In 2023, a total of 41.76 billion IoT or Internet of
Things-connected devices are anticipated to be deployed, per ReportLinker. As
per Guidehouse Insights’ estimations, The global market for IoT in
manufacturing is set to grow to $23.1 billion by 2031, growing at a compound
annual growth rate (CAGR) of 15.0%. Industry 4.0 is here, set to boost
competitiveness across companies.
A McKinsey research reveals IoT is poised to deliver $1.3
trillion in economic value to the manufacturing sector. Among these also is
standardized production settings, but requiring scale for ensuring thorough
capture.
McKinsey research also states IoT’s potential global
economic value to unlock by 2030 could be $5.5 trillion to $12.6 trillion. But
barriers exist, in the form of machinery upgrade costs, investment optimality,
and cybersecurity
risks.
The ultimate Industrial Internet of Things or IIoT
applicability lies in the manufacturing sector. Production lines and industrial
machines’ productivity could massively boost with internet connectivity and
sensors, monitoring production. These could include monitoring temperature,
humidity, noise, or vibrations.
Let’s examine the various IIoT trends in manufacturing:
Transforming IoT Business Model
Industrial IoT Solutions are appealing as they enhance
factory performance via augmented output, whilst also bettering key business
metrics. IoT is an automation catalyst, allowing manufacturers to transform
business models with innovation. The approaches on which IoT works include
the product, the supply chain, and the manufacturing. Championing these three
aspects would enable charting a crystal-clear smart IoT adoption strategy.
Predictive Maintenance & Performance Tracking
Big enterprises have heavily invested in their IoT and IIoT
infrastructures in 2022. In 2023, much attention would be directed toward
predictive maintenance and performance tracking in products and plants.
In today’s advanced industrial environment, factories are
even looking forward to lights-out manufacturing (total automation). IIoT
solutions and deep analytics software today can enable end-to-end production
processes’ performance tracking by manufacturers. Novel machine learning (ML)
technologies have facilitated predictive performance tracking capabilities via
sensor-collected big data analyses.
ML can also facilitate performance tracking to get better
with time, enabling industries to operate for sustained periods without human
oversight.
Equipment downtimes in production environments result in
out-of-the-blue delays and subsequent losses. So, smart operational schedules
are a must for efficient execution and asset availability. That’s when
predictive maintenance can considerably decrease machine failures and power
outages, boosting overall asset life.
Use predictive maintenance to enhance asset life-cycle,
reduce maintenance costs and time, and decrease machine breakdown to enhance
equipment monetization It also allows a reduction in accidental malfunction to
strengthen workers’ physical safety.
Augmented Reality (AR) and Virtual Reality (VR)
AR (Augmented Reality) and VR (Virtual Reality) can be
accessed to experience immersive training, remote
assistance, and collaboration. Instruction manuals’ digitization via AR and
VR is the next frontier in redefining industrial technologies.
Capitalizing on the prospects presented by data exploration,
Virtual and Augmented Reality can minimize waste in industrial processes. VR
and AR can be easily integrated with IoT. Together these technologies can reap
tremendous benefits. Such breakthroughs can come in the form of higher profits,
exploring fresh growth avenues via new products or services, decreased costs,
etc.
AR acts as an enhancement of the user’s surroundings via the
addition of digital components in a live environment. VR replaces real-life
environments with simulated ones as the user is completely immersed in a digital
environment. In the manufacturing sector, VR and AR can be leveraged to make
available designs, organize manufacturing lines, sharpen ideas, and remote
machinery interaction. If in the building process either of the steps is
omitted, its identification is possible via AR and VR.
AR and VR can be integrated in these ways with IoT:
Asset Management: Equipment know-how, performance, and health
data are collected via IoT sensors to transform these into their virtual form.
By doing so, real-time visualization of breakdowns and crashes is possible.
Space Management: The AR technology optimizes inventories in
factories or warehouses, developing optimal routes for workers to navigate
across facilities.
Employee Training: AR allows manufacturers to develop
virtual prototypes of products for integration with IoT data. By doing so, it
can develop a simulation wherein your employees can learn machines’ optimal
usage.
AR and VR can guide technical work by offering real-time
instructions. These technologies can also facilitate technical support on a
remote basis, making training experiences real. AR can analyze machine
environments’ problems. Computer vision in AR can give a map of machines,
allowing highly-skilled laborers to witness real-time manufacturing processes’
stats.
Big Data Insights to Boost Optimization
IoT technology essentially collects data. Industrial Big
Data, for that matter, is a central aspect of Industry 4.0. A smart factory
operates at its optimal level owing to an accurate collection and the finest
analyses of data. There are also several challenges presented by Big data, such
as the efficient collection of the required data (via IoT analytics) and
attributing to it enough value (via integrating artificial intelligence). The
availability of Big Data can make available deeper insights. Unlike traditional
technologies, a multitude of production or supply chain aspects can be tracked
via IoT devices. So, IoT is crucial from the Big Data and manufacturing
perspective.
Edge Computing
The edge computing trend is eagerly looked forward to by the
manufacturing industry as an enabler of automation implementation in factories
and supply chain processes. Edge computing can enhance manufacturing processes
via advanced robotics and machine-to-machine communication. Edge computing
essentially involves various networks and devices surrounding the user to
process data as near to its area of generation as possible at high speeds and
volumes. The outcome of this is a result-oriented action plan in real-time. In
manufacturing, via edge computing, several local edge network factory devices
can enable processing with no need to send data (to a local server first). Edge
computing is speedy, highly efficient, and indeed secure.
There is no need in edge computing for the sensitive
manufacturing data to leave (for distant server processing) the factory
premises. So, there is a reduced risk of hiccups or third-party intrusion.
Enterprises of today can boost their business prospects via the integration of
edge computing and AI, to develop Edge AI.
This way, edge computing facilitates undertaking AI
computation close to the user at the onset of the IoT network, instead of on a
cloud. So, enterprises can attain real-time intelligence in industrial
operations, strengthen privacy and cybersecurity, contain costs, and better
manufacturing processes.
Conclusion
Manufacturing industry solutions based on IIoT are poised
for stupendous growth with efficient asset
management and monitoring, predictive maintenance for reduced machine
breakdown (via performance tracking), and boosted workplace safety.
Entrepreneurs can look forward to profitable business with IIoT transforming
business models.
The Wall