In a physics lab experiment, a compressed spring launches a 37 g metal ball at a...
In a physics lab experiment, a compressed spring launches a 37 g metal ball at a 35° angle. Compressing the spring 20 cm causes the ball to hit the floor 1.5 m below the point at which it leaves the spring after traveling 5.7 m horizontally. Part A What is the spring constant? Express your answer to two significant figures and include the appropriate units. k= Value Units Submit Request Answer
Item 12 In a physics lab experiment, a compressed spring launches a 23 g metal ball at a 35° angle. Compressing the spring 20 cm causes the ball to hit the floor 2.0 m below the point at which it leaves the spring after traveling 5.2 m horizontally. Part A What is the spring constant? Express your answer to two significant figures and include the appropriate units. 'I HÅR 2 ? -- | Value Submit Previous Answers Request Answer
In a physics lab experiment, a compressed spring launches a 29 g metal ball at a 35 ∘ angle. Compressing the spring 18 cm causes the ball to hit the floor 1.8 m below the point at which it leaves the spring after traveling 5.4 m horizontally. What is the spring constant?
In a physics lab experiment, a spring clamped to the table shoots a 22 g ball horizontally, 1.7 m above the floor. When the spring is compressed 18 cm , the ball hits the ground going 14.5 m/s . Ignore friction and air resistance in all calculations. What is the spring constant?
Review Part A In one contest at the county fair, a spring-loaded plunger launches a ball at a speed of 3.2 m/s from one corner of a smooth, flat board that is tilted up at a 20° angle. To win, you must make the ball hit a small target at the adjacent corner, 2.20 m away. (Figure 1) At what angle launcher? should you tilt the ball Express your answer with the appropriate units. IA Value Units Figure 1 of...
ReviewI Constants Part A A 200 g ball attached to a spring with spring constant 2.40 N/m oscillates horizontally on a frictionless table. Its velocity is 22.0 cm/s when What is the amplitude of oscillation'? Express your answer to three significant figures and include the appropriate units. -5.00 cm. A: cm Submit Request Answer Part B What is the speed of the ball when 3.00 cm? Express your answer to three significant figures and include the appropriate units. Submit Request...
A ball of mass m is pushed out by a compressed spring of spring constant k. Both the ball and the spring are on a table (see the diagram below). The other end of the spring is fixed to the table, and the spring is initially compressed by x. The ball moves toward a wedge at the edge of the table and then launches off the wedge and falls on the ground. The heights of the table and the wedge...
Please answer part 1 and 2 carefully. Again, please and thank you Part 1: The spring in the figure has a spring constant of 1000 N/m . It is compressed 15.0 cm , then launches a 200 g block. The horizontal surface is frictionless, but the block's coefficient of kinetic friction on the incline is 0.180. (Figure 1) What distance d does the block sail through the air? Express your answer with the appropriate units. --------------------------- Part 2: A 190...
A vertical spring Oignore its mass), whose spring constant is 825 N/m, is attached to a table and is compressed down by 0.160 m Part A What upward speed can it give to a 0.360-kg ball when released? Express your answer to three significant figures and include the appropriate units. Value Units Submit Request Answer Part B How high above its original position (spring compressed) will the ball ? Express your answer to three significant figures and include the appropriate...
The spring in the figure has a spring constant of 1000 N/m. It is compressed 13.0 cm, then launches a 200 g block. The horizontal surface is frictionless, but the block's coefficient of kinetic friction on the incline is 0.210. (Figure 1) - Part A What distance d does the block sail through the air? Express your answer with the appropriate units. C: A 0 = ? Value Units Submit Request Answer Figure 1 of 1 > < Return to...