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Article

Elastic Properties of Jute Fiber Reinforced Polymer Composites with Different Hierarchical Structures

1
Department of Mechanical Engineering, Prasad V. Potluri Siddhartha Institute of Technology, Kanuru, Vijayawada 520007, Andhra Pradesh, India
2
Department of Mechanical Engineering, V. R. Siddhartha Engineering College, Kanuru, Vijayawada 520007, Andhra Pradesh, India
3
Department of Mechanical Engineering, GLA University, Mathura 281406, Uttar Pradesh, India
4
Department of Medical Physics, Hilla University College, Babylon 51002, Iraq
5
Department of Mechanics and Strength of Materials, Politehnica University Timisoara, 1 Mihai Viteazu Avenue, 300222 Timisoara, Romania
6
School of Mechanical Engineering, Lovely Professional University, Phagwara 144411, Punjab, India
7
Division of Research and Development, Lovely Professional University, Phagwara 144011, Punjab, India
8
Division of Research & Innovation, Uttaranchal University, Dehradun 248007, Uttarakhand, India
*
Authors to whom correspondence should be addressed.
Materials 2022, 15(19), 7032; https://doi.org/10.3390/ma15197032
Submission received: 25 August 2022 / Revised: 30 September 2022 / Accepted: 5 October 2022 / Published: 10 October 2022

Abstract

:
A two-stage micromechanics technique is used to predict the elastic modulus, as well as the major and minor Poisson’s ratio of unidirectional natural fiber (NF) reinforced composites. The actual NF microstructure consists of cellulose, hemicellulose, lignin, lumen, etc., and these constituents and their contributions are neglected in classical models while quantifying their mechanical properties. The present paper addresses the effect of the real microstructure of the natural jute fiber (JF) by applying a micromechanics approach with the Finite Element Method. Six different hierarchically micro-structured JFs are considered to quantify the JF elastic properties in the first level of homogenization. Later, the JF reinforced polypropylene matrix properties are investigated in the second stage by adopting a homogenization approach. Taking into account the different hierarchical structures (HS), the fiber direction modulus (E1), transverse modulus (E2 and E3), in-plane and out-of-plane shear modulus (G12 and G23), and major (ν12, ν13) and minor (ν23, ν21) Poisson’s ratios are estimated for JF and JF reinforced polypropylene composites. The predicted elastic modulus from micromechanics models is validated against the analytical results and experimental predictions. From the present work, it is observed that the HS of NF needs to be considered while addressing the elastic properties of the NF-reinforced composite for their effective design, particularly at a higher volume fraction of NF.

1. Introduction

Natural fibers (NFs) are also called lignocellulosic fibers, which are extracted from plants, and these fibers contain different proportions of cellulose, hemicelluloses, lignin, and lumen. The main constituent among all of these is cellulose, and the percentage of cellulose is in the range of 50–70% [1]. Microfibrils are formed from these cellulose chains, and these microfibrils aggregate together to form macrofibrils through an amorphous matrix termed lignin and hemicellulose. The hollowness in this structure is called the lumen. Cellulose, hemicellulose, lignin, and lumen are the main constituents of plant-based fibers. Based on the differences in the percentage of contributions in the NF, the hierarchical structure (HS) may differ. The use of lignocellulosic fibers has great benefits in terms of biodegradability, energy-friendly production, and has the potential to replace synthetic fibers [2,3].
Due to their mechanical strength and stiffness as well as thermal and tribological properties, jute, bamboo, sisal, flax, kenaf, and hemp fibers are recommended as NFs for the manufacture of natural fiber reinforced (NFR) composites [4]. With the increasing application of NFR composites in the automotive, aerospace, marine, sporting goods, biomedical, and electronic industries, the design and development of NFR composites is becoming a challenging task [5,6]. Because of the difficulties associated with their fabrication and experimentation, many researchers turn to computational methods for the mechanical and thermal characterization of NFR composites [7,8]. The finite element (FE) method is the most commonly used tool in the modelling of NFs and NFR composites to predict the elastic and thermal properties. Due to the differences in the microstructure of plant-based fibers, the analysis of NFs is a challenging task [9]. Using multi-scale homogenization computational methods, the mechanical relationships of a large-scale fiber-reinforced composite material can be established from a small-scale fiber [10]. Using multi-scale FE analysis, the natural flax fiber reinforced composite properties of lamina and laminate are estimated through representative volume elements (RVEs). Using the inputs from the micro-scale (lamina) analysis, the macro-scale (laminate) analysis was performed, and the tensile strength and flexural behavior were estimated [11]. Also, using FE-based software, the acoustic behavior of sisal fiber reinforced composite is estimated by modelling three-layer fiber structures with technical fiber and microfibrils. In this case, the failure process and stress distribution are estimated from the FE models [12]. Two-stage homogenization processes are adopted to predict the elastic properties of NF. The effect of the lumen ratio of NF on the axial Young’s modulus of NF was analyzed, and it was concluded that the prediction of the axial Young’s modulus of NF would be in good agreement with the experimental data by knowing the exact lumen ratio [13]. Although NFs show similar morphology, the differences in the internal area of the lumens and the number of lumens make them different from each other. In addition, the combined effect of chemical and morphological composition on the tensile behavior of fibers is investigated [14]. The elastic modulus of Kevlar 29 and Kevlar 49 fibers was calculated using multi-scale modelling techniques [15]. Using multi-scale homogenization techniques and RVE models, the elastic properties of the dry sugarcane leaf reinforced polymer composite are estimated by adopting ANSYS software. To estimate the elastic properties of dry sugarcane leaf-reinforced epoxy composite using micromechanics analysis, dried sugarcane leaves are considered as rectangular inclusions [16].
Biodegradable cellulose-based fiber-reinforced composite materials’ behavior under low velocity is estimated and compared to the experimental results. Knowing this impact strength, the FE method can be used to provide a new application for biodegradable composite materials [17]. From the above works, it can be seen that the FE method and micromechanics can be used to model and analyze cellulose if homogenization techniques are used [15,18,19]. The RVE method is the most efficient homogenization-based multi-scale model when applied to cellulose-based composites, and represents the relevant features of NF in the uniform structure [20]. In terms of elastic and thermal properties, NFs and matrix constituents have a mismatch effect. The mismatch in the properties has a clear effect on the interfacial shear strength. The mismatch effect on the properties can also be estimated by adopting a micromechanics approach [21,22]. Many authors have used two-stage homogenization techniques to characterize the elastic and thermal behavior of composite materials in the presence of defects such as voids and debonding [23,24]. NFR composites’ mechanical properties are certainly influenced by non-cellulosic compounds such as hemicelluloses, lignin, waxes, pectin, etc. However, it is possible to decrease the percentages of non-cellulosic compound by opting for an appropriate fiber treatment process [25,26]. Estimates of NF properties are unclear with respect to testing, i.e., experiments performed on individual fibers or fiber bundles. This information is not clearly explored. If findings are based on a single fiber, the hollowness of the lumen is considered [27], and the fraction of cross-sectional area taken up by the lumen has been found to be 27.2%, 6.8%, and 34.0% for sisal, flax, and jute, respectively. It was noted that the presence of lignin makes the cellulose rigid [28]. These jute fiber reinforced (JFR) composites have a wide range of applications in household, engineering, building structures, door frames, furniture, shopping bags, etc. and these composites can be thermally stable in the range of 250–365 °C [29]. Another important aspect of jute fiber (JF) is the large lumen, which needs to be reflected in the manufacturing process of composite materials. This hollow lumen has a clear influence on the stiffness of the NF composites. These lumen percentages must be considered when designing the properties of NF composites [30]. JFs consist of a high percentage of hollow lumen structures, which could be beneficial for sound energy conversion [31]. However, this lumen will never contribute to the mechanical properties [32] and will remain as it is inside the composites, and the lumen is a large tubular void in the middle of each NF [33,34].
From the above findings, the authors of this paper observed that the identification of lumen and cellulose percentages is the key step in tailoring the properties of NF composites. The lumen represents the hollowness of the NF and the cellulose promotes the strength of the fiber. Most NF studies have been limited to E, i.e., Young’s modulus in the longitudinal direction. However, NFR composites are orthotropic in nature, requiring the use of nine elastic constants for effective design of NFR composite structures. This data is not yet available for JFR composites. There are few studies on Poisson’s ratio, with more emphasis on elastic modulus and shear modulus. However, Poisson’s ratio requires knowledge of the coupling between deformation in the lateral and longitudinal directions of composite materials. While Poisson’s ratio does not matter much for regular materials, it does matter a lot for composite materials, which are made of two different materials that work together when loaded. This behavior can be identified by Poisson’s ratio. At the same time, the fiber alignment direction also plays a definite role in Poisson’s ratio and must be taken into account. Lumen hollowness and its percentage are dependent on the type of NF. This lumen percentage influence on all elastic properties has not been addressed so far. While comparing the experimental and analytical or simulation studies of the properties of NF composites, the experimental results consider all NF constituents, i.e., cellulose, hemicelluloses, lignin, and lumen, while in the analytical or simulation studies, only the technical fiber [12] property will be considered to estimate the overall composite properties. Considering the aforementioned knowledge gaps, the present problem focuses on the estimation of the nine elastic properties of a jute NFR composite considering the six HSs with different lumen percentages using analytical and simulation studies.

2. Material and Methods

Experimental procedures for estimating the longitudinal modulus of straight natural fiber reinforced composite and their mechanical characterization are well described in the previous article [35]. Using the same procedure, the JFR epoxy composites are prepared and tested. The JFs are treated with NAOH solution and the weight of straight JFs is measured and placed in a mold. The epoxy matrix is poured over the JF according to the fiber weight fraction. The mold is cured for 24 h after which the specimen is removed from the mold. Subsequently, the specimens are cut from the same lamina according to ASTM standards. Five samples are prepared at each weight and tested for longitudinal modulus.
Unidirectional JF is used for the fabrication of NFR polymer composites. Epoxy resin (LY556) and compatible hardener (HY951) are used as a hosting medium. Numerical studies are performed considering the volume fraction, and for conducting the experimental studies, the volume fraction is converted to weight fraction using the density of JFs and epoxy resin. The weight fraction of JF is kept at 12.95% and 36.47% based on the volume fraction of JFs (10% and 30%). Composite specimens are prepared using hand layup technique. Five specimens are prepared for each configuration and tested according to the ASTM D638 standard (Figure 1a). The tensile tests were carried out using the Universal Tensile Testing Machine at the Prasad V. Potluri Siddhartha Institute of Technology, Kanuru, Vijayawada, Andhra Pradesh, India (Figure 1b). Table 1 shows the elastic modulus obtained from experimental tensile tests.

3. Analytical Studies of Jute Fiber Reinforced Composites

In the plant-based NFs, the strong network of hydrogen bonds between the hydroxyl groups of neighboring chains causes the cellulose to organize in a hierarchical way [36]. Cellulose is the main structural component of plant cell walls [37]. In this work, six types of such structures are taken for analysis and the elastic modulus is estimated. The hierarchical structures (HSs) and the percentage of each constituent are presented in Table 2.
These HS structures are designed based on the cellulose percentage i.e., some fibers have maximum cellulose (61%) and some fibers have minimum cellulose (39%). Application of the Micromechanics method to the composite materials to evaluate their elastic properties will start with the selection of the Representative Volume Element (RVE). The NFs in the matrix phase are thought to be straight and spread out evenly.
The space between the JFs and fiber is bf and the thickness is tf. The size of the RVE is represented by lc, bc and tc where lc is the length of the RVE, bc is the width of the RVE, and tc is the thickness of the RVE (Figure 2). The RVE shows the whole lamina of the JF, which can be made by putting the RVEs next to each other over and over again.

3.1. Estimation of Elastic Properties of Selected RVE

The selected RVE is an orthotropic body characterized by nine elastic constants; these are longitudinal modulus (E1), transverse modulus (E2 and E3), Major Poisson’s ratio (ν12, ν13), Minor Poisson’s ratio (ν21, ν23), in-plane and out-of-plane shear modulus (G12, G23, G13).

3.1.1. Longitudinal Modulus E1

To find out the fiber direction modulus of a JFR polymer matrix composite, an electrical analogy was made. When applying the numerical calculations, the HS of JF is taken into account. The HS of NF includes lumen, lignin, hemicellulose, and cellulose. A lumen in the NF is treated as a hollow member; lignin, hemicellulose, and cellulose are different in terms of geometry and material properties. These fibers are uniformly distributed throughout the matrix material.
All constituents present share the load acting on the RVE. Lumen, lignin, hemicellulose, and cellulose will take the load as shown in Figure 3a.
The forces shared by all the constituents are given in Equation (1). Using the relation between the forces and stresses, Equation (2) is developed.
F Φ = F α + F β + F   γ + F δ + Fm
σ Φ · A Φ = σ α × A α + σ β × A β + σ γ × A γ + σ δ × A δ + σ m × Am
Using Hooke’s law, the stress is directly proportional to the strain, as follows:
σ = E · ε
Substituting the Equation (3) in (2) gives:
E 1 Φ · ε 1 Φ · A Φ = E 1 α · ε 1 α · A α + E 1 β · ε 1 β · A β + E 1 γ · ε 1 γ · A γ + E δ · ε δ · A δ + Em · ε m   · Am  
Under the condition of a perfect bond between the constituents of the fiber and the matrix, the strain generated in the RVE is equal to the strain in the fiber and the strain developed in the matrix.
ε 1 Φ = ε 1 α = ε 1 β = ε 1 γ = ε δ = ε m
The Equation (4) becomes:
E 1 Φ = E 1 α · A α A Φ + E 1 β · A β A Φ + E 1 γ · A γ A Φ + E 1 δ · A δ A Φ + Em · Am A Φ  
E 1 Φ = E 1 α · V α + E 1 β · V β + E 1 γ · V γ + E 1 δ · V δ + Em · Vm

3.1.2. Transverse Modulus

This modulus is obtained from the RVE subjected to transverse loading as shown in Figure 3b,c.
The transverse elongation under the applied load is equal to the transverse extension generated in all constituents, such as fiber and matrix. Again, JF is considered with lumen, lignin, hemicellulose, and cellulose, considering all the constituents the total elongation is represented as in Equation (8) thus:
Δ Φ = Δ α + Δ β + Δ γ + δ + m
Replacing the deformation with the strain, the Equation (9) can be obtained. Using the strain in the above is modified as:
ε 2 Φ · w Φ = ε 2 α · w α + ε 2 β · w β + ε 2 γ · w γ + ε 2 δ · w δ + ε m · wm
The transverse strain is obtained by rearranging the equation, the Equation (10) is obtained. Finally the transverse strain in terms of strain of the each constituent and volume fraction of respective constituent the Equation (11) is obtained.
To get the ε 2 Φ
ε 2 Φ = ε 2 α · w α w Φ + ε 2 β · w β w Φ + ε 2 γ · w γ w Φ + ε 2 δ · w δ w Φ + ε m · wm w Φ
ε 2 Φ = ε 2 α · V α + ε 2 β · V β + ε 2 γ · V γ + ε 2 δ · V δ + ε m · Vm
Using the relation between the strain and stress in terms of modulus in the respective directions, the Equation (11) becomes:
σ 2 Φ E 2 Φ = σ 2 α E 2 α · V α + σ 2 β E 2 β · V β + σ 2 γ E 2 γ · V γ + σ 2 δ E 2 δ · V δ + σ m Em · Vm
σ 2 Φ = σ 2 α = σ 2 β = σ 2 γ = σ 2 δ = σ m
After applying the assumption of Equation (13), the Equation (12) becomes:
1 E 2 Φ = V α E 2 α + V β E 2 β + V γ E 2 γ + V δ E 2 δ + Vm Em
The same analogy is applied to calculate the G12 as presented in Equation (15).
1 G 12 Φ = V α G 12 α + V β G 12 β + V γ G 12 γ + V δ G 12 δ + Vm Gm
Substituting the corresponding values of the fiber constituents’ matrix elastic modulus and their percentage in Equations (7), (14) and (15), the longitudinal modulus and transverse modulus and shear modulus of the JFR composite will be estimated, respectively.

4. Simulation Studies of Jute Fiber Using Micromechanics Approach

4.1. First Stage of Homogenization

Further, using the micromechanics and finite element method, the nine elastic properties of the JFR composites were estimated. The work is carried out in two stages. In the first stage, only JF properties were determined by considering different HSs. Each HS contains different constituents such as cellulose, hemicelluloses, lignin, and lumen in different proportions. This stage is considered the first stage of homogenization. In the second step, the properties of the JFR polypropylene composite are estimated using the Finite Element Based Software ANSYS 19.2. To ensure that the simulation models are accurate, the results of the FE models are checked against the analytical results.
Figure 4a shows the cross section of a unidirectional NFR composite, which is illustrated to understand the HS. A fiber bundle can be seen in Figure 4b and the uniform distribution of each fiber in the fiber bundle is idealized to be spread regularly, and the analysis of one fiber is enough to estimate the fiber bundle properties in Figure 4c,d.
The unit cell contains lumen, cellulose, and matrix phase, which are obtained by selecting a fiber from the bundle. In this case study, it is divided into two phases. In the first stage of homogenization, the JF properties are estimated by including cellulose, lumen, lignin, hemicelluloses, and later, using the properties of the JF with all its constituents, the fiber reinforced matrix properties are estimated. These homogenization concepts are used to understand the potential of electrical systems [38]. Similarly, a transverse thermal conductivity model was recently proposed [39] considering the hollow portion of the NF (lumen), and the remaining portion of the fiber is treated as cellulose. In this work, along with the lumen percentage, the lignin, cellulose, and hemicellulose percentages are also reflected in the RVE to estimate the natural properties of JF. The JF contains between 61–71% cellulose, a large amount of hemicelluloses (14–20%), lignin (12–13%), and pectin (0.2%), as cited in Ref. [40]. The Young’s modulus of each constituent of the fiber is provided in Table 3.
The properties of the RVE can be estimated by making the RVEs in a square array look like they are perfect and setting the appropriate boundary conditions. The size of the RVE is determined based on the volume fraction of the fiber constituents. For the HS-1 model, the cellulose percentage is 61%, the hemicellulose percentage is 14%, the lignin is 12%, and the lumen is 13%. Based on these percentages, the radius of each constituent is calculated. For this structure, the square RVE size is 10 × 10 nm2, and the diameter of the lumen is calculated by equating the percentage of lumen to the size of the RVE, which is the area of the lumen. The lumen is treated as a hollow circle in the square RVE. The radius of the lumen is calculated according to the volume fraction. For example, the volume fraction of lumen in the total volume of the RVE is 13% for the HS-1 model. However, the cross-sectional areas are important in this calculation. The thicknesses of all the constituents are the same in the RVE. Hence, the areas of the constituents represent the volume fractions of the constituents. For the fixed RVE size (10 × 10 nm2) and fixed lumen percentage (13% for the HS-1 model), the radius of the lumen is calculated by dividing the lumen area (π/4·dlu2) to the total RVE area (10 × 10 nm2) and equating the outcome to 13% (lumen percentage for the HS-1 model) where dlu is the diameter of the lumen. Similarly, the remaining constituents’ dimensions are also estimated. The cellulose area is obtained by subtracting the lumen, lignin, and hemicellulose areas from the RVE. The FE models corresponding to HS-1 and HS-6 are presented in Figure 5.
Using the geometrical data listed in Table 4 and the properties of the constituents (Table 3), a FE model is generated for all the considered structures (as given in Table 2) to estimate the elastic properties of JF under all possible loading applications [38].
The possible loading cases are longitudinal loading, in-plane transverse loading, out-of-plane transverse loading, in-plane shear, and out-of-plane shear loading. A solid 186 element has been used to describe the model generated for the analysis. This solid 186 is defined by 20 nodes, and each node possesses three directional freedoms, i.e., in the X, Y, and Z directions [41]. Converged FE models are used for the analysis. One-eighth of the RVE is modelled for the analysis in terms of symmetry from the perspectives of loading, geometry, and boundary conditions.
Before finding the required properties of the FE model, the model needs to ensure that the selected unit cell should reflect the total behavior of the selected material. For that, the nodes corresponding to the X = 0, Y = 0, and Z = 0 areas are arrested to move in the X, Y, and Z directions, respectively. Multipoint constraints are applied to the corresponding nodes of the FE model in the positive directions [41,42]. The longitudinal modulus is obtained by applying uniform pressure parallel to the fiber (Z axis) and, using Hooks’ law, the longitudinal modulus is obtained (Figure 3a). The transverse modulus is obtained by applying load in the X and Y directions of the FE model, respectively (Figure 3b,c). The in plane shear modulus is calculated using models loaded in the XZ plane, and the out-of-plane modulus is obtained by applying load in the XY plane. The major Poisson’s ratio is calculated by dividing −ε21 where ε1 is the longitudinal strain ε2 is the lateral strain of the composite material.

4.2. Second Stage of Homogenization

The final JFR composites are evaluated by considering the JF properties, which are obtained by using the methodology proposed in Section 4.1. Considering six hierarchical structural models and their properties, the final JFR composites are estimated and presented in Section 5.2. The concentration of lumen percentage differs between the six HSs.
Using the properties of JF from the first stage of homogenization, the fiber-reinforced polypropylene composite is estimated. The second stage of homogenization is used to Figure out how different HS structures affect the final properties of the composite.

4.3. Validation of Simulation Studies

The FE models are validated by comparing the results with experimental results [43,44]. The experimental results are available for 10 and 30% volume fraction (12.95% and 36.45% weight fraction). Using the method proposed in Section 3 and Section 4, the longitudinal modulus is predicted and compared to the experimental and analytical results (Table 5).

5. Results and Discussions

5.1. Simulation Results of JF Using Micromechanics Approach (First Stage of Homogenization)

Figure 6 shows the variation of fiber directional or longitudinal modulus (E1), transverse modulus (E2 and E3), in-plane (G12) and out-of-plane shear modulus (G23). Among all the moduli, E1 is more than E2 or E3, G12, and G23. A declining trend is observed in all the moduli except G12 from HS-1 to HS-6. Changing the HS from HS-1 to HS-6 decreases the E1 from 80.78 to 54.12 Gpa. The possible reason for the decrease is the increase of lumen (hollowness) in the fiber. Increasing the lumen decreases the cellulose percentage, and cellulose is the main load-bearing element of the fiber [29]. About 33% of E1 is decreased by changing the HS from HS-1 to HS-6. The reason for the decrement is an increase in the lumen percentage from HS-1 to HS-6. Compared to E1, the transverse modulus of E2 and E3 is affected more due to lumen percentage. As a result, 42.78% of E2 decreased from HS-1 to HS-6. A different scenario is observed in shear modulus. The in-plane shear modulus is increases from HS-1 to HS-6, which means that the lumen percentage is not affected by the in-plane modulus and the contribution of cellulose is dominated by the decrease caused by the lumen. As a result, the G12 improves by 44.4% from HS-1 to HS-6 models. G23 become less bright as the lumen percentage goes up, just as lumen does with E1 and E2.
The ratio of lateral strain to the longitudinal strain of the composite material gives the Poisson’s ratio. Composite materials have two types of Poisson’s ratios. Major Poisson’s ratio (ν12 or ν13) minor Poisson’s ratio (ν23 and ν21). For transversely isotropic materials such as (E2 = E3), the magnitude of the major Poisson’s ratio ν12 or ν13 is the same and minor Poisson’s ratio ν21 and ν23 are same. However, the presence of lumen inside the JF makes the difference between the major Poisson’s ratio ν12 and ν13 and the minor Poisson’s ratio ν21 and ν23.
The major Poisson’s ratios ν12 and ν13 increase from HS-1 to HS-6 due to an increase in lumen percentage (Figure 7). This response is caused by excessive deformation in longitudinal loading due to lumen in the transverse loading. The minor Poisson’s ratios ν23, ν32 decrease from HS-1 to HS-6. In the transverse loading, excessive deformation in the longitudinal loading due to lumen is the reason for this response. Ν31 and ν32 are the same, and the magnitude is very small, and the changes in these properties are constant from HS-1 to HS-6. From the whole of Figure 7, it is observed that the ν12, ν13 magnitudes are the same. Moreover, the ν23 and ν32 magnitudes are also the same.
Figure 8 depicts the deformation contours of the FE model under longitudinal and in-plane and out-of-plane transverse loads. The deformation contours of the HS-1 model in the X (ux), Y (uy), and Z (uz) directions under the longitudinal loading direction are shown in Figure 8a [42]. The lumen behavior differs for the HS finite element model when subjected to longitudinal, in-plane transverse, and out-of-plane transverse directions.
Figure 8b,c show the FE deformation contours in X, Y, and Z directions for the FE model under in-plane transverse and out-of-plane transverse loading (X and Y-directions). The JF with lumen behaved differently in the in-plane transverse directions than a transverse isotropic material (Figure 8b). Figure 8a shows the FE contours of the HS-1 model subjected to directional fiber loading.

5.2. Simulation Results of JFR Polypropylene Using Micromechanics Approach (Second Stage of Homogenization)

In this section, the elastic properties of JFR polymer composites are presented by conducting analytical and simulating studies. Jute, a NF with lumen, lignin, hemicellulose, and cellulose was considered for the study. The homogenized properties of JF with different HS are measured. Six HSs models were considered, and each structure is different based on the lumen percentage. The homogenized properties of six hierarchically structured JFs were further used in the second level of homogenization to quantify the JFR polymer matrix composite. Figure 9 depicts the FE models at 0.1 and 0.6 volume fractions, as well as the homogenized JF and polypropylene matrix representations.
The longitudinal modulus (E1) of the JFR polymer composite is presented in Figure 10. The longitudinal modulus decreases at all volume fractions of JF in all Hs models considered for the study, from HS-1 to HS-6. The decrease in E1 is greater at higher volume fractions than at lower volume fractions of JF. Lumen is the primary parameter that determines the property of the HS model. The modulus E1 decreases as the lumen percentage increases from HS-1 to HS-6. Analytical results are also compared with numerical results and good agreement is found. In the authors' previous studies, it was found that the synthetic fiber reinforced composite longitudinal modulus (E1) is not affected by deboning defects and moisture defects [24,41], but the behavior of the NF is different when compared to natural fiber. The HS of the NF has a considerable influence on the E1. From HS-1 to HS-6, the percentage of lumen has increased as a result; the cellulose percentage has decreased as a result, the E1 has decreased from HS-1 to HS-6. Not all the JFs will show the same HS, and selecting the fibers with a high cellulose percentage or low lumen percentage is desirable to achieve the high longitudinal modulus. Perfect alignments between the analytical and FE results are observed at every volume fraction of JF.
Transverse Modulus (E2) also decreased from HS-1 to HS-6 and at a higher volume fraction of JF; the property loss is high, whereas at lower volume fraction of JF the effect of HS is negligible (Figure 11). The main changing parameter of HS is the percentage of lumen in the structure, it increases from HS-1 to HS-6, and the increase of the percentage of lumen decreases the contribution of cellulose in the fiber as a result of the decrease of the modulus. The simulation results are compared with the analytical results, and both results are in good agreement.
The in-plane shear modulus (G12) is not changed with HS (Figure 12). The magnitude of G12 magnitude increases with increasing fiber percentage; however, the influence of HS is negligible on this property. This means that increasing lumen percentage or decreasing cellulose is not affected by final G12.
The out-of-plane shear modulus G23 is influenced by the type of HS of JF, especially at volume fractions of 0.6, 0.5, 0.4, and 0.3 of JF (Figure 13). At lower volume fractions of JF, i.e., 0.1 and 0.2, no such changes are observed in the G23.
Figure 14 shows the major Poisson’s ratios ν12 and ν13 of a JFR polymer composite. ν12 is estimated from the transverse and longitudinal strain of the RVE. The longitudinal strain is obtained by applying the load in the direction (1) of the fiber, under the same load, the RVE will experience transverse strain (ε2), and then the ratio of the transverse strain (ε2) to the longitudinal strain (ε1) will be the major Poisson’s ratio (ν12). Similarly, ν13 is obtained by dividing (ε3) and (ε1) of the JFR composite of the same RVE.
Compared with synthetic fiber composites, ν12 and ν13 are not the same for HS-1, HS-2 and HS-3 structured composites. The highest percentage of cellulose is responsible for this deviation in HS-1, HS-2 and HS-3 model structures. The largest lumen content giving the same response in transverse directions (2 and 3). Unlike ν12 and ν13 of JF, the major Poisson’s ratio of JFR polypropylene composite (Figure 7) shows a clear variation up to HS-3; after that, the ν12 becomes the same as the ν13. This behavior is only due to the matrix phase.
The minor Poisson’s ratio ν21 and ν23 are presented in Figure 15. Compared to ν21, the magnitude of ν23 is very high. The reason for the high magnitude is the increased response of the lumen of the JF.
Currently, jute fiber is utilized in a variety of industries, such as textiles, vehicles, and even some load-bearing applications. In the automotive industry, bio-polymers and advanced composites made from jute are used for manufacturing parts like cup holders, trunk liners, and door panels [45,46,47].

6. Conclusions

Natural fiber reinforced composites manufactured with jute fibers (JFs) and polypropylene matrix are analyzed considering the hierarchical structure (HS) of jute. Different HSs are considered based on different percentages of JF constituents, such as cellulose, lignin, hemicellulose, and lumen.
The type of HS of JF was found to influence the elastic properties of jute fiber reinforced (JFR) polyester composites. Analytical and micromechanics-based finite element models are used to generate the results. A perfect alignment is observed between the analytical and simulation results.
Increasing the lumen percentage from 13 to 35% in the JF from HS-1 to HS-6, decreases the longitudinal modulus (E1) of the JF from 83.75 to 54.12 GPa. The transverse modulus (E2 and E3) of the same fiber decreased from 12.70 to 6.90 GPa. The in-plane shear modulus G12 increased from 3.46 to 4.19 GPa, while the out-of-plane shear modulus G23 decreased again from 7.12 to 3.69 GPa. The lumen and cellulose percentages of JF are not significantly influenced by E1 and E2 and the out-of-plane shear modulus (G23) at a lower volume fraction of JF in the polypropylene matrix. From both analytical and numerical simulation models, it is found that the influence of HS on in-plane shear modulus is negligible.
The major Poisson’s ratio (ν12 and ν13) of JF for different HS models is the same. However, for JFR polyester composites, there was a clear difference in ν12 and ν13 for HS-1, HS-2, and HS-3 models. This is only due to the role of the polypropylene matrix. For JF with different HS models, the magnitude of minor Poisson’s ratio ν21 is much smaller than ν23. The same trend continued for JFR composites due to more elongation of the lumen under transverse loading.

Author Contributions

Conceptualization, P.P. and S.B.K.; methodology, N.K.S.R.M. and V.V.M.V.; formal analysis, K.K.S. and K.A.M.; writing—original draft preparation, P.P., E.L. and C.P.; writing—review and editing, E.L. and C.P.; supervision, D.B., E.L. and C.P.; funding acquisition, E.L. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by a grant of the Romanian Ministry of Research, Innovation and Digitalization, project number PFE 26/30.12.2021, PERFORM-CDI@UPT100—The increasing of the performance of the Polytechnic University of Timișoara by strengthening the research, development and technological transfer capacity in the field of “Energy, Environment and Climate Change” at the beginning of the second century of its existence, within Program 1—Development of the national system of Research and Development, Subprogram 1.2—Institutional Performance—Institutional Development Projects—Excellence Funding Projects in RDI, PNCDI III.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors would like to thank the All India Council for Technical Education (AICTE), India, for giving the financial grant to the first authors of this paper to procure the Digital Universal testing machine. 8-42/FDC/RPS (POLICY-l)/2019–2020 are the file number.

Conflicts of Interest

The authors declare no conflict of interest.

Nomenclature

F Φ Force on the RVE
Force taken by Lumen
Force taken by lignin
Force taken by hemi cellulose
Force taken by cellulose
FmForce taken by the Matrix
σ Φ RVE stress under longitudinal loading
σαLumen stress under longitudinal loading
σβLignin stress under longitudinal loading
σγHemi cellulose stress under longitudinal loading
σδCellulose stress under longitudinal loading
A Φ cross-sectional area of the composite
A α cross-sectional area of the Lumen
cross-sectional area of the lignin
cross-sectional area of the hemi cellulose
cross-sectional area of the cellulose
Amcross-sectional area of the Matrix
σ Φ RVE stress under longitudinal loading
σαLumen stress under longitudinal loading
σβLignin stress under longitudinal loading
σγHemi cellulose stress under longitudinal loading
σδCellulose stress under longitudinal loading
E1 Φ Longitudinal Elastic modulus of RVE
E1αElastic modulus of Lumen
E1βElastic modulus of Lignin
E1γElastic modulus of Hemi cellulose
E1δElastic modulus of Cellulose
HSHierarchical Structures
JFJute Fiber
JFRJute Fiber Reinforced
NFNatural Fiber
NFRNatural Fiber Reinforced
RVERepresentative Volume Element
ε1 Φ Longitudinal Strain of RVE
ε1αLongitudinal strain of Lumen
Δ Φ Transverse deformation of RVE
Δ αTransverse deformation of Lumen
Δ βTransverse deformation of Lignin
Δ γTransverse deformation of Hemi cellulose
Δ δTransverse deformation of Cellulose
Δ mTransverse deformation of matrix
ε2 Φ Transverse Strain of RVE
ε2αTransverse strain of Lumen
ε2βTransverse strain of Lignin
ε2γTransverse strain of Hemi cellulose
ε2δTransverse strain of Cellulose
ε2mTransverse strain of matrix
ε2 Φ Transverse Strain of RVE

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Figure 1. JFR composites specimens at 30% of weight (a) and testing of the JFR composite on tensile testing machine (b).
Figure 1. JFR composites specimens at 30% of weight (a) and testing of the JFR composite on tensile testing machine (b).
Materials 15 07032 g001
Figure 2. Idealization of natural fiber and selection of RVE with reference to the global coordinate system (X, Y and Z).
Figure 2. Idealization of natural fiber and selection of RVE with reference to the global coordinate system (X, Y and Z).
Materials 15 07032 g002
Figure 3. RVE under longitudinal (a) and transverse (b,c) loading. (Red arrows represent the loading direction).
Figure 3. RVE under longitudinal (a) and transverse (b,c) loading. (Red arrows represent the loading direction).
Materials 15 07032 g003
Figure 4. Representation of Natural fiber structure: jute plant (a) fiber bundle of the plant (b), cross-sectional view of the fiber bundle (c) and representation of single fiber with constituents (d).
Figure 4. Representation of Natural fiber structure: jute plant (a) fiber bundle of the plant (b), cross-sectional view of the fiber bundle (c) and representation of single fiber with constituents (d).
Materials 15 07032 g004
Figure 5. Finite Element Model of H1 (a) and H6 (b) models.
Figure 5. Finite Element Model of H1 (a) and H6 (b) models.
Materials 15 07032 g005
Figure 6. Modulus for different Hierarchical models. (Lumen is shown with red arrows).
Figure 6. Modulus for different Hierarchical models. (Lumen is shown with red arrows).
Materials 15 07032 g006
Figure 7. Poisson’s ratio for different Hierarchical Models.
Figure 7. Poisson’s ratio for different Hierarchical Models.
Materials 15 07032 g007
Figure 8. Finite Element contours under longitudinal (a), transverse (2-direction) (b) and transverse (3-direction) (c) loadings of HS-1 model in X, Y and Z directions.
Figure 8. Finite Element contours under longitudinal (a), transverse (2-direction) (b) and transverse (3-direction) (c) loadings of HS-1 model in X, Y and Z directions.
Materials 15 07032 g008aMaterials 15 07032 g008b
Figure 9. Finite element models of jute fiber reinforced polypropylene.
Figure 9. Finite element models of jute fiber reinforced polypropylene.
Materials 15 07032 g009
Figure 10. Longitudinal modulus (E1) of jute fiber reinforced composite.
Figure 10. Longitudinal modulus (E1) of jute fiber reinforced composite.
Materials 15 07032 g010
Figure 11. Transverse Modulus (E2) of jute fiber reinforced composite.
Figure 11. Transverse Modulus (E2) of jute fiber reinforced composite.
Materials 15 07032 g011
Figure 12. In-plane shear modulus (G12) of Jute fiber composites.
Figure 12. In-plane shear modulus (G12) of Jute fiber composites.
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Figure 13. Out-of-plane shear modulus (G23) of Jute fiber composites.
Figure 13. Out-of-plane shear modulus (G23) of Jute fiber composites.
Materials 15 07032 g013
Figure 14. The major Poisson’s ration (ν12 and ν13) of jute fiber reinforced composites.
Figure 14. The major Poisson’s ration (ν12 and ν13) of jute fiber reinforced composites.
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Figure 15. The minor Poisson’s ration (ν 21 and ν 23) of jute fiber reinforced composites.
Figure 15. The minor Poisson’s ration (ν 21 and ν 23) of jute fiber reinforced composites.
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Table 1. Longitudinal modulus from experimental studies.
Table 1. Longitudinal modulus from experimental studies.
Weight Fraction of Jute Fiber (%)Young’s Modulus in GPa
Specimen 1Specimen 2Specimen 3Specimen 4Specimen 5MeanSD
12.9512.64810.11315.69815.16915.16913.7591.055
36.4722.75519.69820.22625.28318.68921.3301.194
Table 2. Volume fraction of fiber constituents with different Hierarchical Structure.
Table 2. Volume fraction of fiber constituents with different Hierarchical Structure.
ModelVolume Fraction of Cellulose
Vc (%)
Volume Fraction of Hemicelluloses
Vhc (%)
Hierarchical Structure
Volume Fraction of lignin
Vl (%)
Volume Fraction of Lumen
Vlm (%)
HS-161141213
HS-259141215
HS-354141220
HS-449141225
HS-544141230
HS-639141235
Table 3. Constituent properties of Jute Fiber [36].
Table 3. Constituent properties of Jute Fiber [36].
ConstituentE1 [Gpa]E2 [Gpa]E2 = E3 [Gpa]G12 [Gpa]ν12 [–]
Cellulose13427.227.24.40.10
Hemicellulose84.04.02.00.20
Lignin44.04.01.50.33
Table 4. Geometrical details of the Hierarchical Structure for FE Models.
Table 4. Geometrical details of the Hierarchical Structure for FE Models.
ConstituentModel
HS-1HS-2HS-3HS-4HS-5HS-6
ri (nm)ro (nm)ri (nm)ro (nm)ri (nm)ro (nm)ri (nm)ro (nm)ri (nm)ro (nm)ri (nm)ro (nm)
Lumen2.032.032.182.182.522.522.822.823.093.093.333.335
Lignin2.032.822.182.932.523.192.823.433.093.653.333.865
Hemicellulose2.823.512.933.613.193.823.434.023.654.223.864.4
Cellulose area [nm2]61.295 59.058 54.03649.02844.01339.178
Table 5. Comparison of longitudinal modulus from experimental and simulation studies.
Table 5. Comparison of longitudinal modulus from experimental and simulation studies.
Weight Fraction of Jute Fiber (%)Young’s Modulus in Gpa% Error of FEM Results
with Experimental Results
ExperimentalAnalyticalFEM
12.9513.75913.8813.981.64%
36.4721.33021.4222.626.04%
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Prasanthi, P.; Kondapalli, S.B.; Morampudi, N.K.S.R.; Vallabhaneni, V.V.M.; Saxena, K.K.; Mohammed, K.A.; Linul, E.; Prakash, C.; Buddhi, D. Elastic Properties of Jute Fiber Reinforced Polymer Composites with Different Hierarchical Structures. Materials 2022, 15, 7032. https://doi.org/10.3390/ma15197032

AMA Style

Prasanthi P, Kondapalli SB, Morampudi NKSR, Vallabhaneni VVM, Saxena KK, Mohammed KA, Linul E, Prakash C, Buddhi D. Elastic Properties of Jute Fiber Reinforced Polymer Composites with Different Hierarchical Structures. Materials. 2022; 15(19):7032. https://doi.org/10.3390/ma15197032

Chicago/Turabian Style

Prasanthi, Phani, Sivaji Babu Kondapalli, Niranjan Kumar Sita Rama Morampudi, Venkata Venu Madhav Vallabhaneni, Kuldeep Kumar Saxena, Kahtan Adnan Mohammed, Emanoil Linul, Chander Prakash, and Dharam Buddhi. 2022. "Elastic Properties of Jute Fiber Reinforced Polymer Composites with Different Hierarchical Structures" Materials 15, no. 19: 7032. https://doi.org/10.3390/ma15197032

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