T g Y A 8 meter radius amusement park ride starts to speed up from rest...
Fantastic news! We've Found the answer you've been seeking!
Question:
Transcribed Image Text:
T g Y A 8 meter radius amusement park ride starts to speed up from rest in the horizontal plane with a 100 kg rider. Left image in the figure for parts a,b. a) Draw a FBD for the person that remains stationary with respect to the wall without touching the floor of the ride. Label all forces using by,on notation. (1.5 pts) b) With a static coefficient of friction equal to 0.6, calculate the minimum constant speed of the person to remain stationary relative to the wall of the ride without touching the floor. (2 pts) Once up to a speed of 20 m/s the ride then moves to rotating in the vertical plane. Right image in the figure for parts c-e. c) For the vertical position with theta as an angle above the horizontal direction and equal to 30 degrees, draw a FBD for the person with constant speed at the instant shown in the figure. (1.5 pts) d) Calculate the magnitude of the normal force by the wall on the person at the instant shown. (2 pts) e) Calculate the magnitude of static friction by the wall on the person at the instant shown. (2 pts) 1 pt for correct units on all answers - (Not required to be shown in your work) T g Y A 8 meter radius amusement park ride starts to speed up from rest in the horizontal plane with a 100 kg rider. Left image in the figure for parts a,b. a) Draw a FBD for the person that remains stationary with respect to the wall without touching the floor of the ride. Label all forces using by,on notation. (1.5 pts) b) With a static coefficient of friction equal to 0.6, calculate the minimum constant speed of the person to remain stationary relative to the wall of the ride without touching the floor. (2 pts) Once up to a speed of 20 m/s the ride then moves to rotating in the vertical plane. Right image in the figure for parts c-e. c) For the vertical position with theta as an angle above the horizontal direction and equal to 30 degrees, draw a FBD for the person with constant speed at the instant shown in the figure. (1.5 pts) d) Calculate the magnitude of the normal force by the wall on the person at the instant shown. (2 pts) e) Calculate the magnitude of static friction by the wall on the person at the instant shown. (2 pts) 1 pt for correct units on all answers - (Not required to be shown in your work)
Expert Answer:
Related Book For
Posted Date:
Students also viewed these physics questions
-
A rigid, mass less rod has three particles with equal masses attached to it as shown in Figure P11.45. The rod is free to rotate in a vertical plane about a frictionless axle perpendicular to the rod...
-
Let A, B be sets. Define: (a) the Cartesian product (A B) (b) the set of relations R between A and B (c) the identity relation A on the set A [3 marks] Suppose S, T are relations between A and B, and...
-
Sita lived in a village and could, not afford refrigerator in her house. She knew how to keep water cold and preserve all perishable items in her house. She kept ivet cloth surrounding the earthen...
-
X1, X2, . . . is a sequence of iid Bernoulli (1/2) random variables. Consider the random sequence Yn = X1 + + Xn. (a) What is limn P[|Y2n - n] n/2]? (b) What does the weak law of large numbers...
-
In 2013, McDonald's reported profits of almost $6 billion on sales of $28 billion. For that same period, Burger King posted a profit of almost $234 million on sales of $1.1 billion. So McDonald's is...
-
What is an environmental intervention? How are environmental interventions and eco-efficiency related?
-
Bettner, Inc., is a calendar year corporation whose financial statements for 2012 and 2013 included errors as follows: Assume that purchases were recorded correctly and that no correcting entries...
-
Obtain the technology matrix from the input-output table. to A B C from A 0 200 300 B 500 400 300 C 0 0 600 Total Output 1,000 2,000 3,000
-
Compute P(E=Good) Compute P(S=Yes, H=Yes) Compute P(N=No, S=Yes, H=No, E=Good) (1) (2) (3) (4) (5) Compute P(E=Good|N=Yes) Compute P(E=Bad|S=No) P(N=Yes) P(N=No) 0.8 0.2 P(S=Yes) P(S=No) Party Last...
-
Approximate the area under the curve over the given interval using 4 midpoint rectangles. 5. y = -x + 2x + 11; [-1,3]
-
What does it mean that a security interest must be perfected?
-
Find and analyze a speech or presentation with significant historical importance. How might the speaker have altered his or her presentation given the communication technologies available today?...
-
Does a common law tort of invasion of privacy exist in Canada?
-
What is the function of a financing statement?
-
Nothing looks worse than a ______________ who appears distracted or uninterested when the rest of the team is presenting.
-
Calculate the ionic strength and the activity coefficient of Fe2+ of a solution that is: La(NO3)3 0.030 M + Fe(NO3)2 0.060 M.
-
What is the expected payoff of an investment that yields $5,000 with a probability of 0.15 and $500 with a probability of 0.85? Select one: O a. $325 O b. $5,500 O c. $2,750 O d. $1,175
-
In addition to its rest energy, a moving proton (p') has kinetic energy. This proton collides with a stationary proton (p), and the reaction forms a stationary neutron (n), a stationary proton (p),...
-
The 0 meson is a particle that has a rest energy of 135.0 MeV (see Table 32.3). It lives for a very short time and then decays into two g-ray photons: 0 + . Suppose that one of the g-ray photons...
-
An object is placed in front of a converging lens in such a position that the lens (f = 12.0 cm) creates a real image located 21.0 cm from the lens. Then, with the object remaining in place, the lens...
-
Find the natural frequency of the system shown in Fig. 2.54. Figure 2.54:- Rotating machine B Isolator (Helical springs) FIGURE 2.54 Isolated rotating machine. Foundation block
-
Use Rayleigh's method to solve Problem 2.93. Data From Problem 2.93:- A uniform slender rod of mass \(m\) and length \(l\) is hinged at point \(A\) and is attached to four linear springs and one...
-
Use Rayleigh's method to solve Problem 2.26. Data From Problem 2.26:- A mass \(m\) is attached to a cord that is under a tension \(T\), as shown in Fig. 2.67. Assuming that \(T\) remains unchanged...
Study smarter with the SolutionInn App