1 / 20

BC-1

Top chord with bending. w w w w w w w. Combined Bending & Axial Forces (BEAM – COLUMNS). Chap. (8). Members subjected to combined axial loads and bending moments are called “Beam-Columns”. Examples of this, are floor or roof beams resisting later wind

Download Presentation

BC-1

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Top chord with bending w w w w w w w Combined Bending & Axial Forces (BEAM – COLUMNS) Chap. (8) Members subjected to combined axial loads and bending moments are called “Beam-Columns”. Examples of this, are floor or roof beams resisting later wind loads. Top chord truss elements supporting roof loading causing bending, etc. Interaction Formula: where: Pu = factored axial compression. Mu = factored bending moment. Pn = nominal axial strength. Mn = nominal bending strength. BC-1

  2. LRFD Criteria for Beam – Column Equation (BC-1) is the basic of AISC design criteria as stated in (chapter H) of AISC – LRFD specs:- BC-2

  3. LRFD Criteria for Beam – Column Example BC-1 The beam-column shown in Figure below is pinned at both ends and is subjected to the factored loads shown. Bending is about the strong axis. Determine weather this member satisfy the appropriate AISC Specification interaction equation. Solution From the column load tables (Table 4.1) the axial compressive design strength of W8x58 with Fy=50 ksi and KyLy=17 ft cPn = 286 kips BC-3

  4. LRFD Criteria for Beam – Column (Contd.) From the beam design charts (Table 3-10 page 3 – 125) for un braced length of Lb=17, and Cb=1.0 bMn = 202 k.ft. For this condition and this loading : Cb=1.32 (table 3.1)  bMn = 1.32 x 202 = 267 k.ft. bMp = 224 k.ft. (Table 3.2 page 3-18).  bMn = 224 k.ft.  bMp This member satisfies the AISC specifications. BC-4

  5. Moment Amplification Moments caused by eccentricity of axial load cannot be ignored for beam-columns. The value of (P·) is called “Moment magnification” due to initial beam column initial crookedness or from bending due to transverse load (). It can be proven that a beam column with initial crookedness (e) and initial moment (Mo = Pu ·e), that the total moment becomes: M = Pu ( e + ymax) BC-5

  6. Moment Magnification Contd. where:- M = Magnified moment. Mo = Initial moment (due to initial crookedness or more often due to transverse loads). Example BC-2 Compute the amplification factor for example (BC-1) So M = 1.15 Mo = 1.15  93.5 = 107.5 k·ft. BC-6

  7. Braced Frames & Unbraced Frames • Moment amplification is covered in chapter C of the AISC code. • Two amplification factors are used in LRFD:- • * One to account for amplification due to deflection. • * One to account for amplification due to frame • sideway to lateral forces in unbraced frames. LRFD account for both effects: Mu = Mr = B1 Mnt + B2 Mlt AISC C2-1a Where: Mr = Mu = factored load combination as affected by amplification. Mnt = Maximum moment assuming no sidesway (no translation) Mlt = Maximum moment caused by sidesway (lateral translation). (Mlt = 0 for braced frames) B1 = amplification factor for braced frames. B2 = amplification factor for unbraced frames. BC-7

  8. Members in Braced Frames The maximum moment in a beam-column depend on the end bending moments in a braced frame, the various cases are accounted for by a factor (Cm) as follows: (AISC C2-2) BC-8

  9. Evaluation of Cm Factor Where: Cm = Coefficient whose value taken as follows: 1: If there are no transverse loads acting on the member, (AISC Equation C2 – 4) M1/M2 is a ratio of the bending moments at the ends of the member. M1 is the end moment that is smaller in absolute value, M2 is the larger, and the ratio is positive for moment bent in reverse curvature and negative for single-curvature bending. Reverse curvature (a positive ratio) occurs when M1 and M2 are both clockwise or both counterclockwise. BC-9

  10. Evaluation of Cm Factor 2. For transversely loaded members, Cm can be taken as 0.85 if the ends are restrained against rotation and 1.0 if the ends are unrestrained against rotation (pinned). End restraint will usually result from the stiffness of members connected to the beam-column. The pinned end condition is the one used in the derivation of the amplification factor; hence there is no reduction for this case, which corresponds to Cm = 1.0. Although the actual end condition may lie between full fixity and a frictionless pin, use of one of the two values given here will give satisfactory results. (AISC C2 – 5) BC-10

  11. 20k W8  35 A36 20k 20k 5' 5' 10' Example on Beam-Columns Example BC-3 The horizontal beam column shown below is subjected to service live loads as shown. The member is laterally braced at its ends. Check its capacity to LRFD code? Solution:- Column Action:- rx = 3.51 in, ry = 2.03 in, Ag = 10.3 in2 BC-11

  12. Example on Beam-Columns (Contd.) c Fcr = 27 ksi (Table 4 - 22 page 4 – 319). c Pn = c Fcr Ag = 27  10.3 = 278.1 k  Use Equation (H1 – 1b) interaction formula. Beam Action:- Lb = 10 ft, Cb = 1.32, Zx = 34.7 in4 Ixx = 127 in3 Sx = 31.2 in3. Mp = Zx Fy = 104.1 k·ft. BC-12

  13. Example on Beam-Columns (Contd.) • Mn = Mp = 104.1k·ft b Mn = 0.9  104.1 = 93.7k·ft BC-13

  14. Example on Beam-Columns (Contd.) Moment Magnification:- Cm = 1.0 (transverse loads and ends unrestrained). Mu = Bi Mnt = 1.013  80.52 = 81.55 k·ft Interaction Formula:- Section is adequate ! BC-14

  15. Laterally Braced Beam-Column Example Example BC – 4 The beam column shown below is part of a braced frame. The factored loads and moments are given as shown. Bending is on strong axis. KxLx = KyLy = 14 ft. The W 14  61 section is made of A572 Gr 50 steel. Is this member safe ? Solution:- • Determine • interaction formula, • and Column Action :- BC-15

  16. Laterally Braced Beam-Column Example (contd.) C) Magnification Factor :- B) Beam Behavior :- From the Beam Design Charts with Cb = 1.0, Lb = 14 b Mn = 344 kips·ft. (page 3.121) For actual (Cb)1 see the moment diagram of the column: • b Mp = 383 k·ft (page 3 – 17 – Zx tables). (also confirmed on page 3 – 121). • b Mn =344 x 1.06 = 364.6 kips·ft. BC-16

  17. Laterally Braced Beam-Column Example (contd.) D) Interaction Equation:- The factored load moments :- Mnt = 82 k·ft , Mlt = 0 Mu = B1Mnt + B2 Mlt = 1.0066  82 + 0 = 82.5 k·ft Section Acceptable BC-17

  18. DL = 20k LL = 40k wk/ft P P w = 12  96 20 ft Laterally Braced Beam-Column Example BC – 5:- Determine the service load w(40% DL + 60% LL) that can be applied to the member shown below, Ends are simply supported. Lateral bracing at ends only A 572 Gr 50 steel, strong axis bending. Solution:- Pu = 1.2  20 + 1.6  40 = 88 kips. Let wu = factored ultimate load (k/ft) = ? Mux = B1 Mnt + B2 Mlt = B1 Mnt BC-18

  19. Laterally Braced Beam-Column Column Action:- c Fcr = 28.9 ksi c Pn = c Fcr Ag = 28.9  28.2 = 815.0 k· Beam Action:- For lb = 20 ft & Cb = 1, b Mnx = 498 k·ft (page 3 – 119 LRFD). Actual Cb = 1.14 Actual b Mnx = 1.14  498 =567.7k·ft Beam-Column Action:- BC-19

  20. Laterally Braced Beam-Column Example (contd.) • 1.2 DL + 1.6 LL = wu • 1.2  (0.4 w) + 1.6  (0.6 w) = 10.5 • 1.44 w = 10.5 • w =7.30 k/ft • DL =3.0 k/ft LL = 4.30 k/ft BC-20

More Related