Preparation of Syntactic Foams made from Green Polyethylene and Glass Microspheres: Morphological and Mechanical Characterization

Cosse, Renato Lemos; Morais, Ana Carolina Lemos de; Silva, Lucas Rafael Carneiro da; Carvalho, Laura Hecker de; Reis Sobrinho, José Francisco dos; Barbosa, Renata; Alves, Tatianny Soares

doi:10.1590/1980-5373-MR-2019-0035

Abstract

Polymeric syntactic foams are composites made from the mixture of Hollow Glass Microspheres (HGM) and polymer matrices. One of their main characteristics is their low density and the production of these composites using a matrix derived from renewable sources potentiates their development without neglecting sustainability. In this paper , the properties of High Density Polyethylene (HDPE)/HGM syntactic foams containing 1% and 5% w/w HGM and 5% w/w of a compatibilizer are assessed. The composites were prepared by two processing routes: single screw extruder and twin screw extruder. The morphology and mechanical properties (tensile and impact) of the syntactic foams thus manufactured were ascertained. Morphological analysis indicated that matrix/filler adhesion was poor for all samples and that the best HGM dispersions were obtained in twin screw extruded samples. Mechanical properties were affected by the processing route adopted and by the content of hollow glass microspheres added. Elastic modulus, tensile strength and strain were reduced by 20, 10 and 23%, respectively, in systems processed in a twin screw extruder. Impact strength was the exception, with an increase of more than 300%. Higher contents of hollow glass microspheres led to reductions in mechanical strength of the syntactic foams, varying from 5% for the elastic modulus to 50% for strain.

Keywords:
Syntactic foams; hollow glass microspheres; green polyethylene

1. Introduction

The search for lighter materials to facilitate transport and use, has led to a growing number of studies in areas, such as science, engineering and design. Polymers and polymer composites are promising options to replace metallic and ceramic materials¹1 Stephen E, Beck W. Introduction. In: Stephen E, Yalcin B, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds. Oxford, UK: Elsevier; 2015. p. 1-6. in several applications as they are light in weight, have a good set of mechanical properties, are easy to process, can be molded in different shapes and can be easily colored.

Composites consist of a mixture of different materials which maintain their original properties and are separated by an interface. Composites are created in order to obtain new materials with unique properties. In general, one of their components acts as reinforcement (filler) and the other as a binder material (matrix). If the matrix is a polymer, a polymer composite is obtained. The development of composites is currently one of the fastest, simplest and cheapest techniques to combine material properties leading to products with distinct characteristics which are not typical of the matrix. The scientific community has expanded research so that composites can be obtained with materials that, in addition to their economic advantages, are more ecologically sound, either within the production chain, applications or disposal after use²2 Li J, Luo X, Lin X. Preparation and characterization of hollow glass microsphere reinforced poly(butylene succinate) composites. Materials and Design. 2013;46:902-909..

Fillers and matrices may be of natural or synthetic origin. Fillers can be fibrous or particulate, ranging from natural or synthetic fibers to organic or inorganic particulate materials. The partial substitution of the polymer matrix by these fillers helps to reduce the amount of synthetic polymers present in the material, which is advantageous since polymers have high production costs and are environmental pollutants when discarded. Besides, filler addition leads to improvements of different characteristics of the neat resin. Low-density composites materials are required for a multitude of applications and these materials can be prepared by incorporating a lightweight filler or gas in a polymer matrix³3 Bibin J, Nair CPR. Update on Syntactic foams. Shropshire, UK: Smithers Rapra Technology; 2010.^,⁴4 Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics. 3rd ed. Indiana: Elsevier; 2014. p. 511-554.. In the 1950s the use of syntactic foams as a new lightweight material gained prominence⁵5 Mucccio EA. Plastics processing technology. 4th ed. USA: ASM International; 1999.. The American Society for Testing and Materials (ASTM) defines syntactic foam as a composite material consisting of hollow microspheres dispersed in a matrix⁴4 Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics. 3rd ed. Indiana: Elsevier; 2014. p. 511-554.^,⁶6 Fritschel L, inventor; Bridgestone Firestone Inc., assignee. Syntactic foams and their preparation. US Patent 3856721. 1973.. Of Greek origin, the word "syntactic" means "to arrange together"⁴4 Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics. 3rd ed. Indiana: Elsevier; 2014. p. 511-554.^,⁷7 Bardella L, Genna F. On the elastic behaviour of syn-tactic foams. International Journal of Solids and Structures. 2001;38:7235-7260.^,⁸8 Banhart J. Manufacture, characterisation and application of cellular metals and metal foams. Progress in Materials Science. 2001;46(6):559-632..

Due to advances in manufacturing research for greater structural stability, Hollow Glass Microspheres (HGM) have stood out as a viable alternative since they have low density and produce composites with interesting characteristics such as dimensional quality and low mass-volume ratio⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903.. Nowadays, new mechanisms of obtaining HGM are under development, aiming at making production more accessible, with less environmental impact and optimizing the reuse of glass waste in the production chain of these materials¹⁰10 Qu YN, Xu J, Su ZG, Ma N, Zhang XY, Xi XQ, et al. Lightweight and high-strength glass foams prepared by a novel green spheres hollowing technique. Ceramics International. 2016;42(2):2370-2377..

Syntactic foams are considered as particulate filled polymer composites and they are categorized as physical foams as the matrix is not foamed chemically, but the gas-containing particles are mechanically added into the matrix⁴4 Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics. 3rd ed. Indiana: Elsevier; 2014. p. 511-554.^,¹¹11 Wouterson EM, Boey FYC, Hu X, Wong SC. Specific properties and fracture toughness of syntactic foam: Effect of foam microstructures. Composites Science and Technology. 2005;65(11-12):1840-1850.^,¹²12 Karthikeyan CS, Sankaran S, Kumar MNJ, Kishore. Processing and compressive strengths of syntactic foams with and without fibrous reinforcements. Journal of Applied Polymer Science. 2001;81(2):405-411.. The hollow microspheres are responsible for the syntactic foam´s low density, high specific strength and low moisture absorption. Besides HGM have a burst pressure high enough to withstand the forces imposed upon them during the formulation, mixing, and dispensing processes⁴4 Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics. 3rd ed. Indiana: Elsevier; 2014. p. 511-554..

Due to the synergistic effect of the processability of the polymer and the high compressive strength of the microspheres, the syntactic foam can be processed by different routes such as extrusion, injection, compression and internal mixer, maintaining a high physical integrity index of the constituents at the end of processing¹³13 Cosse RL., Araújo FH., Pinto FANC., de Carvalho LH, de Morais ACL., Barbosa R, Alves TS. Effects of the type of processing on thermal, morphological and acoustic properties of syntactic foams. Composites Part B: Engineering. 2019; 173: 106933.^,¹⁴14 Zhang B, Fan Z, Hu S, Shen Z, Ma H. Mechanical response of the fly ash cenospheres/polyurethane syntactic foams fabricated through infiltration process. Construction and Building Materials. 2019;206:552-559.. Processing versatility enables HGMs to be inserted into the production environment without major changes in already established industrial plants.

Another important feature in the formation and application of syntactic foams is the compatibility between the hollow glass microspheres and the polymer matrix. The level of interaction between the filler and the array will determine the load transfer efficiency along the interface between the components¹⁵15 Koopman M, Chawla K, Carlisle K, Gladysz G. Microstructural failure modes in three-phase glass syntactic foams. Journal of Materials Science. 2006;41:4009-4014.^,¹⁶16 Rutz BH, Berg JC. A review of the feasibility of lightening structural polymeric composites with voids without compromising mechanical properties. Advances in Colloid and Interface Science. 2010;160(1-2):56-75.. Compatibilizing agents are used to promote adhesion between the HGM and the polymer matrix, thus improving composite mechanical properties under tensile¹⁷17 Nakamura Y., Harada A., Gotoh T., Yokouchi N., Iida T., Effect of silane chain length on the mechanical properties of silane-treated glass beads-filled PVC, Composites Interfaces. 2012; 14: 117-130. and flexural stress¹⁸18 Miller A, Berg JC. Predicting adhesion between a crystalline polymer and silane-treated glass surfaces in filled composites. Journal of Adhesion Science and Technology. 2002;16(14):1949-1956.. The most commonly used compatibilizers to serve as a bridge between the matrix and the filler are those made from Maleic Anhydride, Dicumyl Maleate and Silane Agents¹⁹19 Liang JZ. Reinforcement and quantitative description of inorganic particulate-filled polymer composites. Composites Part B: Engineering. 2013;51:224-32.

20 Patankar SN, Kranov YA. Hollow glass microsphere HDPE composites for low energy sustainability. Materials Science and Engineering: A. 2010;527(6):1361-1366.^-²¹21 Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures. 2018;202:545-550.. The works of PATANKAR and KRANOV⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903., PATANKAR²⁰20 Patankar SN, Kranov YA. Hollow glass microsphere HDPE composites for low energy sustainability. Materials Science and Engineering: A. 2010;527(6):1361-1366. and ÇELEBI²²22 Çelebi H. Thermal Conductivity and Tensile Properties of Hollow Glass Microsphere/Polypropylene Composites. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering. 2017;18(3):746-753. point out the efficiency of compatibilizing agents in the formation of syntactic foams.

There are several reports in the literature indicating that particle size, filler content, particle-matrix interaction, dispersion and filler distribution have major influences on the properties of polymer composites filled with hollow glass microspheres²³23 Zhu BL, Zheng H, Wang J, Ma J, Wu J, Wu R. Tailoring of thermal and dielectric properties of LDPE-matrix composites by the volume fraction, density, and surface modification of hollow glass microsphere filler. Composites Part B: Engineering. 2014;58:91-102.

24 Gogoi R, Manik G, Arun B. High specific strength hybrid polypropylene composites using carbon fibre and hollow glass microspheres: Development, characterization and comparison with empirical models. Composites Part B: Engineering. 2019;173:106875.^-²⁵25 Chen S, Qin Y, Song J, Wang B. The effect of hollow glass microspheres on the properties of high silica glass fiber fabric/liquid silicone rubber composite sheet. Polimery. 2018;63(3):178-184.. Considering that processing conditions have major effects on particle dispersion and distribution, in this paper, the effects of the processing conditions using single screw and twin screw extruder on the morphology and mechanical properties of the syntactic foams made from HDPE/HGM with maleic anhydride grafted PE (PE-g-MA) as a compatibilizer, are investigated.

2. Methodology

2.1 Materials

The polymer matrix used in this paper was HDPE (SHA7260 grade, Braskem), and density was the control property (0.955g.cm^-3). The hollow glass microsphere (iM16K) (3M^TM) used as an inorganic filler and had the following specifications: density of 0.46g.cm^-3, average diameter of 20 µm and crushing strength of 16000 Psi. The polar compatibilizer employed was maleic anhydride-functionalized polyethylene (PE-g-MA), marketed under the name Orevac^® 18507 (Arkema), with density of 0.954g.cm^-3, melt flow index (190°C/2.16kg) of 5g.10min^-1 and melting point of 128°C. The choice compatibilizer was based on the work of Patankar and Kranov (2009)⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903..

2.2 Processing

The syntactic foams were prepared by two different processing routes: single screw extruder and twin screw extruder. In each process the HGM level varied between 1 and 5% while maintaining PE-g-MA at a constant level (5%), as show in Table 1.

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Table 1
Composite formulation

2.2.1 Single Screw Extruder

The foams were processed in a bench top single screw extruder model AX-16 (AX Plásticos) under the following operating conditions: screw rotation speed of 50 rpm, temperature profile from the feeding zone to the matrix of 140°C to 150°C.

2.2.2 Twin Screw Extruder

The composites were prepared in a modular co-rotating twin screw extruder (NZ, model SJ-20), diameter of 22 mm, L/D = 38, and a shape factor of 1.48 with screw configuration with two kneading block sections of intensive shear. The temperature profile employed from the feeding zone to the matrix was 170°C to 190 °C and screw speed was 300 rpm.

The choice of the processing parameters was determined by the work in the literature with different inorganic loads, allowing comparisons between their effects, and considering the limitations imposed by the equipment with respect to feed and screw speed of rotation.

2.3 Production of test specimens

After being processed in the extruders, the composites were pelletized and compression molded in a hydraulic press MH-08-MN (MH Equipamentos Ltda) operating at 180°C with 2 minutes of pre-pressing at 1 ton of applied load, 1 minute without load and then 3 minutes under a load of 3 tons. These conditions were necessary to generate good test specimens for mechanical testing (tensile and impact).

2.4 Characterizations

2.4.1 Morphological analysis - Scanning Electron Microscopy

Scanning electron microscopy of the gold coated fractured surfaces of tensile tested specimens was performed on a Shimadzu SSX-550 apparatus operating in the 6-15 kV range. Adhesion between the polymer matrix and the HGM, as a function of the processing route adopted, was then ascertained.

2.4.2 Mechanical tests

Tensile testing was performed in an EMIC DL 30000 Universal Testing Machine operating at 50mm/min with a load cell of 50 kN, according to ASTM D638 at room temperature. Izod impact tests were performed according to ASTM D256 on a CEAST Resil 5.5 equipment, operating with a 2.75J hammer. The specimens were notched (notch depth = 2.5mm) before impact. All results reported are a mean of 5 specimens.

3. Results and Discussion

3.1 Morphological analysis

Scanning electron microscopy (SEM) photomicrographs images of the fracture regions of tensile tested specimens before (iM16K) and after processing by the two routes adopted here are shown in Figures 1-3. The aim was to observe the interactions of the syntactic foams constituents and to visualize the damage caused to the filler at the end of each processing and to correlate it with the properties of the systems.

Figure 1
iM16K-type HGM particles

Figure 2
Photomicrographs of single screw extruded systems (SS) with 1 (SS1) and 5% (SS5) HGM.

Figure 3
Photomicrographs of the systems via twin screw extruder (TS)

The photomicrographs show although there were few agglomerations of the microspheres and no complete wettability of the filler by the polymer matrix, HGM adhesion to the matrix (indicated by the blue arrows) were observed for for both SS1 and SS5 systems. Although some of the hollow glass microspheres (HGM) were damaged at some point during processing, in general, a high HGM integrity index was observed for both systems.

The high integrity of the glass microspheres after processing is in agreement to what was observed by BARBOZA and DE PAOLI (2002)²⁶26 Barboza ACRN, Paoli MA. Polipropileno Carregado com Microesferas Ocas de Vidro (Glass BubblesTM): Obtenção de Espuma Sintática. Polímeros. 2002;12(2):130-137. for PP/HGM and by Kumar et al. (2016)²⁷27 Kumar BRB, Doddamani M, Zeltmann SE, Gupta N, Ramesh MR, Ramakrishna S. Processing of cenosphere/HDPE syntactic foams using an industrial scale polymer injection molding machine. Materials and Design. 2016;92:414-423. for HDPE/HGM syntactic foams. The authors attributed this behavior to poor HGM adhesion to the polymer matrix, making the stress to which the foams were subjected during tensile test not to be shared with the spherical structures, resulting in the maintenance of their physical integrity. However, as for the presence of glass sediments (indicated by the red arrows) inside the systems, several authors (BARBOZA and DE PAOLI, 2002; YALCIN et al., 2015)²⁶26 Barboza ACRN, Paoli MA. Polipropileno Carregado com Microesferas Ocas de Vidro (Glass BubblesTM): Obtenção de Espuma Sintática. Polímeros. 2002;12(2):130-137.^,³²32 Yalcin B, Amos SE. Hollow Glass Microspheres in Thermoplastics. In: Yalcin B, Amos SE, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds. 2015;35-105. reported that the processing of the components through the knife mill was the cause of most of the stresses necessary for damaging the structure of microspheres.

Figure 3 shows the photomicrographs of the syntactic foams processed in a co-rotating twin screw extruder, Figures 3a and b correspond to the TS1 system, and Figures 3c and d correspond to the TS5 system.

The photomicrographs of the TS1 and TS5 foams reveal a morphological aspect similar to those of the syntactic foams processed in single screw equipment, but there was higher matrix/filler contact. These aspects range from poor adhesion to the existence of hollow spaces and the presence of damaged microspheres.

As for the presence of damaged microspheres, photomicrographs revealed that the TS1 and TS5 systems showed the most pronounced existence of glass sediments originating from HGMs, increasing the matrix contact surface as reported by Hu et al. (2013)²⁸28 Hu Y, Mei R, An Z, Zhang J. Silicon rubber/hollow glass microsphere composites: Influence of broken hollow glass microsphere on mechanical and thermal insulation property. Composites Science and Technology. 2013;79:64-69.. Such behavior regarding the physical integrity of the microspheres was already expected, since in addition to the pelletizing of the extruded yarn, this processing through screw configuration offers more severity for the shear stresses, which is the region with the highest concentration of kneading elements³³33 Chen P, Zhang J, He J. Increased flow property of polycarbonate by adding hollow glass beads. Polymer Engineering and Science. 2005;45(8):1119-1131..

Regardless of the processing route, the effect of PE-g-MA addition was observed through the improved adhesion of hollow microspheres in the polymer matrix. Similar behavior was observed by ÇELEBİ (2017)²²22 Çelebi H. Thermal Conductivity and Tensile Properties of Hollow Glass Microsphere/Polypropylene Composites. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering. 2017;18(3):746-753. for PP/HGM syntactic foams with the addition of a silane agent. LU et al. (2015)²⁹29 Lu X, Qu J, Huang J. Mechanical, thermal and rheological properties of hollow glass microsphere filled thermoplastic polyurethane composites blended by normal vane extruder. Journal Plastics, Rubber and Composites Macromolecular Engineering. 2015;44(8):306-313. prepared syntactic foams based on polyurethane and HGMs and observed that the interaction between filler and matrix was promoted by hydroxyl groups - OH on the surface of the microsphere and carbonyl groups (C = O)

Many authors have studied the influence of compatibilizers on the adhesion between the polymer matrix and HGM processed under different conditions and have shown that its absence causes poor matrix/HGM adhesion⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903.^,¹⁹19 Liang JZ. Reinforcement and quantitative description of inorganic particulate-filled polymer composites. Composites Part B: Engineering. 2013;51:224-32.^,²¹21 Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures. 2018;202:545-550..

3.2 Mechanical tests

3.2.1 Tensile strength

Figure 4 shows the elastic moduli of the syntactic foams processed by single and twin screw extrusion. The mean values and the respective standard deviations of each system were illustrated according to the filler content with microspheres (1% and 5%), followed by assessment of the performance of foams compared to the matrix.

Figure 4
Elastic modulus x Processing

Results indicate that the processing route affects the mechanical behavior of the syntactic foams. Single screw extrusion led to materials with similar or slightly higher modulus than that of the neat matrix, particularly that with 5% HGM. This behavior can be explained by the restriction of the mobility of the polymer chains at higher HMG contents³⁰30 Doumbia AS, Bourmaud A, Jouannet D, Falher T, Orange F, Retoux R, et al. Hollow microspheres - poly-(propylene) blends: Relationship between microspheres degradation and composite properties. Polymer Degradation and Stability. 2015;114:146-153.

31 Wang T, Chen S, Wang Q, Pei X. Damping analysis of polyurethane/epoxy graft interpenetrating polymer network composites filled with short carbon fiber and micro hollow glass bead. Materials and Design. 2010;31(8):2810-3815.^-³²32 Yalcin B, Amos SE. Hollow Glass Microspheres in Thermoplastics. In: Yalcin B, Amos SE, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds. 2015;35-105.. On the other hand, the foams obtained via a twin screw extruder showed a 20% reduction in the elastic modulus, which can be attributed to the lower integrity of the hollow microspheres during processing in the twin screw extruder. Microspheres breakage leads to the formation of rigid microparticles, with little or no adhesion to the polymer matrix, causing the stress concentration and reduced mechanical performance of the syntactic foams. This behavior is in agreement with the systems morphology observed by SEM.

At lower HGM contents, the propagation of microcracks, generated at during load application, is more difficult. However, at higher HGM contents, crack propagation becomes relatively easy due to the presence of multiple possible paths through adjacently located HGMs²⁴24 Gogoi R, Manik G, Arun B. High specific strength hybrid polypropylene composites using carbon fibre and hollow glass microspheres: Development, characterization and comparison with empirical models. Composites Part B: Engineering. 2019;173:106875.. This representation is illustrated in Figure 5.

Figure 5
Illustration of the mechanism of crack propagation in syntactic foams: (a) Behavior of samples after tensile testing; (b) microspheres poorly adhered to the matrix and (c) microspheres adhered to the matrix.

The higher modulus value for foams processed in the single screw extruder are in agreement with other literature studies, such as in the study in which the authors produced Polybutylene Succinate (PBS)/HGM²2 Li J, Luo X, Lin X. Preparation and characterization of hollow glass microsphere reinforced poly(butylene succinate) composites. Materials and Design. 2013;46:902-909. and HDPE/HGM foams in the presence of a compatibilizer²⁷27 Kumar BRB, Doddamani M, Zeltmann SE, Gupta N, Ramesh MR, Ramakrishna S. Processing of cenosphere/HDPE syntactic foams using an industrial scale polymer injection molding machine. Materials and Design. 2016;92:414-423., which indicated that such processing contributed effectively to the distribution of the filler in the matrix, however, it was inefficient in its dispersion.

Crack propagation along the matrix/HGM interface, is shown in Figure 5 (c). The two components are weakly bound by hydroxyl groups present on the surface of the glass microsphere and the polymer matrix.

Figure 6 illustrates the maximum tensile strengths of syntactic foams obtained by the two different processing routes. Results indicate this property to decrease with HGM addition to HDPE.

Figure 6
Maximum strength x Processing

These figures show that (single screw and twin screw extruder) processings produced systems with a 1% HGM and better performance for LMS than foams containing 5% of microspheres.

The data indicates that the syntactic foams obtained by both single and twin screw extruder, the increased HGM content and consequently the increased glass sediments resulting from the damage to the microspheres due to the processing route did not benefit the behavior regarding the limit of maximum strength. KUMAR et al., (2016)²⁷27 Kumar BRB, Doddamani M, Zeltmann SE, Gupta N, Ramesh MR, Ramakrishna S. Processing of cenosphere/HDPE syntactic foams using an industrial scale polymer injection molding machine. Materials and Design. 2016;92:414-423. observed similar behavior in extruded compatibilized HDPE/HGM foams. Despite their good interface interaction, increased HGM contents led to lower tensile strengths of HDPE/HGM syntactic foams.

Figure 7 shows the strains at break of each system when under investigation. As expected, regardless of the processing route chosen, HGM addition led to syntactic foams with decreased stains at break compared to neat HDPE and this decrease was more severe with higher HGM contents.

Figure 7
Deformation in maximum strength x Processing

Results also indicate that this decrease was more severe for the twin extruded systems as for the single screw extruded samples strain reduction on compared to the matrix was 6.06% and 50.73% for SS1 and SS5, respectively, and for those produced by twin screw extrusion reductions of 25.62% and 42.04% for TS1 and TS5, respectively, were observed. This behavior was expected as rigid fillers do not undergo significant deformations and hinder polymer chain mobility and this decrease is more severe the higher the amount of HGM in the system³3 Bibin J, Nair CPR. Update on Syntactic foams. Shropshire, UK: Smithers Rapra Technology; 2010.^,²⁵25 Chen S, Qin Y, Song J, Wang B. The effect of hollow glass microspheres on the properties of high silica glass fiber fabric/liquid silicone rubber composite sheet. Polimery. 2018;63(3):178-184.. Similar behavior was obtained by DOUMBIA et. al. (2015)³⁰30 Doumbia AS, Bourmaud A, Jouannet D, Falher T, Orange F, Retoux R, et al. Hollow microspheres - poly-(propylene) blends: Relationship between microspheres degradation and composite properties. Polymer Degradation and Stability. 2015;114:146-153. for polypropylene matrix syntactic foams.

The higher reduction in strain at break observed for twin screw extruded samples is attributed to the higher amount of glass sediments arising from the filler damage as seen in the micrographs. The presence of HGM in the syntactic foams reduces the continuous area of the matrix, and the tensile stresses reduce the cross section of the test specimens, which, together with a not very efficient anchorage, leads to foam disruption⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903.^,³⁴34 Gupta N, Nagorny R. Tensile properties of glass microballoon-epoxy resin syntactic foams. Journal of Applied Polymer Science. 2006;102(2):1254-1261.^,³⁵35 Yu W, Qian M, Li H. Elastic and plastic properties of epoxy resin syntactic foams filled with hollow glass microspheres and glass fibers. Journal of Applied Polymer Science. 2016;133(46):1-9..

Summarizing, the tensile properties of twin screw extruded syntactic foams are lower than those of the matrix and, in general, lower than single screw extruded systems, which is probably due to the higher HGM filler breakage. As for the percentage of microspheres, lower contents allowed to obtain more rigid syntactic foams.

3.2.2 Impact strength

Impact strength values for all systems investigated are shown in Figure 8.

Figure 8
Impact strength of Syntactic Foams

Results indicate that an expressive increase in the impact strength, when compared to the HDPE matrix was observed for twin screw extruded systems, especially for the composite with 1% HGM (315.13%). Although an increase in filler content to 5% HGM reduced the amount of energy absorbed from the TS5 composite, impact strength still remained more pronounced (215.35%) than that of the matrix. The higher volumetric fraction of these particles within the matrix due to their low density generated more stress around the particle interface during impact overload and resulted in less impact resistance. Regarding processing via single screw extruder, the performance of the SS1 foam decreased approximately 12.17% compared to the matrix, and that of the SS5 foam was not assessed due to the equipment limitations.

The behavior of the foams shown in Figure 8 revealed that the addition of HGM was more effective in raising the impact strength in the systems processed in the twin screw extruder, since this processing requires more intense shear forces for the blend of the components when compared to the single screw extrusion, which resulted in a better distribution and dispersion of the filler in the matrix.

These behaviors showed that the addition of microspheres was more effective for the increase of impact strength in the processing routes using the twin screw extruder, since these processing require higher shear forces for the blend of the components when compared to the single screw extruder, which results in a better distribution and dispersion of the filler in the matrix. As for the elevation of HGM content, OZKUTLU; DILEK & BAYRAM (2018)²¹21 Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures. 2018;202:545-550. observed in their studies on syntactic PMMA/HGM foams that the higher fraction of volume of microspheres inside the matrix generated higher stresses around the interface of the particles during the impact, resulting in lower strength due to the fragile characteristic of the microspheres. In addition, the higher number of damaged fillers in the foams with higher HGM content boosts the decrease in impact strength because the glass sediments intensify the internal stresses and decrease foam toughness. This same behavior of decrease in impact strength with the addition of microspheres is observed for syntactic foams with polypropylene matrices³⁶36 Das A, Satapathy BK. Structural, thermal, mechanical and dynamic mechanical properties of cenosphere filled polypropylene composites. Materials and Design. 2011;32:1477-1484., high-impact polypropylene³⁰30 Doumbia AS, Bourmaud A, Jouannet D, Falher T, Orange F, Retoux R, et al. Hollow microspheres - poly-(propylene) blends: Relationship between microspheres degradation and composite properties. Polymer Degradation and Stability. 2015;114:146-153., and epoxy resin³⁷37 Wouterson EM, Boey FYC, Hu X, Wong SC. Fracture and Impact Toughness of Syntactic Foam. Journal of Cellular Plastics. 2004;40(2):145-154..

In the study the breaking of particles from the processing possibly increased the energy during the impact due to the larger volume of microsphere fractions and to syntactic foams produced from HDPE and HGM was observed increased toughness with the addition of maleic anhydride to the systems⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903., and this result has also been observed in many composites and polymer blends³⁸38 Wu CJ, Kuo JF, Chen CY, Woo E. Effects of reactive functional groups in the compatibilizer on mechanical properties of compatibilized blends. Journal of Applied Polymer Science. 1994;52(12):1695-1706.. Such behavior is observed in foams even when an increase in toughness compared to the matrix is not achieved, since the foams have advantages in this respect in the presence of a compatibilizing material²¹21 Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures. 2018;202:545-550..

In the study on syntactic HDPE/HGM foams, PATANKAR; DAS & KRANOV (2009)⁹9 Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing. 2009;40(6):897-903. observed increased composite toughness when maleic anhydride was added to the systems, evidencing the elevation of such property for treated foams in comparison with foams without a compatibilizer. In many composites and polymer blends the addition of compatibilizer has denoted the increase of toughness in these materials³⁸38 Wu CJ, Kuo JF, Chen CY, Woo E. Effects of reactive functional groups in the compatibilizer on mechanical properties of compatibilized blends. Journal of Applied Polymer Science. 1994;52(12):1695-1706.. This behavior is observed in syntactic foams even when an increase in toughness compared to the polymer matrix is not achieved, since the foams have advantages in this respect in the presence of a compatibilizing material over those with no treatment²¹21 Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures. 2018;202:545-550..

There are few studies that show an increase in the energy absorbed by syntactic foams during the impact in comparison with the matrix, most of which are related to the use of thermoset resins³⁹39 Wang J, Liang G, He S, Yang L. Curing behavior and mechanical properties of hollow glass microsphere/bisphenol a dicyanate ester composites. Journal of Applied Polymer Science. 2010;118(3):1252-1256.^,⁴⁰40 Gupta G, Satapathy A. Processing, characterization, and erosion wear characteristics of borosilicate glass microspheres filled epoxy composites. Polymer Composites. 2015;36(9):1685-1692.. The literature shows that the increased impact strength is strictly related to the path and the transfer of tension in the crack propagation²2 Li J, Luo X, Lin X. Preparation and characterization of hollow glass microsphere reinforced poly(butylene succinate) composites. Materials and Design. 2013;46:902-909.. The crack originated from the impact stress propagates in the matrix and is prevented from continuing this initial path when it encounters a particle of greater rigidity. At this point the crack splits into other fronts by bending over the spherical surface of filler (crack pinning-bowing mechanism). The tensile intensity in the matrix is reduced by splitting the crack around the microspheres, while the reinforcement phase produces an increase in tensile intensity because the crack fronts store more elastic energy than the original crack. Therefore, more energy is required to continue its propagation, and the tensile intensity increases until fracture at the reinforcement phase, thus continuing to propagate⁴¹41 Kinloch AJ, Maxwell D, Young RJ. Micromechanisms of crack propagation in hybrid-particulate composites. Journal of Materials Science Letters. 1985;4(10):1276-1279.

42 Lee J, Yee AF. Fracture of glass bead/epoxy composites: on micro-mechanical deformations. Polymer. 2000;41(23):8363-8373.

43 Lee J, Yee AF. Inorganic particle toughening I: micro-mechanical deformations in the fracture of glass bead filled epoxies. Polymer. 2001;42(2):577-588.

44 Lee J, Yee AF. Inorganic particle toughening II: toughening mechanisms of glass bead filled epoxies. Polymer. 2001;42(2):589-597.^-⁴⁵45 Shariati M, Farzi GA, Dadrasi A, Amiri M, Meybodi RR. An Experimental Study on Toughening Mechanisms of Fillers in Epoxy/Silica Nanocomposites. International Journal of Nanoscience and Nanotechnology. 2015;11(3):193-199..

This mechanism of crack propagation evidences the importance of distribution and dispersion of filler so that it occurs more efficiently in the increase of foam toughness. In addition, the intensity in the matrix/HGM interaction influences the mechanical performance of impact strength, which is best achieved by using twin screw extruder.

The mechanisms of toughening polymers with energy absorbing mechanisms with solid fillers are: microcracking (small, discontinuous cracks that are formed ahead of the main crack), shear yielding (local regions of plastically deformed matrix ahead of the crack tip near the fillers)⁴⁶46 Kawaguchi T, Pearson RA. The effect of particle-matrix adhesion on the mechanical behavior of glass filled epoxies. Part 2. A study on fracture toughness. Polymer. 2003;44(15):4239-4247., and crack bowing¹¹11 Wouterson EM, Boey FYC, Hu X, Wong SC. Specific properties and fracture toughness of syntactic foam: Effect of foam microstructures. Composites Science and Technology. 2005;65(11-12):1840-1850.^,³⁷37 Wouterson EM, Boey FYC, Hu X, Wong SC. Fracture and Impact Toughness of Syntactic Foam. Journal of Cellular Plastics. 2004;40(2):145-154.^,⁴³43 Lee J, Yee AF. Inorganic particle toughening I: micro-mechanical deformations in the fracture of glass bead filled epoxies. Polymer. 2001;42(2):577-588.. So long as the microballoons remain intact, they would exhibit these same toughening mechanisms¹⁶16 Rutz BH, Berg JC. A review of the feasibility of lightening structural polymeric composites with voids without compromising mechanical properties. Advances in Colloid and Interface Science. 2010;160(1-2):56-75..

4. Conclusions

The morphological analysis by MEV showed a poor adhesion between the matrix and the filler as a consequence of the processing routes used in this study, presenting a low wettability of HGMs by the HDPE. The mechanical results showed a reduction of the elastic modulus, and even the syntactic foams showing the highest values (SS1 and SS5) were not superior to pure matrix. The maximum strength and elongation under maximum strength were reduced for all composites. It was observed that both extrusion processings generated fractured specimens with fragile characteristics. Regarding the impact strength, the composite SS1 showed a decrease of 12.17%, and the processing using a twin screw extruder increased the strength of foams. While the composite TS1 had an increase of 315.13%, TS5 revealed an increase of 215.35%, showing a decrease in such property with the increase of HGM content.

5. Acknowledgements

The authors thanks the financial support of the CAPES and CNPq.

6. References

¹
Stephen E, Beck W. Introduction. In: Stephen E, Yalcin B, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds Oxford, UK: Elsevier; 2015. p. 1-6.
²
Li J, Luo X, Lin X. Preparation and characterization of hollow glass microsphere reinforced poly(butylene succinate) composites. Materials and Design 2013;46:902-909.
³
Bibin J, Nair CPR. Update on Syntactic foams Shropshire, UK: Smithers Rapra Technology; 2010.
⁴
Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics 3rd ed. Indiana: Elsevier; 2014. p. 511-554.
⁵
Mucccio EA. Plastics processing technology 4th ed. USA: ASM International; 1999.
⁶
Fritschel L, inventor; Bridgestone Firestone Inc., assignee. Syntactic foams and their preparation US Patent 3856721. 1973.
⁷
Bardella L, Genna F. On the elastic behaviour of syn-tactic foams. International Journal of Solids and Structures 2001;38:7235-7260.
⁸
Banhart J. Manufacture, characterisation and application of cellular metals and metal foams. Progress in Materials Science 2001;46(6):559-632.
⁹
Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing 2009;40(6):897-903.
¹⁰
Qu YN, Xu J, Su ZG, Ma N, Zhang XY, Xi XQ, et al. Lightweight and high-strength glass foams prepared by a novel green spheres hollowing technique. Ceramics International 2016;42(2):2370-2377.
¹¹
Wouterson EM, Boey FYC, Hu X, Wong SC. Specific properties and fracture toughness of syntactic foam: Effect of foam microstructures. Composites Science and Technology 2005;65(11-12):1840-1850.
¹²
Karthikeyan CS, Sankaran S, Kumar MNJ, Kishore. Processing and compressive strengths of syntactic foams with and without fibrous reinforcements. Journal of Applied Polymer Science 2001;81(2):405-411.
¹³
Cosse RL., Araújo FH., Pinto FANC., de Carvalho LH, de Morais ACL., Barbosa R, Alves TS. Effects of the type of processing on thermal, morphological and acoustic properties of syntactic foams. Composites Part B: Engineering 2019; 173: 106933.
¹⁴
Zhang B, Fan Z, Hu S, Shen Z, Ma H. Mechanical response of the fly ash cenospheres/polyurethane syntactic foams fabricated through infiltration process. Construction and Building Materials 2019;206:552-559.
¹⁵
Koopman M, Chawla K, Carlisle K, Gladysz G. Microstructural failure modes in three-phase glass syntactic foams. Journal of Materials Science 2006;41:4009-4014.
¹⁶
Rutz BH, Berg JC. A review of the feasibility of lightening structural polymeric composites with voids without compromising mechanical properties. Advances in Colloid and Interface Science 2010;160(1-2):56-75.
¹⁷
Nakamura Y., Harada A., Gotoh T., Yokouchi N., Iida T., Effect of silane chain length on the mechanical properties of silane-treated glass beads-filled PVC, Composites Interfaces 2012; 14: 117-130.
¹⁸
Miller A, Berg JC. Predicting adhesion between a crystalline polymer and silane-treated glass surfaces in filled composites. Journal of Adhesion Science and Technology 2002;16(14):1949-1956.
¹⁹
Liang JZ. Reinforcement and quantitative description of inorganic particulate-filled polymer composites. Composites Part B: Engineering 2013;51:224-32.
²⁰
Patankar SN, Kranov YA. Hollow glass microsphere HDPE composites for low energy sustainability. Materials Science and Engineering: A 2010;527(6):1361-1366.
²¹
Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures 2018;202:545-550.
²²
Çelebi H. Thermal Conductivity and Tensile Properties of Hollow Glass Microsphere/Polypropylene Composites. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering 2017;18(3):746-753.
²³
Zhu BL, Zheng H, Wang J, Ma J, Wu J, Wu R. Tailoring of thermal and dielectric properties of LDPE-matrix composites by the volume fraction, density, and surface modification of hollow glass microsphere filler. Composites Part B: Engineering 2014;58:91-102.
²⁴
Gogoi R, Manik G, Arun B. High specific strength hybrid polypropylene composites using carbon fibre and hollow glass microspheres: Development, characterization and comparison with empirical models. Composites Part B: Engineering 2019;173:106875.
²⁵
Chen S, Qin Y, Song J, Wang B. The effect of hollow glass microspheres on the properties of high silica glass fiber fabric/liquid silicone rubber composite sheet. Polimery 2018;63(3):178-184.
²⁶
Barboza ACRN, Paoli MA. Polipropileno Carregado com Microesferas Ocas de Vidro (Glass Bubbles^TM): Obtenção de Espuma Sintática. Polímeros 2002;12(2):130-137.
²⁷
Kumar BRB, Doddamani M, Zeltmann SE, Gupta N, Ramesh MR, Ramakrishna S. Processing of cenosphere/HDPE syntactic foams using an industrial scale polymer injection molding machine. Materials and Design 2016;92:414-423.
²⁸
Hu Y, Mei R, An Z, Zhang J. Silicon rubber/hollow glass microsphere composites: Influence of broken hollow glass microsphere on mechanical and thermal insulation property. Composites Science and Technology 2013;79:64-69.
²⁹
Lu X, Qu J, Huang J. Mechanical, thermal and rheological properties of hollow glass microsphere filled thermoplastic polyurethane composites blended by normal vane extruder. Journal Plastics, Rubber and Composites Macromolecular Engineering 2015;44(8):306-313.
³⁰
Doumbia AS, Bourmaud A, Jouannet D, Falher T, Orange F, Retoux R, et al. Hollow microspheres - poly-(propylene) blends: Relationship between microspheres degradation and composite properties. Polymer Degradation and Stability 2015;114:146-153.
³¹
Wang T, Chen S, Wang Q, Pei X. Damping analysis of polyurethane/epoxy graft interpenetrating polymer network composites filled with short carbon fiber and micro hollow glass bead. Materials and Design 2010;31(8):2810-3815.
³²
Yalcin B, Amos SE. Hollow Glass Microspheres in Thermoplastics. In: Yalcin B, Amos SE, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds 2015;35-105.
³³
Chen P, Zhang J, He J. Increased flow property of polycarbonate by adding hollow glass beads. Polymer Engineering and Science 2005;45(8):1119-1131.
³⁴
Gupta N, Nagorny R. Tensile properties of glass microballoon-epoxy resin syntactic foams. Journal of Applied Polymer Science 2006;102(2):1254-1261.
³⁵
Yu W, Qian M, Li H. Elastic and plastic properties of epoxy resin syntactic foams filled with hollow glass microspheres and glass fibers. Journal of Applied Polymer Science 2016;133(46):1-9.
³⁶
Das A, Satapathy BK. Structural, thermal, mechanical and dynamic mechanical properties of cenosphere filled polypropylene composites. Materials and Design 2011;32:1477-1484.
³⁷
Wouterson EM, Boey FYC, Hu X, Wong SC. Fracture and Impact Toughness of Syntactic Foam. Journal of Cellular Plastics 2004;40(2):145-154.
³⁸
Wu CJ, Kuo JF, Chen CY, Woo E. Effects of reactive functional groups in the compatibilizer on mechanical properties of compatibilized blends. Journal of Applied Polymer Science 1994;52(12):1695-1706.
³⁹
Wang J, Liang G, He S, Yang L. Curing behavior and mechanical properties of hollow glass microsphere/bisphenol a dicyanate ester composites. Journal of Applied Polymer Science 2010;118(3):1252-1256.
⁴⁰
Gupta G, Satapathy A. Processing, characterization, and erosion wear characteristics of borosilicate glass microspheres filled epoxy composites. Polymer Composites 2015;36(9):1685-1692.
⁴¹
Kinloch AJ, Maxwell D, Young RJ. Micromechanisms of crack propagation in hybrid-particulate composites. Journal of Materials Science Letters 1985;4(10):1276-1279.
⁴²
Lee J, Yee AF. Fracture of glass bead/epoxy composites: on micro-mechanical deformations. Polymer 2000;41(23):8363-8373.
⁴³
Lee J, Yee AF. Inorganic particle toughening I: micro-mechanical deformations in the fracture of glass bead filled epoxies. Polymer 2001;42(2):577-588.
⁴⁴
Lee J, Yee AF. Inorganic particle toughening II: toughening mechanisms of glass bead filled epoxies. Polymer 2001;42(2):589-597.
⁴⁵
Shariati M, Farzi GA, Dadrasi A, Amiri M, Meybodi RR. An Experimental Study on Toughening Mechanisms of Fillers in Epoxy/Silica Nanocomposites. International Journal of Nanoscience and Nanotechnology 2015;11(3):193-199.
⁴⁶
Kawaguchi T, Pearson RA. The effect of particle-matrix adhesion on the mechanical behavior of glass filled epoxies. Part 2. A study on fracture toughness. Polymer 2003;44(15):4239-4247.

Publication Dates

Publication in this collection
11 Nov 2019
Date of issue
2019

History

Received
18 Jan 2019
Reviewed
18 July 2019
Accepted
04 Sept 2019

This is an Open Access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] ¹
Stephen E, Beck W. Introduction. In: Stephen E, Yalcin B, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds Oxford, UK: Elsevier; 2015. p. 1-6.

[2] ²
Li J, Luo X, Lin X. Preparation and characterization of hollow glass microsphere reinforced poly(butylene succinate) composites. Materials and Design 2013;46:902-909.

[3] ³
Bibin J, Nair CPR. Update on Syntactic foams Shropshire, UK: Smithers Rapra Technology; 2010.

[4] ⁴
Bibin J, Nair CPR. Syntactic Foams. In: Dodiuk H, Goodman SH, editors. Handbook of Thermoset Plastics 3rd ed. Indiana: Elsevier; 2014. p. 511-554.

[5] ⁵
Mucccio EA. Plastics processing technology 4th ed. USA: ASM International; 1999.

[6] ⁶
Fritschel L, inventor; Bridgestone Firestone Inc., assignee. Syntactic foams and their preparation US Patent 3856721. 1973.

[7] ⁷
Bardella L, Genna F. On the elastic behaviour of syn-tactic foams. International Journal of Solids and Structures 2001;38:7235-7260.

[8] ⁸
Banhart J. Manufacture, characterisation and application of cellular metals and metal foams. Progress in Materials Science 2001;46(6):559-632.

[9] ⁹
Patankar SN, Das A, Kranov YA. Interface engineering via compatibilization in HDPE composite reinforced with sodium borosilicate hollow glass microspheres. Composites Part A: Applied Science and Manufacturing 2009;40(6):897-903.

[10] ¹⁰
Qu YN, Xu J, Su ZG, Ma N, Zhang XY, Xi XQ, et al. Lightweight and high-strength glass foams prepared by a novel green spheres hollowing technique. Ceramics International 2016;42(2):2370-2377.

[11] ¹¹
Wouterson EM, Boey FYC, Hu X, Wong SC. Specific properties and fracture toughness of syntactic foam: Effect of foam microstructures. Composites Science and Technology 2005;65(11-12):1840-1850.

[12] ¹²
Karthikeyan CS, Sankaran S, Kumar MNJ, Kishore. Processing and compressive strengths of syntactic foams with and without fibrous reinforcements. Journal of Applied Polymer Science 2001;81(2):405-411.

[13] ¹³
Cosse RL., Araújo FH., Pinto FANC., de Carvalho LH, de Morais ACL., Barbosa R, Alves TS. Effects of the type of processing on thermal, morphological and acoustic properties of syntactic foams. Composites Part B: Engineering 2019; 173: 106933.

[14] ¹⁴
Zhang B, Fan Z, Hu S, Shen Z, Ma H. Mechanical response of the fly ash cenospheres/polyurethane syntactic foams fabricated through infiltration process. Construction and Building Materials 2019;206:552-559.

[15] ¹⁵
Koopman M, Chawla K, Carlisle K, Gladysz G. Microstructural failure modes in three-phase glass syntactic foams. Journal of Materials Science 2006;41:4009-4014.

[16] ¹⁶
Rutz BH, Berg JC. A review of the feasibility of lightening structural polymeric composites with voids without compromising mechanical properties. Advances in Colloid and Interface Science 2010;160(1-2):56-75.

[17] ¹⁷
Nakamura Y., Harada A., Gotoh T., Yokouchi N., Iida T., Effect of silane chain length on the mechanical properties of silane-treated glass beads-filled PVC, Composites Interfaces 2012; 14: 117-130.

[18] ¹⁸
Miller A, Berg JC. Predicting adhesion between a crystalline polymer and silane-treated glass surfaces in filled composites. Journal of Adhesion Science and Technology 2002;16(14):1949-1956.

[19] ¹⁹
Liang JZ. Reinforcement and quantitative description of inorganic particulate-filled polymer composites. Composites Part B: Engineering 2013;51:224-32.

[20] ²⁰
Patankar SN, Kranov YA. Hollow glass microsphere HDPE composites for low energy sustainability. Materials Science and Engineering: A 2010;527(6):1361-1366.

[21] ²¹
Ozkutlu M, Dilek C, Bayram G. Effects of hollow glass microsphere density and surface modification on the mechanical and thermal properties of poly(methyl methacrylate) syntactic foams. Composite Structures 2018;202:545-550.

[22] ²²
Çelebi H. Thermal Conductivity and Tensile Properties of Hollow Glass Microsphere/Polypropylene Composites. Anadolu University Journal of Science and Technology A - Applied Sciences and Engineering 2017;18(3):746-753.

[23] ²³
Zhu BL, Zheng H, Wang J, Ma J, Wu J, Wu R. Tailoring of thermal and dielectric properties of LDPE-matrix composites by the volume fraction, density, and surface modification of hollow glass microsphere filler. Composites Part B: Engineering 2014;58:91-102.

[24] ²⁴
Gogoi R, Manik G, Arun B. High specific strength hybrid polypropylene composites using carbon fibre and hollow glass microspheres: Development, characterization and comparison with empirical models. Composites Part B: Engineering 2019;173:106875.

[25] ²⁵
Chen S, Qin Y, Song J, Wang B. The effect of hollow glass microspheres on the properties of high silica glass fiber fabric/liquid silicone rubber composite sheet. Polimery 2018;63(3):178-184.

[26] ²⁶
Barboza ACRN, Paoli MA. Polipropileno Carregado com Microesferas Ocas de Vidro (Glass Bubbles^TM): Obtenção de Espuma Sintática. Polímeros 2002;12(2):130-137.

[27] ²⁷
Kumar BRB, Doddamani M, Zeltmann SE, Gupta N, Ramesh MR, Ramakrishna S. Processing of cenosphere/HDPE syntactic foams using an industrial scale polymer injection molding machine. Materials and Design 2016;92:414-423.

[28] ²⁸
Hu Y, Mei R, An Z, Zhang J. Silicon rubber/hollow glass microsphere composites: Influence of broken hollow glass microsphere on mechanical and thermal insulation property. Composites Science and Technology 2013;79:64-69.

[29] ²⁹
Lu X, Qu J, Huang J. Mechanical, thermal and rheological properties of hollow glass microsphere filled thermoplastic polyurethane composites blended by normal vane extruder. Journal Plastics, Rubber and Composites Macromolecular Engineering 2015;44(8):306-313.

[30] ³⁰
Doumbia AS, Bourmaud A, Jouannet D, Falher T, Orange F, Retoux R, et al. Hollow microspheres - poly-(propylene) blends: Relationship between microspheres degradation and composite properties. Polymer Degradation and Stability 2015;114:146-153.

[31] ³¹
Wang T, Chen S, Wang Q, Pei X. Damping analysis of polyurethane/epoxy graft interpenetrating polymer network composites filled with short carbon fiber and micro hollow glass bead. Materials and Design 2010;31(8):2810-3815.

[32] ³²
Yalcin B, Amos SE. Hollow Glass Microspheres in Thermoplastics. In: Yalcin B, Amos SE, editors. Hollow Glass Microspheres for Plastics, Elastomers, and Adhesives Compounds 2015;35-105.

[33] ³³
Chen P, Zhang J, He J. Increased flow property of polycarbonate by adding hollow glass beads. Polymer Engineering and Science 2005;45(8):1119-1131.

[34] ³⁴
Gupta N, Nagorny R. Tensile properties of glass microballoon-epoxy resin syntactic foams. Journal of Applied Polymer Science 2006;102(2):1254-1261.

[35] ³⁵
Yu W, Qian M, Li H. Elastic and plastic properties of epoxy resin syntactic foams filled with hollow glass microspheres and glass fibers. Journal of Applied Polymer Science 2016;133(46):1-9.

[36] ³⁶
Das A, Satapathy BK. Structural, thermal, mechanical and dynamic mechanical properties of cenosphere filled polypropylene composites. Materials and Design 2011;32:1477-1484.

[37] ³⁷
Wouterson EM, Boey FYC, Hu X, Wong SC. Fracture and Impact Toughness of Syntactic Foam. Journal of Cellular Plastics 2004;40(2):145-154.

[38] ³⁸
Wu CJ, Kuo JF, Chen CY, Woo E. Effects of reactive functional groups in the compatibilizer on mechanical properties of compatibilized blends. Journal of Applied Polymer Science 1994;52(12):1695-1706.

[39] ³⁹
Wang J, Liang G, He S, Yang L. Curing behavior and mechanical properties of hollow glass microsphere/bisphenol a dicyanate ester composites. Journal of Applied Polymer Science 2010;118(3):1252-1256.

[40] ⁴⁰
Gupta G, Satapathy A. Processing, characterization, and erosion wear characteristics of borosilicate glass microspheres filled epoxy composites. Polymer Composites 2015;36(9):1685-1692.

[41] ⁴¹
Kinloch AJ, Maxwell D, Young RJ. Micromechanisms of crack propagation in hybrid-particulate composites. Journal of Materials Science Letters 1985;4(10):1276-1279.

[42] ⁴²
Lee J, Yee AF. Fracture of glass bead/epoxy composites: on micro-mechanical deformations. Polymer 2000;41(23):8363-8373.

[43] ⁴³
Lee J, Yee AF. Inorganic particle toughening I: micro-mechanical deformations in the fracture of glass bead filled epoxies. Polymer 2001;42(2):577-588.

[44] ⁴⁴
Lee J, Yee AF. Inorganic particle toughening II: toughening mechanisms of glass bead filled epoxies. Polymer 2001;42(2):589-597.

[45] ⁴⁵
Shariati M, Farzi GA, Dadrasi A, Amiri M, Meybodi RR. An Experimental Study on Toughening Mechanisms of Fillers in Epoxy/Silica Nanocomposites. International Journal of Nanoscience and Nanotechnology 2015;11(3):193-199.

[46] ⁴⁶
Kawaguchi T, Pearson RA. The effect of particle-matrix adhesion on the mechanical behavior of glass filled epoxies. Part 2. A study on fracture toughness. Polymer 2003;44(15):4239-4247.

Brasil