Latest Test Equipment Articles

What is Preventive Maintenance?

What Is Preventive Maintenance? A proactive approach for electrical systems using inspections, testing, lubrication, and calibration to reduce downtime, improve reliability, extend asset life, and meet NFPA 70B/IEC standards with CMMS-driven schedules and condition monitoring.

What Is Preventive Maintenance?

Planned electrical upkeep using inspections and testing to prevent failures, maximize uptime, and ensure code compliance.

✅ Schedules PM for switchgear, transformers, relays, and cables

✅ Uses infrared scans, insulation tests, and thermography

✅ Aligns with NFPA 70B, IEC 60364, and IEEE 3007 guidance

Preventive maintenance is a crucial aspect of equipment management that offers numerous benefits, including improved reliability, reduced downtime, and better asset management. By implementing a well-structured maintenance plan and leveraging available tools and software, organizations can optimize their operations and ensure the long-term success of their equipment maintenance programs. To build organizational capability, teams can leverage targeted preventive maintenance training that standardizes practices and improves consistency across sites.

In today's fast-paced world, keeping equipment running smoothly and efficiently is vital for organizations across various industries. One of the most effective ways to achieve this goal is through preventive maintenance, a practice that ensures equipment's proper functioning and longevity. This article will dive into preventive care, its benefits, and the essential components of an effective maintenance program. In manufacturing, utilities, and facilities management, comprehensive industrial electrical maintenance programs help align day-to-day tasks with long-term reliability goals.

Preventive maintenance is a systematic approach to maintaining equipment by performing routine tasks and inspections to prevent equipment breakdowns, increase reliability, and extend the operational life of assets. This proactive strategy focuses on maintaining equipment in optimal working condition to avoid unexpected failures and reduce downtime. Many organizations align their procedures with NFPA 70B 2023 to ensure maintenance activities meet recognized best practices and safety expectations.

One of the main benefits of adopting a preventive maintenance program is improved equipment reliability. Regularly scheduled maintenance tasks and inspections help identify potential issues before they escalate into costly failures. This, in turn, minimizes downtime, increases production efficiency, and reduces overall maintenance costs. Regular routes often include periodic electrical testing to validate equipment condition and detect degradation before it impacts operations.

Another key advantage is the role that preventive maintenance plays in asset management. By implementing a well-structured maintenance plan, organizations can better understand the current condition of their assets, predict equipment life cycles, and make more informed decisions regarding replacements and upgrades. Linking asset records with structured electrical troubleshooting procedures helps teams interpret failure modes and refine replacement strategies.

Creating a preventive maintenance plan requires a systematic approach, beginning with identifying all equipment and assets that need maintenance. Organizations should then develop a maintenance schedule based on the manufacturer's recommendations, historical data, and specific operational requirements. A comprehensive plan should also include procedures for routine inspections, equipment cleaning, component replacement or repair, and guidelines for documentation and record-keeping. Typical routines may specify checking insulation resistance on critical circuits to benchmark health and schedule timely interventions.

A common question when discussing preventive maintenance is the difference between this approach and predictive maintenance. While both strategies focus on preventing equipment failure, predictive maintenance uses advanced technologies and data analysis to predict when a component is likely to fail. This allows organizations to schedule maintenance only when necessary, thus optimizing resources and minimizing downtime. For rotating assets, periodic electric motor testing supports both preventive and predictive approaches by revealing trends in winding and bearing condition.

The essential components of a preventive maintenance program include a well-defined maintenance schedule, documentation and record-keeping systems, trained personnel, and appropriate tools and technologies. In addition, a successful program should be flexible and adaptable, allowing organizations to adjust based on feedback, performance metrics, and evolving needs.

Determining the frequency of preventive maintenance tasks depends on various factors, such as the type of equipment, its usage, environmental conditions, and manufacturer's recommendations. Maintenance should generally be performed regularly to ensure the equipment remains in optimal working condition.

Organizations can take advantage of various tools and software solutions available in the market to streamline the preventive maintenance process and improve efficiency. These technologies can help automate the scheduling of maintenance tasks, generate reports and analytics, track inventory and spare parts, and facilitate communication among team members.

Electrical Test Equipment Channel

Data Logger Explained

Data logger for electrical engineering applications, enabling data acquisition from sensors, high-resolution measurement, time-series recording, telemetry, calibration, and IoT monitoring for power quality, energy metering, equipment diagnostics, and load profiling.

What Is a Data Logger?

A data logger is a device that acquires, timestamps, and stores electrical sensor data for monitoring and analysis.

✅ Logs voltage, current, frequency, and power quality metrics

✅ Interfaces via RS-485, Modbus, CAN, Ethernet, or wireless IoT

✅ Supports timestamping, calibration, alarms, and long-term storage

A data logger (or sometimes called a "datalogger") is a specialized electronic device that measures and records specific data over a certain period of time or in relation to its location either with a built-in instrument or sensor or via external instruments and sensors.
Datalogging is a term used to describe using a device to collect data through a sensor. That way, the data can be analyzed and saved and then the results can be output and the data collection and analysis performed. For teams integrating loggers into power systems work, a grounding in electrical testing concepts ensures proper sensor selection and safety.

A Data logger is commonly used in experiments and in data monitoring systems when there is a desire to harvest information faster than a human being can possibly collect the information, especially when the accuracy of the data is important. When verifying signals during setup, pairing a logger with a handheld DMM and reviewing how to use a digital multimeter can improve measurement accuracy and troubleshooting efficiency.

A Data logger varies between most general-purpose types of equipment for use in a range of measurement situations, to a very specific use in measuring one specific environment. It is most commonly used for general purpose applications. However, data loggers may remain as static devices with only a limited number of changeable parameters. In many data logging situations , electronic type dataloggers have mostly replaced chart recorders. In facilities where legacy panels are common, an analog multimeter can provide immediate spot-checks that complement long-duration logger trends.

A Data logger collects detailed information from an electronic sensing instrument over an exact period of time, usually performed at predetermined intervals.
There are various examples of the kind of information a data logger can collect, including: temperature, sound frequency, vibration, time, light intensity, electrical current, pressure. When capturing electrical parameters, confirming conductor integrity with a megohmmeter helps ensure safe and reliable measurements.
Data logger applications include: specific conditions like a warehouse, a production room, a refrigerator, a freezer, or a sterilizer. For troubleshooting compressed air leaks or partial discharge near monitored equipment, correlating events with acoustic imaging can pinpoint sources more quickly.
A Data logger may be used as a stand-alone configuration or it can be connected to a computer. Before integrating a logger with energized circuits, pre-commissioning with an insulation resistance tester reduces the risk of nuisance faults during runs.
A Data logger can record temperature, which is usually recorded by a thermocouple, a thermistor, or a resistance temperature detector (RTD)
A Data logger may be configured to include: wiring, multiple channels, or by self-contained instruments
For multi-channel deployments on motors or switchgear, checking insulation resistance of connected assets is a prudent preventive step.
A Data logger can be calibrated to an appropriate tolerance. However, the calibration should be National Institute of Standards and Technology (NIST) traceable.
A Data logger can be used to qualify environmental chambers, steam sterilizers, warehouses, and other controlled environments
Remember, when using a data logger, proper probe placement is an essential aspect of data collection.

Electrical Test Equipment Channel

Electrical Troubleshooting: Step-by-Step

Electrical troubleshooting is the process of diagnosing and fixing problems in power systems, circuits, or components. It involves testing, identifying faults, and restoring safe, reliable operation in residential, commercial, or industrial settings using specialized tools and expertise.

What is Electrical Troubleshooting?

Electrical troubleshooting is the methodical approach to detecting and resolving faults in power systems.

✅ Identifies and fixes wiring, circuit, and equipment issues

✅ Restores system safety and operational reliability

✅ Applies diagnostic tools for fast fault detection

Visit Our Electrical Troubleshooting Training Course

It is a crucial skill for diagnosing and resolving energy issues in various systems. Whether it involves a tripped circuit breaker, faulty wiring, or malfunctioning equipment, this process saves time, enhances safety, and prevents further damage to power systems. Workers must be proficient in identifying and solving power faults, which is key to maintaining operational efficiency and ensuring workplace safety. Learn how to perform accurate fault detection with our guide on How to Use a Digital Multimeter, a key tool in power system maintenance.

Common Causes of Power Problems

Problems often arise from a range of sources, including tripped circuit breakers, short circuits, and defective components. Circuit breakers are designed to protect power circuits from overloads by automatically cutting off the flow of electricity when a fault is detected. When a breaker trips, it is one of the most common causes of power issues, leading to interruptions in the power circuit. Workers must thoroughly inspect the breaker and surrounding wiring to identify potential faults and restore functionality.

Short circuits are another frequent cause of many problems. A short circuit occurs when electricity flows along an unintended path, bypassing the proper load. This not only damages components but can also pose serious safety risks. Workers must use a combination of tools and experience to trace the source of the short circuit and repair the system. Our Electrical Testing section explains how testing methods support maintenance and ensure system integrity.

Troubleshooting for Specific Systems

Electrical troubleshooting methods can vary significantly depending on the type of system involved. Each system presents unique components, failure modes, and safety considerations. Below are examples of how troubleshooting is applied in different environments.

Motors

Motors are central to industrial operations and require careful analysis of both power and control circuits. Technicians typically:

Check for three-phase voltage balance and continuity
Inspect motor windings with insulation resistance testers
Test start/stop circuits and contactors
Monitor for overheating, vibration, or noise

Troubleshooting motors often involves verifying overload protection settings and ensuring that all three power legs are properly energized.

Lighting Circuits

Lighting failures can stem from simple issues like burned-out bulbs or more complex wiring problems. Common steps include:

Testing wall switches and dimmers
Inspecting for loose connections at fixtures and junction boxes
Using voltage testers to verify live conductors
Checking for flickering caused by shared neutrals or poor grounding

Lighting systems also demand attention to load ratings and proper ballast operation in fluorescent or HID fixtures.

HVAC Systems

HVAC troubleshooting integrates both electrical and mechanical diagnostics. Since these systems rely on thermostats, relays, and compressors, electricians often:

Test control voltages and low-voltage transformer outputs
Inspect contactors, capacitors, and motor windings
Confirm power supply to blower motors and compressors
Use clamp meters to monitor current draw and identify overload conditions

HVAC systems require a comprehensive understanding of control logic and safety interlocks, especially in rooftop units or complex building automation systems.

Real-World Electrical Fault Examples and Diagnostic Steps

Electrical faults can occur in many forms, from equipment malfunction to circuit failure. Below are three common scenarios with step-by-step troubleshooting approaches to help isolate and resolve issues effectively.

Dead Wall Outlet in an Office

Problem: A computer workstation suddenly shuts off, and the outlet no longer provides power.

Troubleshooting Steps:

Check if other outlets on the same circuit are also dead.
Inspect the electrical panel for a tripped circuit breaker and reset it if needed.
Use a multimeter to test for voltage at the outlet.
If voltage is absent, remove the cover and check for loose wires or burned terminals.
Trace wiring back to the previous live outlet or junction box to identify breaks in continuity.

Resolution: A loose neutral wire in a junction box upstream was found and secured, restoring power to the outlet.

Three-Phase Motor Won’t Start in a Manufacturing Line

Problem: A production motor fails to start when engaged from the control panel.

Troubleshooting Steps:

Verify that control signals from the start button and contactor are functioning.
Use a multimeter or clamp meter to check incoming voltage on all three phases.
Inspect motor leads for continuity and signs of insulation breakdown.
Confirm overload relay settings and test fuses in the motor starter.
Measure resistance across motor windings to rule out internal faults.

Resolution: One phase was found to have an open fuse, causing a single-phasing condition. Replacing the fuse restored proper operation.

Intermittent Lighting Failure in Commercial Building

Problem: Overhead lights flicker randomly throughout the day in one section of a building.

Troubleshooting Steps:

Observe when and where flickering occurs to determine a pattern.
Test voltage at the lighting panel and branch circuits during operation.
Use a data logger or power quality analyzer to check for voltage drops or spikes.
Inspect wiring and connections at affected fixtures and switches.
Check neutral connections and grounding integrity.

Resolution: A corroded neutral connection in a junction box was causing unstable voltage. Cleaning and tightening the connection eliminated the flickering.

Using a Multimeter for Troubleshooting

A multimeter is an essential tool in testing and inspecting. It measures voltage, current, and resistance, helping workers diagnose faults in power circuits. By testing different points in a circuit, a multimeter can detect irregularities in power flow that may indicate a wiring problem or a faulty component. This systematic approach allows workers to identify the problem area and implement the appropriate repairs accurately. Whether it’s a short circuit or an issue with a specific device, a multimeter helps save time and prevent guesswork during the diagnosing process.

Safety Precautions

Safety is paramount in diagnosis, as even minor mistakes can lead to serious injuries. Before beginning any diagnostic work, it is vital to turn off the power supply to the affected area. Workers should always wear proper personal protective equipment (PPE), such as insulated gloves and safety goggles, to minimize the risk of arc flash and shock. Additionally, using insulated tools and following established safety guidelines can prevent accidents while testing and inspecting power systems. Explore our Preventive Maintenance Training resources to reduce equipment failure and improve reliability.

Identifying Faulty Components

Faulty components, such as damaged wiring, defective light bulbs, or worn-out parts, can cause a variety of power problems. When diagnosing potential problems, workers should conduct both a visual inspection and multimeter testing to detect issues. Signs of wear, discoloration, or physical damage often point to the need for replacement. Once the faulty component is identified, replacing it promptly can prevent further damage and restore the proper functioning of the system.

Best Practices

To ensure accuracy and efficiency, following best practices is essential during the testing and diagnosing process. Workers should start by using schematic diagrams to understand the layout of the power circuit, helping them trace the connections and identify potential faults. Systematic testing, starting with simpler checks and progressing to more complex procedures, can also help eliminate possible causes one by one.

Documenting the findings at each step is crucial, as it allows workers to track patterns and recognize recurring issues. This not only assists in the immediate repair but can also provide valuable insight for preventive maintenance.

Preventing Power System Interruption and Failure

Regular preventive maintenance is key to avoiding frequent problems and prolonging the life of power systems. Scheduling routine inspections, replacing worn-out components, and addressing minor issues before they escalate can minimize the need for frequent testing. By adopting a proactive approach, workers can ensure the reliability and safety of systems while preventing costly downtime.

Electrical Test Equipment Channel

How to Test a Contactor Explained

To test a contactor, check coil voltage, inspect for continuity across contacts, and verify proper operation with a multimeter. Ensure power is off before testing. These steps help identify failure in HVAC or motor circuits.

How to Test a Contactor?

A contactor test ensures the device operates correctly and safely in electrical systems. Follow these key steps:

✅ Check coil voltage and verify it matches the contactor's rating

✅ Use a multimeter to test continuity across power and auxiliary contacts

✅ Inspect for mechanical movement and clean contact surfaces if needed

Visit Our Electrical Troubleshooting Training Course

How to Test a Contactor is a critical procedure in diagnosing and ensuring the reliability of electrical systems, especially in air conditioning and heating applications. When they fail, they can cause system breakdowns, continuous running, or intermittent performance, which can be costly and unsafe. Testing allows electrical workers to verify its operational integrity, pinpoint potential issues, and determine if a replacement or repair is necessary. This article outlines a clear, step-by-step approach to safely and accurately test a contactor using a multimeter, empowering workers to maintain efficient and dependable equipment performance. For a deeper understanding of the tools involved in this process, see our electrical test equipment guide, which covers essential instruments for accurate insulation resistance testing.

Understanding the Purpose of a Contactor

It is a device used to manage electrical flow within a system. In air conditioning units, it regulates the connection between various components, like compressors and fans, to control cooling and heating. When the unit is powered on, it responds to a low-voltage signal, activating a magnetic field that enables higher-voltage connections. There are two primary types of contactors: single-pole and double-pole. Single-pole types have one magnetic coil for one circuit, while double-pole ones include two coils for dual-circuit connections. Recognizing these distinctions is important for accurate testing. The accuracy of an insulation resistance test depends on using the right device—learn more in our insulation resistance tester article.

Symptoms of a Malfunctioning Contactor

A failing contactor may cause various operational issues, such as continuous running, clicking sounds, or visible wear and tear. Continuous running might indicate a stuck unit, causing the air conditioner to remain active. Clicking sounds can result from electrical problems, but could also point to thermostat or compressor issues. Additionally, physical damage, known as pitting, often occurs from temperature extremes or debris, potentially leading to functional failures over time. By identifying these symptoms early, electrical workers can take preventive actions before major malfunctions occur. To implement a consistent maintenance schedule that includes insulation testing, read our preventive maintenance training overview.

Safety First: Power Isolation

Before performing any tests, ensure all power is disconnected from the contactor. Confirm with a voltage tester or multimeter. Electrical testing can be dangerous—follow safety protocols and wear appropriate PPE.

Step-by-Step Guide to Testing a Contactor

Using a multimeter is a standard method for testing. Here is a step-by-step process to guide you:

1. Remove Power to the Line Side

Turn off power to the line (L) side. Detach each wire, keeping them organized for reattachment later. Removing power from this side minimizes risk and enables accurate readings.

2. Detach Wires from the Terminal Side

Similarly, disconnect the wires on the terminal (T) side. Ensuring all wires are removed will prevent interference with the readings during testing.

3. Activate the Control Switch

Turn the control switch to the "on" position, listening for a click and a hum. This sound confirms that the magnetic coil is engaging correctly.

4. Set Up the Multimeter

Connect the multimeter’s red lead to the ohm terminal and the black lead to the common terminal. Turn on the multimeter, then touch the leads together to confirm a 0-ohm reading.

5. Line-to-Terminal Continuity (0 Ω)

To evaluate each line-to-terminal connection, place the red lead on L1 and the black lead on T1. A correct connection should show a 0-ohm reading. If the reading varies, it suggests an issue with that segment.

6. Verify Coil Activation

Engage the control switch to test the coil. The absence of an audible click could mean the coil is not receiving proper voltage or is defective.

7. Voltage Verification (e.g. 24 VAC)

To measure voltage, switch the multimeter to the voltage setting, placing the red lead to the volts terminal. Power the coil, and check each connector for the correct voltage. This step confirms the coil’s voltage integrity. If you're testing electric motors, visit our page on electric motor testing to explore diagnostic techniques that help detect insulation breakdown.

8. Testing Coil Resistance (10–100 Ω)

To evaluate the condition of the contactor coil, begin by removing all power from the system and disconnecting the coil wires. Set your multimeter to the resistance (ohms) setting.

Place one probe on each of the coil terminals.
A healthy coil should show a resistance value typically between 10 and 100 ohms, depending on the model and manufacturer specifications.
Readings below 10 ohms may indicate a shorted coil, while readings above 100 ohms (or infinite resistance) suggest an open or damaged coil.

This test helps confirm whether the coil is intact or needs replacement. Always refer to the equipment’s documentation for precise resistance values.

When to Replace the Contactor or Coil

If the coil fails resistance tests, voltage is absent, or contacts are pitted or burnt, replacement is usually required. If continuity tests fail or the coil doesn’t engage with power applied, replace the contactor for safety and performance.

After removing coil wires, switch the multimeter to the ohms setting. Place each lead on the coil’s connectors; the expected reading should fall between 10 to 100 ohms. A lower or higher reading indicates a potential defect in the coil.

If the testing reveals issues with the contactor or coil, replacing the faulty parts can restore the system’s reliability and efficiency. A functioning device ensures the electrical flow in air conditioning systems remains stable, supporting both performance and energy efficiency. Visit our NFPA 70B Testing and Maintenance Training course for more information.

Electrical Test Equipment Channel

Checking Insulation Resistance

Checking insulation resistance ensures safe operation of electrical systems by detecting moisture, degradation, or leakage currents. It’s essential for preventing equipment failure and maintaining high dielectric quality in cables, motors, and switchgear.

Why Are We Checking Insulation Resistance?

Checking insulation resistance is the process of testing electrical insulation to ensure reliability, prevent shock hazards, and maintain system performance. It:

✅ Detects moisture, aging, or breakdown in insulation

✅ Prevents electrical failures and equipment hazards

✅ Commonly used on motors, cables, and switchgear

Regular dielectric resistance testing is a crucial component of maintaining the integrity and safety of electrical insulation systems. This testing helps identify potential issues such as short circuits or degraded non-conductive material that could lead to failures. By performing these tests as part of a preventive maintenance routine, facilities can ensure that their systems operate efficiently and safely. To perform accurate IR testing, it's essential to use a reliable insulation resistance tester designed specifically for assessing the health of dielectric materials in motors, cables, and electrical panels.

What is the purpose of checking insulation resistance in electrical systems?

The primary purpose of conducting an insulation resistance (IR) test is to assess the condition of the electrical insulation protecting conductors and components within a system. Over time, the insulating layer can degrade due to factors such as environmental stress, aging, and exposure to moisture, which can result in short circuits or reduced system efficiency. By identifying potential weaknesses in the insulation, maintenance teams can take proactive measures to prevent unexpected failures and ensure the ongoing reliability of their electrical systems.

The Institute of Electrical and Electronics Engineers (IEEE) standard 43, "Recommended Practice for Testing Insulation Resistance of Electric Machinery," advises that all resistance readings be adjusted to a standardized temperature of 40°C (104°F). This consistent temperature provides a reliable baseline, allowing for meaningful historical comparisons over time. Discover the importance of preventive maintenance in prolonging equipment life and preventing costly failures caused by dielectric material breakdown.

What are the steps when checking insulation resistance?

The process of conducting an IR test begins by ensuring that the equipment being tested is de-energized to prevent accidents. After verifying that the system is safe to work on, insulation resistance testers are used to apply a specified test voltage across the dielectric material. The resistance measurements obtained during the test provide valuable insight into the condition of the insulation. Additionally, a polarization index (PI) test may be performed, which involves taking two separate measurements—one after 60 seconds and another after 10 minutes—to assess the dielectric absorption capabilities of the protective coating. The test results are then compared to industry standards or historical data for the specific equipment.

What are acceptable insulation resistance values for different types of electrical equipment?

Acceptable values for an IR test vary depending on the type of equipment and the system voltage. Typically, higher resistance measurements indicate better dielectric quality, with megohm values often used as the benchmark. For example, large industrial motors or high-voltage transformers may require a minimum of 1 megohm per kilovolt of operating voltage. However, the test results need to be interpreted in context, considering factors such as the age of the equipment and the environment in which it operates. As part of a predictive maintenance strategy, our electric motor testing guide explains how insulation resistance measurements can reveal early-stage deterioration in windings.

How often should insulation resistance be checked?

The frequency of insulation resistance testing depends on the critical nature of the equipment and its operating conditions. For critical infrastructure, testing should be performed as part of a regular preventive maintenance schedule, typically once a year or more frequently if the equipment is exposed to harsh environments. High-voltage systems and those operating in wet or dusty conditions may require more frequent testing to ensure the dielectric material remains intact and effective.

Key Factors in Checking Insulation Resistance

Category	Details
Purpose of IR Testing	Detect degradation, moisture intrusion, aging, and leakage paths
Test Instrument	Insulation Resistance Tester
IEEE Standard Reference	IEEE Std 43 – Test values normalized to 40°C (104°F) for consistency
Minimum Resistance Values	≥1 MΩ per kV of rated voltage (e.g., 5 kV = 5 MΩ minimum)
Test Voltage Range	500 V to 5,000 V DC (varies by equipment type and voltage class)
Test Types	Spot Reading, Time-Resistance Method, Polarization Index (PI)
PI Ratio (10-min / 1-min reading)	≥2.0 (good insulation), 1.0–2.0 (marginal), <1.0 (potential issue)
Frequency of Testing	Annually or more often in harsh, high-voltage, or mission-critical systems
Environmental Influences	Temperature, humidity, contamination, equipment age
Common Applications	Motors, generators, cables, switchgear, transformers

What factors can affect the accuracy of insulation resistance test results?

Several factors can influence the accuracy of an insulation resistance IR test. Temperature, humidity, and contamination can cause fluctuations in resistance measurements, leading to inaccurate assessments. For instance, moisture can lower the resistance value, suggesting degradation when the actual issue is environmental in nature. Similarly, the age of the equipment and the condition of the dielectric material can also impact test outcomes. Properly accounting for these variables during testing ensures that the test results accurately reflect the insulation's condition. IR testing is just one of many procedures outlined in our comprehensive electrical testing resource, which covers the key tools and methods used in field diagnostics.

Insulation resistance testing is a critical component of electrical system maintenance. By regularly performing IR tests and carefully analyzing the test results, maintenance teams can identify potential issues before they result in costly failures. Ensuring that equipment is properly de-energized and following standardized procedures for testing helps achieve accurate and reliable measurements, ultimately improving the longevity and safety of the electrical system.

Quickly Locate Partial Discharge (Pd) With Acoustic Imaging

Flir PD Accoustic Imaging enables ultrasonic detection of partial discharge, corona, and arcing in HV switchgear, transformers, and busbars, supporting non-contact diagnostics, condition monitoring, and predictive maintenance for electrical engineers and asset managers.

What Is FLIR PD Accoustic Imaging?

Ultrasonic imaging that locates partial discharge, corona, and arcing on HV assets for safe, non-contact diagnostics.

✅ Pinpoints PD sources in switchgear, transformers, and bus ducts.

✅ Ultrasonic beamforming maps corona and arcing with high SNR.

✅ Enables condition-based maintenance and reduces outage risk.

The Customer's Challenge
For many years utility companies have been performing partial discharge (PD) measurements on high-voltage electric equipment. PD is an indicator of insulation deterioration that can lead to equipment failures or even worse a catastrophic incident. With traditional ultrasonic solutions, the systems can be large and cumbersome and the inspection reports usually need to be analyzed by an acoustic engineer. Given this, inspections can become less frequent, leaving equipment like motors, generators, switchgear and transformers vulnerable to PD related issues.

To strengthen reliability programs, routine electrical testing provides baseline data that complements PD surveys.

Highlighted Solution
Acoustic imaging, or the ability to see ultrasonic sound, has emerged as an effective method utility organizations use to locate the existence of partial discharge (PD). It enables professionals to conduct more frequent predictive maintenance routines, helping provide a crucial first warning of impending electrical failure that could lead to downtime of critical systems. The FLIR Si124 industrial acoustic imaging camera senses, displays and records sound waves producing a precise acoustic image. The acoustic image is overlaid, in real time, onto a digital camera image all with an easy-to-use, ergonomic, one-handed camera solution weighing a little more than 2 pounds (980 grams).

When anomalies are detected, an insulation resistance tester can verify insulation integrity and guide next steps.

The Results
With the FLIR Si124, professionals can safely detect problems from up to 100 meters away and analyze discharge patterns. The camera classifies three partial discharge types, including surface discharge, floating discharge, and discharge into air. Knowing the type and severity of the discharge allows users to prioritize repairs. Image captures are quickly uploaded over Wi-Fi to the FLIR Acoustic Camera Viewer cloud service for the user to perform further in-depth analysis of the system generated PD patterns. Users can then create reports and easily share them with colleagues. This accelerates electrical troubleshooting by pinpointing fault locations more quickly.

Findings can be corroborated through an electrical insulation resistance test to confirm deterioration trends.

The Si124 enables customers to perform more frequent inspections, helping utilities keep the power flowing.

Between imaging sessions, routinely checking insulation resistance helps verify the effectiveness of repairs and maintenance.

For more information about the FLIR Si124 or to schedule a product demonstration visit: www.FLIR.ca/si124

Deploying the Si124 within broader industrial electrical maintenance workflows ensures consistent documentation and decision making.

Download the Flir Accoustic Imaging White Paper Here

For teams newer to PD diagnostics, learning what a megohmmeter measures can improve interpretation of follow-up test results.

Electrical Test Equipment Channel

Industrial Electrical Maintenance Explained

Industrial electrical maintenance ensures the reliability of plant and factory power systems through regular inspections, testing, and repairs. It minimizes downtime, extends equipment life, improves safety, and prevents costly failures in critical industrial operations.

What is Industrial Electrical Maintenance?

Industrial electrical maintenance (IEM) encompasses the routine upkeep, troubleshooting, and repair of electrical systems in manufacturing and industrial settings.

✅ Enhances equipment reliability through preventive maintenance

✅ Reduces unplanned downtime and costly repairs

✅ Ensures electrical safety and compliance with regulations

NFPA 70B Industrial Electrical Maintenance Training

Electrical Testing and Troubleshooting Training

Request a Free Training Quotation

Industrial electrical maintenance plays a crucial role in ensuring the safety, efficiency, and reliability of industrial facilities. By understanding the key components of a testing and repair program, including preventive maintenance, troubleshooting, equipment maintenance, and the role of automation equipment, companies can develop a robust plan that supports the overall performance and longevity of their systems. Furthermore, investing in the skills and knowledge of technicians, as well as adapting to technological advancements, are crucial for achieving long-term success in industrial electrical maintenance (IEM). Discover how advanced electrical test equipment enables teams to identify issues early and enhance safety across industrial systems.

At the core of an industrial electrical testing and maintenance program are various key components that contribute to a facility's overall success and efficiency. These include preventive maintenance, troubleshooting, and equipment repair. Preventive maintenance involves regular inspections and servicing of systems to identify and address potential issues before they escalate into significant problems. Troubleshooting involves identifying and fixing power-related issues that may arise during regular operations. Ultimately, equipment repair focuses on maintaining the integrity of components and machinery to ensure optimal performance and minimize downtime. For accurate voltage and current measurements, technicians often rely on tools like analog multimeters during regular testing routines.

Industrial facilities rely on various types of equipment, including transformers, motors, generators, and power circuit breakers. Each of these components plays a vital role in the facility's operations. For example, transformers help regulate voltage levels to ensure a stable power supply, while motors and generators convert energy into mechanical motion and vice versa. In addition, power circuit breakers protect circuits from overloads and short circuits. Therefore, regular inspection and service of these components are essential for the smooth operation of an industrial facility.

Another critical aspect is the use of automation equipment, such as variable frequency drives (VFDs) and programmable logic controllers (PLCs). Variable Frequency Drives (VFDs) control the speed of electric motors to optimize energy consumption and reduce wear on mechanical components. At the same time, PLCs serve as the "brain" of automated systems, controlling and monitoring various processes. Therefore, properly maintaining these devices is crucial to ensuring the efficient functioning of automated processes in an industrial setting. See our guide on electrical testing to understand the methods used to verify the condition of high-voltage equipment.

Predictive Maintenance Tools and Techniques

Predictive maintenance is a proactive strategy that uses data and condition-based analysis to prevent failures. Top-performing facilities now include:

Key Predictive Tools:

Thermal Imaging (Infrared Thermography): Detects overheating components in panels, breakers, and motors before failure.
Vibration Analysis: Identifies wear or imbalance in rotating equipment, such as motors and generators.
Ultrasonic Testing: Used to detect arcing, corona discharge, and loose connections in high-voltage systems.
Current and Voltage Harmonic Analysis: Reveals abnormalities in power quality affecting VFDs, PLCs, and other sensitive electronics.
IIoT-Enabled Sensors and Remote Monitoring: Provides real-time insights into temperature, vibration, and power consumption trends across multiple assets.

Predictive maintenance reduces unplanned downtime, extends equipment life, and improves return on investment (ROI) over time compared to reactive or calendar-based methods. Troubleshooting faults is a critical skill—explore our electrical troubleshooting page for techniques and tools used in industrial settings.

The frequency of equipment inspection and service in industrial settings depends on several factors, including the type of equipment, operating conditions, and the manufacturer's recommendations. Generally, more frequent inspections are required for high-voltage or high-power equipment, while lower-voltage devices may need less frequent checks. Regular industrial electrical maintenance schedules can help detect potential problems early on and prevent costly breakdowns and downtime.

Common problems in industrial facilities include loose connections, overheating, and wear and tear. By addressing these issues through preventive testing and servicing, facilities can improve efficiency and safety. Regular inspection can also help prevent fires, equipment damage, and accidents caused by power system failures.

An IEM technician should understand principles, industrial equipment, and safety regulations. Additionally, they should be skilled in troubleshooting issues and able to work effectively with various tools and equipment. Many technicians also undergo specialized training programs to enhance their knowledge and skills in specific areas, such as PLC programming or VFD service.

Testing and troubleshooting play a crucial role in IEM. They help identify issues, assess the condition of equipment, and determine the necessary corrective actions. This process involves using specialized tools and instruments to measure parameters such as voltage, current, and resistance and analyzing the results to detect potential issues or confirm that the equipment is functioning correctly.

Lockout/Tagout (LOTO) Best Practices

LOTO is a legally mandated safety protocol (e.g., OSHA 29 CFR 1910.147) to protect workers from hazardous energy during service. Your article should include:

Best Practices for Lockout/Tagout:

Perform a hazard assessment before work begins to identify all energy sources.
Use authorized lockout/tagout devices that physically prevent the activation of energy.
Communicate clearly: All affected employees must be informed of LOTO procedures.
Follow a written energy control procedure (ECP) tailored to each piece of equipment.
Verify zero energy state using voltage testers before beginning any service.
Each worker applies their personal lock; group lock boxes can be used for teams.
Train employees annually on LOTO steps, responsibilities, and hazard awareness.
Conduct regular audits of your LOTO program to ensure compliance.

Industrial electrical maintenance planning is a crucial aspect of optimizing the performance and lifespan of equipment in industrial environments. It involves developing and implementing a structured service plan outlining equipment upkeep tasks, frequencies, and responsibilities. By adhering to a well-defined service plan, facilities can minimize unexpected equipment failures, reduce downtime, and extend the life of their components. For accurate voltage and current measurements, technicians often rely on tools like analog multimeters during regular testing routines.

To maintain a smooth-running operation, it is crucial to invest in regular training programs for technicians. This allows them to stay up-to-date with technological advancements and safety standards. Moreover, continuous learning can help them enhance their skills and better serve the needs of the industrial facility.

It's essential to remember that IEM is an ongoing process that requires constant attention and effort. Additionally, new equipment and practices must be adopted as technology advances to remain competitive. Therefore, it's vital for companies to periodically review and update their testing and service strategies and plans to accommodate advancements in technology and industry best practices.

North American Industrial Electrical Maintenance Standards

In North America, standards are developed and enforced to ensure the safe and efficient operation of systems and equipment. These standards provide guidelines for inspection, testing, and procedures, outlining best practices and safety requirements for various industrial components. By adhering to these standards, facilities can minimize hazards, reduce downtime, and enhance the overall performance of their power systems. Assessing the condition of rotating machines requires specialized procedures, such as electric motor testing, to detect imbalances and insulation failures.

Two key organizations involved in developing standards in North America are the National Fire Protection Association (NFPA) and the Institute of Electrical and Electronics Engineers (IEEE). The NFPA publishes NFPA 70E, a standard for safety in the workplace, and also publishes NFPA 70B, Recommended Practice for Equipment Maintenance. IEEE also provides numerous standards related to equipment service.

NFPA 70E - Standard for Safety in the Workplace

The NFPA 70E is a widely recognized standard that addresses safety requirements for employees working on or around equipment. This standard covers safe work practices, personal protective equipment (PPE), hazard assessment, and the development of a safety program. Additionally, it provides guidelines for minimizing risks associated with hazards such as arc flash and electric shock. Adherence to the NFPA 70E is crucial for ensuring the safety of electricians and other personnel working with industrial systems.

NFPA 70B - Recommended Practice for Industrial Electrial Maintenance

NFPA 70B is a critical standard that complements NFPA 70E by providing comprehensive guidelines for maintaining equipment in industrial, commercial, and institutional settings. This standard aims to minimize the risk of hazards, equipment failures, and unexpected downtime by outlining best practices for the proper industrial electrical maintenance of systems and components. Our NFPA 70B 2023 page outlines the updated standards for preventive maintenance of industrial power systems.

The NFPA 70B covers various aspects of equipment maintenance, including:

Maintenance Organization and Planning: This section emphasizes the importance of having a structured maintenance program and outlines guidelines for developing and implementing a service plan that addresses a facility's specific needs and requirements.
Inspection and Testing: NFPA 70B provides guidelines for inspecting and testing various types of equipment, including transformers, circuit breakers, motors, and generators. It outlines recommended test methods, frequencies, and safety precautions during these activities.
Preventive and Predictive Maintenance: The standard emphasizes the importance of preventive and predictive inspection and testing in extending equipment life and minimizing the likelihood of failures. It offers recommendations for implementing these service strategies effectively.
Equipment-Specific Maintenance: NFPA 70B provides detailed guidelines for maintaining various types of equipment, including switchgear, batteries, grounding systems, and cables. It addresses the specific service requirements, procedures, and safety precautions associated with each type of equipment.
Maintenance Documentation and Recordkeeping: The standard emphasizes the importance of maintaining accurate records of equipment service activities, test results, and other relevant information. These records can help identify trends, assess equipment performance, and support decision-making on service activities and equipment replacement.
Training and Personnel Safety: NFPA 70B emphasizes the importance of providing proper training to maintenance personnel in safety procedures, equipment operation, and service techniques. It also emphasizes the importance of adhering to safety requirements, including lockout/tagout procedures and the use of personal protective equipment (PPE).

By adhering to the guidelines outlined in the NFPA 70B, organizations can establish a robust inspection and repair program that minimizes the risk of hazards and promotes equipment reliability and efficiency. Additionally, incorporating these best practices into a facility's service strategy can reduce downtime, prolong equipment life, and enhance overall operational performance.