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∙ 11y agomaybe if you spin the spring washer and its shortened the washer move is verry fast.
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∙ 11y agoWhen you shorten the string while a washer is whirling, the velocity of the washer will increase. This is because the radius of the circle that the washer is moving in becomes smaller, which results in a shorter distance for the washer to travel in the same amount of time, increasing its velocity.
The ball will move in a straight line tangent to the circle it was previously following due to inertia. It will continue moving until acted upon by another force.
When a string is shortened, the frequency of the note produced increases. This is because shortening the string increases the tension and decreases the vibrating length, causing the frequency to increase in order to maintain the same pitch.
The ball will follow a tangent to its circular path due to its inertia, flying off in a straight line rather than falling vertically. This is because of its angular momentum, which causes it to maintain velocity in a straight line until acted upon by another force.
Four times greater. The force on the string is determined by the centripetal force required to keep the ball moving in a circular path, which is proportional to the square of the velocity. Doubling the velocity will result in four times the centripetal force.
A wave is propagating along the string that has a length of 2 m and is under a tension of 48 (a)Determine the velocity of the wave along the string (c)The mass of the string N. The displacement of the string is given by S(y,t) = 0.024sin(0.6y –7t) (b)The wavelength of the wave (d)The power carried by t
If you shorten a string, the pitch of the sound produced will increase. This is because shortening the string decreases the vibrating length, which results in a higher frequency and thus a higher pitch.
The ball will move in a straight line tangent to the circle it was previously following due to inertia. It will continue moving until acted upon by another force.
When a string is shortened, the frequency of the note produced increases. This is because shortening the string increases the tension and decreases the vibrating length, causing the frequency to increase in order to maintain the same pitch.
In a stationary wave on a string, the phase velocity represents the speed at which a specific point on the wave oscillates up and down. On the other hand, the group velocity is the speed at which the overall shape or envelope of the wave propagates or moves along the string.
The ball will follow a tangent to its circular path due to its inertia, flying off in a straight line rather than falling vertically. This is because of its angular momentum, which causes it to maintain velocity in a straight line until acted upon by another force.
It will change how the poo smells, poo plays a very important part in string instruments so be careful how much you change it! Understand?
I believe you meant that you had an object on a string that revolved around an axis at a constant velocity. If that is the case, under friction free conditions, when the string snaps, it's velocity would not change, only its direction of movement. The centripetal force that was keeping the mass revolving around the axis would converted into centrifugal force that would make it travel in a straight line away from the axis.
When we tie a stone to a string and whirl it, it moves in a circular path.If the velocity becomes too high then the stone changes to a mass of electrons.It starts radiating energy and ultimately falls in our hand.the energy emitted by the stone is given by E = hv.Where h is Plancks constant and v is the radial velocity of the stone.
The force of those objects' gravity and the gravity of the Sun pull on each other. The result is similar to whirling a ball tied to a string around and around yourself. The string is like the force of gravity.
Four times greater. The force on the string is determined by the centripetal force required to keep the ball moving in a circular path, which is proportional to the square of the velocity. Doubling the velocity will result in four times the centripetal force.
A wave is propagating along the string that has a length of 2 m and is under a tension of 48 (a)Determine the velocity of the wave along the string (c)The mass of the string N. The displacement of the string is given by S(y,t) = 0.024sin(0.6y –7t) (b)The wavelength of the wave (d)The power carried by t
The speed of sound in a stretched string is affected by the tension in the string and the linear density of the string material. A higher tension and lower linear density will result in a faster speed of sound in the string. Additionally, the length and thickness of the string can also impact the speed of sound.