Your search keyword '"Wang, Qingjun"' showing total 18 results

1. Thermal and mechanical properties of recyclable epoxy asphalt vitrimers

Author

Jing, Fan, Wu, Chengwei, Yang, Haocheng, Li, Chenxuan, Xi, Zhonghua, Cai, Jun, Wang, Qingjun, and Xie, Hongfeng

Published

2024

2. Thermal and bonding properties of epoxy asphalt bond coats

Author

Sun, Yifan, Liu, Ya, Gong, Jie, Han, Xiaocheng, Xi, Zhonghua, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Published

2022

3. Improving toughness of epoxy asphalt binder with reactive epoxidized SBS

Author

Jiang, Yongjia, Zhao, Ruikang, Xi, Zhonghua, Cai, Jun, Yuan, Zuanru, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Published

2021

4. Laboratory performance of recycled polyethylene modified epoxy asphalt binders.

Author

Li, Chenxuan, Gong, Jie, Zhao, Ruikang, Xi, Zhonghua, Wang, Qingjun, and Xie, Hongfeng

Subjects

ASPHALT, GLASS transition temperature, POLYETHYLENE, PHASE separation, EPOXY resins, IMPACT loads

Abstract

This paper deals with the impact of polymer loading on the microstructure, viscosity, thermal properties and mechanical performance of recycled polyethylene (rPE) modified epoxy asphalt binder. With this aim, rPE was used as a modifier to improve the toughness of a hot-mix epoxy asphalt binder. rPE particles were found to be highly swollen by the asphalt. Double phase separation was observed in rPE modified epoxy asphalt binders: asphalts dispersed in the continuous epoxy phase and rPE particles distributed in the discontinuous asphalt phase. The viscosity of epoxy asphalt binders increased with more rPE contents but the allowable construction time for pavement remained long. Results revealed that the thermal stability of epoxy asphalt binders was slightly improved with the addition of rPE. Furthermore, rPE lowered the glass transition temperature and increased the storage modulus at the rubbery state. All rPE modified epoxy asphalt binders performed better damping behaviours. In addition, at low rPE concentrations, the mechanical properties of epoxy asphalt binders were improved while at rPE loading higher than 2%, the results were opposite. [ABSTRACT FROM AUTHOR]

Published

2023

5. Enhancement of Bonding and Mechanical Performance of Epoxy Asphalt Bond Coats with Graphene Nanoplatelets.

Author

Jing, Fan, Wang, Rui, Zhao, Ruikang, Li, Chenxuan, Cai, Jun, Ding, Guowei, Wang, Qingjun, and Xie, Hongfeng

Subjects

NANOPARTICLES, ASPHALT, DYNAMIC mechanical analysis, GLASS transition temperature, CONTACT angle, GRAPHENE

Abstract

Improving bonding and mechanical strengths is important for the application of bond coats used in the construction of steel deck bridges. Graphene nanoplatelets (GNPs) are attractive nanofillers for polymer modification because of their low cost, ultra-high aspect ratio, and extraordinary thermal and mechanical performance. In this paper, GNPs were used to reinforce the epoxy asphalt bond coat (EABC). The morphology, viscosity–time behavior, contact angle, dynamic mechanical properties, and mechanical and bonding strengths of GNP-reinforced EABCs were investigated using laser confocal microscopy, a Brookfield rotational viscometer, a contact angle meter, dynamic mechanical analysis, a universal test machine, and single-lap shear and pull-off adhesion tests. GNP dispersed non-uniformly in the asphalt phase of EABC. The viscosity of the neat EABC was lowered with the inclusion of GNPs and thus the allowable construction time was extended. The existence of GNPs enhances the hydrophobicity of the neat EABC. When adding more than 0.2% GNP, the storage modulus, crosslinking density and glass transition temperatures of both asphalt and epoxy of the neat EABC increased. The mechanical and bonding properties of the neat EABC were greatly enhanced with the incorporation of GNPs. Furthermore, the mechanical and bonding strengths of the modified EABCs increased with the GNP content. GNP-reinforced EABCs can be utilized in the pavement of long-span steel bridges with long durability. [ABSTRACT FROM AUTHOR]

Published

2023

6. Waste Cooking Oil-Modified Epoxy Asphalt Rubber Binders with Improved Compatibility and Extended Allowable Construction Time.

Author

Gong, Jie, Jing, Fan, Zhao, Ruikang, Li, Chenxuan, Cai, Jun, Wang, Qingjun, and Xie, Hongfeng

Subjects

CRUMB rubber, ASPHALT, RUBBER, LASER machining, EPOXY resins, DYNAMIC mechanical analysis, WASTE tires

Abstract

The application of crumb rubber from end-of-life tires and waste cooking oil (WCO) in road pavements is of significant importance from an economic and environmental viewpoint. However, the incorporation of crumb rubber greatly shortens the allowable construction time of epoxy asphalt binders due to the high viscosity of the epoxy asphalt rubber (EAR) binder and poor compatibility between crumb rubber and asphalt binder. To lower the viscosity of asphalt rubber, extend the allowable construction time and improve the compatibility of EAR binder, waste cooking oil (WCO) was introduced. The effect of WCO on the viscosity–time behavior, thermal stability, dynamic modulus, glass transitions, crosslink density, damping ability, compatibility, mechanical properties and phase separation of WCO-modified EAR binders was investigated by using the Brookfield viscometer, thermogravimetric analysis, dynamic mechanical analysis, universal testing machine and laser confocal microscopy. The test results demonstrated that the incorporation of WCO declined the viscosity and extended the allowable construction time of the unmodified EAR binder. The inclusion of WCO improved the compatibility between asphalt and crumb rubber and the damping ability and elongation at the break of the unmodified EAR binder. The presence of WCO had a marginal effect on the thermal stability of the unmodified EAR binder. Confocal microscopy observation revealed that asphalt rubber particles aggregated in the epoxy phase of the unmodified EAR binder. With the inclusion of WCO, co-continuous asphalt rubber particles became more spherical. [ABSTRACT FROM AUTHOR]

Published

2022

7. Graphene Oxide-Modified Epoxy Asphalt Bond Coats with Enhanced Bonding Properties.

Author

Zhang, Junsheng, Wang, Rui, Zhao, Ruikang, Jing, Fan, Li, Chenxuan, Wang, Qingjun, and Xie, Hongfeng

Subjects

ASPHALT, GLASS transition temperature, GRAPHENE, MUNICIPAL bonds, BOND strengths, GRAPHENE oxide, ASPHALT modifiers

Abstract

The bonding strength of the bond coat plays an important role in the composite action between the wearing surface and the deck plate of the orthotropic steel deck system. Poor bonding results in the delamination of the wearing surface from the deck plate. Graphene oxide (GO) possesses outstanding mechanical and thermal properties, as well as impressive multifunctional groups, which makes it an ideal reinforcement candidate for polymer matrices. In this study, graphene oxide was used to improve the bonding strength and toughness of the epoxy asphalt bond coat (EABC). The dispersion, hydrophobicity, viscosity–time behavior, phase-separated morphology, dynamic mechanical properties, pull-off strength, shear strength and mechanical performance of GO-modified EABCs were investigated using various techniques. The inclusion of GO improved the hydrophobicity of the unmodified EABC. The viscosity of the unmodified EABC was lowered with the addition of GO during curing. Moreover, the allowable construction time for the modified EABCs was extended with the GO loading. The incorporation of GO enhanced the stiffness of the unmodified EABC in the glassy and rubbery states. However, graphene oxide lowered the glass transition temperature of the asphalt of the unmodified EABC. Confocal microscopy observations revealed that GO was invisible in both the asphalt and epoxy phases of the EABC. The inclusion of GO improved the bonding strength, particularly at 60 °C, and mechanical properties of the unmodified EABC. [ABSTRACT FROM AUTHOR]

Published

2022

8. Viscosity‐curing time behavior, viscoelastic properties, and phase separation of graphene oxide/epoxy asphalt composites.

Author

Zhao, Ruikang, Jing, Fan, Li, Chenxuan, Wang, Rui, Xi, Zhonghua, Cai, Jun, Wang, Qingjun, and Xie, Hongfeng

Subjects

GRAPHENE oxide, PHASE separation, X-ray scattering, GLASS transitions, CONFOCAL microscopy, ASPHALT

Abstract

Graphene oxide (GO) with 0.2, 0.5, and 1.0 wt% loading was used to modify warm‐mix epoxy asphalt binders (WEABs). The thermal stability, structure of GO, rotational viscosity‐curing time performance, dynamic moduli, glass transitions, damping ability, mechanical performance, and phase‐separated morphology of GO/epoxy asphalt composites were investigated in the laboratory. GO significantly enhanced the thermal stability of the pure WEAB. X‐ray scattering analysis revealed that GO layers were delaminated in the epoxy asphalt binder. GO accelerated the cure reaction of the pure WEAB and thus resulted in higher rotational viscosity of GO/epoxy asphalt composites. Furthermore, the viscosity of the modified WEABs slightly increased in the GO content. GO increased the dynamic moduli and Tgs of both epoxy and asphalt for the pure WEAB. However, the damping ability of GO/epoxy asphalt composites was similar to that of the pure WEAB. Confocal microscopy observations revealed that GO was dispersed in both asphalt and epoxy phases of the phase‐separated WEAB. The asphalt domains in the continuous epoxy phase became more spherical and uniform with the existence of GO. Moreover, the dispersion of epoxy in the discontinuous asphalt phase became more evident. The mechanical properties of the pure WEAB were greatly improved with the addition of GO. The tensile toughness and strength of the pure WEAB increased by 31% and 33%, respectively, with the addition of 0.2 wt% GO. [ABSTRACT FROM AUTHOR]

Published

2022

9. Performance of epoxy asphalt binder containing warm-mix asphalt additive.

Author

Gong, Jie, Liu, Ya, Jiang, Yongjia, Wang, Qingjun, Xi, Zhonghua, Cai, Jun, and Xie, Hongfeng

Subjects

EPOXY resins, GLASS transition temperature, ASPHALT modifiers, CRYSTAL structure, BRIDGE floors, PHASE separation, ASPHALT

Abstract

Sasobit has been widely applied as warm-mix asphalt (WMA) additive in an environment friendly and energy saving pavement construction. Epoxy asphalt (EA) has been extensively used on the pavement of steel bridge decks. In the present paper, Sasobit was introduced into warm-mix epoxy asphalt binder (WEAB) to prepare Sasobit modified WEAB. The effect of Sasobit on the viscosity, thermal, damping and mechanical properties and morphology of the neat WEAB were investigated using various characterisation techniques. Sasobit significantly lowered the viscosity of the neat WEAB and prolonged the operational lifetime for mixture pavement. Sasobit lowered the glass transition temperature of the neat WEAB. Sasobit slightly decreases the damping properties and thermal stability of the neat WEAB. However, Sasobit increased the tensile strength of the neat WEAB. The crystalline network structures of Sasobit formed in asphalts were clearly observed. The lamellar crystalline structure of Sasobit turned to gel-like structure in curly ribbon shape with an increase of the WMA additive contents. Reaction-induced phase separation occurred in the neat WEAB and Sasobit modified WEABs. No crystalline network structures of Sasobit were observed in the dispersed asphalt phase of the modified WEABs. Sasobit decreased the size of asphalt particles in the continuous epoxy phase. [ABSTRACT FROM AUTHOR]

Published

2021

10. A critical review on performance and phase separation of thermosetting epoxy asphalt binders and bond coats.

Author

Xie, Hongfeng, Li, Chenxuan, and Wang, Qingjun

Subjects

*PHASE separation, *ASPHALT, *EPOXY resins, *EPOXY coatings, *DYNAMIC mechanical analysis, *THERMOSETTING polymers, *HIGH resolution imaging

Abstract

• Performance of epoxy asphalt binders and bond coats during and after curing is reviewed. • Phase separation evolution and final phase-separated morphology of epoxy asphatls are discussed. • The effect of additives on the properties and phase separation of epoxy asphalts is addressed. • Difference between thermoplastic and thermosetting polymer modified asphalts is compared. • The future outlooks of epoxy asphalts is highlighted. Epoxy asphalt is a unique representative of thermosetting polymer modified asphalt, which has been widely used in the construction of orthotropic steel deck bridges. This paper reviewed the performance and phase separation of epoxy asphalt binders and bond coats. To well understand the characteristics of the main components of epoxy asphalts, epoxy resin and asphalt were introduced. The history and classification of epoxy asphalt were described. The importance of viscosity-curing time behavior for controlling the allowable construction time of epoxy asphalt mixtures was discussed due to the reactive nature of epoxy asphalt binders. The factors that affect the mechanical and bonding properties and thermal stability of epoxy asphalt were analyzed. Cure behaviors of epoxy asphalts characterized by different models of differential scanning calorimetry (DSC) were compared. The relationship between dynamic shear rheometry (DSR) and dynamic mechanical analysis (DMA) for studying the viscoelastic properties of epoxy asphalt was interpreted. The two glass transitions, damping properties and Cole-Cole plots of epoxy asphalt obtained by DMA were reviewed. Although scanning electron microscopy (SEM) and fluorescence microscopy (FM) can be used to observe the phase-separated microstructures of epoxy asphalts to some extent, there were still some disadvantages, such as the inability for observation of phase separation evolution, difficulty in sample preparation and low contrast and resolution. The principle of laser scanning confocal microscopy (LSCM) with high image resolution and contrast was introduced. The phase separation mechanism of epoxy asphalt and polymer modified epoxy asphalts was compared. Influence of phase-separated morphology on the mechanical properties of cured epoxy asphalts and polymer modified epoxy asphalts was analyzed. [ABSTRACT FROM AUTHOR]

Published

2022

11. Halogen-free flame retarded cold-mix epoxy asphalt binders: Rheological, thermal and mechanical characterization.

Author

Chen, Ru, Gong, Jie, Jiang, Yongjia, Wang, Qingjun, Xi, Zhonghua, and Xie, Hongfeng

Subjects

*HALOGENS, *EPOXY resins, *ASPHALT, *BINDING agents, *RHEOLOGY, *THERMOPHYSICAL properties, *MECHANICAL behavior of materials

Abstract

Highlights • Halogen-free flame retarded cold-mix epoxy asphalt binder (CEAB) has been developed. • The flame retardancy of the neat CEAB is significantly increased by halogen-free flame retardant. • The addition of halogen-free flame retardants improves the glass transition temperature, thermal stability and tensile strength of the neat CEAB. Abstract Fire safety of asphalt mixtures in highway tunnels has become a problem of great concerns since asphalt and polymer modified asphalt binders are quite flammable and tend to release poisonous gases and smoke while burning. Therefore, flame retardants are incorporated into asphalt binder to improve the fire retardancy of asphalt mixtures. In this paper, aluminum trihydroxide (ATH) and zinc borate (ZB) were used as halogen-free flame retardants to prepare flame retarded cold-mix epoxy asphalt binders (CEABs). The addition of halogen-free flame retardants increased flame retardancy of the neat CEAB. In addition, ATH-ZB retarded CEAB had higher limited oxygen index (LOI) than single ATH and ZB retarded CEABs at the same content. The presence of halogen-free flame retardants increased the viscosity of the neat CEAB. The viscosity of ATH/ZB retarded CEAB was lower than that of ATH retarded CEAB at a specific content. The incorporation of halogen-free flame retardants enhanced the glass transition temperature of the neat CEAB. Thermal stability of the neat CEAB was improved by the halogen-free flame retardants. ATH/ZB retarded CEAB had better thermal stability than ATH retarded CEAB at the same content. The addition of halogen-free flame retardants increased the tensile strength of the neat CEAB. Uniform dispersion of halogen-free flame retardants in CEABs was observed. [ABSTRACT FROM AUTHOR]

Published

2018

12. Influence of oligomer content on viscosity and dynamic mechanical properties of epoxy asphalt binders.

Author

Zhao, Ruikang, Jing, Fan, Wang, Rui, Cai, Jun, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*DYNAMIC viscosity, *EPOXY resins, *ASPHALT, *GLASS transition temperature, *DYNAMIC mechanical analysis, *TENSILE strength

Abstract

• Epoxy asphalt binders with three different epoxy oligomer contents have been developed. • Viscosity of epoxy asphalt binders decreases in the oligomer content. • Allowable construction time of epoxy asphalt binders increased in the oligomer content. • Glass transition temperatures of both epoxy and asphalt increases in the oligomer content. • The damping ability and tensile strength of epoxy asphalt binders increase in the oligomer content. The impact of oligomer content on the viscosity, dynamic mechanical properties and mechanical behaviors of hot-mix epoxy asphalt binders was investigated by Brookfield viscometer, dynamic mechanical analysis and universal testing machine. The viscosity of epoxy asphalt binders during curing decreased in the oligomer content. However, the allowable construction time increased with the oligomer content. The storage modulus of epoxy asphalt binders at the glassy stage decreased in the oligomer content, whereas an opposite trend appeared at the rubbery stage. Epoxy asphalt binders exhibited two glass transition temperatures (T g s) for both epoxy resin and asphalt, and increased in the epoxy oligomer content. The T g of epoxy of epoxy asphalt binder increased from 30.9 to 42.4 °C when the mass fraction of oligomer increased from 23.5 % to 25.5 %. The damping properties and tensile strength of epoxy asphalt binders increased in the oligomer content, while the elongation at break and toughness showed a contrary trend. The tensile strength of epoxy asphalt binder with 23.5 % oligomer was only 0.89 MPa, which was much lower than the specification required. [ABSTRACT FROM AUTHOR]

Published

2022

13. Microstructure and performance of epoxy asphalt binders modified by core-shell rubbers containing different core polymers.

Author

Su, Wufeng, Zhao, Ruikang, Wang, Rui, Xi, Zhonghua, Cai, Jun, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*ASPHALT, *DYNAMIC mechanical analysis, *GLASS transition temperature, *RUBBER, *POLYMERS, *MECHANICAL ability, *SWELLING of materials

Abstract

[Display omitted] • Core-shell rubbers (CSRs) with two core polymers have been used to toughen epoxy asphalt (EA). • 2 wt% CSR with polybutadiene (PB) core alters the phase separation mechanism of EA. • Both swollen polymer and asphalt particles form in the continuous epoxy phase of EA. • The area fraction of swollen PB particles is higher that of swollen SB particles. • EA modified by CSR with PB core exhibits higher damping and mechanical properties. Core-shell rubber (CSR) is a good candidate for toughening epoxy asphalt binders. However, the knowledge of the effect of the core polymer on the performance of CSR modified hot-mix epoxy asphalt binder (HEAB) is not completed and systematic yet. In this paper, CSR modified HEABs were prepared by the incorporation of 2 wt% CSR particles with different core polymers, which were in turn subjected to viscous measurements, confocal microscopy, thermogravimetric analysis, dynamic mechanical analysis and tensile tests. The results revealed that the viscosity of CSR with styrene-butadiene copolymer (SB) core (CSR SB) modified HEAB is higher than that of CSR with polybutadiene (PB) core (CSR PB) modified HEAB during curing. The shell destruction of CSR particles resulted in the swelling of the core polymers and dispersion of swollen core polymer particles in the epoxy phase in the micron scale along with asphalt particles. The phase separation of CSR PB modified HEAB occurred in the spinodal decomposition mode, which was different from the nucleation and growth mechanism of the neat and CSR SB modified HEABs. The area fraction of swollen PB particles in the CSR modified HEAB was greater than that of swollen SB particles. The core polymer had a negligible effect on the thermal stability of CSR modified HEABs. The glass transition temperatures of epoxy and asphalt, damping ability and mechanical properties of the neat HEAB were increased with the addition of CSR particles. Especially, CSR PB modified HEAB had higher tensile strength and toughness than CSR SB modified HEAB. With 2 wt% CSR PB particles being adding, the tensile strength, elongation at break and toughness of the neat HEAB were increased by 53%, 42% and 110%, respectively. [ABSTRACT FROM AUTHOR]

Published

2021

14. Development of eco-friendly fire-retarded warm-mix epoxy asphalt binders using reactive polymeric flame retardants for road tunnel pavements.

Author

Chen, Ru, Zhao, Ruikang, Liu, Ya, Xi, Zhonghua, Cai, Jun, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*FIREPROOFING agents, *FIRE resistant polymers, *TUNNELS, *EPOXY resins, *ASPHALT, *GLASS transition temperature, *PAVEMENTS

Abstract

[Display omitted] • Eco-friendly fire-retarded warm-mix epoxy asphalt binders (WEABs) have been developed. • RPFR of significantly improved the fire retardancy of the pure WEAB. • RPFR hinders WEAB's cure reaction and extends the allowable construction time of WEAB mixtures. • RPFR improves the glass transition temperature and thermal stability of the pure WEAB. • Double phase separation forms in RPFR modified WEABs. Epoxy asphalt binder is flammable and plenty of fumes are produced during its high-temperature pavements in tunnels. To improve fire retardancy and reduce asphalt fumes, eco-friendly flame-retarded warm-mix epoxy asphalt binders (WEABs) for road tunnel pavements were developed by incorporation of reactive polymeric flame retardant (RPFR), which was composed of a reactive polymeric brominated epoxy oligomer (BEO) and antimony oxide. The influence of RPRF on flame retardancy, rotational viscosity, microstructures, thermal properties and mechanical performance of the pure WEAB was investigated using various techniques: oxygen index instrument, Brookfield viscometer, confocal microscope, differential scanning calorimeter, thermogravimetric analyzer and universal testing machine. The presence of RPFR significantly improved the limited oxygen index (LOI) of the pure WEAB. The LOI of RPFR modified WEABs increased in the flame retardant loading. The reaction of epoxide groups of RPFR with the curing agents of epoxy asphalt reduced the viscosity of the pure WEAB and extended the allowable construction time of the WEAB mixture. The inclusion of RPFR increased the glass transition temperature (T g) of the pure WEAB. For modified WEABs, the T g increased in the RPFR loading. RPFR reacted into the epoxy asphalt backbone through the reaction between epoxy groups and curing agents. The incorporation of RPFR improved the thermal stability of the pure WEAB. The addition of 8 wt% RPFR increased the tensile strength of the pure WEAB, while the inclusion of RPFR slightly decreased the break elongation of the pure WEAB. Double phase separation occurred in RPFR modified WEAB: the main phase separation included the continuous epoxy phase and the discontinuous asphalt domains, in which the secondary phase separation formed with asphalt as the continuous phase and spherical BEO domains as the discontinuous phase. The particle size of BEO domains decreased with the increase of the RPFR loading. [ABSTRACT FROM AUTHOR]

Published

2021

15. Laboratory investigation on the microstructure and performance of SBS modified epoxy asphalt binder.

Author

Zhang, Jing, Su, Wufeng, Liu, Ya, Gong, Jie, Xi, Zhonghua, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*ASPHALT modifiers, *ASPHALT, *GLASS transition temperature, *EPOXY resins, *PHASE separation, *MICROSTRUCTURE

Abstract

• Phase separation of ESBA disrupts the original dispersion of SBS in the asphalt. • The size of SBS domains in ESBAs increases in the SBS loading. • ESBA's viscosity increases in the SBS loading. • The thermal stability of ESBAs enhances with the increase of SBS loading. • The neat EA's elongation at break increases by 56% with the addition of 3 wt% SBS. Both styrene–butadiene-styrene copolymer (SBS) and epoxy resin have been widely applied in the asphalt modification. The influence of SBS concentration on the morphology, viscosity, thermal stability, glass transition temperature (T g), damping performance and mechanical behaviors of the neat EA binder was studied. Double phase separation occurred in the epoxy SBS modified asphalt (ESBA): main phase separation between epoxy and the SBS modified asphalt (SBA) and secondary phase separation between asphalt and SBS. The occurrence of phase separation in the ESBA disrupted the original dispersion of SBS particles in SBA and resulted in the redistribution of SBS in the form of smaller spherical particles. The inclusion of SBS increased the viscosity of the neat EA. Furthermore, the viscosity of ESBAs increased with the SBS content. ESBAs had as long as 150-min construction time for the mixture pavement. The presence of SBS improved the thermostability of the neat EA. In terms of ESBAs, the thermostability increased with the SBS content. The addition of SBS lowered the T g of the neat EA when the SBS content was lower than 4 wt%. The T g of ESBAs increased with the SBS content. The incorporation of SBS significantly enhanced the damping behaviors of the neat EA. The tensile strength of the neat EA was improved with the addition of 2 wt% SBS. The inclusion of SBS improved the elongation at break and the toughness of the neat EA when the SBS loading was greater than 1 wt%. [ABSTRACT FROM AUTHOR]

Published

2021

16. Toughening epoxy asphalt binder using core-shell rubber nanoparticles.

Author

Su, Wufeng, Han, Xiaocheng, Gong, Jie, Xi, Zhonghua, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*GLASS transition temperature, *EPOXY resins, *ASPHALT, *NANOPARTICLES, *DISCONTINUOUS precipitation

Abstract

• Core-shell rubber (CSR) nanoparticle toughened epoxy asphalt (EA) has been developed. • The toughness of the pure EA increases by 2-fold with only addition of 1 wt% CSR. • The shell of CSR is broken and the core of CSR swells in the EA. • Newly micro-scale CSR phase uniformly disperses in the epoxy phase of the EA. • CSR nanoparticles alters the mechanism of phase separation of the pure EA. Core-shell rubber (CSR) has been widely applied in the improvement of the toughness for the brittle epoxy resin. In this study, an epoxy asphalt (EA) binder has been toughened by the inclusion of CSR nanoparticles with approximately 100–200 nm in diameter. The incorporation of CSR nanoparticles significantly increased the viscosity of the pure EA during curing. Even with 5 wt% CSR, the EA blend exhibited extremely long operational lifetime (more than 2.5 h) for mixture pavements. The glassy shell of CSR nanoparticles was broken and the rubbery core of CSR nanoparticles swelled in the EA. New micro-scale CSR domains formed and uniformly dispersed in the epoxy phase of the cured EA. The inclusion of CSR nanoparticles altered the phase separation mechanism of the pure EA. The sea-island morphology of the pure EA took place through the nucleation and growth (NG) mechanism, while co-continuous microstructures in the EA blends with 3 wt% and 5 wt% CSR formed through the spinodal decomposition (SD) mechanism. Both sea-island and co-continuous microstructures via combined the NG and SD mechanisms were observed in the EA blend containing 1 wt% CSR. The glass transition temperature and thermal stability of the pure EA was improved by the inclusion of higher CSR loadings. The incorporation of CSR greatly enhanced the mechanical properties of the pure EA. In the case of 1 wt% CSR inclusion, 29% increase in the tensile strength, 60% improvement in the elongation at break and 2-fold increment in the toughness were obtained. [ABSTRACT FROM AUTHOR]

Published

2020

17. Impact of waste cooking oil on the viscosity, microstructure and mechanical performance of warm-mix epoxy asphalt binder.

Author

Li, Chenxuan, Han, Xiaocheng, Gong, Jie, Su, Wufeng, Xi, Zhonghua, Zhang, Junsheng, Wang, Qingjun, and Xie, Hongfeng

Subjects

*PETROLEUM waste, *VISCOSITY, *ASPHALT, *EPOXY resins, *MICROSTRUCTURE

Abstract

• Waste cooking oil (WCO) modified epoxy asphalt binder (EAB) has been developed. • WCO lowers the viscosity and thus extends the construction time of the neat EAB. • Phase inversion in WEAB occurs when 6 wt% WCO is added. • WCO improves the low-temperature performance of the neat EAB. • WCO enhances the damping properties and thermal stability of the neat EAB. Waste cooking oil (WCO) was used as a warm mix asphalt (WMA) additive to modify warm-mix asphalt binder (WEAB) with the expectation of lowering the viscosity and prolonging the construction time of the binder. The viscosity, phase separation, viscoelasticity, thermostability and mechanical properties of WCO modified WEABs were studied and compared with the neat WEAB. WCO significantly reduced the WEAB's viscosity and extended the construction time of the neat WEAB. Moreover, the reducing and prolonging effects increased with the WCO content. Phase-inverted microstructure and secondary phase separation formed in the modified WEAB with 6 wt% WCO. The inclusion of WCO improved the low-temperature performance of the neat WEAB. The damping behavior and thermostability of the neat WEAB were improved with the inclusion of WCO. The presence of WCO increased the elongation at break of the neat WEAB when the waste oil content was lower than 4 wt%. [ABSTRACT FROM AUTHOR]

Published

2020

18. Laboratory investigation of epoxy asphalt binder modified by brominated SBS.

Author

Jiang, Yongjia, Han, Xiaocheng, Gong, Jie, Xi, Zhonghua, Cai, Jun, Wang, Qingjun, Ding, Guowei, and Xie, Hongfeng

Subjects

*POLYMER networks, *EPOXY resins, *NUCLEOPHILIC substitution reactions, *GLASS transition temperature, *ASPHALT, *FLAMMABILITY, *FORMYLATION, *POLYMERSOMES

Abstract

• Brominated SBS (BrSBS) modified epoxy asphalt (EBrSA) binder has been developed. • The nucleophilic substitution reaction occurs between BrSBS and amine curing agent. • Phase inversion takes place in the EBrSAs with higher BrSBS contents. • The flame retardancy of the neat HEAB is significantly improved by BrSBS. • BrSBS greatly increases the glass transition temperature of the neat HEAB. Brominated styrene–butadienestyrene triblock copolymer (BrSBS) is a novel polymeric flame retardant (PolyFR), which is eco-friendly due to its huge molecule weight. In this paper, BrSBS was added into an epoxy asphalt binder (EAB) to enhance the flame resistance of EAB. The microstructure, viscosity, fire resistance, thermal stability, dynamic mechanical behaviors and mechanical properties of BrSBS modified EABs (EBrSAs) were studied. Double phase separation occurred in EBrSAs. BrSBS modified asphalt (BrSA)-rich phase co-continuously dispersed in the continuous epoxy matrix when BrSBS content was lower. However, phase-inverted morphology appeared when the BrSBS content was higher. In other words, the epoxy-rich phase dispersed in the continuous BrSA-rich phase. The amine curing agent reacted with BrSBS through a bimolecular nucleophilic substitution (S N 2) mechanism, resulting in the formation of epoxy/BrSBS interpenetrating polymer networks (IPNs). The incorporation of BrSBS greatly increased the viscosity of the neat EAB due to the nucleophilic substitution reaction between BrSBS and amine curing agent. BrSBS with lower loading significantly improved the flame retardancy of the neat EAB. BrSBS lowered the thermal stability, mechanical and damping behaviors of the neat EAB. However, the glass transition temperature (T g) of the neat EAB was notably enhanced with the inclusion of BrSBS. [ABSTRACT FROM AUTHOR]

Published

2019