches the least for a given weight applied force has the greatest spring constant. The minus sign shows that this force is in the opposite direction of the force that s stretching or compressing the spring.

For example a thicker rubber band should have a larger spring constant due to its larger cross sectional area. When a rubber band is stretched some of the network chains are forced to become straight. For example if the pegs are placed such that the band is stretched to 52 inches the force the bands apply to the pegs are 57 6 lbs per inch. The sign is there because the force is taken to be positive as is the pressure but the force of the rubber band is in the opposite direction of the force on a piston pulling in instead of pushing out.

Yes and no rubber bands have a linear proportionality between the load and extension only till a certain limit is reached differs from the elastic limit of a spring for instance a 10 increase in stretching force will make a typical rubber band 10 longer however when rubber bands are stretched to twice their original size or more the. From the experiment i did my force was equal to 0 0686n 0 00196n and my x rubber band stretch was equal to 0 003m 0 002. A rubber band is a single molecule as is a latex glove. Say i have a rubber band wrapped around 2 pegs at a certain distance and at that distance i know the pounds of force per inch it is pulling at.

In this experiment you can check this prediction and investigate the way in which hooke s law applies to rubber bands. The rotational spring constant for this thicker band is not surprisingly higher than the normal sized rubber band with a value of 4 92 x 10 4 n m. The variables of the equation are. F which represents force k which is called the spring constant and measures how stiff and strong the spring is and x is the distance the spring is stretched or compressed away from its equilibrium or rest position.

H e pv fd è q w pv fd if we heat the rubber band with a weight attached the force f is constant but the band contracts.