Accumet AB 30 Instruction Manual

TABLE OF CONTENTS

1 INTRODUCTION

1

2 UNPACKING THE METER

2

3 GETTING STARTED

3

3.1 Connectors 3

4 USING THE METER

5

4.1 Conductivity Probes 5

4.2 Display/ Keys 7

4.3 Screen Display 8

5 CONDUCTIVITY OPERATION

9

5.1 Using Setup 9

5.1.1 Using setup from the measure screen 10

5.1.2 Program 1: View the calculated cell constant 12

5.1.3 Program 2: View the standardized value 13

5.1.4 Program 3: Select the conductivity mode 14

5.1.5 Program 4: Select resistivity mode 14

5.1.6 Program 5: Select the TDS mode 14

5.1.7 Program 6: Select the cell constant (1.00) 15

5.1.8 Program 7: Select the cell constant (10.00) 15

5.1.9 Program 8: Select the cell constant (0.10) 15

5.1.10 Program 9: Select the temperature coefficient (2.0%)
16

5.1.11 Program 10: Select the temperature coefficient (5.2%) 17

5.1.12 Program 11: Select the temperature coefficient (0.0%) 17

5.1.13 Program 12: Select the temperature coefficient (1.5%) 19

5.1.14 Program 13: Select the TDS Factor (0.40 Ð 1.00) 20

5.1.15 Program 14: Temperature unit selection (¡C) 21

5.1.16 Program 15: Temperature unit selection (¡F) 21

5.1.17 Program 16: Enable the STABLE icon 22

5.1.18 Program 17: Disable the STABLE icon 23

6 STANDARDIZATION

25

6.1 Using Setup 25

7 MEASUREMENT

28

7.1 Conductivity Measurement 28

7.2 Resistivity Measurement 30

7.3 TDS Measurement 31

7.4 Temperature Measurement 31

8 CONDUCTIVITY OPERATION

33

8.1 Replatinization 33

9 CONDUCTIVITY THEORY

34

10 CLEANING

38

11 METER SPECIFICATIONS

38

1 2 WARRANTY

40

13 NOTICE OF COMPLIANCE

41

14 REPLACEMENT PARTS

42

14.1 Replacement parts 42

1 INTRODUCTION

Thank you for selecting the Fisher Scientific Accumet AB 3 0
bench-top meter. This instruction manual describes the operation
of the meter. The state-of-art meter that you have purchased is
easy to operate and will guide you through the various functions
by displaying easy to understand prompts.

This instruction manual is designed to provide all the information
necessary to guide you through the process of measuring pH or
mV with a series of prompts on the screen.

FF

FF

You will find this symbol appearing in this manual; it indicates
useful tips that ease your meter operation.

The Accumet AB30 provides microprocessor precision in a
compact benchtop design that is easy to use. This meter allows
you to:

§ Measure conductivity, resistivity and Total Dissolved Solids
(TDS).

§ Select cell constants, temperature coefficients, and
temperature units.

§ Standardize with two key strikes

§ Replatinise your conductivity probe

It all adds up to rapid, completely automatic, intuitive operation.

2 UNPACKING THE METER

The following is a listing of what you should have received with
your Accumet AB 30 conductivity meter.

Meter with kit includes

Meter
Power supply
Electrode arm support bracket
Electrode arm
ATC probe
Manual and literature
Note that this meter does not include a conductivity cell
RS 232 communication cable

Meter only includes

Meter
Power supply
Electrode arm support bracket
Manual and literature

If any of these items are missing, please contact the Fisher
Products Group electrochemistry Division by dialling 412/490-6267

Accessory Conductivity Probes are available and can be ordered
by calling Fisher Customer Service at 800/766-7000.

2-cell Conductivity Probes:

Cell Constant Optimal Conductivity Range Glass Body Epoxy Body

0.1 0.5 to 200 uS 13-620-156 13-620-161

1.0 0.01 to 2.0 mS/cm 13-620-155 13-620-160

10.0 1 to 200 mS/cm 13-620-157 13-620-162

4-cell Conductivity Probes:

Cell Constant Optimal Conductivity Range Glass Body Epoxy Body

1.0 0.01 to 2.0 mS/cm 13-620-163 13-620-165

10.0 1 to 200 mS/cm 13-620-164 13-620-166

3 GETTING STARTED

3.1 Connectors

1. Review the layout and arrangement of the rear connector panel.

2. Connect the electrode arm to the base.

3. Connect the power cable to the connector cable to the rear
connector panel power jack and to a power source.

4 USING THE METER

4.1 Conductivity Probes

This meter allows you to use both 2-cell and 4-cell conductivity
probes.

FF

FF

Remove the protective cover from the end of the probe. Prior to
use, soak the probe in distilled or deionized water for 10 minutes.

1. Install the 2-cell probe by plugging the pin connectors into the

OR

Install the 4-cell probe by plugging in its DIN connector into the
DIN jack on the back of the meter.

DO NOT connect both probes together.

dual pin jacks on the back of the meter.

Install the ATC probe by plugging the 1/8Ó mini-phone jack into the
ATC jack on the back of the meter.

FF

FF

The Accumet 4-cell probe has built-in ATC and a separate ATC
probe is not required.

2. Rinse the conductivity probe
sensing elements with distilled or
deionized water between samples.

3. For long term storage, the
probes can be stored dry or in distilled
water.

FF

FF

Note that the cell constant may change slightly due to storage or
use, and it must be re-evaluated with the use of standard
conductivity solution (standardization) prior to use.

4.2 Display/ Keys

Overview of the meter screen display and function key layout.

Press std key to initiate
standardization from measure
mode. Or press std key at the
Standardize mode to confirm
the standardization and
return to Measure mode.

Press setup key to access
setup for configuration of
meter setting.

Press _ key to increase value
or scroll up selection.

Press enter key to confirm
selection or change being
made.

Press stdby key to start up or
put the meter in standby
mode.

4.3 Screen Display

Familiarize yourself with the layout of the digital screen display.

5 CONDUCTIVITY OPERATION

5.1 Using Setup

Setup allows you to set the operating parameters of the meter to
meet your requirements. There are two ways to access setup, and
the parameters that you can set will be different depending on how
you accessed setup. Determine which access route you need to
utilize from the chart below:

To set the following parameter

Select the type of measurement
you wish to make (conductivity,
resistivity or TDS) and associated
units.

View the calibrated cell constant From the Measure Screen

View the last calibrated buffer
value

Select Cell constant From the Measure Screen

Select Temperature coefficients From the Measure Screen

Selecting the TDS factor From the Measure Screen

Select Temperature units From the Measure Screen

Clear the user calibration From the Measure Screen

Access Setup from the following
screen

From the Measure Screen

From the Measure Screen

Conductivity standard solution From the Standardize Screen

5.1.1 Using setup from the measure screen

If you are currently viewing the Setup screen, setup is in essence
a scroll button which allows you to access, view, and change a
variety of operating parameters. While in setup, you may:

std

setup

p

enter

stdby

Press std to exit from setup to measure screen
without making change.

Press setup to scroll to the next parameter to
view or change.

Press π to set values within each setup option.

Press enter to accept the displayed parameter.
The meter will then return to the measurement
mode.

Press stdby to return to the stdby mode without
making a change. Pressing stdby again will
place the meter in the Measure mode.

C ell Cons tant

Program 1:
View Cell Constant

- View the calculated cell constant
s tored in memory. A series of

dashes Ò- - -Ó appears if there is
no cell constant in memory.

COEFF

Program 10:
Select Temperature

Coefficient (5.2%)

- Select the temperature
coefficient from 2.0%, 5.2%,

0.0% or 1.5%. Default is 2.0%.

Program 2:
View standardized value

- View the standardized va lue. A
series of dashes Ò- - -Ó appears if

µS

the mete r is not stand ardiz ed.

COEFF

Program 3:
Conductivity Mode

- S elect the c onductivity m ode
from the setup options.

µS

COEFF

Program 4:
Resistivity Mode

- Select the resistivity mode
from the setup options.

Ωohm

TDS

Program 5:
TDS Mode

- S elect the T otal D issolved Soli d
mode from the setup options.

TDS

sele ct

°C

Program 6:

Cell Constant

Select Cell Constant 1.00

- Select the nominal cell constant
from 1.00, 10.00 or 0.10.

select

°F

Program 11:
Select Temperature

Coefficient (0.0%)

- Selec t the temper ature
coefficient from 2.0%, 5.2 %,

0.0% or 1.5%. Default i s 2.0%.

Program 12:
Select Temperature

Coefficient (1.5%)

- Selec t the temper ature
coefficient from 2.0%, 5.2 %,

0.0% or 1.5%. Default i s 2.0%.

Program 13:
Select TDS Factor

- Select the TDS facto r from 0.40
to 1.00.

Program 14:
Temperature Unit (¡C)

- Select unit of measure for
Temperature e ither in ¡C or ¡F.

Program 15:
Temperature Unit (¡F)

- Select unit of measure for
Temperature e ither in ¡C or ¡F.

Cell Constant

Cell Constant

COEFF

Program 7:
Select Cell Constant 10.00

- Select the nominal cell constant
from 1.00, 10.00 or 0.10.

Program 8:
Select C ell Constant 0.10

- Select the nominal cell c onstant
from 1.00, 10.00 or 0.10.

Program 9:
Select Temperature

clear

Coefficient (2.0%)

- S elect the temperature
coefficient from 2.0%, 5.2%,

0.0% or 1.5%. Default is 2.0%.

Overview of Setup Menus in AB30

Program 16:

STABLE

Enable Stability Indicato r

-Set the stability indicator to be
di splayed on the screen. Select
On.

Program 17:
Disable Stability

Indicator

-S et th e stabi lity indicator to be
NOT displayed on the screen.

Select OFF.

Program 18:Clear User
Standardization

-Select to clear the calibration
and return to Measure screen.

5.1.2 Program 1: View the calculated cell constant

1. Press setup to view the calculated cell constant stored in
memory.

2. If there is no cell constant in memory, a series of dashes Ò---Ò
will appear. Press enter to accept the displayed cell constant
and return to the Measure screen,

OR

3. Press setup again to go to the next page.

Cell Constant

nn

pre ss to select options

set up

pre ss to accept

enter

5.1.3 Program 2: View the standardized value

1. If the meter is not standardized , a series of dashes will
appear , Ò---Ò

2. Press enter to accept the displayed last-standardized value
and return to measure screen or press setup again to go to
the next page.

µS

nn

pre ss to select options

set up

pre ss to accept

enter

STD Solution

5.1.4 Program 3: Select the conductivity mode

Press enter to accept this choice of measuring conductivity and
return to the measure screen or press setup again to go to the
next page.

µS

5.1.5 Program 4: Select resistivity mode

Press enter to accept this choice of measuring resistivity and
return to the measure screen or press setup again to go to the
next page.

Ωohm

5.1.6 Program 5: Select the TDS mode

Press enter to accept this choice of measuring TDS and return to
measure screen or press setup again to go to next page.

TDS

5.1.7 Program 6: Select the cell constant (1.00)

Press enter to accept this choice of nominal cell constant and
return to measure screen or press setup again to go to next
page.

Cell Constant

5.1.8 Program 7: Select the cell constant (10.00)

Press enter to accept this choice of nominal cell constant and
return to measure screen or press setup again to go to next
page.

Cell Constant

5.1.9 Program 8: Select the cell constant (0.10)

Press enter to accept this choice of nominal cell constant and
return to measure screen or press setup again to go to next
page.

Cell Constant

5.1.10 Program 9: Select the temperature coefficient

(2.0%)

Press enter to accept this choice of temperature coefficient and
return to measure screen or press setup again to go to next
page.

%

COEFF

5.1.11 Program 10: Select the temperature coefficient

(5.2%)

Press enter to accept this choice of temperature coefficient and
return to measure screen or press setup again to go to next
page.

%

COEFF

5.1.12 Program 11: Select the temperature coefficient

(0.0%)

Press enter to accept this choice of temperature coefficient and
return to measure screen or press setup again to go to next
page.

%

COEFF

5.1.13 Program 12: Select the temperature coefficient

(1.5%)

Press enter to accept this choice of temperature coefficient and
return to measure screen or press setup again to go to next
page.

%

COEFF

5.1.14 Program 13: Select the TDS Factor (0.40 Ð 1.00)

Use the π key to adjust the TDS factor. Press enter to accept

these adjusted values of TDS Factor and return to measure
screen or press setup again to get to the next page.

TDS

n

press to set value

p

press to select options

n

se tup

press to accept

n

enter

5.1.15 Program 14: Temperature unit selection (¡C)

Press enter to accept the ¡C and return to measure screen or
press setup again to go to the ¡F selection page.

ress to sele ct options

set up

nn

p

press to accept

enter

select

5.1.16 Program 15: Temperature unit selection (¡F)

Press enter to accept the ¡F and return to measure screen or
press setup again to go to the next setup option page.

sele ct

5.1.17 Program 16: Enable the STABLE icon

Press enter to enable (ON) the STABLE and return to measure
screen or press setup again to disable (OFF) the STABLE setup
page.

STABLE

n

press to select options

n

setup

press to a ccept

enter

5.1.18 Program 17: Disable the STABLE icon

Press enter to disable (OFF) the STABLE and return to measure
screen or press setup again to go to the next setup page.

STABLE

n

press to select options

setup

press to accept

n

enter

5.1.19 Program 18: Clear the user standardization

Press enter to select to clear the calibration and return to
measure screen or press setup again to skip the option.

µS

clear

n

press to select options

setup

press to accept

n

FF

FF

Depends on the measure mode you are in, this setup page
clears only the particular mode calibrated value.

Suppose you access the setup pages from TDS measure mode
and you choose to clear the standardized buffer then the meter
only resets the TDS standardization. Conductivity/ Resistivity
standardization if any, will remain unchanged.

FF

FF

When accessing the cell constant, temperature coefficient, TDS
factor, temperature unit selection and stable ON/OFF setup
pages, meter displays the last selected choice and pressing
ÔsetupÕ key, takes you to other options.

enter

6 STANDARDIZATION

6.1 Using Setup

Conductivity probes are generally identified as having a
characteristic cell constant, 0.1, 1.0 or 10.0 which reflects their
physical geometry and their range of application. However, these
are typically nominal cell constants. The actual cell may vary
somewhat from the nominal values, and therefore the actual cell
constant must be calculated using a solution with a known
conductivity value. The standardization process of the AB30
meter permits you to obtain the exact cell constant of your
electrode. Standardize the electrode daily for best results.

Prior to standardizing, use the setup menu from Measure screen
to set the desired units, nominal cell constant which best
matches the electrode you are using, temperature coefficient
desired and the temperature units.

Conductivity/ standardization

Press std to enter to standardize screen. The STD Solution icon
will appear along with the measured value in both lower and
upper display with appropriate unit (uS/ mS)

If you wish to calibrate with different standard solution, press
setup to go to the screen in which user can adjust the desired
solution value in the upper display.

Upper display shows with first digit blinking and with appropriate
decimal point. Note that the unit of value you are going to set for
standardization is same as the current measurement unit. (If the
measurement is uS/ mS then setting also in uS/mS respectively.)

Use the π key to scroll until desired is set in the first digit. After

setting the first digit press setup to set the second digit.

If the first digit is not needed to set then press setup key to go to
the next digit setting.

After setting the all digits that is your standard conductivity
solution value to which you are going to standardize your meter,
press enter to confirm your set value.

After adjusted std solution value (which will be displayed at the
upper display), press std to initiate the standardization and o n
successful completion meter returns to measurement mode.

mS

STABLE

nn

press to select options

se tup

press to standardize

std

STD Solution

FF

FF

Standardization window provided is ±40% of current reading. If
the standard value set is not within the window then meter
displays ÒElectrode ErrorÓ message after initiate the
standardization.

Press enter to return to measurement mode. In this case meter
will not accept the standardization,

If the standardization is successful, then meter displays buffer
icon in the middle part of the display in the measurement mode.

Resistivity/ TDS Standardization

Follow the same procedure as explained in the conductivity
calibration.

Note:

There are separate standardization provided for conductivity,
TDS and resistivity. And also in each mode there are separate
calibration for 2 cell and 4 cell. So altogether 6 independent
calibration are available and each acts independently.

7 MEASUREMENT

7.1 Conductivity Measurement

1. Immerse the electrode into the sample solution. Stir

moderately.

FF

FF

Make sure that the meter is in the Measure mode. If you are
using the 2-cell electrode, and separate temperature probe is
NOT available then meter takes 25¡C as default temperature.

2. When the meter senses that the reading has stabilized, the
stable icon will appear under the reading. The reading may
be recorded at this time.

FF

FF

STABLE icon will only appear provided that it has been set to
ÔOnÕ mode in setup. See Program 16: Enable the Stable icon,
page 22.

mS

nn

press to select options

setup

press to standardize

std

STD Solution

STABLE

7.2 Resistivity Measurement

Unit will be in ohm, kohm or Mohm.

1. Immerse the electrode into the sample solution. Stir
moderately.

FF

FF

Make sure that the meter is in the Measure mode. If you are
using the 2-cell electrode, and separate temperature probe is
NOT available then meter takes 25¡C as default temperature.

2. When the meter senses that the reading has stabilized, the
stable icon will appear under the reading. The reading may
be recorded at this time.

FF

FF

STABLE icon will only appear provided that it has been set to
ÔOnÕ mode in setup. See Program 16: Enable the Stable icon,
page 22.

Ωohm

pres s to select options

setup

nn

pres s to standardize

std

STABLE

7.3 TDS Measurement

TDS readings will be in ppm unit. TDS factor can be selected
from the setup menu. (0.40 to 1.0). Default: 0.66.

1. Immerse the electrode into the sample solution. Stir
moderately.

FF

FF

Make sure that the meter is in the Measure mode. If you are
using the 2-cell electrode, and separate temperature probe is
NOT available then meter takes 25¡C as default temperature.

2. When the meter senses that the reading has stabilized, the
stable icon will appear under the reading. The reading may
be recorded at this time.

FF

FF

STABLE icon will only appear provided that it has been set to
ÔOnÕ mode in setup. See Program 16: Enable the Stable icon,
page 22.

TDS

STABLE

n

press to select options

setup

press to standardize

std

n

7
.

Temperature Measurement

If the temperature probe is not connected then meter displays

25.0¡C default icon on the secondary display. If the temperature
probe is connected then meter senses the actual temperature
and displays with ATC icon.

FF

FF

4-cell conductivity probe has a built-in temperature sensor.

ATC Temperature Calibration

Access method: Press stdby key while pressing the setup key.

Depends on which temperature probe is connected (4 CELL/ 2
CELL temperature probe), user can adjust the temperature value
using the triangle key. Press std key to confirm the setting.
Window: ± 5¡C (9¡F)

p

ress to set value

nn

p

press to standardize

td

s

8 CONDUCTIVITY OPERATION

8.1 Replatinization

Replatinization is the process of replacing the replacing the
platinum on the surfaces of the 2-cell conductivity probes that may
flake or wear off over time. The platinum on the surface of the
probe is used to increase the measuring surface area, resulting in
decreased population error. Should the cell constant of your
conductivity probe change by more than 50% from its typical value,
it may be necessary to Replatinise the probe. Replatinization is a
relatively quick procedure to perform, typically taking no more than
5 minutes. Although replatinization is not a long process,, the
replatinization solution is costly. If you are not certain that
replatinization will improve the performance of your accumet
conductivity probe, please call the technical support hotline at
800/943-2006, or 412/ 490-6260.

1. Immerse the probe into a suitable replatinizing solution.

2. From the Measure Screen, press setup and enter together to
access the replatinization mode. 5.00 minutes will appear on
the main display.

MIN

3. Press enter to initiate replatinization. The timer will countdown
from 5.00 minutes on the main display. Upon completion, the
meter will return to the Measure screen. Repeat step 2 if a
longer replatinization is required.

4. A new cell constant must now be established for the
probe. Refer to the standardization section, page .

9 CONDUCTIVITY THEORY

Conductance is a metric associated with the ability o primarily
aqueous solutions to carry an electrical current, I, between two
metallic electrodes when a voltage E is connected to them.
Though water itself is a rather poor conductor of electricity, the
presence of ions in the water increases its conductance
considerably, the current bring carried by the migration of the
dissolved ions. This is a clear distinction from the conduction of
current through metal, which results from electron transport.

The conductance of a solution is proportional to and a good,
though non-specific indicator of the concentration of ionic species
present, as well as their charge and mobility. It is intuitive that
higher concentrations of ions in a liquid will conduct more current.
Conductance derives from Ohms law, E= IR, and is defined as the
reciprocal of the electrical resistance of a solution.

C= 1/ R

C is conductance (siemens)
R is resistance (ohms)

One can combine Ohms law with the definition of conductance,
and the resulting relationship is:

C= I/ E

I is current (amps)
E is potential (volts)

In practice, conductivity measurements involve determining the
current through a small portion of solution between two parallel
electrode plates when an ac voltage is applied. Conductivity
values are related to the conductance (and thus the resistance) of
a solution by the physical dimensions- area and length- or the cell
constant of the measuring electrode. If the dimensions of the
electrodes are such that the area of the parallel plates is very
large, it is reasonable that more ions can reside between the
plates, and more current can be measured. The physical distance
between the plates is also critical, as it affects the strength of the
electric field between the plates. If the plates are close and the
electric field is strong, ions will reach the plates more quickly than if
the plates are far apart and the electric field is weak. By using cells
with defined plate areas and separation distances, it is possible to
standardize or specify conductance measurements. Thus comes
the term specific conductance or conductivity.

The relationship between conductance and specific conductivity is:

Specific Conductivity, S.C.= (Conductance) ( cell constant, k) =
siemens * cm/ cm2 = siemens/ cm

C is the Conductance (siemens)
K is the cell constant, length/ area or cm/ cm2

Since the basic unit of electrical resistance is the ohm, and
conductance is the reciprocal of resistance, the basic unit of
conductance was originally designated a Òmho:- ohm spelled

ÒsiemenÓ. Conductivity measurements are reported as Siemens/
cm, since the value is measured between opposite faces of a cell
of a known cubic configuration. With most aqueous solutions,
conductivity quantities are most frequently measured in

microSiemens per cm (µS/ cm) or milli-Siemens per cm (mS/ cm).

The accumet Basic AB30 meter automatically converts conductivity
readings from micro or milli Siemens to other derived units that are
widely used. These are ppm TDS (total dissolved solids), and
Resistivity (ohm*cm).

Some users prefer the use of Resistivity units to describe their
water, particularly where high purity water is involved. The unit
most often used to describe Resistivity is megohm*cm, which is

simply the reciprocal of conductivity (µS/ cm). The chart below

shows the relationship between these units.

Conductivity Measurement

Accumet conductivity probes consist of glass or epoxy bodies in
which platinum or platinised sensing elements and are designated
two-cell electrode has two such sensing elements and are
designated two-cell electrodes. The previous discussion has
focused on this type of electrode. Four cell electrodes are also
available, and the theory and application of these are in a
separate section.

These sensors contact the solution whose conductivity value is
sought. The exact cell constant of the electrode must b e
determined prior to measuring the sample. In essence, this is
accomplished by fixing the nominal cell constant of the electrode
into the meter, and recording the observed conductivity value
associated with a standard conductivity solution (usually a KCI
solution) with a precisely known value. The following calculation
yields the actual cell constant.

K= standard value of solution (µS)/ observed value of solution (µS)

Fortunately, the accumet AB30 meter automatically does this
calculation for you by touching the std button.

To produce an appropriate current signal for the meter it is
important to choose an electrode with an appropriate cell constant.
The following table lists the optimum conductivity ranges for
electrodes with cell constants of 0.1, 1, and 10.

Cell Constant Optimum Conductivity Range (µS/cm)

0.1

1.0

10.0

0.5 to 200

10 to 2000

1000 to 200,000

Prior to use, the probes should be conditioned in distilled or
deionized water for at least 10 minutes or in accordance with the
manufacturerÕs instructions.

The four-cell electrode

Traditionally, conductivity measurements were made with a Òtwo
cellÓ electrode. This electrode used two metallic sensors, an anode
and a cathode to which ions migrated. Under the influence of DC
current the electrodes quickly became polarized. In this situation,
molecules formed at the electrode surfaces and ions migrating t o
the area collect around the respective anode or cathode and
actually screen it from other ions. In essence the flow of ions
stops, and current ceases to flow. Polarization and associated
errors can be minimized by using AC voltage, the appropriate cell
constant, and a large electrode surface area. The influence of
polarization can also be minimized by the use of a four-cell
electrode.

The four cell configuration consists of two cells, an outer cell and
an inner cell. Voltage is applied to the sensors of the outer cell,
which in turn generates a voltage across the sensors of the inner
cell. The inner cell is connected to a high impedance circuit and,
unlike the outer cell generates no current. Since no current is
generated across the inner cell, polarization cannot occur at the
inner cell. By measuring the voltage of the inner cell, which is
adjusted to match the reference voltage by increasing or
decreasing the current through the inner cell, one obtains a true
picture of conductivity minus the influence of polarization.

Conductivity and Temperature

Conductivity in aqueous solutions reflects the concentration,
mobility, and charge of the ions in solution. The conductivity of a
solution will increase with increasing temperature, as many
phenomena influencing conductivity such as solution viscosity are
affected by temperature.

The relationship between conductivity and temperature is
predictable `and usually expressed as relative % change per
degree centigrade. This temperature coefficient (% change per
degree) depends on the composition of the solution being
measured. However, for most medium range salt concentrations in
water, 2% per degree works well. Extremely pure water exhibits a
temperature coefficient of 5.2%, and concentrated salt solutions
about 1.5%.

Since temperature effects the conductivity measurement so
profoundly, the usual practice is to reference the conductivity to
some standard temperature. This is typically 25¡C; therefore,
measurements are reported as if the sample were at 25¡C.

The accumet AB30 permits you to enter one of four temperature
coefficients (0.00, 1.5, 2.0, or 5.2%) and use an ATC probe to
automatically temperature compensate back to a reference
temperature of 25¡C.

The meter requires no regular maintenance, but it is recommended
to occasionally wipe down the front with a damp cloth. If there are
any further questions regarding maintenance, call the Fisher Lab
Equipment Technical Support Hotline at 800/943-2006 or
412/490-6260.

10 CLEANING

This meter requires no regular maintenance, but it is recommended
to occasionally wipe down the front with a damp cloth from time to
time.

11 METER SPECIFICATIONS

Description AB30

Display

Screen Size 3Ó X 4.25Ó

Measurement Display Height _Ó H

Temp./ others display height 5/16Ó

Keypad controls 5 keys (membrane)

Memory Internal Diagnostics

Conductivity Mode

Custom LCD

Range 0.0 to 500.0 mS

0.001 for 0.000 Ð 9.999 µS

0.01 for 10.00- 99.99 µS

Resolution

Accuracy 0.5% of the Reading

Resistivity Mode

Resistivity Up to 100 Ohm

Resolution

0.1 for 100.0 Ð 999.9 µS

0.001 for 1.000 Ð 9.999 mS

0.01 for 10.00 Ð 99.99 mS

0.1 for 100.0 Ð 500.0 mS

0.001 for 0.000 Ð 9.999 ohm

0.01 for 10.00- 99.99 ohm

0.1 for 100.0 Ð 999.9 ohm

0.001 for 1.000 Ð 9.999 kohm

0.01 for 10.00 Ð 99.99 kohm

0.1 for 100.0 Ð 999.9 kohm

0.001 for 1.000- 9.999 Mohm

0.01 for 10.00 Ð 99.9 Mohm

Accuracy 0.5% of the reading

TDS Mode

TDS 0 to 99999 ppm

0.001 for 0.000 Ð 9.999

Resolution

Accuracy 0.5% of the reading

Others

Cell constants range 0.1, 1.0, 10.0

Temperature coefficients 0.0%, 1.5%, 2.0%, 5.2%

TDS factor 0.40 Ð 1.00 (adjustable in step of 0.01)

Temperature mode:

Range - 5 to 105¡C 23.0 to 221.0 ¡F)

Resolution 0.1

Accuracy ± 0.5¡C

General

0.01 for 10.00 Ð 99.99

0.1 for 100.0 Ð 999.9
1 for 1000 Ð 99999

Inputs

Power Supply

2 cell (2 pins) conductivity, 4 cell (DIN)

conductivity, ATC

230 V/ 50 Hz, 115/60 Hz 12 V DC

(centre negative)

12 WARRANTY

The Fisher Scientific Company (ÒFisherÓ) warrants to the direct
purchaser that the Accumet meters and Accumet, AccuTupH,
AccuFet, AccupHast, and Microprobe electrodes will be free from
defects in material or workmanship for a specified warranty period.
During that period, Fisher will repair or replace the product or
provide credit, at its sole option, upon prompt notification and
compliance with its instructions. For Accumet meter, that specified
period is 36 months from delivery date. For electrodes, that
specified period is 12 months- except for models 13-620-532, 13­620-533, 13-620-534, 13-620-535, 13-620-536, 13-620-537, 13­620-538, 13-620-539- which are warranted for six months.

Unless otherwise agreed, the warranty is limited to the country in
which the product is sold.

No Fisher employee, agent or representative has the authority to
bind Fisher to any oral representation or warranty concerning any
product sold. Any oral representation or warranty made prior to
purchase of any product and not set forth in writing and signed by
a duly authorized officer of Fisher shall not be enforceable by the
purchaser.

FISHER EXPRESSLY DISCLAIMS ALL OTHER WARRANTIES,
EXPRESS OR IMPLIED WARRANTY OF MERCHANTABILITY
AND FITNESS FOR A PARTICULAR PURPOSE.

FisherÕs sole responsibility and the purchaserÕs exclusive remedy
for any claim arising out of the purchase or any product listed
above is repair, replacement or credit as described above, where
applicable. In no event: 1) shall the cost of the exclusive remedy
exceed the purchase price: 2) shall Fisher be liable for any special,
indirect, incidental, consequential, or exemplary damages,
howsoever arising, even if Fisher has been advised of the
possibility of such damages.

Each article that Fisher furnishes will conform to the written
specifications given in this manual, or those of a further improved
model. Changes are made often to the information in the manual
and will be incorporated into future editions.

13 NOTICE OF COMPLIANCE

Warning

This meter generates, uses, and can radiate radio frequency
energy. If not installed and used properly, that is in strict
accordance with the manufacturerÕs instructions, it may cause
interference to radio communications. It has been tested and
found to comply with the limits for a Class A computing device
pursuant to Subpart J of Part 15 of FCC Rules, which are
designed to provide reasonable protection against such
interference when operated in a commercial environment.
Operation of this equipment in a residential area may cause
interference, in which case the user, at his own expense, will b e
required to take whenever measures may be required to correct
the interference.

This product is to be used only as described in the manual. This
product is for indoor use only, and must be used in a well
ventilated area.

Warning!
To meet or exceed FCC regulations and comply with CE
requirements, the Fisher Scientific supplied power supply
must be used. Use of a power supply that is not approved by
Fisher Scientific may cause safety hazards and/or cause unit
to exceed EMC limits and/or damage unit. When using his
meter with a computer or printer, a shielded RS232 cable must
be used to meet or exceed FCC regulations, and comply with
CE Mark requirements.

14 REPLACEMENT PARTS

14.1 Replacement parts

Description Fisher Catalog Number

AccuFlex electrode support arm 13-637-671

Electrode support bracket 13-637-671A

Power Supplies: 115V, US plug 13-636-100

230V, UK plug 13-636-101

230V, Europe plug 13-636-102

OperatorÕs Manual 13-636-AB15M

ATC probe 13-620-19

To place an order, call 1-800/ 766-7000

For technical Support, call 1-800/ 943-2006

68X295901 Rev. 2 0903