Article | December 10, 2021
IoT in the manufacturing industry introduces a superior technology that is coming up as a blessing for the industry. Manufacturers are enjoying one-of-a-kind benefits and returns on their reinvestments in IoT. Benefits such as enhanced productivity, work safety, reduced downtime, cost-effective operations, and more such benefits of IoT in manufacturing make it more and more popular with each passing day.
The global IoT market is estimated to reach a value of USD 1,386.06 billion by 2026 from USD 761.4 billion in 2020 at a CAGR of 10.53 percent over the forecast period of 2021-2026. So the whole worldwide market of IoT has a bright future in the following years.
“As technology takes over and enhances many of the processes we used to handle with manual labor, we are freed up to use our minds creatively, which leads to bigger and better leaps in innovation and productivity.”
– Matt Mong, VP Market Innovation and Project Business Evangelist at Adeaca
Let’s check out below some exciting facts about IoT in manufacturing and see how IoT makes a difference in the manufacturing industry.
IoT in Manufacturing: Some Interesting Facts
According to PwC, 91% of industrial/manufacturing enterprises in Germany invest in "digital factories" that use IoT solutions.
According to the International Federation of Robotics (IFR), China employs more industrial robots than any other country (many of which are connected to the internet in some way).
According to IoT Analytics, the industrial sector spent more than $64 billion on IoT in 2018 and expects investment in Industry 4.0 to reach $310 billion by 2023.
According to the Eclipse Foundation, most IoT developers are focused on developing smart agriculture systems (26%), while industrial automation is another big focus area (26%). However, home automation is dwindling in popularity, accounting for just 19% of projects.
How Does IoT Work for the Manufacturing Industry?
The Internet of Things (IoT) is a network of interconnected devices that communicate with one another and with other networks. While IoT-enabled devices are capable of various tasks, they are primarily employed to collect data and carry out specific tasks. The implementation of the Internet of Things in manufacturing is often referred to as the IIoT, or Industrial Internet of Things.
IoT makes use of 'smart' devices to collect, process, and act on data. These intelligent devices are equipped with sensors and other software that enable them to communicate and exchange data inside the network.
IoT-enabled equipment gives crucial real-time data that enables manufacturers or machine operators to make informed decisions. So, how does it function in practice?
Sensors capture data from the system and transfer it to the cloud, where it can be analyzed.
The data is transferred to the quality assurance system.
The data that has been analyzed is forwarded to the end-user.
How the IoT is Improving Manufacturing Business Operations
The Internet of Things (IoT) has numerous benefits for the manufacturing industry. We'll go over some of the significant benefits that the Internet of Things brings to the manufacturing business.
Energy Efficiency Solutions
Energy is a high cost in manufacturing. Unfortunately, the current industrial energy infrastructure can only track excessive energy consumption.
The utility bills include the factory's energy consumption records. But, unfortunately, nobody can break down energy consumption to the device level and find out the underperforming pieces. Some energy usage monitoring tools exist, but they only provide partial data, making system analysis difficult.
IoT can help by giving device-level energy data. The sensors will detect any underperforming devices in the network and alert you so you can take action. As a result, the technology can help you reduce energy waste and find other ways to save it.
Data is required to determine trends and quality of production at a manufacturing facility. It also helps manufacturers plan and anticipates changes. These forecasts can help with inventory management, employment, cost control, and other operational procedures. Thus, IoT technology makes it easier to foresee and optimize customer requirements.
The Internet of Things (IoT) uses sensors to gather data about assets' health and productivity. In addition, it uses advanced analytics to give actionable information. These are presented on an appealing dashboard connected to your smart device. This allows for predictive maintenance to be used in the manufacturing industry.
Superior Product Quality
Every manufacturer is determined to produce a high-quality product at a low cost. Therefore, a minor quality modification can have a significant influence on the manufacturing firm.
Customer happiness, waste reduction, sales, and profit can all benefit from high-quality products. But making high-quality products isn't easy.
The Internet of Things (IoT) can assist you in this endeavor. Poorly set, calibrated, and maintained equipment are some of the main reasons for low-quality products. Worst of all, many small things sometimes go ignored as the final product seems perfect. Quality tests show the product is fine, but your consumers start having problems after a couple of months.
Imagine the resources needed to identify and correct the problem. Sensors in an IoT network detect even minimal tweaks in setup and alert operators. The team might momentarily stop production to address the issue before the production cycle gets complete.
Rapid and Informed Decision-Making
The IoT can dramatically improve organizational decision-making. It unlocks vital data about network equipment performance and delivers it to the right person.
Managers and field operators can use this data to improve plant processes and overall production.
In addition to these significant benefits, IoT in manufacturing can help manufacturers improve their manufacturing operations and construct a unit that meets the vision of the smart factory of 2040. The future beyond IoT would be the icing on the cake for all of us, as technology has always amazed us.
Imagine the day when IoT and AI merge, and the virtual gadgets controlled by IoT are the next major milestone. Then, the ideal combination of robotics, AI, and VR may reduce the manufacturing plant size and cost while increasing the output to a level that is unimaginable and unattainable as of now.
Airbus Improved Production Efficiency with Its Factory of the Future Concept
It's a massive task for a commercial airliner to be assembled. The expense of making a mistake throughout making such a craft can be significant, as there are millions of parts and thousands of assembly phases. Airbus has established a digital manufacturing effort called Factory of the Future to optimize operations and increase production capacity. The company has installed sensors on factory floor tools and machinery and supplied workers with wearable technologies, such as industrial smart glasses, to reduce errors and improve workplace safety. The wearable allowed for a 500% increase in efficiency while eliminating nearly all mistakes in one process named cabin seat marking.
While the benefits of IoT devices have long been a topic of discussion among technology enthusiasts, the incorporation of IoT in manufacturing is creating a new buzz in the industry. The benefits of IoT in manufacturing, such as remote analysis of operations, processes, and products, are assisting manufacturers in establishing a more productive manufacturing unit. As a result of these benefits, IoT use in manufacturing is accelerating. Recognize the IoT's potential and take a step toward incorporating it into your manufacturing operation in 2022.
What is the Industrial Internet of Things (IIoT)?
IIoT stands for Industrial Internet of Things. It uses data to improve industrial efficiency. To enhance industrial performance, it uses embedded sensors, cloud data, and connected devices.
Why is the IoT changing manufacturing?
Real-time monitoring of machines and accurate reporting for better decisions are possible through IoT. This improves business strategies and project control. Thus, the Internet of Things has a significant impact on the profitability of any manufacturing company.
How does the IoT transform the way we do business?
We can use data collected by IoT devices to improve efficiency and help organizations make better decisions. They tell organizations the truth, not what they hope or believe.
"name": "What is the Industrial Internet of Things (IIoT)?",
"text": "IIoT stands for Industrial Internet of Things. It uses data to improve industrial efficiency. To enhance industrial performance, it uses embedded sensors, cloud data, and connected devices."
"name": "Why is the IoT changing manufacturing?",
"text": "Real-time monitoring of machines and accurate reporting for better decisions are possible through IoT. This improves business strategies and project control. Thus, the Internet of Things has a significant impact on the profitability of any manufacturing company."
"name": "How does the IoT transform the way we do business?",
"text": "We can use data collected by IoT devices to improve efficiency and help organizations make better decisions. They tell organizations the truth, not what they hope or believe."
Article | December 6, 2021
Aerospace manufacturing and design are getting advanced with additive manufacturing. However, the limitations of traditional manufacturing techniques sometimes make it incompetent to produce technologically oriented products. Additive Manufacturing (AM)helps the aircraft system run more efficiently by creating lightweight aircraft parts.
This is one of the reasons that additive manufacturing is gaining traction in aerospace and other industries. According to recent analysis and data, the global additive manufacturing market is expected to grow from USD 9.52 billion in 2020 to USD 27.91 billion in 2028. The expanding technologies and materials used in additive manufacturing will indeed stimulate industry growth shortly.
It’s important to note that there isn’t one channel that is the silver bullet. Most of the time, a combination of different channels will help drive a more powerful outcome.”
– Wendy Lee, Director of Marketing at Blue Prism
However, the aerospace industry encounters some challenges with additive manufacturing, which is the focus of this article. Scalability, multi-material capabilities, professional workers, high-cost materials, and quality compliance norms are all constraints that aerospace professionals are dealing with. Here we will discuss the top three challenges of additive manufacturing in aerospace and their solutions.
Future of Additive Manufacturing in the Aerospace Industry
Even though additive manufacturing has been around for a while, it has only lately become advanced enough to be used in the aerospace sector.
In the aerospace business, additive manufacturing has the potential to deliver significant benefits. Cost savings, design freedom, weight reduction, shorter time to market, fewer waste materials, better efficiency, and on-demand production are just some of the benefits.
Although additive manufacturing cannot make every part, it provides an exciting opportunity to explore feasible alternatives, either supplementing or replacing traditional manufacturing processes. However, it must be taken into account early in the development phase. Additionally, knowledge must be embedded in aircraft design teams to ensure the successful use of additive manufacturing.
However, in recent years, AM has become more prevalent in end-to-end manufacturing. According to Deloitte University Press, the future of AM in aerospace may include:
Directly embedding additively produced electronics
3D printing engine parts
Making battlefield repair components
Top 3 Additive Manufacturing Challenges in the Aerospace Industry and Solutions
While problems are inherent in any new technology, experts overcome them by identifying solutions. Let's look at the top three challenges that the aerospace industry is currently facing and the solutions to overcome them.
Lack of Qualified Experts
Using 3D printers in production and automating work processes are skills that are lacking. However, the obstacles are natural, and the skilled manufacturing workforce is aging and reluctant to adapt to new design models. This is creating the skills gaps surrounding manipulating AM technology.
How to Overcome
Less time spent educating employees is better for business. For example, the US National Additive Manufacturing Institute and the European ADMIRE initiative offer accelerated courses via remote learning websites.
Of course, you'll need to provide numerous additive manufacturing opportunities to attract the key technologists, either on-site or off-site. They will oversee new hires' activities and help them translate their knowledge of 3D printing into designs and final items.
Over Budget Material
The typical cost of AM equipment is $300,000. Industrial consumables cost between $100 and $150 per item (although the final price is formed after choosing the material; plastic, for example, is the most budget-friendly option).
How to Overcome
To overcome this obstacle, you must plan a long-term implementation strategy based on the manufacturing-as-a-service model. On-demand manufacturing reduces manufacturing costs and speeds up product development. You can also go with cheap 3D printers that use cheap welding wire that hasjust come onto the market. They cost $1,200 and may suit your needs.
Fresh Quality Compliance Guidelines
As 3D printing and CNC manufacturing technologies constantly evolve, there are no established norms or regulations for 3D printed objects. However, 3D printed solutions do not always match traditional quality, durability, and strength. For example, a 3D-printed mechanical part. Can someone order 500 similar parts a few months later? Consistency standards and product post-processing may have a negative impact in such circumstances. So, in such a case, traditional manufacturing wins over 3D printing.
How to Overcome
You might endeavor to set quality criteria for your 3D-printed products to ensure they are comparable to traditional ones. You can also apply the ANSI AMSC and America Makes standards, which define quality criteria for 3D printed products.
How Boeing Applies Additive Manufacturing Technology?
Boeing is focusing its efforts on leveraging and speeding up additive manufacturing to transform its manufacturing system and support its growth. The company operates 20 additive manufacturing facilities worldwide and collaborates with vendors to supply 3D-printed components for its commercial, space, and defense platforms.
Boeing is now designing missiles, helicopters, and airplanes using 3D printing technology. A small internal team contributes roughly 1,000 3D-printed components to the company's flight projects. Boeing claims that addressing design as an "integrated mechanical system" considerably improves manufacturability and lowers costs.
Additive manufacturing is altering the way the aerospace industry designs and manufactures aircraft parts. Aerospace advanced manufacturing is making aircraft production easier. We've explored solutions to some of the snags that you may encounter. However, other concerns, such as limited multi-material capabilities and size constraints, require solutions, and industry specialists are working on them. Despite these challenges, additive manufacturing is still booming and rocking in a variety of industries.
Why is additive manufacturing used in Aerospace?
It allows the industry to build quality parts quickly and inexpensively. Reduce waste and build parts for aircraft that are difficult to manufacture using existing methods.
How does additive manufacturing help in Aerospace applications?
Environmental control system (ECS) ducting, custom cosmetic aircraft interior components, rocket engine components, combustor liners, composite tooling, oil and fuel tanks, and UAV components are examples of typical applications. 3D printing helps in producing solid, complicated pieces with ease.
Which aerospace firms use additive manufacturing/3D printing?
Boeing and Airbus are two of the many aircraft businesses that use additive-created parts in their planes. Boeing incorporates additive manufacturing (AM) components into both commercial and military aircraft. Airbus also employs AM metal braces and bleed pipes on the A320neo and A350 XWB aircraft.
"name": "Why is additive manufacturing used in Aerospace?",
"text": "It allows the industry to build quality parts quickly and inexpensively. Reduce waste and build parts for aircraft that are difficult to manufacture using existing methods."
"name": "How does additive manufacturing help in Aerospace applications?",
"text": "Environmental control system (ECS) ducting, custom cosmetic aircraft interior components, rocket engine components, combustor liners, composite tooling, oil and fuel tanks, and UAV components are examples of typical applications. 3D printing helps in producing solid, complicated pieces with ease."
"name": "Which aerospace firms use additive manufacturing/3D printing?",
"text": "Boeing and Airbus are two of the many aircraft businesses that use additive-created parts in their planes. Boeing incorporates additive manufacturing (AM) components into both commercial and military aircraft. Airbus also employs AM metal braces and bleed pipes on the A320neo and A350 XWB aircraft."
Article | November 12, 2021
Robotics industry growth has accelerated rapidly across several industries. It has aided manufacturers in overcoming numerous barriers related to real-time communication, workplace safety, and overall manufacturing cost and timeliness. However, if we trace its history back to 1961 when George Charles Devol introduced the first robot, dubbed 'UNIMATE,' it has exponentially grown and utilized across sectors to make operations more effortless, precise, and faster.
“As technology takes over and enhances many of the processes we used to handle with manual labor, we are freed up to use our minds creatively, which leads to bigger and better leaps in innovation and productivity.”
– Matt Mong, VP Market Innovation and Project Business Evangelist at Adeaca.
However, the industry has seen snags or difficult times due to market fluctuations, unfavorable situations, and the need to remain competitive in the drive for expansion. To thoroughly understand the robotics industry, let us examine each component that surrounds it.
Industrial Robotics Global Market Size
According to recent Allied Market Research studies, the global industrial robotics market was worth $37,875 million in 2016 and is expected to reach $70,715 million by 2023, rising at a 9.4% compound annual growth from 2017 to 2023.
Industrial Robotics Market Analysis
The global industrial robotics market is primarily driven by a global increase in labor costs, which has compelled firms to replace human labor with robots. As a result, Asia and Europe are the world's fastest-growing areas, with top companies such as ABB, Fanuc, KUKA, Kawasaki, and Yaskawa Electric Corporation headquartered in the region.
The global market of robotics has been segmented by its type, industry, and function.
Soldering and Welding
Electrical & Electronics
Healthcare & Medicine
Assembling & Disassembling
Rubber & Plastics
Painting and Dispensing
Others if any
Machinery & Metals
Cutting and Processing
Food & Beverages
Precision & Optics
Others if any
Others if any
Industries That Are Pioneering the Use of Robotics
As we have observed, the global robotic market will continue to rise in the future years. Therefore, let us examine which industries will extend their use of robotics in their operations.
Healthcare & Medicine
Medical robots help surgeons optimize hospital logistics and free up the working staff to focus on patients. In the healthcare field, robots are revolutionizing surgery by speeding supply delivery and disinfection and freeing up time for doctors to interact with their patients.
da Vinci System – A General Surgical Robot
The da Vinci System is a surgical robot that focuses on a wide range of urological, bariatric, and gynecological surgical treatments. In addition, Stryker's MAKO System also specializes in orthopedic surgery, specifically partial and total knee replacements.
The da Vinci SP system is cleared for use in the United States exclusively for single-port urological procedures, lateral oropharyngectomy (often referred to as radical tonsillectomy), and tongue base excision.
Police robots are meant to gain access to areas inaccessible or dangerous to first responders, and they are capable of manipulating items and gathering data using several technologies. It encompasses robots capable of operating in various conditions and displaying a range of data and communication capabilities.
Agriculture & Food Industry
Farm equipment is now routinely equipped with sensors that utilize machine learning and robotics to identify weeds, compute the appropriate quantity of herbicide to spray, or learn to detect and pick strawberries, for instance.
Additionally, in the food business, robotics has been used to do repetitive tasks such as picking and placing food items and cutting and slicing food items during any given food item. For instance, the modern bakery business uses robotics to perform traditional craft skills and produce any product in large quantities while maintaining high quality and hygiene standards.
The transportation sector is highly leveraging robotics. The powerful transport capability, advanced control technology, and sensing precision are some of the benefits that make the transportation robots widely utilized in this sector. These benefits from robotics help the sector convey various commodities in factories, restaurants, and medical institutions, among other locations.
Robots are employed in manufacturing to do repeated jobs and streamline the overall assembly process. Additionally, robots and humans can also collaborate on product making. Robots can replace humans for hazardous tasks or processes that need large quantities of materials, which might be hazardous for a human employee to handle.
Factors Sustaining the Growth of the Robotics Industry
Reduces Manufacturing Costs: Robotics application in all industries reduces the overall manufacturing process running costs.
Improves Product Quality: The precision of robotics throughout the manufacturing process helps produce high-quality items that meet target client needs.
Offers Competitive Market: Increased income due to utilizing the benefits of robotics applications makes any industry more competitive.
Speed-ups Production Time: Robotics speeds up production and helps manufacturers increase output.
Offers Task or Process Flexibility: Robotics can weld, cast, mold, assemble, machine, transfer, inspect, load, and unload items, among other duties. So, it gives the manufacturer process flexibility.
Reduces Excessive Use and Waste of Production Materials: Robotics employs the exact quantity of material required for the manufactured product, reducing waste and overuse of materials.
Offers a Safe Working Place: Robotics improves employee health and safety by performing tasks that humans find risky. For example, in the chemical industry, a human employee may not do a hazardous task. In such instances, robots can replace people.
The rise of the robotics industry has accelerated dramatically, and it is now spreading its wings across industries. Research firm IDC provided a projection for the commercial robot market, forecasting that the market will exceed $53 billion by 2022, with a compound annual growth rate of more than 20%. In addition, several advantages of robotics such as safety, productivity, uniformity, and perfection are pushing its expansion and making it an essential element of industry 4.0.
Why are robots the future of the manufacturing industry?
The use of robots in manufacturing has improved process efficiency and product quality. As a result, robots are gaining favor in production and becoming the future of manufacturing.
Which industries make the most use of robotics?
Healthcare, agriculture, food, and manufacturing are the industries that are embracing robotics to get the most out of it.
How is manufacturing utilizing robotics?
Manufacturing uses robotics for repetitive tasks. This helps in the reduction of errors and human efforts. It also improves production efficiency.
"name": "Why are robots the future of the manufacturing industry?",
"text": "The use of robots in manufacturing has improved process efficiency and product quality. As a result, robots are gaining favor in production and becoming the future of manufacturing."
"name": "Which industries make the most use of robotics?",
"text": "Healthcare, agriculture, food, and manufacturing are the industries that are embracing robotics to get the most out of it."
"name": "How is manufacturing utilizing robotics?",
"text": "Manufacturing uses robotics for repetitive tasks. This helps in the reduction of errors and human efforts. It also improves production efficiency."
Article | December 30, 2021
Risk management in manufacturing has always been a top priority for manufacturers to avoid any unfortunate incidents. As a result, it is possible to create a more secure work environment for employees by conducting risk assessments and implementing remedies.
“If you don’t invest in risk management, it doesn’t matter what business you’re in, it’s a risky business.”
– Gary Cohn, an American Business Leader.
As of 2019, the worldwide risk management market was valued at $7.39 billion, and it is expected to rise at a CAGR of 18.7% from 2020 to 2027, according to allied market research.
Why is Risk Assessment Critical in Manufacturing?
The manufacturing industry must have a credible risk assessment and management plan to defend itself from any breaches. Risk assessment helps firms understand the dangers they face and their implications if their systems are compromised. Hence, risk assessment is very critical in the manufacturing industry.
Five Risk Assessment Principles
Identify hazards/risks - Employers must examine their workers' health and safety risks. Therefore, an organization must regularly inspect its employee’s physical, mental, chemical, and biological threats.
Identify who may be hurt and in what way – Identifying the personnel both full-time and part-time at-risk. Employers must also examine threats to agency and contract personnel, visitors, clients, and other visitors.
Assess the risks and act accordingly - Employers must assess the likelihood of each danger causing injury. This will evaluate and lower the chance at the working space. Even with all safeguards, there is always some danger. Therefore, employers must assess if danger is still high, medium, or low risk.
Get the Risks Documented - Employers with five or more employees must record the critical findings of the risk assessment in writing. In addition, register any risks identified in the risk assessment and actions to minimize or eliminate risk.
This document confirms the evaluation and is used to examine working practices afterward. The risk assessment is a draft. It should be readable. It shouldn't be hidden away. The risk assessment must account for changes in working techniques, new machinery, or higher work objectives.
5 Manufacturing Risks to Consider in 2022
Accidents at Work
Even if official safety policies and programs are designed, followed, and enhanced, manufacturers may endure workplace accidents and injuries. Risk assessment for workplace accidents assists in mitigating the negative impact on both employees and the organization.
Manufacturers have distinct issues regarding fuel handling and hazardous waste disposal in facilities. Sudden leaks or spills may be extremely costly to clean up and result in fines from state and federal agencies. Risk assessments for such plant accidents assist businesses in mitigating financial losses.
Essential machinery throughout the production process might fail at any time, incurring significant repair or replacement costs. Therefore, it's critical to recognize that business property insurance may not cover mechanical issues.
Risk assessment and prepayment solutions protect against equipment failures without interfering with typical company operations.
Supply Chain Disruption
Dependence on your supply chain may result in unintended consequences that are beyond your control. For example, if you experience downtime on the manufacturing line due to a supplier's failure to supply materials or parts, you risk losing revenue and profitability. If a disturbance to your supply chain poses a hazard, risk management can assist you in managing it more effectively by quickly identifying the risk and providing a suitable response.
Operation Temporarily Suspended
Depending on the severity of the weather event, a factory might be severely damaged or perhaps utterly wrecked. While major repairs or rebuilding are being undertaken, recouping lost income might be vital to the business's future profitability.
Risk assessment in this area enables your organization to budget for overhead expenditures such as rent, payroll, and tax responsibilities during the period of suspension of operations.
Risk management is critical in manufacturing because it enables manufacturers to comprehend and anticipate scenarios and create a well-planned response that avoids unnecessary overhead costs or delays in delivering the production cycle's final result. Manufacturing risks are undoubtedly not limited to the risks listed above and may vary according to the nature of the business and regional environmental conditions. Therefore, create a well-defined strategy to overcome threats in your business and be productive at all times.
How are manufacturing business risks classified?
In most cases, the business risk may be categorized into four types: strategic risk, regulatory compliance risks, operational compliance risks, and reputational risks.
Why should a manufacturer conduct a risk assessment?
Every manufacturing employment has risks for injury or illness. But risk evaluations can significantly minimize workplace injuries and illnesses. In addition, they assist companies in discovering strategies to reduce health and safety risks and enhance knowledge about dangers.