Smart Concrete and Infrastructure
Concrete
Concrete is the most common building material worldwide and is utilized in almost all our infrastructure. However, concrete degradation jeopardizes its serviceability and dependability in the long run. Many times, concrete even fails early due to accelerated degradation.
Concrete failure is primarily caused by a combination of factors, including poor material quality, freeze-thaw cycles, stress from excessive loads or environmental factors, the lack of improved design and situation assessment techniques, as well as the lack of prompt preservation or maintenance.
Exciting breakthroughs in nanotechnology and bio-concrete have recently emerged, offering innovative solutions to these age-old problems with concrete. These advancements unlock a world of potential, particularly in the realm of self-sensing and self-healing capabilities, revolutionizing the way we perceive and utilize concrete.
Ordinary concrete, while versatile and widely used, lacks the inherent ability to adapt, self-heal, or respond to external stimuli like intelligent materials. This limitation has long been a challenge for engineers and architects seeking sustainable and resilient solutions for modern infrastructure.
However, when ordinary concrete is modified to incorporate these cutting-edge properties, it transforms into an intelligent material, capable of sensing and responding to changing environmental and loading conditions. This adaptability enables it to adjust various operating parameters throughout its service life, ensuring optimized performance and durability in the face of evolving demands.
Smart Concrete
Smart concrete is an advanced construction material that combines traditional concrete with innovative properties, enabling it to adapt, self-heal, and respond to external stimuli. By incorporating elements such as embedded sensors, nanotechnology, and specialized additives, smart concrete offers enhanced durability, resilience, and sustainability compared to its conventional counterpart. Widely used in modern infrastructure projects, this intelligent material can monitor its own health, detect structural issues early on, and even repair itself when damaged, ultimately leading to more efficient and cost-effective construction and maintenance processes.
For instance, a novel method of keeping track of the condition of structures made of reinforced concrete is made possible by smart concrete technology. By adding a little amount of short carbon fiber to conventional concrete, it alters the concrete’s electrical resistance in reaction to strain or stress. As a result, when concrete is stretched or deformed, the contact between the cement and fiber matrix changes, changing the volume electrical resistivity of the concrete. The strain is then estimated by measuring the electrical resistance. Particularly after an earthquake, smart concrete is utilized to evaluate the internal condition of structures since it may find incredibly minute structural flaws.
Smart concrete can be developed to optimize their strength, ease of maintenance, lifespan, and other structural functions in contrast to ordinary concrete; lowering life-cycle costs, resource consumption, and associated environmental effects. All of these useful properties contribute to creating a strong material base for creating sustainable built environments and smart cities.
Smart concrete is essential for creating resilient and intelligent infrastructure, as it possesses unique features and functionalities that distinguish it from traditional composite concrete mixtures. These include self-sensing, self-cleaning, self-healing, energy harvesting and storage, electromagnetic shielding, and hydrophobic properties. By responding to external stimuli such as humidity, deformation, stress, and temperature, intelligent concrete enhances the overall resilience of the infrastructure it supports.
The market for smart buildings is expected to expand, which will in turn hasten the use of smart concrete.
Types of Smart Concrete
Self-sensing, self-adjusting, self-healing, and other types of smart concrete fall within the category of smart materials, which is very broad.
Self-sensing Concrete
Self-sensing concrete is an advanced form of smart concrete that has the ability to detect internal tension, strain, and damage. Inherently smart concrete is another name for it. Other names include self-monitoring concrete, pressure-sensitive concrete, piezoresistive concrete and others.
Self-sensing concrete is a subset of smart concrete, which was first postulated and has undergone extensive and rigorous research. Self-sensing concrete primarily has great mechanical strength and durability, a long service life, and is simple to install and maintain. Self-sensing concrete finds widespread use in civil infrastructures like high-rise buildings, highways, bridges, runways for airports, continuous slab-type sleepers for high-speed trains, dams, and nuclear power plants. It has particular promise for use in structural health monitoring, traffic detection, and border/military security.
This would be useful for a variety of purposes, including ensuring structural safety and reliability, extending the life of buildings, enhancing traffic efficiency and safety directing structural as well as traffic designs, lowering resource and consumption of energy, etc. For ensuring long-term sustainability in concrete materials and structures, self-sensing concrete is a “smart” option. It will bring about a profound shift in the use of traditional concrete materials, that should be good for the economy, society, and environment.
Self-adjusting Concrete
Self-adjusting concrete can change its internal pore structures and functional characteristics in reaction to external factors such as heat capacity, hydration and moisture content process. Concrete that adapts to variations in moisture, concrete that adjusts to changes in hydration heat, and thermal parameter self-adjusting concrete are the three main varieties. Self-adjusting concrete can improve habitation comfort by reducing temperature cracks caused by the heat of cement hydration and concrete spalling caused by high temperatures.
Self-healing Concrete
Concrete that has the potential to mend cracks on its own, autonomously, is said to have self-healing properties. It not only fills up the cracks but also partially or completely restores the structural elements’ mechanical qualities. Self-repairing concrete is another name for this type of concrete.
Contrary to other building materials, concrete has limited tensile strength, which causes surface cracks to appear often. Because they allow the movement of liquids and gases that could contain hazardous substances, these gaps degrade the concrete’s durability. The reinforcement steel bars will be vulnerable to assault if microcracks deepen and spread to the reinforcement, in addition to the concrete itself.
Smart Infrastructure
Smart infrastructure leverages advanced technology to create safe and comfortable environments while promoting efficient and economical resource utilization. Designed to accommodate both current and emerging technologies, smart infrastructures may incorporate building management systems (BMS), artificial intelligence (AI), virtual reality (VR), augmented reality (AR), and Internet of Things (IoT) sensors. These technologies and processes work together in smart buildings to optimize and enhance overall performance.
Smart Construction Materials
Revolutionizing the construction industry, smart building materials—also known as intelligent materials—possess the remarkable ability to adapt in response to alterations in their environment or their own state. These materials can detect and react to various stimuli, such as mechanical stress, strain, electrical and magnetic fields, temperature fluctuations, light, moisture, and pH levels.
Owing to their unique characteristics, smart materials have become indispensable in numerous technical and scientific fields. In civil engineering projects, they contribute to enhanced structural performance, increased comfort, and reduced energy consumption, paving the way for a more sustainable and efficient future in construction.
Types of Smart Construction Materials
Smart Concrete
Smart concrete, which is made of concrete and carbon fibers, can detect even the smallest structural defects or fissures. Smart concrete has greater potential and increased strength compared to ordinary concrete.
Electrochromic Materials
Electrochromic materials, a prominent category of smart materials, exhibit the ability to change their optical properties, such as color or transparency, in response to an applied electric voltage. This reversible and controllable process enables these materials to dynamically adapt to their surroundings, offering significant benefits in energy efficiency and user comfort. Widely used in applications like smart windows, electrochromic materials can regulate the amount of light and heat entering a building, thereby reducing energy consumption for heating, cooling, and lighting, and contributing to a more sustainable future.
Piezoelectric Materials
These materials have the ability to generate voltage whenever surface strain is applied. In contrast, when an electric field is applied across the material, deformation (stress) occurs. A piezoelectric material, when incorporated into a structural element, produces an electric field in reaction to mechanical stresses, which can help in detecting degradation/unusual deformation in structural members.
Shape Memory Alloys
When exposed to the proper thermal changes, these materials have the capacity to restore some previously established shape or size. Shape memory alloys are used in revolutionary ways in civil engineering, particularly for the protection of buildings against earthquakes.
Shape memory alloys are used in civil engineering because of their excellent durability and dependability over the long term, their ability to repeatedly absorb strain energy without permanently deforming, their wide range of cyclic behavior, and their ability to resist fatigue under heavy strain cycles.
Electrorheological Fluids
When exposed to an electric field, these colloidal suspensions experience changes in viscosity. These fluids are extremely sensitive and react right away to any alteration in the applied electric field. They are great as shock absorbers.
Magnetostrictive Materials
In proportion to the square of the electric field, these materials experience mechanical deformation, which is the property of the material that causes it to change in size in reaction to an electric or magnetic field and, in the opposite, to produce a voltage when stretched. These materials have potential for use in wind tunnels in aerospace as well as pumps and valves.
Applications of Smart Materials in Infrastructural Development
Self-healing concrete: Incorporating bacteria or microcapsules filled with healing agents, this smart material can repair cracks autonomously, increasing the lifespan of structures.
Electrochromic windows: These smart windows use electrochromic materials to control the amount of light and heat entering buildings, improving energy efficiency and user comfort.
Shape memory alloys (SMAs): Used in seismic-resistant structures, SMAs can absorb and dissipate energy from earthquakes, reducing the risk of structural damage.
Piezoelectric sensors: Integrated into infrastructure, these sensors can monitor the health of structures, identifying potential issues before they become critical.
Thermochromic materials: Applied to buildings' exteriors, these materials change color based on temperature, helping to regulate internal temperatures and save energy.
Smart pavements: Made with piezoelectric materials, these pavements can generate electricity when subjected to pressure from vehicles or pedestrians.
Smart roadways: Featuring embedded sensors, they can monitor traffic conditions, detect accidents, and communicate information to drivers or traffic management systems.
Energy-harvesting materials: Integrated into structures, these materials can convert environmental energy, such as solar or wind, into electricity for powering buildings or public lighting.
Magneto-rheological (MR) and Electro-rheological (ER) fluids: Used in smart dampers, these fluids can adjust their viscosity in response to magnetic or electric fields, providing improved control and stability in bridges or high-rise buildings.
Self-cleaning surfaces: Featuring hydrophobic or photocatalytic coatings, these surfaces can repel water and dirt or break down pollutants, reducing maintenance costs and improving air quality.
Importance of Smart Infrastructure
Safety and Resilience
The terms "safety" and "resilience" refer to the ability to keep systems and designs flexible, to protect users and the infrastructure, and to withstand unforeseen events like human mistake. The management of seating at significant events may be cited as an illustration.
Sustainability
This benefit relates to the fact that decision-making is optimized to ensure that all controlled resources are used sustainably. For instance, cities could manage their garbage, water, and energy more effectively.
Self-control and accuracy in decision-making
These systems automatically monitor an asset’s internal structure, the state of its materials, and the circumstances surrounding its use in order to increase the accuracy and speed of decision-making. Knowing the status of traffic, public transportation, and parking spots would be one example in a smart city. This would allow for the creation of better routes for either public transportation or private vehicles.
Reliability
This is the ability of a company to continue offering its services with the maximum level of dependability by minimizing system outages and unanticipated problems.
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