Grove - ORP Sensor Kit Pro - IP68 ORP probe, ±2000 mV range, ±15mV accuracy, 5 meters, 0-80℃, Arduino, RoHS certification (แท้จาก SeeedStudio)

FEATURES

• Grove ORP Sensor Upgrade: Assemble 5-meters IP68 ORP probe, offering -2000 mV to 2000 mV sensing range, operating under 0-80°C, member of simple-to-use Grove ecosystem
• Enhanced Measurement Performance: Maintain ±15mV sensing accuracy at 0-60°C
• Working Voltage: Support both 3.3V and 5V working conditions
• Exchangeable Sensor Nodes: Support BNC-linker sensor probes
• RoHS Certification: Environmentally friendly, assured detection

If you find it, please use a wet paper towel to gently wipe off the crystals on it, please do not let it near your children to avoid accidental ingestion.
APPLICATIONS

• Monitor and control oxidation-reduction reactions
• Disinfected water detection
• Health-friendly water detection
• Determine the types of microbial
• Dectct anaerobic microbial activity
• Wastewater treatment
• Aquaculture
• Industrial sewage discharge monitoring

SPECIFICATION

Part List

Learn

 

[Wiki] Grove - ORP Sensor Kit (HR-O) WIKI

This is the wiki of Grove - ORP Sensor Kit (HR-O) for you quickly getting started with it.

 

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Instructions for use of Grove ORP Sensor Kit Pro

An Oxidation Reduction Potential (ORP) Sensor measures the activity of oxidizers and reducers in an aqueous solution. It is a potentiometric measurement from a two-electrode system similar to a pH sensor. Sometimes it is also referred to as a redox measurement. Unlike a pH sensor, an ORP sensor measures the ratio of oxidized to reduced forms of all chemical species in solution.

E = Eo – 2.3 (RT/nF) x (log [Ox] / [Red])

Where:

• E = total potential developed between the measurement and reference electrodes
• Eo = a voltage specific to the system
• R = gas constant
• T = temperature in K
• n = the number of electrons involved in the equilibrium between the oxidized and reduced species
• F = Faraday constant
• [Ox] = concentration of the oxidized species
• [Red] = concentration of the reduced form of that species

The output of the ORP sensor is relative to the reference electrode. For example, a reading of +100 mV indicates the potential is 100 mV higher than the potential of the reference half cell and suggests an oxidizing environment. Likewise, a –100 mV reading indicates a potential 100 mV lower than the reference half cell and is a reducing environment. In some applications, redox potential may be reported as Eh which is the voltage reading with respect to the Standard Hydrogen Electrode (SHE). By taking into account the offset of the reference electrode used in the ORP sensor, the potential can be converted into Eh readings. Vernier ORP sensors use a Ag/AgCl saturated KCl reference electrode.

Equipment Installation¶

Before using Grove ORP Sensor Pro, we need to mount the Grove board with the probe. On the Grove board, there will be two protruding round tips at the connection with the probe, align them with the two notches at the probe connection and insert them firmly. Then just rotate them along the notches to the limit.

Tip

If you want to disassemble it, then simply rotate it in the opposite direction along the groove and then forcefully separate the Grove plate from the probe. Please note that the hand force is on the metal part as much as possible to avoid breaking the plate with too much force.

A nut and a spacer are included with the product. If you are in need of frequent disassembly, we do not recommend that you install the spacer and nut, which will make your disassembly difficult.

Arduino / XIAO Example¶

Next, we will introduce the basic usage of Grove ORP Sensor with Seeed Studio's XIAO and Seeeduino products based on Arduino platform.

Step 1. Launch the Arduino application.

Step 2. Select your development board model and add it to the Arduino IDE.

Using Grove ORP Sensor Pro on Seeed Studio XIAO SAMD21¶

A simple working definition for ORP is a solution's capacity for electron transfer known as oxidation or reduction, given in millivolts. The measurement of ORP is the reading of the voltage potential between the measuring electrode and a reference electrode. Depending on the solution being measuring, the ORP electrodes will serve as either an electron donor or an electron acceptor. ORP is similar to pH in that pH indicates how acidic or basic a solution is based on the hydrogen ion activity within the solution and ORP indicates the reduction- oxidation status of a solution based on the collective electron activity within the solution.

In this example, we use XIAO SAMD21 as the main control board to measure the ORP value of Coca-Cola using Grove ORP Sensor Pro.

Materials Required¶

Seeed Studio XIAO SAMD21	Seeed Studio Expansion Base for XIAO	Grove ORP Sensor Pro

Operation Steps¶

Step 1. Connect Grove ORP Sensor Pro to XIAO Expansion Board.

In this example, we will use the A6 and A7 pins above the XIAO as the CAL and SIG pins of the sensor. Please connect the Grove ORP Sensor Pro to the UART port of the XIAO expansion board using the Grove cable.

Step 2. Put the Seeed Studio XIAO SAMD21 on the expansion board.

Step 3. Remove the protective case of the probe.

This step requires special care!

Please make the probe face down vertically before you remove the protective case to expose the probe, and then slowly rotate the case to remove the probe. Please do not tilt during this process, otherwise the potassium chloride inside will easily pour out!

The probe is then fully inserted into the liquid to be measured. You can rest assured that the probe and sensor are waterproof, and we have specially prepared a 5m long cable for you. Please note, however, that the Grove board is not waterproof, so please do not put it into the liquid with it.

Step 4. Upload program.

The following is a sample program for the Grove ORP Sensor.

Before using the program, you need to correct some variables of the program according to the actual situation.

• VOLTAGE: refers to the actual operating voltage of the sensor. It is recommended that you use a multimeter to measure the supply voltage of the pin, the more accurate the value, the more accurate the measurement. On my XIAO expansion board, the measured supply voltage is 3.37V.

• LED: The program adds the function of blinking LED as working indicators, which can be defined here as the LED pin numbers of the control board you are using.

• ArrayLenth: Number of samples per unit of time. The lower the value, the shorter the time to obtain ORP values, but it also makes the result values unstable. The default value is 40.

• orpPin: The orp pin of the sensor is connected to the pin number of the main control board.

• calPin: The cal pin of the sensor is connected to the pin number of the main control board.

After updating the program, select the development board model and port number of Seeed Studio XIAO SAMD21 and upload the program.

Turn on the serial monitor and set the baud rate to 9600, you will see the change of ORP value detected by the current sensor.

Clean Grove ORP Sensor Pro probe¶

Several factors can lead to the blockage of ORP sensor’s diaphragms. In particular, junctions made of ceramic, or other porous material are prone to clogging. The most frequent reasons are listed here together with the respective cleaning procedures:

1. Blockage with silver sulfide (Ag2S): if the reference electrolyte contains silver ions and the sample being measured contains sulfides, the junction will get contaminated with a silver sulfide precipitate. To clear the junction of this contamination, clean it with 8% thiourea in 0.1 mol/L HCl solution for 5-60 minutes (Thiourea Cleaner is available from METTLER TOLEDO).

2. Blockage with silver chloride (AgCl): the silver ions from the reference electrolyte can also react with samples that contain chloride ions, resulting in an AgCl precipitate. This precipitate can be removed by soaking the electrode in a concentrated ammonia solution (35% NH3 aq.).

3. Blockage with proteins: junctions contaminated with proteins can often be cleaned by immersing the electrode in a pepsin/HCl (5 % pepsin in 0.1 mol/L HCl) solution for several hours (Pepsin-HCl Cleaner is available from METTLER TOLEDO).

4. Other junction blockages: if the junction is blocked with other contaminations, try cleaning the ORP sensor in an ultrasonic bath with water or with a 0.1 mol/L HCl solution.

Store Grove ORP Sensor Pro correctly¶

After use, rinse the electrode well with distilled water and tighten the protective case. ORP electrodes should be stored in the wetting cap filled with a reference electrolyte (often 3 mol/L KCl) or InLab storage solution. Store the half-cell dry. The electrode should be stored upright and at room temperature.

Troubleshooting¶

• Q1: Why is calibration not needed for Grove ORP Sensor Pro ?

A: Measuring redox means to measure the reduction potential of the solution. The raw value (mV reading) is the final result. If the redox electrode is verified by measuring in 220mV buffer solution and if it is not within 220 ± 20 mV, the sensor must be cleaned (and not calibrated).

• What to do if Grove ORP Sensor Pro verification fails ?

A: The expected value for the Redox sensor is 220 ± 20 mV. If this condition is not met, it is suggested to clean the metallic ring or pin, using a wet tissue, followed by rinsing with distilled water and then re-measure mV value in redox buffer 220 mV. Another way to clean and remove deposits from the metal ring is to condition it with 0.1 mol/L HCI. Also in some cases, a change of reference electrolyte is recommended.

• When are relative mV measurements done?

A: It might be that someone wants to correct the reading for any offset, for example, to know the potential against a hydrogen standard electrode instead of the Ag/AgCl reference. Therefore, relative mV measurements are performed, and one needs to enter the offset in the measurement parameters.