Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Experimental investigation of the strength of glass fiber-reinforced concrete exposed to high temperature
103
113
EN
Amir Hamzeh
Keykha
0000-0001-5400-809X
Department of Civil Engineering, Faculty of Engineering, Zahedan Branch, Islamic Azad University, Zahedan, Iran
ah.keykha@iauzah.ac.ir
10.22075/macs.2018.1264.1056
This study investigated the effects of high temperature exposure on the compressive, tensile, and flexural strengths of concrete containing glass fiber. A total of 108 cubic specimens (150 mm × 150 mm × 150 mm), cylindrical specimens (300 mm × 150 mm), and prismatic specimens (500 mm × 150 mm × 150 mm) were prepared for compressive, tensile, and flexural strength testing, respectively. The specimens were incorporated with 1%, 2%, and 3% glass fiber and cured for 28 days to derive the desired strengths. The specimens were then annealed and subjected to experiments in which they were exposed to high temperature (600°C) for 30 minutes, one hour, and two hours. The specimens were cooled via slow cooling (exposure to air) and fast cooling (water spraying immediately after exposure to heat). Results showed that the presence of glass fiber exerted different effects on specimen strength and that heat caused the formation of numerous cracks in the specimens.
High temperature,Glass fiber,Concrete,Experimental investigation
https://macs.semnan.ac.ir/article_3282.html
https://macs.semnan.ac.ir/article_3282_6b3ccbfc4abf1c2c0d15ec32749d073b.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Optimization of infinite composite plates with quasi-triangular holes under in-plane loading
115
130
EN
Seyed Ahmad
Mahmodzade Hoseyni
Shahrood university of technology
ahmad.mahmodzade7058@gmail.com
Mohammad
Jafari
Department of Mechanical Engineering, University of shahrood
m_jafari821@shahroodut.ac.ir
10.22075/macs.2018.1749.1088
This study used particle swarm optimization (PSO) to determine the optimal values of effective design variables acting on the stress distribution around a quasi-triangular hole in an infinite orthotropic plate. These parameters were load angle, hole orientation, bluntness, fiber angle, and material properties, which were ascertained on the basis of an analytical method used by Lekhnitskii [3]. The cost function was regarded as the maximum stress created around the hole and was calculated using the aforementioned analytical approach. The finite element method was then employed to verify the results of the analytical calculation. The overlap in the analytical and FEM calculations confirmed the validity of the solution proposed in this research. The findings further indicated that the design variables significantly affect the stress distribution around quasi-triangular holes and structural load-bearing capacity. The performance of the PSO algorithm was also investigated.
Infinite orthotropic plate,Quasi-triangular hole,Particle swarm optimization,Analytical Solution,Complex variable method
https://macs.semnan.ac.ir/article_3283.html
https://macs.semnan.ac.ir/article_3283_cdbb99113dda990fa7f50b13633a876c.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Effects of reinforcement distribution on the mechanical properties of Al–Fe3O4 nanocomposites fabricated via accumulative roll bonding
131
139
EN
Behrooz
Pirouzi
Dep. of Nanotechnology, Nano materials group, Semnan university
behrooz_pirouzi@yahoo.com
Ehsan
Borhani
Semnan University
ehsanborhani@gmail.com
10.22075/macs.2018.12290.1121
This research developed new nanostructured Al–Fe<sub>3</sub>O<sub>4</sub> composites via accumulative roll bonding (ARB). X-ray diffraction (XRD) analysis and field emission scanning electron microscopy were conducted to examine microstructural characteristics and particle distribution in the nanocomposites. Hardness and tensile strength tests were employed to examine their mechanical properties. After eight cycles of XRD analysis, the size of the Al crystals in the nanocomposites reached 198 nm. After eight cycles of tests on mechanical properties, the Al crystals exhibited a tensile strength and a hardness of 204 MPa and 63 HV, respectively. These values are higher than those achieved by pure Al. The depth of nanocomposite rupture observed in fractographic analysis revealed that a ductile fracture occurred in the materials because of the formation and growth of cavities.
Metal matrix composite,Fe3O4,Accumulative roll bonding,Microstructure,Mechanical properties,Fractography
https://macs.semnan.ac.ir/article_3284.html
https://macs.semnan.ac.ir/article_3284_c1bc54a32ae0c481e1a63c6a065ee102.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Creep Strain and Stress Analysis in Laminated Composite Pres-sure Vessels
141
147
EN
Ahmad Reza
Ghasemi
Faculty of Mechanical Engineering, University of Kashan, Kashan
ghasemi@kashanu.ac.ir
Komeil
Hosseinpour
Faculty of Mechanical Engineering, University of Kashan, Kashan
komeil61@gmail.com
10.22075/macs.2018.12562.1125
This study investigates the time-dependent long-term creep strain in a composite cylinder made of glass/vinylester with a unidirectional ply. The cylinder is subjected to an internal pressure and the boundary condition is free–free and acts as thermal insulation. The classical lamination theory (CLT) is used to derive the governing equations as a second-order equation to determine the radial, circum-ferential, axial, and effective stresses in the cylinder wall. The distribution of the radial and circumferential creep strains is based on the Schapery’s single integral model for nonlinear viscoelastic materials. This study focuses on the effect of the orientation of the fibers on the creep strain distribution in the wall of a cylinder. The results show that the creep strain is lower when than at . As the angle of the fibers increases, the distribution of the creep strain becomes more uniform.
Long-term creep strain,Schapery single integral,Nonlinear viscoelastic,Polymer matrix composites
https://macs.semnan.ac.ir/article_3286.html
https://macs.semnan.ac.ir/article_3286_ad1f89ee5cc286e9f6617b8fdc236a94.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Flexural Behavior of Fiber–Metal Laminates Reinforced with Surface-Functionalized Nanoclay
149
156
EN
Sh.
Vahedi
Materials Science and Engineering Faculty, K.N. Toosi University of Technology, Tehran, Iran
vahedi1372@eng.usb.ac.ir
S.M.H.
Siadati
Materials Science and Engineering Faculty, K.N. Toosi University of Technology, Tehran, Iran
siadati@kntu.ac.ir
H.
Khosravi
Department of Materials Engineering, Faculty of Engineering, University of Sistan and Baluchestan, Zahedan, Iran
hkhosravi@eng.usb.ac.ir
A.
Shahrabi
Materials Science and Engineering Faculty, K.N. Toosi University of Technology, Tehran, Iran
ashahrabi@mail.kntu.ac.ir
10.22075/macs.2018.13315.1130
The effects of surface-functionalized Na<sup>+</sup>-montmorillonite nanoclay particles on the flexural behavior of E-glass fiber-reinforced aluminum (GLARE) laminates were investigated. The nanoclay particles were subjected to surface functionalization using 3-(trimethoxysilyl)propylamine to increase their compatibility with the epoxy matrix and improve their dispersion within the matrix. Experimental results indicated that the GLARE laminates achieved the highest flexural strength (61%) and energy absorption (51%) at an addition of 3 wt% functionalized nanoclay. The highest flexural modulus (67% increase) was observed at an addition of 5 wt% functionalized nanoclay. The flexural properties of the functionalized nanoclay-filled GLARE laminates were significantly better than those of untreated nanoclay-filled GLARE laminates. Microscopic observations suggested that the introduction of functionalized nanoclay particles markedly enhanced the interfacial adhesion between the matrix and the E-glass fibers.
Fiber-metal laminates,Nanoclay,Surface functionalization,Three-point bending test,Fracture surface
https://macs.semnan.ac.ir/article_3287.html
https://macs.semnan.ac.ir/article_3287_df2567a1cf2cae87d5211c4c055343d5.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Improving the Performance of Porous Concrete Composites Using Zeolite as a Coarse Grain
157
163
EN
Mahsa
Doostmohamadi
Graduated MSc. Student, Faculty of Civil Engineering, Semnan University, Semnan, Iran.
m.doostmohamadi@semnan.ac.ir
Hojat
Karami
Assistant Professor, Faculty of Civil Engineering, Semnan University, Semnan, Iran.
hkarami@semnan.ac.ir
Saeed
Farzin
Assistant Professor, Faculty of Civil Engineering, Semnan University, Semnan, Iran.
saeed.farzin@semnan.ac.ir
Sayed-Farhad
Mousavi
Professor, Faculty of Civil Engineering, Semnan University, Semnan, Iran.
fmousavi@semnan.ac.ir
10.22075/macs.2018.13363.1131
Porous concrete is a mixture of cement and water that may contain fine grains, which play a role in water transfer and permeability. Porous concrete can act as a drain to pass rainwater and recharge groundwater. In this study, 25%, 50%, 75%, and 100% zeolite were used to replace the coarse aggregates in porous concrete. The effects of the zeolite on the compressive strength, permeability coefficient, porosity, and density of the concrete were investigated. The results showed that the zeolite reduced the compressive strength of the concrete samples because of its porous nature. The permeability coefficient and porosity increased with the addition of zeolite. The highest (10.29 MPa) and lowest compressive strength (6.79 MPa) were observed in the 25% and 100% zeolite samples, respectively. The highest porosity (30.97%) and permeability coefficient (1.76 mm/s) were measured in the 100% zeolite sample. For the 25%, 50%, 75%, and 100% zeolite samples, the permeability coefficient increased by 6.99%, 17.39%, 21.3%, and 24.4%, respectively; the density decreased by 7.77%, 10, 15%, and 19.44%, respectively, with respect to the control sample.
Porous concrete,Additive,Zeolite,Physical properties,Groundwater recharge
https://macs.semnan.ac.ir/article_3288.html
https://macs.semnan.ac.ir/article_3288_c78e8224a1fbc8ad836bf19207daa88e.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Investigation of Capsulated Epoxy and DCPD in Epoxy Based Self-healing Composites - DFT Calculation and Experimental Analysis
165
171
EN
Sepide
Khostavan
Department of chemistry, Faculty of sience, University of Semnan , Semnan, Iran
s.khostavan@gmail.com
Mostafa
Fazli
Department of chemistry, Faculty of sience, University of Semnan , Semnan, Iran
mfazli@semnan.ac.ir
Abdollah
Omrani
Department of Physical Chemistry , Faculty of Chemistry, University of Mazandaran, Babolsar, Iran
Morteza
Ghorbanzadeh Ahangari
University of Mazandaran
ghorbanzadeh.morteza@gmail.com
10.22075/macs.2018.15389.1152
Epoxy and dicyclopentadien (DCPD) are two common healing agents, which are introduced into epoxy matrix through encapsulation in order to prepare self-healing composites. In a comparative study, the compatibility of healing agents and epoxy matrix is investigated through experimental tests and DFT calculations. The interaction energy is considered to be the determinative parameter in DFT calculation. The values of total interaction energy are -0.14eV for DCPD and +0.169eV for epoxy absorbing on epoxy matrix. According to the obtained results from DFT, an attraction between DCPD and epoxy matrix is observed. DOS and charge analysis of these systems are fulfilled and demonstrated the charge transfer of 0.07 e from epoxy to DCPD. The obtained data reveal the most charge transfer is occurred in DCPD-epoxy, which affects the mechanical properties of healed composites. To examine the mechanical properties, tensile strength parameters are measured experimentally and demonstrated the improved ultimate strength of 783.49 MPa in DCPD/epoxy system rather than the ultimate strength of 571.87 MPa in epoxy/epoxy system. Also elongation at break in DCPD-epoxy system is improved to 3.44% compared to 1.84% in epoxy/ epoxy blend. These findings highlight the role of interaction energy in mechanical properties of polymeric interface, and prompt further experiments and simulations to confirm this effect.
Epoxy,DCPD,DFT,interaction energy,tensile strength
https://macs.semnan.ac.ir/article_3291.html
https://macs.semnan.ac.ir/article_3291_674d0a1ecb40dc8e45fe43f0d752eec6.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
An Analytical Approach to Thermoelastic Bending of Simply Supported Advanced Ribbed Composite Plates
173
185
EN
Morteza
Shahravi
Department of Aerospace Eng.
shahravim@yahoo.com
Sina
Falahzade
department of SGC
m.mokthtari@sina.kntu.ac.ir
Madhid
Mokhtari
S.G. center of research
m.mokhtari@sina.kntu.ac.ir
10.22075/macs.2018.12357.1124
In the present paper, an analytical approach is used to study the thermal deflections of a simply supported composite plate with a beam-like stiffener. The results for a plate–beam system exposed to a sinusoidal thermal load is used to study the effects of the low Earth orbit (LEO) thermal conditions on the composite plates, which have been used in the structure of satellites and spacecraft. To solve the governing equations of the system, the Laplace transform method for the time domain is used with the Navier series expansions. As the employed method is completely analytical, the results are exact.
Ribbed composite plate,Thermoelastic Bending,Laplace transform,Advanced composite
https://macs.semnan.ac.ir/article_3285.html
https://macs.semnan.ac.ir/article_3285_21c0427816f32ae920e9c4fd078c9f24.pdf
Semnan University
Mechanics of Advanced Composite Structures
2423-4826
2423-7043
5
2
2018
11
01
Thermoelastic Interaction in a Three-Dimensional Layered Sandwich Structure
187
198
EN
Abhik
Sur
Department of Applied Mathematics, University of Calcutta, India
abhiksur4@gmail.com
M.
Kanoria
Department of Applied Mathematics, University of Calcutta, India
10.22075/macs.2018.14201.1141
The present article investigates the thermoelastic interaction in a three-dimensional homogeneous and isotropic sandwich structure using the dual-phase-lag (DPL) model of generalized thermoelasticity. The incorporated resulting non-dimensional coupled equations are applied to a specific problem in which a sandwich layer of unidentical homogeneous and isotropic substances is subjected to time-dependent thermal loadings; the two outer sides are traction-free. The analytical expressions for the displacement components, stress, temperature, and strain are obtained in the physical domain using the normal mode analysis. The mathematical difficulties in dealing with the hyperbolic heat conduction equation are overcome and the thermophysical quantities of the sandwich structure are depicted graphically. The effect that the two phase lags have on the studied field are highlighted. The results demonstrate the phenomenon of a finite speed of wave propagation in a sandwich structure for each field.
Generalized thermoelasticity,Dual-phase-lag thermoelastic model,Hyperbolic heat conduction,Finite wave speed,Normal mode analysis
https://macs.semnan.ac.ir/article_3290.html
https://macs.semnan.ac.ir/article_3290_c3a227cc8e384519454159e98561e0b3.pdf