infinite-uptime
Infinite Uptime
Infinite Uptime is a global Predictive Maintenance Services and Plant
Reliability
solutions company. We help the maintenance and manufacturing teams to
attain the highest level of plant reliability by reducing unplanned
downtime,
mitigating operational risks, and improving overall efficiency.
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The Future of Maintenance
in the Metal Industry
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IIoT-based predictive maintenance – A mission critical need for manufacturing
Industry 4.0 continues to gain momentum across every industrial and manufacturing segment. This revolution is built upon three primary technologies: Big Data, Edge Computing and the Internet of Things (IoT). As the adoption of IoT devices continues to grow, many organizations are switching to edge technology because of its advantages over legacy cloud solutions. One of the key advantages of edge computing is real-time predictive maintenance. In a predictive analytics solution, Artificial Intelligence (AI) is combined with Business Intelligence (BI) to monitor the operating condition and predict when to perform maintenance on that asset.
What is Predictive Analytics?
Predictive analytics uses statistical algorithms and advanced analytics combined with AI techniques to predict future outcomes based on historical and current data patterns. Organizations use this method to benefit possible future events by using predictive modelling to take maintenance decisions before a disruptive event. This technique imports data from the targeted asset synthesizes it and combines it with different data sources. Once a large amount of data is cleaned, the data analysis is initiated to recognize patterns and trends. In simple words, using Artificial Intelligence and Machine Learning technique, a machine can predict future events.
What is Predictive Maintenance?A subset of predictive analytics, predictive maintenance is the process of utilizing data analysis to predict future outcomes. This technique is used to recognize potential faults in machines and processes. Manufacturing and service industries need to improve the performance of their assets. As per the report by a leading publication, spending on IoT-enabled predictive maintenance will reach 12.9 billion by 2022 compared to $3.4 billion in 2018.
Benefits of Predictive Maintenance:
An AI-enabled predictive maintenance solution comes with numerous competitive advantages as compared to legacy maintenance processes.1. Improved Machine Lifespan:By identifying problems, machines can be serviced even before the problem occurs. Also, with a constant study of the machine, the AI solution prevents any significant damage from occurring, consequently improving the overall health of connected equipment and uptime its average lifespan.2. Increased Production:With the ability to constantly monitor a machine’s performance, one can avoid unscheduled downtimes and improve operations throughput. This not only improves the machine’s health but also enhances the quality of the production.3. Minimize Maintenance Costs:With the help of IoT sensors, it becomes easy to detect anomalies and repair them before the problem becomes irreversible. This minimizes the chance of operational setbacks due to unplanned machine downtime. A report by McKinsey suggests that a predictive maintenance application can minimize maintenance costs by 25%. On the other hand, Deloitte believes it can reduce machine breakdowns by 70%.4. Reduction in Downtime:A predictive maintenance solution can cause approximately a 45% reduction in downtime. The analytics provide insight on faults and require repairs so you can schedule them accordingly. This helps companies to effectively optimize their resource schedules or schedule maintenance outside of operation hours.5. Improved Benefits:The data collected from the IoT-based solution helps businesses make practical and calculative decisions regarding machine management. This can improve manufacturing value by enhancing the overall equipment effectiveness and the production volume. This can also decrease replacement or repair costs. Businesses are leveraging IoT-based predictive maintenance to improve value and minimize costs.
The Future of Predictive Maintenance
Although cloud computing can support predictive analytics systems, organizations gain a crucial advantage by refining data analytics and processing speed and performance through edge computing. A predictive maintenance solution performed at the edge minimizes data storage costs along with real-time analytics and low latency. IoT devices and sensors gather data frequently, meaning these IoT-enabled solutions work with enormous data.
When we implement such solutions through cloud computing, vast data gets shared over the network to the cloud. While the load on the internet continues to grow, the cost of networking will increase as well. Predictive maintenance solutions, run on the edge analyze the data on-premise in real-time to minimize the amount of data shared on the cloud, saving businesses money on cloud storage costs.
About Infinite Uptime
Infinite Uptime is transforming the industrial health diagnostics space with a Digital First approach. We provide comprehensive solutions around Machine Diagnostics, Predictive Maintenance and Condition Monitoring to the top engineering and process industries globally. We promise to deliver maximum Machine Uptime, minimize Factory Disruption and elevate Equipment Reliability for a stellar factory performance.
Infinite Uptime leverages IoT, machine learning, artificial intelligence, smart communications, cloud computing, analytics and data science techniques to accelerate digital adoption and turn Industry 4.0 into a business reality. To know more about us and our customer success stories, please visit www.infinite-uptime.com or write to [email protected].
This blog is referenced from : https://www.infinite-uptime.com/iiot-based-predictive-maintenance-a-mission-critical-need-for-manufacturing/
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Impact of Industrial Analytics in Fostering Manufacturing Transformation
If data is oil, manufacturing is the brightest lamp powered from it. Manufacturing is expected to generate 1812 Petabytes (PB) of data every year, a lot more than BFSI, healthcare & many other industries, according to Deloitte. Industrial Analytics today are helping optimize every facet of manufacturing by enabling proactive decision making & automation across organizations through the access of the right data to the right people on time.
What does Industrial Analytics exactly do?
Industrial Analytics collects, analyses, and uses data generated in industrial operations through machines, processes, and people.
Traditionally Manufacturers have always been using data to improve their efficiency & machine health for years. But what has changed now with technologies like IoT is how the data is captured. In the past, data collection was done manually, with plant operators recording data or feeding it in a machine. But these approaches are flawed- they are time-consuming and prone to human errors and biases. This data is still grassroots and not actionable for decision-making, particularly at a senior level. With digital transformation, tons of strategically placed sensors capture every critical machine data, recorded and analyzed in real-time. The level of insights that emerge is actionable for every level.Here is how industrial analytics is transforming various use cases in manufacturing, improving the efficiency and productivity of machines, processes & people:
In a hyperconnected world, manufacturing processes and supply chains are getting increasingly extensive and complicated. Industrial Analytics enable manufacturers to hone in on every stage of the manufacturing process and study supply chains in minute detail, accounting for individual activities and tasks. Based on machine health, inventory status, forecasting of orders, preparation, and choice of suppliers can be made in advance.
IReduce Downtime
Manufacturers can extend the life of critical assets by using data to predict when they will fail. Predictive maintenance systems today collect past data to produce insights that aren’t visible using traditional methods. For example, companies may utilize industrial analytics to identify the conditions that may cause a machine to malfunction and monitor input parameters to act before the equipment breaks or be prepared to replace it when it does, reducing downtime. Factors like Misaligned shafts, lubricant oil contamination and excessive vibrations can result in unplanned downtime if not controlled in time. Technologies like Infinite Uptime’s IDAP can allow plant managers to track these in real-time and predict anomalies with a prescribed solution, effectively minimizing planned and unplanned downtime.
Since machine downtime can cause a loss of around $260,000 an hour per hour for a manufacturing company, this is one of the most critical use cases for industrial analytics.
Productivity & Production process improvement
Improved workforce productivity and processes can be measured, monitored and optimized with suitable parameters via industrial analytics. With the efficiency of machines and processes in place, operator efficiency performance can be mapped to benchmarks to identify techniques that cause a decrease in operator performance at various stages of production.
On the other hand, Manufacturers can detect bottlenecks and inefficient processes and components that are causing them. Industrial analytics also reveals interdependence between different processes and their outputs, allowing producers to consider each process separately, improve manufacturing processes, and devise predictive maintenance procedures to address any stumbling blocks.
Drive machine OEE improvement
OEE improvement is a crucial metric for shopfloor performance. With effective Manufacturing analytics in place, components like asset utilization, efficiency, product quality rating and runtime for every machine can be tracked. This information in real-time can enable manufacturers to figure out the machines causing the bottlenecks in reaching the planned OEE. Mapping these key performance metrics at a plant level can help top-level decision-makers to make changes at an asset and process level to take the OEE to the planned level.
For the plant head & manufacturing head for multiple plants, it is easy to track performance vis-a-vis assets and entire plants to find what is performing well and what can be improved.
Reduce Manufacturing Errors
Industrial analytics can assist in reducing errors in manufacturing processes, operators and machines, improving the quality of the output.
For example, a perfectly aligned machine can perform at its best, producing quality output. Infinite Uptime’s IDAP helps ensure the machine is correctly aligned at all times and functioning at its optimal capacity.
With predictive & prescriptive industrial analytics, any potential downstream quality or equipment issues can be detected. Corrective action can be taken to salvage the quality, and in the case of discrete manufacturing, an intermediate product can be discarded to save further losses.
Conclusion
Industrial Analytics can thus be the key to unlocking hidden potential and business value in various parts of your manufacturing process.
Want to realize the potential of your manufacturing data? Reach out to us at [email protected] to set up a call with our team of experts.
This blog is referred from : https://www.infinite-uptime.com/impact-of-industrial-analytics-in-fostering-manufacturing-transformation/
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Complying with ATEX standards in hazardous environments. Why does it matter?
Manufacturing facilities are no less than war zones – they have difficult workplace conditions like explosive atmosphere, flammable & toxic gasses and combustible substances. A few more hazardous than others are like Oil & Gas, Petrochemical, Chemical plants & Power plants. Such a high-risk workplace environment is safeguarded by mandatory health & safety risk assessments, certifications, safety gear, rules & regulations. It ranges from what kind of devices can be used on-site to the gear worn by the workers.
An ATEX certification for your equipment can be a gamechanger. This article tried to address the most common questions around ATEX certification.
What is an ATEX Certification?
ATEX stands for
AT
mosphere
EX
plosible.It certifies equipment & protective systems intended for use in potentially explosive atmospheres. It categorizes equipment based on its protection against turning into an active ignition source. Here are the two European Directives for certifying equipment that is declared ‘intrinsically safe’ in the explosive atmospheres:
Directive 1999/92/EC (also called ‘ATEX 153’ or the ‘ATEX Workplace Directive’)
Directive 2014/34/EU (also called ‘ATEX 114’ or ‘the ATEX Equipment Directive)
The ATEX 2014/34/EU is the new accepted safety standard for testing & certifying equipment intended to be utilized in potentially explosive environments in the EU, post a 2015 Legislative change.
The ATEX certification covers explosions from flammable gas/vapours and combustible dust/fibres (which can also lead to explosions)
Here are how zones for flammable gas/vapour (a potentially explosive atmosphere consisting of air with a mix of toxic substances in the form of mist/vapour/gas) are classified for ATEX certification:
Zone 0 – A place where a potentially explosive atmosphere is present continuously or for long periods.
Zone 1 – An area in which a potentially explosive atmosphere is likely to occur occasionally.
Zone 2 – A place where a potentially explosive atmosphere is not expected to occur usually, but if it does happen, it will persist for a short period only.
Identifying an ATEX certified Equipment
If equipment has an official ATEX certification, it has been completely certified to be safe for being used in hazardous/explosive atmospheres. ATEX approved equipment can be identified by the official ‘Ex’ logo shown in the image above.
Any equipment without Atex certification must not be brought onto site in manufacturing facilities with an explosive atmosphere to prevent any probability of disasters.
Why is ATEX Certification challenging to achieve?
For a product to be ATEX certified, it must undergo rigorous tests quality checks for weeks & even months in various test conditions. Even after the certification is processed, quality assurance, compliance checks, and audits are conducted to ensure that the product complies with the stringent benchmarks.
Once the certification is provided to a product, even a tiny tweak or alteration to the product in any form can render the certification null & void.
Is an ATEX Certification applicable across the globe?
Although initially constituted by the European Union for its member states, the ATEX certification is slowly gaining global acceptance as a preferred standard for accepted devices in potentially explosive atmospheres. OEMs with ATEX Certifications now find interested buyers even outside the EU, and it is predicted that it may one day become the globally accepted standard.
Conclusion
If you are looking for equipment to be used in a plant with a potentially explosive environment like the industries mentioned above, then looking up an ATEX certification first will go a long way in finding reliable equipment.
At Infinite Uptime, we very well understand the importance of HSE initiatives in manufacturing and how every small bit of diligence is critical to ensuring a risk-free environment & safety of the workers. To this end, we are delighted to share that vEdge, our edge computing technology that enables our Diagnostics Service, has received a Zone 0 ATEX Certification from the International Centre for Quality Certification (ICQC LLC), Latvia. Here is the ATEX-Certification for our vEdge. Want to know more about how vEdge can propel digital reliability even in the most difficult environments?
Reach out to our team at [email protected]
This blog is referenced from : https://www.infinite-uptime.com/complying-with-atex-standards-in-hazardous-environments-why-does-it-matter/
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Predictive Maintenance as a Service for Cement Industry: An Overview
These processes & machines need to occur in tandem, without intervals, to create high-quality cement. Unplanned downtime in even one of these machines can unleash havoc on the ongoing process, not just endangering efficiency & quality but also health & safety of personnel on-site.
The cement manufacturing industry is one of the oldest and most critical manufacturing industries for the global civilization. It has witnessed unparalleled growth at the heart of most economic developments and international growth this decade. Fortune Insights report says, the global cement market will grow from $326.80 billion in 2021 to $458.64 billion in 2028, a steep 5.1% globally. It is then no wonder that cement plants face pressure for process and asset maintenance.
CEMENT MANUFACTURING PROCESS & NEED FOR PREDICTIVE MAINTENANCE
Cement manufacturing is one of the most complex continuous manufacturing processes, with multiple ingredients & steps involved. Here is an overview of the entire process wrt machines used at each stage:
Predictive Maintenance checklist for cement industry:
Extractors: Used to Quarry the raw materials, i.e. limestone & clay
Crushers used to crush high rock piles into coarse powders called raw meal
Blenders & Mixers mix the crushed raw meal in the right proportions
Grinders to further grind the raw material to free different minerals in the ore
A rotary kiln where the raw meal is heated up to 1450 degrees & then cooled
Assembly belts & conveyors to carry the cement for packing & dispatching to customers
These processes & machines need to occur in tandem, without intervals, to create high-quality cement. Unplanned downtime in even one of these machines can unleash havoc on the ongoing process, not just endangering efficiency & quality but also health & safety of personnel on-site.
Common causes for machine downtime in a cement plant
Loose nuts, bolts, springs, plates, spring rods, flywheel, bearings, shaft, coupling housing, hammer rotor
Motor failure, Conveyor belt, breakage, bearing failure, stretching rod breakage, breakage of separator blade
Fan bearing breakage, fan unbalance
Gear knocking, gear tooth wear, gear deformation, gear spitting and spalling
Axle spindle breakage, crusher bearings failure, slip tape breakage
Disc liner shift
Rolling mill cracks, tubing failure, pump failure, spoke breakage
Grate plate breakage
Why asset maintenance in cement plants is a necessity?
Asset maintenance in cement plants is critical because:
Extensive repair & replacement costs
Chances of industrial safety hazards & accidents
Over maintenance of equipment, causes wear & tear
Harsh operating environment
Dynamic environment, needing proactive decision making
Enable remote monitoring & control for agility & resilience to
How can Predictive Maintenance as a Service help?
With the stakes so high and a constantly changing environment, real-time machine diagnostics are necessary to empower plant managers with the correct data. IIoT can enable this by enabling a 360-degree view of interconnected assets across the plant. Predictive maintenance as a service allows plant managers in cement managers to move away from reactive measures like reactive maintenance and preventive maintenance to a predictive one, where critical machines don’t have to be pulled down unless there is a specific anomaly.
At a grass root level, predictive maintenance as a service by IU for cement plants can be implemented by putting sensors at strategic positions on the machines. Vibration analysis of mechanical equipment components like Air Compressors, Belt drives or Conveyors, Fans and blowers, Kiln rollers, Motor bearings & Vertical and horizontal mills can help predict anomalies.
The Predictive Maintenance as a service solution by Infinite Uptime involves collecting data, analysis & computing of the triaxial vibrations, temperature and noise of the mechanical equipment on edge at real-time via a patented edge computing system. The data then is monitored & analyzed in real-time, and a machine health score is assigned. A machine with a lower health score is flagged to the plant supervisor or plant engineer with a diagnostic assessment of the probable cause for the anomaly and a recommendation on improving the same. Not just that, if not considered severe yet, but still significant; the fault is continuously monitored, with relevant parameters like temperature, vibration etc., to assure that it does not aggravate the status quo. This information can be made available in real-time to the appropriate people at their fingertips. An access-based dashboard ensures that you get access to the most relevant machine data for the plant from single machine access for a plant operator to multiple machines across the plant access for a plant head and a multi-plant machine score for a manufacturing head. Let’s look at a
case study
around how we helped a top Indian cement manufacturer reduce 250 hours of downtime.
Conclusion
Today, the cement industry is on the cusp of digital transformation, fueled by rising demand and cut-throat competition and increasingly stringent regulations. The pressure on the cement industry’s assets, processes, and people to be on the top of their game has never been higher. In such a scenario, Predictive Maintenance as a Service for your cement plant can help avoid machine failures and the associated unplanned downtime and the quality of the output cement and the OEE (Overall Equipment Effectiveness) of the cement plants. It improves machine availability and performance, also saving costs for repairs & spare parts. But most importantly, it arms you with resilience & agility during unpredictable times via remote monitoring and proactive maintenance when needed the most.
This blog is referenced from : https://www.infinite-uptime.com/predictive-maintenance-as-a-service-for-cement-industry-an-overview/
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Predictive Maintenance as a Service: A game-changer for Manufacturing.
Manufacturing encompasses a diverse and wide array of processes, industries, and raw materials. Yet all manufacturers everywhere share a common enemy: Unplanned Downtime, which harms productivity, asset health, brand reputation & dotted line.
Every year, top fortune 500 manufacturing enterprises lose almost 1 trillion to unplanned downtime, nearly 8% of their annual revenue. Here is how the introduction of Predictive Maintenance as a Service can be a gamechanger in the world of manufacturing & asset maintenance to curb unplanned downtime.
But to understand why Predictive Maintenance as a service is so revolutionary, let’s understand how asset maintenance was performed until a few years ago:
What are the types of Asset Maintenance practices in Manufacturing?
Reactive Maintenance:
Reactive Maintenance means letting your machines run unchecked till they fail. Maintenance here is post-failure, as a reactive approach after the anomaly. While it saves you unnecessary downtime & maintenance costs for parts that don’t require servicing, it also means you risk machine failure anytime by being blind about your machine health.
Planned Maintenance or Preventive Maintenance:
After the reactive maintenance approach resulted in constant fire-fighting for the plant manager, maintenance became a time-based activity, i.e., annual, bi-annual, based on their own and peer’s experiences. But often, it was noted that a planned downtime, although revealing nothing wrong with the asset, would still result in loss of productivity & profits. And sometimes, the machines would fail even before the planned period, so the problem persisted.
With the failure of both of these approaches to curb machine failure and thereby unplanned downtime in time, the industry looked forward to solutions like IoT & AI to power up maintenance with real-time insights. And that is what predictive maintenance as a service is all about.
Predictive Maintenance as a Service:
Predictive Maintenance (PdM) relies on real-time monitoring of machine health using smart technologies like edge-computing, IIoT, data science, and analytics. Once an anomaly (w.r.t vibration, temperature, or acoustics) is detected, it is flagged off to the relevant plant supervisor for the next immediate action. A maintenance activity can thus be scheduled if something goes wrong while the maintenance expert can also decode the exact ‘something’. PdM enables the maintenance teams with necessary controls to extend equipment lifecycle, optimize the cost of maintenance, maximize machine uptime and amplify factory performance.
Types of machine maintenance in mining What Industries can Predictive Maintenance as a Service make the most impact on?
While any manufacturing plant- whether discrete or process-based can deliver a clear impact with Predictive Maintenance as a Service measures, the process-based manufacturing plants can truly thrive because of their unique workflow of interconnected processes.
Since the output of the process manufacturing plant depends on the previous steps completed in tandem, the stoppage of even a single machine can halt the entire production process. This is where predictive maintenance as a service can help by ensuring that the machine health issues are taken care of before they become serious.
Here are some examples of plants where Predictive Maintenance as a Service can save the day:
Cement plants
Steel plants
Metals & Mining
Oil & Gas Refineries
Power plants
Chemical plants
Pharmaceutical plants
Petrochemical plants
How can Predictive Maintenance as a Service be a gamechanger for Manufacturing?
Predictive Maintenance as a Service brings all the benefits of cutting-edge technology without the financial downside of capital intensiveness and sustainability. Here is how it can do magic for manufacturing plants:
Asset health & performance:
In an asset-intensive industry like manufacturing, where the equipment is costly and used to the extreme, equipment & component replacement costs are prohibitively high. You can boost asset life, RUL (Remaining Useful Life), and Machine Uptime & Reliability by tackling asset issues before they get serious.
EHS & Compliance benefits:
Manufacturing plants consist of the most demanding working environments with toxic gases, material, and dangerous machines working furiously. It is no wonder that the regulatory guidelines get stringent now and then. It is also a risky working environment for the operators and other employees. Predictive maintenance as a service policy ensures no untoward accidents or compliance issues. Read more on our ATEX Certification.
OEE:
Standing for Overall Equipment Effectiveness OEE is a globally prevalent metric that measures the productivity of a manufacturing asset. Calculated as a product of equipment availability, performance & quality of output produced, OEE is a benchmark for comparing the productivity of plants. The availability & performance of the machine depends on the maintenance & servicing when it is needed. According to a Deloitte study, a regular PM results in high OEE, Uptime & Reliability, compared to all types of maintenance.
Quality & Brand reputation:
Regular Asset maintenance and machine health analysis can ensure that the machine performs at the top of its capacity. This will provide a high quality of the overall output. A fully functional plant producing quality output with minimal disruptions will also ensure a good brand image & reputation in the ecosystem.
Increased Employee Productivity:
A well-functioning asset means that employees don’t have to fight fires caused due to last-minute machine failures. It also means quality and timely output, allowing them to be productive at what they do.
What Infinite Uptime’s Predictive Maintenance as a Service brings to the table?
The end-to-end Predictive Maintenance as a service by Infinite Uptime involves collecting data & computing the triaxial vibrations, temperature, and noise of the mechanical equipment in real-time via its patented edge computing system. The data is then monitored & analysed in real-time, and a machine health score is assigned. A machine with a lower health score is flagged to the plant supervisor or plant engineer with a diagnostic assessment score and the probable cause for the anomaly and a recommendation on improving the machine. This helps the maintenance teams to plan better and save critical downtime of machines which positively impacts the overall factory performance and productivity.
Conclusion
With real-time insights from interconnected assets being monitored and analysed instantly, predictive maintenance as a service provides massive power to the manufacturers without any drawbacks of a conventional maintenance solution. And that is when the true digital transformation will happen when data and insights combine to provide value.
This blog is referenced from : https://www.infinite-uptime.com/predictive-maintenance-as-a-service-a-game-changer-for-manufacturing/
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Predictive Maintenance as a Service for the Steel Industry.
Introduction:
The steel industry plays an essential role in developing the economic standing of any country. Since steel is a necessary component for every primary sector, to keep the country’s economy in full bloom, steel factories need to ensure that all production processes are running smoothly, which can be hindered by unplanned downtime.
Unexpected downtime can cost not just a lot of money and time for any steel plant but can also affect the production and growth of downstream industries dependent on steel production. Machine availability and reliability being the top concern in steel production, the cost of secondary damages of such breakdowns can be astronomical. This can significantly affect the quality, operational efficiency, loss of productivity, and increased risk of accidents on site. With such high stakes, using predictive maintenance to avoid unexpected downtime can be a gamechanger for steel plants.
What are the Challenges in Steel Manufacturing Industry?
PROCESS LEVEL CHALLENGES:
Steelmaking involves many manufacturing techniques which are time-consuming and complex. Apart from primary production processes, there are many sub-processes where the intermediate products are reheated, solidified or pressed into various forms, like pipes, sheets, bars, rods, and different structural shapes based on the requirement.
The primary steel manufacturing process is continuous and process-based, whereas the secondary manufacturing phases are discrete. What complicates it further is the fact that:
Production process parameters from the upstream steel manufacturing processes strongly influence the downstream ones.
The intermediate products in the process undergo both chemical and mechanical changes, making monitoring quality and output more difficult.
PLANT LEVEL CHALLENGES:
While steel manufacturing is already a complex process, steel plants may also face many on-ground challenges in maintaining efficiency, such as:
Older & legacy machinery
Frequent halts in production due to machine failure & downtime
Expensive coal & raw materials
Avoiding unexpected accidents on site
Various external factors like lockouts, strikes, inefficient administration, and shortage of raw materials
What is Predictive Maintenance?
Predictive maintenance is the next level of condition-based maintenance that regularly monitors the operating condition and health of machines through edge computing. It helps predict asset issues before they occur, thus not disrupting the manufacturing workflow, reducing accidents, and improving the machine’s overall availability & reliability.
The data from the edge computing systems continuously provide results in real-time to alert you of machine performances and machine breakdowns. It also alerts you of maintenance based on what machine data indicates, which helps to avoid any unexpected repair costs.
Advantages of Predictive Maintenance for Steel plants
Reducing downtime and Ensuring asset longevity & RUL:
Failure of machines can be pretty stressful and is an added expense. Using predictive maintenance, you can predict issues ahead of time, reduce downtime of machines, increase uptime by 15-20%, schedule maintenance as and when required, and thus improve the lifeline of the old machine by up to 20%.
Reducing maintenance costs
Since all the machines in the steel manufacturing process are constantly monitored and fixed before the problem gets severe, maintenance and spare part costs are way lower than what they would be for reactive maintenance or preventative maintenance. There is also no need for unnecessary planned downtime.
Improving Workplace safety
Predictive maintenance can lower the risk of workplace accidents by flagging off any anomalies that can trigger off an accident on site. Predictive maintenance ensures a hygienic and healthy environment in the plant and reduces safety risks by up to 14%.
Enhancing productivity
By ensuring that both planned downtime & unplanned downtime are at their minimal, predictive maintenance ensures that there are fewer disruptions to production, improving the overall productivity drastically.
How Does Infinite Uptime’s Predictive Maintenance as a Service Solution Work for Steel Industry?
Infinite Uptime’s Predictive Maintenance as a Service uses real-time data to find out the status of the machine and the health of every rotating asset. The edge computing system is deployed to monitor all critical assets in every process and monitors parameters like vibration, temperature, etc. A machine health score is provided in real-time for every monitoring location. Anytime there is a dip between the prescribed machine score, an alert goes to the plant supervisor, along with a recommended remedial action suggested by our Predictive Maintenance as a Service solution. The machine status is further analyzed to ensure that the mitigated solution has improved the status quo.
Customized dashboards for different levels like plant operator, manager, plant head, or manufacturing head (multi-plant) are created & made accessible for the team to ensure agile & proactive decision making to ensure the production continues smoothly.
Conclusion
The steel industry is the linchpin of global economic development. Any unplanned downtime or production stoppage can jeopardize the steel manufacturers and manufacturers of all the industries that rely on it.
Predictive maintenance can be a value-added service for steel manufacturers. With the right Predictive Maintenance solution on your side, you can avoid extra costs, reduce downtime, increase productivity and focus your time and efforts on your business instead of worrying about unexpected downtimes or machine failures.
Want to learn more about how we have helped large global steel manufacturers avoid downtime & improve factory performance? Click here to read a case study.
This blog is referred from : https://www.infinite-uptime.com/predictive-maintenance-as-a-service-for-the-steel-industry/
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Decoding IT/OT Convergence: A Guide on Understanding IT and OT
As IoT grows synonymous with digital transformation & advancements in manufacturing, it has also led to a wave of change on the shop floor. This is a significant result of IT/OT Convergence, which led to faster decision-making, better collaboration, and a single source of truth across the organization.
But what does the IT/OT Convergence do with IoT, though? How are IoT, Information Technology (IT), and Operational Technology (OT) connected? For starters, they have the same three letters appearing in some sequence in all three abbreviations, but what more do these three have in common?
It’s essential to understand these terms before analyzing the IT/OT convergence.
What is Information Technology (IT) and Operational Technology (OT)?
Until IoT became a thing, there were two distinct worlds – traditional OT systems, which have machines, devices, and other industrial equipment, and more digital IT systems that handle everything related to computers, servers, storage, networking, and others. It’s been a while since the two worlds crossed over into one – IoT. To put this in simpler terms using an application of IoT, the smart devices in our homes today that are automated are a perfect example. These devices are part of a network that combines the prowess of both IT and OT systems to automate seemingly mundane human tasks like switching on and off lights. Now that we understand how IT/OT convergence happens, let’s look at IT/OT definitions with some jargon. As the name suggests, Information Technology (IT) includes computers, servers, and networking devices to create, process, store, and exchange all forms of electronic data in a secure manner. For a manufacturing environment, it can be hardware like laptops and servers and software for ERPs, inventory management, and other business-related tools.On the other hand, Operational technology focuses on managing and controlling physical devices operating globally. For manufacturing, it can include systems like MES, SCADA, PLCs, and CNCs that monitor & control the processes on the shop floor.
How does IT/OT Convergence help in Manufacturing?
Converging various aspects of technology is as old as technology itself. Integrating and interoperating different technologies can increase efficiency, cut down costs, and improve the workflows of multiple applications.
Earlier, the OT teams would handle everything that came under the purview of operations, keeping the plant running smoothly. On the other hand, the IT team runs business applications smoothly from the head office. They would only collaborate for one-off tasks like unplanned downtime, an untoward security incident etc., without any real collaboration.
The data for both teams was available in silos with no single source of truth-giving birth to communications issues, blind spots in processes and delayed decision-making. The OT machines, in particular, were only communicating with the world via niche M2M protocols, with data stored at disparate locations, available only in silos. This is where IT/OT convergence came in.
The IT/ OT convergence aimed to bring physical equipment (OT) into the digital world of IT. This was made possible, thanks to many advances in the tech industry, starting from Machine-to-Machine (M2M) communication, not to mention the increasing sophistication of IoT sensors and actuators that can be incorporated into OT equipment. Wireless communication over standard networking protocols allowed the data from each OT system to be communicated to a central server. The IT OT convergence allows for increased autonomy, maintenance, uptime, and accuracy of all the physical systems involved, with instant machine data access to the relevant stakeholders.
This convergence is focused primarily on automatic processes, using connected devices equipped with sensors to gather, send, and receive data. The data then is stored in a central platform, where it can be analyzed, monitored and actioned upon in real-time. This opens up a new realm of possibilities, where anyone with the know-how can develop APIs to analyze different devices and monitor, analyze & control their functioning.
Manufacturers Boon – The IoT Convergence
With IoT, IT/OT convergence in manufacturing has become a success story.
The convergence allows businesses and manufacturing entities to be more cost-efficient (or, more precisely, resource-efficient – be it costs, time or supply involved). With the sales and inventory data to optimize manufacturing operations, equipment and energy consumption is more efficient, while maintenance and the quantity of unsold inventory are reduced.
Here are some notable key benefits of switching to an IoT-enabled manufacturing environment.
Real-time decision making:IIoT (Industrial Internet of Things) allows manufacturers to collect all the data they would ever need and analyze it in real-time. Sensitive data can be analyzed directly at the source, which significantly reduces the bandwidth required, not to mention the increased levels of security.
Predictive Maintenance: One of the most significant benefits of IIoT is the revolution of predictive maintenance. Unplanned downtime can cause manufacturing entities to lose a substantial amount of money, while the traditional preventive maintenance method proves to be highly costly. The IT/OT convergence makes it possible for manufacturers to predict when the machines need maintenance and plan accordingly without unnecessary downtime or repair costs.
Increased Efficiency: Whether your manufacturing entity is looking to decrease annual energy costs, increase inventory turns, reduce the time to introduce a new PLC, decrease defect rates, or improve the overall effectiveness of the physical machinery involved – IT/OT convergence can help your business do it all.
Phases of IT/OT Convergence
There are three primary phases of IT/OT Convergence.
Process convergence – Deals with the intersection of workflows, ensuring that important projects and data are communicated to relevant stakeholders.
Software and Data Convergence – Deals with procuring the necessary software and data from the front office for the IT/OT needs. This is a technology-based convergence that deals with the network architecture of the enterprise.
Physical Convergence – Deals with the hardware – old hardware is either replaced or retrofitted with new sensors and actuators to accommodate the incorporation of IT into traditional OT.
Final Word
IT/OT convergence has been a significant milestone in the IoT journey and a win-win for both OT & IT Teams.
The OT teams can now access the machine data whenever they need it for proactive decision making to create value in their machines, processes & workforce. They can align better with overall business systems like ERP etc., creating unparalleled insights.
The IT teams can fulfil their smart factory vision with a healthy understanding of the ground reality and collaborate with the operations team to evolve together.
We’ve covered many of such stories in detail
in our Case Studies section
– where we showcase just how much businesses in your industry can gain through process digitization and using the Internet of Things.
Want to know how IT/OT convergence can revolutionize your manufacturing processes? Please
get in touch
with us – and our domain experts would be happy to explain over a quick call.
Click here to schedule a demo with our team of experts.
This blog is referenced from : https://www.infinite-uptime.com/decoding-it-ot-convergence-a-guide-on-understanding-it-and-ot/
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Why are cement plants the perfect candidates for Predictive Maintenance?
There are three facts about cement plants that are universally true:
The average machine age in a cement plant is at least 30-40 years.
Finding the right expertise to maintain them consistently is challenging.
Every machine – big or small – has the power to bring the whole process to a complete standstill.
These three facts establish that proactive machine maintenance in cement plants is critical to remain profitable and scale efficiently. As demand for cement grows hand-in-hand with blooming infrastructure, GDP growth & exports, the pressure on cement plants to produce continuous, high-quality output also increases proportionately.
This article discusses Predictive Maintenance, a new age approach for plant maintenance, and why an IoT-led Predictive Maintenance approach can solve most of your maintenance worries for your cement plants.
Introduction to Predictive Maintenance
Predictive Maintenance in process manufacturing plants such as the cement industry can identify deviations in machine health at the nascent stage before they escalate into full-blown problems that may result in unplanned downtime.
But that is putting it very mildly. If you look at the daunting results of a neglected cement plant, violent accidents and sky-high repair and replacement costs, while the downtime continues indefinitely, are two of many consequences of a system that is not armed with the intel that Predictive Maintenance can provide.
Here’s a simple example that explains the difference between the health of a machine that uses Predictive Maintenance and one that doesn’t – exam preparation.
An intelligent student looks at exam preparation as a daily occurrence, checking in regularly to maintain good grades and maximize performance at the end of the year. A weaker one only thinks about the exam preparation as a reaction to the possibility of failing and only begins to take action when things have started to go south.
Condition Monitoring & Predictive Maintenance operate how a good student goes about exam prep. While Condition Monitoring checks in with the machine’s health periodically, Predictive Maintenance sees that the machine is continuously monitored and will keep functioning like it is supposed to for as long as possible.
Why is Predictive Maintenance critical for the cement industry?
Let’s dive into the specifics of what makes Predictive Maintenance critical for cement plants:
Diverse assets and asset categories make finding the right workforce difficult.
The cement manufacturing process involves multiple ingredients & processes, with various machinery used at every stage of every process, meaning many types of assets need to be covered. The sheer number of diverse machines makes it difficult to find the same variety of expertise and strength in numbers to manage them. Add to this the fact that many employees don’t have the specialized knowledge to evaluate the machines and act in time, and you have a classic problem.
With Predictive Maintenance, employees need to act upon prescribed causes & mitigation steps to restore machine status. So, even when their domain knowledge is limited, automated Condition Monitoring and Predictive Maintenance nudge things along the way.
Remote locations make reactive action expensive and delayed
The remote locations of cement plants make unplanned downtime a lengthy affair. Finding the root cause of machine failure, sourcing & transporting the spare parts takes a long time. For uncommon causes of machine failure, having a Subject Matter Expert (SME) or an experienced plant engineer on-site 24*7 is next to impossible today, and escorting them to the premises whenever required turns out to be very expensive. Predictive Maintenance can solve this by providing concise instructions to fix problems, reducing the need to fly in experts frequently. On the other hand, the Subject Matter Experts (SMEs) can also diagnose the root cause of machine failure remotely with all the relevant data at their disposal.
Digitize the entire plant, not parts of it.
Every business has assets they value more than others, which is the case in cement plants too. Assets considered to be more income-generating than others and acquired at a higher cost are taken care of more meticulously.
As a result, according to statistics, only 10% of equipment at cement plants is digitized, leaving the others to be monitored manually & open for risks of sudden failure.
This can escalate into unexpected downtimes with dire consequences at a process manufacturing plant. Regardless of the size of output or functionality of a machine, a system failure for one machine spells unexpected downtime for the whole plant. IoT-based Predictive Maintenance makes it easy to digitize all the machinery in a plant, making it easy to monitor the entire process regardless of location.
Lack of number & skilled workforce adds risks.
Workforce planning in manufacturing is more expensive than ever, and it is challenging to scale labor at the same rate as capital. The traditional mindset toward plant maintenance perceives it as a quality function rather than a revenue generation function. This means that although the total number of workers across the plant may grow 10X, the Condition Monitoring team size still stays X.
On top of this, experienced plant SMEs who retire or change their jobs also take the native knowledge of the machine operations with them. Lesser skilled personnel might find it challenging to understand the finer details about all the machines.In this scenario, Predictive Maintenance can help make the process seamless, making it easier for less-qualified or inexperienced plant managers to follow specific instructions and fulfill their duties.
Reducing repeated capital expenditure with prolonged asset life.
Going back to the beginning of this article– most of the machinery we are talking about here is several decades old, and it may have been there since the very beginning of the industry in the country. The aging equipment will require replacement in the coming decades.
Replacing plant machinery requires a colossal capital influx and is not a feasible option. According to Entrepreneurship magazine, setting up a cement plant today producing 5000 MT/day would require an investment of at least USD 13.77 million to start with, only for the plant & machinery. That is why Predictive Maintenance is the best way to take care of these machines and prolong their Remaining Useful Life (RUL) as long as possible by detecting every minor fault that has the potential to turn into a catastrophe.
Save costs & time by narrowing fault down to a specific machine part.
Predictive Maintenance can identify the problem areas of your plants very closely, making it easier and cheaper to fix problems. For example, A kiln is integral to the functioning of a cement plant, but there are smaller fixtures inside this massive furnace that are just as important. Nuts, bolts, and exhaust fans are small but essential kiln components.
If one of these shows anomalies, Predictive Maintenance can indicate that the problem is occurring due to an issue with the exhaust and not the kiln as a whole. Quickly replace the fan, and your system is as good as new.
Integrated machine analytics help in proactive decision-making.
Integrated machine analytics allow organizations to understand the plant operations better and make proactive decisions about machine maintenance, product output, and efficiency. By collecting data from various machines across plants and presenting it on a dashboard that can be accessed remotely from anywhere, it becomes easy for the concerned authorities to identify patterns and trends and take insightful actions in time.
Predictive Maintenance ensures optimum operation and performance of machines, thereby ensuring consistent output. This consistency eventually makes for better quality, helping you stand out as a company that has the potential to be a market leader.
Ensure consistent quality of output, sustainability & Environment Safety.
Sustainability & Predictive Maintenance don’t seem to be connected at first, but they are deeply interlinked. A poorly maintained machine doesn’t just result in bad performance or output but can be a sink for energy consumption and a catalyst for an explosion or an on-site accident. These accidents can result in a catastrophe both from a sustainability and a worker safety point of view.
Why are IoT-driven Predictive Maintenance solutions better than conventional factory automation systems?
Before IoT-driven Predictive Maintenance solutions, manufacturers used factory automation solutions like Allen Bradley & Siemens for plant maintenance. Here is how IoT-driven Predictive Maintenance solutions are a better choice for cement plants:
1. Predictive Maintenance is a proactive solution, not a reactive one.
A conventional factory automation system will shut down operations in response to a crisis to avoid further damage.
An IoT-based solution will see that crisis coming from a distance, initiate a likely fix, and alert superiors of the occurrence.
2. Factory automation systems are prohibitively expensive compared to IoT-driven predictive solutions.
The higher costs meant that manufacturers could only cover their most expensive assets, leaving risks for unexpected downtime.
IoT-enabled Predictive Maintenance covers the entire plant at a reasonable cost, ensuring all the machines receive equal coverage..
3. Factory automation systems were designed decades back, and a lot has changed since then.
The main action taken by these archaic systems is to shut things down and minimize damage, sealing its fate as a glorified fire extinguisher.
On the other hand, IoT-driven solutions for the cement industry aim to:
Maximize the productivity of your plant, not just to avoid calamities.
It gives you the power of foresight, which is valuable in an industry as competitive as this one.
Older systems do not even look into parameters that IoT scrutinizes, e.g., measuring the vibrations of a machine is a brand-new feature overlooked before.
Conclusion
With the right solution & team of domain experts, Predictive Maintenance can create an unbeatable competitive advantage for your cement plant, fostering efficiency across the workforce, resources, and processes. By identifying and addressing minor issues with critical assets before they become big problems, Predictive Maintenance helps keep machines running smoothly and efficiently, leading to higher quality products and lower costs. It not only optimizes maintenance costs but also increases improves operational efficiency by reducing unscheduled downtimes.
About Infinite Uptime–
Infinite Uptime is transforming the industrial health diagnostics space with a Digital-First approach. We provide comprehensive solutions around Machine Diagnostics, Predictive Maintenance, and Condition Monitoring to the top engineering and process industries globally.
Infinite Uptime has saved 1000s of hours of unscheduled downtime for integrated cement plants globally and accelerated their industry 4.0 adoption and digitalization journey. For more success stories or to schedule a demo with our experts, please visit our website www.infinite-uptime.com or write to [email protected]
This blog is referenced from : https://www.infinite-uptime.com/why-are-cement-plants-the-perfect-candidates-for-predictive-maintenance/
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How to choose a maintenance solution for your plant in 2022?
Revolutions are synonymous with disruptions. Industry 4.0 is nothing different. It demands new and advanced technologies for manufacturing plant maintenance and discarding obsolete plant maintenance processes at a much faster pace. It sometimes becomes overwhelming to understand and adopt new technologies as a plant head. So, here, we have an article to help you choose the right maintenance solution for your plant in 2022.
In this article, we’ll majorly talk about how you can choose the right Predictive Maintenance solution for your plant. But let’s start with the 3 basic types of industrial plant maintenance solutions available in the market.
Types of industrial plant maintenance
Reactive Maintenance
Maintenance that is out of reaction rather than duty and is performed only after the equipment is finally broken. This obsolete maintenance strategy can save you money in the short term but eventually increases your losses by increasing machine downtime, inefficiency, and frequent failures
Preventative Maintenance
Preventative plant maintenance requires scheduled check-ups routined on industry standards, and it involves timely maintenance and carry-out tasks like a belt and filter changes regularly. This maintenance strategy for plants and equipment increases equipment life but requires regular labor for check-ups and maintenance.
Predictive Maintenance
Predictive plant maintenance leverages artificial intelligence, cloud storage, and IoT to provide real-time data on plant equipment. It diagnoses the real-time condition of in-service equipment, and then the required maintenance schedule is followed. It also reduces the operating cost by 12-18% and provides a safer working environment.
Objectives of a Predictive Plant Maintenance Solution
The objective of opting for a plant maintenance solution is to elongate the life of plant equipment and operate them in an optimum condition at minimum cost. Here are all the significant objectives below-
To maintain the peak productivity of the manufacturing plant.
To obtain the optimum working capacity of equipment at the lowest possible cost.
To minimize the losses from unwanted breakdowns and downtimes.
To provide a safe working environment for plant workers.
To protect the equipment from frequent breakdowns and efficiency loss.
7 most important questions to consider before choosing a Predictive Plant Maintenance solution
Predictive Plant Maintenance Solution comprises equipment and sensors, gateway, cloud service, and management to sense, record, and provide actionable insights on the machine’s condition. Artificial intelligence, machine learning, and IoT always try to yield accurate results.
But before you buy a predictive plant maintenance solution, consider these 7 critical aspects of it to decide which predictive maintenance solution is right for you.
Easy-to-Use and intuitive for everybody
The ideal Predictive Maintenance solution must be easy to use for all, from onsite plant operators and technicians to the plant manager & plant head. It should be intuitive and user-friendly to be mainly accessible to everyone required. If you need a data scientist every time to decode the insights provided by this software, then you are set up for sudden asset failures due to delayed responses.
The right predictive plant maintenance solution can empower the onsite condition monitoring/ maintenance teams with the correct machine data at the right time for successful plant maintenance assessments with actionable insights.
Finding the root cause, not just alerts
Some Predictive Maintenance solutions indicate only alerts of anomalies, while the others yield insightful data alerts with what might be causing them. Those insights can be used to get a 360º condition of working equipment, and plant engineers can trace the root cause of the problems and plan a more effective solution. It also helps to distinguish the false alerts from the true ones.
For example: Just pointing out an issue with an exhaust fan of a kiln in a cement plant may lead to 1000 causes, but a solution that analyzes this further and points to a loose bearing that may be the cause can lead to a different level of agility for your maintenance teams.
Are the outcomes measurable or just hopeful?
Ensure that the maintenance technology brings you the results in some way or the other. And the results must be measurable and not hypothetical, which means you should be able to calculate the profits that the technology is bringing against its cost.
The average cost per hour of equipment downtime is $260,000. Look for a predictive maintenance solution that can save you the downtime cost and increase profits. Predictive maintenance can reduce machine downtime by 30%-50% and increase machine life by 20%-40%. (McKinsey)
Usable across assets and manufacturers
A plant usually has various types of equipment from multiple manufacturers and suppliers, depending upon the quality and cost. The Predictive Maintenance solution you are planning to install must easily integrate and comply with every piece of equipment in the plant- regardless of its age, type, and manufacturer.
Having different data collection mechanisms for different equipment is costly and leads to entropy & silos that obstruct the whole picture. Technology, along with human intelligence, functions to streamline complex processes and increase efficiency, and not the opposite.
Experience around process plants
Process manufacturing plants differ from other industries in various aspects. Predictive maintenance solutions request historical data to function reliably, but process plants have limited historical machine data, making it difficult for the predictive solution to function properly. Make sure your vendor has experience working with process plants to tackle the situation constructively.
Deployment & scaling time
One of the most popular hesitation in IoT-driven Plant maintenance deployments is the time taken to deploy the solution. If the deployment takes months, the internal enthusiasm built around the deployment dies down, and so does the ROI.
It is also essential that the deployment velocity is maintained when the solution is scaled up-whether from some machines to the entire plant or across plants.
Look for a predictive maintenance vendor that can integrate the solution in your plant and enable working within a few weeks and not months.
Predictive Maintenance in mining can cause many benefits – direct & indirect.
Conclusion
Predictive plant maintenance solutions save millions of dollars for manufacturing companies by predicting equipment health and indicating impending failures beforehand. Various predictive maintenance solution providers come with multiple packages, and hence choosing the right fit for your plant is important. Look for an easy-to-use and intuitive product that can comply with mixed assets from diverse manufacturers. At Infinite Uptime, we strive to transform the industrial & machine health diagnostics space. Our Predictive Maintenance solutions are used by hundreds of process plants globally, saving millions of hours of downtime, and improving the efficiency, scale & output of plants, one insight at a time.
Want to know more about how you can safeguard your machine’s health & reliability with Predictive Maintenance?
Click here to schedule a demo with our team of experts
This blog is referenced from : https://www.infinite-uptime.com/how-to-choose-a-maintenance-solution-for-your-plant-in-2022/
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Future of maintenance in the metals sector
Metals and Mining industries are one of the oldest industries and have always helped in the economic development across the globe, right from the first industrial revolution. Today, the metals sector faces numerous challenges from lack of competitive advantage, power shortages, tight budget, regulatory compliances, etc. But one of the significant challenges is still unplanned downtime and maintenance in metalworking.
Here, in this article, we’ll break down the major challenges and discuss the future of maintenance through the predictive maintenance solution for the metal industry.
Challenges faced in the maintenance of the metal industry
Challenges from growing competitors, increasing energy costs, government regulations, etc., make it difficult for metal companies to maintain profits. To add to this, unplanned machine failures and downtimes increase the production cost, reducing the revenue.Anomalies with old and legacy machineryMachinery in the metalworking plant is generally old (~30/40 years old) and demands extra care and services. Though equipment in the metal sector was designed to work in the harshest conditions, it does break down with age and poor maintenance strategies. And thus, continuous monitoring & maintenance of assets is essential.
Unplanned downtimes due to machine failures
Downtimes are the worst nightmares for the metal plant heads as they come with no warning alarms and cost time, money, and manpower. Unplanned downtimes decrease plant productivity and delay production, leading to loss of customers and a decline in profits. Thus, maintenance in metalworking plants is required to prevent unplanned downtimes.
Low Maintenance Budget
Cost pressures on metal manufacturing are increasing due to the soaring prices of coking coal. Manufacturers end up trimming the maintenance budget to meet tight margins, retain customers and stay profitable. Even when the rest of the plant scales, maintenance teams are typically still small & lean. What needs to be understood is that plant maintenance activities are critical for business profitability, and investment in tools that can help your maintenance team be on top of all machine parameters is mandatory.
Lower Productivity of Workforce
Inefficient maintenance strategies and improper structure and scheduling often hamper productivity. Even when not entirely down, faulty machines result in sub-par output quality, increased time for plant operators, and lower productivity. Maintenance teams have to spend a hefty amount of time diagnosing issues from scratch, which hampers the plant’s overall productivity. Predictive Maintenance helps avoid this by pointing out anomalies and also suggesting resolutions.
High chances of a safety hazard due to machine failures
Machine failures cost money and lives if spiraling out of control. There are always chances of safety hazards around old machines as they frequently break down. Predictive maintenance for the metal industry can resolve this issue by cautioning about the imminent machine failures before they reach a severe stage.
Scope of Predictive Maintenance for the metal industry in the future
The maintenance of a metal industry or plant is a cumbersome process. It demands diligence and precision, yet machines break down. Machine failures and downtimes are very catastrophic for the plant. One significant machine failure takes away all the past maintenance hard work, plant productivity, and future profits.
Fortunately, advanced technologies that empower industry 4.0 have got our backs. The rise of IoT, 5G connectivity, automation tools, AI, and Machine learning simplifies the maintenance process. An IoT-led Predictive Maintenance solution can foretell the potential failures and prescribe the requisite corrective measures, protecting not just machines but your bottom line too. Here is how:
Benefits of Predictive Maintenance in the metal industry
Predictive maintenance tools can be beneficial in the metal industry as they can save a lot of money and time. It thoroughly resolves some significant problems in the maintenance of the metal industry.
Predictive Maintenance analytics offers substantial time and cost savings.
Unlike Reactive Maintenance, Predictive Maintenance has a high initial cost but can save your plant much more than it costs. If we do the math, unplanned shutdowns cost a lot (USD 2,60,000 per hour) which can be saved by predicting a failure and fixing it beforehand. A study revealed
that predictive maintenance decreases the costs by 12%.
Prevent downtime & asset health degradation
What could be better than having the real-time data of all your plant assets? You can monitor critical machine parameters like temperature and vibration, which can be early indicators of a severe problem. Any abnormal behavior will get tracked down and assessed, and warning alarms and corrective measures will communicate serious issues. A McKinsey report states that predictive maintenance reduces downtime by 30%-50% and extends the life by 20%-40%.
Foster real-time decisions
Deloitte says, on average,
Predictive Maintenance increases productivity by 25%
. It helps plant heads, Maintenance Planners, Systems Engineers, and Controllers optimize asset performance & availability and prescribes corrective measures as needed. It is easy to use for plant workers and technicians, and you need not employ a data scientist for it.
Better quality output
Predictive Maintenance is highly cost-effective, saving roughly 8% to 12% over Preventive Maintenance and up to 40% over Reactive Maintenance (according to the U.S. Department of Energy). It gives you a competitive edge against the other players in the market, which you can leverage to produce and supply higher quantities of goods.
Low chances of safety hazards
Well-functioning machines promise a safe on-site environment. Real-time assessment and beforehand cure of any anomaly can sustain the plant equipment and extend its life. Non-faulty machines reap great results and ensure a safer working environment for plant workers.
Conclusion
Future maintenance in the metal industry necessitates futuristic technology to cut costs and increase production efficiency. A Predictive Maintenance solution answers the most questions on plant maintenance, and it provides a competitive edge that you can leverage to increase your profits.
At Infinite Uptime, we strive to transform the industrial health diagnostics space by enabling process manufacturers to use their assets to their full potential. With our advanced predictive maintenance platform, we are helping unveil the untapped efficiency and productivity of the metal industry and creating a profitable future.
Want to know how we can enable better asset health & performance for your metal plant? Reach out to our team of experts today.
This blog is referenced from : https://www.infinite-uptime.com/future-of-maintenance-in-the-metals-sector/
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Predictive Maintenance & IoT Impact on Mining
The mining industry is one of the oldest & most hazardous commercial sectors where the use and implementation of modern technology are very gradual. Mining companies utilize a plethora of expensive equipment in a high stakes & cost environment. In these cases, asset health is critical to the safety & profitability of the mine.
This is where IoT-driven Predictive maintenance can be a gamechanger. It has the potential to collect and analyze environmental and equipment data instantaneously and conduct real-time risk and area evaluation. It reduces the risk of downtime & loss due to machine failure and reduces overall maintenance & spare part costs of high capital-intensive machinery. The application of IoT in the mining industry is quintessential because of its advantages for large-scale operations in mining, where the operating environment is constantly changing & workforce operates in a compact, adapting, and potentially hazardous environment.
Let’s first try to understand the what makes maintenance for the mining industry difficult:
Challenges in the mining industry
Disruptive & exorbitant impact of equipment failure in minesEquipment failure is the worst nightmare for mines. A standard mining operation spends 35-50 percent of its yearly operations budget on just asset maintenance & repairs. Unpredictable equipment failure can disrupt production & a considerable dent in the bottom line.Remote monitoring of equipment at far-off locationsMines are typically located far away from civilization. So in case of unplanned downtime, it takes time to get expert maintenance personnel and spare parts to reach, diagnose and repair the equipment. These transportation delays & costs impact the budget as well as profitability.Workforce safety depending on asset healthWorker health & safety remains a big concern in the mining industry due to the difficult working conditions. Furthermore, as mines get deeper, the likelihood of a collapse & danger increases. While safety in mines has improved dramatically over the years, the fatalities caused by asset malfunction are a big reason for on-site hazards.Unreliable connectivity optionsAdditionally, because more mines are constructed in off-grid locations, providing stable electrical infrastructure to power mining operations and appropriate water supply becomes increasingly tricky. Connectivity is limited or unreliable, particularly in underground mines, and the 3G/4G signals may be difficult to pick up in remote regions.
Types of machine maintenance in mining
The different types of machine maintenance are:
Reactive Maintenance/ Run-to-Failure Maintenance: This refers to repairs performed after a machine has already failed and it is unexpected and thus leads to emergency rushed repairs.
Preventive Maintenance: This refers to any planned or scheduled machine maintenance that aims to identify and repair problems before they cause failure. It can be annual/bi-annual. But it cannot prevent asset failure between two schedules or unnecessary downtime.
Condition-based Maintenance: It focuses on monitoring the current status of assets to undertake maintenance when evidence of decreasing performance or approaching breakdown is detected.
Predictive Maintenance: It expands on condition-based maintenance by utilizing instruments and sensors to continuously evaluate machinery performance & flagging off any anomaly and its root cause before it results in a full-blown asset failure.
Predictive Maintenance in mining can cause many benefits – direct & indirect.
Some of the benefits of Predictive Maintenance are:
Reduced Downtime: Utilizing predictive maintenance, you can anticipate troubles ahead of time, decrease machine downtime, increase uptime by 15-20%, schedule maintenance as needed, and thus extend the life of an old machine by up to 20%.
Increasing Productivity: It ensures that both planned and unplanned downtime is kept to a minimum, resulting in fewer interruptions to production and a significant increase in overall productivity.
Higher Production Capacity: Asset availability of high performing & critical assets in mines helps plan and optimize production capacity, which is crucial for effective management & production planning and staying on schedule.
Lowered Maintenance & Spare Part Costs: Maintenance and spare part costs are significantly lower for preventative maintenance since all machines in the manufacturing process are continuously monitored and repaired before a problem becomes severe.
Enhancing Workplace Safety: Predictive maintenance can reduce the risk of work-related accidents by identifying any discrepancies that could lead to an accident on-site. Predictive maintenance ensures a sanitary and healthy environment in the plant while reducing safety risks by up to 14%.
Proactive Decision Making: The implementation of IoT enables mining maintenance managers to detect when there is a breakdown or a drop in performance, enabling them to react quickly and effectively. In addition, monitoring, obtaining, and analyzing data from particular mining equipment over a period may help them understand how the overall efficiency of the process itself can be improved.
Conclusion
The mining industry has been a critical sector globally for centuries. With the right Predictive Maintenance solution, mine maintenance managers can ensure that the production continues without impacting commercial efficiency while ensuring worker safety. A sound & functioning asset also ensures a greener footprint and fewer hazards, proving to be less dangerous for the environment.
Want to know more about how a competent Predictive Maintenance solution by Infinite Uptime is helping some of the largest mining companies improve asset & operational efficiencies?
Click here to schedule a demo with our team of experts.
This Blog is Referenced from : https://www.infinite-uptime.com/predictive-maintenance-iot-impact-on-mining/
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Optimizing machine health with Condition Monitoring
Industry 4.0 aims to bring operational excellence by introducing the Industrial Internet of Things (IIoT) to the industries and factories. It allows machine health monitoring using IIoT, streamlining the process and increasing efficiency. In this blog, we’ll share why IIoT machine monitoring is useful and how it can help you?
Importance of Machine Health Monitoring in the Industrial 4.0 Era
Despite applying the best reactive and preventative maintenance strategies, industries lose a lot of money & time because of unplanned downtime, machine failures, and wasted maintenance cycles. Unplanned downtime decreases plant productivity and hinders the supply chain. To overcome this, plants need to adopt Condition Monitoring technologies.
IIoT machine monitoring offers real-time insights to assist maintenance teams in making better decisions, enhancing the machine’s efficiency and extending its lifetime. IIoT plays a vital role in enabling plant reliability by:
Providing robust connectivity across the plant
Catering to the growing shortage of plant workers.
Helping in planning and scheduling maintenance strategies.
Bringing more profit against its initial implementation cost.
It also creates a safer working environment for plant workers by reducing the chances of machine failures.
Benefits of Machine Health Monitoring using IIoT
Improvement in the overall efficiency of manufacturing
IIoT machine monitoring machinery considerably increases the overall plant efficiency. It increases the cost efficiency by cutting unnecessary maintenance and decreasing unplanned downtime. Unplanned downtime constitutes a 40-50% loss in efficiency. Condition monitoring predicts the impending failures and helps in curing them beforehand.
Real-time monitoring and required maintenance of all the plant assets enhance the plant’s productivity and sustain it. It also extends the plant equipment’s lifetime, saving many costs that otherwise would go in vain.
Considerable Reduction in Waste
IIoT machine monitoring can help industries in waste management. Defective items are the most significant manufacturing waste from plants. Trivial machine malfunctions often get ignored, which causes the production of defective items or sub-par output quality. It costs money, resources, and man-hours. Also, starting up after unplanned downtimes produces unprocessed/semi-processed goods, further increasing the overall plant waste. IIoT machine monitoring can eliminate this waste by foretelling the possible threats.
Intelligent adoption of IIoT-enabled solutions also reduces the burden of excessive maintenance, lubrication, and spare parts waste. Assessing and predicting machine failures saves time and resources, which would otherwise go to waste.
Improved communication & decision making
Machine health monitoring using IIoT improves communication by providing 360-degree visibility of manufacturing operations to all the right people. Advanced solutions connect plant equipment to a manager, manager to the operator, and operator to operator effectively, reducing the chances of delayed communication.
Providing the right & timely information across the plant boosts the plant productivity multiple folds. Usually, a lot of time gets wasted in planning and scheduling maintenance strategies. IoT-based machine health monitoring systems capture the fault and track down the root cause to advise you on the best approach to tackle it.
Real-time Data Collection, Analysis, and Alerts
IIoT-based condition monitoring systems collect real-time data from all the machinery and analyse and assess them according to the recommended performance levels. If the machine health fails to meet the set parameters, the platform immediately alerts the maintenance manager and conveys the problems with the recommendations to take care of it.
The sensors record data from various equipment to perform vibration analysis, oil analysis, temperature analysis, and other relevant analyses. After analyzing, if it detects any issue, it quickly notifies the possible reasons. For example, the reports may suggest engine erosion if higher than usual iron content is found in the oil analysis. On the other hand, if a higher range of a combination of iron, Aluminium, and chrome is found, it may signal the upper cylinder wear. The maintenance manager can then take immediate action on this.
Conclusion
Even the best reactive and preventative maintenance strategies couldn’t do justice to the cost and productivity. So, industrial revolution 4.0 brings advanced machine health monitoring using IIoT technology to address production and maintenance issues. The technology gained its importance by tackling day-to-day problems in various industries. It benefits industries by reducing plant wastes, collecting and analyzing real-time data, streamlining communication, and increasing overall plant reliability.
At Infinite Uptime, we have pledged to transform the industrial health diagnostics space. Thus, we offer IIoT-based machine health monitoring solutions for process plants like yours. Our intelligent solutions easily integrate into the plant using AI and machine learning and help tap your plant’s peak efficiency.
This Blog is Referenced from : https://www.infinite-uptime.com/optimizing-machine-health-with-condition-monitoring/
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Why the move from condition monitoring to predictive maintenance is the next big thing in the cement industry
The increasing urbanization in the world has consistently put demand pressure on the cement industry. Consequently, the industry has streamlined its operations from time to time and focused on high-quality throughput. Fortune Insights report says the global cement market will grow from $326.80 billion in 2021 to $458.64 billion in 2028, a steep 5.1% globally. Keeping pace with the rising demand and changing market scenario, digital transformation in the cement industry for efficient operation and maintenance is an immediate requirement.
While condition-based monitoring has seen wide adoption to support digital transformation initiatives in cement manufacturing, predictive maintenance is shaping to be the next big thing. With plant reliability objectives and operational excellence goals on the line, this shift must happen. In this article, we will compare both technologies and deliberate on why this evolution is necessary for cement manufacturers.
Condition-based Monitoring (CBM) in the Cement Industry.
In the cement industry, machinery works under challenging conditions- with fume, gases, dust, and high temperatures. The continuous nature of the cement manufacturing process also ensures that halts in production cannot be without a substantial reason. Thus, routine manual check-ups are sometimes impossible
Asset Maintenance in cement plants is today being practiced using condition monitoring technology. Condition monitoring gives real-time machine working conditions via alerts and allows the maintenance team to take action when the problem is detected. In the cement industry, CBM performs vibration analysis of rotating equipment, oil, grease analysis, thickness measurement of kiln shell and chimney ducting, etc., to examine the assets’ health.
Predictive Maintenance (PdM) in the Cement Industry.
The highly competitive & quality-focused requirement of cement plants today means that condition monitoring falls short in many aspects. This gives rise to Predictive Maintenance: a proactive approach to maintenance that uses IoT and machine learning to predict impending machine failure.
Predictive Maintenance solutions consist of hundreds of strategically placed sensors that record data and send it to a central IoT platform. The IoT platform monitors and analyses any anomalies and notifies the plant manager of the equipment’s life.
The Need to Move from CBM to Predictive Maintenance in the Cement Industry.
1. Condition-based Monitoring technology monitors the real-time condition of the machine and shows warnings when an anomaly happens. While this means it is better than the time-based & reactive maintenance approaches, it still can cause downtimes & in some cases, need repair & spare part costs. Predictive Maintenance technology, on the other hand, predicts the imminent machine failure before it takes place and saves from unplanned downtimes.
2. Condition Monitoring provides on-site engineers with data parameters that are often difficult to interpret in isolation. This means they need their subject matter experts to analyse these first before taking the right actions. By comparison, Predictive Maintenance gives insights behind the data around a machine anomaly, with the why of a particular machine behaviour & recommended actions for mitigation. This means faster decision-making by the on-site team without bothering SMEs for every minor glitch.
3. Also, CBM technology warns of trivial anomalies that lead to excessive maintenance in cement plants, which leads to unnecessary maintenance and a loss in productivity & efficiency.
Predictive maintenance monitors the real-time condition of the equipment. It predicts faults with potential repercussions, ensuring maintenance activities are performed precisely where they are needed & only when they are required.
Thus, using PdM over CBM makes maintenance in cement plants more efficient and hassle-free.
Significance of Predictive Maintenance in the Cement Industry
First-generation machinery that is decades old is still being used in cement manufacturing. Due to rough operating conditions & continuous running, machines are more susceptible to breakdowns resulting in downtimes. These unplanned downtimes hamper the production quality, reduce profits and create unsafe working environments in the plant.
Predictive maintenance in cement manufacturing resolves these frequent maintenance issues by foretelling the machine failures with least or no human inspection. It enhances the visibility of machine health throughout the plant, enhancing proactive decision-making.
Predictive maintenance is essential in the cement industry because
It helps lengthen the life & performance of older machines.
It reduces repair & spare part costs due to proactive maintenance.
It reduces the frequent planned & unplanned downtimes, which results in a better quality of cement and consistent production.
It reduces the chances of any safety hazards caused due to machine malfunction.
It saves a lot of time and costs, which otherwise would go into maintenance.
It leads to better worker productivity & overall plant efficiency.
Why Predictive Maintenance is the Future of Cement Manufacturing?
A sustainable future of high-quality output, a productive workforce & reliable machinery can be achieved by the digital transformation in the cement industry. As the cement industry is getting ready for a global inflection, environmental & regulatory compliances are expected. Green cement manufacturing will soon become necessary to save the environment and resources.
The rise in the requirement for green cement will necessitate a lean and highly efficient operating style and long-term bottom-line growth. Amidst all developments, predictive maintenance solutions will remain a significant value driver in the shifting roadmaps for obtaining a competitive advantage in this market, enabling better results for workers, customers, management & overall ecosystem.
Conclusion:
Machines in the cement industry work in harsh conditions and, thus, are more prone to breakdowns. A proactive approach to maintenance would be beneficial for plant productivity. Predictive maintenance is preferred over condition-based monitoring systems as it can predict the problem before it happens. In contrast, CBM can only monitor real-time equipment conditions and can’t predict future anomalies.
Also, CBM is less accurate, while PdM is proved more accurate over time by learning through machine learning technology using historical and real-time data. Predictive maintenance technologies will surely lead the future of maintenance in cement plants.
At Infinite Uptime, we strive to transform the industrial health diagnostics space, particularly for process-driven industries like the Cement industry. We offer predictive maintenance solutions enabled with machine learning and IIoT technology that companies combat downtime, lapses in quality, productivity & OEE.
Want to know how we helped the largest cement manufacturer in India? – click here.
This blog is referenced from : https://www.infinite-uptime.com/why-the-move-from-condition-monitoring-to-predictive-maintenance-is-the-next-big-thing-in-the-cement-industry/
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Decoding plant reliability in manufacturing and a process to reach there.
Process manufacturers typically operate in data-rich environments and know their plants inside out. While they know their assets and how their resources are deployed, they are often unaware of factors contributing to optimal asset performance. Even if this information exists within the manufacturing ecosystem, the plant maintenance and operational heads don’t really know how to use it to achieve optimum plant productivity.
Studies reveal that frequent downtimes at process manufacturing plants can result in nearly $15000 per hour of lost revenue. Digitalization of the maintenance process and proactive asset performance management directly contribute to saving this cost. Prioritizing plant reliability becomes the only way to improve overall operations and mitigate unplanned downtimes.
But what is plant reliability, and what processes need to be institutionalized to achieve it? In this article, we will discuss what reliability means for manufacturing and lay out a six-step process to devise a plant reliability strategy for a manufacturing plant effectively.
What is plant reliability, and how can you measure it?
Any reliable system accounts for its safety and trustworthiness while ensuring minimal maintenance costs. For plant assets, reliability can depend on performance, condition, maintenance needs, and availability. An asset reliability check can be done based on factors like frequency of maintenance or repair costs, number of malfunctions, unexpected downtimes, and more.
Keeping plant’s maintenance up to the mark ensures that assets run 24/7 with fewer interruptions or unexpected delays due to frequent maintenance incidents. This leads to faster go-to-market, better output quality, employee productivity, and significantly lower operational costs or costs per unit.Plant reliability in production can be quantitatively measured using the Overall Equipment Effectiveness (OEE). A popular metric for measuring manufacturing productivity, OEE factors in a product of availability (number of downtimes/uptime), performance (speed or run time of your processes), and quality (number of defects).An OEE score of 100% indicates a completely reliable, dependable, and high-quality plant with maximum productivity. Therefore, calculating OEE and securing a top score should be part of your asset management’s best practices.
Six steps to creating an effective reliability plan at your plant.
Every successful plan consists of a set of clear and executable steps. And the same principle applies to achieving top-notch plant reliability as well. Without a clear, planned route, it can be hard for you to envision your end goal – optimum plant and asset reliability management. Here are the six actionable steps that are essential to executing your plan successfully:
1. Building the right team.
The right team can make or break reliability goals- from top to bottom.
Effective leadership, skilled personnel, and onsite-plant operations team must be aligned with accomplishing plant reliability goals.
Achieving reliability is a team effort and a continuous improvement process. Designated team champions have to be distributed within Operations, Maintenance, and Engineering along with sufficient alignment around their common goals & individual targets. This way, every individual is well aware of their role in constantly improving the plant and understands their dependencies on the other teams. There has to be also a Reliability Leader who helps drive this initiative
2. Creating the right mindset for reliability
For a successful plan, having the right mindset for asset reliability is as important as relevant skills, processes & technical understanding.
Since achieving reliability requires continuous effort, you can try to define your target numerically & align every department’s target accordingly. This target & its deadline needs to be agreed upon by each department-operations, maintenance, engineering, and the subsequent KPIs that befall them individually.
It is critical that all teams uphold this goal as their guiding principle and implement it through individual responsibilities every day.
3. Adapting Predictive Maintenance (PdM) approach
Plant reliability is also heavily dependent on asset health & reliability. The approach towards asset reliability is centered around the plant maintenance methodology chosen.
An advanced framework like predictive maintenance alongside numerous assets and operations can speed up the process of obtaining plant reliability. By proactively anticipating flaws or anomalies within the plant and addressing them, reliability objectives can be progressively achieved.
And when you proactively work towards fixing them, you can see your maintenance costs and the dreaded plant downtimes plummet instantly. Also, by understanding what caused these failures, your teams can work towards optimizing their maintenance strategy in the future.
4. Having a best practices checklist for assured equipment reliability
It is not enough to be proactive at one time; it has to become a process for excellence in reliability. For this, rigorous observation of what worked needs to be executed..
Best practices for different plant segments and units can be documented for standardized records and accessibility. Mainly for equipment reliability which requires defined steps, having a list of executables becomes highly essential. These practices are initially set for a particular type of machine in a plant -like a gearbox which can be applied for gearboxes across multiple plants for the same organization to benefit from learnings.
This can help your team focus on improving reliability at the plant, bit by bit, and avoid recurring mistakes alongside employing PdM.
5. Prioritizing critical assets first
Your plant might have critical equipment that causes the most impact – both financially and operationally when down, like a kiln in a cement plant.
So to reduce this unpredictable impact, you can prioritize these assets and implement a model like Predictive Maintenance to fix issues on priority beforehand. Predictive Maintenance can also improve equipment reliability as it works toward assuring asset performance and health around-the-clock through continuous evaluation.
6. Assessing your Reliability plan’s progress
Using your goals & best practices checklist, perform regular audits to check for any shortcomings. Organize audits as frequently as monthly or quarterly, based on your process durations. Check if your charted reliability program progress is aligned with your monthly/quarterly goals.
Continuous improvement requires continuous learning too. Make a detailed implementation plan with clear-cut steps for each task for every department involved and skill improvement and tool usage training at periodic intervals. Skills like vibration monitoring.
This practice keeps your plant and teams’ performance in constant check. Also, assessing highlights hidden improvement areas that may be hindering your plant’s reliability.
Conclusion:
A well-articulated plant reliability plan and set targets can be the driving force towards rapidly fulfilling your reliability goals. Since consistency is key to realizing this goal, it requires a combined proactive effort from leadership, stakeholders, and staff.
At Infinite Uptime, we provide cutting-edge solutions to implement predictive maintenance programs, seamlessly improving your plant’s reliability. With plant reliability, we help manufacturers across the globe see faster results by significantly improving plant efficiency, fewer downtimes, and better quality using predictive maintenance.
Want to achieve faster plant reliability? Get in touch with us today to schedule a free demo!
This Blog is referenced from : https://www.infinite-uptime.com/decoding-plant-reliability-in-manufacturing-and-a-process-to-reach-there/
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Why Predictive Maintenance is gaining adoption in the Paper Industry
The pulp and paper industry has been steadily experiencing a decline in demand for graphic papers used for newsprint, printing, and writing. In a digital-first economy, paper can very well be seen as an obsolete commodity and the growth numbers of past years are nothing but strong evidence of the same. However, as some paper applications decline, others are growing.
Paper packaging is replacing plastics at a fast pace, while specialty paper is gaining popularity in niche markets. Resultantly, thousands of paper production units around the world are adapting their production environments to cater to this transforming demand. There’s an increased focus on optimal utilization of resources, re-integrating waste products into processes, and finding sustainable ways to ensure asset reliability.
Predictive maintenance can play a pivotal role in these changing industry-wide objectives, and here’s how:
Predictive maintenance in Paper Industry
Several rotating equipments are utilized in industrial paper production that requires continuous upkeep and availability. Any undiagnosed machine faults or failures can surmount equipment breakdown and unplanned process downtime. Not only can this mean increased production costs and an unsafe work environment, but it could also mean a disrupted supply chain and unhappy customers. To manage such contingencies, most paper producers rely on preventive or scheduled maintenance, organizing planned production downtimes to carry out maintenance activities and machine part replacements. While this approach reduces the likelihood of factory floor mishaps or sudden machine breakdowns, it does nothing to reduce production downtime. The preventive maintenance approach also leads to a decrease in the remaining useful life (RUL) of assets under deployment and increases the total maintenance cost.
This is why the paper manufacturing plants of the future are slowly but surely adopting a predictive maintenance strategy and shifting away from preventive maintenance. Predictive maintenance (PdM) is a maintenance approach that uses cloud-enabled technologies to monitor diverse assets involved in paper production in real time.
With predictive maintenance, maintenance managers and plant heads can proactively track machine health, estimate the maintenance needs of all deployed assets, and support maintenance decision-making.
The adoption of PdM in paper production contributes toward digital reliability objectives and delivers the following benefits to maintenance and operation teams:
Maintenance activity is highly targeted in predictive maintenance and only performed when a fault or anomaly is detected. Routinely organized production downtimes and pre-emptive part replacements are not required.
PdM is increasingly efficient over time and reduces the labor-intensive nature of maintenance activities. Predictive maintenance is also more cost-efficient, reducing the inventory carrying burden for spare parts.
PdM dashboards also offer machine health insights with digital twin technology, supporting intelligent decision-making for maintenance planning and procurement of machine parts. Consequently, the net cost of assets is effectively reduced as the complete useful life of every machine is utilized before any replacement is done.
The likelihood of unplanned reactive maintenance is reduced by 70-90% with a predictive approach. Since equipment faults are diagnosed well before the actual functional failure, organized maintenance events can help avoid process disruption and reactive efforts.
Critical equipment problems and underlying causes of diminishing productivity can be accurately identified with predictive maintenance. As a result, a higher network system reliability can be achieved in a cost-efficient manner.
Critical PdM Applications in Paper Industry
Given the numerous benefits of predictive maintenance, its adoption across the paper and pulp industry seems only natural. But with cost optimization as an important driving force for all strategic planning within the sector, it’s important to identify the critical applications of predictive maintenance and plan a systematic adoption.The following equipment and machine groups that play a significant role in the paper production process are the most important applications of predictive maintenance solutions in the paper industry:
Several machine groups utilized in paper production have a complex design, making manual monitoring and intervention difficult. Therefore, for each equipment application, the digitization points need to be carefully identified and validated for condition monitoring. With real-time vibration monitoring and predictive analytics, commonly occurring faults can be proactively diagnosed, such as:
Misalignment
Unbalance
Bearing faults
Structural Looseness
Gear Defects
Friction (lack of lubrication)
The maintenance teams can then organize OEM inspections on focused locations and fix or replace machine components that are suffering from a particular fault. The resultant reduction in unplanned downtime and improved machine health can translate into a stronger bottom line and help paper manufacturers develop a true competitive advantage.
Final Thoughts
In conclusion, for the paper industry, automation and digitization initiatives have to be driven by the ultimate objective of achieving better cost efficiencies and operational excellence. Predictive maintenance can significantly reduce production and maintenance costs and improve process hygiene across any paper production unit.
With real-time data analytics and access to intelligent insights about machine conditions, PdM can empower maintenance and operation teams more than ever. This is precisely why; global paper manufacturers are adopting predictive maintenance solutions for making their plants more reliable and efficient.
Infinite Uptime’s digital reliability solutions suit specific industry needs and provide advanced analytics to support maintenance and minimize unplanned downtime.
Get in touch with our experts or book a demo now to understand how our solutions fit your plant.
This blog is referenced from : https://www.infinite-uptime.com/why-predictive-maintenance-is-gainingadoption-in-the-paper-industry/
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