Nanjing Juge Environmental Technology Co., Ltd.
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Digital RS485 4-20mA Digital pH Sensor for Organic Solvents and Non-aqueous Phase Environmental Monitoring
>>Overview
Dual salt bridge design with a double-layer exudation interface, resistant to medium back infiltration. The ceramic pore-structured electrode interface minimizes clogging and is optimized for monitoring in organic solvents and non-aqueous phase environments. Featuring a high-strength glass bulb design for enhanced durability and an oversized sensing bulb that significantly improves hydrogen ion detection capability, this electrode excels in organic solvents and non-aqueous environments. Constructed with impact-resistant PP material, it demonstrates exceptional mechanical toughness and resistance to diverse organic solvents, acids, and alkalis. Equipped with a digital sensor, it offers robust anti-interference performance, high stability, and extended signal transmission range.
Applications: Ideal for organic solvents and non-aqueous phase environmental monitoring.
>>Feature
>>Technical Parameter
Power Supply: 9–36 VDC
Output: RS485 MODBUS RTU
Sensing Material: Glass/Silver + Silver Chloride; SNEX
Housing Material: PP (Polypropylene)
Protection Rating: IP68
Measurement Range: 0–14 pH
Accuracy: ±0.05 pH
Pressure Resistance: 0–0.6 MPa
Temperature Compensation: NTC10K Thermistor
Temperature Range: 0–80°C
Calibration: Sample Calibration, Standard Solution Calibration
Connection: 4-core Cable
Thread Type: NPT 3/4"
Cable Length: 10m or Customizable
Applications: Suitable for organic process environments.
>>Principle
The core theory of pH electrode measurement is the Nernst equation. The sensor used in potentiometric analysis is called a galvanic cell. A galvanic cell is a system that converts chemical reaction energy into electrical energy. The voltage of this cell is referred to as the electromotive force (EMF). This EMF consists of two half-cells. One half-cell is the measuring sensor, whose potential is related to the activity of specific ions; the other is the reference half-cell, often called the reference sensor, which is typically connected to the measurement solution and the instrument.
ORP (Oxidation-Reduction Potential) is a critical indicator of water quality. While it cannot independently determine water quality, it reflects the ecological environment of aquatic systems by integrating other water quality parameters.
In water, each substance has its unique redox properties. Simplistically, this can be understood as: at a microscopic level, different substances possess varying oxidation-reduction capacities. These substances interact to form an overall macroscopic redox characteristic. ORP reflects the collective redox behavior of all substances in the solution. A higher ORP indicates stronger oxidizing capacity, while a lower ORP suggests weaker oxidizing capacity. A positive potential signifies oxidizing properties, whereas a negative potential indicates reducing properties.
>>Installation Diagram
Before use, unscrew the electrode protective cap and install it with the appropriate mounting bracket or accessories.
1. Sidewall Installation: Ensure the interface tilt angle exceeds 15 degrees.
2. Top Flange Installation: Note flange dimensions and electrode insertion depth.
3. Pipe Installation: Consider pipe diameter, flow velocity, and pressure.
4. Flow-Through Installation: Monitor flow velocity and pressure.
5. Submersion Installation: Adjust bracket length as needed.
>>Electrode Maintenance and Care
○ Before use, unscrew the protective cap and immerse the electrode bulb and liquid junction in the sample.
○ If salt crystals form near the electrode tip or inside the cap due to electrolyte evaporation, rinse with water. This indicates normal dialysis membrane function.
○ Check for air bubbles in the glass bulb by shaking the electrode vertically.
○ Keep the glass membrane hydrated for fast response. After measurement or calibration: Rinse the electrode thoroughly. Add storage solution (3 mol/L KCl) to the protective cap.
○ Ensure terminal connections remain dry. Clean with anhydrous alcohol if contaminated.
○ Avoid prolonged immersion in distilled water, protein solutions, or contact with silicone grease.
○ For aged electrodes with cloudy membranes or deposits, soak in 10% HCl, then rinse.
○ Regularly clean and calibrate the electrode. If calibration fails after maintenance, replace the electrode.
>>Lifespan
Under normal conditions with proper maintenance, electrodes last over 12 months. Even unused electrodes have a shelf life of 12–24 months (if stored correctly). Exposure to strong acids, bases, high temperatures, or corrosive liquids shortens lifespan. Electrodes are consumables and generally not covered by warranty.
>>Electrode Calibration
○ Use fresh pH/ORP standard buffer solutions of appropriate concentrations.
○ Remove the protective cap and rinse the electrode with distilled water.
○ Set the instrument to calibration mode (refer to the instrument manual for details).
○ After calibration, measure actual samples.