Chemical Modification on Woven Jute and Nonwoven Wet-Laid Glass Fiber Sheet Reinforced Poly-(ε-Caprolactone) Composites ()
1. Introduction
Composite is a substance that’s formed using mixing two or more verity of substances in such a way that the outcome substances delivered with properties superior contrast to ordinary ones. Polymer matrix-based reinforces composite got comparatively more attraction compared to ceramic and metal matrix as well as in the area of textile and material research. The exceptional resistance of glass fibers into the ecological assault produced glass-fiber-reinforced polymers more appealing among food and chemical sectors as well as due to low elongation at break, better stiffness and strength with preferable properties turned PCL significant biopolymer contributor in the area of tissue engineering, medical surgery, aerospace, construction industry, automobile, environmental engineering application as well as unremittingly opening new industrial possibilities are broadening day by day [1] [2] [3] [4] [5]. Ordinary jute can be utilized for elementary and non-invasive industrial textile items, whether expected property achieved throughout proper modification, as well as the industry can be capable of offering professional and environmentally friendly products within a reasonable price. Jute has a good enough mechanical property of high specific mechanical strength, good moisture regain (13.75%) and 100% degradable, renewable resources, ease of access, lower-cost, highly breathable, and lower contamination emission to nature [6] [7]. These factors make jute fiber along with coir, flax, sisal, pineapple, ramie, hemp, and kenaf a high point of interest for researchers for using as a reinforcing material [8] - [15].
As a second, most used organic fiber jute will be an outstanding substitute, whereas prospective high specific strength, nonrenewable resources, and a comparatively lower price is an important issue [16]. On the other hand, glass fiber gained enormous attention from the past century to the researchers in compared to other synthetic fiber benefits including significant stiffness, high heat, corrosive and impact resistance, comparatively lower price and simplicity of setup, better processability, relatively better immunity to environmental substances and fatigue [17].
For this reason, a substitute for concrete, wood, and metal materials with glass fiber used a broad array utilizing in fabricating different types of composites such as insulation, heat and corrosion-resistant application, and noise reduction [18]. K, Jarukumjorn et al. [19] investigated the tensile strength and bending strength improved after using glass fiber as reinforcement in the sisal-PP composite without influencing tensile and bending modulus as well as significant improvement exhibited in the thermal degradation along with moisture absorption properties of the composite. Manually chopped short length jute with glass fiber reinforced hybrid PET composites exhibit significant improvements in mechanical property due to affecting heap order [20]. R, Velmurugan et al. [21] studied adding glass fiber with palmyra hybrid composite improves the mechanical property, and adding extra glass fiber exhibited further improvements in successive rate. Huq, Tanzina, et al. [22] performed a comparative interfacial property evaluation of jute glass-fiber-reinforced PET composite results exhibited glass matt-pet composites comparatively better mechanical (Tensile, flexural and water absorption) properties compared to other composites in the experimental group. M, Boopalan, et al. [23] executed a comparative investigation in jute-sisal reinforced PLA biocomposites where jute reinforced PLA biocomposites outcome revealed significantly improved mechanical properties than sisal. T. Munikenche Gowda et al. [24] analyzed the mechanical property test of jute-glass-fiber reinforced polyester Figured even though mechanical properties of jute/polyester composites tend not to own matrix and strengths as large as those of other traditional composites, they could process much better advantages than timber composites and several plastics. Besides, they have some drawbacks, too; weak interfacial adhesion between natural fiber and thermoplastic is the major problem that can overcome by treating the surface of fiber using different chemical processing [25].
Alkali treatment washes out the impurities of fiber and increases the interfacial bonding between the fiber and thermoplastic polymer as well as micro-fibril rearrange of cellulosic content and lignin dissolving of highly hydrophobic content of fiber [26] [27]. After investigating previous studies, soaking jute fibers fiber in a solution of silane coupling agent for surface treatment resulting in better mechanical properties with strong interfacial adhesion also exhibited slightly improved outcomes in thermal stability over untreated even more then alkali-treated bio composites broadly contemplated in [28] [29]. Gassan et al. performed an investigation in epoxy with 3-glycidoxypropyltrimethoxysilane (KH560) treated jute and concluded with a result of enhanced 100% of dynamic modulus over untreated experimental composites. Wang, Xue, et al. [30] studied woven jute with silane coupling agent (KH560) modified epoxy laminated composite trend to better adhesion between fiber epoxy with enhanced crystallinity and thermal stability, 10 times better silicon grafted in jute fiber exhibit upon EDS observation as well as tensile strength (42%), tensile modulus (39%), bending strength (49%) and flexural modulus (51%) enhanced due to silane treatment compared to untreated woven jute which is comparatively better than few wood-based composite application. Having OH and amine (Primary NH2 Secondary NH4) groups, the silane coupling agent can help to set up a bond between the fibers and polycaprolactone (PCL). Debeli et al. [31] performed comparative investigation and outcome exhibited natural fiber reinforced PLA biocomposites and concluded with fiber, which surfaces treated with a silane coupling agent and alkali exhibited noticeable outstanding results in the area of tensile strength and modulus, flexural strength and impact strength as well as enhanced burial degradation process demonstrated over untreated bio-composites. Both jute and glass fiber have a significant property to develop advanced products as well as further research needed.
However, only a few researchers investigated and fabricated woven jute, and wet-laid glass fiber sheet reinforced PCL composites using a hot-pressing method. In this research paper, woven jute fabric surface chemically modified with a silane coupling agent, alkali and alkali-silane combined treatments along with commercial untreated woven jute fabric for the comparative purpose. A design was containing eight optimized samples prepared throughout the hot-pressing method according to different hot-pressing temperatures, time and pressure to find out preeminent processing conditions and effects of different chemical treatments in optimized woven jute and glass fiber reinforced PCL composite properties.
2. Experimental
2.1. Materials and Method
In this experiment, polycaprolactone (PCL) granules were used as a matrix with dichloromethane (DCM) as a solvent for dissolving PCL. For fiber surface treatments, alkali (sodium hydroxide-NaOH ≥ 98%), and silane coupling agent (3-glycidoxypropyltrimethoxysilane-KH560 ≥ 98%) with a molecular weight of 236.34 obtained from Hangzhou mi ke chemical instrument co. Ltd, Hangzhou, China. Besides, woven jute fabric was collected from the local market of Narsingdi, Dhaka, Bangladesh-1200, then cut manually 20 × 20 cm & specimens comprising 40 wt% jute fibers were fabricated using the hot-pressing method. Nonwoven wet-laid glass fiber sheet obtained from Xinxiang filter material Co. Ltd., China, was use as a reinforcement of PCL with woven jute fabric. Other significant parameters of jute fiber, glass fiber, and PCL matrix are presented in Table 1.
2.2. Fiber Treatments and Composite Fabrication
An amount of 7% (7 g/100mL water) NaOH solution was prepared. Woven jute fabric (20 × 20 cm) dipped in a solution of 7% NaOH and dried in a woven (Shanghai Hasuc Tools Fabricate Co. Ltd., model: DHG-90538) at 80˚C temperature for 60 minutes. After completing the drying process, treated woven jute fabric kept 9 hours at room temperature. Again, jute fabric is saturated in a solution of KH560 (7 g/100mL water) and kept for a maximum of 10 hours at room temperature. Besides, woven jute fibers were dipped in a solution of 7% NaOH and 7% KH560/100mL water for comparison purposes. Afterward, both treated jute fibers had rinsed with regular water using acetic acid till surplus alkali (NaOH) and silane (KH560) were removed away and maintained a pH value of 5 for both chemically treated fiber due to enhancing hydrolysis process. Subsequently, completion of the treatment process, both treated fibers dried in woven at 80˚C for almost 5 hours separately for reduced absorbed moisture content and eliminate unwanted void space during the fabrication of composites.
Table 1. Detailed mechanical properties of jute, glass fiber sheet, and polycaprolactone.
Furthermore, silane comprises an epoxy group that functions as an organofunctional silane trend to enhance interfacial adhesion within fibers and reinforced matrix—a detailed three-stage chemical reaction mechanism of KH-560, and NaOH with woven jute fabric representing in Figure 1. As demonstrated in Scheme 1, silane reacts with water to form silanol and alcohol. In Scheme 2, a stable covalent bond was created using reaction with a fibers hydroxyl group and silanol [32]. As demonstrated in Scheme 3, methyl functional group of silanes would react with the matrix hydroxyl group when they reinforced together; thus, an enhanced bond formed within PCL matrix and silane coupling acid resulting enhanced fiber-matrix adhesion. Natural cellulose is a monoclinic crystalline lattice of cellulose-I structure. This structure converted into Na-cellulose-I after reacting with alkali which is exhibiting in Scheme 4. Besides, this structure changed to cellulose-II due to washing with distilled water [1].
The treated woven jute fabrics were exposed to open air for five days, then a solution of PCL (1:3 ratio for PCL: DCM) took in a glass beaker and mixed using electric stirrer almost 90 minutes until PCL granules dissolve properly within DCM solvent. Woven jute fabric wetted with PCL solution manually and dried 2 h at room temperature before going through the fabrication process of composites, A design containing eight samples followed closely, as well as a hot-pressing process, was selected and intended to detect a compatible condition for assembling composite based on different hot-pressing temperatures of 155˚C and 165˚C, time 9-minute heating with 6-minute curing and pressure of 7 MPa respectively. Moreover, a detailed schematic fabrication process of woven jute and glass fiber reinforced PCL composite is presented in Figure 2.
Figure 1. Scheme (1) representing the chemical structure of silane coupling agent (KH-560), (2), (3) representing the reaction of KH560 with woven jute fabric (4) representing the chemical reaction of NaOH with woven jute fabric [26] [28].
Figure 2. The schematic fabrication process of woven jute fabric and glass fiber reinforced PCL composites.
3. Characterization
3.1. Fourier Transform Infrared (FTIR)
Fourier transform infrared (FTIR) was performed to observe the spectra changes and surface functional groups due to chemical treatments. Dried 2 mg powder of jute fiber mixed with KBr further compounded into a fine powder using mortar and pestle then compressed. Jute fiber both treated and untreated surface chemistry analyzed using (Nicolet, Model: iS50 FT-IR) within a range of 500 - 4000 cm−1.
3.2. Tensile Strength and Modulus
Tensile strength test completed and documented data at room temperature of 20˚C and 65% relative humidity employing a computer-controlled Instron tester (Model: 5943, Instron Shanghai Ltd.) The entire testing was conducted following the standard of GB/T1447-2005 with a loading speed rate of 5 mm/min [33]. For tensile strength specimen tested and recorded data carefully.
3.3. Water Absorption
WA measured following ASTM D570 standard, and each of the calculations & outcomes was recorded carefully. Before immersion, all prepared optimized samples dried at 60˚C for 5 hours. Subsequently, the WA test has been sustained to 180 hours. Each of the outcomes listed carefully within the specified time using Yueping automatic electrical balance (capacity of Min: 10 milligrams Max: 100 gm, Model: FA1004B, Shanghai Yueping Scientific Tool Co., Ltd., China) in room temperature.
[34]
where, Mt stands for sample weight, t for immersion time, and M1 is initial dry sample weight.
3.4. Thickness Swelling
Thickness swelling (TS) was conducted according to ASTM, D570 standard. Prepared specimens immersed in distilled water [35] and recorded data in room temperature at 20˚C and 65% humidity using a thickness tester (Model: FY144, Wenzhou Fang yuan Instrument Co. Ltd., China). In total, five times tested every optimized sample and averaged to get the accurate data.
3.5. Thermogravimetric Analysis of Optimized Composites
Thermogravimetric or thermal decomposition analysis (TGA) of woven jute and glass fiber reinforced PCL composites studied to observe the thermal degradation behavior of treated and untreated composites. Whereas the sample weight was 3 to 8 mg, temperature range, and the rate was respectively 30 - 600 (˚C) and 20˚C/min−1 using (NETZSCH Model: TG209 F1 Libra; Germany).
3.6. Morphology Analysis of Optimized Composites
The morphological composition of woven jute and glass fiber reinforced PCL composites was studied to see the interfacial adhesion between fiber and matrix using an SEM (Scanning Electron Microscopes JSM-5610LV from JEOL, Japan) after being coated with gold (JFC-1600 fine auto coater from JEOL, Japan). The SEM specimens received from fracture during tensile strength test.
4. Results & Discussion
4.1. Characterization of Treated and Untreated Composites Surface Chemistry
The consequences of silane and alkali treatments significantly enhanced the mechanical properties of woven jute, and glass fibers reinforced PCL composites over untreated composites distinctly observed from outcomes of Figure 5. The outcomes of FTIR spectroscopy due to chemical treatments in woven jute fabric are exhibited in Figure 3.
The treated and untreated composites revealed a broad and powerful vibration spectrum in 3435 cm−1, 3440 cm−1, 3439 cm−1, and 3434 cm−1 for untreated, silane, alkali, and combined-treated jute suggesting O-H stretching vibration due to cellulose [36]. In 2950 cm−1 and 2871 cm−1 vibration peak detected for methyl and methylene group (cellulose and hemicellulose) revealed by C-H stretching that transfer to 2917 cm−1, 2865 cm−1 for silane in alkali 2942 cm−1, 2865 cm−1 and combined treated jute which is slightly minimized and transferred to 2915 cm−1 and 2853 cm−1 respectively [37]. The robust peak is showing in untreated jute at 1730 cm−1 corresponding vibration stretching from the carboxylic acid (C=O) and ester attributing of having hemicellulose content in jute fiber [38] which due to structural change shifted silane 1743 cm−1 and alkali 1733 cm−1
Figure 3. FTIR spectroscopy of untreated and treated woven jute and glass fiber reinforced PCL composites.
after chemical treatment. Besides, absorption spectra detected at 1465 cm−1 represents -CH3 bond, peaks presenting in 1375 cm−1 and 1248 cm−1, respectively attributing of lignin C-H stretching vibration. These peaks minimized in the treated spectra are an indication of lignin removed after chemical treatment [39]. Furthermore, peaks presenting in untreated jute fiber spectra around 1045 cm−1 representing C-O-C, O-H and C-O stretching of celluloses and hemicellulose [3] [38].
As demonstrated in Figure 4, small spectra in combined treated jute, indicating near 1000 cm−1 due to asymmetric stretching vibration of Si-O-Si or cellulose-O-Si bonds because of possible reaction among cellulose hydroxyl and hydrolyze of silane [40] [41]. KH560 holds OH and NH2 group, which creates a connection involving treated fibers with the matrix as well as occupying polar and non-polar groups supplied maximum pressure and heat significantly toward treated fiber throughout composites fabrication [31]. Also, the effect of chemical treatments on woven jute fabric surface is presented in Figure 4.
4.2. Tensile Strength
Figure 5 exhibiting tensile strength of woven jute & glass fiber reinforced PCL composites for various preparing conditions (preparing conditions 1, 2, 3, 4, …8), as displayed in Table 2.
Proper working parameters are incredibly potential to provide outstanding results together with the essential chemical and physical attributes required. The chemical treatment effect observed from the outcomes of composite mechanical properties. As demonstrating, combined-treated composite sample C2 (7% of NaOH and KH560 with 165˚C temperature and 7 MPa Pressure) exhibiting a
Figure 4. The photographic spectacle of (a) Raw/untreated; (b) Treated with alkali; (c) Silane; (d) Alkali-silane combined treated woven jute fabric.
Figure 5. Tensile strength of woven jute and nonwoven glass fiber reinforced PCL composites.
Table 2. Detailed process and parameter for fabricating woven jute and glass fiber reinforced PCL composites.
substantial maximum effect over other composites. The fiber mass volume ratio has a vital role in keep and dispersing by PCL construction via an external heat and load supplied on composites [2]. Furthermore, 9 minutes of hot-pressing with 6 min curing considered appropriate requirements for this experimental group to get extraordinary results. Mechanical properties of composite mostly depend on interfacial adhesion between fiber and matrix as well as individual fiber and matrix strength and modulus [1]. Alkali and silane combined treatment occur potential physical and chemical modification into fiber surface resulting in better interfacial bonding with enhanced tensile strength and modulus over untreated fiber. Because insufficient heat transfer failed to spread PCL properly through jute fabric leads to improper wettability to the surface of jute fiber as well as the interface of glass fiber, causing comparatively weak interfacial adhesion between untreated jute fiber and PCL consequences sample R1 displaying the lowest results in the experimental group. Combined treatment in nonwoven jute fiber matt significantly reduces jute fiber stiffness with increased fiber surface roughness develops better interfacial adhesion [28] within jute fiber and PCL, resulting in exhibiting better tensile strength, which is almost 48.37% and 32.04% higher compared to untreated composites tensile strength.
4.3. Water Absorption (WA)
WA test was performed to observe the amount of moisture absorption of optimized composites (R2, A2, S2, and C2) after immersion in distilled water for a specific period, and the result is displayed in Figure 6.
Figure 6 exhibiting the effect variation due to consuming water in air-filled voids, and pores contribute to up-taking more water and increase the weight of composites. Moisture absorption of composite influenced by cellulosic fiber
Figure 6. Water absorption behavior of treated and untreated woven jute and glass fiber reinforced PCL optimized composites.
content, matrix stiffness, hardness, void, or empty hole in composite, humidity, and temperature [42]. As demonstrated, untreated jute and glass fiber reinforced PCL composite optimized sample R2 consumed more water in the air-filled void and pores basically created during fabrication of composites over treated composites, which is 31.73% more than silane treated optimized sample S2. That is an indication of changing in dimensional stability of the cellulose-based composites. The WA behavior of composites determined by the capability of their fiber to consume water or moisture due to the existence of hydroxyl groups that mainly responsible for WA throughout the creation of hydrogen (H) bonding. The higher the moisture content of any organic fiber, higher alteration in the mechanical and physical characteristics of the composites, resulting in lower adhesion between reinforced matrix with fiber [35].
For this reason, untreated jute and glass fiber reinforced PCL composites displayed maximum WA that is 10.4%. Besides, silane and alkali treatment enhanced jute fiber roughness topography and improved aspect ratio influenced in better fiber-matrix interfacial adhesion, including air-filled voids and pore filled up throughout the preparation of composite trend to lower water uptake. Moreover, glass fiber matt is highly hydrophobic that limits the moisture consumption between glass and jute fiber due to high toughness nature of the PCL matrix [22] [43]. After conducting WA, we observed the common tendency of composites showing significant changes in weight with extent immersion time as well as consuming excess moisture at the beginning of immersion until achieved a stable condition.
4.4. Thickness Swelling (TS)
Thickness swelling behavior of both treated and untreated optimized woven jute and glass fiber reinforced PCL composites exhibited in Figure 7.
Figure 7. Thickness swelling behavior of treated and untreated woven jute and glass fiber reinforced PCL optimised composites.
TS of composite has been arising predominantly due to the vulnerability of lignocellulosic fiber around the surface of composite because the amount of lingo cellulosic fiber varies with distinct moisture material [44]. The hydrophilic properties of lingo cellulosic substances with medium called capillary action get the consumption of water once the specimens saturated in water consuming the fiber resulting in changing the dimensional stability of the composite [42]. Figure 7 demonstrated that, the untreated optimized composites R2 showing maximum results due to this reason among the optimized experimental group, which is around 7.9%. Which is also an indication of low interfacial adhesion, micro air-filled void space, and pores appear in the composite that uptake the water inside those micro-voids and pores take part in changing dimensional stability with reversible and irreversible swelling of the composites [45]. Besides, the lowest TS result exhibiting the combined treated optimized sample C2 after 180 hours of immersion, which is respectively 12.06% lower than alkali-treated optimized sample A2 and 8.92% for silane treated optimized sample S2 attributed to comparatively better reducing the hydroxyl (OH) group responsible for water uptake with chemical treatment [46]. At the beginning of immersion, the untreated composites incessantly uptakes more water and showing exceeding TS change than the treated reinforced composites. In addition, silane treatment, hydrogen (H), and a covalent bond formed with polymer matrix resulting in enhanced fiber-matrix adhesion. It summarized from Figure 7, combined treated woven jute and glass fiber reinforced composite exhibited the lowest result, whereas silane and alkali-treated jute and glass fiber reinforced composite showing moderate result over untreated composite, which recorded the highest score in the optimized experimental group.
4.5. Thermogravimetric Analysis of Composite
The Thermogravimetric Analysis (TGA) outcomes affirmed that chemical treatments of woven jute fabric in jute and glass fiber reinforced PCL composites raised the operation of degradation resistance for these optimized processing composites, as exhibited in Figure 8.
Thermal stability is an essential property of fiber-reinforced composites [47]. Untreated composite decomposed in two-stage and started decomposing at lower temperatures compared to treated composite corresponding optimized samples. As demonstrated in Figure 8, both WL % and DWL% graph. Untreated jute initiated the first degradation step around 250˚C, and the second stage starts from 449˚C, which proceeded to accomplish decomposition around 520˚C. Alkali-treated composite overcomes this tendency and degradation completed in a single step due to the removal of hemicellulose as well as increase, and decrease of PCL reinforced molecular mass comparatively affects the thermal degradation process of the composites [48]. Besides, chemically treated woven jute and glass fiber reinforced PCL composites exhibiting improved thermal stability and enhanced the degradation of the composite over untreated composites. The thermal decomposition starts for alkali-treated composite from 302.5˚C following
Figure 8. Thermal stability of treated & untreated woven jute and glass fiber reinforced PCL composites.
reached to the ultimate stage near about 500.8˚C. As demonstrated, combined treated nonwoven jute and glass fiber reinforced PCL composite exhibited bit enhanced thermal stability compared to silane and alkali-treated composite, which is an indication elimination of natural hydrolyzed elements that decompose before that lignin and cellulose [49]. Moreover, decomposition of jute fiber can describe by heat range between 25˚C - 150˚C composites weight loss indicated because of water volatilization, the second peak allocating between 190˚C - 300˚C, indicating the degradation of hemicellulose, the third peak showing between 300˚C - 360˚C attributed to the degradation of cellulose. Lignin degradation takes place between 280˚C - 500˚C [28] [50]. Moreover, a detailed decomposition process of selective processing conditions is enlisted in Table 3.
4.6. Composites Morphology Analysis
Surface morphology of woven jute and glass fiber reinforced PCL composites obtained from tensile fracture is displayed in Figure 9.
Figure 9(a) showing SEM images of nonwoven glass fibers in 2 µm range, whereas that Figure 9(b) showing the close look of glass fibers in 10 µm. SEM morphology of Figure 9(c) exhibiting the cross-sectional view of silane treated unidirectional woven jute attributed to the stiffness of composites.
That is an indication that PCL dispersed adequately into the surface of jute fibers without compromising essential distinctness, leading to improved ductility and stiffness of composites [4]. Figure 9(d) exhibiting empty hole or void content in the surface of untreated optimized sample. These voids take place during fabrication that likely causes detrimental effects in the mechanical properties of composites, which also responsible for excessive moisture absorption [2]. The
Figure 9. SEM morphology of woven jute and glass fiber reinforced PCL composites at different magnification range.
Table 3. Thermal decomposition values of optimized woven jute and glass fiber reinforced PCL composites derived from Figure 8.
Where Trange stands for temperature range and Wloss for weight loss.
fractured surface of Figure 9(e) clearly demonstrates lower adhesion within fiber and PCL matrix, where fiber pull-out and debonding phenomena can observe. Figure 9(f) revealed that due to chemical treatment, PCL grafted thoroughly into the surface of jute fibers without any destruction. Alkali-silane combined treatment promotes removing hemicellulose content that is responsible for strong hydrophobic character of natural fibers thus improved fiber-matrix adhesion formed with fibrillate tendency [5]. Besides, microcracks observed in specific figure evidence of higher amount of load efficiently transferred by extending fiber-matrix interface, respectively.
For this reason, thermal stability and moisture resistance capabilities of composites significantly enhanced [3] [19].
5. Conclusion
In this experiment, woven jute and glass fiber reinforced PCL composites were fabricated using the hot-pressing method where jute used as a sandwich with upper and lower nonwoven glass fiber sheets using PCL as a matrix. The experiment was conducted to distinguish the effects of chemical treatment and detect hot pressing preeminent parameters such as hot-pressing temperature, pressure, and time. As demonstrated, alkali and silane combined treated optimized sample C2 exhibited the highest tensile strength. Surface chemistry was analyzed using FTIR, and observed fiber modification occurred in every treatment of woven jute fiber. Mechanical properties of composite influenced by interfacial adhesion between fiber and matrix as substantiated after observing morphological structures with a scanning electron microscope (SEM). Mechanical properties, tensile strength resulting in 48.38% improvement in tensile strength in alkali-silane combined treated composite over untreated optimized composites. Better fiber-matrix interfacial adhesion attributes accelerated thermal stability of combined treated composite compared to alkali, silane, and untreated commercial woven jute-glass fibers reinforced PCL composites. Eventually, a 165˚C hot pressing temperature, 7 MPa pressure, and 9 minutes of heat pressing with 6 minutes curing can consider as a suitable parameter for this composite to produce outstanding lightweight woven jute and glass fiber reinforced PCL composites. Besides, alkali-silane combined chemical treatment revealed maximum effective outcomes from the experimental group.
Acknowledgements
The authors gratefully acknowledge the Hangzhou mi ke chemical instrument co. Ltd and Xinxiang filter material co. Ltd for providing experimental materials.
List of Abbreviations
PCL = Polycaprolactone, Wt% = weight %. DCM = Dichloromethane, ˚C = Celsius, GPa = Giga pascal, MPa = Mega pascal, Kj/m2 = Kilojoule/square meter.