Automation in construction

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Automation in construction is the combination of methods, processes, and systems that allow for greater machine autonomy in construction activities. Construction automation may have multiple goals, including but not limited to, reducing jobsite injuries, decreasing activity completion times, and assisting with quality control and quality assurance. [1] Some systems may be fielded as a direct response to increasing skilled labor shortages in some countries. [2] Opponents claim that increased automation may lead to less construction jobs and that software leaves heavy equipment vulnerable to hackers. [3]

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Transportation Construction

Kratos Defense & Security Solutions fielded the world’s first Autonomous Truck-Mounted Attenuator (ATMA) in 2017, in conjunction with Royal Truck & Equipment. [4]

Uses of Automation in Construction

  1. Equipment control and management: Automation can be used to control and monitor construction equipment, such as cranes, [5] excavators, and bulldozers.
  2. Material handling: Automated systems can be used to handle, transport, and place materials such as concrete, bricks, and stones.
  3. Surveying: Automated survey equipment and drones can be used to collect and analyze data on construction sites.
  4. Quality control: Automated systems can be used to monitor and control the quality of materials and construction processes.
  5. Safety management: Automated systems can be used to monitor and control safety conditions on construction sites.
  6. Scheduling and planning: Automated systems can be used to manage schedules, resources, and costs.
  7. Waste management: Automated systems can be used to manage and dispose of waste materials generated during construction.
  8. 3D printing: Automated 3D printing can be used to create prototypes, models, and even full-scale building components. [6]

Benefits of Automation in Construction

The use of automation in construction has become increasingly prevalent in recent years due to its numerous benefits. Automation in construction refers to the use of machinery, software, and other technologies to perform tasks that were previously done manually by workers.

One of the most significant benefits of automation in construction is increased productivity [7] . Automation can help speed up construction processes, reduce project completion times, and improve overall efficiency. For example, using automated machinery for tasks such as concrete pouring, bricklaying, and welding can significantly increase the speed and accuracy of these tasks [8] , allowing for more work to be completed in a shorter amount of time.

Another benefit of automation in construction is improved safety. By automating tasks that are hazardous to workers, such as demolition or working at height, companies can reduce the risk of accidents and injuries on site. Automation can also help to reduce worker fatigue, which can be a significant factor in accidents and mistakes.

Overall, the use of automation in construction can improve productivity, reduce costs, increase safety, and improve the quality of construction projects. As technology continues to advance, the use of automation is likely to become even more prevalent in the construction industry.

Related Research Articles

<span class="mw-page-title-main">Automation</span> Use of various control systems for operating equipment

Automation describes a wide range of technologies that reduce human intervention in processes, namely by predetermining decision criteria, subprocess relationships, and related actions, as well as embodying those predeterminations in machines. Automation has been achieved by various means including mechanical, hydraulic, pneumatic, electrical, electronic devices, and computers, usually in combination. Complicated systems, such as modern factories, airplanes, and ships typically use combinations of all of these techniques. The benefit of automation includes labor savings, reducing waste, savings in electricity costs, savings in material costs, and improvements to quality, accuracy, and precision.

<span class="mw-page-title-main">Logistics automation</span> Application of computer software or automated machinery

Logistics automation is the application of computer software or automated machinery to improve the efficiency of logistics operations. Typically this refers to operations within a warehouse or distribution center, with broader tasks undertaken by supply chain engineering systems and enterprise resource planning systems.

<span class="mw-page-title-main">Robot welding</span>

Robot welding is the use of mechanized programmable tools (robots), which completely automate a welding process by both performing the weld and handling the part. Processes such as gas metal arc welding, while often automated, are not necessarily equivalent to robot welding, since a human operator sometimes prepares the materials to be welded. Robot welding is commonly used for resistance spot welding and arc welding in high production applications, such as the automotive industry.

<span class="mw-page-title-main">Mechanised agriculture</span> Agriculture using powered machinery

Mechanised agriculture or agricultural mechanization is the use of machinery and equipment, ranging from simple and basic hand tools to more sophisticated, motorized equipment and machinery, to perform agricultural operations. In modern times, powered machinery has replaced many farm task formerly carried out by manual labour or by working animals such as oxen, horses and mules.

Lights-out manufacturing is the methodology of fully automating the production of goods at factories and other industrial facilities, such as to require no human presence on-site. Many of these factories are considered to be able to run "with the lights off," but few run exclusively lights-out production. For example, in computer numerical control machining, the presence of human workers is typically required for removing completed parts and setting up tombstones that hold unfinished parts. As the technology necessary for total automation becomes increasingly available, many factories are beginning to use lights-out production between shifts to meet increasing production demand or to save money on labor.

<span class="mw-page-title-main">Material-handling equipment</span>

Material handling equipment (MHE) is mechanical equipment used for the movement, storage, control, and protection of materials, goods and products throughout the process of manufacturing, distribution, consumption, and disposal. The different types of equipment can be classified into four major categories: transport equipment, positioning equipment, unit load formation equipment, and storage equipment.

<span class="mw-page-title-main">Agricultural robot</span> Robot deployed for agricultural purposes

An agricultural robot is a robot deployed for agricultural purposes. The main area of application of robots in agriculture today is at the harvesting stage. Emerging applications of robots or drones in agriculture include weed control, cloud seeding, planting seeds, harvesting, environmental monitoring and soil analysis. According to Verified Market Research, the agricultural robots market is expected to reach $11.58 billion by 2025.

<span class="mw-page-title-main">Manufacturing engineering</span> Branch of engineering

Manufacturing engineering or production engineering is a branch of professional engineering that shares many common concepts and ideas with other fields of engineering such as mechanical, chemical, electrical, and industrial engineering. Manufacturing engineering requires the ability to plan the practices of manufacturing; to research and to develop tools, processes, machines and equipment; and to integrate the facilities and systems for producing quality products with the optimum expenditure of capital.

<span class="mw-page-title-main">Material handling</span> Sub-discipline of mechanical engineering

Material handling involves short-distance movement within the confines of a building or between a building and a transportation vehicle. It uses a wide range of manual, semi-automated, and automated equipment and includes consideration of the protection, storage, and control of materials throughout their manufacturing, warehousing, distribution, consumption, and disposal. Material handling can be used to create time and place utility through the handling, storage, and control of waste, as distinct from manufacturing, which creates form utility by changing the shape, form, and makeup of material.

Business process management (BPM) is the discipline in which people use various methods to discover, model, analyze, measure, improve, optimize, and automate business processes. Any combination of methods used to manage a company's business processes is BPM. Processes can be structured and repeatable or unstructured and variable. Though not required, enabling technologies are often used with BPM.

<span class="mw-page-title-main">Modular construction</span> Structure of the building

Modular construction is a construction technique which involves the prefabrication of 2D panels or 3D volumetric structures in off-site factories and transportation to construction sites for assembly. This process has the potential to be superior to traditional building in terms of both time and costs, with claimed time savings of between 20 to 50 percent faster than traditional building techniques.

Automated mining involves the removal of human labor from the mining process. The mining industry is in the transition towards automation. It can still require a large amount of human capital, particularly in the developing world where labor costs are low so there is less incentive for increasing efficiency. There are two types of automated mining- process and software automation, and the application of robotic technology to mining vehicles and equipment.

Agent-assisted automation is a type of call center technology that automates elements of what the call center agent 1) does with his/her desktop tools and/or 2) says to customers during the call using pre-recorded audio. It is a relatively new category of call center technology that shows promise in improving call center productivity and compliance.

Automation bias is the propensity for humans to favor suggestions from automated decision-making systems and to ignore contradictory information made without automation, even if it is correct. Automation bias stems from the social psychology literature that found a bias in human-human interaction that showed that people assign more positive evaluations to decisions made by humans than to a neutral object. The same type of positivity bias has been found for human-automation interaction, where the automated decisions are rated more positively than neutral. This has become a growing problem for decision making as intensive care units, nuclear power plants, and aircraft cockpits have increasingly integrated computerized system monitors and decision aids to mostly factor out possible human error. Errors of automation bias tend to occur when decision-making is dependent on computers or other automated aids and the human is in an observatory role but able to make decisions. Examples of automation bias range from urgent matters like flying a plane on automatic pilot to such mundane matters as the use of spell-checking programs.

<span class="mw-page-title-main">Factory automation infrastructure</span>

Factory automation infrastructure describes the process of incorporating automation into the manufacturing process of end/final products.

<span class="mw-page-title-main">Packaging machinery</span>

Packaging machinery is used throughout all packaging operations, involving primary packages to distribution packs. This includes many packaging processes: fabrication, cleaning, filling, sealing, combining, labeling, overwrapping, palletizing.

<span class="mw-page-title-main">Ergonomic hazard</span>

Ergonomic hazards are physical conditions that may pose a risk of injury to the musculoskeletal system due to poor ergonomics. These hazards include awkward or static postures, high forces, repetitive motion, or short intervals between activities. The risk of injury is often magnified when multiple factors are present.

Digital banking is part of the broader context for the move to online banking, where banking services are delivered over the internet. The shift from traditional to digital banking has been gradual and remains ongoing, and is constituted by differing degrees of banking service digitization. Digital banking involves high levels of process automation and web-based services and may include APIs enabling cross-institutional service composition to deliver banking products and provide transactions. It provides the ability for users to access financial data through desktop, mobile and ATM services.

Manual material handling (MMH) work contributes to a large percentage of the over half a million cases of musculoskeletal disorders reported annually in the United States. Musculoskeletal disorders often involve strains and sprains to the lower back, shoulders, and upper limbs. They can result in protracted pain, disability, medical treatment, and financial stress for those afflicted with them, and employers often fi nd themselves paying the bill, either directly or through workers’ compensation insurance, at the same time they must cope with the loss of the full capacity of their workers.

<span class="mw-page-title-main">Workplace impact of artificial intelligence</span> Impact of artificial intelligence on workers

The impact of artificial intelligence on workers includes both applications to improve worker safety and health, and potential hazards that must be controlled.

References

  1. "The impact and opportunities of automation in construction". McKinsey & Company. Retrieved 13 November 2020.
  2. Vernon, Joe; Hughes, Jeff (1 September 2017). "Using Automation to Combat the Impending Labor Shortage". Industry Week. Retrieved 13 November 2020.
  3. Carter, Jamie (5 March 2019). "Hacked Driverless Cars Could Cause Collisions And Gridlock In Cities, Say Researchers". Forbes. Retrieved 13 November 2020.
  4. Peck, Abe (23 July 2019). "From War Zone to Work Zone". Autonomous Media, LLC. Inside Unmanned Systems. Retrieved 20 December 2020.
  5. "Introduction to Construction Cranes". Spanco. 2018-07-24. Retrieved 2023-01-31.
  6. "Engineering News-Record | ENR". www.enr.com. Retrieved 2023-03-14.
  7. "The impact and opportunities of automation in construction | McKinsey". www.mckinsey.com. Retrieved 2023-03-14.
  8. Robotics and Automation in Construction. [Place of publication not identified]: InTech. ISBN   953-7619-13-3. OCLC   1096651329.