Benefits of Using Micro Conductivity Probes in Scientific Research

Micro conductivity probes are a valuable tool in scientific research, offering a range of benefits that can enhance the accuracy and efficiency of experiments. These probes are designed to measure the electrical conductivity of a solution at a very small scale, providing researchers with detailed information about the properties of the sample being studied. In this article, we will explore some of the key advantages of using micro conductivity probes in scientific research.

Model pH/ORP-810 pH/orp meter
Range 0-14 pH; -2000 – +2000mV
Accuracy ±0.1pH; ±2mV
Temp. Comp. Automatic temperature compensation
Oper. Temp. Normal 0~50℃; High temp 0~100℃
Sensor pH double/triple sensor; ORP sensor
Display LCD Screen
Communication 4-20mA output/RS485
Output High/Low limit dual relay control
Power AC 220V±10% 50/60Hz or AC 110V±10% 50/60Hz or DC24V/0.5A
Working Environment Ambient temperature:0~50℃
Relative humidity≤85%
Dimensions 96×96×100mm(H×W×L)
Hole Size 92×92mm(H×W)
Installation Mode Embedded

One of the primary benefits of micro conductivity probes is their ability to provide precise and reliable measurements. By using a probe that is specifically designed for small-scale measurements, researchers can obtain accurate data that is not influenced by external factors. This level of precision is essential in many scientific disciplines, where even small variations in conductivity can have a significant impact on the results of an experiment.

In addition to their accuracy, micro conductivity probes are also highly versatile. These probes can be used in a wide range of applications, from analyzing the conductivity of biological samples to measuring the salinity of seawater. This versatility makes micro conductivity probes a valuable tool for researchers working in diverse fields, allowing them to gather valuable data that can inform their research.

Another key advantage of micro conductivity probes is their ease of use. These probes are typically compact and easy to handle, making them ideal for use in laboratory settings where space may be limited. Additionally, many micro conductivity probes are designed to be compatible with a variety of instruments and software, allowing researchers to seamlessly integrate them into their existing workflows.

ROS-2210 Double-Stage Reverse Osmosis Program Controller
  1.water source water tank without water protection
  2. Pure tank low level
  3.Pure tank high level
Acquisition signal 4.low pressure protection
  5.high pressure protection
  6.pretreatment regeneration
  7.manual/automatic control
  1.water inlet valve
  2. flush valve
Output control 3. low pressure pump
  4.high pressure pump
  5.conductivity over standard valve
Measuring range 0~2000uS
Temperature range Based on 25℃, automatic temperature compensation
  AC220v±10% 50/60Hz
Power supply AC110v±10% 50/60Hz
Medium temperature The normal temperature electrode<60℃
  High temperature electrode<120℃
Control output 5A/250V AC
Relative humidity ≤85%
Ambient temperature 0~50℃
Hole Size 92*92mm(high*wide)
Installation method The embedded
Cell constant 1.0cm-¹*2
Display usage Digital display: conductivity value/temperature value; Supporting RO process flow chart
  1.Electrode constant and type setting
  2.Conductivity overrun setting
  3.Flush Settings at intervals of * hours
Main function 4.Flushing time setting
  5.RO membrane running time setting
  6.Power on automatic operation/stop setting
  7.Mailing address, baud rate setting
  8.Optional RS-485 communication interface

Furthermore, micro conductivity probes are often more cost-effective than traditional conductivity meters. Because these probes are designed for small-scale measurements, they require less material and are generally less expensive to manufacture. This cost savings can be particularly beneficial for researchers working on tight budgets, allowing them to invest in high-quality equipment without breaking the bank.

One of the most significant advantages of using micro conductivity probes in scientific research is their ability to provide real-time data. Unlike traditional conductivity meters, which may require samples to be collected and analyzed separately, micro conductivity probes can provide instant feedback on the conductivity of a solution. This real-time data can help researchers make informed decisions about their experiments and adjust their methods as needed.

Overall, micro conductivity probes offer a range of benefits that can enhance the accuracy, efficiency, and versatility of scientific research. By providing precise measurements, being easy to use, cost-effective, and offering real-time data, these probes are an invaluable tool for researchers working in a variety of fields. Whether studying biological samples, analyzing environmental samples, or conducting experiments in a laboratory setting, micro conductivity probes can help researchers gather the data they need to advance their research and make new discoveries.


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