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True or False: Introspect Technology only designs & manufactures test and measurement instruments for specific protocols. False! Beyond developing protocol-specific solutions, Introspect has also created tools with non-proprietary instrument interfaces, such as the 𝐏𝐕𝟐 𝐔𝐧𝐢𝐯𝐞𝐫𝐬𝐚𝐥 𝐀𝐜𝐭𝐢𝐯𝐞 𝐏𝐫𝐨𝐛𝐞. The PV2 dramatically enhances productivity by facilitating the attachment of a wide range of instruments to devices under test while minimizing circuit loading and maintaining signal integrity. Learn more about the PV2 below. #oscilloscope #testandmeasurement 

Track 6: Condition Monitoring, Fault Diagnosis, and Prognosis focuses on the essential technologies and methodologies for ensuring the health, safety, and reliability of electrical machines and systems. In an era where downtime and failures can result in significant costs, predictive maintenance and real-time monitoring are becoming indispensable. This track covers a range of topics, including advanced techniques for real-time condition monitoring (F01), fault detection and isolation (F02), and predictive algorithms for fault prognosis (F03). Attendees will explore the latest tools and strategies for detecting anomalies early, diagnosing faults accurately, and predicting machine failures before they occur. With a focus on both theoretical advancements and practical applications, sessions will address issues like signal processing, machine learning for fault detection, and sensor-based monitoring systems. Whether you're working to extend machine life, improve reliability, or reduce maintenance costs, this track will provide crucial insights into safeguarding the performance of electrical systems. Join industry leaders and experts to learn how condition monitoring and prognostics are transforming maintenance practices and minimizing operational risks. #condition_monitoring, #fault_diagnosis, #iemdc, #electric_machines

🔍 Understanding Sensor Calibration: Beyond mere adjustments, calibration services ensure error-free operation by addressing measurement uncertainties, leading to reliable data collection and analysis. 🛠️ Significance: Sensors such as load cells are susceptible to errors caused by aging, output drift, and overload. Annual recalibration is imperative to uphold accuracy and maintain consistent performance. 🔄 Ensuring Accuracy: Through regular recalibration, you can verify whether your sensor meets specifications over time, providing a calibration certificate as evidence of reliability. Don't underestimate the significance of calibration—it serves as the foundation for trustworthy measurements. Explore more about calibration services in our FAQ page: https://bit.ly/3W78lFS #SensorCalibration #PrecisionMeasurement #FUTEK

4 Channels High Accuracy Thermometers                                K Type: -200℃~+1370℃ T Type: -200℃~+400℃ J Type: -200℃~+1200℃ Accuracy：±(0.3%|t|+0.40)℃ YET-640 series is with principle of thermocouple temperature measurement, which is an instrument used to measure temperature. This series of instruments use cyclic measurement technology, therefore the sample rate can still be 2 times per second while four channels are working simultaneously with low power consumption. Benefit by the high-precision circuit principle and high-precision reference source inside the instrument, coupled with accurate factory calibration, the resolution of the instrument can be reached 0.01℃, and the factory accuracy can be reached ±(0.3%|t|+0.40)℃. Four channels to be measured temperature is supported by YET-640 series, and temperature graph can be displayed in single channel mode. And support the data alarm function, when exceeding or below the set value, the buzzer alarm, so as to detect the abnormality at the first time during quality inspection and adjust in time. Point calibration by users is supported by this instruments, and multiple points calibration can greatly improve the measuring accuracy of it (system composed of instrument and probe). This series of instruments supports the most commonly K, T and J types of thermocouple probes. The compatibility with multiple types of probes expands the application fields of the instrument. For instruments with recording function, the data during measurement can be stored in the instrument for user data analysis. When the data need to be viewed in a file after recording, the model YET-640L can be selected, the model YET-640X can be selected when the data needs to be analyzed with a chart after recording is completed. The PC software of YET-640X can monitor the temperature of multiple probes in real time. User can view the data recorded by the instrument on the PC software, and also can export files in a variety of formats. FEATURES:  Four channels  PC real time monitor (YET-640X)  K, T and J type thermocouple supported  Resolution up to 0.01℃  Factory accuracy ±(0.3%|t|+0.40)℃  Accuracy up to ±0.1℃ after point calibration  Measuring range -200~1370℃  Display temperature graph  Over-limit alarm function  Displaydata for maximum, minimum, average  Sample rate 2 times/second  20000 groups oftemperature data recordable (record version)  3 kinds offormatfiles generated (YET-640L)  Large dot matrix LCD screen, high-quality backlight  View and exp

Computer Vision is helping to make industrial operations safer and more efficient with 24/7 monitoring and real time alerts. Monitoring and reporting procedures at factories, refineries, manufacturing centers, and industrial facilities are crucial to operations. These systems help to spot potential hazards to keep employees safe and also track on-site materials and other activities of note. Now, Computer Vision on video cameras is helping to enhance safety and efficiency at industrial sites using tailor-made applications. Computer Vision enables 24/7, remote monitoring and instant alerts, which is solving real-world problems by catching safety hazards as they happen and delivering real-time data to help optimize performance. Check out the video showcasing Noema’s suite of Smart Factory applications, which include: - Liquid Leak Detection: Spot liquid leaks from tanks or other storage units instantly. - Flare Monitoring: Be alerted to flare-outs at refineries to avoid costly fines. - Analog Gauge Monitoring: Get real-time, digitized data for analog gauges and meters - Tank Level Monitoring: Monitor material level in industrial tanks and get alerts for level-changing events. Leverage Noema Computer Vision to make your operation safer and more efficient. Visit https://lnkd.in/giUPe2b5 to learn more about our CV and AI solutions. #Noema #CV #ComputerVision #SmartFactory #SmartRefinery #SmartFacilities #OperationsTechnology

Which temperature sensor measures the most accurate temperature reading? The accuracy of temperature measurement depends on various factors, including the type of temperature sensor used, the calibration process, environmental conditions, and the application requirements. Different temperature sensors have their own advantages and limitations in terms of accuracy, precision, response time, and cost. However, some commonly used temperature sensors known for providing accurate temperature readings include: 1. Resistance Temperature Detectors (RTDs): RTDs are based on the principle of electrical resistance change with temperature. They typically use platinum, nickel, or copper as the sensing element. Platinum RTDs (PT100, PT1000) are known for their high accuracy, stability, and linearity over a wide temperature range. RTDs offer high precision and are often used in industrial and scientific applications where accuracy is critical. 2. Thermocouples: Thermocouples consist of two different metal wires joined at one end, generating a voltage proportional to the temperature difference between the junction and the reference junction. While thermocouples are widely used due to their ruggedness, fast response time, and wide temperature range, their accuracy can vary depending on the type of metals used, calibration, and environmental conditions. Certain thermocouple types, such as Type S, Type R, and Type B, offer higher accuracy compared to others. 3. Thermistors: Thermistors are semiconductor devices whose resistance changes significantly with temperature. They offer high sensitivity and accuracy, especially over a narrow temperature range. Precision thermistors (such as NTC thermistors) can provide accurate temperature readings with high resolution, making them suitable for applications requiring precise temperature control, such as medical devices and laboratory equipment. 4. Platinum Resistance Thermometers (PRTs): PRTs are similar to RTDs but use platinum as the sensing element. They offer excellent accuracy, stability, and repeatability, particularly at cryogenic temperatures and in metrology applications. PRTs are often used as reference standards for calibration due to their high precision and linearity. Ultimately, the choice of temperature sensor depends on factors such as the required accuracy, temperature range, environmental conditions, cost considerations, and application-specific requirements. Calibration, proper installation, and regular maintenance are essential for ensuring accurate temperature measurements regardless of the sensor type used.

How to measure the current sensor (current sensor test method) 5. In-depth analysis of accuracy and resolution: Based on the linearity test results, the response ability of the sensor to small current changes is further measured. This step is a detailed analysis of the sensor's performance to ensure its accuracy in practical applications. 6, temperature impact and environmental adaptability test: After determining the accuracy and resolution of the sensor, its performance at different temperatures is tested. This step is to evaluate the adaptability and stability of the sensor under different environmental conditions. 7. Long-term stability and reliability evaluation: Based on the temperature test, the sensor is run for a long time to monitor the stability of its output. This step is to evaluate the long-term operation capability of the sensor to ensure its reliability in practical applications. 8, professional equipment assisted comprehensive performance test: Finally, a comprehensive performance test is performed using professional equipment such as current calibrators, oscilloscopes and multi-purpose meters. This step is the final validation of the overall performance of the sensor, ensuring that it meets the high performance requirements under a variety of conditions. The correct test method is essential to ensure the performance of the current sensor. Through the above test methods and guidelines, users and engineers can quickly and accurately evaluate the performance of current sensors to ensure the safety and efficiency of electrical systems. CHIPSENSE is a national high-tech enterprise that focuses on the research and development, production, and application of high-end current and voltage sensors, as well as forward research on sensor chips and cutting-edge sensor technologies. CHIPSENSE is committed to providing customers with independently developed sensors, as well as diversified customized products and solutions. "CHIPSENSE makes magnetic world charming!”

How to measure the current sensor (current sensor test method) 5. In-depth analysis of accuracy and resolution: Based on the linearity test results, the response ability of the sensor to small current changes is further measured. This step is a detailed analysis of the sensor's performance to ensure its accuracy in practical applications. 6, temperature impact and environmental adaptability test: After determining the accuracy and resolution of the sensor, its performance at different temperatures is tested. This step is to evaluate the adaptability and stability of the sensor under different environmental conditions. 7. Long-term stability and reliability evaluation: Based on the temperature test, the sensor is run for a long time to monitor the stability of its output. This step is to evaluate the long-term operation capability of the sensor to ensure its reliability in practical applications. 8, professional equipment assisted comprehensive performance test: Finally, a comprehensive performance test is performed using professional equipment such as current calibrators, oscilloscopes and multi-purpose meters. This step is the final validation of the overall performance of the sensor, ensuring that it meets the high performance requirements under a variety of conditions. The correct test method is essential to ensure the performance of the current sensor. Through the above test methods and guidelines, users and engineers can quickly and accurately evaluate the performance of current sensors to ensure the safety and efficiency of electrical systems. CHIPSENSE is a national high-tech enterprise that focuses on the research and development, production, and application of high-end current and voltage sensors, as well as forward research on sensor chips and cutting-edge sensor technologies. CHIPSENSE is committed to providing customers with independently developed sensors, as well as diversified customized products and solutions. "CHIPSENSE makes magnetic world charming!”

Computer Vision is helping to make industrial operations safer and more efficient with 24/7 monitoring and real time alerts. Monitoring and reporting procedures at factories, refineries, manufacturing centers, and industrial facilities are crucial to operations. These systems help to spot potential hazards to keep employees safe and also track on-site materials and other activities of note. Now, Computer Vision on video cameras is helping to enhance safety and efficiency at industrial sites using tailor-made applications. Computer Vision enables 24/7, remote monitoring and instant alerts, which is solving real-world problems by catching safety hazards as they happen and delivering real-time data to help optimize performance. Noema, a DSR Company, provides Computer Vision applications helping to solve real-world problems. Check out the video showcasing Noema’s suite of Smart Factory applications, which include: - Liquid Leak Detection: Spot liquid leaks from tanks or other storage units instantly. - Flare Monitoring: Be alerted to flare-outs at refineries to avoid costly fines. - Analog Gauge Monitoring: Get real-time, digitized data for analog gauges and meters - Tank Level Monitoring: Monitor material level in industrial tanks and get alerts for level-changing events. Leverage noema Computer Vision to make your operation safer and more efficient. Visit www.noema.tech to learn more about our CV and AI solutions. #Noema #CV #ComputerVision #SmartFactory #SmartRefinery #SmartFacilities #OperationsTechnology

🎙ProseraPod: Ask Greg McMillan - What role do you see dynamic simulation playing in the future of best temperature measurement selection? 🎙Greg's Response: Temperature is often the most important of the common measurements because it is an indicator of process stream composition and product quality. Temperature measurements are also essential for equipment protection and performance monitoring. In the process industry 99% or more of the temperature loops use thermocouples (TCs) or resistance temperature detectors (RTD). The RTD provides sensitivity (minimum detectable change in temperature), repeatability, and drift that are an order of magnitude better than the thermocouple (Table 1). Sensitivity and repeatability are 2 of the 3 most important components of accuracy. The other most important component, resolution, is set by the transmitter. Drift is important for controlling at the proper setpoint and extending the time between calibrations. Operators often adjust setpoints to account for the unknown drift. When the TC is calibrated or replaced, the modified set point no longer works. The RTD is also more linear and much less susceptible to electro-magnetic interference. The supposed issue of a slightly slower sensor response will be addressed in the next post on how to get the best installation. Thermistors have seen only limited use in the process industry despite their extreme sensitivity and fast (millisecond) response, primarily because of their lack of chemical and electrical stability. Thermistors are also highly nonlinear but this may be addressed by smart instrumentation. Optical pyrometers are used when contact with the process is not possible or extreme process conditions cause chemical attack, physical damage, or an excessive decalibration, dynamic, velocity, or radiation error of a TC or RTD. Simulations that include sensitivity, repeatability, drift, and EMF noise can show the advantage offered by the RTD. For much more knowledge, see the ISA book Advanced Temperature Measurement and Control Second Edition (use promo code ISAGM10 for a 10% discount on Greg’s International Society of Automation (ISA) books). 📖 https://lnkd.in/gx8mAaVB Learn more on the ProseraPod - https://lnkd.in/ej2K3U8r #Prosera #ProseraPod #InnovateAtProsera #ProcessControl #DynamicSimulation #AskGregMcMillan #DigitalTwins