I have no idea how to start this problem how do I do it. те 3D 19000 kgvo = 64 m/sx = 3 metersh = 47 metersHk = 0.620 = 33.1 degreesL = 10.8 metersWWhat is the total work done on the system?Click here for a hintWłot= 101787.94 N*mUgEtКЕF You are designing a runaway truck ramp for Interstate 70 near Dillon. The setup is shown below.spring.gravelThe hill is covered in gravel so that the truck's wheels will slide up the hill instead of rolling up the hill. The coefficient of kinetic frictionbetween the tires and the gravel is lk. This design has a spring at the top of the ramp that will help to stop the trucks. This spring islocated at height h. The spring will compress until the truck stops, and then a latch will keep the spring from decompressing (stretchingback out). The spring can compress a maximum distance x because of the latching mechanism. Your job is to determine how strong thespring must be. In other words, you need to find the spring constant so that a truck of mass mt, moving at an initial speed of vo, will bestopped. For this problem, it is easiest to define the system such that it contains everything: Earth, hill, truck, gravel, spring, etc. In all ofthe following questions, the initial configuration is the truck moving with a speed of vo on the level ground, and the final configuration isthe truck stopped on the hill with the spring compressed by an amount x. The truck is still in contact with the spring. *Solve all of thequestions algebraically first. Then use the following values to get a number for the desired answer.*

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Description: I have no idea how to start this problem how do I do it. те 3D 19000 kgvo = 64 m/sx = 3 metersh = 47 metersHk = 0.620 = 33.1 degreesL = 10.8 metersWWhat is the total work done on the system?Click here for a hintWłot= 101787.94 N*mUgEtКЕF You are desi

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m = 19000 kg vo = 64 m/s x = 3 meters h = 47 meters Hk = 0.62 0 = 33.1 degrees L = 10.8 meters What is the total work done on the system? Click here for a hint ............................. Wtot= 101787.94 N*m Ug Et KE k

m = 19000 kg vo = 64 m/s x = 3 meters h = 47 meters Hk = 0.62 0 = 33.1 degrees L = 10.8 meters What is the total work done on the system? Click here for a hint ............................. Wtot= 101787.94 N*m Ug Et KE k

Physics for Scientists and Engineers, Technology Update (No access codes included)

9th Edition

ISBN:9781305116399

Author:Raymond A. Serway, John W. Jewett

Publisher:Raymond A. Serway, John W. Jewett

Chapter8: Conservation Of Energy

Section: Chapter Questions

Problem 8.3CQ

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I have no idea how to start this problem how do I do it.

те 3D 19000 kg
vo = 64 m/s
x = 3 meters
h = 47 meters
Hk = 0.62
0 = 33.1 degrees
L = 10.8 meters
W
What is the total work done on the system?
Click here for a hint
Włot= 101787.94 N*m
Ug
Et
КЕ
F

You are designing a runaway truck ramp for Interstate 70 near Dillon. The setup is shown below.
spring.
gravel
The hill is covered in gravel so that the truck's wheels will slide up the hill instead of rolling up the hill. The coefficient of kinetic friction
between the tires and the gravel is lk. This design has a spring at the top of the ramp that will help to stop the trucks. This spring is
located at height h. The spring will compress until the truck stops, and then a latch will keep the spring from decompressing (stretching
back out). The spring can compress a maximum distance x because of the latching mechanism. Your job is to determine how strong the
spring must be. In other words, you need to find the spring constant so that a truck of mass mt, moving at an initial speed of vo, will be
stopped. For this problem, it is easiest to define the system such that it contains everything: Earth, hill, truck, gravel, spring, etc. In all of
the following questions, the initial configuration is the truck moving with a speed of vo on the level ground, and the final configuration is
the truck stopped on the hill with the spring compressed by an amount x. The truck is still in contact with the spring. *Solve all of the
questions algebraically first. Then use the following values to get a number for the desired answer.*

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