Get to know our new Electric Current Sensor

Exploring new technologies and advancements is crucial for ensuring the efficient performance of industrial assets. In this context, the electric current sensor has become essential for online monitoring operating motors.

These devices are crucial in detecting current signals, providing valuable insights into equipment operation.

In this article, we introduce the new electric current sensor developed by SEMEQ, its main features, benefits, and the types of plants for which it best suits.

SEMEQ’s Electric Current Sensor Features

SEMEQ’s electric current sensor stands out in the market for its adaptability and versatility in online asset monitoring. Here are the key features that set this solution apart.

Adaptable Voltage

The SEMEQ current sensor is meticulously designed to adapt to various conditions, operating within a voltage range of 100 to 240 VAC and frequencies of 50 to 60 Hz. This exceptional adaptability ensures its seamless integration in different industrial environments, providing you with the reassurance of compatibility.

Remote Configuration

One of the most empowering features is the ability to edit parameters remotely via an interface. This operational flexibility allows for precise adjustments in transmission cadence according to specific application needs, putting you in control of your current monitoring optimization.

Over-the-Air (OTA) Firmware Updates

SEMEQ’s electric current sensor supports firmware updates via OTA (Over the air) to stay ahead of technological demands. This feature allows remote updates, ensuring the device is always equipped with the latest improvements and features without physical intervention.

Measure Button and Bluetooth Low Energy 5.1 Communication

The sensor features a Measure button, enabling users to trigger measurements and manually transmit data. Additionally, it incorporates wireless communication via Bluetooth Low Energy 5.1, providing efficient, low-power connectivity for broader and more effective integration with other devices and systems.

How SEMEQ’s New Sensor Works

SEMEQ’s new electric current sensor is a highly efficient intelligent device crucial in detecting potential failures in electric motors and associated power circuits.

The sensor analyzes variables such as temperature, vibration, electric current, and other process factors to identify potential failure modes in electric motors.

This solution simplifies preventive maintenance and allows industrial plants to enhance machine reliability and uptime, improving productivity and profitability.

Benefits and Advantages of SEMEQ’s Electric Current Sensor

Below, we list some benefits of incorporating SEMEQ’s electric current sensor in your plant.

  • Continuous online monitoring
  • Early detection of anomalies
  • Prevention of unplanned downtime
  • Reduced operational costs
  • Competitive advantage through advanced maintenance practices

Ideal for industries using compressors, centrifuges, and drive motors. Contact SEMEQ for more information.

Monitoring

The SEMEQ electric current sensor plays a vital role in industrial plants. It enables continuous and precise monitoring, ensuring performance, safety, and operational efficiency are maintained at all times.

Quick Identification of Anomalies

By detecting abnormal current variations, such as overloads, short circuits, or component failures, the sensor provides insights for rapid interventions to prevent accidents or severe damage.

Prevention of Unplanned Downtime

Identifying potential issues before they become critical is crucial for maintaining safety and minimizing unplanned downtime.

Operational Cost Reduction

The electric current sensor helps reduce operational costs by optimizing resource use and enhancing efficiency.

Competitive Advantage

In a competitive environment, the precise process control and adjustments enabled by the sensor are not just essential, they can be the key to your operational success and efficiency. Discover how SEMEQ’s electric current sensor can give you the competitive edge you need.

Ideal Industrial Applications

The SEMEQ electric current sensor is versatile and practical for various industrial environments, particularly those using compressors, centrifuges, and drive motors. Its adaptable voltage and remote adjustment capabilities ensure efficient integration, flexibility, and simplified maintenance.

Contact Us

SEMEQ offers innovative, customized monitoring solutions to boost your business performance. We ensure operational efficiency in your industrial plant with advanced real-time monitoring tools. Contact us today to discover how SEMEQ’s electric current sensor can enhance your asset management. We’re ready to help elevate your industrial plant to the next level.

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Trends & Challenges in Remote Maintenance – The Future is Here but Also Facing Hurdles

In this modern age, remote maintenance has become a game-changer in the industrial world. It has completely transformed the way we approach equipment upkeep and operational efficiency. Today, in this blog post, we’ll discuss an important topic – remote maintenance for industrial machines and equipment. This allows experts to fix issues from far away without traveling to the site. It’s a pretty cool concept. But it also has some challenges that need to be understood.

 

First, what exactly is remote maintenance? Basically, it uses technology like computers, sensors, cameras, and machine maintenance software to monitor and control equipment remotely. Technicians can see data, view videos, and even make adjustments – all from their office hundreds of miles away! This can save huge time and money compared to sending staff to every breakdown.

 

Remote maintenance is becoming very popular across many industries like manufacturing, energy, transportation, and more. There are several key trends driving this growth:

 

  1. The technology keeps getting better and cheaper – Things like fast internet, cloud computing, AI, secure connections etc. When combined with machine maintenance software, it allows comprehensive remote oversight.
  2. Companies want to cut costs – Travel is expensive, as is having technicians idle between site visits. Remote capabilities reduce these expenses significantly.
  3. Skills shortage – There is a major lack of trained technicians, especially in remote areas. Being able to have a few experts handle multiple sites is extremely valuable.
  4. Improved productivity – Quicker detection and resolution of issues increases equipment uptime and output.
  5. Safety – Fewer technicians exposed to hazardous environments on-site.

 

It sounds great, right? So why aren’t all companies using remote maintenance yet? Well, there are still some important challenges:

 

  1. Integration – Getting new machine maintenance software and systems to work with older, existing equipment can be very difficult and costly.
  2. Security risks – Anytime industrial equipment is connected to the internet, there are cyber-security vulnerabilities to consider carefully.
  3. Organizational resistance – Some companies and workers are uncomfortable with (or distrustful of) new technological changes like this.
  4. Limited capabilities – Not everything can be done remotely yet. For complex issues, on-site staff may still be required.
  5. Telecommunications – Many industrial sites have poor internet/cellular connectivity, making remote capabilities difficult.

 

Overall though, the trends indicate remote maintenance capabilities will keep expanding rapidly across all industries. The benefits of reduced downtime, travel costs, workplace risks etc. are just too compelling.

 

Those are the key points in this fascinating shift in how critical equipment and infrastructure is maintained in any industrial setting. Companies must work to overcome the challenges through strategic planning, phased integration, comprehensive training and more. With proper preparation and utilizing a capable machine maintenance software, remote maintenance can be a game-changer in industrial operations!

Top Features to Look for in Machine Maintenance Software

Effective machine maintenance is essential to reduce downtime and increase output. Machine maintenance software has developed into a vital tool for companies, assisting in the optimization of maintenance procedures, the early detection of problems, and the preservation of equipment life. The efficacy and efficiency of your maintenance operations can be greatly impacted by the important aspects you should consider when choosing machine maintenance software.

The following are the top qualities to look for when getting machine maintenance software:

Predictive Maintenance

The most revolutionary aspect of contemporary maintenance software is predictive maintenance. Predictive maintenance is able to anticipate any malfunctions before they occur by employing sensors and data analytics. This function prolongs the life of machinery, minimizes unplanned downtime, and aids in proactive maintenance planning. Predictive maintenance gives maintenance staff useful insights by examining data trends and patterns, allowing them to solve problems as they arise.

Real-Time Alerts and Monitoring

Real-time monitoring enables continuous tracking of the status and performance of the equipment. This function includes gathering data via sensors and Internet of Things devices, which are then instantly evaluated. The system promptly notifies the maintenance staff in the event that it notices any abnormalities or situations that depart from the usual. This instant notification system keeps small issues from turning into significant failures by ensuring that difficulties are dealt with right away.

Comprehensive Analytics and Reporting

Robust reporting and analytics skills are essential for making effective decisions. Comprehensive reports on a range of maintenance-related topics, including work orders, equipment history, downtime analysis, and cost tracking, should be available through maintenance software. Trends, inefficiencies, and potential improvement areas may be found with the aid of advanced analytics. Maintenance managers may make data-driven choices to improve operational efficiency and cut costs with the help of thorough reporting.

Asset Management

It is crucial to track and manage the entire fleet of machinery and equipment within an organization. This requires a feature-rich asset management system. This entails keeping comprehensive records of every asset, including measurements for performance, warranty details, purchase date, and maintenance history. Efficient asset management facilitates planning for future investments, guarantees regulatory compliance, and maximizes the use of machines.

User-friendly Interface

An intuitive interface is essential to guarantee that the software is accessible and simple to use for any member of the maintenance crew. The interface should be straightforward to use with simple navigation, unambiguous directions, and visual aids like dashboards and charts. An interface that is well-designed lowers the learning curve, boosts user adoption, and reduces the risk of mistakes occurring when entering data and managing tasks.

Integration Capabilities

Integration capabilities are crucial to make sure that the maintenance software can interact with other systems in the company, such as IoT platforms, CMMS (Computerized Maintenance Management System), and ERP (Enterprise Resource Planning). Information can easily move between departments, increasing overall productivity and opening the door to a more comprehensive approach to maintenance management because of this interoperability.

Choosing the right machine maintenance software is crucial and can have a significant impact on the productivity and operational efficiency of an organization. Getting feature-rich maintenance software is essential for prolonging the life of vital equipment and lowering maintenance expenses, both of which are ultimately beneficial to the long-term performance of the organization.

Integrating Temperature Sensors with Industrial Control Systems

Integration of industrial temperature sensors with industrial monitoring solutions is essential for process optimization, safety, and efficiency improvement in current industrial settings. Real-time data from industrial temperature sensors can be utilized to track and manage a range of industrial processes. This is a comprehensive guide discussing the advantages and recommended steps for temperature sensor integration with industrial control systems.

The Importance of Temperature Sensors in Industrial Processes

Temperature sensors are essential for a wide range of industrial purposes. They assist in maintaining the ideal atmosphere, guarantee that equipment operates as intended, and protect against freezing or overheating. Precise temperature control is vital for product quality and safety in industries including manufacturing, food processing, pharmaceuticals, and chemical production, where accurate temperature monitoring is crucial.

The Advantages of Integration

  • Enhanced Process Management

Automatic modifications based on real-time data are made possible by the integration of temperature sensors with control systems. Increased uniformity and precision in the process result in higher-quality goods.

  • Enhanced Safety

Automatic temperature monitoring can identify abnormalities early on, averting potentially dangerous situations like equipment overheating or uncontrollably heated chemical reactions. This proactive strategy also improves workplace safety.

  • Enhanced Efficiency

The best possible use of energy is made possible by real-time temperature data. Systems may be configured to only run when absolutely essential, which lowers operating expenses and energy usage.

  • Predictive Maintenance

Constant temperature monitoring aids in the early detection of equipment faults. Proactive scheduling of maintenance may reduce downtime and increase the lifespan of equipment.

Action Items for Successful Integration

  • Pick the Correct Sensors 

Choose temperature sensors that are appropriate for the particular industrial application you have in mind. Consider factors like temperature range, precision, reaction time, and surrounding circumstances.

  • Ensure Compatibility 

Verify that the sensors work with the control systems you have in place, such as SCADA or PLC (Supervisory Control and Data Acquisition) systems. Compatibility guarantees smooth data processing and transfer.

  • Proper Installation

Attach sensors at vital locations where precise temperature measurements are necessary. Install according to the manufacturer’s instructions to guarantee accuracy and lifespan.

  • Calibration and Testing

Calibrate sensors on a regular basis to ensure accuracy. Thoroughly test the systems throughout the integration phase to make sure the sensors and control systems interact with each other and react to temperature changes appropriately.

  • Data Integration

Incorporate sensor data into the software of the control system. Set up the system so that it can analyze the data and carry out control actions according to preset criteria. This might entail adding unique logic to your SCADA or PLC software.

  • User Training 

Educate staff members about the recently integrated system. Make sure they know how to read data, react to warnings, and maintain sensors and control systems on a regular basis.

 

The strategic integration of industrial temperature sensors with industrial control systems yields substantial advantages for process control, safety, efficiency, and maintenance. Companies can fully leverage temperature monitoring technology through appropriate selection of sensors, verification of compatibility, adherence to best practices for installation, and integration of data. This integration helps create safer and more reliable industrial processes in addition to increasing operational efficiency.

 

Remaining ahead of the curve in the quickly changing field of industrial automation may be achieved through the efficient integration of temperature sensors. Adopt this technology to improve the accuracy, safety, and efficiency of your industrial operations.

Motor Circuit Analysis: A Powerful Predictive Maintenance Technique

Motor circuit analysis (MCA) is an essential predictive maintenance technique utilized by equipment performance monitoring services to assess the condition of critical rotating machinery. By performing a comprehensive series of electrical tests, MCA provides in-depth diagnostic data about the operating health and performance of motors, generators, servomotors and other electro-mechanical assets.

 

This powerful analysis method allows for early detection of developing faults like insulation degradation, voltage imbalances, overheating, misalignment and more – often before they lead to major failures or unexpected downtime. For facility operators, implementing MCA as part of a world-class condition monitoring program is invaluable for maximizing asset reliability, availability and productive uptime while minimizing costs and safety risks.

The MCA Diagnostic Process

To assess the electrical condition of a motor or generator, motor circuit analysis evaluates key properties of the equipment’s circuitry including resistance, inductance, capacitance, impedance, phase angles, current/frequency ratio, dissipation factor, and static/dynamic electrical signatures. A typical MCA diagnostic follows this process:

 

  • With the asset de-energized, take offline electrical tests to establish baseline readings
  • While the equipment is running, perform online current analysis and voltage analysis
  • Analyze the data to identify any anomalies or deviations from established benchmarks

 

Even subtle changes in these electrical properties can indicate issues like turn-to-turn shorts, ground faults, contamination, loose connections, and other developing faults. By detecting them early through motor circuit analysis, MCA allows the opportunity for remedial actions before catastrophic failures occur.

Applications Across Industries

Motor circuit analysis has applications across numerous industry sectors wherever critical rotating equipment is utilized, such as manufacturing, power generation, oil and gas, mining, utilities, and more. Whether for AC or DC motors, generators, servos or other rotating assets, MCA provides invaluable equipment performance monitoring services.

 

For these facilities, the key benefits of implementing motor circuit analysis as part of a comprehensive predictive maintenance program include:

 

  • Improved asset reliability and availability through early fault detection
  • Extended useful operating life by identifying issues before major damage
  • Enhanced workplace safety by mitigating electrical hazards and fire risks
  • Comprehensive equipment condition data even during normal operations
  • Optimized maintenance strategies, production schedules and budgets

 

By continuously monitoring asset health through techniques like MCA, facilities can transition away from reactive maintenance approaches. This proactive, predictive maintenance strategy increases uptime, reduces costly unexpected breakdowns, and improves overall risk management.

 

Whether for new installations or aging assets, motor circuit analysis should be a core component of the predictive maintenance program at any facility that relies on rotating machinery. The detailed diagnostic insights it provides about electrical system condition allows maintenance teams to plan repairs during scheduled outages and optimize equipment lifetime performance and reliability.

 

Motor circuit analysis offers a powerful condition monitoring solution for pinpointing developing faults before they result in downtime events. By leveraging MCA’s in-depth electrical signature analysis as part of equipment performance monitoring services, operators can make data-driven decisions to increase asset availability, productivity and operating safety while minimizing costs and risks.

Why Your Industrial Operation Needs Real-Time Predictive Machine Performance Monitoring

In industrial settings, machines are very important. They do the hard work of manufacturing products and handling automation tasks. But did you know that machines need maintenance too? Just like a car, industrial machines can break down if not taken care of properly through routine maintenance and real-time monitoring.

 

Predictive maintenance is a smart way to keep machines running smoothly. It uses special machine performance monitoring services, wireless sensors, and software to check on machine performance. These services watch for any problems before they lead to malfunctioning and then failure. That way, maintenance can be done at the right time to prevent bigger issues.

 

This blog post explains why predictive maintenance through machine monitoring is so valuable. We’ll cover the major advantages it provides industries across sectors.

Real-Time Tracking

One key advantage of industrial monitoring solutions is real-time tracking. Special sensors are placed on machines to constantly measure things like temperature, vibration, pressure and more. The machine data is monitored by software that looks for any unusual readings.

 

For example, say a machine’s vibration levels get too high. That could mean a bearing is going abnormal and needs replacement soon before it causes the machine to break down.

 

The real-time monitoring alerts the team when readings go outside the normal ranges. This allows them to inspect the machine and fix small issues before they turn into expensive maintenance!

Workflow Improvements

Over 80% of companies have faced unplanned downtime due to machine failures in recent years. Downtime is very costly and disruptive to workflows.

 

Industrial monitoring solutions help optimize workflows by predicting machinery issues ahead of time. This allows maintenance to be scheduled during already-planned stoppages rather than unexpected breakdowns.

 

Let’s look at a cement mill for example. These big mills grind rock into the powder that becomes cement. A monitoring system tracks things like the mill’s motor current, vibration, temperature, material flow, and more.

 

If motor current starts rising abnormally, it may signal a blockage or mechanical fault. Without monitoring, this could burn out the motor and cause a fire hazard! But the system alerts teams to check on the issue before an emergency shutdown is required.

 

With predictive insights, cement makers can schedule the perfect time for maintenance that avoids disrupting the entire workflow. This maximizes productivity and efficiency.

Improved Safety

Another key benefit of machine performance monitoring services is improved workplace safety. Monitoring helps stop dangerous situations before they can occur.

 

For example, if a motor’s temperature readings are too high, it could mean lubrication problems that lead to overheating and fire risks. The early alerts give teams a chance to shut it down and fix the issues safely.

 

Real-Time Monitoring also reduces the need for major repairs by catching small faults early. This minimizes situations where technicians have to make complex, high-risk repairs under time pressure before serious failures happen.

 

In simple words, real-time machine performance monitoring helps keep both equipment and people safe throughout manufacturing facilities.

Higher Product Quality

Nobody wants to buy low-quality or defective products. That’s why monitoring machine performance is so important for quality control.

 

Monitoring systems integrate with quality systems to capture data from all machines and sensors. By analyzing this data, they can identify any machine faults or deviations that could lead to quality issues in the final products.

 

Let’s say a plastic injection molding machine’s temperature is reading too low. This means the plastic won’t flow properly, resulting in defective parts. Monitoring software can automatically pause the line and alert quality teams before a whole batch of pool-quality products gets manufactured.

 

With this level of monitoring, manufacturers can ensure consistent high quality by immediately addressing anything that could negatively impact production quality.

Better Equipment Reliability

Monitoring also contributes to overall better reliability for all manufacturing machinery and assets. It enables true condition-based predictive maintenance.

 

Instead of routine maintenance at fixed intervals, which may be too soon or too late, monitoring data reveals the precise condition of each machine. This way, maintenance gets scheduled only when actually required based on equipment health.

 

For example, analyzing bearing vibration trends predicts when replacements are needed. The right spares and labor can be prepared to swap out the failing bearings during a scheduled downtime window. No unexpected breakdowns!

 

This condition-based approach ensures maintenance actions directly target the areas that need attention most. It eliminates unnecessary maintenance while also preventing untimely failures. The result is maximum reliability, uptime, and asset lifespan for all machines.

 

In summary, deploying machine performance monitoring services provides manufacturing companies incredible value through:

 

  • Real-time machine health tracking
  • Optimized maintenance workflows
  • Improved workplace safety
  • Consistent high product quality
  • Maximum equipment reliability and uptime

 

With all these benefits, predictive maintenance through industrial monitoring solutions is an absolute must-have for any modern manufacturing operation.

 

Don’t let unexpected machine failures, unplanned downtime, quality issues, and safety risks plague your facility. Stay one step ahead by investing in a proven machine monitoring platform today. Your operations, maintenance teams, and entire business will thrive!

Introducing Our Dynamic Partnership: Transforming Laser Shaft Alignment with HAMAR

We are thrilled to announce a game-changing collaboration redefining Laser Shaft Alignment in the southern United States.

 

SEMEQ SYSTEMS and HAMAR LASER, renowned for their top-notch products like the X-Series™ Laser Shaft Alignment, have joined forces. As authorized distributors of Hamar Laser in Texas, Oklahoma, Louisiana, Arkansas, Missouri, and Iowa states, we are excited to bring you the best-in-class X-Series™ Laser Shaft Alignment products, known for their unwavering reliability and performance.

 

Our quest to expand and capture market share in the region led us to seek a partner who shares our vision for innovation and brings unique strengths and expertise;  we found the ideal match – a company with a diverse clientele and a proven history of delivering exceptional solutions in HAMAR LASER.

 

About HAMAR

 

For over 55 years, Hamar Laser Instruments has pioneered laser alignment, with 34 years dedicated to shaft alignment applications. The company aims to enhance asset availability, drive customers’ profitability, and reduce operational costs. Hamar Laser is committed to innovation and clients’ success and delivers cutting-edge solutions that empower customers to thrive.

 

 X-SERIES PRODUCTS

 

Discover the Innovation Behind Unidirectional Dual-Beam™ and Dual-Fan™ Technology

 

The X-Series™ Laser Shaft Alignment products are designed with your ease of use in mind. Our Hamar software has undergone rigorous development to ensure user-friendliness, requiring minimal training even for complex applications. We aim for simplicity that instills confidence and comfort in our users, making the technology feel like second nature.

 

Safety Features in the X-Series™

 

The X-Series™ is designed with your safety in mind, and it incorporates multiple safety features, including rugged IP65 Windows® tablets and IP67 laser heads and targets suitable for harsh environments. Bluetooth® technology enables wireless communication between the tablet, laser, and target, enhancing safety around rotating equipment. Small-diameter laser beams and narrow-line laser fans maximize the PSD sensor measuring range, enhancing safety compared to competitors’ more comprehensive laser lines. With these safety features, you can feel confident and secure about the operation of the X-Series™.

 

Advantages of Laser Alignment Systems Over Indicators

 

The X-Series™ Laser Shaft Alignment products offer advantages over traditional methods like dial indicators. Determining the rotation axis of one shaft relative to another in shaft alignment is crucial for eliminating misalignment. Conventional methods could be more convenient, precise, and time-consuming, requiring interpolation of readings, compensation for bracket sag, and manual calculations, complicating the process. The X-Series™ Lasers streamline alignment by recording position and angular data using the software while rotating the laser and target, capturing up to 16 points/second. This method calculates and subtracts mounting errors from the raw data, providing highly accurate alignment without manual calculations and offering a hassle-free experience.

 

Unlocking Enhanced Precision and Flexibility with Dual-Beam™ Detector Technology

 

Our patented Dual-Beam™ technology is a game-changer in laser alignment systems. It allows for simultaneous measurement of offset and angle with just one PSD, boosting system accuracy by an impressive 50%. We conduct a meticulous 500-point calibration on the PSD, setting a new industry standard for accuracy that surpasses competitors’ systems by up to 15 times. With this level of precision and accuracy, you can trust the performance of our Dual-Beam™ technology.

 

 

But the innovation continues beyond there. With Dual-Beam™ technology, you gain an extraordinary angular range of +/- 12 degrees, ensuring consistent laser targeting even in long-distance applications. Plus, our angular resolution surpasses the highest angular tolerance by a factor of 10, guaranteeing unmatched precision in alignment processes.

 

Our blinking laser technology seamlessly compensates for ambient light variations to elevate performance further, ensuring reliable measurements regardless of environmental conditions.

 

 

Outperforming Competitor’s Mid-Range Systems: Introducing Entry-Level Dual-Fan™ Detector Technology

 

Our Dual-Fan™ technology redefines entry-level shaft alignment systems, delivering unmatched economy, versatility, and accuracy. With Dual-Fan™, you can achieve exact measurements of offset and angularity simultaneously, thanks to two 0.5-degree laser fans and two 20 mm PSDs.

 

 

Unlike competitors’ lasers, which pose safety concerns with wider fan spreads, our specially designed laser fan extends only to 1 inch (25.4 mm) at 15 feet (4.6 m), ensuring safer operation without compromising accuracy.

 

Moreover, Dual-Fan™ offers a full angular measuring range across the entire operating distance between the laser and the target. This eliminates the limitations of the “cross-fire” lasers face, which experience restricted angular measuring ranges beyond 3 feet (and 1 m). Conducts a meticulous 40-point calibration procedure on the P to further enhance accuracy, making our Dual-Fan™ technology up to 5 times more precise than competing mid-priced systems. Blinking laser-fan technology also compensates for ambient light, guaranteeing consistent environmental performance.

 

 

Durable, Sealed IP67 Casings

 

All X-Series™ alignment hardware “heads” are compact, sturdy, and engineered to swiftly and effortlessly deliver precise, reliable alignment data. They boast an IP67 rating for waterproofing (submersible up to 3 feet or 1 meter), ensuring durability in harsh conditions. Our handheld display units feature high-resolution, color touchscreens. Unlike competitors, our wireless transmitter is securely enclosed within the heads, eliminating the risk of connector or cable failure.

 

 

Embedded Technology

 

We prioritized user-friendly design, integrating “smart” LEDs for intuitive laser status indication at a glance.

 

Intuitive Software for Seamless Alignment

 

Our Couple6 software is as intelligent as our hardware, featuring Easy-Guide™ navigation with vibrant color screens that guide users effortlessly through each alignment step. Even beginners can achieve expert-level results with our 5-step process, culminating in easy report generation.

 

 

Revolutionary Live Move Screen for Precision Shaft Alignment

 

Introducing Duo-Plane™ Live Move screen, an innovative feature on the T-1290 5-Axis Target. Unlike traditional systems, Duo-Plane™ allows users to view vertical and horizontal alignment screens simultaneously, eliminating the need to rotate shafts. This groundbreaking technology saves valuable time, particularly on large machine applications where bolt tightening can cause machine movement, necessitating realignment.

 

 

In our X-660 and X-770 3-axis systems, we introduce an intuitive 2-axis “live” display feature. This dynamic display showcases continuously updating graphics, clearly illustrating motor alignment along the horizontal or vertical axis. Simply rotate the shafts from 12:00 to 3:00 or 9:00 to activate the horizontal axis live move screen. The Couple6 system seamlessly transitions to display alignment results, allowing you to adjust the motor position without the need to reacquire data.

 

 

Effortless Precision with Extended PSD Measuring Area

 

Experience the convenience of our large 20-33 mm PSD measuring areas integrated into our target heads. Coupled with our uni-directional laser beams and an impressive +/- 8 to +/-12 degrees of angular range, you can bypass the time-consuming “rough” alignment process typically required during new machine installations. This translates to significant savings in labor hours each month! Simply attach the laser and target to the shafts and proceed to our Step 2 Laser Setup Screen, where you’ll find a live display of the angular alignment. Rotate the shafts, and you’re ready to capture data if you achieve readings for at least 90 degrees. If not, utilize the live display to roughly align the motor angle for data collection. It’s that straightforward!

 

 

Instant Support with On-Demand Training Resources

 

Always feel safe again with our comprehensive training resources available at your fingertips. Access our electronic manual directly within our Couple6 software by selecting the Help Menu or hitting F1. The correct page of the manual will automatically display, providing quick assistance whenever needed. Watch our on-demand training videos for a quick recap of any procedure. Compare this seamless support experience to our competitors’ cumbersome multi-page cheat sheets or lengthy manuals. With our intuitive software, training is primarily needed for more complex applications, ensuring efficient and hassle-free operation.

 

 

No Worries with Off-the-Shelf Software Display

 

With the X Series, you get the convenience of Windows 10 IoT Enterprise IP65 rugged tablets, available at most computer stores. Say goodbye to costly, proprietary display devices – if your tablet breaks, replacements are easily sourced.

 

 

Seamless Upgrade to Advanced Features

 

Upgrade your entry-level laser system to unlock advanced features effortlessly. Simply send your distributor or us a purchase order for the desired features, and within a day, you will receive a new license via email. Installation takes seconds, and voilà – the new features are ready to use in our Couple6 software!

 

 

Printing Reports Made Simple

 

With our tablets and PCs, printing detailed, customizable color reports is a breeze. Just plug the report into a printer and hit print. Need to email a report? No sweat! Select PDF in the print screen, attach the report to your email, and send it off. Easy as pie!

 

Continuous Software Updates at No Cost

 

We believe in constantly enhancing our software to serve our customers better. That’s why we provide free updates for life. With just a click on “Check for Updates,” Couple6 takes care of the rest.

 

 

The Advantage of Unidirectional Dual-Beam™ and Dual-Fan™ Technology for Long Spans

 

Long-distance applications pose challenges for traditional 2-laser/2-detector shaft systems. Even tiny angular movements can significantly affect readings, making alignment difficult, especially for the horizontal axis. Our uni-directional laser technology eliminates this problem. Unlike traditional systems, angular moves to the motor don’t impact the laser beam or offset values. This makes motor alignment remarkably easy, particularly over long distances.

 

 

Enhancing Equipment Reliability: a comprehensive guide

Maintaining equipment reliability is paramount to operational success in today’s industrial landscape. With the advent of technologies, companies can now access many tools and strategies to optimize equipment performance and minimize downtime. Let’s delve into some key components of effective equipment maintenance management and explore innovative solutions:

Machine Maintenance Software

Streamline your maintenance operations with a cutting-edge machine maintenance system. These platforms offer robust features such as scheduling, work order management, and asset tracking, enabling you to stay organized and proactive in your maintenance efforts.

Predictive and Prescriptive Maintenance

Say goodbye to reactive maintenance approaches and embrace predictive and prescriptive maintenance techniques. By harnessing the power of data analytics and machine learning algorithms, you can anticipate potential equipment failures and take proactive measures to prevent them, ultimately saving time and resources.

Sensors and Condition Monitoring

Equip your machinery with advanced sensors for real-time condition monitoring. Whether it’s vibration analysis, motor circuit analysis, or acoustics issuance analysis, these sensors provide invaluable insights into your equipment’s health and performance. They allow you to detect and address anomalies before they escalate into costly issues.

Lubrication Engineering

Effective lubrication engineering practices optimize equipment performance and prolong lifespan. Proper lubrication reduces friction and wear and helps dissipate heat and contaminants, ensuring smooth operation and minimal downtime.

Temperature and Humidity Sensors

Invest in heavy-duty temperature and high-accuracy humidity sensors for precise electrical control panels. Whether operating in extreme or sensitive environments, these sensors provide reliable data to help you maintain optimal working conditions and prevent equipment damage.

Industrial Monitoring Solutions

Leverage industrial monitoring solutions tailored to your specific needs. From comprehensive equipment performance monitoring services to high-temperature applications with sensor monitoring, these solutions offer customizable features to meet the unique challenges of your industry.

By integrating these tools and strategies into your equipment maintenance management framework, you can enhance reliability, minimize downtime, and unlock new levels of efficiency in your operations. Embrace innovation and stay ahead of the curve in today’s competitive landscape with SEMEQ.

7 benefits of wireless sensors in predictive maintenance

Industry 4.0 combines various digital innovations and technologies, such as the Internet of Things and artificial intelligence, which can revolutionize industrial operations.

Today, the wireless sensor is one of the most widely used technologies in predictive maintenance. This device provides more accurate results on the state of the equipment since it has a very high sensitivity for detecting anomalous minimum vibrations. It can also be monitored online, even in industrial parks far from major centers.

If you still doubt the effectiveness of these devices, here are 7 benefits of wireless sensors in predictive maintenance.

1. Greater efficiency in production processes

Through process simplification and enhanced data accessibility, wireless sensors empower industrial parks to optimize productivity and minimize resource utilization on the factory floor.

According to Senai’s research, Industry 4.0’s digital technologies can increase the productivity of micro, small, and medium-sized companies by an average of 22%.

Industry 4.0, with its reliance on wireless sensors, significantly reduces maintenance and labor costs, allowing manufacturers to enhance productivity, quality, and revenue growth.

2. Safer, data-based decision-making

The benefits of the wireless sensor in predictive monitoring are significant. Using artificial intelligence technologies, a large volume of data can be collected to generate valuable insights for the operation of industrial parks.

Some examples are the performance of each piece of equipment, the useful life, the availability and reliability of each industrial plant, and the production potential of each park.

This data is collected using big data & analytics resources and read by professionals in predictive monitoring.

3. Savings on repairs and downtime

One of the main benefits of the wireless sensor in predictive maintenance is the regular checking of assets in advance, thus avoiding unexpected problems with repair maintenance.

In addition, because it is a wireless sensor, it is possible to save on cabling and labor for data capture since the process is automated.

4. Ease of monitoring hard-to-reach locations

One challenge before Industry 4.0 was carrying out predictive monitoring in places that needed to be made accessible or far from the center. This is because data collection was done manually, and the logistics of professionals at each piece of factory equipment had to be considered.

Today, wireless sensors monitor equipment in dangerous environments and places that are difficult to access or far from urban centers since the data is sent directly to the monitoring company’s database and analyzed by professionals with expertise.

5. Much more frequent monitoring

The wireless sensor for predictive maintenance allows monitoring to be done remotely much more frequently than traditional predictive maintenance, which used to be done once or twice a month, depending on the park’s size and the company.

In the traditional method, asset maintenance in the field requires the periodic dispatch of technical teams, which involves high costs in terms of time, resources, logistical complexity, and a low collection rate.

6. Avoids losses from downtime costs

According to a study by Emaint, factories lose between 5% and 20% of their production capacity due to downtime. This happens when equipment is unavailable, forming bottlenecks in the production line.

Around 82% of companies have experienced unplanned downtime in the last three years, according to a survey by Aberdeen Research. The report says unplanned downtime can cost a company up to $260,000 per hour.

The good news is that using predictive maintenance and artificial intelligence resources in data analysis helps prevent these machine failures and avoid unplanned downtime. Research by McKinsey shows that predictive maintenance reduces machine downtime by 30-50% and increases the useful life of assets by 20-40%.

7. Faster responses to problems

When a predetermined limit for machine operation is reached, an alert is generated immediately, and analysts have instant access to machine condition data. They can then conduct precise analyses through asset management software, in real-time and from anywhere.”

Avoid unforeseen events! Have wireless sensors monitoring your equipment 24/7

Your industrial park can also benefit from Industry 4.0 technologies in predictive maintenance. SEMEQ has know-how and experience in this area and uses traditional and predictive maintenance techniques. We currently have one of the most technological and sensitive sensors on the market, capable of identifying even minimal vibrations in each piece of equipment.

SEMEQ wireless sensor

  • 10kHZ sensitivity – detects bearing and gear failures;
  • Up to 3 years of battery life and replaceable;
  • No need to discard the sensor when the battery runs out;
  • 3G/4G connection and independent operation;
  • Triggers and variable load.

Our company has over 300 employees and a portfolio of more than 500 monitored factories in 45 countries.

Contact us to have your industrial park fully monitored.

How can predictive monitoring be applied in the food industry?

Technology is playing an increasingly important role. Predictive monitoring is one of the innovations that has profoundly transformed the food industry. 

This approach uses sensors, real-time data, and advanced analytics to predict equipment failures, optimize maintenance, and improve operational efficiency.

This article will explore how to apply predictive monitoring in food industries, discussing the benefits, challenges, and best practices for implementing this technology effectively.

Main challenges in industrial food plants

Maintenance in industrial food plants faces several crucial challenges to guarantee the continuity of operations and the quality of products. Some of the main ones include:

Risk Management

Risk management is a crucial obstacle in maintaining industrial facilities in the food sector. By their nature, operations involve inherent risks, making it essential to implement rigorous safety measures to safeguard equipment integrity and workers’ protection.

One strategy for tackling this issue is establishing a solid safety program, including a thorough risk assessment, identifying potential hazards, drawing up a standard operating procedure (SOP), and periodic staff training. In addition, predictive monitoring in the food industry is essential to mitigate the risk of failures and accidents.

Asset management

Asset management represents a substantial challenge in the maintenance of industrial facilities. Preserving the functional state of equipment and machinery is fundamental to ensuring their proper performance over time. However, asset management is a complex task that requires thorough planning and efficient execution.

One strategy to overcome this challenge involves adopting a data-driven approach, which entails collecting data related to equipment and machines to monitor their performance and identify potential problems at an early stage.

Availability of resources

The availability of resources is a third major challenge in the maintenance of industrial facilities. Maintenance requires a wide range of resources, including workforce, equipment, tools, and materials. However, ensuring these resources are readily available when needed can be challenging.

An effective strategy for tackling this challenge involves developing a detailed maintenance plan and efficiently allocating resources.  Ensuring that the necessary resources are available before maintenance execution is essential

Online predictive monitoring is the key to increasing plant performance.

Predictive monitoring in the food industry is a maintenance technique that uses sensors and analysis to predict failures in industrial equipment before they occur. This helps to: 

  • Avoid unplanned downtime;
  • Reduce damage to equipment;
  • Optimize the useful life of machines; 
  • Reduce energy costs;
  • Ensure the health and safety of employees;
  • Minimize environmental impacts.

Based on the analysis, ultrasound, and thermography results, periodic monitoring aims to reduce problems and increase the useful life of equipment. 

This approach allows for creating a targeted action plan to restore optimal equipment performance and increase your plant’s performance.

Why carry out online monitoring in the food industry?

By understanding maintenance models, it is possible to see the gains that can be made in the food industry through management based on planning, emphasizing predictive and preventive actions. These benefits include

  • More excellent continuity on the production line: by adopting predictive monitoring in the food industry, the company can significantly reduce the number of unscheduled stoppages on its production line;
  • Planned interventions: maintenance interventions are conducted in a planned manner without affecting ongoing production;
  • Increased equipment useful life: predictive maintenance helps to extend the lifespan of equipment, reducing the need for frequent replacements and saving resources.

In addition to these benefits, it is important to highlight another significant advantage. When maintenance management is based on predictive actions, corrective procedures become more precise because they are carried out according to prior planning.

The maintenance team is adequately prepared with the appropriate use of tools and protective clothing. It can handle the critical elements of the equipment with care, avoiding any direct contact with production.

How online predictive monitoring is carried out in plants

Online predictive monitoring in industrial plants is an essential strategy for efficient equipment maintenance and ensuring continuity of operations. It is based on advanced techniques that make it possible to identify problems before they cause unplanned downtime.

Use of online sensors

One of the bases of online predictive monitoring is the sensors installed in the plant’s strategic equipment. These sensors are chosen in advance by the technical team and the maintenance manager, taking into account the critical points of each machine. The great advantage is that these sensors are wireless, which means they are installed on several machines without complex cabling.

These sensors collect a range of data, such as vibration, temperature, pressure, and oil consumption. This information is sent to a central database that gathers data on the monitored equipment’s performance.

Implementing platforms for data monitoring

With the data collected by the sensors, it is possible to create a monitoring platform that is accessed remotely. This platform can be viewed on various devices, such as computers, tablets, and smartphones, giving maintenance managers flexibility.

When any anomaly is detected, even the slightest vibration, the platform sends an alert to the maintenance manager. This allows the technical team to act proactively, planning corrective actions before a serious fault occurs.

How SEMEQ can help with predictive monitoring in the food industry

SEMEQ is a company specializing in advanced predictive monitoring solutions, with expertise in meeting the specific needs of the food industry. Our innovative approach and cutting-edge technologies are designed to optimize equipment maintenance and ensure maximum operational efficiency in food processing facilities.

SEMEQ sensors

Our state-of-the-art sensors are designed to meet the highest standards of quality and reliability. They are ideal for the food industry, where precision and early detection of anomalies are essential. Wireless sensors monitor real-time vibration, temperature, pressure, humidity, and other critical parameters.

My SEMEQ

The My SEMEQ platform answers the need for real-time data monitoring and management. 

Maintenance managers in the food industry, with access to this platform, monitor the performance of their equipment remotely, receive instant alerts about any problems detected by the sensors, and access valuable information for informed decision-making.

If you are looking for reliable and customized predictive monitoring solutions for the food industry, SEMEQ is ready to help. 

Contact us

Contact us today to discuss your specific needs and find out how our sensors and platform can improve the efficiency and reliability of your maintenance operations.

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