Discover when and where energy in your facility is being consumed. Automatically capture and log voltage, current, power, energy and associated values. The WiFi/Bluetooth feature gives you access to share data remotely with your team via Fluke Connect® app so you can maintain safer working distances and make critical decisions in real-time. Includes 3 flexible current probes.
Discover when and where energy in your facility is being consumed. Automatically capture and log voltage, current, power, energy and associated values. The WiFi/Bluetooth feature gives you access to share data remotely with your team via Fluke Connect® app so you can maintain safer working distances and make critical decisions in real-time. Includes 3 flexible current probes.
Energy logging is now within your reach— discover where you're wasting energy, optimize your facility's energy use and reduce your bill. The three-phase electrical energy logger introduces a new simplicity to discovering sources of electrical energy waste. Discover when and where energy in your facility is being consumed; from the service entrance to individual circuits. The purpose of this tool is to make it feasible for a greater variety of licensed electrical professionals to setup and connect the logger, and for a facility manager to review energy usage logs without being a power quality expert. Profiling energy usage across your facility helps you identify opportunities for energy savings, and provides you with the data you need to act on them. The new Energy Analyze software package allows you to compare multiple data points over time to build a complete picture of energy usage, which is the first step to reduce the cost of your energy bill.
Features
Applications
Load Studies
Discover how much energy
individual pieces of equipment are consuming
when they are operating at minimum and
maximum capacity. Check capacity of circuits
prior to adding additional loads (various
standards exist for this process; in the US the NEC 220-87 is the recommended standard). Load studies can also identify situations where you may be exceeding the allowable load on the circuit or
when an agreed peak demand applies from the
utility. For convenience, some load studies simply
measure current which makes installation of the
measuring equipment quick and easy. It is often
recommended that load surveys be performed
for 30 days so that all typical load conditions are
encountered during the test.
Logging Related Analog Measurements
When conducting energy studies, it is useful to log
related analog measurements such as
temperature,voltage, current or pressure. These variables provide a better overall picture of operating conditions and allow you to correlate asset
performance data with energy consumption.
Correlating these variables provides more of the
data you need to make cost saving performance
adjustments. With the Fluke 1734, up to two
Fluke Connect wireless modules can be used to
capture these measurements, and the values will
be automatically logged along with power and
energy readings.
Simplified Load Studies
For situations where it's either difficult or impractical to make a voltage connection the simple load study feature allows users to perform a simplified load study by measuring current only. The user can enter the nominal expected voltage to create a simulated power study. For accurate power and energy studies it is required to monitor both voltage and current but this simplified method is useful in certain circumstances.
Use up to two Fluke Connect wireless modules with the Fluke 1734 to capture analog measurements.
Energy Assessments
Quantify energy consumption before, and after
improvements, to justify energy saving devices.
Energy Surveys
Users often ask where measurements
should be taken for an energy survey. The
answer is multiple points within the facility. Start
at the main service feeders; compare the power
and energy measured here with the readings
from the utility meter to ensure you're receiving
the correct charges. Then move downstream to
the larger loads; these should be easy to identify
by the current rating of the electrical panels
downstream of the service entrances. Measuring
at many points will allow a full picture of energy
usage across the facility to be developed. The
next question users typically have is how long an
energy survey should last. This of course depends
on the facility, but it is recommended that you
measure for a period that matches a typical facility
activity period. If the facility operates over
a five day work week with down time on the
weekend, a seven day survey will most likely
capture typical conditions. If the facility operates at a constant level for 24 hours a day, 365 days a
year, a single day could be reasonably representative as long as you avoid a period where there
may be planned maintenance. To capture a full picture of the facilities energyusage it is not necessarily required to have measurements made simultaneously at every consumption point in the facility. To get a comprehensive picture, spot measurements can be made and then compared on a sliding time timescale.For example, you could compare the service entrance results from a typical Tuesday between 6:00 am and 12:00 pm with those of a larger load in the facility. Typically there will be some correlation between these profiles.
Power and Energy Logging
When a piece of
equipment is operated it instantaneously consumes a specific amount of power in watts (W) or
kilowatts (kW). This power is accumulated over
the operating time and expressed as energy consumed in kilowatt hours (kWh). Energy is what
your electric utility charges for; there will be a
standard charge from the utility per kilowatt hour.
Utilities may have other additional charges, such
as peak demand, which is the maximum power
demand over a defined period of time, often 15 or
30 minutes.
There may also be power factor charges, which
are based on the effects of the inductive or
capacitive loads in the facility. Optimizing peak
demand and power factor often results in lower
monthly electricity bills. The 1733 and Fluke
1734 Three Phase Electrical Energy loggers have
the capability to measure and characterize these
effects enabling you to analyze the results and
save money.
Voltage | |
Range | 1000 V |
Maximum Resolution | 0.1 V |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.2% + 0.01%) |
i17xx-Flex 1500 12" | |
Range | 150 A 1500 A |
Maximum Resolution | 0.1 A 1 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.02%) ±(1% + 0.02%) |
i17xx-flex 3000 24" | |
Range | 300 A 3000 A |
Maximum Resolution | 1 A 10 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.03%) ±(1% + 0.03%) |
i17xx-flex 6000 36" | |
Range | 600 A 6000 A |
Maximum Resolution | 1 A 10 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(.51% + 0.03%) ±(1.5% + 0.03%) |
i40s-EL Clamp | |
Range | 4 A 40 A |
Maximum Resolution | 1 mA 10 mA |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.7% + 0.02%) ±(0.7% + 0.02%) |
Frequency | |
Range | 42.5 to 69 Hz |
Maximum Resolution | 0.01 Hz |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.1%) |
Aux Input | |
Range | ±10 V DC |
Maximum Resolution | 0.1 mV |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.2% + 0.02%) |
Voltage Min/Max | |
Range | 1000 V |
Maximum Resolution | 0.1 V |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.1%) |
Current Min/Max | |
Range | Defined by accessory |
Maximum Resolution | Defined by accessory |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(5% + 0.2%) |
THD on Voltage | |
Range | 1000% |
Maximum Resolution | 0.1% |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±0.5 |
THD on Current | |
Range | 1000% |
Maximum Resolution | 0.1% |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±0.5 |
Active Power P Active Energy Ea |
|
Influence Quantity | PF ≥0.99 |
Apparent Power S Active Energy Eap |
|
Influence Quantity | 0 ≤PF ≤1 |
Reactive Power Q Reactive Energy Er |
|
Influence Quantity | 0 ≤PF ≤1 |
Additional Uncertainty in % of Range | |
Influence Quantity | VP-N <250 V |
Power Supply | |
Voltage Range | 100 to 500 V using safety plug input when powering from the measurement circuit 100 to 240 V using standard power cord (IEC 60320 C7) |
Power Consumption | Maximum 50 VA (max. 15 VA when powered using IEC 60320 input) |
Efficiency | >68.2% (in accordance with energy efficiency regulations) |
Maximum No-Load Consumption | <0.3 W only when powered using IEC 60320 input |
Mains Power Frequency | 50/60 Hz ± 15% |
Battery | Li-ion 3.7 V, 9.25 Wh, customer-replaceable |
On-Battery Runtime | Four hours in standard operating mode, up to 5.5 hours in power saving mode |
Charging Time | <6 hours |
Data Acquisition | |
Resolution | 16-bit synchronous sampling |
Sampling Frequency | 10.24 kHz at 50/60 Hz, synchronized to mains frequency |
Input Signal Frequency | 50/60 Hz (42.5 to 69 Hz) |
Circuit Types | 1-ϕ, 1-ϕ IT, split phase, 3-ϕ delta, 3-ϕ wye, 3-ϕ wye IT, 3-ϕ wye balanced, 3-ϕ Aron/Blondel (2-element delta), 3-ϕ delta open leg, currents only (load studies) |
Data Storage | Internal flash memory (not user replaceable) |
Memory Size | Typical 10 logging sessions of 8 weeks with 1-minute intervals and 500 events |
Basic Interval | |
Measured Parameters | Voltage, current, aux, frequency, THD V, THD A, power, power factor, fundamental power, DPF, energy |
Averaging Interval | User selectable: 1, 5, 10, 30 sec, 1, 5, 10, 15, 30 min |
Averaging Time Min/Max Values | Voltage, Current: Full cycle RMS updated every half cycle Aux, Power: 200 ms |
Demand Interval (Energy Meter Mode) | |
Measured Parameters | Energy (Wh, varh, VAh), PF, maximum demand, cost of energy |
Interval | User selectable: 5, 10, 15, 20, 30 min, off |
Interfaces | |
USB-A | File transfer via USB flash drive, firmware updates, max. supply current: 120 mA |
WiFi | File transfer and remote control via direct connection or WiFi infrastructure |
Bluetooth | Read auxiliary measurement data from Fluke Connect® 3000 series modules |
USB-Mini | Data download device to PC |
Voltage Inputs | |
Number of Inputs | 4 (3 phases and neutral) |
Maximum Input Voltage | 1000 V RMS, CF 1.7 |
Input Impedance | 10 MΩ |
Bandwidth | 42.5 Hz to 3.5 kHz |
Scaling | 1:1 and variable |
Measurement Category | 1000 V CAT III/600 V CAT IV |
Current Inputs | |
Number of Inputs | 3, mode selected automatically for attached sensor |
Input Voltage | Clamp input: 500/50 mV rms; CF 2.8 |
Rogowski Coil Input | 150/15 mV rms at 50 Hz 180/18 mV rms at 60 Hz CF 4 All at nominal probe range |
Range | 1 to 150 A, 10 to 1500 A with thin flexible current probe i17XX-flex1500 12" 3 to 300 A, 30 to 3000 A with thin flexible current probe i17XX-flex3000 24" 6 to 600 A, 60 to 6000 A with thin flexible current probe i17XX-flex6000 36" 40 mA to 4 A, 0.4 to 40 A with 40 A clamp i40s-EL |
Bandwidth | 42.5 Hz to 3.5 kHz |
Scaling | 1:1 and variable |
Auxiliary Inputs | |
Number of Inputs | 2 |
Input Range | 0 to ±10 V DC, 1 reading/s |
Scale Factor | Format: mx + b (gain and offset) user configurable |
Displayed Units | User configurable (7 characters, for example, °C, psi, or m/s) |
Wireless Connection | |
Number of Inputs | 2 |
Supported Modules | Fluke Connect® 3000 series |
Acquisition | 1 reading/s |
Environmental Specifications | |
Operating Temperature | 14 to 122°F (-10 to 50°C) |
Storage Temperature | −4 to 140°F (-20 to 60°C) With battery: −4 to 122°F (-20 to 50°C) |
Operating Humidity | 50 to 86°F (10 to 30°C) max. 95% RH 86 to 104°F (30 to 40°C) max. 75% RH 104 to 122°F (40 to 50°C) max. 45% RH |
Operating Altitude | 6561.7' (2000 m) up to 13,123.4' (4000 m) derate to 1000 V CAT II/600 V CAT III/300 V CAT IV |
Storage Altitude | 39,370.1' (12,000 m) |
Enclosure | IP50 in accordance with EN60529 |
Vibration | MIL-T-28800E, Type 3, Class III, Style B |
Safety | IEC 61010-1 IEC Mains Input: Overvoltage Category II, Pollution Degree 2 Voltage Terminals: Overvoltage Category IV, Pollution Degree 2 IEC 61010-2-031: CAT IV 600 V/CAT III 1000 V |
Electromagnetic Compatibility (EMC) | EN 61326-1: Industrial CISPR 11: Group 1, Class A Korea (KCC): Class A Equipment (industrial broadcasting and communication equipment) USA (FCC): 47 CFR 15 subpart B. This product is considered an exempt device per clause 15.103 |
Temperature Coefficient | 0.1 x accuracy specification/°C |
General Specifications | |
Color LCD Display | 4.3" (109.2 mm) active matrix TFT, 480 x 272 pixels, resistive touch panel |
Dimensions | Instrument: 7.8 x 6.6 x 2.2" (19.8 x 16.7 x 5.5 cm) Power supply: 5.1 x 5.1 x 1.8" (13 x 13 x 4.5 cm) |
Weight | Instrument: 2.5 lbs (1.1 kg) Power supply: 0.9 lb (400 g) |
Fluke engineers have delivered an innovative mobile platform and tool that helps solve everyday problems, allowing you to instantly document measurements, retrieve historical data, and share live measurements with your team. All handled by the Android™ or iOS smart phone you already carry.
Fluke Connect with ShareLive™ video call is the only wireless measurement system that lets you stay in contact with your entire team without leaving the field. The Fluke Connect mobile app is works with over 20 different Fluke products - the largest suite of connected test tools in the world.
Make the best decisions faster than ever before by viewing temperature, mechanical, electrical and vibration measurements for each equipment asset in one place. Get started saving time and increasing your productivity.
Click on a category to view a selection of compatible accessories with the Fluke 1734/EUS Three Phase Electrical Energy Logger, WiFi with current probes.
Load Studies
Discover how much energy
individual pieces of equipment are consuming
when they are operating at minimum and
maximum capacity. Check capacity of circuits
prior to adding additional loads (various
standards exist for this process; in the US the NEC 220-87 is the recommended standard). Load studies can also identify situations where you may be exceeding the allowable load on the circuit or
when an agreed peak demand applies from the
utility. For convenience, some load studies simply
measure current which makes installation of the
measuring equipment quick and easy. It is often
recommended that load surveys be performed
for 30 days so that all typical load conditions are
encountered during the test.
Logging Related Analog Measurements
When conducting energy studies, it is useful to log
related analog measurements such as
temperature,voltage, current or pressure. These variables provide a better overall picture of operating conditions and allow you to correlate asset
performance data with energy consumption.
Correlating these variables provides more of the
data you need to make cost saving performance
adjustments. With the Fluke 1734, up to two
Fluke Connect wireless modules can be used to
capture these measurements, and the values will
be automatically logged along with power and
energy readings.
Simplified Load Studies
For situations where it's either difficult or impractical to make a voltage connection the simple load study feature allows users to perform a simplified load study by measuring current only. The user can enter the nominal expected voltage to create a simulated power study. For accurate power and energy studies it is required to monitor both voltage and current but this simplified method is useful in certain circumstances.
Use up to two Fluke Connect wireless modules with the Fluke 1734 to capture analog measurements.
Energy Assessments
Quantify energy consumption before, and after
improvements, to justify energy saving devices.
Energy Surveys
Users often ask where measurements
should be taken for an energy survey. The
answer is multiple points within the facility. Start
at the main service feeders; compare the power
and energy measured here with the readings
from the utility meter to ensure you're receiving
the correct charges. Then move downstream to
the larger loads; these should be easy to identify
by the current rating of the electrical panels
downstream of the service entrances. Measuring
at many points will allow a full picture of energy
usage across the facility to be developed. The
next question users typically have is how long an
energy survey should last. This of course depends
on the facility, but it is recommended that you
measure for a period that matches a typical facility
activity period. If the facility operates over
a five day work week with down time on the
weekend, a seven day survey will most likely
capture typical conditions. If the facility operates at a constant level for 24 hours a day, 365 days a
year, a single day could be reasonably representative as long as you avoid a period where there
may be planned maintenance. To capture a full picture of the facilities energyusage it is not necessarily required to have measurements made simultaneously at every consumption point in the facility. To get a comprehensive picture, spot measurements can be made and then compared on a sliding time timescale.For example, you could compare the service entrance results from a typical Tuesday between 6:00 am and 12:00 pm with those of a larger load in the facility. Typically there will be some correlation between these profiles.
Power and Energy Logging
When a piece of
equipment is operated it instantaneously consumes a specific amount of power in watts (W) or
kilowatts (kW). This power is accumulated over
the operating time and expressed as energy consumed in kilowatt hours (kWh). Energy is what
your electric utility charges for; there will be a
standard charge from the utility per kilowatt hour.
Utilities may have other additional charges, such
as peak demand, which is the maximum power
demand over a defined period of time, often 15 or
30 minutes.
There may also be power factor charges, which
are based on the effects of the inductive or
capacitive loads in the facility. Optimizing peak
demand and power factor often results in lower
monthly electricity bills. The 1733 and Fluke
1734 Three Phase Electrical Energy loggers have
the capability to measure and characterize these
effects enabling you to analyze the results and
save money.
Voltage | |
Range | 1000 V |
Maximum Resolution | 0.1 V |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.2% + 0.01%) |
i17xx-Flex 1500 12" | |
Range | 150 A 1500 A |
Maximum Resolution | 0.1 A 1 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.02%) ±(1% + 0.02%) |
i17xx-flex 3000 24" | |
Range | 300 A 3000 A |
Maximum Resolution | 1 A 10 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.03%) ±(1% + 0.03%) |
i17xx-flex 6000 36" | |
Range | 600 A 6000 A |
Maximum Resolution | 1 A 10 A |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(.51% + 0.03%) ±(1.5% + 0.03%) |
i40s-EL Clamp | |
Range | 4 A 40 A |
Maximum Resolution | 1 mA 10 mA |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.7% + 0.02%) ±(0.7% + 0.02%) |
Frequency | |
Range | 42.5 to 69 Hz |
Maximum Resolution | 0.01 Hz |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.1%) |
Aux Input | |
Range | ±10 V DC |
Maximum Resolution | 0.1 mV |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(0.2% + 0.02%) |
Voltage Min/Max | |
Range | 1000 V |
Maximum Resolution | 0.1 V |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(1% + 0.1%) |
Current Min/Max | |
Range | Defined by accessory |
Maximum Resolution | Defined by accessory |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±(5% + 0.2%) |
THD on Voltage | |
Range | 1000% |
Maximum Resolution | 0.1% |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±0.5 |
THD on Current | |
Range | 1000% |
Maximum Resolution | 0.1% |
Intrinsic Accuracy at Reference Conditions (% of Reading + % of Full Scale) | ±0.5 |
Active Power P Active Energy Ea |
|
Influence Quantity | PF ≥0.99 |
Apparent Power S Active Energy Eap |
|
Influence Quantity | 0 ≤PF ≤1 |
Reactive Power Q Reactive Energy Er |
|
Influence Quantity | 0 ≤PF ≤1 |
Additional Uncertainty in % of Range | |
Influence Quantity | VP-N <250 V |
Power Supply | |
Voltage Range | 100 to 500 V using safety plug input when powering from the measurement circuit 100 to 240 V using standard power cord (IEC 60320 C7) |
Power Consumption | Maximum 50 VA (max. 15 VA when powered using IEC 60320 input) |
Efficiency | >68.2% (in accordance with energy efficiency regulations) |
Maximum No-Load Consumption | <0.3 W only when powered using IEC 60320 input |
Mains Power Frequency | 50/60 Hz ± 15% |
Battery | Li-ion 3.7 V, 9.25 Wh, customer-replaceable |
On-Battery Runtime | Four hours in standard operating mode, up to 5.5 hours in power saving mode |
Charging Time | <6 hours |
Data Acquisition | |
Resolution | 16-bit synchronous sampling |
Sampling Frequency | 10.24 kHz at 50/60 Hz, synchronized to mains frequency |
Input Signal Frequency | 50/60 Hz (42.5 to 69 Hz) |
Circuit Types | 1-ϕ, 1-ϕ IT, split phase, 3-ϕ delta, 3-ϕ wye, 3-ϕ wye IT, 3-ϕ wye balanced, 3-ϕ Aron/Blondel (2-element delta), 3-ϕ delta open leg, currents only (load studies) |
Data Storage | Internal flash memory (not user replaceable) |
Memory Size | Typical 10 logging sessions of 8 weeks with 1-minute intervals and 500 events |
Basic Interval | |
Measured Parameters | Voltage, current, aux, frequency, THD V, THD A, power, power factor, fundamental power, DPF, energy |
Averaging Interval | User selectable: 1, 5, 10, 30 sec, 1, 5, 10, 15, 30 min |
Averaging Time Min/Max Values | Voltage, Current: Full cycle RMS updated every half cycle Aux, Power: 200 ms |
Demand Interval (Energy Meter Mode) | |
Measured Parameters | Energy (Wh, varh, VAh), PF, maximum demand, cost of energy |
Interval | User selectable: 5, 10, 15, 20, 30 min, off |
Interfaces | |
USB-A | File transfer via USB flash drive, firmware updates, max. supply current: 120 mA |
WiFi | File transfer and remote control via direct connection or WiFi infrastructure |
Bluetooth | Read auxiliary measurement data from Fluke Connect® 3000 series modules |
USB-Mini | Data download device to PC |
Voltage Inputs | |
Number of Inputs | 4 (3 phases and neutral) |
Maximum Input Voltage | 1000 V RMS, CF 1.7 |
Input Impedance | 10 MΩ |
Bandwidth | 42.5 Hz to 3.5 kHz |
Scaling | 1:1 and variable |
Measurement Category | 1000 V CAT III/600 V CAT IV |
Current Inputs | |
Number of Inputs | 3, mode selected automatically for attached sensor |
Input Voltage | Clamp input: 500/50 mV rms; CF 2.8 |
Rogowski Coil Input | 150/15 mV rms at 50 Hz 180/18 mV rms at 60 Hz CF 4 All at nominal probe range |
Range | 1 to 150 A, 10 to 1500 A with thin flexible current probe i17XX-flex1500 12" 3 to 300 A, 30 to 3000 A with thin flexible current probe i17XX-flex3000 24" 6 to 600 A, 60 to 6000 A with thin flexible current probe i17XX-flex6000 36" 40 mA to 4 A, 0.4 to 40 A with 40 A clamp i40s-EL |
Bandwidth | 42.5 Hz to 3.5 kHz |
Scaling | 1:1 and variable |
Auxiliary Inputs | |
Number of Inputs | 2 |
Input Range | 0 to ±10 V DC, 1 reading/s |
Scale Factor | Format: mx + b (gain and offset) user configurable |
Displayed Units | User configurable (7 characters, for example, °C, psi, or m/s) |
Wireless Connection | |
Number of Inputs | 2 |
Supported Modules | Fluke Connect® 3000 series |
Acquisition | 1 reading/s |
Environmental Specifications | |
Operating Temperature | 14 to 122°F (-10 to 50°C) |
Storage Temperature | −4 to 140°F (-20 to 60°C) With battery: −4 to 122°F (-20 to 50°C) |
Operating Humidity | 50 to 86°F (10 to 30°C) max. 95% RH 86 to 104°F (30 to 40°C) max. 75% RH 104 to 122°F (40 to 50°C) max. 45% RH |
Operating Altitude | 6561.7' (2000 m) up to 13,123.4' (4000 m) derate to 1000 V CAT II/600 V CAT III/300 V CAT IV |
Storage Altitude | 39,370.1' (12,000 m) |
Enclosure | IP50 in accordance with EN60529 |
Vibration | MIL-T-28800E, Type 3, Class III, Style B |
Safety | IEC 61010-1 IEC Mains Input: Overvoltage Category II, Pollution Degree 2 Voltage Terminals: Overvoltage Category IV, Pollution Degree 2 IEC 61010-2-031: CAT IV 600 V/CAT III 1000 V |
Electromagnetic Compatibility (EMC) | EN 61326-1: Industrial CISPR 11: Group 1, Class A Korea (KCC): Class A Equipment (industrial broadcasting and communication equipment) USA (FCC): 47 CFR 15 subpart B. This product is considered an exempt device per clause 15.103 |
Temperature Coefficient | 0.1 x accuracy specification/°C |
General Specifications | |
Color LCD Display | 4.3" (109.2 mm) active matrix TFT, 480 x 272 pixels, resistive touch panel |
Dimensions | Instrument: 7.8 x 6.6 x 2.2" (19.8 x 16.7 x 5.5 cm) Power supply: 5.1 x 5.1 x 1.8" (13 x 13 x 4.5 cm) |
Weight | Instrument: 2.5 lbs (1.1 kg) Power supply: 0.9 lb (400 g) |
Fluke engineers have delivered an innovative mobile platform and tool that helps solve everyday problems, allowing you to instantly document measurements, retrieve historical data, and share live measurements with your team. All handled by the Android™ or iOS smart phone you already carry.
Fluke Connect with ShareLive™ video call is the only wireless measurement system that lets you stay in contact with your entire team without leaving the field. The Fluke Connect mobile app is works with over 20 different Fluke products - the largest suite of connected test tools in the world.
Make the best decisions faster than ever before by viewing temperature, mechanical, electrical and vibration measurements for each equipment asset in one place. Get started saving time and increasing your productivity.
Click on a category to view a selection of compatible accessories with the Fluke 1734/EUS Three Phase Electrical Energy Logger, WiFi with current probes.