The 1018 steel strap of Fig. 9–21 has a 1000-lbf, completely reversed load applied.
Determine the factor of safety of the weldment for infinite life.
Question 9.5: The 1018 steel strap of Fig. 9–21 has a 1000-lbf, completely...
From Table A–20 for the 1018 attachment metal the strengths are S_{ut} = 58 kpsi and S_{y} = 32 kpsi. For the E6010 electrode, S_{ut} = 62 kpsi and S_{y}= 50 kpsi. The fatigue stress-concentration factor, from Table 9–5, is K_{fs} = 2.7. From Table 6–2, p. 280, k_{a}= 39.9(58)^{−0.995} = 0.702 . The shear area is:
A = 2(0.707)0.375(2) = 1.061 in^{2}
Table 9–5 Fatigue Stress-Concentration Factors, K_{fs}
| K_{fs} | Type of Weld |
| 1.2 | Reinforced butt weld |
| 1.5 | Toe of transverse fillet weld |
| 2.7 | End of parallel fillet weld |
| 2.0 | T-butt joint with sharp corners |
Table 6–2 Parameters for Marin Surface Modification Factor, Eq. (6–19)
k_{a} = aS^{b}_{ut} (6–19)
| Exponent b | Factor a | Surface Finish | |
| S_{ut}, MPa | S_{ut}, kpsi | ||
| −0.085 | 1.58 | 1.34 | Ground |
| −0.265 | 4.51 | 2.70 | Machined or cold-drawn |
| −0.718 | 57.7 | 14.4 | Hot-rolled |
| −0.995 | 272. | 39.9 | As-forged |
From C.J. Noll and C. Lipson, “Allowable Working Stresses,” Society for Experimental Stress Analysis, vol. 3, no. 2, 1946 p. 29. Reproduced by O.J. Horger (ed.) Metals Engineering Design ASME Handbook, McGraw-Hill, New York. Copyright © 1953 by The McGraw-Hill Companies, Inc. Reprinted by permission.
Table A–20 Deterministic ASTM Minimum Tensile and Yield Strengths for Some Hot-Rolled (HR) and Cold-Drawn (CD) Steels [The strengths listed are estimated ASTM minimum values in the size range 18 to 32 mm ( \frac {3}{4} to 1\frac {1}{4}in). These strengths are suitable for use with the design factor defined in Sec. 1–10, provided the materials conform to ASTM A6 or A568 requirements or are required in the purchase specifications. Remember that a numbering system is not a specification.] Source: 1986 SAE Handbook, p. 2.15
| 8
Brinell Hardness |
7
Reduction in Area, % |
6
Elongation in 2 in, % |
5
Yield Strength, MPa (kpsi) |
4
Tensile Strength, MPa (kpsi) |
3
Proces-sing |
2
SAE and/or AISI No. |
1
UNS No. |
| 86 | 55 | 30 | 170 (24) | 300 (43) | HR | 1006 | G10060 |
| 95 | 45 | 20 | 280 (41) | 330 (48) | CD | ||
| 95 | 50 | 28 | 180 (26) | 320 (47) | HR | 1010 | G10100 |
| 105 | 40 | 20 | 300 (44) | 370 (53) | CD | ||
| 101 | 50 | 28 | 190 (27.5) | 340 (50) | HR | 1015 | G10150 |
| 111 | 40 | 18 | 320 (47) | 390 (56) | CD | ||
| 116 | 50 | 25 | 220 (32) | 400 (58) | HR | 1018 | G10180 |
| 126 | 40 | 15 | 370 (54) | 440 (64) | CD | ||
| 111 | 50 | 25 | 210 (30) | 380 (55) | HR | 1020 | G10200 |
| 131 | 40 | 15 | 390 (57) | 470 (68) | CD | ||
| 137 | 42 | 20 | 260 (37.5) | 470 (68) | HR | 1030 | G10300 |
| 149 | 35 | 12 | 440 (64) | 520 (76) | CD | ||
| 143 | 40 | 18 | 270 (39.5) | 500 (72) | HR | 1035 | G10350 |
| 163 | 35 | 12 | 460 (67) | 550 (80) | CD | ||
| 149 | 40 | 18 | 290 (42) | 520 (76) | HR | 1040 | G10400 |
| 170 | 35 | 12 | 490 (71) | 590 (85) | CD | ||
| 163 | 40 | 16 | 310 (45) | 570 (82) | HR | 1045 | G10450 |
| 179 | 35 | 12 | 530 (77) | 630 (91) | CD | ||
| 179 | 35 | 15 | 340 (49.5) | 620 (90) | HR | 1050 | G10500 |
| 197 | 30 | 10 | 580 (84) | 690 (100) | CD | ||
| 201 | 30 | 12 | 370 (54) | 680 (98) | HR | 1060 | G10600 |
| 229 | 25 | 10 | 420 (61.5) | 770 (112) | HR | 1080 | G10800 |
| 248 | 25 | 10 | 460 (66) | 830 (120) | HR | 1095 | G10950 |
For a uniform shear stress on the throat, k_{b} = 1.
From Eq. (6–26), p. 282, for torsion (shear),
k_{c} =\begin{cases} 1 & bending \\ 0.85 & axial \\ 0.59 & torsion ^{17} \end{cases} (6-26)
17: Use this only for pure torsional fatigue loading. When torsion is combined with other stresses, such as bending, k_{c} = 1 and the combined loading is managed by using the effective von Mises stress as in Sec. 5–5. Note: For pure torsion, the distortion energy predicts that (k_{c})_{torsion} = 0.577.
k_{c} = 0.59 k_{d} = k_{e} = k_{f} = 1
From Eqs. (6–8), p. 274, and (6–18), p. 279,
S′_{e}=\begin{cases}0.5S_{ut}& S_{ut} ≤ 200 kpsi (1400 MPa) \\100 kpsi & S_{ut} > 200 kpsi \\700 MPa & S_{ut} > 1400 MPa \end{cases} (6-8)
S_{e} = k_{a}k_{b}k_{c}k_{d}k_{e}k_{f} S′_{e} (6–18)
S_{se} = 0.702(1)0.59(1)(1)(1)0.5(58) = 12.0 kpsi
K_{f s} = 2.7 F_{a} = 1000 lbf F_{m} = 0
Only primary shear is present:
τ^{′}_{a} =\frac {K_{f s} F_{a}}{A} = \frac {2.7(1000)}{1.061} =2545 psi τ^{′}_{m} = 0 psi
In the absence of a midrange component, the fatigue factor of safety n_{f} is given by
n_{f} =\frac {S_{se}}{τ^{′}_{a}} =\frac {12 000}{2545} = 4.72
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