over 9,000.
The value of the spring constant ''k'' in a spring-mass system would remain constant regardless of the mass of the trapped gas, as it only depends on the stiffness of the spring and not on the mass attached to it.
To predict how many centimeters the spring will stretch, we need to know the spring constant in N/cm and apply Hooke's Law. Hooke's Law states that the force exerted by a spring is directly proportional to its extension. By knowing the spring constant and the total mass attached, we can calculate the stretch.
K, also known as the spring constant, is determined experimentally by measuring the force applied to a spring and the resulting displacement. The formula to calculate K is K = F / x, where F is the force applied and x is the displacement. By plotting the force-displacement data and calculating the slope of the line, the spring constant can be determined.
Slinky seismology is a simple and educational experiment where a slinky toy is used to simulate and demonstrate how seismic waves travel through different materials. By shaking one end of the slinky, users can observe how the energy is transferred through the coils, similar to how seismic waves move through the Earth's crust.
A popular toy used to demonstrate seismic waves is the Slinky toy. By holding one end of the Slinky and shaking it back and forth, you can create a visual representation of how seismic waves travel through the Earth. The coils of the Slinky demonstrate the movement of energy waves, similar to how seismic waves move through the Earth.
Yes, a slinky is a type of spring. Specifically, it is a helical spring, made of coiled wire that can stretch and compress in a wave-like motion.
The slinky toy is a spring. As you move it up and down the coils in the spring will cause it to become longer, then shorter.
A slinky is made of metal or plastic and functions as a mechanical toy that moves in a spring-like manner when pushed or pulled.
The "Slinky" was voted as one of the top one hundred toy inventions by members of the toy Industry . "What walks down stairs, alone or in pairs, and makes a slinkity sound? A spring, a spring, a marvelous thing! Everyone knows it's Slinky. It's Slinky, it's Slinky. For fun it's a wonderful toy. It's Slinky, it's Slinky. It's fun for a girl or a boy. It's fun for a girl or a boy !"
The slinky was invented by Richard James in 1943. He came up with the idea when he accidentally knocked over a tension spring and saw how it moved in a slinking manner. James then developed the slinky toy using this property of the spring.
The slinky was invented by Richard James in 1945 when he accidentally knocked over a coiled spring and saw how it "walked" down some books. Recognizing its potential as a toy, he and his wife Betty developed the idea further and introduced the slinky to the market.
To remove a kink from a slinky spring, gently stretch the spring and work the kink out by hand. Be patient and carefully straighten the affected area to restore the spring's shape. Avoid pulling too forcefully to prevent damaging the spring.
A slinky can have both potential energy when it is stretched or compressed due to its elasticity, and kinetic energy when it is moving. The potential energy arises from the deformation of the slinky, while the kinetic energy is related to its motion.
no the spring constant is not constant on moon because there is no restoring force there
Richard James invented the slinky accidentally while working on springs for naval equipment during World War II. He noticed how a spring fell off a shelf and "walked" down instead of toppling over, inspiring the idea for the slinky toy.
As you move a slinky toy up and then release it, the coils compress together due to gravity, causing the slinky to contract and move downward in a spring-like motion. The slinky will continue to bounce and oscillate until the internal energy dissipates.
If the length of the spring is halved, the spring constant remains the same. The spring constant is determined by the material and shape of the spring, and is not affected by changes in length.