Question 13.7: Pinion 2 in Fig. 13–34a runs at 1750 rev/min and transmits 2...

The pitch diameters of gears 2 and 3 are

d_2 = N_2m = 20(2.5) = 50 mm

d_3 = N_3m = 50(2.5) = 125 mm

From Eq. (13–36) we find the transmitted load to be

W_t=\frac{60 000H}{\pi d_2n}=\frac{60 000(2.5)}{\pi (50)(1750)}=0.546 kN

Thus, the tangential force of gear 2 on gear 3 is F^t_{23} = 0.546 kN, as shown in Fig. 13–34b.

Therefore

F^r_{23} = F^t_{23} tan 20° = (0.546) tan 20° = 0.199 kN

and so

F_{23}=\frac{F^t_{23}}{\cos 20°}=\frac{0.546}{\cos 20°} =0.581  kN

Since gear 3 is an idler, it transmits no power (torque) to its shaft, and so the tangential reaction of gear 4 on gear 3 is also equal to W_t. Therefore

F^t_{43} = 0.546 kN                F^r_{43} = 0.199 kN              F_{43} = 0.581 kN

and the directions are shown in Fig. 13–34b.
The shaft reactions in the x and y directions are

F^x_{b3}=-(F^t_{23}+F^r_{43})=-(-0.546+0.199)=0.347  kN

F^y_{b3}=-(F^r_{23}+F^t_{43})=-(0.199-0.546)=0.347  kN

The resultant shaft reaction is

F_{b3}=\sqrt{(0.347)^2+(0.347)^2}=0.491  kN

These are shown on the figure.