Y532-A Digital pH Sensor
Yosemitech Y532-A digital pH sensor adopts a robust industrial-grade online electrode and an integrated temperature sensor for automatic temperature compensation, rendering it highly suitable for long-term online monitoring applications. It features an RS485 communication interface and supports the standard MODBUS protocol, enabling networking and system integration without the need for an external controller. Y532-A pH probe is extensively utilized in various fields, including water quality treatment, hydrological monitoring, wastewater management, swimming pools, industrial control systems, and biological applications.
- Digital sensor with RS-485 output and MODBUS protocol support;
- Requires no electrolyte, exhibits strong resistance to interference, and eliminates the need for frequent calibration.
- Includes an integrated temperature sensor with automatic temperature compensation functionality.
- Utilizes high-performance industrial-grade online electrodes designed for reliable operation over extended periods.
- All calibration data is stored directly in the sensor, enabling on-site installation and immediate use.
| Name | pH sensor |
| Model | Y532-A |
| Measuring principle | Glass electrode method |
| Range | 0-14 pH |
| Accuracy | ±0.02 pH |
| Resolution | 0.01 |
| Temperature range | 0-50℃ |
| Maximum water depth | 30m |
| IP range | IP68 |
| Sensor interface | RS-485,MODBUS protocol |
| Power | 0.3W(DC 12-24V,≥1A) |
| Size | Φ28mm*194mm(No protective cover) |
| Cable length | 10 m (default), customizable |
| Calibration | two-point or three-point calibration |
| Sensor housing material | POM+Ti |
- pH Sensor
- 10m Cable(default), Customizable
- User Manual
- Delivery Inspection Report
Environmental Monitoring:
Surface Water: Monitoring the pH of lakes, rivers, and reservoirs to assess water quality.
Groundwater: Ensuring the safety and quality of groundwater resources.
Water Treatment:
Drinking Water: Monitoring and controlling the pH during water treatment processes to ensure safe drinking water.
Wastewater: Managing the pH of wastewater to comply with environmental regulations.
Industrial Processes:
Chemical Manufacturing: Monitoring pH in chemical processes to ensure product quality and safety.
Food and Beverage: Ensuring the pH of products meets quality standards.
Agriculture:
Soil pH: Monitoring soil pH to optimize crop growth and nutrient availability.
Hydroponics: Managing the pH of nutrient solutions in hydroponic systems.
Biological Factors
- Photosynthesis: Phytoplankton (e.g., algae) consume CO₂ during photosynthesis, reducing CO₂ levels and increasing pH. In summer, intense algal growth often raises water pH.
- Respiration: Aquatic organisms release CO₂ during respiration, lowering pH. At night, without photosynthesis, pH typically decreases.
- Organic Matter Decomposition: Microbial decomposition of organic matter (e.g., leftover feed, feces) produces organic acids, reducing pH. In aquaculture ponds, accumulated organic matter can significantly lower pH if oxygen is insufficient.
Chemical Factors
- Water Hardness: High water hardness limits pH increases due to calcium and magnesium ions forming precipitates with carbonate ions. In low-hardness waters, pH rises more easily after CO₂ consumption by photosynthesis.
- Chemical Additives: Substances like quicklime increase pH, while acidic substances (e.g., organic acids, hydrochloric acid) decrease it.
Physical Factors
- Temperature: Rising temperatures reduce CO₂ solubility and increase photosynthesis rates, raising pH. However, temperature-induced water ionization slightly increases hydrogen ion concentration, with minimal effect on pH.
- Pressure: In high-pressure environments (e.g., deep sea), increased CO₂ dissociation lowers pH.
Other Factors
- External Water Sources: Introducing water with differing pH can drastically alter pond pH. For example, acidic or alkaline water sources significantly impact water body pH.
- Soil: Soil leachate affects pond pH. Acidic soils lower pH (e.g., southern mangrove areas), while coastal saline-alkaline soils raise it.
pH value, also referred to as the hydrogen ion activity index or acid-base indicator, quantifies the activity of hydrogen ions in a solution and serves as a standard for assessing the acidity or basicity of a solution under normal conditions. Typically, at standard temperature (approximately 25°C or 298 K), a pH value closer to 0 indicates a higher degree of acidity, while a pH value closer to 14 signifies a higher degree of alkalinity. A solution with a pH less than 7 is classified as acidic, whereas a pH greater than 7 denotes an alkaline solution. When the pH equals 7, the solution is considered neutral.
Chlorophyll Sensors!
Ever wondered how we track algal blooms or monitor water health in real time?
Dive into our latest video to explore Chlorophyll Sensors — keeping our waters safe!
What’s Inside?
How to Use Yosemitech Self-cleaning Chlorophyll Sensor?
Why Care?
Chlorophyll sensors aren’t just gadgets — they’re guardians of freshwater and marine life.
From April 21th to 23rd, 2025, IE Expo China 2025 concluded successfully at the Shanghai New International Expo Centre. As a highly anticipated communication platform in the industry, the exhibition attracted exhibitors, experts, scholars, and industry elites from around the world to gather in Shanghai. Through various forms such as cutting - edge technology displays and high - end forum sharing, it created a professional and forward - looking audio - visual feast for the industry.
Suzhou Yosemite Technology Co., Ltd. ("YOSEMITECH"), which has been deeply involved in the water quality monitoring field for over 11 years, always adheres to the mission of "Water Monitoring Made Simple". YOSEMITECH showcased its self - developed water quality monitoring sensors and instruments at the exhibition. As a manufacturer of water quality monitoring sensors, we had in - depth exchanges with domestic and foreign partners and industry peers during the exhibition. It fully demonstrated its profound expertise in areas such as water quality sensor research and development and intelligent monitoring system integration, and continuously empowered global water quality monitoring scenarios with innovative technologies to promote the efficient and intelligent development of the industry.
Y532-A Digital pH Sensor Calibration
Required equipments and raw materials
Required equipments: four 1000mL beakers, one set of gloves.
Raw materials: three pH standard liquid powders and deionized water.
Calibration steps
There are three methods of user calibration for the pH sensor: 3-points calibration.
3-point calibration was done in 4.01、6.86、9.18 standard solution.
3-points calibration step
Connection method of connecting RS485 to USB connector: the red wire connects the positive terminal of the power supply, the black wire connects the negative terminal of the power supply, the green wire connects the A of the RS485 interface, the white wire connects the B of the RS485 interface, as shown in the following figure.
Y514-A self-cleaning chlorophyll sensor calibration
Required equipments and raw materials
Required equipments: two 1L brown bottles, one iron stand, one set of gloves
Raw materials: 2mg/L chlorophyll standard solution and deionized water
Calibration steps
There are three methods of user calibration for the chlorophyll sensor: 0-point calibration, 1-point calibration and 2-points calibration.
0-point calibration was done in deionized water, 1-point calibration was done in 2mg/L chlorophyll standard solution, 2-points calibration was done in deionized water and 2mg/L chlorophyll standard solution.
0-point calibration step (change the B value)
Step 1: put an appropriate amount of distilled water or deionized water into a 1L brown bottle, remove the rubber protective cap on the front of the sensor and put the sensor in the center of the brown bottle, which not close to the wall around the brown bottle, and then fix the sensor with an iron stand, adjust the high and low position of the sensor. Pay attention to maintain a distance greater than 10cm between the front end of the sensor and the bottom of the brown bottle.
Step 2: Under the “Automatic Calibration” interface, click “0 point” to do zero-point calibration, wait for the values in the pop-up window to stabilize, and click “OK” to complete the calibration. Click “Get” to check whether the B value is written correctly.
Step 3: click “Start” under the “CHL” interface to get the real-time measurement of the CHL and temperature, check that the CHL is close to 0 to verify that the zero-point calibration is successful.
1-point calibration step (change the K value)
Step 1: put an appropriate amount of 2mg/L chlorophyll standard solution into a 1L brown bottle, remove the rubber protective cap on the front of the sensor and put the sensor in the center of the brown bottle, which not close to the wall around the brown bottle, and then fix the sensor with an iron stand, adjust the high and low position of the sensor. Pay attention to maintain a distance greater than 10cm between the front end of the sensor and the bottom of the brown bottle.
Step 2: Under the “Automatic Calibration” interface, change the “Single/First Point Calibration Value” to 227.1, click “1 point” to do one-point calibration, wait for the values in the pop-up window to stabilize, and click “OK” to complete the calibration. Click “Get” to check whether the K value is written correctly.
Step 3: click “Start” under the “CHL” interface to get the real-time measurement of the CHL and temperature, check that the CHL is close to 227.1 to verify that the one-point calibration is successful.
2-points calibration step (change the K and B values)
Step 1: put an appropriate amount of distilled water or deionized water into a 1L brown bottle, and put an appropriate amount of 2mg/L chlorophyll standard solution into another 1L brown bottle.
Step 2: remove the rubber protective cap on the front of the sensor, put the sensor in the center of the brown bottle containing distilled water or deionized water, which not close to the wall around the brown bottle, and then fix the sensor with an iron stand, adjust the high and low position of the sensor. Pay attention to maintain a distance greater than 10cm between the front end of the sensor and the bottom of the brown bottle.
Step 3: Under the “Automatic Calibration” interface, change the “Single/First Point Calibration Value” to 0, change the “Second Point Calibration Value” to 227.1, click “2 points” to do two-points calibration, wait for the values in the pop-up window to stabilize, and click “OK”. Then wipe the sensor dry and put it into 2mg/L chlorophyll standard solution according to the method of step 2, wait for the values in the pop-up window to stabilize, and click “OK” to complete the calibration. Click “Get” to check whether the K and B values are written correctly;
Step 4: click “Start” under the “CHL” interface to get the real-time measurement of the CHL and temperature, check that the CHL is close to 227.1, then clean the sensor with distilled water or deionized water, wipe it dry and put it into the distilled water or deionized water according to the method of step 2 to get the real-time measurement of the CHL and temperature, check that the CHL is close to 0 to verify that the two-points calibration is successful.
