Improvement of the performance of water-sensitive geomaterials using hydrophobic additives. Geo-structures such as road and railway bases suffer from water induced damage because they readily interact with the atmosphere and shallow water tables. Under traffic loading, damage to geo-structures occurs as cracking, rutting and roughness, when the strength and stiffness of the geomaterials are compromised by on-going moisture variations. Substantial cost savings to the community can be made if ef ....Improvement of the performance of water-sensitive geomaterials using hydrophobic additives. Geo-structures such as road and railway bases suffer from water induced damage because they readily interact with the atmosphere and shallow water tables. Under traffic loading, damage to geo-structures occurs as cracking, rutting and roughness, when the strength and stiffness of the geomaterials are compromised by on-going moisture variations. Substantial cost savings to the community can be made if effective methods can be found to minimise such damage. This project proposes to study a novel technique, in which blends of hydrophobic polymer additives are used to increase the stability of geomaterials subjected to varying moisture levels and traffic loading.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101662
Funder
Australian Research Council
Funding Amount
$396,958.00
Summary
Reusable Fire-Resistant Column Rehabilitation with Fibre Reinforced Polymer. The application of fibre reinforced polymer (FRP) composites in structural rehabilitation is sometimes challenged or opposed due to the limitation of its fire resistance. This project aims to solve the fire resistance problem of FRP in column jacketing work using innovative approaches. The proposed scheme will be developed by using advanced materials and mechanical fastening technology. It can ensure structural servicea ....Reusable Fire-Resistant Column Rehabilitation with Fibre Reinforced Polymer. The application of fibre reinforced polymer (FRP) composites in structural rehabilitation is sometimes challenged or opposed due to the limitation of its fire resistance. This project aims to solve the fire resistance problem of FRP in column jacketing work using innovative approaches. The proposed scheme will be developed by using advanced materials and mechanical fastening technology. It can ensure structural serviceability of FRP jackets during a fire. And after the fire, the proposed jacketing scheme is reusable by applying a new layer of epoxy. The project is expected to advance the theory and technologies in structural rehabilitation. It will also provide significant benefits to the construction industry via sustainable construction.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100406
Funder
Australian Research Council
Funding Amount
$429,000.00
Summary
Next generation Floating Structures with High-Performance Composites. Floating structures are facing severe deterioration problem due to steel corrosion. This project proposes to address the deterioration problem by developing prefabricated high-performance fibre-reinforced polymer (FRP)-ultra-high performance cementitious (UHPC) composite elements for future floating structures. FRP-UHPC composite elements have excellent strength-to-weight ratio and improved durability. Basic mechanical propert ....Next generation Floating Structures with High-Performance Composites. Floating structures are facing severe deterioration problem due to steel corrosion. This project proposes to address the deterioration problem by developing prefabricated high-performance fibre-reinforced polymer (FRP)-ultra-high performance cementitious (UHPC) composite elements for future floating structures. FRP-UHPC composite elements have excellent strength-to-weight ratio and improved durability. Basic mechanical properties and durability of FRP-UHPC composites will be investigated. Also, reliable connection device for FRP-UHPC structural units will be proposed and verified. The project is expected to provide durable floating structures with low maintenance cost, leading to a revolution of the current floating structures.Read moreRead less
Development of novel viscoelastic sprayed material for the effective blast resistance of critical and resource infrastructure. This project aims to conduct theoretical, numerical and experimental investigations on the mechanism of surface sprayed viscoelastic materials for blast mitigation of structural members in critical and resource infrastructure. The project design is different from traditional designs and aims to achieve protection with a higher efficiency, in a flexible manner and at a lo ....Development of novel viscoelastic sprayed material for the effective blast resistance of critical and resource infrastructure. This project aims to conduct theoretical, numerical and experimental investigations on the mechanism of surface sprayed viscoelastic materials for blast mitigation of structural members in critical and resource infrastructure. The project design is different from traditional designs and aims to achieve protection with a higher efficiency, in a flexible manner and at a lower cost. Therefore, it is worth exploring systemically the development of design methods which are not yet available. The project outcomes intend to be incorporated into design codes for the purposes of improving the civil infrastructure environment subjected to extreme events.Read moreRead less
Special Research Initiatives - Grant ID: SR0354805
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Research Network for Rehabilitation of Structures Using Advanced Materials and Frontier Technologies. There is an urgent need to rehabilitate existing structures that are considered inadequate in strength and serviceability. Frontier strengthening technologies (such as external post-tensioning and plate bonding) using conventional and advanced materials are being currently developed in Australia by different groups, but as yet not in a coordinated manner. The aim of this network is to bring tog ....Research Network for Rehabilitation of Structures Using Advanced Materials and Frontier Technologies. There is an urgent need to rehabilitate existing structures that are considered inadequate in strength and serviceability. Frontier strengthening technologies (such as external post-tensioning and plate bonding) using conventional and advanced materials are being currently developed in Australia by different groups, but as yet not in a coordinated manner. The aim of this network is to bring together a multi-disciplinary team with complementary strengths to provide an integrated solution for rehabilitation of structures. The core of the network focuses on design tools, linking the various technologies to provide appropriate rehabilitation and understanding of life cycle demands for major infrastructure.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101349
Funder
Australian Research Council
Funding Amount
$390,749.00
Summary
Fibre Reinforced Polymer (FRP)-Confined Concrete-Encased Steel Composite Columns. The infrastructure in Australia and beyond has long suffered from deterioration due to corrosion of steel reinforcement/sections. This project will address this problem by investigating a new form of hybrid columns, namely fibre reinforced polymer confined concrete-encased steel composite columns. The idea of combining a fibre reinforced polymer-confined concrete and a steel section not only makes the column a dura ....Fibre Reinforced Polymer (FRP)-Confined Concrete-Encased Steel Composite Columns. The infrastructure in Australia and beyond has long suffered from deterioration due to corrosion of steel reinforcement/sections. This project will address this problem by investigating a new form of hybrid columns, namely fibre reinforced polymer confined concrete-encased steel composite columns. The idea of combining a fibre reinforced polymer-confined concrete and a steel section not only makes the column a durable and ductile alternative to steel/concrete columns, but also makes them an efficient method for retrofitting or strengthening deteriorated steel columns. This project will study the structural behaviour of fibre reinforced polymer confined concrete-encased steel composite columns, and develop design methods to pave the way towards their wide practical applications. Read moreRead less
Hybrid multiple-tube concrete columns incorporating composite materials. The project aims to investigate the behaviour of and design hybrid multiple-tube concrete columns, a form of column. These columns allow the use of small circular high-strength steel tubes, readily available in the market, to suit the specific needs of construction projects of various scales. In the column, a durable outer tube made of fibre-reinforced polymer (FRP) composites protects steel tubes, and their high yield stre ....Hybrid multiple-tube concrete columns incorporating composite materials. The project aims to investigate the behaviour of and design hybrid multiple-tube concrete columns, a form of column. These columns allow the use of small circular high-strength steel tubes, readily available in the market, to suit the specific needs of construction projects of various scales. In the column, a durable outer tube made of fibre-reinforced polymer (FRP) composites protects steel tubes, and their high yield stress can be fully exploited through section configuration. The new column is expected to enable wider, safer and more economical use of FRP and high-strength steel, and meet demands for resilient civil infrastructure.Read moreRead less
Design of Composites for Exceptional Functional Properties by Maximising the Poisson Effect. This project will establish an effective and efficient computational framework for the topological optimisation of composites whose constituent phases possess significantly different Poisson ratios. In particular, the proposed research will be focused on exploiting the dramatic improvements in functional properties of composites when the Poisson ratio of one of the constituent phases is either negative o ....Design of Composites for Exceptional Functional Properties by Maximising the Poisson Effect. This project will establish an effective and efficient computational framework for the topological optimisation of composites whose constituent phases possess significantly different Poisson ratios. In particular, the proposed research will be focused on exploiting the dramatic improvements in functional properties of composites when the Poisson ratio of one of the constituent phases is either negative or near its incompressibility limit. The expected outcomes will be a new methodology and an advanced engineering design tool that can be used for the development of a new class of composites with exceptional properties. Such new composite systems will have many potential applications, particularly in aerospace, defence and medical industries.Read moreRead less
Design of Novel Metamaterials Considering Large Deformation and Plasticity. The project aims to establish an effective and efficient computational framework for the topological design of novel mechanical metamaterials considering both geometrical and material nonlinearities. This would overcome a formidable bottleneck in practical applications of metamaterials which are mostly based on linear elastic assumptions. The expected outcomes will be a new methodology and an advanced engineering design ....Design of Novel Metamaterials Considering Large Deformation and Plasticity. The project aims to establish an effective and efficient computational framework for the topological design of novel mechanical metamaterials considering both geometrical and material nonlinearities. This would overcome a formidable bottleneck in practical applications of metamaterials which are mostly based on linear elastic assumptions. The expected outcomes will be a new methodology and an advanced engineering design tool that can be used for the development of new classes of metamaterials with exceptional mechanical properties (eg negative compressibility or negative Poisson’s ratio) over a large strain range. Such novel metamaterials would have many important applications, particularly in biomedical and defence industries.Read moreRead less