A Purple Block about (mA = 24 kg) glides along a rail, it starts at point 1 with a height H1 = 5.40 m). (Entire rail is frictionless) and before entering a loop the (radius R = 1.80 m). Three more points 2, 3, and 4 are all marked on the sides as well as on the top of these loops. The purple block then comes out of the loop while travelling at a speed of 12 m/s. Has a t-bone collision with the blue block which is mB = 8 kg with a speed of 6 m/s before the collision happens. After the accident, purple block's speed is 5.30 m/s and is still moving in the same direction it was before the collision. (see picture) A)What kind of collision is this?For the purple block: (parts a-b)a.) speed of block have at point 1?v1 = _____ m/sb.) At point 2, speed of the block:v2 = _____ m/sthe force acting on the block not to closely to the circle:______ N, with the motion, against the motion, it is zero force acting on the block, radial to the circle:______ N, toward the center of the loop, away from the center of the loop, it is zero (total) acceleration of the block:A = ______ m/s2, ______o to the block's velocityc.) speed of blue block right after the collision?_______m/s The image depicts a physics diagram illustrating the motion of an object along a track with a loop. 1. **Track Description:** - The track begins with a steep descent, from a height labeled \( H_1 \). - It transitions into a flat section before entering a loop of radius \( R \). - After the loop, the track straightens out, leading to a block labeled \( B \).2. **Objects in the Diagram:** - A small object, labeled \( A \), is positioned at the top of the track. - A second object, a movable block, is shown on the flat section, with arrows indicating possible movement towards or away from point \( B \).3. **Loop Structure:** - The loop is a circular section of the track, annotated with numbers around its perimeter: \( 3 \) at the top and \( 4 \) at the bottom.This setup is typical for analyzing energy conservation, with potential energy at \( H_1 \) converting to kinetic energy as the object moves along the track, as well as centrifugal forces acting on the object within the loop. The dynamics of the blocks, including potential collisions or interactions, can also be analyzed based on the given setup.

Given: The mass of the purple block is 24 kg. The height of the block1 is 5.40 m. The radius of the…

A Purple Block about (mA = 24 kg) glides along a rail, it starts at point 1 with a height H1 = 5.40 m). (Entire rail is frictionless) and before entering a loop the (radius R = 1.80 m). Three more points 2, 3, and 4 are all marked on the sides as well as on the top of these loops. The purple block then comes out of the loop while travelling at a speed of 12 m/s. Has a t-bone collision with the blue block which is mB = 8 kg with a speed of 6 m/s before the collision happens. After the accident, purple block's speed is 5.30 m/s and is still moving in the same direction it was before the collision. (see picture)

A Purple Block about (mA = 24 kg) glides along a rail, it starts at point 1 with a height H1 = 5.40 m). (Entire rail is frictionless) and before entering a loop the (radius R = 1.80 m). Three more points 2, 3, and 4 are all marked on the sides as well as on the top of these loops. The purple block then comes out of the loop while travelling at a speed of 12 m/s. Has a t-bone collision with the blue block which is mB = 8 kg with a speed of 6 m/s before the collision happens. After the accident, purple block's speed is 5.30 m/s and is still moving in the same direction it was before the collision. (see picture)

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