\nRelative test critical load<\/td>\n 1<\/td>\n 3.71<\/td>\n 2.31<\/td>\n 0.72<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/figure>\nIt is to be expected that there will be some differences between the predicted and the test critical loads, but significant error occurs in the fixed-free model (Table10-2). Several trials showed that the free-end at the bottom of the strut was not really free to move laterally due to small amount of friction. In addition, the column is shorter than the others, which can be seen in Fig. 10-6a. Real structures rarely behave in exactly the same manner as the theoretical models.<\/p><\/p><\/div>Model 3<\/label>
Lateral buckling of beams<\/h5>\n This set of models demonstrates the behaviour of lateral buckling of a narrow rectangular beam with different sizes of section and thus the validity of Eq. 10-8.<\/em><\/p>\n\n
\n
a) Model A <\/figcaption><\/figure>\n<\/div>\n\n
b) Model B <\/figcaption><\/figure>\n<\/div>\n\n
c) Model C<\/figcaption><\/figure>\n<\/div>\n<\/div>\nFig. 10-7: Lateral torsional buckling behaviour<\/p>\n
The buckling behaviour of the three brass cantilevers described in Example 10-1 is demonstrated through simple tests. One end of each of the brass strips is fixed to a wooden block through screws, creating cantilevers as shown in Fig. 10-7.<\/p>\n
Model A: 270 mm long cantilever with a 12.7 mm x 0.397 mm rectangular cross-section<\/strong>Model B: 270 mm long cantilever with a 25.4 mm x 0.397 mm rectangular cross-section<\/strong>Model C: 270 mm long cantilever with a 12.7 mm x 0.794 mm rectangular cross-section<\/strong>Model D: Model A with a lateral support<\/strong>Table 10-3: Comparison between the calculated and measured lateral buckling loads<\/p>\n\n\n\n\nBoundary conditions<\/td>\n Model A<\/td>\n Model B<\/td>\n Model C<\/td>\n<\/tr>\n \nTheoretical critical load ( N )<\/td>\n 0.462<\/td>\n 0.924<\/td>\n 3.70<\/td>\n<\/tr>\n \nRelative theorectical critical load<\/td>\n 1<\/td>\n 2<\/td>\n 8<\/td>\n<\/tr>\n \nTest critical load ( N )<\/td>\n 0.49<\/td>\n 0.98<\/td>\n 3.83<\/td>\n<\/tr>\n \nRelative test critical load<\/td>\n 1<\/td>\n 2<\/td>\n 7.8<\/td>\n<\/tr>\n<\/tbody>\n<\/table>\n<\/figure><\/p><\/div>Model 4<\/label>
Buckling of an empty aluminum can<\/h5>\n This demonstration shows that local buckling occurred on a drinks can causes the global collapse of the can.<\/em><\/p>\n\n
\n
(a)<\/figcaption><\/figure>\n<\/div>\n\n
(b)<\/figcaption><\/figure>\n<\/div>\n<\/div>\nFig. 10-8: Buckling failure of empty drinks cans<\/p>\n
The phenomenon of buckling is not limited to columns. Buckling can occur in many kinds of structures and can take many forms. Fig. 10-8a shows that two empty drinks cans can carry a standing person of 65 kg. However, this is close to the critical loads of the two cans. When the standing person slightly moved his body, which caused a small shift of some of the body weight from one can to the other, the thin cylindrical wall of one can buckled and the cans then collapsed completely as shown in Fig. 10-8b.<\/p><\/p><\/div><\/div><\/div>\n\n\n\n
Practical Examples<\/h3>\n\n\nExample 1<\/label>
Buckling of bracing members<\/h5>\n\n
\n
a) Buckling of a bracing member in a storage rack (Courtesy of Dr A Mann, Jacobs)<\/figcaption><\/figure>\n<\/div>\n\n
b) Buckling of two bracing members in a building<\/figcaption><\/figure>\n<\/div>\n<\/div>\nFig. 10-9: Buckling of bracing members<\/p>\n
Steel bracing members are normally slender and are not ideal for use in compression. Therefore they are usually designed to transmit tension forces only. For cross-braced panels which are often used to resist lateral loads, one bracing member will be in tension and the other in compression. When the loading is applied in the opposite direction, the member previously in tension will be subjected to compression and the other member becomes a tension member.<\/p>\n
Fig. 10-9a shows one of two bracing members in a panel of a storage rack which has buckled. Comparing the value of the material stored and cost of the bracing members, the use of more substantial bracing members would have easily been justified. Fig. 10-9b shows two buckled bracing members in a building.<\/p><\/p><\/div>Example 2<\/label>
Buckling of a box girder<\/h5>\n\n
Fig. 10-10: Buckling of a box girder (Courtesy of Dr A Mann, Jacobs)<\/figcaption><\/figure>\n<\/div>\nFig. 10-10 shows a box girder that buckled during an earthquake. The girder was subjected to large compressive forces and the material was also squashed.<\/p><\/p><\/div>Example 3<\/label>
Prevention of lateral buckling of beams<\/h5>\n\n
Fig. 10-11: Additional supports provided to prevent lateral torsional buckling (Courtesy of Westok Ltd)<\/figcaption><\/figure>\n<\/div>\nFig. 10-11 shows a system where additional members are provided to prevent the lateral and torsional buckling of cantilever beams through reducing the beam length. Cellular beams are used as supporting structures for the cantilever roof of a grandstand. The lower parts of the beams are subjected to compressive forces, but the lateral supports from the roof cladding on the top of the beams may not be effective at preventing lateral and torsional buckling at the bottom parts of the beams, thus additional members are placed perpendicular to the beams.<\/p>\n
\n
\n
\n
Fig. 10-12: Members are provided to prevent the lateral buckling of arches<\/p>\n
Fig. 10-12 shows the lateral supports provided to two arch bridges. The loads on the bridges are transmitted through mainly the compression forces in arches to the supports of the arches. Thus lateral supports are provided to prevent any possible lateral buckling.<\/p><\/p><\/div>Example 4<\/label>
Example 4: Bistability of a slap band<\/h5>\n Bistability is a fundamental phenomenon in nature. A slap band that is bistable can be at rest in two equilibrium states. By default, the band will be in the state with the minimum energy as shown on the right side in Figure 10.A1a. A transition from the state of minimal energy to the other state of equilibrium that has maximum energy requires some form of activation energy to be provided. If one stretches the band into a straight position, it can be held as shown in Figure 10.A1b. If a little disturbance is given to the straight band which corresponds to the state of maximum energy, the band will relax into the state of lowest energy again.<\/p>\n
\n
\n
a) Equilibrium with the smallest energy<\/figcaption><\/figure>\n<\/div>\n\n
b) Equilibrium with the largest energy<\/figcaption><\/figure>\n<\/div>\n<\/div>\nFigure 10.A1: A slap band at its two equilibrium states with the largest and smallest energies<\/p>\n
Reflective slap bands, as shown in Figure 10.A1, have high visibility and became a safety product, which can be wrapped round wrists, arms and legs. Due to the interesting nature of bistability and low cost, slap bands are also used as a promotion product.<\/p><\/p><\/div><\/div><\/div>\n\n\n\n
References<\/h3>\n\n\n\n 10.1 Benham, P P, Crawford, R J and Armstrong, C G, (1998), Mechanics of Engineering Materials, Addison Wesley Longman Limited, Harlow, ISBN 0-582-25164-8.<\/p>\n\n\n\n
10.2 Kirby, P A and Nethercot, D A, (1979), Design for Structural Stability, Granada Publishing, London, ISBN 0258 97063 4.<\/p>\n\n\n\n
10.3 Gere J M (2004), Mechanics of Materials, Sixth Edition, Thomson Books\/Cole, USA, ISBN 0-534-41793-0.<\/p>\n\n\n\n
10.4 Allen H G and Bulson P S, (1980), Background of Buckling, McGraw-Hill, New York, ISBN 0-07-084100-4.<\/p>\n\n\n\n
10.5 Timoshenko S P and Gere J M, (1961), Theory of Elastic Stability, McGraw-Hill, New York, ISBN 0-07-085821-7.<\/p>\n","protected":false},"excerpt":{"rendered":"
Buckling Buckling of columns : When a slender structural member is loaded with an increasing axial compression force, the member deflects laterally and fails by combined bending and compression rather than by direct compression alone. This phenomenon is called buckling. Critical load of a structure is the load which creates the borderline between stable and unstable equilibrium […]<\/p>\n","protected":false},"author":3,"featured_media":0,"parent":0,"menu_order":0,"comment_status":"closed","ping_status":"closed","template":"page-statics.php","meta":{"_genesis_hide_title":false,"_genesis_hide_breadcrumbs":false,"_genesis_hide_singular_image":false,"_genesis_hide_footer_widgets":false,"_genesis_custom_body_class":"","_genesis_custom_post_class":"","_genesis_layout":"","footnotes":""},"class_list":{"0":"post-1080","1":"page","2":"type-page","3":"status-publish","5":"entry"},"yoast_head":"\n
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. Increasing the value of the second moment of area of the section I and\/or reducing the length L will increase the critical load.<\/li><\/ul>\n\n\n\n