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    Fluke 283FC/PV Solar Kit

    Model: 283FC/PV | UPC: 195112129722

    Fluke 283FC/PV Solar Kit-

    Downloads: datasheet manual

    Fluke 283FC/PV Solar Kit

    Model: 283FC/PV

    Whether you're performing frontline troubleshooting on a utility-scale PV array, wind power installation, electric railways, or data centers, this kit is the perfect troubleshooting combination for technicians in DC environments up to 1500 V. In addition, this kit enhances safety and increases productivity while giving you accurate, reliable, and repeatable results.

    Whether you're performing frontline troubleshooting on a utility-scale PV array, wind power installation, electric railways, or data centers, this kit is the perfect troubleshooting combination for technicians in DC environments up to 1500 V. In addition, this kit enhances safety and increases productivity while giving you accurate, reliable, and repeatable results.

    Your Price $1331.44 CAD
    Availability 2 to 3 Weeks
    Quantity

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    Fluke 283FC/PV Offers

    The 283 FC/PV includes CAT III 1500 V DC safety-rated accessories so you can work confidently without compromising safety. Staubli MC4 test leads allow you to quickly make reliable, secure connections to modules or strings to test DC voltage up to 1500 V DC. TL175-HV CAT III 1500 V/CAT IV 1000 V rated silicone test leads give you more flexibility when testing voltage, millivoltage, resistance, continuity, or capacitance on inverters, combiner boxes, PV arrays, or individual PV modules. With a bright backlit display and illuminated buttons it's easier to work in various lighting conditions, and the included magnetic hanging kit frees up your hands while troubleshooting. With an included custom hard carrying case your investment is protected while you transport it.

    Features

    • CAT III 1500 V/CAT IV 1000 V safety rated multimeter, wireless current clamp and test leads
    • Includes CAT III 1500 V rated Staubli MC4 test leads and TL175-HV CAT III 1500 V/CAT IV 1000 V safety rated premium test leads
    • Current measurements up to 60 A AC/DC for safely troubleshooting individual strings of modules with greater accuracy (when using a283 FC wireless current clamp)
    • Visual and audio polarity indicators help prevent accidental module wiring issues
    • Highly accurate voltage measurements for precise frontline troubleshooting
    • Current measurements up to 60 A AC/DC for safely troubleshooting individual strings with of modules
    • with greater accuracy (when using a283 FC wireless current clamp)
    • Visual and audio polarity indicators with on/off function help prevent accidental module wiring issues
    • User-defined limit gauge helps you make quick go/no-go troubleshooting decisions
    • Unique multimeter readiness self-check helps ensure your meter is ready to test
    • Save and log measurements to internal memory and view them on your mobile device via Fluke Connect™

    User-Defined Limit Gauge

    On large-scale PV projects where you’re taking repetitive measurements and expect consistent results, the user-defined limit gauge becomes a vital time-saving tool. The adjustable limit gauge can trigger audio and visual indications whenever a measurement falls outside your expected range. This saves you time letting you quickly evaluate measurement results, increasing your confidence in the system's performance, and helping to identify potential issues that need to be addressed.

    With the dedicated limit gauge button, you can easily turn the limit gauge warnings on and off, set up new measurement parameters, or select from previously used parameter profiles. This customization streamlines troubleshooting, allowing you to quickly identify measurement deviations or errors, and helps maintain optimal solar installation performance.

    Unique Multimeter Readiness Self-Check

    The size and location of utility-scale solar sites can present unique challenges whether they’re logistical, environmental, or testing related. Because of that, you want to have confidence that your meter is fully functional, capturing the right data every time so you don’t have to do the same job twice. The 283 FC features a unique integrated multimeter readiness selfcheck, that ensures your meter is in proper working order before you take your next reading. This quick self-check is an additional readiness test that gives you valuable insight to the status of your meter’s calibration, battery life availability, test lead functionality, and AC/DC voltage measurement functionality so you can be confident that your meter is ready to work when you are.

    Logging/Saving

    The 283 FC offers convenient logging and saving features that set it apart from other digital multimeters. With a built-in real-time clock, each measurement can be time- and date-stamped for accurate recordkeeping. The multimeter has internal memory to save and log measurements, which can then be easily transferred to Fluke Connect for further analysis. Additionally, you have the flexibility to customize logging durations and intervals, ensuring the logging process matches the specific needs of the system you are testing.

    Fluke Connect™ with Fluke Cloud™ Storage

    Fluke Connect™ compatibility provides convenient features to enhance your troubleshooting experience. As part of the Fluke Connect family, the 283 FC can transmit measurements to a smartphone or tablet for later, detailed analysis. No need to write down the results. Trend and monitor measurements live on your phone screen and upload those measurements to the cloud. Combine measurement data from multiple Fluke Connect test tools to create and share reports from the job site via email and collaborate in real time with other colleagues with ShareLive™ video calls or email. The table view feature organizes measurements, notes, and images in a clear and efficient manner, making it easier to reference data, identify issues, and generate reports for customers. Fluke Connect™ with Fluke Cloud™ Storage streamlines your workflow and ensures accurate data storage and organization.

    Wireless Current Clamp

    The a283 FC True-RMS wireless current clamp is designed to simplify the troubleshooting process without compromising on safety and reliability. It can measure both AC and DC current up to 60 A, ensuring precise and reliable readings for a wide range of applications including solar installations, electrical systems, and industrial equipment.

    With its non-contact design, the clamp allows for safe connections without the need to touch live wires, enabling you to close the clamp in a cabinet and take measurements from a safe distance. It carries a CAT III 1500 V, CAT IV 1000 V rating that matches the safety rating of the 283 FC.

    Wireless connectivity allows for convenient transmission of measurements, eliminating the hassle of tangled wires and allowing you to install the current clamp in an enclosure so you can safely measure at a distance. The clamp has a thin jaw design to ensure easy access to combiner boxes and tight spaces, enhancing overall efficiency in your measurement process.

    Voltage and Current at the same time

    With the 283 FC digital multimeter and a283 FC wireless current clamp, you can measure voltage and current at the same time and automatically calculate VA power. This eliminates the hassle of having to change your measurement setup to capture both measurements and eliminates the need to manually calculate power in the field. Voltage and current are time-stamped, eliminating any concerns about potential disparities being caused by environmental factors. You can also view more than one measurement at a time allowing you to monitor additional parameters like DC amperage or voltage, giving you even more insights into system performance.

    CAT III 1500 V/CAT IV 1000 V Safety Rated

    CAT III 1500 V DC systems are now a standard in utility scale PV systems, offering significant cost savings and efficiency improvements to facility owners. These systems operate at higher voltage levels, allowing each inverter to handle more energy, enable longer strings of connected panels, and reduce the need for additional wiring and inverters. Consequently, standard CAT IV inverter outputs of 800 V AC or higher are more prevalent, making it crucial to prioritize safety and accuracy in measurements.

    The CAT III 1500 V/CAT IV 1000 V rated 283 FC multimeter and a283 FC wireless current clamp meet the safety requirements for test equipment (IEC 61010-2-032) corresponding to the overvoltage category level of the PV array electrical installation (IEC 61730-1). Combine these with CAT III 1500 V/CAT IV 1000 V rated TL175-HV Premium Silicone Test Leads, CAT III 1500 V MC4 connectors and you’ve got a comprehensive frontline troubleshooting solution that offers safe and accurate voltage measurement for troubleshooting everything from the inverters, combiners, strings of modules, or individual modules.

    Applications

    • Testing voltage, millivoltage, resistance, continuity, or capacitance on inverters, combiner boxes, PV arrays, or individual PV modules.
    • Frontline troubleshooting of 1500 V DC systems such as utility-scale solar photovoltaic (PV) arrays, wind power installations, electric railways, or data centers.
    • Logging and saving measurements to internal memory or Fluke Connect to perform later detailed analysis.
    • Streamlining troubleshooting with the use of the user-defined limit gauge setting, allowing you to quickly identify measurement deviations or errors, and helping to maintain optimal performance.

    Fluke 283FC/PV Specifications

    Function (Multimeter)
    AC Volts Range: 6.000 V
    Resolution: 0.001 V
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 60.00 V
    Resolution: 0.01 V
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 600.0 V
    Resolution: 0.1 V
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)

    Range: 1000 V
    Resolution: 1 V
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)
    DC Volts Range: 6.000 V
    Resolution: 0.001 V
    Accuracy: 0.09% + 3

    Range: 60.00 V
    Resolution: 0.01 V
    Accuracy: 0.09% + 3

    Range: 600.0 V
    Resolution: 0.1 V
    Accuracy: 0.15% + 2

    Range: 1500 V
    Resolution: 1 V
    Accuracy: 0.15% + 2
    DC mV Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 0.09% + 2
    AC mV Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)
    Continuity Range: 600.0 Ω
    Resolution: 1 Ω
    Resistance Range: 600.0 Ω
    Resolution: 0.1 Ω
    Accuracy: 0.5% + 4

    Range: 6.000 kΩ
    Resolution: 0.001 kΩ
    Accuracy: 0.5% + 4

    Range: 60.00 kΩ
    Resolution: 0.01 kΩ
    Accuracy: 0.5% + 4

    Range: 600.0 kΩ
    Resolution: 0.1 kΩ
    Accuracy: 0.5% + 4

    Range: 6.000 MΩ
    Resolution: 0.001 MΩ
    Accuracy: 1.5% + 4

    Range: 50.00 MΩ
    Resolution: 0.01 MΩ
    Accuracy: 1.5% + 4
    Capacitance Range: 1000 nF
    Resolution: 1 nF
    Accuracy: 1.2% + 2

    Range: 10.00 μF
    Resolution: 0.01 μF
    Accuracy: 1.2% + 2

    Range: 100.0 μF
    Resolution: 0.1 μF
    Accuracy: 10% typical

    Range: 9999 μF
    Resolution: 1 μF
    Accuracy: 10% typical
    Frequency Range: 99.99 Hz
    Resolution: 0.01 Hz
    Accuracy: 0.1% + 2

    Range: 999.9 Hz
    Resolution: 0.1 Hz
    Accuracy: 0.1% + 2

    Range: 9.999 kHz
    Resolution: 0.001 kHz
    Accuracy: 0.1% + 2

    Range: 99.99 kHz
    Resolution: 0.01 kHz
    Accuracy: 0.1% + 2
    AC VA (45 to 500 Hz) Range: 360.0 VA
    Resolution: 0.1 VA
    Accuracy: 2% + 1.0 VA

    Range: 3.600 kVA
    Resolution: 0.001 kVA
    Accuracy: 2% + 1.0 kVA

    Range: 36.00 kVA
    Resolution: 0.01 kVA
    Accuracy: 2% + 0.15 kVA

    Range: 60.00 kVA
    Resolution: 0.1 kVA
    Accuracy: 2% + 0.15 kVA
    DC VA Range: 360.0 VA
    Resolution: 0.1 VA
    Accuracy: 2% + 1.0 VA

    Range: 3.600 kVA
    Resolution: 0.001 kVA
    Accuracy: 2% + 1.0 kVA

    Range: 36.00 kVA
    Resolution: 0.01 kVA
    Accuracy: 2% + 0.15 kVA

    Range: 90.00 kVA
    Resolution: 0.1 kVA
    Accuracy: 2% + 0.25 kVA
    Environmental Specifications (Multimeter)
    Operating Temperature -10 to 60°C (14 to 140°F)
    Storage Temperature -30 to 70°C (-22 to 158°F)
    Humidity (without condensation) 0 to 90%, 10 to 30°C (50 to 86°F)
    0 to 75%, 30 to 40°C (86 to 104°F)
    0 to 45%, 40 to 60°C (104 to 140°F)
    Protection (Multimeter)
    Electromagnetic compatibility IEC 61326-1, IEC 61326-2-2, Portable, Group 1, Class A
    Overvoltage category CAT III 1500 V, CAT IV 1000 V
    Agency approvals ETL (AMER and EMEA), CSA (APAC), CE, UK CA
    Drop test 2 m (6.5') drop test
    Ingress protection IP52
    Mechanical and General Specifications (Multimeter)
    Counts 6000
    Battery life > 150 hours typical, without backlight (Alkaline, 3 AA)
    > 100 hours typical when connected to wireless current clamp (Alkaline, 3 AA)
    Dimensions 22.5 x 10.5 x 5.7 cm (8.8 x 4.1 x 2.2")
    Weight 0.7 kg (1.5 lb)
    Function (Current Clamp)
    AC Current (True-RMS) Range: 60 A
    Resolution: 0.01 A
    Accuracy: 1.5% + 0.15 A, 45 to 500 Hz
    DC Current Range: 60 A
    Resolution: 0.01 A
    Accuracy: 1.5% + 0.15 A
    Environmental Specifications (Current Clamp)
    Operating Temperature -10 to 60°C (14 to 140°F)
    Storage Temperature -30 to 70°C (-22 to 158°F)
    Humidity (without condensation) 0 to 90%, 5 to 30°C (41 to 86°F)
    0 to 75%, 30 to 40°C (86 to 104°F)
    0 to 45%, 40 to 60°C (104 to 140°F)
    Protection (Current Clamp)
    Electromagnetic compatibility IEC 61326-1, IEC 61326-2-2, Portable, Group 1, Class A
    Overvoltage category CAT III 1500 V, CAT IV 1000 V
    Agency approvals ETL (AMER and EMEA), CSA (APAC), CE, UK CA
    Drop test 2 m (6.5') drop test
    Ingress protection IP52
    Features (Current Clamp)
    LED indicator Indicates wireless connection and data transmission status
    Battery indicator Indicates battery status
    Power Key Power On/Off
    Zero Key A DC zeroing function
    Mechanical and General Specifications (Current Clamp)
    Jaw opening 34 mm (1.34")
    Battery life > 80 hours typical (Alkaline, 2 AAA)
    Dimensions 22.6 x 9.1 x 4.2 cm (8.9 x 3.6 x 1.7")
    Weight 0.375 kg (13.2 oz)
    Click here for complete specifications on the Fluke 283FC/PV

    What's included with the Fluke 283FC/PV

    • 283 FC TRMS Wireless Digital Multimeter
    • a283 FC 60A TRMS Wireless AC/DC Current Clamp
    • Solar MC4 Test Lead set
    • TL175-HV TwistGuard™ Silicone Test Leads
    • Carrying Case
    • TPAK Magnetic Hanging Strap
    • Limited Lifetime Warranty on the Multimeter
    • One-Year Warranty on the Clamp

    Multimeter measurements on adjustable speed drives

    In the past, motor repair meant dealing with traditional three-phase motor failures that were largely the result of water, dust, grease, failed bearings, misaligned motor shafts, or just plain old age. But motor repair has changed in a big way with the introduction of electronically controlled motors, more commonly referred to as adjustable speed drives (ASDs). These drives present a unique set of measurement problems that can vex the most seasoned pro. Thanks to new technology, now for the first time you can take accurate electrical measurements with a DMM during the installation and maintenance of a drive and diagnose bad components and other conditions that may lead to premature failure.

    Troubleshooting philosophy

    Technicians use many different methods to troubleshoot an electrical circuit, and a good troubleshooter will always find the problem - eventually. The trick is tracking it down quickly and keeping downtime to a minimum. The most efficient troubleshooting procedure begins at the motor and then works systematically back to the electrical source, looking for the most obvious problems first. A lot of time and money can be wasted replacing perfectly good parts when the problem is simply a loose connection. As you go, take care to take accurate measurements. Nobody takes inaccurate measurements on purpose, but it's easy to do, especially when working in a high-energy, noisy environment like an ASD. Likewise, choosing the right test tools for troubleshooting the drive, the motor, and the connections are of utmost importance. This is especially true when taking voltage, frequency, and current measurements on the output side of the motor drive. But until now, there hasn't been a digital multimeter on the market able to accurately measure ASDs. Incorporates a selectable low pass filter* that allows for accurate drive output measurements that agree with the motor drive controller display indicator. Now, technicians won't have to guess whether the drive is operating correctly and delivering the correct voltage, current, or frequency for a given control setting.

    Drive measurements

    Input side measurements

    Any good quality True RMS multimeter can verify proper input power to an ASD. The input voltage readings should be within 1% of one another when measured from phase to phase with no load. A significant unbalance may lead to erratic drive operation and should be corrected when discovered.

    Output side measurements

    On the flip side, a regular True RMS multimeter can't reliably read the output side of a pulse width modulated (PWM) motor drive, because the ASD applies pulse width modulated nonsinusoidal voltage to the motor terminals. A True RMS DMM reads the heating effect of the non-sinusoidal voltage applied to the motor, while the motor controller's output voltage reading only displays the RMS value of the fundamental component (typically from 30 Hz to 60 Hz). The causes of this discrepancy are bandwidth and shielding. Many of today's True RMS digital multimeters have bandwidths out to 20 kHz or more, causing them to respond not only to the fundamental component, which is what the motor responds to but to all of the high-frequency components generated by the PWM drive. And if the DMM isn't shielded for high-frequency noise, the drive controller's high noise levels make the measurement discrepancies even more extreme. With the bandwidth and shielding issues combined, many True RMS meters display readings as much as 20 to 30% higher than what the drive controller is indicating. The incorporated selectable low pass filter allows troubleshooters to take accurate voltage, current, and frequency measurements on the output side of the drive at either the drive itself or the motor terminals. With the filter selected, the readings for both voltage and frequency (motor speed) should agree with the associated drive control display indications, if available. The low pass filter also allows for accurate current measurements when used with Hall-effect type clamps. All of these measurements are especially helpful when taking measurements at the motor location when the drive's displays are not in view.

    Taking safe measurements

    Before taking any electrical measurements, be sure you understand how to take them safely. No test instrument is completely safe if used improperly, and many test instruments are not appropriate for testing adjustable speed drives. Also, make sure to use the appropriate personal protective equipment (PPE) for your specific working environment and measurements. If at all possible, never work alone.

    Safety ratings for electrical test equipment

    ANSI and the International Electrotechnical Commission (IEC) are the primary independent organizations that define safety standards for test equipment manufacturers. The IEC 61010 second edition standard for test equipment safety states two basic parameters: a voltage rating and a measurement category rating. The voltage rating is the maximum continuous working voltage the instrument is capable of measuring. The category ratings depict the measurement environment expected for a given category. Most three-phase ASD installations would be considered a CAT III measurement environment, with power supplied from either 480V or 600V distribution systems. When using a DMM for measurements on these high-energy systems, make sure it's rated at a minimum for CAT III 600V and preferably for CAT IV 600V/CAT III 1000V. The category rating and voltage limit are typically found on the front panel, at the input terminals. Dual-rated CAT IV 600V and CAT III 1000V. Refer to the ABC's of DMM Safety* from Fluke for additional information on category ratings and taking safe measurements.

    How to take measurements

    Now let's put the multimeter to the test. The measurements in the following procedure are designed to be made on a 480 volt 3 phase drive control at the control panel terminal strips. These procedures would also be valid for lower voltage 3 phase drives powered by either single or 3 phase supply voltages. For these tests, the motor is running at 50 Hz.

    Input voltage

    To measure the ac voltage supply to the input side of the drive at the drive:

    • Select the ac voltage function.
    • Connect the black probe to one of the three phase input terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase input terminals and record the reading.
    • Leaving the black probe on the reference phase now move the red probe to the third phase input and record this reading.
    • Make sure there's no more than a 1% difference between these two readings.

    Input current

    Measuring the input current generally requires a current clamp accessory. In most cases, either the input current exceeds the maximum current measurable by the current function, or it isn't practical to "break the circuit" to take an in-line series current measurement. Regardless of clamp type, insure that all readings are within 10% of each other for proper balance.

    Transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A AC function.
    • Place the clamp around each of the input supply phase cables in succession, recording each of the readings as they are taken. Since these clamps output one milliamp per amp, the milliamp readings shown on the display are the actual phase current readings in amps.

    Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the AC voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter is enabled, the meter will be in the 600 mV manual range mode.
    • Place the clamp around each of the input supply phase cables in succession, recording each of the readings as they are taken. Since these clamps output one millivolt per amp, the millivolt readings shown on the display are the actual phase current readings in amps.

    Figure 1. Output voltage reading without using the low pass filter.

    Figure 2. Output voltage reading with low pass filter enabled.

    Output voltage

    To measure the AC output voltage at either the drive or the motor terminals:

    • Plug the black test lead into the common jack and the red test lead into the V/W jack.
    • Select the AC voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the yellow button to enable the low pass filter. Now record the reading.
    • Leaving the black probe on the reference phase, now move the red probe to the third phase output voltage or motor terminal and record this reading.
    • Make sure that there's no more than a 1% difference between these two readings (see Figure 2). The readings should also agree with the controller display, panel if available.
    • If the low pass filter isn't enabled, the output voltage readings may be 10 to 30% higher, as on a regular DMM (see Figure 1).

    Figure 3. Output frequency (motor speed) without the low pass filter.

    Figure 4. Output frequency (motor speed) using the low pass filter.

    Motor speed (Output frequency using voltage as a reference)

    To determine motor speed, simply take a frequency measurement while using the low pass filter. The measurement can be made between any two of the phase voltage or motor terminals.

    • Plug the black test lead into the common jack and the red test lead into the V/W jack.
    • Select the ac voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the yellow button to enable the low pass filter.
    • Press the Hz button. The displayed reading in hertz will be the motor speed (see Figure 3). This measurement couldn't be made successfully without the low pass filter (see Figure 4).

    Output current

    TAs with input current, measuring the output current generally requires a current clamp accessory. Once again, regardless of clamp type, insure that all readings are within 10% of each other for proper balance.

    Transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A ac function.
    • Place the clamp around each of the output phase cables in succession, recording each of the readings as they're taken. Since these clamps output 1 milliamp per amp, the milliamp readings shown on the display are the actual phase current readings in amps.

    Figure 5. Output current reading without using the low pass filter.

    Figure 6. Output current reading with low pass filter enabled.

    Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the ac voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter is turned on, the meter will be in the 600 mV manual range mode.
    • Place the clamp around each of the output phase cables in succession, recording each of the readings as they are taken (see Figure 6). Since these clamps output 1 millivolt per amp, the millivolt readings shown on the 87-V display are the actual phase current readings in amps. This measurement would not be possible without the low pass filter (see Figure 5).

    Motor speed (Output frequency using current as a reference)

    For motors that pull at least 20 amps of running current, motor speed can be determined by taking a frequency measurement with current clamps. Until now, noise issues have prevented accurate readings using hall effect type clamps. Here's how the low pass filter makes it possible.

    Motor speed using a Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the ac voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter has been turned on, the meter will be in the 600 mV manual range mode.
    • Place the clamp around one of the output phase cables. Verify that the multimeter is reading a current of at least 20 amps (20 mV in the display).
    • Press the Hz button. The readings now display the motor speed as a frequency measurement.

    Motor speed using a transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A AC function.
    • Place the clamp around one of the output phase cables. Verify that the multimeter is reading a current of at least 20 amps (20mA in the display).
    • Press the Hz button. The readings now display the motor speed as a frequency measurement.

    DC Bus measurements

    A healthy dc bus is a must for a properly operating motor drive. If the bus voltage is incorrect or unstable, the converter diodes or capacitors may be starting to fail. The DC bus voltage should be approximately 1.414 times the phase to phase input voltage. For a 480 volt input, the DC bus should be approximately 679 VDC. The DC bus is typically labeled as DC+, DC- or B+, Bon the drive terminal strip. To measure the DC bus voltage:

    • Select the dc voltage function.
    • Connect the black probe to either the DC- or B- terminal.
    • Connect the red probe to the DC+ or B+ terminal. The bus voltage should agree with the example mentioned above and be relatively stable. To check the amount of ac ripple on the bus, switch the 7V's function switch to the vac function. Some small drives don't allow external access to the DC bus measurement without disassembling the drive. If you can't access the DC bus, use the peak min max function on the multimeter to measure the dc bus voltage via the output voltage signal.
    • Plug the black test lead into the common jack and the red test lead into the V/½ jack.
    • Select the AC voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the min/max button.
    • Press the (Peak min/max) button.
    • The displayed reading in Peak min/max will be the DC bus voltage.
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    Fluke 283FC/PV Offers

    The 283 FC/PV includes CAT III 1500 V DC safety-rated accessories so you can work confidently without compromising safety. Staubli MC4 test leads allow you to quickly make reliable, secure connections to modules or strings to test DC voltage up to 1500 V DC. TL175-HV CAT III 1500 V/CAT IV 1000 V rated silicone test leads give you more flexibility when testing voltage, millivoltage, resistance, continuity, or capacitance on inverters, combiner boxes, PV arrays, or individual PV modules. With a bright backlit display and illuminated buttons it's easier to work in various lighting conditions, and the included magnetic hanging kit frees up your hands while troubleshooting. With an included custom hard carrying case your investment is protected while you transport it.

    Features

    • CAT III 1500 V/CAT IV 1000 V safety rated multimeter, wireless current clamp and test leads
    • Includes CAT III 1500 V rated Staubli MC4 test leads and TL175-HV CAT III 1500 V/CAT IV 1000 V safety rated premium test leads
    • Current measurements up to 60 A AC/DC for safely troubleshooting individual strings of modules with greater accuracy (when using a283 FC wireless current clamp)
    • Visual and audio polarity indicators help prevent accidental module wiring issues
    • Highly accurate voltage measurements for precise frontline troubleshooting
    • Current measurements up to 60 A AC/DC for safely troubleshooting individual strings with of modules
    • with greater accuracy (when using a283 FC wireless current clamp)
    • Visual and audio polarity indicators with on/off function help prevent accidental module wiring issues
    • User-defined limit gauge helps you make quick go/no-go troubleshooting decisions
    • Unique multimeter readiness self-check helps ensure your meter is ready to test
    • Save and log measurements to internal memory and view them on your mobile device via Fluke Connect™

    User-Defined Limit Gauge

    On large-scale PV projects where you’re taking repetitive measurements and expect consistent results, the user-defined limit gauge becomes a vital time-saving tool. The adjustable limit gauge can trigger audio and visual indications whenever a measurement falls outside your expected range. This saves you time letting you quickly evaluate measurement results, increasing your confidence in the system's performance, and helping to identify potential issues that need to be addressed.

    With the dedicated limit gauge button, you can easily turn the limit gauge warnings on and off, set up new measurement parameters, or select from previously used parameter profiles. This customization streamlines troubleshooting, allowing you to quickly identify measurement deviations or errors, and helps maintain optimal solar installation performance.

    Unique Multimeter Readiness Self-Check

    The size and location of utility-scale solar sites can present unique challenges whether they’re logistical, environmental, or testing related. Because of that, you want to have confidence that your meter is fully functional, capturing the right data every time so you don’t have to do the same job twice. The 283 FC features a unique integrated multimeter readiness selfcheck, that ensures your meter is in proper working order before you take your next reading. This quick self-check is an additional readiness test that gives you valuable insight to the status of your meter’s calibration, battery life availability, test lead functionality, and AC/DC voltage measurement functionality so you can be confident that your meter is ready to work when you are.

    Logging/Saving

    The 283 FC offers convenient logging and saving features that set it apart from other digital multimeters. With a built-in real-time clock, each measurement can be time- and date-stamped for accurate recordkeeping. The multimeter has internal memory to save and log measurements, which can then be easily transferred to Fluke Connect for further analysis. Additionally, you have the flexibility to customize logging durations and intervals, ensuring the logging process matches the specific needs of the system you are testing.

    Fluke Connect™ with Fluke Cloud™ Storage

    Fluke Connect™ compatibility provides convenient features to enhance your troubleshooting experience. As part of the Fluke Connect family, the 283 FC can transmit measurements to a smartphone or tablet for later, detailed analysis. No need to write down the results. Trend and monitor measurements live on your phone screen and upload those measurements to the cloud. Combine measurement data from multiple Fluke Connect test tools to create and share reports from the job site via email and collaborate in real time with other colleagues with ShareLive™ video calls or email. The table view feature organizes measurements, notes, and images in a clear and efficient manner, making it easier to reference data, identify issues, and generate reports for customers. Fluke Connect™ with Fluke Cloud™ Storage streamlines your workflow and ensures accurate data storage and organization.

    Wireless Current Clamp

    The a283 FC True-RMS wireless current clamp is designed to simplify the troubleshooting process without compromising on safety and reliability. It can measure both AC and DC current up to 60 A, ensuring precise and reliable readings for a wide range of applications including solar installations, electrical systems, and industrial equipment.

    With its non-contact design, the clamp allows for safe connections without the need to touch live wires, enabling you to close the clamp in a cabinet and take measurements from a safe distance. It carries a CAT III 1500 V, CAT IV 1000 V rating that matches the safety rating of the 283 FC.

    Wireless connectivity allows for convenient transmission of measurements, eliminating the hassle of tangled wires and allowing you to install the current clamp in an enclosure so you can safely measure at a distance. The clamp has a thin jaw design to ensure easy access to combiner boxes and tight spaces, enhancing overall efficiency in your measurement process.

    Voltage and Current at the same time

    With the 283 FC digital multimeter and a283 FC wireless current clamp, you can measure voltage and current at the same time and automatically calculate VA power. This eliminates the hassle of having to change your measurement setup to capture both measurements and eliminates the need to manually calculate power in the field. Voltage and current are time-stamped, eliminating any concerns about potential disparities being caused by environmental factors. You can also view more than one measurement at a time allowing you to monitor additional parameters like DC amperage or voltage, giving you even more insights into system performance.

    CAT III 1500 V/CAT IV 1000 V Safety Rated

    CAT III 1500 V DC systems are now a standard in utility scale PV systems, offering significant cost savings and efficiency improvements to facility owners. These systems operate at higher voltage levels, allowing each inverter to handle more energy, enable longer strings of connected panels, and reduce the need for additional wiring and inverters. Consequently, standard CAT IV inverter outputs of 800 V AC or higher are more prevalent, making it crucial to prioritize safety and accuracy in measurements.

    The CAT III 1500 V/CAT IV 1000 V rated 283 FC multimeter and a283 FC wireless current clamp meet the safety requirements for test equipment (IEC 61010-2-032) corresponding to the overvoltage category level of the PV array electrical installation (IEC 61730-1). Combine these with CAT III 1500 V/CAT IV 1000 V rated TL175-HV Premium Silicone Test Leads, CAT III 1500 V MC4 connectors and you’ve got a comprehensive frontline troubleshooting solution that offers safe and accurate voltage measurement for troubleshooting everything from the inverters, combiners, strings of modules, or individual modules.

    Applications

    • Testing voltage, millivoltage, resistance, continuity, or capacitance on inverters, combiner boxes, PV arrays, or individual PV modules.
    • Frontline troubleshooting of 1500 V DC systems such as utility-scale solar photovoltaic (PV) arrays, wind power installations, electric railways, or data centers.
    • Logging and saving measurements to internal memory or Fluke Connect to perform later detailed analysis.
    • Streamlining troubleshooting with the use of the user-defined limit gauge setting, allowing you to quickly identify measurement deviations or errors, and helping to maintain optimal performance.
    Show More...

    Fluke 283FC/PV Specifications

    Function (Multimeter)
    AC Volts Range: 6.000 V
    Resolution: 0.001 V
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 60.00 V
    Resolution: 0.01 V
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 600.0 V
    Resolution: 0.1 V
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)

    Range: 1000 V
    Resolution: 1 V
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)
    DC Volts Range: 6.000 V
    Resolution: 0.001 V
    Accuracy: 0.09% + 3

    Range: 60.00 V
    Resolution: 0.01 V
    Accuracy: 0.09% + 3

    Range: 600.0 V
    Resolution: 0.1 V
    Accuracy: 0.15% + 2

    Range: 1500 V
    Resolution: 1 V
    Accuracy: 0.15% + 2
    DC mV Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 0.09% + 2
    AC mV Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 1.0% + 3 (45 Hz to 500 Hz)

    Range: 600.0 mV
    Resolution: 0.1 mV
    Accuracy: 2.0% + 3 (500 Hz to 1 kHz)
    Continuity Range: 600.0 Ω
    Resolution: 1 Ω
    Resistance Range: 600.0 Ω
    Resolution: 0.1 Ω
    Accuracy: 0.5% + 4

    Range: 6.000 kΩ
    Resolution: 0.001 kΩ
    Accuracy: 0.5% + 4

    Range: 60.00 kΩ
    Resolution: 0.01 kΩ
    Accuracy: 0.5% + 4

    Range: 600.0 kΩ
    Resolution: 0.1 kΩ
    Accuracy: 0.5% + 4

    Range: 6.000 MΩ
    Resolution: 0.001 MΩ
    Accuracy: 1.5% + 4

    Range: 50.00 MΩ
    Resolution: 0.01 MΩ
    Accuracy: 1.5% + 4
    Capacitance Range: 1000 nF
    Resolution: 1 nF
    Accuracy: 1.2% + 2

    Range: 10.00 μF
    Resolution: 0.01 μF
    Accuracy: 1.2% + 2

    Range: 100.0 μF
    Resolution: 0.1 μF
    Accuracy: 10% typical

    Range: 9999 μF
    Resolution: 1 μF
    Accuracy: 10% typical
    Frequency Range: 99.99 Hz
    Resolution: 0.01 Hz
    Accuracy: 0.1% + 2

    Range: 999.9 Hz
    Resolution: 0.1 Hz
    Accuracy: 0.1% + 2

    Range: 9.999 kHz
    Resolution: 0.001 kHz
    Accuracy: 0.1% + 2

    Range: 99.99 kHz
    Resolution: 0.01 kHz
    Accuracy: 0.1% + 2
    AC VA (45 to 500 Hz) Range: 360.0 VA
    Resolution: 0.1 VA
    Accuracy: 2% + 1.0 VA

    Range: 3.600 kVA
    Resolution: 0.001 kVA
    Accuracy: 2% + 1.0 kVA

    Range: 36.00 kVA
    Resolution: 0.01 kVA
    Accuracy: 2% + 0.15 kVA

    Range: 60.00 kVA
    Resolution: 0.1 kVA
    Accuracy: 2% + 0.15 kVA
    DC VA Range: 360.0 VA
    Resolution: 0.1 VA
    Accuracy: 2% + 1.0 VA

    Range: 3.600 kVA
    Resolution: 0.001 kVA
    Accuracy: 2% + 1.0 kVA

    Range: 36.00 kVA
    Resolution: 0.01 kVA
    Accuracy: 2% + 0.15 kVA

    Range: 90.00 kVA
    Resolution: 0.1 kVA
    Accuracy: 2% + 0.25 kVA
    Environmental Specifications (Multimeter)
    Operating Temperature -10 to 60°C (14 to 140°F)
    Storage Temperature -30 to 70°C (-22 to 158°F)
    Humidity (without condensation) 0 to 90%, 10 to 30°C (50 to 86°F)
    0 to 75%, 30 to 40°C (86 to 104°F)
    0 to 45%, 40 to 60°C (104 to 140°F)
    Protection (Multimeter)
    Electromagnetic compatibility IEC 61326-1, IEC 61326-2-2, Portable, Group 1, Class A
    Overvoltage category CAT III 1500 V, CAT IV 1000 V
    Agency approvals ETL (AMER and EMEA), CSA (APAC), CE, UK CA
    Drop test 2 m (6.5') drop test
    Ingress protection IP52
    Mechanical and General Specifications (Multimeter)
    Counts 6000
    Battery life > 150 hours typical, without backlight (Alkaline, 3 AA)
    > 100 hours typical when connected to wireless current clamp (Alkaline, 3 AA)
    Dimensions 22.5 x 10.5 x 5.7 cm (8.8 x 4.1 x 2.2")
    Weight 0.7 kg (1.5 lb)
    Function (Current Clamp)
    AC Current (True-RMS) Range: 60 A
    Resolution: 0.01 A
    Accuracy: 1.5% + 0.15 A, 45 to 500 Hz
    DC Current Range: 60 A
    Resolution: 0.01 A
    Accuracy: 1.5% + 0.15 A
    Environmental Specifications (Current Clamp)
    Operating Temperature -10 to 60°C (14 to 140°F)
    Storage Temperature -30 to 70°C (-22 to 158°F)
    Humidity (without condensation) 0 to 90%, 5 to 30°C (41 to 86°F)
    0 to 75%, 30 to 40°C (86 to 104°F)
    0 to 45%, 40 to 60°C (104 to 140°F)
    Protection (Current Clamp)
    Electromagnetic compatibility IEC 61326-1, IEC 61326-2-2, Portable, Group 1, Class A
    Overvoltage category CAT III 1500 V, CAT IV 1000 V
    Agency approvals ETL (AMER and EMEA), CSA (APAC), CE, UK CA
    Drop test 2 m (6.5') drop test
    Ingress protection IP52
    Features (Current Clamp)
    LED indicator Indicates wireless connection and data transmission status
    Battery indicator Indicates battery status
    Power Key Power On/Off
    Zero Key A DC zeroing function
    Mechanical and General Specifications (Current Clamp)
    Jaw opening 34 mm (1.34")
    Battery life > 80 hours typical (Alkaline, 2 AAA)
    Dimensions 22.6 x 9.1 x 4.2 cm (8.9 x 3.6 x 1.7")
    Weight 0.375 kg (13.2 oz)
    Click here for complete specifications on the Fluke 283FC/PV

    What's included with the Fluke 283FC/PV

    • 283 FC TRMS Wireless Digital Multimeter
    • a283 FC 60A TRMS Wireless AC/DC Current Clamp
    • Solar MC4 Test Lead set
    • TL175-HV TwistGuard™ Silicone Test Leads
    • Carrying Case
    • TPAK Magnetic Hanging Strap
    • Limited Lifetime Warranty on the Multimeter
    • One-Year Warranty on the Clamp

    Multimeter measurements on adjustable speed drives

    In the past, motor repair meant dealing with traditional three-phase motor failures that were largely the result of water, dust, grease, failed bearings, misaligned motor shafts, or just plain old age. But motor repair has changed in a big way with the introduction of electronically controlled motors, more commonly referred to as adjustable speed drives (ASDs). These drives present a unique set of measurement problems that can vex the most seasoned pro. Thanks to new technology, now for the first time you can take accurate electrical measurements with a DMM during the installation and maintenance of a drive and diagnose bad components and other conditions that may lead to premature failure.

    Troubleshooting philosophy

    Technicians use many different methods to troubleshoot an electrical circuit, and a good troubleshooter will always find the problem - eventually. The trick is tracking it down quickly and keeping downtime to a minimum. The most efficient troubleshooting procedure begins at the motor and then works systematically back to the electrical source, looking for the most obvious problems first. A lot of time and money can be wasted replacing perfectly good parts when the problem is simply a loose connection. As you go, take care to take accurate measurements. Nobody takes inaccurate measurements on purpose, but it's easy to do, especially when working in a high-energy, noisy environment like an ASD. Likewise, choosing the right test tools for troubleshooting the drive, the motor, and the connections are of utmost importance. This is especially true when taking voltage, frequency, and current measurements on the output side of the motor drive. But until now, there hasn't been a digital multimeter on the market able to accurately measure ASDs. Incorporates a selectable low pass filter* that allows for accurate drive output measurements that agree with the motor drive controller display indicator. Now, technicians won't have to guess whether the drive is operating correctly and delivering the correct voltage, current, or frequency for a given control setting.

    Drive measurements

    Input side measurements

    Any good quality True RMS multimeter can verify proper input power to an ASD. The input voltage readings should be within 1% of one another when measured from phase to phase with no load. A significant unbalance may lead to erratic drive operation and should be corrected when discovered.

    Output side measurements

    On the flip side, a regular True RMS multimeter can't reliably read the output side of a pulse width modulated (PWM) motor drive, because the ASD applies pulse width modulated nonsinusoidal voltage to the motor terminals. A True RMS DMM reads the heating effect of the non-sinusoidal voltage applied to the motor, while the motor controller's output voltage reading only displays the RMS value of the fundamental component (typically from 30 Hz to 60 Hz). The causes of this discrepancy are bandwidth and shielding. Many of today's True RMS digital multimeters have bandwidths out to 20 kHz or more, causing them to respond not only to the fundamental component, which is what the motor responds to but to all of the high-frequency components generated by the PWM drive. And if the DMM isn't shielded for high-frequency noise, the drive controller's high noise levels make the measurement discrepancies even more extreme. With the bandwidth and shielding issues combined, many True RMS meters display readings as much as 20 to 30% higher than what the drive controller is indicating. The incorporated selectable low pass filter allows troubleshooters to take accurate voltage, current, and frequency measurements on the output side of the drive at either the drive itself or the motor terminals. With the filter selected, the readings for both voltage and frequency (motor speed) should agree with the associated drive control display indications, if available. The low pass filter also allows for accurate current measurements when used with Hall-effect type clamps. All of these measurements are especially helpful when taking measurements at the motor location when the drive's displays are not in view.

    Taking safe measurements

    Before taking any electrical measurements, be sure you understand how to take them safely. No test instrument is completely safe if used improperly, and many test instruments are not appropriate for testing adjustable speed drives. Also, make sure to use the appropriate personal protective equipment (PPE) for your specific working environment and measurements. If at all possible, never work alone.

    Safety ratings for electrical test equipment

    ANSI and the International Electrotechnical Commission (IEC) are the primary independent organizations that define safety standards for test equipment manufacturers. The IEC 61010 second edition standard for test equipment safety states two basic parameters: a voltage rating and a measurement category rating. The voltage rating is the maximum continuous working voltage the instrument is capable of measuring. The category ratings depict the measurement environment expected for a given category. Most three-phase ASD installations would be considered a CAT III measurement environment, with power supplied from either 480V or 600V distribution systems. When using a DMM for measurements on these high-energy systems, make sure it's rated at a minimum for CAT III 600V and preferably for CAT IV 600V/CAT III 1000V. The category rating and voltage limit are typically found on the front panel, at the input terminals. Dual-rated CAT IV 600V and CAT III 1000V. Refer to the ABC's of DMM Safety* from Fluke for additional information on category ratings and taking safe measurements.

    How to take measurements

    Now let's put the multimeter to the test. The measurements in the following procedure are designed to be made on a 480 volt 3 phase drive control at the control panel terminal strips. These procedures would also be valid for lower voltage 3 phase drives powered by either single or 3 phase supply voltages. For these tests, the motor is running at 50 Hz.

    Input voltage

    To measure the ac voltage supply to the input side of the drive at the drive:

    • Select the ac voltage function.
    • Connect the black probe to one of the three phase input terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase input terminals and record the reading.
    • Leaving the black probe on the reference phase now move the red probe to the third phase input and record this reading.
    • Make sure there's no more than a 1% difference between these two readings.

    Input current

    Measuring the input current generally requires a current clamp accessory. In most cases, either the input current exceeds the maximum current measurable by the current function, or it isn't practical to "break the circuit" to take an in-line series current measurement. Regardless of clamp type, insure that all readings are within 10% of each other for proper balance.

    Transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A AC function.
    • Place the clamp around each of the input supply phase cables in succession, recording each of the readings as they are taken. Since these clamps output one milliamp per amp, the milliamp readings shown on the display are the actual phase current readings in amps.

    Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the AC voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter is enabled, the meter will be in the 600 mV manual range mode.
    • Place the clamp around each of the input supply phase cables in succession, recording each of the readings as they are taken. Since these clamps output one millivolt per amp, the millivolt readings shown on the display are the actual phase current readings in amps.

    Figure 1. Output voltage reading without using the low pass filter.

    Figure 2. Output voltage reading with low pass filter enabled.

    Output voltage

    To measure the AC output voltage at either the drive or the motor terminals:

    • Plug the black test lead into the common jack and the red test lead into the V/W jack.
    • Select the AC voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the yellow button to enable the low pass filter. Now record the reading.
    • Leaving the black probe on the reference phase, now move the red probe to the third phase output voltage or motor terminal and record this reading.
    • Make sure that there's no more than a 1% difference between these two readings (see Figure 2). The readings should also agree with the controller display, panel if available.
    • If the low pass filter isn't enabled, the output voltage readings may be 10 to 30% higher, as on a regular DMM (see Figure 1).

    Figure 3. Output frequency (motor speed) without the low pass filter.

    Figure 4. Output frequency (motor speed) using the low pass filter.

    Motor speed (Output frequency using voltage as a reference)

    To determine motor speed, simply take a frequency measurement while using the low pass filter. The measurement can be made between any two of the phase voltage or motor terminals.

    • Plug the black test lead into the common jack and the red test lead into the V/W jack.
    • Select the ac voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the yellow button to enable the low pass filter.
    • Press the Hz button. The displayed reading in hertz will be the motor speed (see Figure 3). This measurement couldn't be made successfully without the low pass filter (see Figure 4).

    Output current

    TAs with input current, measuring the output current generally requires a current clamp accessory. Once again, regardless of clamp type, insure that all readings are within 10% of each other for proper balance.

    Transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A ac function.
    • Place the clamp around each of the output phase cables in succession, recording each of the readings as they're taken. Since these clamps output 1 milliamp per amp, the milliamp readings shown on the display are the actual phase current readings in amps.

    Figure 5. Output current reading without using the low pass filter.

    Figure 6. Output current reading with low pass filter enabled.

    Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the ac voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter is turned on, the meter will be in the 600 mV manual range mode.
    • Place the clamp around each of the output phase cables in succession, recording each of the readings as they are taken (see Figure 6). Since these clamps output 1 millivolt per amp, the millivolt readings shown on the 87-V display are the actual phase current readings in amps. This measurement would not be possible without the low pass filter (see Figure 5).

    Motor speed (Output frequency using current as a reference)

    For motors that pull at least 20 amps of running current, motor speed can be determined by taking a frequency measurement with current clamps. Until now, noise issues have prevented accurate readings using hall effect type clamps. Here's how the low pass filter makes it possible.

    Motor speed using a Hall Effect type (AC/DC) clamp (i410,i-1010)

    • Connect the clamp to the common and V/W input jacks.
    • Select the ac voltage function.
    • Press the yellow button to enable the low pass filter. This allows the meter to reject all of the high frequency noise generated by the drive controller. Once the low pass filter has been turned on, the meter will be in the 600 mV manual range mode.
    • Place the clamp around one of the output phase cables. Verify that the multimeter is reading a current of at least 20 amps (20 mV in the display).
    • Press the Hz button. The readings now display the motor speed as a frequency measurement.

    Motor speed using a transformer type clamp (i200, 80i-400, 80i-600A)

    • Connect the clamp to the common and 400 mA input jacks.
    • Select the mA/A AC function.
    • Place the clamp around one of the output phase cables. Verify that the multimeter is reading a current of at least 20 amps (20mA in the display).
    • Press the Hz button. The readings now display the motor speed as a frequency measurement.

    DC Bus measurements

    A healthy dc bus is a must for a properly operating motor drive. If the bus voltage is incorrect or unstable, the converter diodes or capacitors may be starting to fail. The DC bus voltage should be approximately 1.414 times the phase to phase input voltage. For a 480 volt input, the DC bus should be approximately 679 VDC. The DC bus is typically labeled as DC+, DC- or B+, Bon the drive terminal strip. To measure the DC bus voltage:

    • Select the dc voltage function.
    • Connect the black probe to either the DC- or B- terminal.
    • Connect the red probe to the DC+ or B+ terminal. The bus voltage should agree with the example mentioned above and be relatively stable. To check the amount of ac ripple on the bus, switch the 7V's function switch to the vac function. Some small drives don't allow external access to the DC bus measurement without disassembling the drive. If you can't access the DC bus, use the peak min max function on the multimeter to measure the dc bus voltage via the output voltage signal.
    • Plug the black test lead into the common jack and the red test lead into the V/½ jack.
    • Select the AC voltage function.
    • Connect the black probe to one of the three phase output voltage or motor terminals. This will be the reference phase.
    • Connect the red probe to one of the other two phase output voltage or motor terminals.
    • Press the min/max button.
    • Press the (Peak min/max) button.
    • The displayed reading in Peak min/max will be the DC bus voltage.
    datasheet for the Fluke 283FC/PV Solar Kit manual for the Fluke 283FC/PV Solar Kit Brochure: Multimeter Selection Guide

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