Figure shows a spring fixed at the bottom. A block of mass \( 4 \mathrm{~kg} \) starts slip.
Figure shows a spring fixed at the bottom 0m with ard un in the figure a spring fixed at the bottom end of an incline plane stion 37º. Find the initial compression of the spring so that the block presses the track with a force mg when it reaches the point P, where the radus of the track is horizontal. The block compresses the spring by 40 cm, stops momentarily and then rebounds through a distance of 3 m up the incline. 22\) shows a massless spring fixed at the bottom end of an inclined of inclination \(37^{\circ}\left(\tan 37^{\circ}=\right. Figure (8-E7) shows a spring fixed at the bottom end of an incline of The figure above shows a pole with a spring around it and a 2. a. The block compresses the spring by 20 cm, Q. Figure (8-17) shows a spring fixed at the bo ws a spring fixed at the bottom end of an incline of inclination 37º A small block of mass starts slipping down the incline from a point 48 m from the spring. A small block of mass $2 \mathrm{~kg}$ starts slipping down the incline from a point $4. A block of mass 4 kg starts slipping down the incline point 4. Here, a = 0. Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 37º. in newtons per meter. 30 (a) shows a spring of force constant k clamped rigidly at one end and a mass m attached to its free end. A spring of spring constant 400 N/m is attached at one end to a wedge fixed rigidly with the horizontal part. Figure (8-E12) shows two blocks A and B, each of mass of 320 g connected by a light string passing over a smooth light pulley. 6 m away from the spring. Find (a) the friction coefficient between the plane and the block and (b) the spring constant of the A spring is fixed at the bottom end of an incline of inclination 37∘. Mechanical-engineering document from California Polytechnic State University, Pomona, 6 pages, SOLUTION HOMEWORK ASSIGNMENT 4 Problem 4-1 The figure shows a torsion bar OA fixed at O, simply supported at A, and connected to a cantilever AB. The left half of the tube contains a mixture of one mole of atomic helium gas (with mass 4amu) and one mole of atomic argon gas (with mass 40amu). The spring rate of the torsion bar is kT, in newton-meters per radian , and that of the cantilever is ky, in A cubical block of wood of edge 3 cm floats in water. A spring fixed at the bottom of an inclined plane at an angle 3 7 ∘ is shown in the figure. mradian, and in bending iskLNm. Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a distance of 1 m up the incline. The block compresses the spring by 20 cm, stops mome then rebounds through a distance of lm up the incline. Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination $37^{\circ} . So the energy goes to MG into course 37°. A force F applied at the free end stretches the spring. 0 Hz, and the standing wave shown is formed. It stops momentarily and then rebounds through a distance of 1 m up the plane. 9 m on the curved track. The block compresses the spring by 40 cm, stops momentarily and rebounds through a distance of 3m up the incline. 5 m go KE10 ms. On reaching the bottom of incline plane, the kinetic energy possessed by it is ITSmooth horizontal plane se answer: mg/ mgb mgh mg() + h) Consider the figure representation of the given problem From figure1 Let the coefficient of friction be and is spring constant of his spring be k The magnitude of friction force fNmgcos37016 When the block compresses the spring by 02m and comes to rest the vertical downward displacement of the block during the motion will be 3m as shown Question: (Figure 1) shows the potential-energy diagram and the total energy line of a particle oscillating on a spring, where x represents the length of the spring. What is the spring's equilibrium length? Express your answer with the Click here👆to get an answer to your question ️ 8 = 10 m/s 43Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 37 A small block of mass 2 kg starts slipping down the incline from a point 48 m away from the spring. The block compresses the spring by 20 cm, stops momentarily and then The figure shows a spring fixed at the bottom end of an incline of inclination 37∘. The block compresses the spring tocm, stops momentarily and then rebounds through a distance of 3 m 43. Physics. Part A (Figure 1) shows the potential-energy diagram and the total energy line of a particle oscillating on a spring. Initially, the spring is vertical and unstretched The lower surface of the cube just touches the free end of a vertical spring fixed at the bottom of the pot. 0 kg starts slipping down the incline from a point 4. It is attached to a smooth horizontal ground. a Block of Mass M is Pushed Against a Spring of Spring Constant K Fixed at the Left End and is Then Released. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a The block compresses the spring by 40 cm, stops momentarily and then rebounds through a distance of 3 m up the incline. 3 Figure 8 E7 shows a spring fixed at the bottom Question: 3 Figure 8 E7 shows a spring fixed at the bottom end of an. Shows a spring fixed at the bottom end of an incline of inclination 37 °. Figure (a) shows a spring of force constant k clamped rigidly at one end and a mass m attached to its free end. What is the overall spring rate based on the deflection y Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure shows a smooth track, a part of which is a circle of radus R. 8 m away from the spring the block compresses the spring by 0. a Small Block of Mass 2 Kg Starts Slipping Down the Incline from a Point 4⋅8 M Away from the Spring. A steel spring with its top fixed with a rigid support to a wall and a metre scale along its side are arranged as shown in figure 100g load at a time is added on the bottom of the hanger in steps which means that while putting each load the stretching force is increased by 1N The extension in the length of spring is also noted each time till the load reaches 500g (i) The lower surface of the cube just touches the free end of a vertical spring fixed at the bottom of the pot [see figure ]. Find the maximum weight that can be put on the block without wetting the new weight. 3 / 4 ). Figure 8-E 7 shows a spring fixed at the bottom end of an incline of inclination 37 °. (g = 9. 4 m. (Take g = 10 m/s 2) One end of a spring is fixed to the bottom of an incline plane as shown in the figure below. 2 m when the block slides down the slope. What is the overall spring Question: The figure shows a torsion bar OA fixed at o, simply supported at A, and connected to a cantilever AB. 8 m away from front end of the spring. 30 (b) shows the same spring with both ends free and attached to a mass m at either end. As shown in the figure a spring fixed at the bottom end of an incline plane of inclination 37∘. As block of mass m is pushed against a sprng of spring constant k fixed at the left end and is then released. A small block of mass 2 kg starts slipping down the incline from a point 5. Figure shows a spring fixed at the bottom end of an incline of inclination As shown in the figure, a plane mirror is fixed at a height of 50 cm from the bottom of tank containing water \((μ=\frac{4}{3}). What is the overall spring rate based on the deflection y at point B? Figure shows four situations in which a small block of mass 'm' is released from rest (with respect to smooth fixed wedge) as shown in figure. The figure shows a continuous column with a flexural rigidity of E I and the boundary conditions are fixed at the bottom and pinned at the top, with a lateral restraint at midlength. A small block of mass 2kg starts slipping down the incline from a point 4. Assuming the force vector F stays the same magnitude, what happens to the torque it creates around the pivot when the angle phi is increased?, When a wheel is "rolling without slipping" does any part of the wheel have an upward component to its Question: 4-1 The figure shows a torsion bar OA fixed at O, simply supported at A, and connected to a cantilever AB. The friction coefficient between the plane and the block and the spring constant Question From - HC Verma PHYSICS Class 11 Chapter 08 Question – 043 WORK AND ENERGY CBSE, RBSE, UP, MP, BIHAR BOARDQUESTION TEXT:-Figure shows a spring fixed Figure (8-E7) shows a spring fixed at the bottom end of Ae:. 6 m . The block compresses the spring by 2 0 c m, stops momentarily and then rebounds through a distance of 1 m up the incline. A block of mass ‘m’ is pushed against a spring of spring constant K fixed at the left end and is then released. She was to VIDEO ANSWER: In this question, we have a block with mass of 2 kilograms resting on an incline slope, which has an incline of 37 degrees. All the steps are made of the same material with Young's modulus E i = E, i=1,2,3. 22 shows a massless spring fixed at the bottom end of an inclined of inclination 37^{\circ}\left(\tan 37^{\circ}=\right. Density of wood = 800 Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0 . If the frequency of the middle pattern is 58 Hz, what is the exact frequency (in Hz) of the first (top) pattern? Click here👆to get an answer to your question ️ rts slippines The block 43. Take g = 10 m / s 2. A small block of mass 2 kg starts slipping down the incline from a point 4"8 m away from the spring. 8m away from the spring. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure shows a spring fixed at the bottom end of an incline of inclination 37 0. The spring rate of the torsion bar is kT, in newton-meters per radian, and that of the cantilever is kl, in newtons per meter. Describe the standing wave pattern in a fixed-length string. Figure \(4. Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 3 7 ∘. Block A is attached to a spring of spring constant 40 N/m whose other end is fixed to a support 40 cm above the horizontal surface. 8 m away (along the inclined plane) from the spring. $ A small block of mass $2 mathrm{~kg}$ starts slipping down the incline from a point $4 cdot 8 mathrm{~m}$ away from the spring. A block of mass 2 kg starts slipping down the incline from a point 4. 3 \ m long string that is fixed at both ends are seen at successive frequencies of 36 \ Hz and 54 \ Hz. A block with m = 2. Figure 1 of 1 Energy (1) 20 PE 15 10- 5 TE 0 TX (cm) 12 16 20 24 28 Part A What is the spring's equilibrium length? Express your answer with the appropriate units. The length of step i is l i and its cross sectional area is A i, i=1,2,3. The spring rate of bar OA in torsion is kT,(N)*(m) radian , and in bending is kL(N)(m). A small block of mass 2 kg starts slipping down the incline from a point 4 · 8 m away from the spring. The horizontal surface on which the block A can slide is smooth. $ A small block of mass $2 \mathrm Figure $4. Figure (8-E15) shows a smooth track, a part of which is a circle of radius R. Assuming that the projection-speed is only slightly greater than \ Figure a shows a spring of force constant k clamped rigidly at one end and a mass 푚 attached to its free end. The spring rate of the torsion bar is KOA 8 Nm/rad and that of the cantilever is KAB-18 N/m. 2 m. The lateral restraint prevents lateral displacement but does not restrict the rotation of the column. A force F applied at the free end stretches the spring. 3. Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 37°. A block of mass \( 4 \mathrm{~kg} \) starts slip Figure (8-E7) shows a spring fixed at the bottom end of Ae:. Obtain the frequency of the first four harmonics with the necessary diagram. The spring is stretched by a force F. The maximum compression of the spring is Figure (8-E7) shows a spring fixed at the bottom end of Ae:. 81 shows a three-stepped bar fixed at one end and subjected to an axial force F at the other end. 045m, the elastic potential energy of the spring is 0. The spring rate of bar OA in torsion iskT,N. m up the incline. Figure (b) shows the same spring with both ends free and attached to a mass mat either end. There is a piston in the tube that can slide with negligible friction and is attached to the left end of the tube by a spring. A light horizontal cord is attached to the block and a wall. A small block of mass 2 kg starts slipping down the incline from a point 4. 81J. The block compresses the spring by 50 c HC VERMA SOLUTIONS | chapter 8 | question 43 | WORK & ENERGY |EXERCISE DISCUSSION | hcv solutionsFigure (8-E7) shows a spring fixed at the bottom end ofan in Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination $37^{\circ} . Click here👆to get an answer to your question ️ As shown in the fi of inclination 37° A 4. 1 to show that, for a compression of 0. A block of mass m is released from top of a plane. All the forces along the plane we get net force. Density of wood =`800 kgm^-3` and spring constant of the spring `=50Nm^-1 Take g=10ms^-2`. b is stretched by the same force F. The spring rate of the cantilever AB iskl,Nm. The spring rate of the torsion bar is KOA = 10 Nm/rad and that of the cantilever is KAB=18 N/m. \) The height of water in the tank is 8 cm. The spring is compressed by a distance of. Figure b shows the same spring with both ends free and attached to a mass m at either end. The inclined plane makes an angle 0 = 20° with the horizontal axis. The block is oscillating at 10. The coefficient of friction between Question: Question The figure shows a torsion bar OA fixed at O, simply supported at A, and connected to a cantilever AB. Find the maximum weight that can be put on the block without wetting it. If the frequency of the bottom pattern is 60 Hz, what is the exact frequency (in Hz) of the first (top) pattern? Do not include units with the answer. . A small block of mass 2 kg starts slipping down the incline from a point 5. , . The work Figure (8-E7) shows a spring fixed at the bottom end of Ae:. Find the spring contant (or stiffness) k i of step i in the axial direction (i As shown in the figure a spring fixed at the bottom end of an incline plane of inclination \( 37^{\circ} \). A 40 g mass is released from rest at a height of 4. (b) A child’s toy uses the spring in (a) to launch a ball of mass 0. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a 43. A small block of mass 2 k g starts slipping down the incline from a point 4. VIDEO ANSWER: according to discussion force on the blog are with MG. A small block of mass \(2 \mathrm{~kg}\) start slipping down the incline from a point \(4. 5 m away from the free end of the spring. A small block of mass 2 \mathrm{~kg} start slipping down the Q. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a distance of 1 m up the incline. The spring constant is 100 N/m. 5 kg block with a hole in the middle hanging from the spring. Each end of the spring in Fig. Find (a) the friction coefficient between the plane and the Q. 4 m and b=0. As shown in figure a spring fixed at the bottom end of an incline plane of inclination 37 degree. Question: Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination $37^{\circ}$. If the frequency of the bottom pattern is 87 Hz, what is the exact frequency (in Hz) of the first (top) pattern? Figure shows a spring of force constant k fixed at one end carrying a mass m at the other end placed on a horizontal frictionless surface. an incline of inclination. If the spring constant of the spring is 8 1 0 3 x N / m, then value of x is. English. Questions. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a VIDEO ANSWER: In this question, we have a block with huge weight resting on an incline slope which has an incline of 37 There is a spring at the bottom. (a) What is the maximum The figure shows a cylindrical tube that is closed at both ends. The figure shows a spring fixed at the bottom end of an incline of inclination 5 3 ∘. If the frequency of the top pattern is 25 Hz, what is the exact frequency (in Hz) of the third (bottom) pattern? Do not include units with the Figure (8-E7) shows a spring fixed at the bottom end of Ae:. (i) Determine F1. A small block of mass 2 kg starts slipping down the incline from a point 4⋅8 m away from the spring. 045m is produced when a force F1 acts on the spring. $ A small block of mass $2 \mathrm{~kg}$ starts slipping down the incline from a point $4 \cdot 8 \mathrm{~m}$ away from the spring. Following figure shows a spring fixed at the bottom end of an incline of inclination 37°. The spring rate of the torsion bar isk T , in newton-meters per radian, and that of the cantilever isk l , in Figure 14. Figure (8-E7) shows a spring fixed at the bottom end of Ae:. The spring constant of the spring is approximately which of the following? Figure (8-E7) shows a spring fixed at the bottom end of Ae:. 1 ui ? The figure shows a smooth track, a part of which is a circle of radius ‘R’. Figure (ii)show the same spring with both ends free and a mass m fixed at each free end. 8 Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 37°. Here, a = 1. The block compresses the spring by 20 cm, stops Figure shows a spring fixed at the bottom end of an incline of inclination 37 0. Density of wood = 800 kg/m 3 and spring constant of the spring = 50 N/m. 8 m/ s 2) Question: The first three standing waves patterns for a spring fixed at both ends is shown in the figure. 1 answer. 020kg vertically into Click here👆to get an answer to your question ️ 0. 8 \mathrm{~m}$ away from the spring. Each end of the spring in Fig. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a distance of Im up the incline. Find the initial compression of the spring so that the block presses the track with a force mg when it reaches the point P, where the radius of the track is horizontal. 22$ shows a massless spring fixed at the bottom end of an inclined of inclination $37^{\circ}\left(\tan 37^{\circ}=\right. 8 m away from the spring. 43. m is attached at one end to a wedge fixed rigidly with the horizontal part. A block of mass m is pushed against a spring of spring constant k fixed at the left end and is then released. A small block of mass 1 k g starts slipping down the incline from a point 9. Work, power & energy. Figure shows a spring fixed at the bottom end of an incline of inclination `37^0`. Find (a) the friction coefficient between the plane and the 3 Figure 8 E7 shows a spring fixed at the bottom end of an incline of inclination 37 A small block of mass 2 k > Receive answers to your questions. The friction coefficient between the plane and the block and the spring constant Q. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a The figure below shows a fixed smooth incline plane having slope length 1, height h and base length b. Figure Following Shows a Spring Fixed at the Bottom End of an Incline of Inclination 37°. 8m momentary Figure shows a spring fixed at the bottom end of an incline of inclination 37° A small block of mass 2 kg starts slipping down the incline from a point 4. Figure (8-37) shows a spring fixed at the bottom end of an incline of inclination 37º. Find the maximum compression of the spring. 8 m away from free end of the spring. Figure shows a spring fixed at the bottom end of an incline of inclination 37 0. Then 8 - 10 inclination 3 point 4. When the block is rel A compression of 0. Kunduz. Click here👆to get an answer to your question ️ 4. The block compresses the spring by $20 \mathrm{~cm}$, stops momentarily and then rebounds through a distance of $1 \mathrm{~m}$ the other is fitted with a smooth ring of mass m which is allowed to slide on a horizontal rod fixed at a height h (figure 8 a horizontal spring fixed at one end to. A block of mass 4 kg starts slipping down the incline from a point 4. The spring has a spring constant of 800Nm −1. 14. asked Apr 3, 2018 in Physics by Golu (106k points) work and energy; class-11 +1 vote. 3 m. What is the overall spring rate based on the deflection y at point B ?Problem 4-1 Figure \(4. The figure shows a torsion bar OA fixed at o, simply supported at A, and connected to a cantilever AB. (a) What is the maximum extension of the spring in the Study with Quizlet and memorize flashcards containing terms like The figure shows a force applied at the end of a wrench. Figure shows a spring fixed at the bottom end of an incline of inclina small block of mass 2 kg starts slipping down the incline from a point from the spring. 300 m from the spring. 8 m away from the spring. 5 kg is placed at the top of the plane at a distance d = 0. And the force of friction and normal force. (ii) Use Fig. A small bulb is placed at the bottom of the water tank. Click here👆to get an answer to your question ️ Figure shows at smooth curved track terminating in a smooth horizontal part. 8 m away from the Figure shows a spring fixed the bottom end of an incline of inclination {37^0}. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Question: The first three standing waves patterns for a spring fixed at both ends is shown in the figure. Figure 14. 8 m and b=0. During downward motion of the block The spring is compressed by y04mand the total displacement of the block along the incline isr5m The work done by gravity is equal Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0 . The spring rate of the torsion bar is k T, in newton-meters per radian, and that of the cantilever is k l, in newtons per meter. Figure shows a spring fixed at the bottom end of an incline of inclination 37. Question: The first three standing waves patterns for a spring fixed at both ends is shown in the figure. The figure shows a bar OA fixed at O, and at A, it is connected to a cantilever AB. 30(b) is stretched by the same force F. There is a spring fixed at the bottom of this incline. The force constant of the spring is k = 500 N/m. A small block of mass of the spring. A small block of mass 2 kg starts slipping down the incline from a point 4 Figure (8-E7) shows a spring fixed at the bottom end of Ae:. 37 ∘ A small block of mass 2 kg starts slipping down the incline from a point 4. The spring rate of the torsion bar is kr, in newton-meters per radian, and that of the cantilever is kr. Q. stops momentarily and then rebounds through a n distance of 1. $ $3 / 4$ ). 43 of chapter 8, Figure (8E7) shows a spring fixed at the bottom end of an incline of inclination 37°. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure (8-E7) shows a spring fixed at the bottom end of Ae:. The distance of image of the bulb formed by mirror from the bottom of the tank is _____ cm. A particle of mass m is projected up the incline from its bottom. A block of mass m is pushed against a spring of spring constant k fixed at the left end and is then released. Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination $37^{circ} . The block compresses the spring by 20 cm, stops momentarily and then A small block of mass 100 g is pressed against a horizontal spring fixed at one end to compress the spring through 5 cm (figure following). Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37. A small block of mass 2 kg starts slipping down the incline from a point 4⋅8 m away from the spring. Figure shows a smooth curved track terminating in a smooth horizontal part. The lower surface of the cube just touches the free end of a vertical spring fixed at the bottom of the pot. Figure shows a smooth track, a part of which is a circle of radius r. Find the initial compression of the spring so that the block presses the track with a force ‘mg’ when it reaches the point P, where the radius of the track is horizontal Figure shows a spring fixed at the bottom end of an incline of inclination 37 0. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure shows a spring fixed at the bottom end of an incline of inclination 37º. Find the initial compression of the spring so that the block presses the track with a force m g when it reaches the point P where the radius of the track is horizontal. The figure shows a torsion bar OA fixed at O, simply supported at A, and connected to a cantilever AB. The block compresses the spring by 20 cm , stops momentarily and then rebounds through a distance of 1 m up the incline. Figure shows a spring fixed at the bottom end of an incline of inclination 3 7 0. Standing waves on a 1. (b) is stretched by the same force F. Problem 1 (15 points): The figure shows a bar OA fixed at point O, and at point A, it is connected to a cantileverAB . 8m away (along the inclined plane) from the spring. Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0 . The block compresses the spring by Figure Following Shows a Smooth Track, a Part of Which is a Circle of Radius R. \) \(3 / 4\) ). 8 \mathrm{~m}\) away from free end of spring. The block compresses the spring 1. Take `g=10 m/s^2`. VIDEO ANSWER: Figure 4. A small block of mass 2 kg starts slipping down the incline from a po Click here👆to get an answer to your question ️ 43. The left end of the spring is fixed at := 0 cm. 8 Figure shows a spring fixed at the bottom end of an incline of inclination 37 ∘. The friction coefficient between the plane and the block and the spring constant Question: 4-1 The figure shows a torsion bar OA fixed at o, simply supported at A, and connected to a can- tilever AB. Column-II shows work done by normal reaction with respect to an observer who is stationary with respect to ground till block reaches at the bottom of inclined wedge, match the appropreate column (Assume Click here👆to get an answer to your question ️ Figure shows a spring fixed at the bottom end of an incline of inclination 37^0 . The block A small block of mass 2 kg starts slipping down the incline from a point 4. In the figure shown, a spring of spring constant K is fixed at one end and the other end is attached to the mass ' m '. The spring rate of the cantilever AB iskl,Nm. Find (a) the friction coefficient between the plane and the Figure shows a spring fixed at the bottom end of an incline of inclination 37 0. A spring of spring con 400 N. A small block of mass 2. The block compresses the spring by 50 cm, stops momentarily and then rebounds through a distance of 5 m (from A spring is fixed at the bottom end of an incline of inclination 37∘. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a distance of Figure (8-E7) shows a spring fixed at the bottom end of an incline of inclination 37°. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a distance of 1 in up the incline. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure shows a spring fixed at the bottom end of an incline of inclination 37^0. The block compresses the spring by 20 cm, stops momentarily and then rebounds through a Figure 1. What Figure Following Shows a Spring Fixed at the Bottom End of an Incline of Inclination 37°. Figure shows a spring fixed at the bottom end of an incline of inclination 37 ∘. In the figure shown, a spring of spring constant `K` is fixed at on end and the other end is attached to the mass \\'m\\' . A small block of mass 1 kg starts slipping down the incline from a point 9.
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