AND RV-10000 Vibro Rheometer Instruction Manual

: June 9, 2024
: AND

RV-10000 Vibrio Rheometer
Instruction Manual AND RV 10000 Vibro Rheometer

RV 10000
Vibrio Rheometer
-INSTRUCTION MANUAL

RV-10000 Vibrio Rheometer

© 2013 A&D Company Ltd. All rights reserved.
No part of this publication may be reproduced, transmitted, transcribed, or translated into any language in any form by any means without the written permission of A&D Company Ltd.
The contents of this manual and the specifications of the instrument covered by this manual are subject to change for improvement without notice.

INTRODUCTION

This manual describes how the rheometer RV-10000 works and how to get the most out of it in terms of performance.
Read this manual thoroughly before using the rheometer and keep it at hand for future reference.

1-1 Compliance
Compliance with FCC Rules
Please note that this device generates, uses and can radiate radio frequency energy. This device has been tested and has been found to comply with the limits of a Class A computing device pursuant to Subpart J of Part 15 of FCC rules. These rules are designed to provide reasonable protection against interference when this device is operated in a commercial environment. If this unit is operated in a residential area, it may cause some interference and under these circumstances the user would be required to take, at his own expense, whatever measures are necessary to eliminate the interference.
(FCC = Federal Communications Commission in the U.S.A.)

Compliance with Council Directives
This device features radio interference suppression and safety regulation in compliance with the following Council Directives
Council directive 89/336/EEC EN61326 EMC directive
Council directive 73/23/EEC EN60950 Safety of Information Technology Equipment
EN61326 Emission and Immunity.
Note
The CE mark is an official mandatory European marking.
Please note that any electronic product must comply with local laws and regulations when sold or used anywhere outside Europe.
1-2 Features

High accuracy
The Vibrio Rheometer adopting the sine-wave vibration technique, achieves a high measurement accuracy of 1% (repeatability) over the full range.
Because amplitude with the sensor plates can be changed, viscosity change can be measured by change in shear speed.
The sensor plates are made of corrosion resistant titanium. Although titanium is a chemically stable material, it is corroded by some liquid such as sulfuric acid. So, handle it with much care.
Wide range continuous measurement
Continuous measurement over the whole measuring range is possible, without replacing the viscosity detection sensor plates.
Standard temperature sensor
The temperature sensor to measure the sample temperature is installed as standard. The temperature sensor is located between the two sensor plates. So, the accurate detection of the relation between temperature and viscosity is possible.
Accurate measurement
Due to the low heat capacity of the viscosity detection unit (sensor plates and temperature sensor), the time required for temperature equilibrium is short. Thus, the sample viscosity can be measured accurately in a short time.
Long continuous measurement time
The sensor plates, with a low frequency of 30 Hz, apply very little load to the sample. So, the rheometer can continuously obtain stable viscosity values without causing a temperature rise or damaging the sample.
The sine-wave vibrio rheometer (viscometer) measures “viscosity x density”. While viscosity (mPa.s) is used as the unit for measuring, this is displayed assuming that density is 1g/cm3.
Measurement of a non-Newtonian fluid/foaming sample
The thin sensor plates allow little deformation of the sample texture. Thus, non-Newtonian fluid can be measured in a stable way. And, foaming samples (whipped cream, etc.)) can be measured without breaking minute foam particles and with less influence scattering large foam particles.
When measuring tap water, bubbles may accumulate on the sensor plates, increasing the viscosity.
Viscosity measurement of a flowing sample
The two sensor plates oscillate in the opposite direction. So, even when a sample is in motion, errors are eliminated. This allows measurement of a sample while being stirred. Therefore, the rheometer can be used for a continuously flowing product line, which enables field management with identical data used at the laboratories.
Calibration
The rheometer can be calibrated using a standard viscosity fluid or a sample of a known viscosity. Calibration allows the rheometer to maintain the accuracy constantly.
Simplified calibration when measuring the viscosity near 1 maps
Simplified calibration using purified water is a one-key operation. The rheometer has a built-in function to measure the temperature of the purified water using the temperature sensor and calculates the viscosity value of the purified water at that temperature. At this time, be careful not to influence the viscosity value by generating bubbles.
Standard windows communication tools Win CT-Viscosity
Windows communication tools Win Ct-Viscosity (CD-ROM) is provided as standard. The CD-ROM contains the graphing program Viscous, which imports the data into a personal computer and displays the results as a graph in real time. With Viscous, changes in viscosity over time and temperature dependency of viscosity can be observed easily and the obtained data can be saved in files.
When using the accessory serial / USB converter, the personal computer can input the data using the personal computer’s USB port.
The cup, that the sample is to be measured in, can be the plastic sample cup and the glass sample cup. When measuring an organic solvent, use the glass sample cup.

UNPACKING THE RHEOMETER

The rheometer is a precision instrument. Unpack the rheometer carefully. Keep the packing material to be used for transporting the rheometer in the future.

2-1 Part names
＊The illustration below is after assembling. AND RV 10000 Vibro Rheometer -
Fig1

Accessories

AND RV 10000 Vibro Rheometer - Accessories

Note
Please confirm that the AC adapter type is correct for your local voltage and receptacle type. AND RV 10000 Vibro Rheometer -
Fig2 AND RV
10000 Vibro Rheometer - Fig4

DISPLAY AND KEYS

3-1 Display

AND RV 10000 Vibro Rheometer - Display

Name	Description

Viscosity display

| Standby mode| Displays [——- ].
Measurement mode| Displays the viscosity value in real time.
Viscosity units| Displays the unit of viscosity.
Temperature display| Standby mode| Displays the temperature value in real time.
Measurement mode
Temperature units| Displays the unit of temperature.
Processing indicator| Blinks while the measurement is being performed. (While the sensor plates are in vibrating motion)
Rs Viscos link indicator| Illuminates while measurement is performed using Rs Viscos, the graphing program contained in the Win CT-Viscosity (CD-ROM).
Calibration indicator| Displays ” C ” in the calibration mode.

Calibration mode ID indicator

3-2 Keys

AND RV 10000 Vibro Rheometer - Fig5

Key

| Description
---|---

ON:OFF
Power

| Turns the power on and off.
When the power is turned on, the rheometer enters the standby mode ( [——- ] is displayed.)

START
Start measurement

| Start a measurement. (The processing indicator blinks.) Displays the viscosity and temperature values in real time during measurement.
If the display is set to HOLD, release it by pressing the START key.

STOP
Stop measurement

| Stops the measurement (The processing indicator is off) and freezes the display of the viscosity and temperature values at the time the STOP key is pressed during measurement.
When the STOP key is pressed again, the rheometer enters the standby mode.

Decrease amplitude value

| Press and release: Decreases the amplitude value gradually.
Press and hold: Enters the calibration mode.

Increase amplitude value

| Press and release: Increases the amplitude value gradually.
Press and hold: Puts into function setting mode.

PRINT
Output data

| Outputs the measurement data.

3-3 Displaying the Viscosity Values
The viscosity values are displayed as below, depending on the unit selected and the viscosity range.
The correlation of the units are as follows: 1 mPa×s = 0.001 Pa.s = 1 cpm =0.01 P
It is possible to switch between mPa×s (Millipascal second) and Pa.s (Pascal second), or between cpm (Centipoise) and P (Poise), using the function setting. (Refer to “8. FUNCTION SETTING”)
The unit selected at the factory before shipment is mPa×s.
When the viscosity unit is mPa×s or Pa.s:

Viscosity measured
mPa×s| Unit selected
---|---
mPa×s| Pa×s
Display| Minimum display| Unit| Remarks| Display| Minimum display| Unit| Remarks
10| 0.30
｜
1.00
｜
9.99
10.0
｜
99.9|

0.01
0.1

| mmPa×s| | 0.0003
0.0010
0.0099
0.0100
0.0999|

0.0001
0.0001

| Pa×s| Digit indicating

0.01 mPa×s is not displayed

100| 100| | | 0.100| | |
| ｜| 1| | | 0.001| |
| 999| | | 0.999| | |
1000
10000| 1.00
｜
10.00|

0.01

| Pa×s| Switches to Pa×s| 1.00
｜
10.00| 0.01| |

When the viscosity unit is cpm or P:

Viscosity measured

mPa×s

| Unit selected
---|---
cP| P
Display| Minimum display| Unit| Remarks| Display| Minimum display| Unit| Remarks
1
10
100
1000
10000| 0.30
｜
1.00
｜
9.99
10.0
｜
99.9
100
｜
999|

0.01
0.1
1

| cpm| | 0.0030
｜
0.0100
｜
0.0999
0.100
｜
0.999
1.00
｜
9.99
10.0
｜
100.0| 0.0001

0.001
0.01
0.1

| P|
10.0
｜
100.0| 0.1| P| Switches to P

PRECAUTIONS

To get the optimum performance from the rheometer and acquire accurate measurement data, note the following:

4-1 General Precautions
For accurate measurement, use care with the following conditions.

Install the rheometer in an environment where the temperature and humidity are not excessive.
The best operating temperature is 25°C2°C at 45-60% relative humidity.
For precise measurement, install the rheometer where there are no great changes in temperature and humidity.
Install the rheometer where it is free of dust.
The rheometer uses the Tuning-fork Vibration Method. So, use much care to avoid external vibration, especially when measuring low viscosity.
Places where the rheometer is prone to vibration are: Second or higher floor, soft ground, near busy highways or rail lines.
Avoid these places as a measuring site. If measurement is to be performed in such a place, use an anti-vibration table that is available as an option (AD- 1671A).
Do not measure where heaters or air conditioners can affect the measurement.
Do not measure where direct sunlight can affect the measurement.
Install the rheometer away from equipment which produces magnetic fields.
Protect the internal parts from liquid spills and excessive dust.
Do not disassemble the rheometer.
When precise measurement is required, acclimatize the rheometer to the measuring environment. After installation, plug in the AC adapter and warm up the rheometer for one hour or more.

4-2 During Use

The RV-10000 rheometer, designed for very accurate measurement, is sensitive to vibration or shock during transportation, as that may cause a display value error. Before measurement, calibrate the rheometer using the sample cup that will be used for measurement.
To level the surface of the sample, adjust the leveling feet. (Height adjustment of the right and left leveling feet.)

AND RV 10000 Vibro Rheometer - During Use

In general, a viscosity value with a liquid changes in accordance with temperature change (In general, if increasing the temperature, the viscosity value decreases about 2 to 10 percent per degree Celsius). Take changes in the liquid temperature into consideration for an accurate measurement.
Be sure to calibrate using the standard viscosity fluid or purified water before measurement. In a measurement that takes a long time, perform calibration periodically, as necessary.
Ensure a stable power source when using the AC adapter.
Placing the sensor plates and the temperature sensor in the sample may change the sample temperature. For precise measurement, leave the sample as is for a while, after placing the sensor plates and the temperature sensor, to ensure no changes to the sample temperature. And then, start a measurement.
Use only your finger to press the keys. Using a sharp instrument such as a pen may damage keys.
Handle the sensor plates with care.
If the sensor plates, or the protector, touch the inner wall of the sample cup, it may cause measurement error. When measuring, be sure to adjust the spacing between the sensor plates and the inner walls of the sample cup.
The sample cups are made of polycarbonate (PC) or glass. When using organic solvents, we recommend the use of the glass sample cup (accessory or sold separately) or a commercially available glass beaker.
Raise or remove the protector if necessary.
Precautions to be taken with the sample cup used
When the sample cup for measuring is changed, that may cause a change in the displayed viscosity value. Therefore, we recommend that you calibrate the rheometer using standard viscosity fluid. (Refer to “6-4. Measuring the Absolute Value of Viscosity Using the Small Sample Cup” for details.)

How to remove the protector:
Press the left and right side frames lightly in the direction indicated as 1 to remove the rotational axis. Pull the protector in the direction indicated as 2 to remove. AND RV 10000 Vibro Rheometer - Fig6

4-3 After Use

Remove any residual sample material from the sensor plates, temperature sensor and protector using alcohol. Using the sensor plates, temperature sensor and protector with residue of an old sample left on will cause a measurement error. Clean the sensor plates carefully to avoid bending them. The sensor plates and the temperature sensor are made of titanium.
How to clean the sensor plates and temperature sensor
Hold the sensor plate or temperature sensor with tissue paper.
Move the tissue paper downward to remove the sample.
Then, use tissue paper moistened with alcohol, to remove any residual sample material.
Clean the sample cup as necessary.
Unlock the cable connector before disconnecting the connection the cable. How to unlock the cable connector

AND RV 10000 Vibro Rheometer - Fig8 AND RV 10000
Vibro Rheometer - Fig9

4-4 About viscosity measured with the RV
When the sample cup for measuring is not a sample cup with 45mL capacity, viscosity will change at a value where viscosity is several thousand mPa×s or more. Therefore, calibrate using standard viscosity fluid by the cup used.
The RV-10000 Sine-wave Vibrio Rheometer, as a measuring principle, detects the product of viscosity and density (defined as “static viscosity”)..
Static viscosity = Viscosity x Density …………. [1] While the displayed value has a unit of mPa×s, it indicates the product of viscosity and density.
Example (1) When a sample has a viscosity of 2.00 mPa×s and density of 1.000:
Displayed value = 2.00 [mPa×s] x 1.000 = 2.00 [mPa×s] (2) When a sample has a viscosity of 2.00 mPa×s and density of 0.800:
Displayed value = 2.00 [mPa×s] x 0.800 = 1.60 [mPa×s]

Note
The density can be measured, using the density determination kit, AD-1653 in combination with a balance.
To obtain the absolute viscosity value precisely, do as follows:
4-4-1 At Measurement
Divide the static viscosity by the sample density to obtain the viscosity.
Example (1) Measure the sample and confirm the static viscosity.
Here, 736 mPa×s as an example.
(2) Check the sample density at the temperature when the sample is measured.
Here, 0.856 as an example.
(3) Divide the static viscosity by the sample density to obtain the viscosity.
Here, 860 mPa×s is obtained as the viscosity.

4-4-2 At Calibration
When calibrating, enter the product of the absolute viscosity value and the density of the standard viscosity fluid used for calibration, as a correction value.
The standard viscosity fluid has the calculation sheet of kinetic viscosity and viscosity at various temperatures attached. To obtain the correction value using this sheet, do as follows: AND RV 10000 Vibro Rheometer -
Fig11

Example 1: To calibrate the rheometer using a standard viscosity fluid:
Using the calculation sheet, calculate the value used for calibration.
(1) Check the kinetic viscosity and the viscosity at the temperature when the calibration is performed. Here, 1011 mm2/s for the kinetic viscosity and 889 mPa×s for the viscosity at 20°C as an example.
(2) Substitute the values above into equation [4]. 781 mPa.s is obtained as a correction value used for calibration.
(3) After calibration, measure the viscosity of the standard viscosity fluid used. In this example, a value similar to “781 mPa×s” is confirmed as static viscosity, and calibration
then ends.

Example 2: To calibrate using a standard viscosity fluid with known values of viscosity and density.
In this example, a standard viscosity fluid with a viscosity of 889 mPa×s at 20°C is used.

Check the viscosity value and the density of the standard viscosity fluid at the temperature when the calibration is performed.. Here, 889 mPa×s for the viscosity and 0.878 for the density at 20°C as an example.
Substitute the values above into equation [3]. 889 x 0.878 x 781 781 mPa×s is obtained as a correction value used for calibration.
After calibration, measure the viscosity of the standard viscosity fluid used. In this example, a value similar to “781 mPa×s” is confirmed as static viscosity, and calibration then ends.

4-5 About the relation among amplitude value, shear speed and viscosity
When measuring with a non-Newtonian fluid, a viscosity can not be judged without deciding a value for shear speed or shear stress because there is no proportional relation between shear speed and shear stress.
When measuring with the RV-10000, vibration is repeatedly applied to the sample using sine vibration, and viscosity is expressed by converting into an effective value the shear speed that is constantly changing due to vibration.
Refer to the following charts for details of the relation among amplitude value, shear speed and viscosity with the RV-10000.
The second chart below shows the relation between the viscosity measurement range at each amplitude and shear speed. AND RV 10000 Vibro Rheometer -
Fig13

MEASUREMENT

5-1 Preparing the Sample

Vibration or shock during transportation may cause a display value error. Before measurement, calibrate the rheometer using the sample cup that will be used for measurement. For calibration with purified water, refer to “7-2-3 Simplified Calibration Using Purified Water”.

Operation procedure

Pour the sample into the cup until its surface is between the level gauges.
– With the 45 mL sample cup, the lower level gauge indicates 35 mL, the upper level gauge indicates 45 Mr.
– The 13 mL glass sample cup does not have level gauges.
The position approximately 25 mm above the cup bottom indicates 13 Mr.
Attach the cup on the table along the guides.
Confirm that the protector is in the position as shown in the figure.
Raise the lever to release the sensor unit.
Pinch the grips, support the front side of the sensor unit and gently lower the sensor plates above the sample surface.
Lower the lever to secure the sensor unit.
Confirm that the positioning of the sensor plates is in center of the sample cup by adjusting the X-Y-Z stage.
Turn the knob (Height direction) so as to adjust the sample surface to the center of the narrow part of the sensor plates. At this time, use the surface locator plate as a guide. The surface locator plate has been secured in position so that the tip of the surface locator plate comes into contact with the sample surface.

Note

Adjust the height of the sample surface correctly, otherwise it may cause a measurement error.
The surface locator plate can be attached or removed by loosening the screw.
Before removing the sensor protective cover, remove the surface locator plate.
Removing and reattaching the surface locator plate will cause the position (Height) of the sensor plates and the sample surface to change. Therefore, it is recommended
that calibration be performed using a standard viscosity fluid before measurement.

Note
Use the protector in the position as shown on the left below. If the protector is not used, a measurement error may occur, especially in measuring a viscosity over 5000 mPa×s. AND RV 10000 Vibro Rheometer -
Fig22 When the position of the sensor plates in the liquid is not at the same level, level the rheometer using the leveling feet so that the liquid surface will be leveled.

5-2 Basic measurement
5-2-1. Setting amplitude value

With the power off, press the ON:OFF key.
Once the display is in standby mode, press the key.
The amplitude value display blinks.
By pressing key, the amplitude value increases.
By pressing key, the amplitude value decreases.
Press the PRINT key at the desired amplitude value to confirm the amplitude value.
(Even if the START key is pressed, the amplitude value will be confirmed. After that, vibration is started.)

Settable range of amplitude

Amplitude *	Amplitude value display
0.07mm	o7
0.1mm	0 . 1
0.2mm	0 . 2
0.4mm	0 .4
0.6mm	0 .6
0.8mm	0 . 8
1.0mm	1 .0
1.2mm	1 . 2

The amplitude value is peak to peak (P-P).

5-2-2. Measurement

1. Starting measurement
Press the START key to start vibration. The viscosity value is displayed after approx. 15 seconds. While measurement is being carried out, the processing indicator illuminates. (2) Changing the amplitude during measurement

Even while the measurement is being carried out, it is possible to change the amplitude by pressing the key. If the display blinks. key is pressed, the amplitude
By further pressing the key, the amplitude value changes.
Press the PRINT key at the desired amplitude value to confirm the amplitude value.

When an amplitude is changed, the bar display blinks. The amplitude value is displayed after approx. 15 seconds.
(3) Stopping measurement
Press the STOP key to stop the measurement. The viscosity value is held.
(4) Measuring again 1
When measuring again at the amplitude value where the measurement was stopped, press the key without making any changes. The measurement starts at the amplitude value where START the measurement was stopped.
(5) Measuring again 2
When measuring with a different amplitude value from the amplitude value where the measurement was stopped, first press the key. The amplitude value display will start to blink. Confirm the change to the amplitude value (Refer to “5-2-1. Setting amplitude value”), and then press the START key to start the measurement.

5-2-3. Measurement when using WinCT-Viscosity
It is possible to acquire viscosity or temperature data at each amplitude.
(1) How to use

Install Win CT-Viscosity (For details of the installation, refer to Readme in the CD-ROM. Win CT-Viscosity can be used with the RV-10000 in addition to the SV series. When reading contents noted in Win CT-Viscosity, replace “SV” with “RV-10000”.).
Start Viscous in Win CT-Viscosity.
Confirm the amplitude value using the RV-10000. (Refer to “5-2-1. Setting amplitude value“)
Press the Start button in Rs Viscos to start the measurement. Data acquisition starts after approx. 15 seconds.

(2) Precautions to be taken when acquiring data with changed amplitude
When acquiring data with changed amplitude, first press the Stop button in Rs Viscos to end the measurement, and then change the amplitude value with the RV-10000.

Press the Stop button in Rs Viscos to end the measurement.
Confirm the amplitude value on the RV-10000. (Refer to “5-2-1. Setting amplitude value“)
Press the Start button in Rs Viscos to start the measurement.

USING THE WATER JACKET

6-1. Introduction
The water jacket, is used with the rheometer RV-10000, to maintain the sample temperature constant or to measure the viscosity when the sample temperature is changed. The operating temperature range is 0°C to 100°C
The water jacket consists of the following:
Water jacket 1 pc (Main body: PC (Polycarbonate), Packing: Silicone rubber, Washer: Nylon)
Screw 1 pc (Screw: POM (Polyacetal), Washer: Nylon)

Note

As a heating medium, use water, isopropyl alcohol (IPA), mixture of water and IPA, or silicone oil, which does not erode the materials described above. Using the heating medium other than these may damage the water jacket.
When using the water jacket, make sure that no inner pressure is exerted in the water jacket due to the kinked or blocked tubes, as that could exert the pressure in the water jacket, causing it to break.
To control the temperature, a commercially available constant temperature bath is required separately.

6-2. Installation
Use the small sample cup (capacity: 10 mL) provided or the glass sample cup (capacity: 13 mL) provided.
To circulate the heating medium into the water jacket, a commercially available constant temperature bath is required.

Using silicone tubes with an inside diameter of 8 mm, make a connection between the “OUT” connector of the bath and the lower nozzle of the water jacket indicated as 1 in the illustration, and then, between the “IN” connector and the upper nozzle indicated as 2.
Pour the heating medium into the water jacket indicated as 3. An appropriate sample amount is approximately 11 Mr.
The heating medium conducts the heat of the water jacket to the sample cup.
Note: When the levels of the sample surface and the heating medium surface are the same and hard to distinguish the positioning of the sensor plates, change the amount of the heating medium.
Insert the small sample cup into the water jacket indicated as 3.
When the specific gravity of the sample liquid is small and the small sample cup floats, secure lightly the front side of the cup to the water jacket using the screw provided. Use the small sample cup cover for volatile samples.

If the handles of the sample cup holder or the small sample cup interfere with the measurement, they can be removed.
Apply force in the up and down directions slowly as shown in the illustration, to break the handle off.

6-3. How to Use

Attach the water jacket on the table along the guides. Make sure that the water jacket is slid furthest along the guides until stopped.
When the water jacket is used, be sure to raise or remove the protector.
Use much care so that the sensor plates and the temperature sensor do not come into contact with the inner wall of the sample. If they are in contact, a measurement error may occur.
Be sure to adjust the sample surface to the center of the narrow part of the sensor plates.

6-4. Measuring the Absolute Value of Viscosity Using the Small Sample Cup
The RV-10000 has been calibrated using the accessory sample cup (45 mL) when shipped. The distance between the inner wall and the sensor plates when the accessory sample cup is used, differs from the distance when the small sample cup (10 mL) is used. This causes a difference in the sensor plate’s detection capability, thus causing a difference in the viscosity measured.
Therefore, to measure the absolute value of viscosity using the small sample cup (10 mL), it is recommended that calibration be performed using a fluid with a known viscosity value which is close to the sample viscosity. (Refer to “7. VISCOSITY CALIBRATION” of the rheometer instruction manual.)

6-5. Maintenance
Clean the sample cup as necessary. If cleaning is not sufficient, a measurement error may occur due to contamination.

6-6. Specifications
Operating temperature: 0°C to 100°C
Circulation nozzle outside diameter: 10.5 mm
Recommended hose: Silicone tube with an inside diameter of 8 mm
When a stirrer is attached at the bottom of the water jacket, the sample viscosity can be measured while the sample is being stirred. The maximum viscosity value which can be measured is 1000 mPa×s.
Stirrer: VARIOMAG MICRO manufactured by H+P Labor Technik AG

Note

Use a rotator with a size of 6 mm (length) x 4 mm (diameter).
Attach the stirrer to the bottom of the water jacket, using an M4 screw from below.
When the rotator is used, make sure that the rotator will not touch the temperature sensor or the sensor plates. If it does, increase the sample amount so that the rotator will be farther away from the sensor plates.
Use the stirrer with a revolution speed which will not cause ripples in the sample surface.

VISCOSITY CALIBRATION

Viscosity calibration is to correct the viscosity value.
Calibration methods are one-point calibration and two-point calibration using desired standard viscosity fluids. It is also possible to carry out simplified calibration using purified water.
It is recommended that calibration be performed using a fluid with a known viscosity value which is close to the sample viscosity.
When the measuring range is great, perform two-point calibration. Two-point calibration requires two standard viscosity fluids (high viscosity and low viscosity) that are appropriate for the measuring range.
When measuring the viscosity near 1 mPa×s, simplified calibration using purified water, which is a one-key operation, is available. The RV-10000 has a built-in function to perform an automatic temperature compensation on the viscosity value, based on the temperature of the purified water used.
In one-point and two-point calibration, the viscosity of a fluid with a known value, such as a standard viscosity fluid, is measured, displayed, corrected digitally and saved in memory.
To obtain the absolute viscosity value precisely, use the correction value as described in “4-4- 2 At Calibration”.
If the wrong calibration data such as a correction value have been entered, the rheometer condition can be restored. For details, refer to “Initialization (Cllr)” of the function setting.

7-1 Notes on Viscosity Calibration

Pay close attention to the liquid temperature at calibration. Be sure to enter the temperature corrected viscosity value of the liquid at calibration. Even when using a standard viscosity fluid, temperature change near room temperature causes viscosity change (if increasing the temperature, the viscosity value decreases about 2 to 10 percent per degree Celsius). And even when using purified water, temperature change similarly causes viscosity decrease of about 2 percent per degree Celsius.
The temperature of the standard viscosity fluid must be the same as the temperature of the sensor plates and the temperature sensor. Allow the displayed temperature to stabilize before calibration.
Be sure to adjust the sample surface to the center of the narrow part of the sensor plates. Otherwise, a measurement error may occur.
In the calibration mode, the unit of viscosity is mPa×s. The unit of temperature is fixed to °C.
Influence caused by the sample cup
The rheometers have been calibrated with the following cups when shipped. When using another cup, use that cup to measure viscosity only after calibrating with it.
Note
The rheometer has been calibrated with the protector attached when shipped. Please note that the value, obtained when the rheometer is calibrated without the protector, may be different from that upon shipment.
If purified water (such as pressurized tap water) is used for simplified calibration, or the water temperature is different from the ambient temperature, bubbles may accumulate on the sensor plates and cause a measurement error. Remove any accumulated bubbles before calibration.
If the measured viscosity of the purified water is 3.00 mPa×s or greater, it is contaminated and simplified calibration can not be performed using it. Replace the water.

7-2 Calibration Procedure
Note
As to the correction value used for one-point calibration and two-point calibration, enter the product of the absolute viscosity value and the density of the standard viscosity fluid. For details, refer to “4-4-2 At Calibration”.
After calibration, check the values, comparing the product described above with the displayed value. AND RV 10000 Vibro Rheometer -
Fig39

Example 1: To calibrate the rheometer using a standard viscosity fluid:
Using the calculation sheet, calculate the value used for calibration.
(1) Check the kinetic viscosity and the viscosity at the temperature when the calibration is performed.
Here, 1011 mm2/s for the kinetic viscosity and 889 mPa×s for the viscosity at 20°C as an example.
(2) Substitute the values above to obtain the value for

781 mPa×s is obtained as a correction value used for calibration.

Example 2: To calibrate using a standard viscosity fluid with known values of viscosity and density.
In this example, a standard viscosity fluid with a viscosity of 889 mPa×s at 20°C is used.

Check the viscosity value and the density of the standard viscosity fluid at the temperature when the calibration is performed.. Here, 889 mPa×s for the viscosity and 0.878 for the density at 20°C as an example.
Substitute the values above to obtain the value for Viscosity . Density. 889 x 0.878 ≈ 781 781 mPa×s is obtained as a correction value used for calibration.

7-2-1 One-point Calibration

In the standby mode, press and hold the key to enter the calibration mode. ” ” appears.
Select one-point calibration ( ) PRINT key to confirm. and press the The standby mode of the one- calibration mode appears. Use the key to switch between the calibration modes, one-point calibration ( ) or two-point calibration ( ).

Press the calibration STOP key to exit the mode. The display returns to the standby mode. 3. Place the standard viscosity fluid in the sample cup. Press the START key to start a measurement. 4. After the measurement, wait for the display to become stable and press the PRINT key. The measurement value blinks and is ready to be corrected. 5. Correct the value using the following keys: key Switches the blinking digits. START key Changes the setting of a blinking digit. STOP key Moves the decimal point. 6. Press the PRINT key to confirm the correction value. 7. To exit the calibration mode:
With ” ” being displayed, press the PRINT key again to return to the standby mode. To correct the value:
With ” ” being displayed, press the STOP key and correct the value.
1. Measure the viscosity of the standard viscosity fluid used. Confirm that the rheometer displays the similar value as the entered correction value.

7-2-2 Two-point Calibration

In the standby mode, press and hold the key to enter the calibration mode. “ ” appears.
Select two-point calibration ( ) PRINT key to confirm. and press the The standby mode of the two- calibration mode appears. Use the (One-point calibration) key to switch between the calibration modes, one-point calibration ( ) or two-point calibration ( ).

Press the calibration STOP key to exit the mode. The display returns to the standby mode. 3. Press the PRINT key to put the display in the standby mode. In two-point calibration mode, the calibration mode ID indicator (-) appears below the temperature display. 4. Place the standard viscosity fluid in the sample cup. Press the START key to start the measurement of the first point. 5. After the measurement, wait for the display to become stable and press the PRINT key.
The measurement value blinks and is ready to be corrected.
1. Correct the value using the following keys:
  key Switches the blinking digits.
  START key Changes the setting of a blinking digit.
  STOP key Moves the decimal point.
2. Press the PRINT key to confirm the correction value.
3. To correct the value:
  In the calibration standby mode to enter the second point, press the STOP key and correct the value.
4. When the measurement of the first point has completed, clean the sensor plates, temperature sensor and protector and prepare the second standard viscosity fluid.
5. Place the second standard viscosity fluid in the sample cup. Press the START key to start the measurement of the second point.
6. After the measurement, wait for the display to become stable and press the PRINT key.
  The measurement value blinks and is ready to be corrected.
7. Correct the value using the following keys:
  key Switches the blinking digits.
  START key Changes the setting of a blinking digit.
  STOP key Moves the decimal point.
8. Press the PRINT key to confirm the correction value.
9. To exit the calibration mode:
  With ” end ” being displayed, press the PRINT key again. The calibration data is saved and the display returns to the standby mode.
  To correct the value:
  With ” end ” being displayed, press the STOP key and correct the value.
10. Measure the viscosity of the two standard viscosity fluids used. Confirm that the rheometer displays the similar value as the entered correction value for each fluid.

7-2-3 Simplified Calibration Using Purified Water

Place the purified water in the sample cup.
Press the START the purified water. key to measure Confirm that the viscosity and temperature values are stabilized.
Press and hold the START key.
The theoretical viscosity value (Viscosity x Density) of the purified water at the measuring temperature is displayed and all the displays blink.
To cancel the operation, press the key. The display returns to STOP the status before calibration.
Press the START key again to perform calibration.
When calibration is completed, ” ” is displayed. Then, the viscosity returns to the measuring status.

Reference data: Theoretical viscosity value (Viscosity x Density) of the purified water at various temperatures

Temperature (°C)	Viscosity ´ Density (mPa×s)
10.0	1.31
11.0	1.27
12.0	1.24
13.0	1.20
14.0	1.17
15.0	1.14
16.0	1.11
17.0	1.08
18.0	1.05
19.0	1.03
20.0	1.00
21.0	0.98
22.0	0.95
23.0	0.93
24.0	0.91
25.0	0.89
26.0	0.87
27.0	0.85
28.0	0.83
29.0	0.81
30.0	0.79

Note

When tap water is poured into the sample cup directly and is measured, bubbles are generated on the sensor plates due to the difference in pressure and temperature and the viscosity may increase gradually. Pressurized tap water generates bubbles easily. Therefore, use distilled or purified water that is not pressurized. Leave the sensor plates and sample in the same environment to acclimatize before measuring, to decrease temperatures fluctuations.
In a measurement that takes a long time, the sample viscosity may increase due to water contamination. Perform a periodic check on water quality.

FUNCTION SETTING

The rheometer, by selecting functions to be used in the function setting, can specify the performance appropriate to the usage.
Each function is assigned parameters. The performance of a function is specified by changing the parameter.
The parameters saved, even if the power is turned off, are maintained in non- volatile memory.

8-1 Operation
The operational procedure of the function setting is as follows:

In the standby mode, press and hold the key for at least 2 seconds to enter the function setting mode.
Press the key to select a function item.
Press the PRINT key to confirm the function item. The changeable digit blinks.
Press the START key or key to change the blinking digit.
START key Increases the value of the blinking digit. When the value reaches the upper limit of the setting range, the minimum value appears again.
key Decreases the value of the blinking digit. When the value reaches the lower limit of the setting range, the maximum value appears again.
To save the new setting, press the PRINK key. After ” end “, the next item is displayed.
To cancel the new setting, press the STOP key. The next item is displayed.
To change other settings, repeat the procedure starting at step 2.
To exit the function setting mode, press the STOP key. The rheometer returns to the standby mode.

Note
The operational procedures for setting the date and time , ID number and initialization are not the same as the procedure described above. Refer to “8-3 Description of Items”.
“Date/Time” pages 44-46
“Device ID Number” pages 42

Example of the function setting procedure
To change the setting of “Unit upon power-on to the viscosity: cpm (Centipoise) and the temperature: °C (Celsius).

In the standby mode, press and hold the key to enter the function setting mode. ” ” appears.
Press the key to select ” “.
Press the PRINT key to confirm the item.
(The decimal point illuminates when the setting currently saved is displayed.)
Press the START key or the unit to be used. key to select
(In this example, ” 2 ” is selected. Viscosity: cpm, Temperature: °C)
Press the PRINT key to save the setting. After ” “, the next item is displayed.
Press the STOP key to return to the standby mode.

8-2 Details of the Function Items

Function item	Parameter	Description
Date/Time		Sets the order of the date (YMD,MDY,DMY) and the date/time.
Condition		Follows the viscosity changes quickly. (Prone to vibration)
•		****
Follows the viscosity changes slowly.	(Stable values)

Unit upon power-on| | Viscosity| mPa×s| ****

Temper- ature

| °C|
| Pa×s
| cpm
| P
| mPa×s| °F
| Pa×s
| cpm
| P

Decimal point

| | Dot| With “Comma” selected, the separator for CSV format will be “;” (semicolon).
| Comma

ID number output| | Sets the ID number output| By setting , the ID number output can be added to measurement data
Initialization| | Restores the function settings and calibration data to the factory setting.

• Factory setting

8-3 Description of Items
Condition ( )
The stability of the viscosity measurement results can be adjusted, taking ambient conditions such as vibration into consideration.

Parameter	Settings	Description
Follows the viscosity changes quickly. (Prone to vibration)	When the

viscosity value is unstable due to external vibration, set a greater parameter.
To measure while following the rapid changes in viscosity, set a smaller parameter.
With a smaller setting, the measurement is prone to external vibration. Consider the ambient conditions of the installation site.
•| ↔
| Follows the viscosity changes slowly. (Stable values)

Unit Upon Power-on ( )
The units of viscosity and temperature displayed when the power is turned on are specified.

Parameter	Settings	Description
	Viscosity	mPa×s (Millipascal second)

*1 For the viscosity over 1000mPa.s, the unit is fixed to Pa.s. For the viscosity over 1000cP, the unit is fixed to P.
Decimal Point ( )

Parameter	Settings	Description
•	Dot “.”	The decimal point format for the displayed

measurement data and the decimal point code for measurement data output via RS-232C are specified.
With “Comma” selected, the separator for CSV format and Rs Viscos format will be “;” (semicolon).
| Comma “,”

Data Output Mode ( )
The condition to output the measurement data via RS-232C is set.

Parameter	Settings	Description
•	Key mode	During measurement or in the data hold mode, pressing the

PRINT key outputs the current measurement values.
| Auto print mode| The measurement values are output automatically when the STOP key ends the measurement. Pressing the PRINT key outputs the measurement values again.
| Stream mode| The measurement values are output continuously during measurement.
When D.P. format is selected in “Output format ( )” of the function setting, only the viscosity value is output, regardless of the settings of .
When this mode is selected, the data hold mode using the HOLD key is not available.

Data Output Format ( )
The output format appropriate for the device connected to RS-232C can be selected.

Parameter	Settings	Description
A&D standard format	Used with the printer MODE 1 or MODE 2 when the

optional compact printer AD-8121B is connected. Only the viscosity value is output.
1 ·| D.P. format| Used with the printer MODE 3 when the optional compact printer AD-8121B is connected.
With selected for “Data output mode ( )”, output contents can be selected by the settings of With” ” selected for “Data output mode ( )”, only the viscosity value is output.
2| CSV format| Appropriate when a personal computer is used to collect data. Measurement values are output in comma separated format.
With “ ” and “ ” settings, the date/time and ID number can be added to the measurement data.
When a comma is selected as the decimal point by “ “, a semicolon “;” is used as a data separator.
The viscosity value and the temperature are output using the internal resolution. 2
3| Viscous format| Used with the graphing program Viscous.
When a measurement is started using Viscous, the rheometer automatically selects this format.
The viscosity value and the temperature are output using the internal resolution.2

*2 The relation between the measuring unit and the internal resolution is as follows:

| Viscosity| Temperature
---|---|---
mPa×s| Pa･s| cP| P| °Ｃ| °Ｆ
Internal resolution| 0.01| 0.0001| 0.01| 0.0001| 0.01| 0.01
–| 0.01| –| 0.1

Measurement Elapsed Time Output ( )

Parameter	Settings	Description
No output	With D.P. format selected, whether or not to add the measurement

elapsed time (the time elapsed from a measurement start) to the measurement data can be selected.
For examples of output format, refer to “8-4 Data Output Format Examples”.

•

| Output

Date/time Output ( )

Parameter	Settings	Description
****	No output	With D.P. format or CSV format selected, whether or not to

add the date and time to the measurement data can be selected.
For examples of output format, refer to “8-4 Data Output Format Examples”.
•| Output

Other Output ( )

Parameter	Settings	Description
****	No output
Outputs remarks.	With D.P. format selected, whether or not to add remarks,

Device ID information or signature to the measurement data can be selected.
For examples of output format, refer to “8-4 Data Output Format Examples”.
•| Outputs remarks, Device ID information and signature.
| Outputs ID number.| With CSV format selected, whether or not to add ID number to the measurement data can be selected.
For examples of output format, refer to “8-4 Data Output Format Examples”.

Pause at Data Output ( )

Parameter	Settings	Description
****	No pause	Whether or not to take a pause of two seconds each time one

line is output can be selected, when the data are output via RS-232C.

When MODE 3 of the optional compact printer AD-8121B is used, select “ “.

•| Pause (Approx. 2 seconds)

Device ID Number (id)

The ID number is used to identify the rheometer.
Whether or not to add the ID number to the measurement data can be selected by “ ” of the function setting.
The ID number is six characters long. The following characters are available for the ID number.

AND RV 10000 Vibro Rheometer - fig

For examples of output format, refer to “8-4 Data Output Format Examples”.

Setting the ID number

In the standby mode, press and hold the key to enter the function setting mode. ” ” appears.
Press the key to select ” id “.
Press the PRINT key to enter the ID number setting mode.
Set the ID number using the following keys:
key Switches the blinking digits.
START key Increases the value of the blinking digit by one.
key Decreases the value of the blinking digit by one.
STOP key Cancel the operation
Press the PRINT key to save the setting. After ” “, the next item is displayed.
Press the STOP key to return to the standby mode.

Initialization ( )
Restores the following data to the default setting.

Function setting (Setting of “ ” is not returned by this operation)
Calibration data

After initialization, check the viscosity value and perform calibration as necessary. (Refer to “7. VISCOSITY CALIBRATION”).

In the standby mode, press and hold the key to enter the function setting mode. ” ” appears.
1. Press the key to select “ “.
Press the PRINT key to display ” “.
Press the START key to select ” “.
Press the PRINT key to execute initialization. After ” “, the next item is displayed. Initialization has completed.
Press the STOP key to return to the standby mode.

Date/Time ( )

The upper two digits of the year are not displayed. For example, the year 2007 is displayed as “07”.
The time is set using the 24-hour system.
Do not enter a non-existing date and time.
Set the order of the date, the date and time as follows:
(Example: To change April 5, 2003, 11:22:33 to June 8, 2004, 12:34:00)

In the standby mode, press and hold the key to enter the function setting mode. ” ” appears.
Press the PRINT key to display the current date. When the date is not to be changed, press the key to display the current time.Changing the order of the date
Press the PRINT key. ” ” (Year), ” ” (Month) and ” ” (Day) blink.
4 Press the START key or key to change the order of displaying the date.
Changing the date
The date is changed in the selected displaying order.
The following is an example when the order of ” ” (Year), ” ” (Month) and ” ” (Day) is selected.
Press the key to select the setting value of ” ” (Year). (Example:03)
Press the START key or key to change the year. (Example:03→04)
START key Increases the value of the blinking digit by one.
key Decreases the value of the blinking digit by one.
Press the key to select the setting value of “ ” (Month). (Example:04)
Press the START key or key to change the month. (Example:04→06)
Press the key to select the setting value of ” ” (Day). (Example:05)
Press the START key or key to change the day. (Example:05→08)
Press the PRINT key to save the date.
After ” “, the current time is displayed.
Changing the time
The current time is displayed. Press the key to display the current date.
Press the PRINT key to select the setting value of the hour. (Example:11)
Press the START key or key to change the hour. (Example:11→12)
Press the key to select the setting value of the minute. (Example:22)
Press the START key or key to change the minute. (Example:22→34)
Press the key to select the setting value of the second. (Example:33)
Press the START key or key to change the second. (Example:33→00)
Press the PRINT key to save the time. After ” “, the next item is displayed.
20 Press the STOP key to return to the standby mode.

8-4 Data Output Format Examples
8-4-1 A &D Standard Format
Used with the printer MODE 3 when the optional compact printer AD-8121B is connected. Only the viscosity value is output.
Output format example

Viscosity unit	Display	Output format	Remarks
mPa×s	L mPa×s	OL,-99999999mPs	Below measuring range error
0.30mPa･s	ST,+00000.30mPs
10.0 mPa×s	ST,+00010.00mPs	The digit of 0.01mPa×s is always zero.
100 mPa×s	ST,+00100.00mPs	The digits of 0.01mPa×s and 0.1mPa×s are always

8-4-2 D.P. Format
Used with the printer MODE 3 when the optional compact printer AD-8121B is connected.
With selected for “Data output mode ( ) “, output contents can be selected by the settings of .
With “ ” selected for “Data output mode ( )”, only the viscosity value is output The following shows printing examples.

Printing format example (1)

AND RV 10000 Vibro Rheometer - fig17

Printing format example (2)

AND RV 10000 Vibro Rheometer - fig18

Printing format example (3) AND RV 10000 Vibro Rheometer -
fig19

(*) The displaying order of the date (YMD/DMY/MDY) depends on the setting of “Date/Time ( )”.

Printing format example (4) AND RV 10000 Vibro Rheometer -
fig20

Printing format example (5) AND RV 10000 Vibro Rheometer -
fig21

8-4-3 CSV Format
Appropriate when a personal computer is used to collect data. Measurement values are output in comma separated format.
With “ ” setting, the date and time can be added to the measurement data.
When a comma is selected as the decimal point by “ “, a semicolon “;” is used as a data separator.
With CSV format selected, the viscosity value and the temperature are output using the internal resolution.
The relation between the measuring unit and the internal resolution is as follows:

| Viscosity| Temperature| Amplitude value
---|---|---|---
mPa×s| Pa･s| cP| P| °Ｃ| °Ｆ| mm
Internal resolution| 0.01| 0.0001| 0.01| 0.0001| 0.01| 0.01| 0.01
－| 0.01| －| 0.1

Output format example (1) With ID number, date and time added

Outputs in the order of ID number, date, time, temperature, temperature unit, viscosity and viscosity unit.
The output data are 52 characters long excluding the terminator.

Output format example

AND RV 10000 Vibro Rheometer - fig25

Output format example (2) With date and time added Outputs in the order of date, time, temperature, temperature unit, viscosity and viscosity unit. The output data are 46 characters long excluding the terminator.

Output format example

Viscosity / Temperature	Display	Output format example
mPa×s / °C	1.23 mPa×s	,2003/03/19,12:34:56,+025.67,C,+00001.23,mPa s,0.40,mm

:Space (ASC 20h)

Output format example (3) To output the measured temperature and viscosity only

Outputs in the order of temperature, temperature unit, viscosity and viscosity unit. The output data are 28 characters long excluding the terminator.

Output format example

Viscosity / Temperature	Display	Output format example
mPa×s / °C	1.23 mPa×s	,,,+025.67,C,+00001.23,mPa s,0.40,mm

:Space (ASC 20h)

8-4-4 Viscous Format
Used with the graphing program Viscous. Measurement data are output in comma separated format.
When a comma is selected as the decimal point by “ “, a semicolon “;” is used as a data separator.
When a measurement is started using Viscous, the rheometer automatically selects this format.
Measurement data are output in the order of viscosity, viscosity unit, temperature and temperature unit.
The output data are 25 characters long excluding the terminator
With Viscous format selected, the viscosity value and the temperature are output using the internal resolution.
The relation between the measuring unit and the internal resolution is as follows:

| Viscosity| Temperature| Amplitude value
---|---|---|---
mPa×s| Pa･s| mm| P| °Ｃ| °Ｆ| mm
Internal resolution| 0.01| 0.0001| 0.01| 0.0001| 0.01| 0.01| 0.01
－| 0.01| －| 0.1

Output format example

AND RV 10000 Vibro Rheometer - fig26

CONNECTION TO A PERSONAL COMPUTER

9-1 Introduction
If connecting the RV-10000 to a personal computer using the Windows communication tools Win CT- Viscosity (CD-ROM), the measurement data can be imported into the personal computer.
The graphing program Viscous that is contained in the Windows communication tools Win CT- Viscosity has following features.
– This program can display a graph of the sample viscosity changing in real time. At this time, the sample temperature is imported into the personal computer. Therefore you can easily understand the sample characteristic by displaying a graph of the relation between the temperature and viscosity.
– When measuring at any time, you can compare the sample characteristic by displaying a graph on a graph.
– The measurement data can be saved with the CSV file in the personal computer. The input data can be displayed as a graph again.
– The graph data can be printed with a printer that is connected to the personal computer.

For an example of a measurement, refer to the sample measurement collection. For details of how to use the examples, refer to “Readme” that is installed in the personal computer after the CD-ROM set up.

9-2 Installation of Win CT-Viscosity
Refer to “\English\ReadMe.txt” on the CD-ROM, to install Win CT-Viscosity in a personal computer.
9-3 Connection to a personal computer
In a case where the personal computer has a COM port
The RV-10000 can connect to a personal computer using the RS-232C cable.

AND RV 10000 Vibro Rheometer - Fig

In a case where the personal computer does not have a COM port (Example: notebook type etc)
By using the standard Serial-USB converter provided, a personal computer can increase the number of COM ports available. Therefore, the RV-10000 can connect to a personal computer using the RS- 232C cable.
Setting up

Connect the Serial-USB converter to the personal computer. Install the driver of the Serial-USB converter in the personal computer (Refer to the instruction manual of the Serial-USB converter.).
Connect the Serial-USB converter to the RV-10000 by using the RS-232C cable.

AND RV 10000 Vibro Rheometer - Fig1

9-4 Configuration of the COM port
When connecting the RV-10000 to a personal computer, confirm that the COM port setting match up.

(1) Configuring of the COM port

Click the START bottom → the“Setting” → the“Control panel”.
Double-click the“System” .
Click the“Hardware” Tab, and click the“Device Manager” .
Double-click the“Port (COM and LPT)” ,confirm the number of the COM port.
When using the USB converter, “ATEN USB to Serial Bridge (CM4)” is displayed.
With this example, the COM port is displayed set to “4”. The COM port of the personal computer is displayed as “Communications Port (COM1)”.

With this example, The COM port of the personal computer is two. Therefore, the COM port number that is connected to the personal computer directly is displayed as “1” and “2”. When a personal computer has many COM ports, all of the COM ports are displayed sequentially (Example: Communications Port (COM1), Communications Port (COM2)…) Confirm the COM port number by the connecting position of the COM port.

( 2) Setting of the COM port (Example: graphing software“RsVisco”)
1 Click the START bottom → the“Program” → the“A&D Win CT-Viscosity” → the “Viscous”. AND RV 10000 Vibro Rheometer - Fig3

5 With “RS-232C (R)” of menu → the“COM Port (C)”, set the COM port described above “ (1) Configuring of the COM port”

9-5 Controlling the measurement using a personal computer
(In case of the graphing software“RsVisco”)

Refer to “5. MEASUREMENT”, prepare the measurement.
Start the graphing software“RsVisco”.
Confirm that the COM port of the“RsVisco” is set properly.
Click the START button of the“RsVisco” to start the measurement.
If you want to finish the measurement, click the START button of the“RsVisco”.

For details on how to use the software, refer to the file “Readme” that is installed in a personal computer after the CD-ROM set up.

CONNECTION TO A PRINTER

The rheometer can be connected to the optional compact printer AD-8121B using the standard RS-232C interface and the measurement results can be printed.
The statistical calculation data of the results and the changes in the viscosity value per a certain time can be printed using the function of the AD-8121B.
Use the AD-8121B accessory cable to connect the printer to the rheometer.

Setting List

AND RV 10000 Vibro Rheometer - fig28 • Factory setting

Note
AD-8121B settings

Mode	AD-8121B DIP switches	Description
Mode 1		Prints upon data receipt Standard mode, statistical calculation mode
Mode 2		Prints using the AD-8121B DATA key or the AD-8121B built-in timer

Standard mode, interval mode, chart mode
Mode 3| | Prints upon data receipt Dump print mode

DIP switch 3: Handling unstable data
ON = To print unstable data OFF = Not to print unstable data
DIP switch 4: Data input specification
ON = Use the current loop OFF = Use the RS-232C

RS-232C SERIAL INTERFACE

RS-232C Serial Interface

Transmission system	EIA RS-232C
Transmission form	Asynchronous, bi-directional, half duplex
Data format	Baud rate 2400 bps
Data bits	7 bits
Parity	EVEN
Stop bit	1 bit
Code	ASCII
Terminator	CR LF (CR: 0Dh, LF: 0Ah)

AND RV 10000 Vibro Rheometer - Fig 9 Pin Connections

|

RV-10000 (DCE)

|

Computer (DTE)

---|---|---
Pin No.| Signal Name 1| Description| Direction| Signal Name
1| FG| Frame ground| –| FG
2| RXD| Receive data| ←| TXD
3| TXD| Transmit data| →| RXD
4| RTS| Ready to send    2| ←| RTS
5| CTS| Clear to send     2| →| CTS
6| DSR| Data set ready| →| DSR
7| SG| Signal ground| –| SG
16, 18, 19, 21, 23| Internal use| Do not connect   3
Others| Not used|

1: Signal names of the rheometer side are the same as the DTE side with TXD and RXD reversed.
2: RTS and CTS flow control are not used. CTS output is HI always.
*3: Normal DOS/V cables do not use these terminals.

COMMAND LIST

The rheometer can be controlled by the following commands from the computer. Add a terminator ( 0Dh、0Ah ) to each command.

Command	Description
Q	Outputs the current data. (This is effective whether not measurement being

TROUBLESHOOTING

The rheometer is a precision instrument. When the operating environment or the operating method is inadequate, correct values can not be obtained. If measurement values do not become stable or they seem to be incorrect, check as described below. If improper performance persists after checking, contact the local A&D dealer for repair.

13-1 When measurement values do not become stable
Is the ambient environment free from vibration and drafts?

Places such as second or higher floor or near busy highways or rail lines are prone to vibration.
Avoid these places or use an anti-vibration table, AD-1671A.
Reconsider the setting of “Condition ( ) ” of the function setting.
Set it to “ “.
Avoid direct drafts in the vicinity of the rheometer.

Is there a strong electrical or magnetic noise source such as a motor near the rheometer?

Install the rheometer away from the electrical or magnetic noise sources

Is the protector or the sensor protective cover in contact with the sensor plates or the temperature sensor?

Attach the protector and the sensor protective cover properly so that they do not touch the sensor plates or the temperature sensor.
Remove the protector, the surface locator plate or the sensor protective cover when necessary.

(1) How to remove the protector AND RV 10000 Vibro Rheometer -
Fig12

Press the left and right side frames lightly in the direction indicated as 1 to remove the rotational axis. Pull the protector in the direction indicated as 2 to remove.

(2) How to remove and attach the surface locator plate

Removing
Loosen the screw and remove the surface locator plate from the temperature sensor.

Attaching
Install the surface locator plate as shown in the illustration. Slip the locator plate onto the temperature sensor. Move the plate to the top of the sensor. Adjust the position of the locator plate so that the tip of the locator plate aligns to the center of the narrow part of the sensor plates. Tighten the screw.
Note
When the sensor plate and the surface locator plate are too close, a measurement error may occur due to the liquid surface tension. Therefore, secure a clearance of at least 1 mm between the sensor plate and the surface locator plate. Maintain the clearance by rotating the surface locator plate when necessary.
**(3) How to remove the sensor protective cover![AND RV 10000 Vibro Rheometer

Fig14](https://manuals.plus/wp-content/uploads/2023/04/AND-RV-10000-Vibro- Rheometer-Fig14-2.png)**

Remove the protector and the surface locator plate.
Pull the sensor protective cover in the direction indicated as 1 to release the portions A (two) and B from Sensor protective cover 1 the protector frame.
Pull the sensor protective cover in the direction indicated as 2 to remove.
Note
When removing the sensor protective cover, it may touch the sensor plates and the temperature sensor. Use much care not to damage them.

13-2 When measurement values are not correct
Has the sample surface been adjusted to the center of the narrow part of the sensor plates?
• Adjust the table height by turning the knob so that the center of the narrow part of the sensor plates is on the sample surface.
Are the positions of the left and right sensor plates in the sample surface the same?
• If not the same, level the rheometer using the leveling feet so that the liquid surface will be leveled.
Are the sensor plates clean?
• Remove any residual sample material from the sensor plates using alcohol.
• When any residual sample material is on the portion of the sensor plates above the sample surface, changes in the mass cause the vibration frequency to shift, which will result in a measurement error.
Are the sensor plates bent?
• If bent, contact the local A&D dealer for repair.
Is the protector properly attached to the rheometer.
Does the sample generate bubbles because of the differences in the sample temperature and the ambient temperature and do the bubbles stick to the sensor plates?
The sample viscosity depends on the temperature.
• In general, because the viscosity of a liquid depends on its temperature, the viscosity value decreases about 2 to 10 percent per degree Celsius if increasing the temperature.
Is the sample surface lowered?
• In a measurement that takes a long time, evaporation may cause the sample surface to be lowered. Maintain the sample surface level.
Do the main unit and the display unit have the same serial number?
• The main unit and the display unit have been adjusted in pairs. Confirm that the main unit and the display unit have the same serial number.
Is calibration performed?
• When the absolute viscosity value is important, it is recommend that a periodic calibration be performed using a standard viscosity fluid.
Sample cup influence
The rheometer have been calibrated with the following cups when shipped. When using another cup, use that cup to measure viscosity only after calibrating with it. Sample cup (Capacity: 45 mL)

Note
The rheometer has been calibrated with the protector attached when shipped. Please note that the value, obtained when the rheometer is calibrated without the protector, may be different from that upon shipment.

13-3 When more precise measurement is required:
When the rheometer is installed for the first time or is moved to another location, plug in the AC adapter and warm up the rheometer for one hour or more, to acclimatize the rheometer to the measuring environment.
And before measurement, calibrate the rheometer using the sample cup that will be used for measurement.
Placing the sensor plates and the temperature sensor in the sample may change the sample temperature. For precise measurement, leave the sample as is for a while, after placing the sensor plates and the temperature sensor, to ensure no changes to the sample temperature.
And then, start a measurement.
When the sensor plates and the temperature sensor are cleaned using alcohol, the plates and the sensor are cooled temporarily and their temperature is lowered. Allow the plates and the sensor to acclimatize to the measuring environment before measurement.

13-4 When the temperature values are not correct
Is the display unit connected to the main unit properly using the connection cable?
Make a connection between the display unit and the main unit. Refer to page 13.
13-5 When water viscosity is to be measured
When tap water is poured into the sample cup directly and is measured, bubbles are generated on the sensor plates due to the difference in pressure and temperature and the viscosity may increase gradually. Pressurized tap water generates bubbles easily. Therefore, use distilled or purified water that is not pressurized.
Leave the sensor plates and sample in the same environment to acclimatize before measuring, to decrease temperatures fluctuations.
In a measurement that takes a long time, the sample viscosity may increase due to water contamination. Perform a periodic check on water quality.

ERROR DISPLAY

Error display	Description
****	Above measuring range error

The viscosity value exceeds the upper limit of the viscosity measuring range.
The viscosity of the sample can not be measured.
This error may occur when the display unit is not connected to the main unit.
| Below measuring range error
The viscosity value is below the lower limit of the viscosity measuring range.
The viscosity of the sample can not be measured.
This error may occur when the display unit is not connected to the main unit.
| The power supply for the internal clock is depleted.
Press any key to enter the clock correction mode. Setting the clock enables the rheometer to be used temporarily.
If the error occurs frequently, contact the local A&D dealer for repair.
| Internal IC error
Turn the power off. Then, turn the power on again. If this does not release the error, contact the local A&D dealer for repair.

SPECIFICATIONS

Measurement method| Sine-wave Vibrio Rheometer using the Tuning-fork Vibration method Vibration frequency 30 Hz
---|---
Amplitude range| 0.07 to 1.2mm (At the tip of the sensor plate)

Viscosity measuring range

Minimum display

| Range (mPa×s)| Minimum display (mPa×s)| Minimum display (Pa･s)
0.3～10| 0.01| 0.0001
10～100| 0.1| 0.0001
100～1000| 1| 0.001
1000～25000| 104| 0.01
Unit (Viscosity)| mPa×s, Pa×s, cP, P
Operating temperature| 10 to 40°C (50 to 104°F)
Minimum sample amount| 10 mL or more
Temperature display| 0 to 99°C/0.1°C, (32 to 210.2°F/0.1°F) 5 100 to 160°C/1°C, (212 to 320°F/1°F)

Temperature measurement accuracy

| 0 to 20°C/32 to 68°F: ±1°C/±1.8°F
20 to 30°C/68 to 86°F: ±0.5°C/±0.9°F
30 to 100°C/86 to 212°F: ±2°C/±3.6°F
100 to 160°C/212 to 320°F: ±4°C/±7.2°F
Display| Vacuum fluorescent display (VFD)
Connection cable length| 1.5 m (between the main unit and the display unit)
Communication| RS-232C standard
Power supply| AC adapter (Confirm that the adapter type is correct for the local voltage and power receptacle type.)
Power consumption| Approx. 14 VA (Including the AC adapter)

External dimensions/mass

| Sensor unit: 112 (W) x 132 (D) x 291 (H) mm/Approx. 0.8 kg
Display unit: 238 (W) x 132 (D) x 170 (H) mm/Approx. 1.3 kg
Stand unit: 296 (W) x 314 (D) x 536 (H) mm/Approx. 4.6 kg

Standard accessories

| AC adapter (1 pc), Connection cable (1 pc), Sample cup (Capacity: 45mL, 5 pcs), Small sample cup (Capacity: 10 mL, 5 pcs), Small sample cup cover (5 pcs), Glass sample cup (Capacity: 13 mL, 2 pcs), Glass sample cup holder (1 pc), Water jacket (1 pc), Windows communication tools Win CT-Viscosity (1 pc), RS-232C cable (1 pc), Serial-USB converter (1 pc), Stand for securing the sensor unit (1 pc), X-Y-Z stage (1 pc)

1 When the sample cup (45mL) is used
2 Repetitive measurement with the sensor plates remaining in the sample
3 The value after calibration using a standard viscosity fluid at a temperature range between 20°C and 30°C with no condensation.
In a measurement that takes a long time, perform calibration using a standard viscosity fluid or purified water periodically, as necessary.
4 The unit switches to Pa⋅s.
*5 The operating temperature of each standard and optional accessory is as follow

Name	Temperature used

Sample cup-capacity 45 mL (AX-SV-33), Small sample cup-capacity 10 mL / Small sample cup cover (AX-SV-34), Sample cup-capacity 2 mL (AX-SV-58), Sample cup holder-For capacity 2 mL (AX-SV-56-1/2)| 0 to 120°C
Glass sample cup-capacity 13 mL (AX-SV-35), Glass sample cup-capacity 2 mL (AX-SV-59)| 0 to 230°C
Water jacket (AX-SV-37)| 0 to 100°C
Glass Storage Container (AX-SV-38)| 0 to 180°C
Plastic Storage Container (AX-SV-39)*| 0 to 80°C

Lid: 80°C max
Take the operating temperature shown above into considerations when using the above items.

OPTIONAL ACCESSORIES

List of Optional Accessories (sold separately)

Model	Name
AX-SV-31-2.5	Standard viscosity fluid (JS2.5)

Capacity: 500 mL, with certification according to JIS Z8809

AX-SV-31-5| Standard viscosity fluid (JS5)
AX-SV-31-10| Standard viscosity fluid (JS10)
AX-SV-31-20| Standard viscosity fluid (JS20)
AX-SV-31-50| Standard viscosity fluid (JS50)
AX-SV-31-100| Standard viscosity fluid (JS100)
AX-SV-31-200| Standard viscosity fluid (JS200)
AX-SV-31-500| Standard viscosity fluid (JS500)
AX-SV-31-1000| Standard viscosity fluid (JS1000)
AX-SV-31-2000| Standard viscosity fluid (JS2000)
AX-SV-31-14000| Standard viscosity fluid (JS14000)
AX-SV-31-160000| Standard viscosity fluid (JS160000)
AX-SV-33| Sample cup (Capacity: 45 mL)    10 pcs
AX-SV-34| Small sample cup (Capacity: 10 mL)    10 pcs
AX-SV-35| Glass sample cup (Capacity: Approx.13 mL)    1 pc
AX-SV-36| Positioning Stopper   1 pc
AX-SV-37| Water jacket    1 pc
AX-SV-38| Glass storage container (Capacity: Approx.50 mL)   10 pcs
AX-SV-39| Plastic storage container (Capacity: Approx.120 mL)   20 pcs
AX-SV-42| Analog output
AX-SV-43| Extension cable (5 m)
To extend the distance between the main unit and the display unit.
AX-SV-51| Stand set
Stand for securing the sensor unit   1 pc X-Y-Z stage   1 pc
Sample cup (Capacity: 2 mL, Lid attached)    1 pc Sample cup holder (For 2 mL capacity)    1 pc
Sample cup (Capacity: 45 mL)    1 pc
AX-SV-52| X-Y-Z stage1 pc
AX-SV-53-EX| Software set (Serial-USB converter included) Win CT-Viscosity   1 pc
RS232C striate cable    1 pc
Serial-USB converter   1 pc
AX-SV-54| Cup set（Capacity: 10 mL・13 mL・45 mL） (Water jacket attached) Sample cup (Capacity: 45 mL)    5 pcs
Small sample cup (Capacity: 10 mL)    5 pcs Small sample cup cover   5 pcs
Glass sample cup (Capacity: Approx.13 mL)   2 pcs Glass sample cup holder   1 pc
Water jacket 1 pc
AD-8121B| Compact printer
AD-1682| Rechargeable battery

AX-SV-33 Sample Cup
• The AX-SV-33 consists of :
Sample cup (Capacity: 45 mL) 10 pcs
(Polycarbonate, Operating temperature: 120°C max.)

AX-SV-34 Small Sample Cup (10mL)
• Used when a small amount of sample will be measured.
– The AX-SV-34 consists of : Small sample cup (10 mL) 10 pcs
Small sample cup cover 10 pcs
Sample cup 1 pc
(All: Polycarbonate, Operating temperature: 120°C max.)

AX-SV-35 Glass Sample Cup (Approx. 13 mL)
• Used when organic solvents will be measured.
– The AX-SV-37 consists of : Glass sample cup (Capacity: Approx.13 mL) 1 pc
(Pyrex® glass, Operating temperature: 230°C max.)
Glass sample cup holder (Stainless steel) 1 pc
Sample cup 1 pc
(Polycarbonate, Operating temperature: 120°C max.)

AX-SV-36 Positioning Stopper

Used to fix the position of the sensor unit and the sensor plates so that positioning the sensor plates and the sample surface is not required each time a measurement is performed in a repetitive test. See below for how to attach the positioning stopper.

How to attach the positioning stopper:

Raise the lever so that the sensor unit can be moved.
While pinching the grips, lift out the sensor unit from above.
While pinching the grips on the positioning stopper, attach the stopper, with the lever on the left side as seen from front, on the supporting post. Be sure to place the guide located on the inner wall of the stopper in the guide channels located on the supporting post.
Position the stopper at an appropriate height. Raise the lever to secure the stopper.
While pinching the grips, attach the sensor unit on the supporting post.
Lower the sensor unit until it comes into contact with the stopper.
Lower the lever to secure the sensor unit.

AX-SV-37 Water Jacket Assembly

Used, in combination with a commercially available constant temperature bath for heating medium circulation, to maintain the sample temperature constant or to measure the viscosity while changing the sample temperature.
The glass sample cup sold separately can also be used.
The AX-SV-37 consists of :
Water jacket 1 pc
(Main body: Polycarbonate, Packing: Silicone rubber, Washer: Nylon)
Small sample cup 4 pcs
(Polycarbonate, Operating temperature: 120°C max.)
Small sample cup cover 4 pcs
(Polycarbonate, Operating temperature: 120°C max.)
Screw 1 pc
(Screw: Polyacetal, Washer: Nylon)
Specifications Circulation nozzle: Outside diameter 10.5 mm
Recommended hose: Silicone tube, inside diameter 8 mm
It is recommended that, for safety, a commercially available tubing clamp (clamping size: 11 to 20 mm) be used to fasten the tube securely to the nozzle.
When using the water jacket, make sure that no inner pressure is exerted in the water jacket due to the kinked or blocked tubes, as that could exert the pressure in the water jacket, causing it to break.
When a stirrer is attached at the bottom of the water jacket, the sample viscosity can be measured while the sample is being stirred. The maximum viscosity value which can be measured is 1000 mPa×s.
Stirrer: VARIOMAG MICRO manufactured by H+P Labor Technik AG Use a rotator with a size of 6 mm (length) x 4 mm (diameter).

AX-SV-38 Glass Storage Container

Used to store sample fluids.
The viscosity of the sample stored in the container can be measured as it is.
– The AX-SV-38 consists of : Glass storage container (Capacity: Approx.50 mL) 10 pcs (Borosilicate glass, Operating temperature: 180°C max.)
Lid 10 pcs
(Polyethylene, Operating temperature: 80°C max.)

AX-SV-39 Plastic Storage Container

Used to store sample fluids.
The viscosity of the sample stored in the container can be measured as it is.
– The AX-SV-39 consists of : Plastic storage container (Capacity: Approx.120 mL) 20 pcs (Polypropylene, Operating temperature: 80°C max.)
Lid 20 pcs
(Polyethylene, Operating temperature: 80°C max.)

AX-SV-51 Stand Set

Used for securing the sensor unit while measuring the viscosity of a sample.
– Consists of :
Stand for securing the sensor unit 1 pc
X-Y-Z stage 1 pc
Used when a small amount of sample (2 mL) will be measured. (Only for SV-1A/SV-1H)
– Consists of :
Sample cup (Capacity: 2 mL) 1 pc
Sample cup holder 1 pc
Sample cup (Capacity: 45 mL) 1 pc
(Polycarbonate, Operating temperature: 120°C max.)
Lid 1 pc
(Polypropylene, Operating temperature: 80°C max.)

AX-SV-52 X-Y-Z Stage
• Used to support and adjust the sample cup position.
– Consists of :
X-Y-Z stage 1 pc

AX-SV-53-EX Software Set
• Used while acquiring the viscosity data with a personal computer.
– Consists of :
Win CT-Viscosity 1 pc
RS-232C straight cable 1 pc
Serial-USB converter 1 pc
AX-SV-54 Cup Set (10 mL / 13 mL / 45 mL)
(Use the AX-SV-51 Stand Set if necessary.)
• Used when a small amount of sample will be measured.
– Consists of : Sample cup (45 mL) 5 pcs
Small sample cup (10 mL) 5 pcs
Small sample cup cover 5 pcs
(All: Polycarbonate, Operating temperature: 120°C max.) Used when organic solvents will be measured.
Glass sample cup (Capacity: Approx.13 mL) 2 pcs
(Pyrex® glass, Operating temperature: 230°C max.)
Glass sample cup holder (Stainless steel) 1 pc

• Water Jacket
Used, in combination with a commercially available constant temperature bath for heating medium circulation, to maintain the sample temperature constant or to measure the viscosity while changing the sample temperature.
– Consists of : Water jacket 1 pc
(Main body: Polycarbonate, Packing: Silicone rubber, Washer: Nylon)

AD-1671A Anti-vibration table