Description
What once took two people, now takes one
Allows one technician to do the job that would require two people. This remote display allows the user to clamp around a conductor, detach the display. Furthermore, they can walk across the room to configure controls or remove protective equipment, all while watching real-time readings.
The iFlex® Flexible Current Probe (included) expands the measurement range to 2500 A AC while providing increased display flexibility. With a cord that runs 6′, you can finally measure those tight spaces, awkward sized conductors and disorganized wires.
This product includes an ISO Certificate with full Data and Uncertainties.
Measurement capability
1000 A AC and dc current measurement with fixed jaw
2500 A AC current measurement with iFlex flexible current probe
1000 V AC and dc voltage measurement
True RMS ac voltage and current for accurate measurements on non-linear signals
Frequency measurement to 500 Hz with both jaw and iFlex
60 kµ resistance measurement with continuity detection
Min, max, average and inrush recording to capture variations automatically
Features
Wireless technology allows the display to be carried up to 30′ (9.15 m) away from the point of measurement for added flexibility without interference with measurement accuracy
iFlex™ flexible current probe expands the measurement range to 2500 A ac while providing increased display flexibility, ability to measure awkward sized conductors and improved wire access
CAT IV 600V, CAT III 1000 V safety rating
Integrated low pass filter and state of the art signal processing allows for use in noisy electrical environments while providing stable readings
Proprietary inrush measurement technology to filter out noise and capture motor starting current exactly as the circuit protection sees it
Ergonomic design fits in your hand and can be used while wearing personal protective equipment
The removable magnetic display can be conveniently mounted where it is easily seen
Radio transmitter automatically turns off when the display is connected to the meter
Large, easy to read, backlight display automatically sets the correct measurement range so you do not need to change switch positions while taking a measurement
Safety conformance: IEC/EN 61010-1:2001, 1000V CAT III, 600V CAT IV
How to measure signals using test probes
To measure ac or dc voltage:
Turn the meter’s dial to the proper voltage function ().
Connect the black test lead to the COM terminal and the red test probe to the V terminal, indicated by on the Fluke 381.
Measure the voltage by touching the probes to the desired test points of the circuit.
View the reading in the display.
To measure resistance or continuity:
Turn the dial to .
Remove power from the circuit being tested.
Connect the black test probe to the COM terminal and the red test probe to terminal.
Measure the resistance by touching the probes to the desired test points of the circuit.
View the reading on the display.
If the resistance is <30Ω, continuity is indicated by a beeper continuously sounding. If the display reads OL, the circuit is open or the resistance being measured is greater than the meters resistance range. Visual of an AC/DC voltage measurement To measure frequency (on the Fluke 381): Turn the dial to . Center the jaw or flexible probe around the measurement source. Push the yellow shift button ( on the Fluke 381) to shift to Hz. View the measurement in the display. What is True RMS? “RMS” stands for root-mean-square. It comes from a mathematical formula that calculates the “effective” value (or heating value) of any ac wave shape. In electrical terms, the ac rms value is equivalent to the dc heating value of a particular waveform—voltage or current. For example, if a resistive heating element in an electric furnace is rated at 15 kilowatts (kW) of heat at 240 V ac rms, then we would get the same amount of heat if we applied 240 V of dc instead of ac. Electrical power system components such as fuses, bus bars, conductors, and thermal elements of circuit breakers are rated in rms current because their main limitation has to do with heat dissipation. If we want to check an electrical circuit for overloading, we need to measure the rms current and compare the measured value to the rated value for the component in question. If a current clamp is labeled and specified to respond to the true-rms value of current, it means that the clamp’s internal circuit calculates the heating value according to the rms formula. This method will give the correct heating value regardless of the current wave shape. Certain low-cost current clamps, which don’t have true rms circuitry, use a short cut method to find the rms value. These meters are specified to be “average responding-rms indicating.” These meters capture the rectified average of an ac waveform and scale the number by 1.1 to calculate the rms value. In other words, the value they display is not a true value, but rather is a calculated value based on an assumption about the wave shape. The average responding method works for pure sine waves but can lead to large reading errors up to 40 percent, when a waveform is distorted by nonlinear loads such as adjustable speed drives or computers. The table below gives some examples of the way the two different types of meters respond to different wave shapes. Some true-rms clamp meters are ac coupled, which gives the rms value of only the ac component of a waveform. (This dates from the time when a majority of measurements in the electrical industry were predominately sinusoidal with no dc offset.) To measure the rms with an ac coupled clamp meter, first measure the rms value of the ac component. Then measure the waveform on the dc scale. Combine the ac and dc components by squaring each, adding the results, and then extracting the square root. The function AC+DC in Fluke true rms clamp meters essentially does the calculation for you. A comparison of average responding and true-rms units Learn more about True RMS Fluke Clamp Selection GuideWhat once took two people, now takes one Allows one technician to do the job that would require two people. This remote display allows the user to clamp around a conductor, detach the display. Furthermore, they can walk across the room to configure controls or remove protective equipment, all while watching real-time readings. The iFlex® Flexible Current Probe (included) expands the measurement range to 2500 A AC while providing increased display flexibility. With a cord that runs 6', you can finally measure those tight spaces, awkward sized conductors and disorganized wires. This product includes an ISO Certificate with full Data and Uncertainties. Measurement capability 1000 A AC and dc current measurement with fixed jaw 2500 A AC current measurement with iFlex flexible current probe 1000 V AC and dc voltage measurement True RMS ac voltage and current for accurate measurements on non-linear signals Frequency measurement to 500 Hz with both jaw and iFlex 60 kµ resistance measurement with continuity detection Min, max, average and inrush recording to capture variations automatically Features Wireless technology allows the display to be carried up to 30' (9.15 m) away from the point of measurement for added flexibility without interference with measurement accuracy iFlex™ flexible current probe expands the measurement range to 2500 A ac while providing increased display flexibility, ability to measure awkward sized conductors and improved wire access CAT IV 600V, CAT III 1000 V safety rating Integrated low pass filter and state of the art signal processing allows for use in noisy electrical environments while providing stable readings Proprietary inrush measurement technology to filter out noise and capture motor starting current exactly as the circuit protection sees it Ergonomic design fits in your hand and can be used while wearing personal protective equipment The removable magnetic display can be conveniently mounted where it is easily seen Radio transmitter automatically turns off when the display is connected to the meter Large, easy to read, backlight display automatically sets the correct measurement range so you do not need to change switch positions while taking a measurement Safety conformance: IEC/EN 61010-1:2001, 1000V CAT III, 600V CAT IV How to measure signals using test probes To measure ac or dc voltage: Turn the meter's dial to the proper voltage function (). Connect the black test lead to the COM terminal and the red test probe to the V terminal, indicated by on the Fluke 381. Measure the voltage by touching the probes to the desired test points of the circuit. View the reading in the display. To measure resistance or continuity: Turn the dial to . Remove power from the circuit being tested. Connect the black test probe to the COM terminal and the red test probe to terminal. Measure the resistance by touching the probes to the desired test points of the circuit. View the reading on the display. If the resistance is <30Ω, continuity is indicated by a beeper continuously sounding. If the display reads OL, the circuit is open or the resistance being measured is greater than the meters resistance range. Visual of an AC/DC voltage measurement To measure frequency (on the Fluke 381): Turn the dial to . Center the jaw or flexible probe around the measurement source. Push the yellow shift button ( on the Fluke 381) to shift to Hz. View the measurement in the display. What is True RMS? “RMS” stands for root-mean-square. It comes from a mathematical formula that calculates the “effective” value (or heating value) of any ac wave shape. In electrical terms, the ac rms value is equivalent to the dc heating value of a particular waveform—voltage or current. For example, if a resistive heating element in an electric furnace is rated at 15 kilowatts (kW) of heat at 240 V ac rms, then we would get the same amount of heat if we applied 240 V of dc instead of ac. Electrical power system components such as fuses, bus bars, conductors, and thermal elements of circuit breakers are rated in rms current because their main limitation has to do with heat dissipation. If we want to check an electrical circuit for overloading, we need to measure the rms current and compare the measured value to the rated value for the component in question. If a current clamp is labeled and specified to respond to the true-rms value of current, it means that the clamp’s internal circuit calculates the heating value according to the rms formula. This method will give the correct heating value regardless of the current wave shape. Certain low-cost current clamps, which don’t have true rms circuitry, use a short cut method to find the rms value. These meters are specified to be “average responding-rms indicating.” These meters capture the rectified average of an ac waveform and scale the number by 1.1 to calculate the rms value. In other words, the value they display is not a true value, but rather is a calculated value based on an assumption about the wave shape. The average responding method works for pure sine waves but can lead to large reading errors up to 40 percent, when a waveform is distorted by nonlinear loads such as adjustable speed drives or computers. The table below gives some examples of the way the two different types of meters respond to different wave shapes. Some true-rms clamp meters are ac coupled, which gives the rms value of only the ac component of a waveform. (This dates from the time when a majority of measurements in the electrical industry were predominately sinusoidal with no dc offset.) To measure the rms with an ac coupled clamp meter, first measure the rms value of the ac component. Then measure the waveform on the dc scale. Combine the ac and dc components by squaring each, adding the results, and then extracting the square root. The function AC+DC in Fluke true rms clamp meters essentially does the calculation for you. A comparison of average responding and true-rms units Learn more about True RMS Fluke Clamp Selection Guide Fluke 381-NIST Specifications Electrical Specifications Range 999.9 A Resolution 0.1 A Accuracy 2% ± 5 digits (10 to 100 Hz) 5% &plusn; 5 digits (100 to 500 Hz) Crest Factor (50/60 Hz) 3 at 500 A 2.5 at 600 A 1.42 at 1000 A Add 2% for C.F. >2
AC Current via Flexible Current Probe
Range
999.9, 2500 A (45 to 500 Hz)
Resolution
0.1, 1 A
Accuracy
3% ± 5 digits
Crest Factor (50/60 Hz)
3.0 at 1100 A
2.5 at 1400 A
1.42 at 2500 A
Add 2% for C.F. >2
DC Current
Range
999.9 A
Resolution
0.1 A
Accuracy
2.5% ± 5 digits
Click here for complete specifications on the Fluke 381-NIST
What’s included with the Fluke 381-NIST
Remote Display True RMS AC/DC Clamp Meter
ISO Certificate with full Data and Uncertainties
8″ (203.2 mm) Flexible Current Probe
Test Leads
Soft Carrying Case
5 x AA Alkaline Batteries
Coated Instruction Card
Safety Information Sheet
How to Measure Inrush Current with Fluke 381 Remote Display True RMS AC/DC Clamp Meter
In this video, the user will learn how to measure inrush current with their Fluke 381 clamp meter. To measure a motor or another mechanical device, the dial must be turned to “Amps” and then press “Inrush” to start the measurement to get the data. This device also works with iFlex so that if you’re in a tight spot, you can still get your measurement. To do so, hit the “iFlex” button and then “Inrush”.
Fluke iFlex™ & Tight Spaces
This short video demonstrates a few applications in which users can benefit from the Fluke iFlex.
How To Select The Best Fluke Clamp Meter
This video will provide a brief overview of a few Fluke clamp meters. This will allow users to get some insight into which meter they need to complete their job based on their specifications.
Fluke iFlex™ Flexible Current Probe
Need a highly flexible current clamp? This short video demonstrates an application in which users can benefit from the Fluke iFlex.
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