Download - Fin Plate to Column Flange - LRFD
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SECTION PROPERTIES
1
Properties for Universal Bea
1 UB 1016x305x4872 UB 1016x305x438
3 UB 1016x305x393
4 UB 1016x305x349
5 UB 1016x305x314
6 UB 1016x305x272
7 UB 1016x305x249
8 UB 1016x305x222
9 UB 914x419x388
10 UB 914x419x343
11 UB 914x305x289
12 UB 914x305x253
13 UB 914x305x22414 UB 914x305x201
15 UB 838x292x226
16 UB 838x292x194
17 UB 838x292x176
18 UB 762x267x197
19 UB 762x267x173
20 UB 762x267x147
21 UB 762x267x134
22 UB 686x254x170
23 UB 686x254x152
24 UB 686x254x140
25 UB 686x254x125
26 UB 610x305x238
27 UB 610x305x179
28 UB 610x305x149
29 UB 610x229x140
30 UB 610x229x125
31 UB 610x229x113
32 UB 610x229x101
33 UB 533x210x122
34 UB 533x210x10935 UB 533x210x101
36 UB 533x210x92
37 UB 533x210x82
38 UB 457x191x98
39 UB 457x191x89
40 UB 457x191x82
41 UB 457x191x74
DesignationSl.
No
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2 UC 356x406x551
3 UC 356x406x467
4 UC 356x406x393
5 UC 356x406x340
6 UC 356x406x287
7 UC 356x406x235
8 UC 356x368x202
9 UC 356x368x177
10 UC 356x368x153
11 UC 356x368x129
12 UC 305x305x283
13 UC 305x305x240
14 UC 305x305x198
15 UC 305x305x158
16 UC 305x305x137
17 UC 305x305x118
18 UC 305x305x97
19 UC 254x254x16720 UC 254x254x132
21 UC 254x254x107
22 UC 254x254x89
23 UC 254x254x73
24 UC 203x203x86
25 UC 203x203x71
26 UC 203x203x60
27 UC 203x203x52
28 UC 203x203x46
29 UC 152x152x37
30 UC 152x152x30
31 UC 152x152x23
Properties for W sections as
1 W44X335
2 W44X290
3 W44X262
4 W44X230
5 W40X593
6 W40X503
7 W40X431
8 W40X3979 W40X372
10 W40X362
11 W40X324
12 W40X297
13 W40X277
14 W40X249
15 W40X215
16 W40X199
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17 W40X392
18 W40X331
19 W40X327
20 W40X294
21 W40X278
22 W40X264
23 W40X235
24 W40X211
25 W40X183
26 W40X167
27 W40X149
28 W36X800
29 W36X652
30 W36X529
31 W36X487
32 W36X441
33 W36X395
34 W36X361
35 W36X330
36 W36X30237 W36X282
38 W36X262
39 W36X247
40 W36X231
41 W36X256
42 W36X232
43 W36X210
44 W36X194
45 W36X182
46 W36X170
47 W36X160
48 W36X150
49 W36X135
50 W33X387
51 W33X354
52 W33X318
53 W33X291
54 W33X263
55 W33X241
56 W33X221
57 W33X201
58 W33X169
59 W33X152
60 W33X141
61 W33X130
62 W33X118
63 W30X391
64 W30X357
65 W30X326
66 W30X292
67 W30X261
68 W30X235
69 W30X211
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70 W30X191
71 W30X173
72 W30X148
73 W30X132
74 W30X124
75 W30X116
76 W30X108
77 W30X99
78 W30X90
79 W27X539
80 W27X368
81 W27X336
82 W27X307
83 W27X281
84 W27X258
85 W27X235
86 W27X217
87 W27X194
88 W27X178
89 W27X16190 W27X146
91 W27X129
92 W27X114
93 W27X102
94 W27X94
95 W27X84
96 W24X370
97 W24X335
98 W24X306
99 W24X279
100 W24X250
101 W24X229
102 W24X207
103 W24X192
104 W24X176
105 W24X162
106 W24X146
107 W24X131
108 W24X117
109 W24X104
110 W24X103
111 W24X94
112 W24X84
113 W24X76
114 W24X68
115 W24X62116 W24X55
117 W21X201
118 W21X182
119 W21X166
120 W21X147
121 W21X132
122 W21X122
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123 W21X111
124 W21X101
125 W21X93
126 W21X83
127 W21X73
128 W21X68
129 W21X62
130 W21X55
131 W21X48
132 W21X57
133 W21X50
134 W21X44
135 W18x311
136 W18x283
137 W18x258
138 W18x234
139 W18x211
140 W18x192
141 W18X175
142 W18X158143 W18X143
144 W18X130
145 W18X119
146 W18X106
147 W18X97
148 W18X86
149 W18X76
150 W18X71
151 W18X65
152 W18X60
153 W18X55
154 W18X50
155 W18X46
156 W18X40
157 W18X35
158 W16X100
159 W16X89
160 W16X77
161 W16X67
162 W16X57
163 W16X50
164 W16X45
165 W16X40
166 W16X36
167 W16X31
168 W16X26
169 W14X730
170 W14X665
171 W14X605
172 W14X550
173 W14X500
174 W14X455
175 W14X426
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176 W14X398
177 W14X370
178 W14X342
179 W14X311
180 W14X283
181 W14X257
182 W14X233
183 W14X211
184 W14X193
185 W14X176
186 W14X159
187 W14X145
188 W14X132
189 W14X120
190 W14X109
191 W14X99
192 W14X90
193 W14X82
194 W14X74
195 W14X68
196 W14X61197 W14X53
198 W14X48
199 W14X43
200 W14X38
201 W14X34
202 W14X30
203 W14X26
204 W14X22
205 W12X336
206 W12X305
207 W12X279
208 W12X252
209 W12X230
210 W12X210
211 W12X190
212 W12X170
213 W12X152
214 W12X136
215 W12X120
216 W12X106
217 W12X96
218 W12X87
219 W12X79
220 W12X72
221 W12X65
222 W12X58223 W12X53
224 W12X50
225 W12X45
226 W12X40
227 W12X35
228 W12X30
229 W12X26
230 W12X22
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231 W12X19
232 W12X16
233 W12X14
234 W10X112
235 W10X100
236 W10X88
237 W10X77
238 W10X68
239 W10X60
240 W10X54
241 W10X49
242 W10X45
243 W10X39
244 W10X33
245 W10X30
246 W10X26
247 W10X22
248 W10X19
249 W10X17
250 W10X15251 W10X12
252 W8X67
253 W8X58
254 W8X48
255 W8X40
256 W8X35
257 W8X31
258 W8X28
259 W8X24
260 W8X21
261 W8X18
262 W8X15
263 W8X13
264 W8X10
265 W6X25
266 W6X20
267 W6X15
268 W6X16
269 W6X12
270 W6X9
271 W6X8.5
272 W5X19
273 W5X16
274 W4X13
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Column Rows Bolts Gauge Pitch Ext. distance Sum of r2
nc nr n g p r Er
1 2 2 50 50 25.00 1,250.0
1 3 3 50 50 50.00 5,000.0
1 4 4 80 80 120.00 32,000.0
1 5 5 70 70 140.00 49,000.0
1 6 6 75 75 187.50 98,437.5
2 2 4 30 30 21.21 1,800.0
2 3 6 60 60 67.08 19,800.0
2 4 8 70 70 110.68 58,800.0
2 5 10 70 70 144.31 110,250.0
2 6 12 100 75 252.80 366,875.0
3 2 6 30 30 33.54 4,950.0
3 3 9 70 75 102.59 63,150.0
3 4 12 70 75 129.03 118,500.0
3 5 15 70 75 158.82 203,250.0
3 6 18 70 75 190.39 324,750.0
4 2 8 70 75 117.82 66,050.0
4 3 12 70 75 132.50 123,575.0
4 4 16 70 75 153.89 210,500.0
4 5 20 70 75 179.60 336,625.0
4 6 24 100 80 277.31 892,000.05 2 10 150 75 167.71 168,750.0
5 3 15 100 80 188.68 #N/A
5 4 20 100 80 219.32 506,000.0
5 5 25 100 80 256.12 820,000.0
5 6 30 100 80 296.82 1,259,000.0
6 2 12 100 80 206.16
6 3 18 100 80 223.61
6 4 24 100 80 250.00
6 5 30 100 80 282.84
6 6 36 100 80 320.16
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SHEET OF
Designed by: RBP
PROJECT: CLEVELAND CLINIC, ABU DHABI Checked by: KMK
SUBJECT: DESIGN OF CONNECTION DATE:
BEAM TO COLUMN - SHEAR CONNECTION USING FIN PLATE
INPUT DATA TO BE PROVIDED : Connection Identification SC-
Support
D = mm r = mm Weight = kG/m
B = mm D' = mm
tw = mm A = cm2
tf = mm n = mm
Connecting Member
D = mm r = mm Weight = kG/m
B = mm D' = mm
tw = mm A = cm2
tf = mm n = mm
Member End Reactions
UNFactored C = kN T = kN V = kN
C = kN T = kN V = kN
Connection Web
Grade of bolt =
Type of Connection =
Nominal Shear Strength of Bolt Fnv = M Pa
Nominal Tensile Strength of Bolt Fnt = M Pa
Nominal Strength of Weld Electrode material Use minimum E70 Electrode Fw = M Pa
Grade of material -Member = A Plate = AMinimum Tensile Strength -Member Fum = M Pa Plate Fup = M Pa
Minimum Yield Strength -Member Fym = M Pa Plate Fyp = M Pa
Diameter of bolt db = mm
Diameter of bolt hole dbh = mm
Nr of bolt columns nc =
Nr of bolt rows nr =
Spacing of bolt rows (pitch) p = mm
Spacing of bolt columns (gauge) g = mmHorizontal Edge distance for plate Leh,p = mm
Vertical End distance in plate at top Lev,pt = mm
Vertical End distance in plate at bottom Lev,pb = mm
Vertical End distance in member at top Lev,mt = mm
Vertical End distance in member at bottom Lev,mb = mm
Horizontal Edge distance for member Leh,m = mm
Distance between support & Connecting memb (setback) Sb = mm
Thickness of plate tp = mm
Thickness of reinforcement plate (doubler plate) twrp = mmNr of shear planes Ns =
Sum of square of 'r' for the bolt group e r2
= mm2
Minimum Bolt Pretension Tb = kN
Hole Factor for hsc =
Slip factor for m =
Size of weld sw = mm
Lenght of plate = mm Cope depth at top dct = mm
Width of plate = mm Cope depth at bottom dcb = mm
Thickness of plate = mm
EVERSENDAI ENGINEERING LLC
29-Jun-13
201.9
74.3
290
50
50
03
Grade 50
88.5
10
1
5
345
Grade 50
0
0
15
572
0 190
572450
414
Bearing Connection
450
345
285
70
0
A325-X
27
24
620
50
407.6
105.0
Standard Size Holes
94.6
0 0
14.5
9.0
25.0
0
15.2
290.2
374.6
374.7
0
6
Class A N.A.
380.0
190.4
10.0
457.0 10.2
UC 356x368x202
UB 457x191x74
16.5
27.0
257.0
0.0
45
88.5
N.A.
1
49000
1
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BEAM TO COLUMN - SHEAR CONNECTION USING FIN PLATE
SC-
Safe. Strength of one bolt = > Fb. ( )
Safe. Compression Strength of the plate = > Cw. ( )
Safe. Tensile Strength of the plate = > Tw. ( )
Safe. Compression Strength of the web = > Cw. ( )
Safe. Tensile Strength of the web = > Tw. ( )
Safe. Bearing Strength of the plate per bolt = > Fb. ( )
Safe. Bearing Strength of the web per bolt = > Fb. ( )
Safe. Shear Strength of the plate = > V. ( )
Safe. Shear Strength of the web = > V. ( )
Safe. Block Shear Strength of plate = > V. ( )
Safe. Block Shear Strength of web = > V. ( )
Safe. Axial Block Shear Strength of plate = > Fw,max. ( )
Safe. Axial Block Shear Strength of web = > Fw,max. ( )
Safe. Flexural Strength of the fin plate = > Mf. ( )
Since the beam is not Coped, this check is not required.
N.A. Flexural strength of the coped section = N.A. ( )
Safe. Weld strength for fillet of mm = kN > R. ( )
Interaction Check for Block Shear of plate
Interaction Check for Block Shear of web
Interaction Check for Fin plate
Lenght of plate Lp = mm
Width of plate Wp = mm
Thickness of plate tp = mm
Cope depth at top dnt = mm
Cope depth at bottom dnb = mm
0.57
0.49
0.53
N.A.
N.A.
0.41
kN 0.0
N.A.
N.A.
0.52
0.52
N.A.
184.78 kN
1277.09
kN
0.0
0.0
1179.90
826.875
0.00
0.0
285.0
10.0
17.10
285.0
75.1
285.0
285.0
kN.m.
0.574
75.1140.5 kN
3
kN.m
N.A.
0.23
0.52
kN
75.0
545.84
N.A.
N.A.
kN
586.85 kN
143.52 kN
75.1
kN
285.0
545.40
kN978.1
496.13 kN
0.0
0.41
0.23
6 700.37
380.0
105.0
0.27
0.27
0.0
728.33 kN 0.0
637.27 kN 0.0
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Length of cope c = mmN.A.
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EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT Reference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition
BEAM TO COLUMN - SHEAR CONNECTION USING FIN PLATE
Connection identification SC-
Supporting member D1 = mm tw1 = mm r1 = mm
UC 356x368x202 B1 = mm tf1 = mm D'1 = mm
A1 = cm2 n = mm
Supported member D2 = mm tw2 = mm r2 = mm
UB 457x191x74 B2 = mm tf2 = mm D'2 = mmA2 = cm2 n = mm
Member End Actions
UnFactored UnFactored
Compressive force C = kN kN
Tensile force T = kN kN
Shear force V = kN kN
Web connection
Connection details
Grade of bolt = Bearing Connection
Grade of material Rolled sections = A Plates -
Diameter of bolt db =
Diameter of bolt hole dbh =
Area of one nominal bolt Ab =
Effective area of one bolt Abn =
Nr of bolt column nc =
Nr of bolt rows nr =
Nr of bolts n =
Spacing of bolt rows (pitch) p =
Spacing of bolt coumns (gauge) g =
Horizontal Edge distance for plate Leh,p =
Horizontal Edge distance for member Leh,m =
Vertical End distance in plate at top Lev,pt =Vertical End distance in plate at bottom Lev,pb =
Vertical End distance in member at top Lev,mt =
Vertical End distance in member at bottom Lev,mb =
Distance between support & Conn.member Sb = (setback)
Length of plate Lp =
Width of plate Wp =
Thickness of plate tp = ( 1 - mm plate )
Thickness of reinforcement twrp =
Total thickness of web tw =
Least thickness of connected parts t =
Nr of shear planes Ns =
Sum of square of 'r' for the bolt group e r2
=
452.4
mm
16.5
24.0 mm
1
374.6
50.0
374.7
0.0
27.0
1
49000.0
45.0
50.0
5
15.2
290.2
0.0
10.2
407.6
0.0
285.0
0.0
70.0
mm
50.0mmmm
mm380.0
0.0
mm2
5
0.0
457.0
03
257.0
mm2
mm2
25.0
190.0
27.0
572
361.9
mm
10.0
9.0
mm
mm9.0
105.0
mm
mm
mm
mm
mm
88.5 mm
mm15.0
88.5 mm
190.4 14.5
0.0
9.0
03
A325-X
CLEVELAND CLINIC
572A
94.6
10
KMKJun 29, 2013
RBP
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EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
Reference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
Force in web
Due to compressive force C Cw = C
=
Due to tensile force T Tw = T
=
Maximum axial force in web Fw,max =
Vertical shear V =
Shear in bolt due to V Fv = V/n
=
Eccentricity of V about c.g. of bolt group e = Sb+Leh,m+0.5*(nc-1)*g
=
Moment due to eccentricity Me = V*e Since the conneciton is flexible, Moment
= transfered to bolts.
Distance of outermost bolt from cg of b. group r = Sqrt(((nc-1)*g/2)2+((nr-1)*p/2)
2)
=
Sum of square of 'r' for all bolts e r2
=
Vertical shear per bolt due to V FVl = V/n
=
Horizontal shear per bolt due to Fv,max FHl = Fw,max/n
=
Maximum shear in bolt due to Me Fm = Me*r/Er2
=Vertical shear due to Fm FVm = Fm * cosq q =
=
Horizontal shear due to Fm FHm = Fm * sinq
=
Total vertical shear FV =
Total horizontal shear FH =
Resultant shear in bolt Fb =
Check for bolts
Nominal Shear Strength of Bolt Fnv =
Nominal Tensile Strength of Bolt Fnt =
Minimum Bolt Pretension Tb =
Shear Strength of one bolt *Ps = *(Ns*Fnv*Ab) where,
= =
Slip resistance of one bolt
(Slip at required strength level) PSL = N.A.
hsc =
Slip factor m =
Minimum Bolt Pretension Tb =
PSL =
Strength of one bolt *Ps = > Fb. Safe.
0.00
kN
kN
414.0
140.5
0.0
N.A.
1.0
N.A.
kN
140.5
N.A.
57.00
620.0
48.86
kN
kN
kN
48.86
kN
kN
kN
0.00
57.00
kN
M Pa
M Pa
75.07
0.0
kN
kN
kN
kN
48.86
60.0
285.0
49000.0
17.10
kN
N.A.
140.0
mm
kN.m
mm2
mm
kN
kN
57.0
0.0
90
0.75
kN
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EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
ReferenceDESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
( )75.1
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7/28/2019 Fin Plate to Column Flange - LRFD
17/23
EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT Reference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
Check for connected plies
Rolled sections Plates
Grade of material = A Grade 50 = Grade
Minimum Tensile Strength Fum = Fup =
Minimum Yield Strength Fym = Fyp =
Slenderness ratio, KL/r = {K *L*sqrt(12)} / tp where, L = Leh,m + sb
= L = mm
For KL/r < 25, K =
Nominal compressive strength Pn = Fyp*Ag (E3.)
=
For KL/r > 25, Pn = Fcr*Ag
Elastic Buckling Critical Stress Fe =2*E/(KL/r)
2
=
4.71*sqrt(E/Fy) =
Flexural Buckling Stress Fcr = 0.658 (Fy/Fe) * Fy =
=
Compression Strength of the plate = Fcr*Ag
Ag = Lp*tp
=
Nominal compressive strength Pn =
Compressive strength of the plate *Pn = > Cw. Safe.
( )
Tensile Strength of the plate = Lower ( Tensile Yielding, Tensile Rupture)
Tensile Yielding of the plate *Rn = *(Fy*Ag) Where,
= =
Effective net area Ae = U*An < Ag
An = (Lp-nr*dbh)*tp
=
U =
Ae =
Tensile Rupture of the plate*
Rn =*
(Fu*Ae) Where,= =
Tensile Strength of the plate = > Tw. Safe.
( )
Compression Strength of the web *Pn = Limiting to Fy, since uncoped section,
Ag = (D2-dct-dcb)*tw Fcr =
=
Compression Strength of the web *Pn = > Cw. Safe.
( )
Tensile Strength of the web = Lower ( Tensile Yielding, Tensile Rupture)
Tensile Yielding of the web *Rn = *(Fy*Ag) Where,
= =
Effective net area Ae = U*An < Ag
An = (D2-dct-dcb-nr*dbh)*tw
kN
kN
kN
M Pa
1179.90
342.29
1311.00
113.40
10.39
0.0
mm2
0.90
0.0
kN
0.75
345.0
mm2
0.9
kN
0.0
0.5
0.9
3800
345.0
572
2450
1179.90
1300.68
18277.05
450.0
M Pa
kN
2450
mm2
1277.09
1277.1
826.875
1.0
4113
*(Fcr*Ag)
826.875
A 572
450.0 M P
345.0 M P
mm2
kN
M Pa
M Pa
kN
60.0
M Pa
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EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
ReferenceDESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
= mm2
2898
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19/23
EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECTReference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
U =
Ae =
Tensile Rupture of the web *Rn = *(Fu*Ae) Where,
= =
Tensile Strength of the web = > Tw. Safe.
( )
Bearing Strength of the plate per bolt *Rn
= *(1.5*Lc*t*Fu) Fb. Safe.
( )
Bearing Strength of the web per bolt *Rn = *(1.5*Lc*t*Fu) Fb. Safe.
( )
Shear Strength of the plate = Lower ( Shear Yielding, Shear Rupture)
Shear Yielding of the plate *Rn = *(0.6*Fy*Ag) Where,
= =
Net Area subjected to shear Anv = (Lp-nr*dbh)*tp
=
Anv =
Shear Rupture of the plate *Rn = *(0.6*Fu*Anv) Where,
= =
Shear Strength of the plate V p = > V. Safe.
( )
Shear Strength of the web = Lower ( Shear Yielding, Shear Rupture)
Shear Yielding of the web *Rn = *(0.6*Fy*Ag) Where,
= =
Net Area subjected to shear Anv = (D2-dct-dcb-nr*dbh)*tw
=Anv =
Shear Rupture of the web *Rn = *(0.6*Fu*Anv) Where,
= =
Shear Strength of the web V w = > V. Safe.
( )
Block shear strength of Plate *Rn = {(0.6*Fu*Anv+Ubs*Fu * Ant)}* Where,
< {(0.6*Fy*Agv+Ubs*Fu * Ant)}* =
Gross area subject to shear Agv = {(nr-1)*p+Lev,pt} * tp
=
Gross area subject to tension Agt
= {(nc-1)*g+L
eh,p} * t
p=
Net area subject to shear Anv = {(nr-1)*p+Lev,pt+0.5*dbh - nr*dbh} * tp
=
mm2
kN
kN
kN
kN
3300
500
586.85
75.1
75.1
kN
285.0
mm2
mm2
kN
0.75
0.0
285.0
0.75
1.0
0.75
kN
1.0
2085
496.13
2898
496.125
851.4
31.5
2450
36.5
786.6
184.78
143.52
mm2
mm2
kN
2450
586.8
2898
mm2
mm2
kN
978.1
1.0
978.1
KN
2898
0.75
mm2
-
7/28/2019 Fin Plate to Column Flange - LRFD
20/23
EVERSENDAI ENGINEERING LLC Sheet
PROJECT Job No Designed by
Date Checked by
SUBJECTReference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
Net area subject to tension Ant = {(nc-1)*g+Leh,p+0.5*dbh - nc*dbh} * tp
=
Reduction Coefficient for block shear Ubs =
Block shear strength of plate = > V. Safe.
( )
Block shear strength of Beam Web *Rn = {(0.6*Fu*Anv+Ubs*Fu * Ant)}* Where,
< {(0.6*Fy*Agv+Ubs*Fu * Ant)}* =
Gross area subject to shear Agv = {(nr-1)*p+Lev,mt } * tw
=
Gross area subject to tension Agt = {(nc-1)*g+Leh,m} * tw
=
Net area subject to shear Anv = {(nr-1)*p+Lev,m t+0.5*dbh - nr*dbh} * tw
=
Net area subject to tension Ant = {(nc-1)*g+Leh,m+0.5*dbh - nc*dbh} * tw
=
Block shear strength of beam web = > V. Safe.
( )
Axial Block shear strength of Plate *Rn = {(0.6*Fu*Anv+Ubs*Fu * Ant)}* Where,
< {(0.6*Fy*Agv+Ubs*Fu * Ant)}* =
Gross area subject to shear Agv = {(nc-1)*g+Leh,p} * tp * 2
=
Gross area subject to tension Agt = {(nr-1)*p} * tp=
Net area subject to shear Anv = {(nc-1)*g+Leh,p+0.5*dbh - nc*dbh} * tp * 2
=
Net area subject to tension Ant = {(nr-1)*p+ dbh - nr*dbh} * tp
=
Reduction Coefficient for block shear Ubs =
Axial Block shear strength of plate = > Fw,max. Safe.
( )
Axial Block shear strength of Beam Web *Rn = {(0.6*Fu*Anv+Ubs*Fu * Ant)}* Where,
< {(0.6*Fy*Agv+Ubs*Fu * Ant)}* =
Gross area subject to shear Agv = {(nc-1)*g+Leh,m} * tw* 2
=Gross area subject to tension Agt = {(nr-1)*p } * tw
=
Net area subject to shear Anv = {(nc-1)*g+Leh,m+0.5*dbh - nc*dbh} * tw* 2
=
Net area subject to tension Ant = {(nr-1)*p+dbh - nr*dbh} * tw
=
Axial Block shear strength of beam web = > Fw,max. Safe.
( )
Flexural Strength of the fin plate (F11)
Moment in fin plate Mf =
Plastic section modulus of the fin plate Zf = tp*(Lp2-p
2*nr*(nr
2-1)*dbh/Lp)/4
=
Elastic section modulus of the fin plate Sf = tp*d2/6
=
Yielding Lb*d/t2
0.08*E/Fy , Mn = Mp = Fy Zf < 1.6My
length between point that braced againts Lb = mm
1
3316.5
mm3
kN.m
0.0
mm2
365
kN
kN
mm2
0.0
mm2
285.0
285.0
mm2
256553
17.10
545.84
2223
283.5
mm2
mm2
1
545.40
405
60.0
171035
0.75
1000 mm2
2800 mm2
730 mm2
1720
728.33
0.75
810 mm2
2520 mm2
kN
0.75
567 mm2
1548 mm2
mm3
637.27 kN
-
7/28/2019 Fin Plate to Column Flange - LRFD
21/23
EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
Reference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
twist of cross section
depth of plate d = mm
thickness of plate t = mm
Lb*d/t2
=
Cb =
0.08*E/Fy =
Nominal Flexural Strength, Mn = 345 * 256552.6315 < 1.6My
=
Mn = Mp =
Lateral-Torsional Buckling
0.08*E/Fy < Lb*d/t2 1.9*E/Fy =
1.9*E/Fy =
My = Fy*Sf
=
Nominal Flexural Strength, Mn = Cb*{1.52-0.274(Lb*d/t2)*(Fy/E)}*My < Mp
=
Lb*d/t2
> 1.9*E/Fy
Nominal Flexural Strength, Mn = Fcr Sf < Mp
Fcr = 1.9E*Cb/(Lb*d/t2)
= Mpa
Mn = 1666.667 * 171035.087719298
Nominal Flexural Strength, Mn =
Nominal Flexural Strength, Mn =Flexural strength of fin plate *Mn = > Mf. Safe.
( )
Interaction check for Axial & Moment = (< 1 Safe)
Check for Coped beam
Cope depth at top dct =
Cope depth at bottom dcb =
Cope length c = (Assumed 15mm gap)
Since the beam is not Coped, this check is not required.
Design load V =
Eccentricity about the notched section e =
Moment at the Cope M' =
Depth of beam at coped section ho =
Breadth of flange B2' = =
Area of web at coped section Aw' = tw*ho
=
Area of flange at coped section Af' = tf2*(B2'-tw)
=
Distance of c.g. from soffit of the beam c1 = (Af*tf2/2+Aw*ho/2)/(Af+Aw)
=
M.I. of the coped section I' =
Extreme fibre distance h1 =
Sectional modulus at coped section Snet =
Flexure rupture strength for a beam = Mn /
coped at the top flange or both the =top and bottom flanges Mn = Fum Snet
Nominal rupture strength = #
0.9
cm3
mm
mm
cm4
mm2
2
1101.45
mm
0
228.50
142.2
1.67
mm
mm
kN.m.
285.0
mm2
0.23
59.01 kN.m
75.0083.33
1666.67
kN.m
kN.m
17.10
83.33
10.0
kN.m
kN.m
457.0
2630.3
190.4
380.0
N.A.
N.A.
0.0
0.0
88.51 kN.m
88.51 kN.m
46.4
1
228.0
0.0
88.51
N.A.
mm
mm
mm
kN
4113.0
-
7/28/2019 Fin Plate to Column Flange - LRFD
22/23
EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
Reference
DESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
=
Flexural rupture strength Mn / =
Flexure local buckling strength for a beam = Mn /
coped at the top flange or both the =
top and bottom flanges Mn = Fcr Snet
Nominal rupture strength = #
= Poisson ration, n =
Available buckling stress Fcr = p2
E (tw/h1)2*f*k
for a beam coped at the top flange only 12(1-n^2)
Plate buckling model adjustment factor f = 2c / d when c/d < 1.0 c/d = N.A./457
= 1 + c/d when c/d > 1.0 =f = c/h1 = N.A./228.5
Plate bucking coefficient k = 2.2 (h1/c)^1.65 when c/h1 < 1.0 =
= 2.2 (h1/c) when c/h1 > 1.0
k =
Fcr = For c
-
7/28/2019 Fin Plate to Column Flange - LRFD
23/23
EVERSENDAI ENGINEERING LLC Sheet of
PROJECT Job No Designed by
Date Checked by
SUBJECT
ReferenceDESIGN OF STEEL WORK CONNECTIONS SC- AISC 13th Edition03
CLEVELAND CLINIC
KMKJun 29, 2013
RBP
( )285.00