(a) Moment on riveted (b) Forces on rivets
connection in right rowFIGURE 58/i =/4 = 96,000(5.15)7140 = 3530 Ib (15,701.4 N); and/ 2 =/ 3 = 96,000(2.92)7140 = 2000
Ib (8896.0 N). The directions are shown in Fig. 586.
- Compute the shearing stress
Using s = PIA 9 we find S 1 =S 4 = 3530/0.442 = 7990 lb/in^2 (55,090 kPa); also, S 2 = S 3 =
2000/0.442 = 4520 lb/in^2 (29,300 kPa).
5. Check the rivet forces
Check the rivet forces by summing their moments with respect to an axis through the cen-
troid. Thus M 1 =M 4 = 3530(5.15) = 18,180 in-lb (2054.0 N-m); M 2 =M 3 = 2000(2.92) =
5840in-lb (659.8 N-m). Then EM = 4(18,180) + 4(5840) = 96,080 in-lb (10,855.1 N-m).
ECCENTRIC LOAD ON RIVETED
CONNECTIONCalculate the maximum force exerted on a rivet in the connection shown in Fig. 59a.Calculation Procedure:- Compute the effective eccentricity
To account implicitly for secondary effects associated with an eccentrically loaded con-
nection, the AISC Manual recommends replacing the true eccentricity with an effective
eccentricity.
To compute the effective eccentricity, use ee = ea-(\ + n)/2, where ee = effective ec-
centricity, in (mm); ea = actual eccentricity of the load, in (mm); n = number of rivets in a
vertical row. Substituting gives ee = 8 - (1 + 3)/2 = 6 in (152.4 mm). - Replace the eccentric load with an equivalent system
The equivalent system is comprised of a concentric load P Ib (N) and a clockwise mo-
3 (S) 3"(76.2mm)=
9"(228.6mm)