In the frictionless horizontal plane, the first blocks with masses of m, 2m and 3m, respectively, have a velocity v and the other blocks connected to the spring are in rest. Spring force is not impulsive. Since the spring coefficient is k and the collision coefficient is e, a) How long will the spring be (or shorten)? b) What is the smallest value of the kinetic energy of the system? Hint: The equations can be set up with respect to the moving axis whose origin is at the center of mass of the blocks connected to the spring. m v 2m k 3m

In the frictionless horizontal plane, the first blocks with masses of m, 2m and 3m, respectively, have a velocity v and the other blocks connected to the spring are in rest. Spring force is not impulsive. Since the spring coefficient is k and the collision coefficient is e, a) How long will the spring be (or shorten)? b) What is the smallest value of the kinetic energy of the system? Hint: The equations can be set up with respect to the moving axis whose origin is at the center of mass of the blocks connected to the spring. m v 2m k 3m

Name: In the frictionless horizontal plane, the first blocks with masses of
Uploaded: 2024-03-20T06:57:16.000Z
Channel: Bartleby
Description: In the frictionless horizontal plane, the first blocks with masses of m, 2m and3m, respectively, have a velocity v and the other blocks connected to the springare in rest. Spring force is not impulsive. Since the spring coefficient is k and thecolli

College Physics

11th Edition

ISBN:9781305952300

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter1: Units, Trigonometry. And Vectors

Section: Chapter Questions

Problem 1CQ: Estimate the order of magnitude of the length, in meters, of each of the following; (a) a mouse, (b)...

See similar textbooks

Related questions

Q: height ℎ, with negligible friction. At the bottom, where it is moving horizontally, it collides with…

A: a) First, we need to calculate the speed v1 of the crate of mass m1 at the bottom of the hill using…

Q: The spring connects two objects. In this case, it's the object that moves and accelerates, and the…

Q: Understand what is physically happening with the spring -- the ideal version, and differences from…

A: When a spring is stretched or pulled a force is exerted by the spring which is proportional to the…

Q: A 5 kg block falls from rest down a 7 m high frictionless hill. It collides with a stationary 2 kg a…

Q: A box of mass m is pressed against (but is not attached to) an ideal spring of force constant k and…

Q: On a frictionless horizontal table, two blocks (A of mass 2.00 kg and Bof mass 3.00 kg) are pressed…

A: In the question given two blocks are are initially at rest and they are pressed together here the…

Q: crate of mass m1 slides down a well-lubricated hill of height h, with negligible friction. At the…

Q: Shown in the figure below is a block and track system. All locations indicated by solid black lines…

Q: Suppose a spring (with a spring constant of 600 N/m) is compressed 0.4 m. If a projectile of mass…

A: GivenSpring constant, K=600 N/mSpring compressed to distance, d=0.4 mMass of projectile, m=0.05 kg

Q: A 45 kg gymnast is bouncing on a trampoline. Model the gymnast as a particle and the trampoline as a…

A: given that,k=15000 NmA=30cm=0.3 mm=45 kgg=9.8ms2

Q: a block with a mass m is initially at rest at the top of the incline plane which has a height of…

A: Sin = Height/length of inclineLength of incline = Therefore length of the inclined is L = 19.589…

Q: A 2.0 kg mass is placed against a spring of force constant 800 N/m, which has been compressed 0.22…

Q: A 1500 kg rocket has a net propulsion force of 500 n. Over short period of time, the rocket speed up…

Q: ds and collides with the block on the table vith nd Relative Velocity Equations to develop your fter…

A: Given:mass, m1 = 3 kg m2 = 1 kgInitial velocity, u1 = 0

Q: Shown in the figure below is a block and track system. All locations indicated by solid black lines…

Q: A block of mass m1=2.4kg is connected to a second block of mass m2=1.8kg. When the blocks are…

A: Given information:m1 =2.4kgm2 =1.8kgdistance moved by the masses, d = 0.5 mkinetic friction between…

Q: A pendulum of mass m and length L is initially at rest at an angle 8. The pendulum then swings down…

Q: Block A in (Figure 1) has mass 0.800 kg, and block B has mass 2.85 kg. The blocks are forced…

Q: In the ballistic pendulum shown below, the block has a mass of 1.7 kg, the bullet has a mass of…

Q: 7.39 A block with mass 0.50 kg is forced against a horizontal spring of negligible mass, compressing…

A: First we need to find work done due to friction

Q: if k = 29 N/cm, ℓ = 9 cm, and x = 12 cm, calculate the force (in Newtons) on the object, including…

A: The force exerted by the spring on the object is proportional to the displacement (compression or…

Q: 2M Two blocks, of masses M = 4.0 kg and 2M, are connected to a spring of spring constant k = 150 N/m…

Q: On the axes below, make a sketch of the kinetic energy (K), and elastic po tial energy (elastic) of…

A: Given, to us is a spring mass system. The smaller mass m collides with the mass M with a velocity…

Concept explainers

Kinematics

A machine is a device that accepts energy in some available form and utilizes it to do a type of work. Energy, work, or power has to be transferred from one mechanical part to another to run a machine. While the transfer of energy between two machine parts, those two parts experience a relative motion with each other. Studying such relative motions is termed kinematics.

Kinetic Energy and Work-Energy Theorem

In physics, work is the product of the net force in direction of the displacement and the magnitude of this displacement or it can also be defined as the energy transfer of an object when it is moved for a distance due to the forces acting on it in the direction of displacement and perpendicular to the displacement which is called the normal force. Energy is the capacity of any object doing work. The SI unit of work is joule and energy is Joule. This principle follows the second law of Newton's law of motion where the net force causes the acceleration of an object. The force of gravity which is downward force and the normal force acting on an object which is perpendicular to the object are equal in magnitude but opposite to the direction, so while determining the net force, these two components cancel out. The net force is the horizontal component of the force and in our explanation, we consider everything as frictionless surface since friction should also be calculated while called the work-energy component of the object. The two most basics of energy classification are potential energy and kinetic energy. There are various kinds of kinetic energy like chemical, mechanical, thermal, nuclear, electrical, radiant energy, and so on. The work is done when there is a change in energy and it mainly depends on the application of force and movement of the object. Let us say how much work is needed to lift a 5kg ball 5m high. Work is mathematically represented as Force ×Displacement. So it will be 5kg times the gravitational constant on earth and the distance moved by the object. Wnet=Fnet times Displacement. 

Topic Video

Question

In the frictionless horizontal plane, the first blocks with masses of m, 2m and
3m, respectively, have a velocity v and the other blocks connected to the spring
are in rest. Spring force is not impulsive. Since the spring coefficient is k and the
collision coefficient is e,
a) How long will the spring be (or shorten)?
b) What is the smallest value of the kinetic energy of the system?
Hint: The equations can be set up with respect to the moving axis whose origin
is at the center of mass of the blocks connected to the spring.
m v
2m
k
3m

Expert Solution

This question has been solved!

Explore an expertly crafted, step-by-step solution for a thorough understanding of key concepts.

SEE SOLUTION Check out a sample Q&A here

Step 1

VIEW

Step 2

VIEW

Step 3

VIEW

Step by step

Solved in 3 steps

SEE SOLUTION Check out a sample Q&A here

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, physics and related others by exploring similar questions and additional content below.

Similar questions

A crate of mass m1 slides down a well-lubricated hill of height h, with negligible friction. At the bottom, where it is moving horizontally, it collides with another crate, of mass m2, that initially was sitting at rest and that is attached to a wall by a spring of spring constant k that initially is at its equilibrium length. Assume that the spring itself has negligible mass. a)Given that the distance d that the crates compress the spring is d=0.35 m, calculate the speed v2 of the crates immediately after the collision, in units of meters per second. Use the following values:k=950 N/mm1=2.4 kgm2=2.6 kgμ=0.49g=9.8 m/s2 b) What was the speed of the crate of mass m1 just before the collision with the second block, in meters per second? c)What is the height h of the hill, in meters?
Please asap
A superelastic collision is one in which kinetic energy before the collision equals kinetic energy after the collision. O kinetic energy after the collision is zero. kinetic energy before the collision is less than kinetic energy after the collision. kinetic energy before the collision is greater than kinetic energy after the collision.
Lab cart A has a mass of 2.5kg. Lab cart B has a mass of 1.8kg. Both cares are at rest on a horizontal surface. Between them is a spring, k=150N/m, compressed 15cm. The system is help at rest and then released. (a) How much energy is initially stored in the spring? (b) After being released from rest, what is the velocity of each of the lab carts?
On the axes below, make sketches of the kinetic energy (K), gravitational potential energy (Ugrav), and elastic potential energy (Uel) of the system on the y-axis as a function of the height of m2 on the x-axis, where the location y = 0 is defined as the point where mass m2 collides with the spring. Note that the start of the x-axis is height h, and the end of the x-axis is height -d. K h U grav 0 height of mass m₂ above the spring h PO -d 0 -d height of mass m₂ above the spring h 0 height of mass m₂ above the spring -d
In this question you will use an energy approach to determine how the mass of a spring affects its motion. Normally we assume the spring has zero mass. But if we realize real springs have mass we can find the contribution to the kinetic energy of the system due to the motion of the spring. What makes this hard is that different parts of the spring move at different velocities. So, we must use a little calculus to find the result.Consider a vertical spring of mass m that has a mass M attached at its end. Let the position of the mass at the end of the spring relative to the point of attachment be given by Y and its velocity be given by V. a) What is the velocity of a small segment of the spring at the point of attachment? b) What is the velocity of a small segment of the spring right next to the moving mass? c) What is the velocity of a small segment of the spring that is exactly halfway between the top and the bottom? d) Now let the mass of the spring be m and…
You have been asked to design a "ballistic spring system" to measure the speed of bullets. A bullet of mass m is fired into a block of mass M. The block, with the embedded bullet, then slides across a frictionless table and collides with a horizontal spring whose spring constant is k. The opposite end of the spring is anchored to a wall. The spring's maximum compression d is measured. What percentage of the bullet's energy is "lost"?
A crate of mass m1 slides down a well-lubricated hill of height h, with negligible friction. At the bottom, where it is moving horizontally, it collides with another crate, of mass m2, that initially was sitting at rest and that is attached to a wall by a spring of spring constant k that initially is at its equilibrium length. Assume that the spring itself has negligible mass. a)Given that the distance d that the crates compress the spring is d=0.35 m, calculate the speed v2 of the crates immediately after the collision, in units of meters per second. Use the following values:k=950 N/mm1=2.4 kgm2=2.6 kgμ=0.49g=9.8 m/s2 b)What was the speed of the crate of mass m1 just before the collision with the second block, in meters per second? c) What is the height h of the hill, in meters?
A crate of mass m1 slides down a well-lubricated hill of height h, with negligible friction. At the bottom, where it is moving horizontally, it collides with another crate, of mass m2, that initially was sitting at rest and that is attached to a wall by a spring of spring constant k that initially is at its equilibrium length. Assume that the spring itself has negligible mass. a)Given that the distance d that the crates compress the spring is d=0.35 m, calculate the speed v2 of the crates immediately after the collision, in units of meters per second. Use the following values:k=950 N/mm1=2.4 kgm2=2.6 kgμ=0.49g=9.8 m/s2 b) What was the speed of the crate of mass m1 just before the collision with the second block, in meters per second? c)What is the height h of the hill, in meters?
A Ballistic Spring is like a Ballistic Pendulum, but it uses elastic potential energy instead of gravitational potential energy to measure the incident velocity of a projectile. Questions 4 and 5 refer to the Ballistic Spring shown below, where a projectile of mass m travelling with an initial velocity v impacts and travels through a block with mass M, emerging with a velocity , and causing the spring with constant k that is attached to the block to be compressed a distance d. m Vo Before M wwwww M Wowwwww After
Two balls of mass m and M are attached by strings of length L. The two balls are initially at rest at an angle θ, and are then released. The balls undergo a totally inelastic collision at the bottom of their swings. Assume that m = 1.7kg, M = 2.8kg, L = 0.80m and θ = 67o.a) Calculate the speed of the balls immediately after the totally inelastic collision.b) To what maximum angle do the conjoined balls rise after the collision?
Ballistic pendulum: The height h can be found using conservation of mechanical energy after the object is embedded in the block. If a ballistic pendulum of mass 1.17 kg rose to a height of 0.12 m after being hit by a 11 g bullet, find the initial speed of the bullet at which it was shot. Ignore air resistance.