An automobile of mass m=1600kg travels at a speed of of 35 km/h. when the driver...
An automobile of mass m=1600kg travels at a speed of of 35 km/h. when the driver jams on the brakes, causing all four wheels to lock, the automobile skids to rest in 7m. determine the magnitude of the normal reactions and of the friction force at each wheel as the automobile skidded to rest. CG is 400mm from surface and 1200mm away from both wheels a and b.
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An automobile of mass m=1600kg travels at a speed of of 35 km/h.
when the driver...
A car of mass 875 kg is traveling 30.0 m/s when the driver applies the brakes,...
A car of mass 875 kg is traveling 30.0 m/s when the driver applies the brakes, which lock the wheels. The car skids for 5.60 s in the positive -direction before coming to rest. (a) What is the car's acceleration? (b) What magnitude force acted on the car during this time? (c) How far did the car travel? [Ans: ()-536 m/s (b) 4690 N(c) 84,0 m]
A car of mass 772 kg is traveling 24.4 m/s when the driver applies the brakes,...
A car of mass 772 kg is traveling 24.4 m/s when the driver applies the brakes, which lock the wheels. The car skids for 5.27 s in the positive x-direction before coming to rest. a). What is the car's acceleration (in m/s2)? (Indicate the direction with the sign of your answer.) b). What magnitude force (in N) acted on the car during this time? c). How far (in m) did the car travel?
Traveling at a speed of 16.7 m/s, the driver of an automobile suddenly locks the wheels...
Traveling at a speed of 16.7 m/s, the driver of an automobile suddenly locks the wheels by slamming on the brakes. The coefficient of kinetic friction between the tires and the road is 0.640. What is the speed of the automobile after 2.00 s have elapsed? Ignore the effects of air resistance. m/s
An automobile travels on a straight road for 35 km at 35 km/h. It then continues...
An automobile travels on a straight road for 35 km at 35 km/h. It then continues in the same direction for another 50 km at 55 km/h. (a)What is the average velocity(km/h) of the car during this 85km trip?(Assuming that it moves in the positive-x direction) (B)What is its average speed in m/s?
Learning Goal Part A-Time for the Car to Reach 100 km/h ? To apply the concepts...
Learning Goal Part A-Time for the Car to Reach 100 km/h ? To apply the concepts of impulse and momentum to problems involving unknown forces, velocities, and times. Find the time it will take for the car to reach u 100 km/h from rest. A new rear-wheel drive automobile design is being tested and you have been asked to estimate its performance. The car without wheels (i.e., the body) has a mass of mc 1450 kg. The wheels (including tires)...
A driver is traveling at a speed of 70 km/h in car A when he looks...
A driver is traveling at a speed of 70 km/h in car A when he looks down to text a friend that he is running late. Just before he looks down. he is 80 m from an intersection, and a bicydist B, traveling at a constant speed of 10m/s,s d= 40 m from that same intersection. The light turns red during the 3 s text, and when the driver looks up, he hits the brakes, causing a constant deceleration of...
QUESTION 3 The 1500-kg rear driving truck reaches a speed of 50 km/h from rest in...
QUESTION 3 The 1500-kg rear driving truck reaches a speed of 50 km/h from rest in a distance of 60 m up the 10-percent incline with constant acceleration. Calculate the normal force under each pair of wheels and the effective coefficient of friction between the tires and the road during this motion (Hints: the driving force from the friction of the rear wheels, not from front wheels). (20 marks) 600 mm 1500 mm 1500 mm 10
QUESTION 3 The 1500-kg...
A car traveling 54.7 km/h is 21.1 m from a barrier when the driver slams on...
A car traveling 54.7 km/h is 21.1 m from a barrier when the driver slams on the brakes. The car hits the barrier 2.15 s later. (a) What is the car's constant deceleration magnitude before impact? (b) How fast is the car traveling at impact?
A car traveling 52.4 km/h is 23.3 m from a barrier when the driver slams on...
A car traveling 52.4 km/h is 23.3 m from a barrier when the driver slams on the brakes. The car hits the barrier 1.76 s later. (a) What is the car's constant deceleration magnitude before impact? (b) How fast is the car traveling at impact?
The driver of a car of mass M which is moving along a straight road with...
The driver of a car of mass M which is moving along a straight road with initial speed v0 sees a deer in her headlights, and reacts quickly, lifting her foot of the gas and applying the brake pedal with maximum force. The anti-lock brakes cause the largest possible static friction force to be applied on the tires by the road, which continue to roll so the car does not skid. The coefficient of static friction between the tires and...
A car of mass 875 kg is traveling 30.0 m/s when the driver applies the brakes, which lock the wheels. The car skids for 5.60 s in the positive -direction before coming to rest. (a) What is the car's acceleration? (b) What magnitude force acted on the car during this time? (c) How far did the car travel? [Ans: ()-536 m/s (b) 4690 N(c) 84,0 m]
Learning Goal Part A-Time for the Car to Reach 100 km/h ? To apply the concepts of impulse and momentum to problems involving unknown forces, velocities, and times. Find the time it will take for the car to reach u 100 km/h from rest. A new rear-wheel drive automobile design is being tested and you have been asked to estimate its performance. The car without wheels (i.e., the body) has a mass of mc 1450 kg. The wheels (including tires)...
A driver is traveling at a speed of 70 km/h in car A when he looks down to text a friend that he is running late. Just before he looks down. he is 80 m from an intersection, and a bicydist B, traveling at a constant speed of 10m/s,s d= 40 m from that same intersection. The light turns red during the 3 s text, and when the driver looks up, he hits the brakes, causing a constant deceleration of...
QUESTION 3 The 1500-kg rear driving truck reaches a speed of 50 km/h from rest in a distance of 60 m up the 10-percent incline with constant acceleration. Calculate the normal force under each pair of wheels and the effective coefficient of friction between the tires and the road during this motion (Hints: the driving force from the friction of the rear wheels, not from front wheels). (20 marks) 600 mm 1500 mm 1500 mm 10
QUESTION 3 The 1500-kg...
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