A mass of 500 grams is attached to two springs whose spring constants are k1=2 N/m and k2 = 5 N/m, which are in turn attached to a wall. The system is on a horizontal frictionless surface. The system is displaced to the right and released. (a) What is the effective spring constant of the two springs in ”series”? Hint use Hooke’s law and the fact that the force required to displace the system is the same acting on each spring. (b) What is the period of oscillation? (c) What is the frequency of oscillation?
A mass of 500 grams is attached to two springs whose spring constants are k1=2 N/m...
Hello, I'm having difficulty solving this problem for my Physics II (Non-Calculus) class. If you can, can you help me write out the equations for each and the answers? Thank you! are ki-2 N/m and k2 5 N/m, which are in turn attached to a wall. The system is on a horizontal frictionless surface. The system is displaced to the right and released. use Hooke's law and the fact that the force required to displace the system is the same...
Newton's Third Law (two springs) Two springs with spring constants k1 = 24.6 N/m and k2 = 15.6 N/m are connected as shown in the Figure. Find the displacement y of the connection point from its initial equilibrium position when the two springs are stretched a distance d = 1.3 m as a result of the application of force F 0 0.824 m Use Newton's first law and apply it to the connection point! Submit Answer Incorrect. Tries 1/6 Previous...
Two springs, with force constants k1=150N/m and k2=235N/m, are connected in series Two springs, with force constants ki = 150 N/m and k2 = 235 N/m, are connected in series, as shown in (Figure 1). Part A When a mass m = 0.60 kg is attached to the springs, what is the amount of stretch, ? Express your answer to two significant figures and include appropriate units. Figure < 1 of 1 > TT HÀ • • • Ea ?...
Two springs, with force constants k1=170N/m and k2=240N/m, are connected in series. When a mass m=0.55kg is attached to the springs, what is the amount of stretch, x?
Question: A block with mass of m = 3.78 kg is attached to springs with spring constants of ki = 18.1 N/m and k = 25.6 N/m, in different configurations shown in the figures below. Assume in all these cases that friction is negligible. Part 1) You will need to calculate the period of oscillations for each situation In this situation the mass is connected between the two springs which are each connected to opposite walls (Figure 1). What is...
A block with mass m = 5.7 kg is attached to two springs with spring constants kleft = 36 N/m and kright = 53 N/m. The block is pulled a distance x = 0.23 m to the left of its equilibrium position and released from rest. 1) What is the magnitude of the net force on the block (the moment it is released)? 2) What is the effective spring constant of the two springs? 3) What is the period of oscillation of...
A block with mass m = 5.8 kg is attached to two springs with spring constants kleft = 37 N/m and Kright = 55 N/m. The block is pulled a distance x = 0.24 m to the left of its equilibrium position and released from rest. 1) What is the magnitude of the net force on the block (the moment it is released)? 2) What is the effective spring constant of the two springs? 3) What is the period of oscillation of the...
Springs A and B have spring constants of k_A = 2000 N/m and k_B = 2000 N/m, respectively. Spring A is hung from a rigid horizontal beam and its other end is attached to the end of Spring B. The pair of springs is then used to suspend a body of mass m = 50-kg from the lower end of spring B. What is the period of harmonic oscillation of the system These same two springs are now connected to...
A 3.00-kg block is connected to two ideal horizontal springs having force constants k1 = 23.0 N/cm and k2 = 18.0 N/cm. The system is initially in equilibrium on a horizontal, frictionless surface. The block is now pushed 15.0 cm to the right and released from rest. What is the maximum speed of the block?
In the figure below, two identical springs of spring constant 7500 N/m are attached to a block of mass 0.300 kg. What is the frequency of oscillation on the frictionless floor? Give your answer in Hz