New hybrid approach for free vibration and stability analyses of axially functionally graded Euler-Bernoulli beams with variable cross-section resting on uniform Winkler-Pasternak foundation

Soltani, Masoumeh; Asgarian, Behrouz

doi:10.1590/1679-78254665

Masoumeh Soltani ^**Corresponding author

Department of Civil Engineering, Faculty of Engineering, University of Kashan, Kashan, Iran. E-mail: msoltani@kashanu.ac.ir

https://orcid.org/0000-0002-5377-032X

Behrouz Asgarian

Civil Engineering Faculty, K.N.Toosi University of Technology, Tehran, Iran. E-mail: asgarian@kntu.ac.ir

https://orcid.org/0000-0001-6052-7515

*Corresponding author

Figures (10)
Tables (7)

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Figure 1:
Non-prismatic beam resting on a two-parameter elastic foundation

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Figure 2:
Boundary conditions of a beam element in global and local coordinate systems.

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Figure 3:
Members with various end conditions; left and right sections corresponding to cases A to C.

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Figure 4:
(a) Schematic representation of AFG beam with exponentially tapered cross-section, (b) Exponentially varying width along member, (c) Constant thickness through beam’s length.

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Figure 5:
Variations of the non-dimensional free transverse frequency of AFG exponentially tapered beam with respect to non-uniformity parameter: (a) Simply supported, (b) Cantilever, (c) Clamped-Pinned

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Figure 6:
Variations of the non-dimensional buckling load parameter of AFG exponentially tapered beam with respect to non-uniformity parameter: (a) Simply supported, (b) Cantilever, (c) Clamped-Pinned

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Figure 7:
Convergence of non-dimensional natural frequency of simply supported Euler-Bernoulli beam resting on one or two parameter elastic foundation: (a) homogeneous beam with constant cross-section, (b) AFG beam with constant cross-section, (c) homogeneous tapered beam, (d) AFG tapered beam.

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Figure 8:
Convergence of normalized buckling load parameter of simply supported Euler-Bernoulli beam resting on one or two parameter elastic foundation: (a) homogeneous beam with constant cross-section, (b) AFG beam with constant cross-section, (c) homogeneous tapered beam, (d) AFG tapered beam.

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Figure 9:
Influence of Winkler type elastic foundation modulus on the natural frequency parameters of (a) pinned-ended beams, (b) clamped-pinned beams

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Figure 10:
Influence of Winkler type elastic foundation modulus on the critical buckling load parameters of (a) pinned-ended columns, (b) clamped-pinned columns

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Table 1:
Convergence of the proposed numerical technique in determination of the first non-dimensional vibration frequency (ω_nor) and normalized buckling load (P_nor) of tapered beam (Case B) with two different end conditions.

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Table 2:
Effect of power series terms on the non-dimensional natural frequency (ω_nor) and buckling load (P_nor) of double tapered beam with two different end conditions and CPU time comparisons

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Table 3:
Normalized natural frequencies for columns of different cases (A, B and C) with various boundary conditions

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Table 4:
Normalized critical buckling loads for columns of different cases (A, B and C) with various boundary conditions

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Table 5:
Natural frequencies comparison of power series method and finite element results for simply supported beam

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Table 6:
The effect of number of power series terms (P _nor ) on precision of normalized critical axial load parameter for homogenous exponentially tapered beams with different boundary conditions

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Table 7:
Natural frequency and Critical axial load parameters (

ω_{n o r}, P_{n o r}

) for simply supported beams resting on two-parameter elastic foundation.

Case	End Conditions	β	Type of Analysis	Number of terms of power series (PSM)					ANSYS
Case	End Conditions	β	Type of Analysis	n=10	n=20	n=30	n=40	n=50
B	Hinged-Hinged	0	(ω_nor)	9.6730	9.8696	9.8696	9.8696	9.8696	9.7980
		0	(P_nor)	9.8820	9.8696	9.8696	9.8696	9.8696	9.8700
		0.2	(ω_nor)	8.8944	8.8462	8.8462	8.8462	8.8462	8.8172
		0.2	(P_nor)	7.0133	7.0456	7.0456	7.0456	7.0456	7.0556
		0.6	(ω_nor)	6.8076	6.4754	6.4667	6.4666	6.4666	6.4542
		0.6	(P_nor)	2.5324	2.6774	2.6789	2.6789	2.6789	2.6638
	Clamped-Free	0	(ω_nor)	3.5073	3.5160	3.5160	3.5160	3.5160	3.5040
		0	(P_nor)	2.4669	2.4674	2.4674	2.4674	2.4674	2.4670
		0.2	(ω_nor)	3.6273	3.6083	3.6083	3.6083	3.6083	3.6027
		0.2	(P_nor)	2.0241	2.0233	2.0233	2.0233	2.0233	2.0203
		0.6	(ω_nor)	4.7193	3.9660	3.9351	3.9343	3.9343	3.9557
		0.6	(P_nor)	0.7016	1.1273	1.0999	1.0999	1.0999	1.0970

Case	End Conditions	β	Type of Analysis	Number of terms of power series (PSM)					ANSYS
Case	End Conditions	β	Type of Analysis	n=10	n=20	n=30	n=40	n=50
C	Hinged-Hinged	0.2	Vibration	8,8933	8.8246	8.8246	8.8246	8.8246	8.7952
			(ω_nor )	(3.14s)	(7.98s)	(17.92s)	(125.82s)	(3088.7s)	8.7952
			Stability	6.2364	6.2668	6.2668	6.2668	6.2668	6.2846
			(P_nor)	(4.88s)	(11.95s)	(25.81s)	(140.31s)	(3314.6s)	6.2846
		0.6	Vibration	6.8936	6.2346	6.2092	6.2086	6.2085	6.1952
			(ω_nor)	(2.89s)	(8.85s)	(22.64s)	(133.62s)	(3522.6s)	6.1952
			Stability	1.4466	1.5933	1.5958	1.5958	1.5958	1.6006
			(P_nor)	(4.51s)	(12.75s)	(31.28s)	(148.12s)	(3607.1s)	1.6006
	Clamped-Free	0.2	Vibration	3.8802	3.8551	3.8551	3.8551	3.8551	3.8166
			(ω_nor)	(5.02s)	(11.56s)	(25.54s)	(142.79s)	(3504.8s)	3.8166
			Stability	1.9164	1.8835	1.8835	1.8835	1.8835	1.8821
			(P_nor)	(8.38s)	(17.07s)	(37.72s)	(160.11s)	(3690.4s)	1.8821
		0.6	Vibration	6.1174	5.0720	5.0113	5.009	5.0090	5.0803
			(ω_nor)	(5.04s)	(11.84s)	(25.80s)	(147.32s)	(3628.7s)	5.0803
			Stability	0.8758	0.8163	0.7658	0.7624	0.7624	0.7605
			(P_nor)	(7.11s)	(17.75s)	(34.99s)	(164.18s)	(3819.6s)	0.7605

Case	β	Free Vibration Analysis
		Hinged-Hinged			Clamped-Free			Clamped-Hinged
		ANSYS	Present Method	$Δ (%)$	ANSYS	Present Method	$Δ (%)$	ANSYS	Present Method	$Δ (%)$
A	0.1	9.792	9.868	0.776	3.618	3.631	0.359	15.540	15.527	0.084
	0.3	9.785	9.860	0.766	3.901	3.916	0.384	15.784	15.768	0.101
	0.5	9.752	9.825	0.748	4.297	4.315	0.418	16.065	16.044	0.131
	0.7	9.748	9.747	0.010	4.949	4.932	0.343	16.385	16.351	0.208
	0.9	9.545	9.563	0.188	6.091	6.084	0.115	16.720	16.724	0.024
B	0.1	9.306	9.368	0.666	3.547	3.559	0.338	14.862	14.849	0.087
	0.3	8.253	8.302	0.594	3.655	3.667	0.328	13.658	13.640	0.132
	0.5	7.093	7.122	0.409	3.813	3.824	0.288	12.328	12.300	0.227
	0.7	5.736	5.745	0.157	4.134	4.082	1.258	10.788	10.737	0.473
	0.9	3.885	3.976	2.342	4.713	4.754	0.870	8.772	8.879	1.220
C	0.1	9.301	9.362	0.656	3.661	3.674	0.355	14.969	14.955	0.094
	0.3	8.206	8.250	0.536	4.050	4.067	0.419	13.982	13.962	0.143
	0.5	6.926	6.957	0.448	4.610	4.625	0.325	12.883	12.850	0.256
	0.7	5.348	5.359	0.206	5.499	5.512	0.236	11.620	11.577	0.370
	0.9	3.045	3.063	0.591	7.267	7.300	0.454	10.097	10.159	0.617

Case	β	Stability Analysis
		Hinged-Hinged			Clamped-Free			Clamped-Hinged
		Wang et al. (2005Wang C.M, Wang, C.Y and Reddy J.N. (2005). “Exact Solutions for Buckling of Structural Members”. CRC Press LLC, Florida. )	Present Method	$Δ (%)$	Wang et al. (2005Wang C.M, Wang, C.Y and Reddy J.N. (2005). “Exact Solutions for Buckling of Structural Members”. CRC Press LLC, Florida. )	Present Method	$Δ (%)$	Wang et al. (2005Wang C.M, Wang, C.Y and Reddy J.N. (2005). “Exact Solutions for Buckling of Structural Members”. CRC Press LLC, Florida. )	Present Method	$Δ (%)$
A	0.1	9.372	9.372	0.000	2.393	2.393	0.000	19.170	19.168	0.010
	0.3	8.343	8.343	0.000	2.235	2.235	0.000	17.030	17.035	0.029
	0.5	7.256	7.256	0.000	2.062	2.062	0.000	14.740	14.739	0.007
	0.7	6.069	6.069	0.000	1.865	1.879	0.751	12.180	12.177	0.025
	0.9	4.667	4.672	0.107	1.621	1.631	0.617	9.029	9.083	0.598
B	0.1	8.436	8.434	0.024	2.246	2.246	0.000	17.250	17.252	0.012
	0.3	5.840	5.840	0.000	1.798	1.798	0.000	11.920	11.923	0.025
	0.5	3.628	3.628	0.000	1.336	1.336	0.000	7.362	7.362	0.000
	0.7	1.821	1.806	0.824	0.853	0.861	0.938	3.634	3.604	0.834
	0.9	0.471	0.474	0.637	0.321	0.325	1.246	0.875	0.881	0.686
C	0.1	7.994	7.994	0.000	2.175	2.175	0.000	16.350	16.354	0.024
	0.3	4.836	4.836	0.000	1.595	1.595	0.000	9.893	9.893	0.000
	0.5	2.467	2.470	0.122	1.029	1.029	0.000	5.048	5.058	0.198
	0.7	0.888	0.894	0.676	0.498	0.502	0.803	1.817	1.832	0.825
	0.9	0.099	0.100	0.909	0.080	0.081	1.250	0.202	0.205	1.485

α	Vibration Mode	Number of terms of power series (PSM)			Exact Solution
α	Vibration Mode	n=10	n=20	n=30	n=40	n=50	Ece et al. (2007)
0	1	9.673	9.8696	9.8696	9.8696	9.8696	9.8696
	2	-	39.41691	39.4784	39.4784	39.4784	39.4784
	3	-	149.0075	88.81072	88.8264	88,8264	88.8266
1	1	9.65319	9.7729	9.7729	9.7729	9.7729	9.7729
	2	-	39.6464	39.5704	39.5704	39.5704	39.5704
	3	-	77.7059	88.9738	88.9705	88.9705	88.9705

End Conditions	α	Number of terms of power series (PSM)				Wang et al. (2005Wang C.M, Wang, C.Y and Reddy J.N. (2005). “Exact Solutions for Buckling of Structural Members”. CRC Press LLC, Florida. )		$Δ (%)$
End Conditions	α	n=10	n=20	n=30	n=40	n=50
Hinged-Hinged	-0.1	9.0847	9.3857	9.3857	9.3857	9.3857	9.380	0.061
	-0.5	8.1909	7.6345	7.6345	7.6345	7.6345	7.634	0.006
	-1.0	5.7210	5.8266	5.8265	5.8265	5.8265	5.827	0.009
	-1.5	3.7071	4.3873	4.3885	4.3885	4.3885	4.389	0.011
	-2.0	2.6917	3.2624	3.2636	3.2636	3.2636	3.264	0.012
Clamped- Free	-0.1	2.3970	2.3945	2.3945	2.3945	2.3945	2.394	0.021
	-0.5	2.0973	2.1121	2.1121	2.1121	2.1121	2.110	0.100
	-1.0	1.7976	1.7821	1.7821	1.7821	1.7821	1.782	0.006
	-1.5	1.7190	1.4804	1.4803	1.4803	1.4803	1.480	0.020
	-2.0	1.8681	1.2092	1.2093	1.2093	1.2093	1.209	0.025
Clamped- Hinged	-0.1	17.8937	19.2016	19.2018	19.2018	19.2018	19.200	0.009
	-0.5	14.2300	15.6388	15.6399	15.6399	15.6399	15.640	0.001
	-1.0	8.8990	11.9984	11.9884	11.9884	11.9884	11.990	0.013
	-1.5	5.7520	9.0437	9.0980	9.0980	9.0980	9.098	0.000
	-2.0	4.9715	6.7942	6.8397	6.8397	6.8397	6.839	0.010

Material	(β)	The Pasternak foundation constant ( ${\bar{k}}_{G}$ )	Non-dimensional bending frequency					Non-dimensional critical buckling load
			The Winkler foundation constant ( ${\bar{k}}_{w}$ )					The Winkler foundation constant ( ${\bar{k}}_{w}$ )
			0	20	40	60	80	0	20	40	60	80
Homogeneous	0	0	9.8696	10.8340	11.7207	12.5449	13.3182	9.8694	11.8965	13.9236	15,9507	17,9778
		2	10.8217	11.7093	12.5343	13.3082	14.0395	11.8694	13.8965	15.9236	17,9507	19,9778
		4	11.6979	12.5236	13.2982	14.0300	14.7255	13.8694	15.8965	17.9236	19,9507	21,9778
		6	12.5130	13.2881	14.0205	14.7165	15.3810	15.8694	17.8965	19.9236	21,9507	23,9778
		8	13.2781	14.0109	14.7074	15.3723	16.0096	17.8694	19.8965	21.9236	23,9507	25,9778
	0.5	0	6.9566	9.2419	11.0495	12.5923	13.9584	2.4891	4.3334	6.0834	7,6699	9,0018
		2	9.2683	11.0618	12.5956	13.9558	15.1891	4.4891	6.3334	8.0834	9,6699	11,0018
		4	11.0660	12.5938	13.9499	15.1805	16.3142	6.4891	8.3334	10.0834	11,6699	13,0018
		6	12.5885	13.9418	15.1706	16.3031	17.3582	8.4891	10.3334	12.0834	13,6699	15,0018
		8	13.9322	15.1597	16.2915	17.3462	18.3373	10.4891	12.3334	14.0834	15,6699	17,0018
Axially Functionally Graded m=2	0	0	9.5994	10.7618	11.8099	12.7718	13.6657	7.8308	9.8396	11.8455	13,8478	15,8453
		2	10.7502	11.7989	12.7614	13.6557	14.4947	9.8308	11.8396	13.8455	15,8478	17,8453
		4	11.7877	12.7507	13.6456	14.4849	15.2778	11.8308	13.8396	15.8455	17,8478	19,8453
		6	12.7399	13.6353	14.4750	15.2683	16.0220	13.8308	15.8396	17.8455	19,8478	21,8453
		8	13.6248	14.4650	15.2587	16.0128	16.7326	15.8308	17.8396	19.8455	21,8478	23,8453
	0.5	0	6.5127	9.3065	11.4053	13.1480	14.6634	1.7011	3.3688	4.7855	5,8456	6,5903
		2	9.3724	11.4325	13.1540	14.6577	16.0058	3.7011	5.3688	6.7855	7,8456	8,5903
		4	11.4441	13.1525	14.6487	15.9930	17.2215	5.7011	7.3688	8.7855	9,8456	10,5903
		6	13.1464	14.6377	15.9795	17.2072	18.3441	7.7011	9.3688	10.7855	11,8456	12,5903
		8	14.6252	15.9654	17.1928	18.3302	19.3938	9.7011	11.3688	12.7855	13,8456	14,5903

[1] *Corresponding author

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New hybrid approach for free vibration and stability analyses of axially functionally graded Euler-Bernoulli beams with variable cross-section resting on uniform Winkler-Pasternak foundation

Abstract