EMBED Equation

cos 45  T 2x T2 T 2 x  T 2 cos 45 T 2y sin 45  T2 T 2 y  T 2 sin 45 T 3x cos 30  T3 T 3 x  T 3 cos 30 sin

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Citation preview

cos 45 

T 2x T2

T 2 x  T 2 cos 45 T 2y sin 45  T2 T 2 y  T 2 sin 45 T 3x cos 30  T3 T 3 x  T 3 cos 30 sin 30 

T 3y T3

T 3 y  T 3 sin 30

 Fx  0 T 2 cos 45  T 3 cos 30  0 T 2 cos 45  T 3 cos 30 T2 

T 3 cos 30 cos 45

T 2  1,22 * T 3 (1)

 Fy  o T 2 sin 45  T 3 sin 30  T 1  0 (2) Remplazando.(1)en (2)

(1,22 * T 3) sin 45  T 3 sin 30  T 1 0,86 * T 3  0,5T 3  400 N 400 N 1,36 T 3  294 N T3 

T 2  1,22(294) T 2  358 N

La tension en la cuerda AC es de 294N y en la cuerda BC es de 358N Segunda parte

a b c   sin A sin B sin B c a  sin C sin A 1m a  sin 105 sin 30 1* sin 30  0,5m sin 105 c b  sin C sin B 1m b  sin 105 sin 45

1* sin 45  0,7 m sin 105 Las longitudes naturales de las cuerdas AC= 0,7 metros BC= 0, 5 metros