Help and FAQ

Viscometer (SV-A/SV Series)

General

The SV Series vibrates its two sensor plates like a tuning fork while keeping a constant frequency and amplitude, and measures the driving electric current that is varied to keep the constant vibration according to viscosity change during measurement. The SV Series displays viscosity converted from the measured driving electric current.

No. The sensor plates vibrate at 30Hz.

At just about 0.4mm. Thus, it causes less damage to the structure of sample.

The target level of immersion is the most narrowed place just above the round part of each sensor plate. Adjust this level to the level of the fluid surface.

Although it depends on viscosity of each sample fluid, if the level changes by 1mm with SV-10 in low viscosity range, measurement error of approx. 2-3%, and with SV-100 in high viscosity range, approx. 10-15%, could be produced.

Just about 35ml for the standard Sample Cup is enough to perform measurement.

We offer you an accessory for smaller sample measurement, the Small Sample Cup (AX-SV-34), enabling measurement of only 10ml sample.

We offer you the Glass Sample Cup (AX-SV-35) for small sample measurement, another accessory enabling viscosity measurement of approx. 13ml. If a sample amount need not be small, a commercial glass beaker can be also used without problems.

Temperature is one of the most influential factors on viscosity. In general when temperature is low viscosity becomes high, and temperature is high viscosity becomes low.

No, it is not. This frequency is unchangeably fixed at 30Hz. 30Hz is the most sensitive resonance point that is obtainable within the measurable range of viscosity. In the production line the vibration frequency is adjusted within +/-0.02Hz to enhance the measurement accuracy.

It is impossible under the system of the SV Series. However, in measurement of Newtonian fluid the results are not affected by setting of (in relation to the rotational viscometer) what is called shear rate, or rotating speed of spindle, rpm. For measurement of Non-Newtonian fluid, it necessitates a predetermination of either shear rate or shear stress, which are not in proportion.

In case of the standard fluid, which is a Newtonian fluid, conformity in the results is observed. In measurement of Non-Newtonian fluid, the viscosity value measured at low rotational speed with the rotational viscometer, since a rotational speed of spindle, rpm, is determined for setting shear rate, may be approx. 10 times as high as that with the SV Series.

The difference in results is merely due to the difference of their measurement systems, thus both results are correct in their own ways. For example, if you change shear rate, as measurement condition of rotational viscometer, by increasing the rotational speed, rpm, the measured viscosity changes. This shows that measurement results depend on measurement conditions and that those results are both valid.

Viscosity change of a Non-Newtonian fluid appears as its physical structure is changed or damaged when stirred, beaten or pressed with stress. In measurement with the SV Series, viscosity usually decreases in the beginning as the vibration starts breaking the fluid structure around the sensor plates, but then stabilizes after a period time. In case of the rotational viscometer it causes greater damage to fluid structure and takes longer to stabilize the result in measurement than the SV Series does.

The SV Series displays viscosity just about 15 seconds after pressing the Start key, and continues displaying real-time measurement values from then on.

Temperature

Yes. The SV series comes equipped with a temperature sensor placed between the two sensor plates, which enables constant accurate temperature measurement.

Standard measurement ranges from 0 °C to 160 °C.

Use the Water Jacket (AX-SV-37) to connect the temperature-controllable Water Bath. Or you can use a heater to heat the sample during measurement. It is possible to monitor changes in viscosity with temperature changes if you refrigerate the sample before measurement and then heat it with a heater or just leave it at room temperature during measurement.

We guarantee the temperature measurement down to 0 °C. SV Series displays temperature even down to 20 to 30 °C below freezing, but we cannot guarantee the accuracy of +/-1 °C or higher.

Yes. Select the temperature unit °C or °F from the function setting. You can choose a combination with the viscosity unit of your choice.

Sensor plate

It is made of gold-plated stainless steel SUS304.

Because it protects the sensor plate from highly acidic fluids during measurements.

It depends on the use conditions and frequency of use. The sensor plates are basically not expendable parts and can be used semi-permanently.

The thickness of the sensor plate is approx. 0.3mm. It is much stronger than it looks. Although it may yield when pressed or hit with great impact, you can recover it by straightening it and use it without harming measurement accuracy.

The sensor plate is replaceable. After replacement, please perform calibration. Please note that simply replacing the sensor plates for SV-10 with the sensor plates for SV-100 cannot make model change since their shapes are different.

Calibration

You do not have to regularly perform calibration since usually the calibration values will not shift and produce errors as a result. We recommend that you follow your company protocol if it mandates regular calibration.

The SV Series has user-friendly calibration function. Just prepare the standard fluids. You can choose from one-point calibration or two-point calibration.

You can re-input correct calibration values by performing another calibration. It is also possible to recall the factory calibration values (SV-10 at 1mPas and 1000mPas / SV-100 at 1000mPas and 10000mPas) that are stored in the nonvolatile memory easily by using the “CLr” function.

Pipette Accuracy Testers

A balance outputs a mass (mg) while a pipette is managed by volume (µL). Since the pipette accuracy tester converts mass to volume, it can check the volume required for the pipette. Furthermore, it can accurately measure without concern for evaporation because of its evaporation trap. Finally, it can confirm that the specified volume and the output volume match (accuracy and repeatability).

Humidity: This entry is a record of the measurement environment. In cases where an evaporation trap is not used, it is important to record the humidity because the evaporation volume rises as the surrounding humidity decreases. However, if an evaporation trap is used, the evaporation volume is minimized and measurement can be performed without worrying about the surrounding humidity. Since entering the humidity does not affect the conversion of mass to volume, the humidity value does not have to be entered.
Atmospheric pressure: The range of atmospheric pressure change in a single location is generally ±15 hPa. Therefore, even though an average (fixed value) is used, the pressure fluctuation can be locked in easily between ±30 hPa. The effect of pressure changes on volume conversion in this case is ±0.003%. Consequently, it is acceptable to enter a representative value for the atmospheric pressure of the location.

A volume of 2 µL is about 2 mg and the balance requires a resolution of 1 µg (0.001 mg). The AD4212B-PT can display mass at a resolution of 0.001 mg up to 5 g so 2 µL pipettes can be inspected. One µg is about 1,000,000th of a one yen coin (about 2,500,000th of an American penny). As you can imagine, measuring at 1 µg is not a simple task and the measuring environment is extremely important. When setting up the tester, ensure that the following conditions are met.

  • Avoid measuring on a weak foundation, on the second floor or higher, in the center of a floor away from the support pillars, in earthquake-proof structures, near tall structures, along heavily traveled roadways, etc.
  • Place the balance on a stand.
  • Prevent direct contact with air blown from air conditioners, etc.
  • Perform tests in a temperature and humidity controlled room.

If these conditions are met and measurement values are still not stable, it is necessary to take further countermeasures, such as decreasing the precision level of the values displayed by the balance. (For example, by pressing SAMPLE to select a resolution of 0.01 mg.)

Leak Tester

Since the leak tester was developed as a pipette inspection tool, the pressure display is output for reference.*1  Since leaks are detected by changes in pressure, the absolute accuracy of the pressure is not important for judgment. If a pressure inspection record or traceability diagram is required, one can be published for a fee.
*1 Decompression: -20 kPa±20% (mentioned in the product specifications) is guaranteed as accurate.

The values have been determined from past results of pipette leak testing. Specifically, it has been determined that the pressure and detection conditions are sufficient to detect leakage and do not damage pipettes from 2 to 10,000 µL.
If a test is failed very close to the limit of the leak detection conditions, the pipette might have a minute leak or temperature changes after adiabatic expansion of the equipment may have caused a pressure change. In such cases, use a pipette accuracy tester to check if the output volume is correct and then judge whether the pipette is acceptable or not.