Brymen TBM157, TBM357 User Manual

USER'S MANUAL

TBM157 & TBM357

3-Phase PowerClamp

TM

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1

1) SAFETY

This manual contains information and warnings that must be followed for operating the
instrument safely and maintaining the instrument in a safe operating condition. If the
instrument is used in a manner not specified by the manufacturer, the protection
provided by the instrument may be impaired.

The meter protection rating, against the users, is double insulation per IEC61010-1 2nd
Ed., EN61010-1 2nd Ed., UL61010-1 2nd Ed., CAN/CSA C22.2 No. 61010.1-0.92,
IEC61010-2-032, EN61010-2-032 & UL61010B-2-032:
Category CAT III 600V AC & DC.

PER IEC61010 OVERVOLTAGE INSTALLATION CATEGORY

OVERVOLTAGE CATEGORY II

Equipment of OVERVOLTAGE CATEGORY II is energy-consuming equipment to be
supplied from the fixed installation.
Note – Examples include household, office, and laboratory appliances.

OVERVOLTAGE CATEGORY III

Equipment of OVERVOLTAGE CATEGORY III is equipment in fixed installations.
Note – Examples include switches in the fixed installation and some equipment for
industrial use with permanent connection to the fixed installation.

OVERVOLTAGE CATEGORY IV

Equipment of OVERVOLTAGE CATEGORY IV is for use at the origin of the installation.
Note – Examples include electricity meters and primary over-current protection
equipment.

TERMS IN THIS MANUAL

WARNING identifies conditions and actions that could result in serious injury or even

death to the user.

CAUTION identifies conditions and actions that could cause damage or malfunction

in the instrument.

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2

WARNING

To reduce the risk of fire or electric shock, do not expose this product to rain or
moisture. The meter is intended only for indoor use.

To avoid electrical shock hazard, observe the proper safety precautions when working
with voltages above 60 VDC or 30 VAC rms. These voltage levels pose a potential
shock hazard to the user.

Keep your hands/fingers behind the hand/finger barriers (of the meter and the test
leads) that indicate the limits of safe access of the hand-held part during measurement.
Inspect test leads, connectors, and probes for damaged insulation or exposed metal
before using the instrument. If any defects are found, replace them immediately.

This Clamp-on meter is designed to apply around or remove from uninsulated
hazardous live conductors. But still, individual protective equipment must be used if
hazardous live parts in the installation where measurement is to be carried out could be
accessible.

CAUTION

Disconnect the test leads from the test points before changing meter functions.

INTERNATIONAL ELECTRICAL SYMBOLS

!

Caution ! Refer to the explanation in this Manual
Caution ! Risk of electric shock
Earth (Ground)
Double Insulation or Reinforced insulation
Fuse
AC--Alternating Current
DC--Direct Current
Application around and removal from hazardous live conductors is permitted

2) CENELEC Directives

The instruments conform to CENELEC Low-voltage directive 2006/95/EC and
Electromagnetic compatibility directive 2004/108/EC

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3

3) PRODUCT DESCRIPTION

Note: Top of the line model is used as representative for illustration purposes. Please
refer to your respective model for function availability.

1) Transformer Clamp Jaws for AC
current magnetic field pick up

2) Jaw marking lines for ACA (& thus
Power) position error indication

3) Hand/Finger Barrier to indicate the
limits of safe access to the jaws during
current measurements

4) Push-buttons for special functions &
features

5) Input Jack for all functions EXCEPT
non-invasive ACA current (& thus
Power) function

6) Common (Ground reference) Input
Jack for all functions EXCEPT
non-invasive ACA current (& thus
Power) function

7) Slide-switch Selector to turn the
power ON/OFF and Select a function

8) LCD display

9) Jaw trigger for opening the
transformer clamp jaws

10) Jaw center Indicators, at where
best ACA (& thus Power) accuracy is
specified

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4

4) OPERATION

CAUTION

Before and after hazardous voltage measurements, test the voltage function on a
known source such as line voltage to determine proper meter functioning.

AutoVATMfunction

Set the slide-switch function-selector to the position.

With no input, the meter displays “ ” when it is ready.
With no ACA current input via the jaws but a voltage signal above the nominal

threshold of DC 2.4V or AC 30V (40Hz ~ 500Hz) up to the rated 600V is present on
V-COM terminals, the meter displays the voltage value in appropriate DC or AC,
whichever larger in peak magnitude. Annunciators “Auto” “dc” and “Auto” “

” turn

on respectively.

On the contrary, with no voltage signal present on V-COM terminals but a ACA

current signal above the nominal threshold of AC 1A (40Hz ~ 500Hz) up to the rated
1000A is input via the jaws, the meter displays the ACA current value. Annunciators
“

” and “Auto” turn on accordingly.
The Auto-VA feature stays at the auto-selected function as long as its signal remains
above the specified threshold. Press SELECT button momentarily to manually select
and lock (annunciator “Auto” turns off) thru the functions ACA, ACV, DCV and then
goes back to Auto-VA.

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5

CAUTION (Application and removal of the Clamp-on meter)

For non-invasive ACA current measurements, press the jaw trigger and clamp the

jaws around only one single conductor of a circuit for load current measurement. Make
sure the jaws are completely closed, or else it will introduce measurement errors.
Enclosing more than one conductor of a circuit will result in differential current (like
identifying leakage current) measurement. Locate the conductor(s) at the Jaws center
as much as possible to get the best measuring accuracy. For removal, press the jaw
trigger and remove the jaws from the conductor(s).
Adjacent current-carrying devices such as transformers, motors and conductor wires
will affect measurement accuracy. Keep the jaws away from them as much as possible
to minimize influence.

THD%-F Total Harmonic Distortion - Fundamental function (model 157 only)

Total Harmonic Distortion - Fundamental (THD%-F) function is designed to give basic
indication on the presence of Harmonics. It is the percentage ratio of the Total
Harmonics RMS value to the Fundamental RMS value of a voltage or current signal,
and is given by the expression:

THD%-F = (Total Harmonics RMS / Fundamental RMS) x 100%

An ideal sinusoidal waveform has a theoretical value of 0 THD%. A badly distorted
sinusoidal waveform may have a much higher THD% value of even up to several
hundreds. It is thus a good parameter to identify the degree of “cleanness” on power
systems.

When the meter is in ACV or ACA function, THD%-F values will be displayed in the
secondary mini display automatically. Press THD%-F button momentarily toggles
THD% readings to main display.

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6

Peak-rms mode

Peak-rms

compares and displays the maximum RMS value of surge voltage or
current with durations as short as 65ms. When ACV or ACA function is auto-selected
or manual-selected, press and hold Peak-rms

button for one second or more
toggles to this mode. The annunciators “P-” “Max” turn on. APO (Auto Power Off)
feature is disabled automatically accordingly.

In ACA function, the Peak-rms mode starts at the highest 1000A (600A for model 357)
range to maximize measuring dynamic range. Before making measurement, press the
Peak-rms button momentarily again can manually select thru lower measuring
dynamic range 400.0A or 40.00A for higher measuring resolutions.

Line-level Frequency (Hz) function

When ACV or ACA function is auto-selected or manual-selected, press Hz button
momentarily toggles to Line-level Frequency (Hz) function. The Hz trigger level is
determined by the selected function-range from where the Hz function is activated.

In ACA function, activating the Hz function during significant measurements can get the
most appropriate trigger level to avoid electrical noises in most cases. Activating the Hz
function at AC 40.00A range (before making significant measurements) can get the
lowest trigger level (highest sensitivity).

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7

HOLD mode

When any function is auto-selected or manual-selected, press HOLD

button

momentarily toggles to Hold mode. The annunciator “

” turns on. Hold mode freezes

the display for later viewing.

Notes on Displacement Power Factor & Total Power Factor

Introduction: Power is the rate of change of energy with respect to time (in terms of

voltage V and current A). Instantaneous (real) power w = vi where v is the
instantaneous voltage and i the instantaneous current. The average (real) power is the
mean of vi and is given by:

W = /2vi dt , over the interval from 0 to 2/

Displacement Power Factor (more traditional): Assuming V and A are pure

sinusoidal waveforms without harmonics (as in most traditional cases), that is, v = V
sint and i = I sin (t -), the expression can be simplified to:

W = 1/2 x V x I x Cos where V and I are the peak values,  is the

displacement power factor angle, and Cos is the displacement power factor. Using
RMS values, it is written as:

W = V

rms

x A

rms

x Cos

Practically, in such cases without harmonics,  is also called the phase-shift angle of
the current A to the voltage V. An inductive circuit is said to have a lagging power factor

since current A lags voltage V (phase-shift angle  and thus Sin are both “+”),
and a capacitive circuit is said to have a leading power factor since current A leads

voltage V (phase-shift angle  and thus Sin are both “-”).

Total Power Factor (encountering harmonics): When encountering distorted
waveforms with the presence of harmonics, however, the simplified power expression
should not be used since substituting the above mentioned pure sinusoidal V and A
functions cannot fulfill the actual conditions. Cosine of phase-shift angle (Cos), or

the displacement power factor, is no longer the only component constituting the overall
power factor. Harmonics do increase apparent power and thus decrease the overall
power factor. That is, the Total Power Factor is actually affected by both phase-shift
angle and harmonics, and is given by the expression:

Total Power Factor (PF) = Real Power (W) / Apparent Power (VA)

In order to improve overall system power factor, nowadays power-system engineer
needs to address both phase-shift and harmonics problems. Practically, harmonics
should be dealt with (e.g. filtering out) before phase-shift to be corrected (e.g. installing
capacitors in parallel with inductive loads).

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8

Single-Phase Power & 3-Phase Balanced-Load Power functions
Set the slide-switch function-selector to the “3~Bal  1~” Power position.

Default at last selected function.
Press “3~Bal  1~” button momentarily to toggle between “Single-Phase” and

“3-Phase Balanced Load” Power functions. Annunciators “

” and “3~” turn on

respectively.

Press SELECT button momentarily selects between W (real power), VAR (reactive
power), VA (apparent power) & kWHr (real-time readings or stored result) functions. In
W (real power), VAR (reactive power), or VA (apparent power) function:

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9

1. PF (Total Power Factor) is displayed automatically in the secondary mini display.

2. Annunciator “A-lags-V” turns on to indicate an inductive circuit is being measured.
That is, the Current waveform is lagging the Voltage waveform, and the phase-shift
angle  is “+”.

3. On the contrary, together with significant PF values, WITHOUT “A-lags-V” being
turned on indicates that a capacitive circuit is being measured. That is, the Current
waveform is leading the Voltage waveform, and the phase-shift angle  is “-”.

Note:

1. Under proper measurement setups for load circuits, the W (real power) readings are
always positive. Negative W readings indicate reversed clamp-on jaws direction or test
leads polarities, or even incorrect voltage lines are being measured as in 3-phase
measurement setups. Correct them for proper “A-lags-V” indications.

2. When encountering largely distorted waveforms, “A-lags-V” detection might be
affected due to the influence of harmonics. It is recommended to manage (e.g. filter
out) harmonics problems before measuring/dealing with phase-shift problems.

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10

kWHr (kilo-Watt-Hour) Recording function

Set the slide-switch function-selector to the “3~Bal  1~” Power position. Setup power
measurements as mentioned in the previous “Single-Phase Power & 3-Phase
Balanced-Load Power functions” section

To start (“ ”) kWHr Recording, press “3~Bal  1~” and “HOLD” buttons at the
same time. Annunciator “

” turns on & flashes. kWHr accumulated time (in Hour) is

displayed automatically in the secondary mini display.
To pause (“

”), press “HOLD” button momentarily. Annunciator “ ” stops flashing

and is always on.
To continue (“

”), press the “HOLD” button momentarily again. Annunciator “ ”

resumes flashing.

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11

To stop (“ ”), press the “3~Bal  1~” and “HOLD” buttons at the same time again.
Annunciator “

” turns off. The kWHr Recording result is then displayed on the LCD

for immediate viewing. Annunciator “

” turns on & flashes.

When the low battery annunciator “

” turns on, the meter will stop (

“

”

) kWHr

recording session automatically and display kWHr Recording result as in above.

Note:

During kWHr Recording session, real-time W, VAR, VA as well as kWHr
accumulated readings can be selected by pressing the SELECT button momentarily. A
flashing “

” denotes that kWHr Recording is still under-going. An always on “ ”
denotes that kWHr Recording is being paused.
When kWHr Recording is not activated, kWHr stored result instead of accumulated
readings is displayed when selected as in above. Annunciator “

” turns on & flashes.
The meter separately stores one Single-Phase and one 3-Phase-Balanced-Load
kWHr result for later viewing. When they are being viewed, press “3~Bal  1~” button
momentarily to toggle between them.

When the display readings exceed 9999kWHr/999hours, exponential readings are

displayed. “2.3E4” kWHr represents 2.3 x 104kWHr, or 23000 kWHr for example,.
After the kWHr Recording session is stopped (

“

”

) properly, the new result will
supersede the previous one stored in the non-volatile memory. You can then switch off
the meter for transportation, storage, or even battery changing with memory remained.

To avoid mis-storage to memory, it is important to properly stop (

“

”

) kWHr
Recording session before sliding the slide-switch function-selector to any other
function positions.

3-Phase 3-Wire (3

3W) Unbalanced-Load Power Function

Set the slide-switch function-selector to the “3~Un-Bal” Power position. Press
“3W4W” button momentarily to select 3-Wire measurements. Annunciator “3W” turns
on.

Clamp the jaws around “Line 1” as reminded by annunciators “

L1”, and connect
Black test probe (COM terminal) to “Line 3” and Red test probe (+ terminal) to “Line 1”
as reminded by annunciators “ ” on mini-display.

When the reading is stable, press “

” button momentarily to enter the first

measuring value.

Then clamp the jaws around “Line 2” as reminded by annunciators “

L2”, and
connect Black test probe (COM terminal) to “Line 3” and Red test probe (+ terminal) to
“Line 2” as reminded by annunciators “

” on mini-display.

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When the reading is stable, press “ ” button momentarily to enter the second
measuring value. The meter will then calculate, store and display the total 3-Phase
Power result automatically. Annunciators “

L1 L2 L3” turn on.

Press “

” button momentarily again for new measurements.

Press “SELECT” button momentarily to view (“

”) the last stored result.

Annunciator “

” turns on & flashes. Press “SELECT” button momentarily again to

continue (“

”).

3-Phase 4-Wire (3 4W) Unbalanced-Load Power function

Set the slide-switch function-selector to the “3~Un-Bal” Power position. Press
“3W4W” button momentarily to select 4-Wire measurements. Annunciator “4W” turns
on.

Clamp the jaws around “Line 1” as reminded by annunciators “

L1”, and connect
Black test probe (COM terminal) to “Line n (neutral)” and Red test probe (+ terminal) to
“Line 1” as reminded by annunciators “ ” on mini-display.

When the reading is stable, press “

” button momentarily to enter the first

measuring value.

Then clamp the jaws around “Line 2” as reminded by annunciators “

L2”, and
connect Black test probe (COM terminal) to “Line n (neutral)” and Red test probe (+
terminal) to “Line 2” as reminded by annunciators “

” on mini-display.

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13

When the reading is stable, press “ ” button momentarily to enter the second
measuring value.

Then clamp the jaws around “Line 3” as reminded by annunciators “

L3”, and
connect Black test probe (COM terminal) to “Line n (neutral)” and Red test probe (+
terminal) to “Line 3” as reminded by annunciators “ ” on mini-display.

When the reading is stable, press “

” button momentarily to enter the third
measuring value. The meter will then calculate, store and display the total 3-Phase
Power result automatically. Annunciators “ L1 L2 L3” turn on.

 Press “

” button momentarily again for new measurements.

Press “SELECT” button momentarily to view (“ ”) the last stored result.
Annunciator “

” turns on & flashes. Press “SELECT” button momentarily again to

continue (“

”).

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/ functions

Set the slide-switch function-selector to the 

/ function position. Default at last

selected function. Press SELECT button to toggle between 

and measurement

functions.

Backlighted display
Press the SELECT button for 1 second or more to toggle the display backlight on or off.

Auto Power Off (APO)

The meter turns off after approximately 30 minutes of neither switch nor button activity.
To wake up the meter from APO, press SELECT button or slide the function-selector to
OFF position and back on again. Always turn the function-selector to OFF when the
meter is not in use.

Auto Power Off Quick Test

Press-and-hold the 3W.4W button while powering the meter on. The LCD displays
“

” & “ ” to confirm activation right after the 3W.4W button is released. Quick test

APO timing is 10 seconds after such activation.

Disabling Auto-Power-Off (APO)

Press-and-hold the HOLD button while powering the meter on. The LCD displays “ ”
& “ ” to confirm activation right after the HOLD button is released.

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15

Line Frequency setup

Press-and-hold the Hz button while powering the meter on. LCD displays the last 50Hz
or 60 Hz setup. Press SELECT button momentarily to select 50Hz or 60Hz to cope with
your local line frequency. Press Hz button for one second to store your selection and
resume measurements. Incorrect line frequency setup will introduce errors to THD%.

PC computer interface capabilities

The instrument equips with an optical isolated data output port at the bottom case near
the battery compartment. Optional purchase PC interface kit BRUA-13X (including
BA-1XX Optical Adapter Back, BC-100R Cable, BUA-2303 USB-to-Serial adaptor & Bs
software/driver CD) is required to connect the meter to PC computer USB port. The
Data Recording System software equips with a digital meter, an analog meter, a
comparator meter, and a Data Graphical recorder. Refer to the README file comes
with the interface kit for further details.

5) MAINTENANCE

WARNING

To avoid electrical shock, disconnect the meter from any circuit, remove the test leads
from the input jacks and turn OFF the meter before opening the case. Do not operate
with open case.

Trouble Shooting

If the instrument fails to operate, check batteries and test leads etc., and replace as
necessary. Double check operating procedure as described in this user’s manual

If the instrument voltage-resistance input terminal has subjected to high voltage
transient (caused by lightning or switching surge to the system) by accident or
abnormal conditions of operation, the series fusible resistors will be blown off (become
high impedance) like fuses to protect the user and the instrument. Most measuring
functions through this terminal will then be open circuit. The series fusible resistors and
the spark gaps should then be replaced by qualified technician. Refer to the LIMITED
WARRANTY section for obtaining warranty or repairing service.

Cleaning and Storage

Periodically wipe the case with a damp cloth and mild detergent; do not use abrasives
or solvents. If the meter is not to be used for periods of longer than 60 days, remove
the batteries and store them separately

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Battery replacement

The meter uses standard 1.5V AAA Size (NEDA 24A or IEC LR03) battery X 2
Loosen the 2 captive screws from the battery cover case. Lift the battery cover case.
Replace the batteries. Replace battery cover case. Re-fasten the screws.

6) Specifications
General Specifications
Display :

Voltage functions: 6000 counts LCD display
Power, Ohm & Hz functions: 9999 counts LCD display
ACA clamp-on function: 4000 counts LCD display

Update Rate :

Power function: 2 per second nominal
Voltage, ACA clamp-on & Ohm functions: 2 per second nominal
Hz function: 1 per second nominal

Polarity : Automatic
Low Battery : Below approx. 2.4V
Operating Temperature : 0oC to 40oC
Relative Humidity : Maximum relative humidity 80% for temperature up to 31oC

decreasing linearly to 50% relative humidity at 40oC

Altitude : Operating below 2000m
Storage Temperature : -20oC to 60oC, < 80% R.H. (with battery removed)

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Temperature Coefficient : nominal 0.15 x (specified accuracy)/oC @(0oC -18oC or
28oC -40oC), or otherwise specified

Sensing : True RMS sensing
Safety : Meets IEC61010-1 2nd Ed., EN61010-1 2nd Ed., UL61010-1 2nd Ed.,

CAN/CSA C22.2 No. 61010.1-0.92, IEC61010-2-032, EN61010-2-032 &
UL61010B-2-032

Measurement Category : III 600 Volts ac & dc

Transient protection : 6.5kV (1.2/50s surge)
Pollution degree : 2
E.M.C. : Meets EN61326-1:2006 (EN55022, EN61000-3-2, EN61000-3-3,

EN61000-4-2, EN61000-4-3, EN61000-4-4, , EN61000-4-5, EN61000-4-6,
EN61000-4-8, EN61000-4-11)

In an RF field of 3V/m:

Total Accuracy = Specified Accuracy + 50 digits
Performance above 3V/m is not specified

Overload Protections :

ACA Clamp-on jaws :

AC 1000A rms continuous for model 157;
AC 600A rms continuous for model 357

+ & COM terminals (all functions) : 600VDC/VAC rms

Power Supply : standard 1.5V AAA Size (NEDA 24A or IEC LR03) battery X 2
Power Consumption :

Voltage, ACA, Hz & Power functions: 11mA typical
Ohm function: 5.5mA typical

APO Timing : Idle for 30 minutes
APO Consumption : 4A typical

Dimension : L224 X W78 X H40 mm for model 157; L189 X W78 X H40 mm for model

357

Weight : 224 gm approx for model 157; 192 gm approx for model 357
Jaw opening & Conductor diameter : 45mm max for model 157; 26mm max for

model 357
Special features : Backlighted display; AutoVATM(Auto Selection on ACV, DCV or ACA
functions); selectable Power parameters of W, VAR & VA with Total Power Factor in
dual-display; Total harmonic distortion THD%-F in dual-display (model 157 only); kWHr
Recording; Display Hold; PEAK-rms HOLD; PC-Comm computer interface capabilities

Accessories : Test leads (pair), batteries installed, user's manual & soft carrying pouch
Optional accessories : PC interface kit BRUA-13X (including BA-1XX Optical Adapter

Back, BC-100R Cable, BUA-2303 USB-to-Serial adaptor & Bs software/driver CD)

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18

Electrical Specifications

Accuracy is ±(% reading digits + number of digits) or otherwise specified, at 23oC ±5

o

C & less than 75% R.H.

True RMS ACV & ACA clamp-on accuracies are specified from 0% to 100% of range or
otherwise specified. Maximum Crest Factor are as specified below, and with frequency
spectrums, besides fundamentals, fall within the meter specified AC bandwidth for
non-sinusoidal waveforms. Fundamentals are specified at 50Hz and 60Hz.

AC Voltage

RANGE

Accuracy

50Hz

/ 60Hz

600

.0V0.5

% + 5d

45Hz~ 500Hz

600

.0V1.5

% + 5d

500

Hz

~ 3.1kHz

600

.0V2.5

% + 5d

CMRR : >60dB @ DC to 60Hz, Rs=1k
Input Impedance: 2M, 30pF nominal

Crest Factor:

model 157: < 2.3 : 1 at full scale & < 4.6 : 1 at half scale
model 357: < 2 : 1 at full scale & < 4 : 1 at half scale

ACV AutoVATMThreshold: 30VAC (40Hz ~ 500Hz only) nominal

DC Voltage

RANGE

Accuracy

600

.0V0.5

% +

5

d

NMRR : >50dB @ 50/60Hz
CMRR : >120dB @ DC, 50/60Hz, Rs=1k
Input Impedance: 2M, 30pF nominal

DCV AutoVATMThreshold: 2.4VDC nominal

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19

ACA Current (Clamp-on)

RANGE

Accuracy

1) 2)

50Hz / 60Hz

40.00A,

400

.0A,

1000A (600A for model 357)

1.0% +

5d4

5Hz

~50

0Hz

40.00A,

400

.0A2.0

% +

5d1000A

(600A for model 357)

2.5% +

5d500

Hz

~ 3.1kHz

40.00A,

400

.0A2.5

% +

5d1000A

(600A for model 357)

3.0

% +

5

d

ACA AutoVATMThreshold: 1A AC (40Hz ~ 500Hz only) nominal
Crest Factor:

model 157:

< 2.5 : 1 at full scale & < 5.0 : 1 at half scale for 40.00A & 400.0A ranges
< 1.4 : 1 at full scale & < 2.8 : 1 at half scale for 1000A range

model 357:

< 3 : 1 at full scale & < 6 : 1 at half scale for 40.00A, 400.0A & 600A ranges

1)

Induced error from adjacent current-carrying conductor: < 0.06A/A

2)

Specified accuracy is from 1% to 100% of range and for measurements made at the

jaw center. When the conductor is not positioned at the jaw center, position errors
introduced are:

Add 1% to specified accuracy for measurements made WITHIN jaw marking lines
(away from jaw opening)
Add 4% to specified accuracy for measurements made BEYOND jaw marking lines
(toward jaws opening)

PEAK-rms HOLD (ACA & ACV only)

Response: 65ms to >90%

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20

THD%-F (model 157 only)

RANGE

Harmonic order

Accuracy

1)

0.0% ~50.0%

Fundamental

1.5%+ 6d

2nd ~ 3rd

7%+ 6d

4th ~ 21st

2.5%+ 6d

2) 3)

22nd ~ 51st

10%+ 10d

4)

50.0% ~100%

2nd ~ 3rd

Unspecified

4th ~ 21st

2.5%+ 6d

5) 6)

22nd ~ 51st

10%+ 10d

4)

100% ~450%

7)

2nd ~ 3rd

Unspecified

4th ~ 21

st7%

+ 6d

2) 4)

22nd ~ 51st

Unspecified

THD%-F is defined as: (Total Harmonic RMS / Fundamental RMS) x 100%

1)

Accuracy specified @ fundamental



70V & Total RMS



600V for ACV THD%-F,

fundamental



6A & Total RMS



1000A for ACA THD%-F, and Crest Factors @ :

< 2.5 for 600V Range
< 2.5 for 40A Range
< 3.0 for 400A Range
< 1.6 for 1000A Range

2)

Add 4d to specified accuracy @ 40A Range

3)

Add 4.5% to specified accuracy @ 1000A range

4)

Unspecified @ 1000A range

5)

Add 1% + 4d to specified accuracy @ 40A Range

6)

Add 4.5% to specified accuracy @ 400A ~ 750A; unspecified @ > 750A

7)

~150% for 600V Range

Frequency

RANGE

Accuracy

5Hz ~ 500Hz

0.5%+4d

Sensitivity (Sine RMS)
40A range: > 4A
400A range: > 40A
1000A (600A for model 357) range: > 400A
600V range: > 30V



21

Ohms

RANGE

Accuracy

999.9



1.0

% +

6

d

Open Circuit Voltage : 0.4VDC typical

Audible Continuity Tester

Audible threshold: between 10 and 300.
Response time: 250s

Single-Phase & 3-Phase Balanced-Load Power

RANGE

5)

0 ~ 600.0kVA

Accuracy

1) 2) 3)

F ~ 10th

11th ~ 45th

46th ~ 51st

@ PF = 0.99 ~ 0.1

2.0%+6d

3.5%+6d

5.5%+6d

RANGE

5)

0 ~ 600.0kW / kVAR

Accuracy

1) 2) 4)

F ~ 10th

11th ~ 25th

26th ~ 45th

46th ~ 51st

@ PF = 0.98 ~ 0.70

2.0%+6d

3.5%+6d

4.5%+6d 10%+6d

@ PF = 0.70 ~ 0.50

3.0%+6d

@ PF = 0.50 ~ 0.30

4.5%+6d

@ PF = 0.30 ~ 0.20

10%+6d

15%+6d

1)

Specified accuracy is for ACA clamp measurement at the center of jaws. When the

conductor is not positioned at the jaw center, position errors introduced are:

Add 1% to specified accuracy for ACA measurements made WITHIN jaw marking
lines (away from jaw opening)
Accuracy is not specified for ACA measurement made BEYOND jaw marking lines
(toward jaws opening)

2)

Add 4d to specified accuracy for 3-Phase Balanced-Load Power measurements.

3)

Add 1% to specified accuracy @ ACA fundamental < 6A or ACV fundamental < 90V.

Accuracy is not specified @ ACA fundamental < 1A or ACV fundamental < 30V

4)

Add 1% to specified accuracy @ ACA fundamental < 6A or ACV fundamental < 90V.

Accuracy is not specified @ ACA fundamental < 2A or ACV fundamental < 50V

5)

0 ~ 360.0 for model 357



22

Total Power Factor (PF)

RANGE

Accuracy

1)

0.10~ 0.99

F ~ 21st

22nd ~ 51

st3d5d

1)

Specified accuracy @ ACA fundamental > 2A ; ACV fundamental > 50V

A-lags-V Indication:

LCD annunciator “A-lags-V” turns on to indicate an inductive circuit, or Current A lags
Voltage V (i.e., phase-shift angle



is “+”).

A-lags-V Indication is specified at 50/60Hz fundamental without the presence of

harmonics, and at ACV > 90V, ACA > 9A and PF < 0.95

kWHr (kilo-Watt-Hour Energy)

Time base accuracy: < 30ppm
Non-volatile memory: Separately stores one 3-Phase-Balanced-Load and one

Single-Phase result

3-Phase Unbalanced-Load Power

This 3-Phase Unbalanced-Load Power measurement is achieved thru the calculation of

discrete single-phase measurements that are taken one at a time manually. Since it is
not real-time on all 3 phases simultaneously, it is intended only for stable power
conditions without significant power fluctuations over the time of measurements.
Result accuracy is hence the accumulated accuracy of the discrete single-phase
measurements plus the associated fluctuations.

LIMITED WARRANTY

BRYMEN warrants to the original product purchaser that each product it manufactures
will be free from defects in material and workmanship under normal use and service
within a period of one year from the date of purchase. BRYMEN's warranty does not
apply to accessories, fuses, fusible resistors, spark gaps, batteries or any product
which, in BRYMEN's opinion, has been misused, altered, neglected, or damaged by
accident or abnormal conditions of operation or handling.

To obtain warranty service, contact your nearest BRYMEN authorized agent or send
the product, with proof of purchase and description of the difficulty, postage and
insurance prepaid, to BRYMEN TECHNOLOGY CORPORATION. BRYMEN assumes
no risk for damage in transit. BRYMEN will, at its option, repair or replace the
defective product free of charge. However, if BRYMEN determines that the failure
was caused by misused, altered, neglected, or damaged by accident or abnormal
conditions of operation or handling, you will be billed for the repair.

THIS WARRANTY IS EXCLUSIVE AND IS IN LIEU OF ALL OTHER WARRANTIES,
EXPRESSED OR IMPLIED, INCLUDING BUT NOT LIMITED TO ANY IMPLIED
WARRANTY OR MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE
OR USE. BRYMEN WILL NOT BE LIABLE FOR ANY SPECIAL, INDIRECT,
INCIDENTAL OR CONSEQUENTIAL DAMAGES.

BRYMEN TECHNOLOGY CORPORATION

TEL:+886 2 2226 3396
FAX:+886 2 2225 0025

http://www.brymen.com

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