A non-rotating space station in the shape of a long thin uniform rod of mass 5.31 x 10^6 kg and length 1218 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 7.92 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 2 minutes and 26 seconds before shutting off, then how fast will the station be rotating when the engines stop? A) 2.05 rpm B) 1.03 rpm C) 3.28 rpm D) 4.59 rpm

A non-rotating space station in the shape of a long thin uniform rod of mass 5.31 x 10^6 kg and length 1218 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 7.92 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 2 minutes and 26 seconds before shutting off, then how fast will the station be rotating when the engines stop? A) 2.05 rpm B) 1.03 rpm C) 3.28 rpm D) 4.59 rpm

Physics for Scientists and Engineers: Foundations and Connections

1st Edition

ISBN:9781133939146

Author:Katz, Debora M.

Publisher:Katz, Debora M.

Chapter13: Rotation Ii: A Conservation Approach

Section: Chapter Questions

Problem 45PQ: A thin rod of length 2.65 m and mass 13.7 kg is rotated at anangular speed of 3.89 rad/s around an...

See similar textbooks

Similar questions

A thin rod of length 2.65 m and mass 13.7 kg is rotated at anangular speed of 3.89 rad/s around an axis perpendicular to therod and through its center of mass. Find the magnitude of therods angular momentum.
Consider a non-rotating space station in the shape of a long thin uniform rod of mass 9.84 x 10^6 kg and length 1286 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 4.77 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 2 minutes and 49 seconds before shutting off, then how fast will the station be rotating when the engines stop? 0.73 rpm 0.29 rpm 0.88 rpm 1.32 rpm
This time we have a non-rotating space station in the shape of a long thin uniform rod of mass 8.92 x 10^6 kg and length 867 meters. Small probes of mass 7618 kg are periodically launched in pairs from two points on the rod-shaped part of the station as shown, launching at a speed of 3581 m/s with respect to the launch points, which are each located 296 m from the center of the rod. After 17 pairs of probes have launched, how fast will the station be spinning? 2.35 rpm 6.10 rpm 1.88 rpm 4.69 rpm
QUESTION 6 Consider a non-rotating space station in the shape of a long thin uniform rod of mass 2.87 x 10^6 kg and length 1118 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 5.93 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 1 minutes and 23 seconds before shutting off, then how fast will the station be rotating when the engines stop? 0.88 rpm 2.82 rpm 3.38 rpm 1.76 rpm
This time we have a non-rotating space station in the shape of a long thin uniform rod of mass 1.79 x 10^6 kg and length 1323 meters. Small probes of mass 5796 kg are periodically launched in pairs from two points on the rod-shaped part of the station as shown, launching at a speed of 2268 m/s with respect to the launch points, which are each located 453 m from the center of the rod. After 17 pairs of probes have launched, how fast will the station be spinning?
QUESTION 6 Consider a non-rotating space station in the shape of a long thin uniform rod of mass 5.42 x 10^6 kg and length 516 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 5.46 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 1 minutes and 17 seconds before shutting off, then how fast will the station be rotating when the engines stop? A 3.30 rpm B 1.72 rpm C 1.38 rpm D 2.75 rpm
Consider a non-rotating space station in the shape of a long thin uniform rod of mass 8.82 x 10^6 kg and length 1357 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 4.55 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 2 minutes and 13 seconds before shutting off, then how fast will the station be rotating when the engines stop? a. 0.29 rpm b. 0.75 rpm c. 1.05 rpm d. 0.58 rpm
This time we have a non-rotating space station in the shape of a long thin uniform rod of mass 3.21 x 10^6 kg and length 1116 meters. Small probes of mass 6342 kg are periodically launched in pairs from two points on the rod-shaped part of the station as shown, launching at a speed of 2853 m/s with respect to the launch points, which are each located 370 m from the center of the rod. After 16 pairs of probes have launched, how fast will the station be spinning? a. 2.58 rpm b. 6.14 rpm c. 3.68 rpm d.8.60 rpm
We have a non-rotating space station in the shape of a long thin uniform rod of mass 2.60 x 10^6 kg and length 769 meters. Small probes of mass 8303 kg are periodically launched in pairs from two points on the rod-shaped part of the station as shown, launching at a speed of 2888 m/s with respect to the launch points, which are each located 196 m from the center of the rod. After 11 pairs of probes have launched, how fast will the station be spinning? 3.70 rpm 7.71 rpm 4.63 rpm 10.02 rpm
Consider a non-rotating space station in the shape of a long thin uniform rod of mass 6.07 x 10^6 kg and length 613 meters. Rocket motors on both ends of the rod are ignited, applying a constant force of F = 1.79 x 10^5 N to each end of the rod as shown in the diagram, causing the station to rotate about its center. If the motors are left running for 2 minutes and 39 seconds before shutting off, then how fast will the station be rotating when the engines stop?
What is the angular momentum of a 0.25 kg mass rotating on the end of a piece of rope in a circle of radius 0.75m at an angular speed of 12.5 rad/s?
Three children are riding on the edge of a merry-go-round that is a disk of mass 110 kg, radius 1.5 m, and is spinning at 18 rpm. The children have masses of 21.2 kg, 28.4 kg, and 33.8 kg. If the child who has a mass of 28.4 kg moves to the center of the merry-go-round, what is the new magnitude of angular velocity in rpm?