There are several different definitions for drones, so the numbers may vary, but Business Insider Intelligence projects drone sales of more than USD 12 billion in 2021 for military, personal and commercial use.

Commercial applications for drones are especially on the rise with an expected compound annual growth rate (CAGR) of 19 percent from 2015 to 2020, and The Association for Unmanned Vehicle Systems International estimates commercial drones will be worth USD 82 billion by 2025.

New ways of incorporating drones into the workforce are popping up everywhere, such as for marketing, expedient delivery and information gathering. In heavy industries like steel manufacturing, drones are playing an increasingly important role in workplace safety. When paired with AI, drones have even more possibilities for minimizing workplace hazards.

Accident Prevention

An accident in a heavy industry worksite can be disastrous for workers, the company as well as the environment. That’s why it’s important for factories to be able to monitor and prevent potential dangers before they happen, and it’s one of the most widely applied areas for drones.

Audi’s factory uses drones for automated parts transportation. (Source: Audi)

For example, steelmaker POSCO is incorporating drones into its smart factory to monitor gas leaks that are hard to detect. Workers also wear smart sensors that alert them of potential danger, and let others know their location in the factory.

SEE ALSO: How Factories Produce Steel – the Smart Way

Keeping Humans Out of Dangerous Industrial Areas

Besides monitoring the workplace, drones can be of practical use and take on dangerous and costly tasks formerly done by people. This includes accessing dangerous places. For example, drones can take aerial job site survey photos, eliminating the need for a pilot, helicopter and other employees. Construction companies are using drone mapping to create 3D models of their projects, saving time and resources along the way.

Drones can keep workers out of dangerous workplaces. (Source: Fortune)

The mining industry also uses drones to enter hazardous areas to gather information before sending in workers. Smart drones, or drones equipped with AI software, can provide and process information in real time, saving companies major costs.  

Accident Investigation

Even with drones, not all accidents are preventable. Once an accident occurs it’s vital to have accurate data that tells exactly how the event played out. Drones are a useful forensic tool to recall events and diagnose the situation. With this information, companies can not only fix equipment and operational failures, they can use the data for legal matters regarding insurance claims, court fees and compensation litigation.

Workers can use drones to access stored information. (Source: The Economist)

Due to the increasing adoption of drones in the workplace and the vital role they play in worker safety, the commercial drone market is looking to expand. With increased investment, drones are being upgraded from its structure to the software that goes in them.

What Drones are Made of

Drones are largely composed of a frame, motor, camera, propeller, sensor, controller and battery. The frame serves as the base of the drone to which various parts mounted. Therefore, the frame of the drone has to be light yet durable, in order to maintain its structural integrity and minimize battery consumption.

Most drones are powered by an electric battery. On longer flights and in harsh weather conditions, the motor gets overworked, putting a toll on the battery. Engineers are constantly working to improve the capacity of the battery, which usually results in a bigger, heavier battery pack.

The DJI Phantom 4 is an example of a drone with a magnesium body for weight reduction and added strength. (Source: Petapixel)

In order to make up for the added weight and volume, manufacturers are turning to light and strong materials such as magnesium, the lightest commercial metal available. Magnesium alloys are lighter than aluminum alloys and are widely used in smartphones, tablet PCs and automotive and aircraft parts. Magnesium alloys have high thermal conductivity and excellent heat dissipation. It also has high strength and durability against impact. Moreover, it is corrosion-resistant and cost-effective, making it an ideal material for drones.

The market for drones will be an exciting one to watch going into 2018 due to friendlier regulations, significant investments and drones’ unlimited potential for application. It will result in more industries actively incorporating drones into their operations, and the world can expect the launch of more technologically and structurally innovative drones that will play an increasingly vital role in workplaces.

Cover photo courtesy of Wired.

Here’s a look at how steel is produced in a steel mill or factory, and what the “smartization” of steel factories will look like.

So, how is steel made?

Iron Making

To make steel, manufacturers first need molten iron. Molten iron comes from two raw materials; iron ore and coal. Iron ore is converted into sinter ore in a sintering plant and coal is converted into raw coke using a coke oven. The processed materials are poured into a blast furnace where hot air reaching 1200℃ is blown in from the bottom through tuyeres, causing a chemical reaction. This process oxidizes the coke and reduces the sintered ore, creating molten iron.   

Steelmaking

In the steelmaking stage, the molten iron is transported to the steel making plant via a torpedo car, where the liquid is poured into a converter. Then, oxygen is blown into the converter to burn off all the impurities. All that is left is pure molten steel.

Continuous Casting

This is where steel finally becomes solidified into different shapes such as slab, bloom and billet. Liquid steel is poured into molds and cooled as it passes through a continuous casting machine until it solidifies into the desired shape.

Hot steel passes through rolling machines to be rolled into specific sizes and thicknesses. (Source: Global Sourcing Blog)

Rolling Process

During the rolling process, steel is heated once more to achieve various sizes and thicknesses. Steel slabs are heated to over 1100℃, then pass through rolling machines. This results in hot-rolled coils that can be shaped for different uses such as thick plates. They can also be processed into long, wire-shaped rods for billets. Often, the hot-rolled coils are rolled at room temperature for cold-rolled coils. Cold-rolled coils can be fabricated to produce galvanized and electrical steel products.

“Smartizating” these processes will involve converging IoT, Big Data, and AI to connect the different facilities, IT systems and workers in order to collect and analyze data for optimization.

POSCO is “smartizing” the steel-production process

POSCO is a steel company looking to lead the industry in adopting smart factories. CEO Kwon Ohjoon made “smartization” one of the 4 key priorities for POSCO starting back in 2014, and Kwon will continue to increase those investments.

POSCO smart factory incorporates artificial intelligence to enhance safety and efficiency.

SEE ALSO: How Smart Factories are Changing the Manufacturing Industry

In 2016, POSCO established its Smart Solution Council in order to research AI, big data and IoT applications. In the same year, POSCO ICT’s smart factory platform, PosFrame, was completed and installed in POSCO’s Gwangyang Steel Mill. PosFrame allows engineers to collect and monitor big data. So far, the company has saved over USD 14 million by incorporating the new technology in its production practices.

Here are some other features of POSCO’s Smart Factory.

POSCO’s Smart Blast Furnace

The Pohang Blast Furnace No.3 became a smart furnace in 2017, following a 102-day repair period. The furnace is now equipped with automated sensors that monitor and control its internal conditions using AI technology. Smart sensors monitor the blast furnace for factors like raw material quality and ventilator status, preventing breakdowns and ensuring a much longer lifecycle.

SEE ALSO: Will Artificial Intelligence Lead to Breakthroughs in the Steel Industry?

Worker Safety

Smart sensors can be used for more than just process monitoring. The company is working toward a full implementation of smart sensors for safety purposes, using IoT to create a better working environment.

Steel manufacturing involves high temperatures and high pressure levels, which is dangerous for workers who come in close contact with the equipment. With smart sensors monitoring all of the factory information, workers will instead be monitoring operation from a safe distance.

Workers in POSCO’s smart factory wear smart sensors for safety.

Wearable sensors, in conjunction with factory smart sensors, will be able to detect if and when workers are approaching potentially dangerous areas, and will alert them. These sensors will also detect and alert with regards to any impending accidents, or life-threatening situations like gas leaks, explosions, or fires.

Also, dust, sulfur, and nitrogen compounds will be removed via a high-plasma method, creating an eco-friendly steel plant and a healthier environment for workers.

POSCO will continue to add more smart features to its steel mills to increase efficiency, safety and sustainability. In efforts to learn and implement new technologies, POSCO CEO Kwon Ohjoon visited GE’s smart factories to learn about their technology earlier this year. POSCO also held the 2017 Smart POSCO Forum to share its insights with clients and affiliates, all as part of its expanding smartization efforts.