200 216.2 0.2165 2.1271 250 8 266.55 02. 266.5 2.6/17 Average force constant Kaug Force constant Ktren from the slope of the trendline in the graph % relative difference between Kavg and Ktren Mhi Mass of the weight hanger 1. Xo: Position

Transcribed Image Text:

the 2 5 13.0 2.5 2.6 1.5- 1.0 60.5 yo ‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒‒ Please show here the calculation of the slope. Slope = 0.00 Op Figure. 32.5n/m OUL 0.03 0.04 0.05 006 007 0.08

Transcribed Image Text:

Figure 4. How to correctly measure the position of the bottom of the spring when the weight hanger carries the required added masses. M₁ (8) = 6₁54 Msw (g) Table # 1: Determination of the spring constant K g= 9.80 m/s² xo (cm) = 2 MT= Mh+ Msw MT MT (kg) 6.6.5, 0.066.5 116:52 0.11 6.5 F =W=Mrg F (N) 0 0.6517 1.1417 xf (cm) 11.7 3.3 4.9 X = Xf- Xo X (cm) X (m) 0 50 100 150 200 166.5 0.766.5 1.63/7 216.30.2165 2.1217 266.55 (2.2665 2.6/17 Average force constant Kavg 250 8 Force constant Ktren from the slope of the trendline in the graph % relative difference between Kavg and Ktren Mh: Mass of the weight hanger Msw: Mass of added slotted weights Mr: Total Mass W: Weight of hanger plus slotted weights K = F(N) x(m) K (N/m) 0.2 0.1 65√7 2.5ch 0.025 45:068 You 0.09 40,7925 0:055 38 57636364 7.2 0.072 36.973 6 UI! 55 35.7829 n/m Xo: Position of the spring's bottom (unstretched) xf: Position of the spring's bottom (stretched) x: Elongation of the spring K: Force constant of the spring 25 2. 0.0. C