Numerical simulation of composite steel-concrete alveolar beams: web-post buckling, Vierendeel and flexural mechanisms

Benincá, Matheus Erpen; Morsch, Inácio Benvegnu

doi:10.1590/1679-78256062

Matheus Erpen Benincá ^** Corresponding author

Programa de Pós-Graduação em Engenharia Civil, Universidade Federal do Rio Grande do Sul, Porto Alegre, RS, Brasil. E-mail: matheuseb@hotmail.com, morsch@ufrgs.br

https://orcid.org/0000-0003-4852-6127

Inácio Benvegnu Morsch

Programa de Pós-Graduação em Engenharia Civil, Universidade Federal do Rio Grande do Sul, Porto Alegre, RS, Brasil. E-mail: matheuseb@hotmail.com, morsch@ufrgs.br

https://orcid.org/0000-0002-2473-3474

* Corresponding author

Author’s Contributions:

Conceptualization, ME Benincá and IB Morsch; Investigation, ME Benincá; Methodology, ME Benincá and IB Morsch; Software, ME Benincá; Supervision, IB Morsch; Validation, ME Benincá and IB Morsch; Visualization, ME Benincá; Writing - original draft, ME Benincá; Writing - review & editing, ME Benincá and IB Morsch.

Editor:

Marco L. Bittencourt.

	Present Work	Müller et al. (2006Müller, C., Hechler, O., Bureau, A., Bitar, D., Joyeux, D., Cajot, L.G., Demarco, T., Lawson, R.M., Hicks, S., Devine, P., Lagerqvist, O., Hedman-Pétursson, E., Unosson, E., Feldmann, M. (2006). Large web opening for service integration in composite floors: final report, Office for Official Publications of the European Communities (Luxembourg). ISBN: 92-79-01723-3 )	Bake (2010Bake, S. (2010). Behaviour of cellular beams and cellular composite floors at ambient and elevated temperatures, Ph.D. Thesis, University of Manchester, UK. )	Ferrari (2013Ferrari, G.A. (2013). Numerical modeling of structural behavior of composite castellated beams of steel and concrete, M.Sc. Dissertation (in Portuguese), Federal University of Viçosa, Brazil. )
Software	ANSYS	MARC/MENTAT	ABAQUS	ABAQUS
Steel profile
Element type	4-node shell (SHELL181)	8-node shell	4-node shell (S4)	3 or 4-node shell (S3, S4R)
Yield surface	von Mises	von Mises	von Mises	von Mises
Hardening law	nonlinear, Gattesco (1999Gattesco, N. (1999). Analytical modeling of nonlinear behavior of composite beams with deformable connection. J. Constr. Steel Res. 52:195-218. https://doi.org/10.1016/S0143-974X(99)00026-7 https://doi.org/10.1016/S0143-974X(99)00... )	not specified	linear hardening	no hardening
Initial Imperfection
Buckling Mode(s)	combination of two modes	first (positive)	similar to test failure	similar to test failure
Amplitude	d_g /600	d_g /250	d_g /600	d_g /1000
Concrete Slab
Element type	20-node solid (SOLID186)	20-node solid	layered 4-node shell (S4)	8-node solid (C3D8R)
Material model(s)	DP-Concrete and Usermat	Mohr-Coulomb	smeared cracking	damaged plasticity
Reinforcement	embedded elements	not specified	layer of S4 element	not specified
Shear Connectors
Element type	spring (COMBIN39)	spring	perfect coupling	connector (CONN3D2)
Q x d curve	nonlinear	nonlinear	full interaction (no slip)	bilinear
Steel-Deck Sheet
Element type	8-node shell (SHELL281)	none	bottom layer of S4 element	none
Material model	von Mises, no hardening		not specified

Material	Data	Unit	Hosain and Speirs (1973Hosain, M.U., Speirs, W.G. (1973). Experiments on Castellated Steel Beams. Welding Research: Supplement to the Welding Journal 52:329-342. )		Nadjai et al. (2007Nadjai, A., Vassart, O., Ali, F., Talamona, D., Allam, A., Hawes, M. (2007). Performance of cellular composite floor beams at elevated temperatures. Fire Saf. J. 42:489-497. https://doi.org/10.1016/j.firesaf.2007.05.001 https://doi.org/10.1016/j.firesaf.2007.0... )		Müller et al. (2006Müller, C., Hechler, O., Bureau, A., Bitar, D., Joyeux, D., Cajot, L.G., Demarco, T., Lawson, R.M., Hicks, S., Devine, P., Lagerqvist, O., Hedman-Pétursson, E., Unosson, E., Feldmann, M. (2006). Large web opening for service integration in composite floors: final report, Office for Official Publications of the European Communities (Luxembourg). ISBN: 92-79-01723-3 )
Material	Data	Unit	A-1	G-1	A1	B1	1	3
Profile Steels	E	kN/cm²	20000	20000	20000	20000	20000	20000
	f_yf	kN/cm²	42.92	30.52	31.20	30.30; 31.90	45.10	45.30; 40.80
	f_uf	kN/cm²	55.72	47.13	43.85	43.85	54.12	51.90; 52.45
	f_yw	kN/cm²	44.68	31.96	31.20	30.30; 31.90	48.90	48.80; 46.70
	f_uw	kN/cm²	55.81	47.83	43.85	43.85	58.68	58.15; 55.80
	ε_h/ε_y	-	7.5	7.5	7.5	7.5	7.5	7.5
	E_h	kN/cm²	400	400	400	400	400	400
Connectors	Q_u	kN	-	-	110	110	100	100
	m	mm^-1	-	-	1.3	1.3	1.9	1.9
	n	-	-	-	1.0	1.0	1.0	1.0
Concrete	f_cm	kN/cm²	-	-	3.50	3.50	4.20	3.02
	f_c2m	kN/cm²	-	-	4.08	4.08	4.86	3.53
	f_ctm	kN/cm²	-	-	0.27	0.27	0.32	0.24
	E_ci	kN/cm²	-	-	3264	3264	3469	3108
	ε_c1	‰	-	-	2.2	2.2	2.3	2.1
	ε_c,lim	‰	-	-	3.5	3.5	3.5	3.5
Steel-Deck	E	kN/cm²	-	-	21000	21000	21000	21000
Steel-Deck	f_y	kN/cm²	-	-	32.7	32.7	32.7	32.7
Reinforcement Steel	E	kN/cm²	-	-	21000	21000	21000	21000
Reinforcement Steel	f_y	kN/cm²	-	-	46	46	50	50

Element type	Hosain and Speirs (1973Hosain, M.U., Speirs, W.G. (1973). Experiments on Castellated Steel Beams. Welding Research: Supplement to the Welding Journal 52:329-342. )		Nadjai et al. (2007Nadjai, A., Vassart, O., Ali, F., Talamona, D., Allam, A., Hawes, M. (2007). Performance of cellular composite floor beams at elevated temperatures. Fire Saf. J. 42:489-497. https://doi.org/10.1016/j.firesaf.2007.05.001 https://doi.org/10.1016/j.firesaf.2007.0... )		Müller et al. (2006Müller, C., Hechler, O., Bureau, A., Bitar, D., Joyeux, D., Cajot, L.G., Demarco, T., Lawson, R.M., Hicks, S., Devine, P., Lagerqvist, O., Hedman-Pétursson, E., Unosson, E., Feldmann, M. (2006). Large web opening for service integration in composite floors: final report, Office for Official Publications of the European Communities (Luxembourg). ISBN: 92-79-01723-3 )
Element type	A-1	G-1	A1	B1	1A	1B	3
SOLID186	-	-	2000	2000	7040	7040	7040
SHELL181	3112	3376	2423	2629	4320	4320	6072
SHELL281	-	-	1248	1248	4928	4928	4928
COMBIN39	-	-	30	30	86	86	86
REINF264	-	-	402	402	1840	1840	1840
MPC184	-	-	-	-	-	1	-
Total	3112	3376	6103	6309	18214	18215	19966

Beam		Concrete Model	Symmetry condition	Solution method	Load control
Hosain and Speirs (1973Hosain, M.U., Speirs, W.G. (1973). Experiments on Castellated Steel Beams. Welding Research: Supplement to the Welding Journal 52:329-342.)	A-1	-	No	Newton-Raphson	Displacement
	G-1	-	No	Newton-Raphson	Displacement
Nadjai et al. (2007Nadjai, A., Vassart, O., Ali, F., Talamona, D., Allam, A., Hawes, M. (2007). Performance of cellular composite floor beams at elevated temperatures. Fire Saf. J. 42:489-497. https://doi.org/10.1016/j.firesaf.2007.05.001 https://doi.org/10.1016/j.firesaf.2007.0... )	A1	DP-Concrete	Yes	Newton-Raphson	Displacement
		Usermat	Yes	Newton-Raphson	Displacement
	B1	DP-Concrete	Yes	Newton-Raphson	Displacement
		Usermat	Yes	Newton-Raphson	Displacement
Müller et al. (2006Müller, C., Hechler, O., Bureau, A., Bitar, D., Joyeux, D., Cajot, L.G., Demarco, T., Lawson, R.M., Hicks, S., Devine, P., Lagerqvist, O., Hedman-Pétursson, E., Unosson, E., Feldmann, M. (2006). Large web opening for service integration in composite floors: final report, Office for Official Publications of the European Communities (Luxembourg). ISBN: 92-79-01723-3)	1A	DP-Concrete	No	Arc-Length	Force
		Usermat	No	Newton-Raphson	Force
	1B	DP-Concrete	No	Arc-Length	Force
	3	DP-Concrete	No	Arc-Length	Force
		Usermat	No	Newton-Raphson	Force

Beam		Experimental			Numerical
Beam		Failure Mode	Load [kN]	Failure Mode	Load [kN]	Relative Difference
Hosain and Speirs (1973Hosain, M.U., Speirs, W.G. (1973). Experiments on Castellated Steel Beams. Welding Research: Supplement to the Welding Journal 52:329-342.)	A-1	VM	166.81	VM	164.24	- 1.54%
		LB	178.82	LB	174.95	- 2.16%
	G-1	FM	142.20	FM	144.50	+ 1.62%
		WPB	168.59	WPB	164.67	- 2.32%

Beam	Load when u_y=27.4 mm [kN]	Relative difference
Composite beam with original IPE400 profile	580.50	-
Composite cellular beam 1A	728.07	+ 25.42%
Composite cellular beam 1B	733.87	+ 26.42%
Composite beam, expanded profile without holes	998.09	+ 71.94%

Beam	Steel Profile	k	h₀ [cm]	a₀ [cm]	D₀ [cm]	s [cm]	b_w [cm]	b_i [cm]	h_t [cm]	α
FW1	Original IPE400, d=40cm	1	-	-	-	-	-	-	-	-
FW2	Expanded, without holes	1.5	-	-	-	-	-	-	-	-
CA1	Castellated Litzka	1.5	40	46.19	-	69.28	23.09	11.55	10	60°
CA2	Castellated Anglo-Saxon	1.5	40	33.15	-	43.20	10.05	11.55	10	60°
CA3	Castellated Peiner	1.5	40	40.00	-	60.00	20.00	10.00	10	63.43°
CE1	Cellular, s/D₀=1.1	1.5	-	-	44	48.40	4.40	-	8.00	-
CE2	Cellular, s/D₀=1.2	1.5	-	-	44	52.80	8.80	-	8.00	-
CE3	Cellular, s/D₀=1.3	1.5	-	-	44	57.20	13.20	-	8.00	-
CE4	Cellular, s/D₀=1.4	1.5	-	-	44	61.60	17.60	-	8.00	-
CE5	Cellular, s/D₀=1.5	1.388	-	-	38	57.00	19.00	-	8.76	-

When u_y=44mm	FW1	FW2	CA1	CA2	CA3	CE1	CE2	CE3	CE4	CE5
Linear load [kN/m]	29.17	61.60	46.38	48.12	47.08	28.35	39.96	42.68	44.99	41.52
Relative difference	-	111.18%	59.00%	64.96%	61.40%	-2.81%	36.99%	46.31%	54.23%	42.34%

Steel profile - stage of behavior	FW1	FW2	CA1	CA2	CA3	CE4	CE5
First sign of yield - inferior flange	52.50	83.20	64.01	66.81	65.39	62.72	59.63
First sign of yield - web	55.50	88.00	61.23	60.59	63.45	54.32	50.90
Total yield of the lower tee-section	-	-	67.01	67.68	66.90	63.95	61.49
Steel failure - 1^st element that reaches f_u	-	-	-	-	-	75.32	73.59

Stage of behavior	Data	Unit	FW1	FW2	CA1	CA2	CA3	CE4	CE5
Q/Q_u=98% - 1^st connector	q	kN/m	55.50	81.60	76.01	76.89	76.54	75.23	71.08
	u_y	mm	93.46	61.33	218.70	246.77	240.12	264.87	247.16
Q/Q_u=98% - 20^th connector	q	kN/m	66.00	104.00	79.01	78.24	78.11	76.05	72.81
	u_y	mm	214.95	148.37	321.34	294.98	285.61	294.82	315.25
1^st concrete crushed point	q	kN/m	67.68	110.91	80.76	79.47	79.11	77.60	73.72
	u_y	mm	456.39	452.12	406.76	360.98	330.18	381.23	375.22

Brasil

Brasil

Numerical simulation of composite steel-concrete alveolar beams: web-post buckling, Vierendeel and flexural mechanisms

Abstract

Graphical Abstract