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Benefits of Using Atlas Scientific dissolved oxygen sensor in Aquaculture
Aquaculture, the farming of aquatic organisms such as fish, shellfish, and plants, has become an increasingly important industry in meeting the growing demand for seafood worldwide. As aquaculture operations continue to expand, the need for reliable and accurate monitoring of water quality parameters, such as dissolved oxygen levels, becomes crucial to ensure the health and productivity of the aquatic organisms being farmed.
One of the main benefits of using the Atlas Scientific dissolved oxygen sensor in aquaculture is its high level of accuracy. The sensor is calibrated to provide precise measurements of dissolved oxygen levels, ensuring that aquaculture farmers have reliable data to work with. This accuracy is essential for maintaining optimal water quality conditions for the aquatic organisms being farmed, as even small fluctuations in dissolved oxygen levels can have a significant impact on their health and growth.
In addition to its accuracy, the Atlas Scientific dissolved oxygen sensor is also known for its durability and reliability. The sensor is designed to withstand the harsh conditions often found in aquaculture environments, such as high levels of salinity and fluctuating temperatures. This durability ensures that the sensor can continue to provide accurate measurements over an extended period of time, reducing the need for frequent maintenance and replacement.
Another benefit of using the Atlas Scientific dissolved oxygen sensor in aquaculture is its ease of use. The sensor is designed to be user-friendly, with simple installation and calibration procedures that can be easily carried out by aquaculture farmers. This ease of use allows farmers to quickly set up the sensor and start monitoring dissolved oxygen levels in their aquaculture systems, without the need for specialized training or expertise.
Furthermore, the Atlas Scientific dissolved oxygen sensor is equipped with advanced features that enhance its functionality and performance. For example, the sensor can be connected to a data logging system or a remote monitoring platform, allowing aquaculture farmers to track dissolved oxygen levels in real-time and receive alerts if levels fall outside of the desired range. This remote monitoring capability enables farmers to respond quickly to any changes in water quality, helping to prevent potential issues before they escalate.
Overall, the Atlas Scientific dissolved oxygen sensor offers a range of benefits for aquaculture farmers looking to monitor and manage dissolved oxygen levels in their operations. From its high level of accuracy and durability to its ease of use and advanced features, this sensor provides a reliable and effective solution for ensuring optimal water quality conditions in aquaculture systems. By investing in a quality dissolved oxygen sensor like the Atlas Scientific model, aquaculture farmers can help to improve the health and productivity of their aquatic organisms, ultimately leading to a more sustainable and successful aquaculture operation.
How to Calibrate and Maintain Atlas Scientific dissolved oxygen sensor for Accurate Readings
The Atlas Scientific dissolved oxygen sensor is a valuable tool for monitoring oxygen levels in various applications, such as aquaculture, environmental monitoring, and water treatment. To ensure accurate readings, it is essential to calibrate and maintain the sensor regularly. In this article, we will discuss the steps involved in calibrating and maintaining the Atlas Scientific dissolved oxygen sensor.
| Model | POP-8300 free chlorine online analyzer |
| Measurement range | (0.00-2.00)mg/L(ppm) (0.00-20.00)mg/L(ppm) |
| Accuracy | Indication error 10% |
| Resolution | 0.01mg/L(ppm) |
| Communication interface | RS485 MODBUS RTU communication protocol |
| Analog output | Double channel (4-20)mA output; Isolated, reversible, completely adjustable, instrument/transmitter dual mode; ±0.1mA transmission accuracy |
| Control output | Double channels, Load capacity 50mA(Max),AC/DC 30V |
| Power supply | Connected to electric supply AC80-260V;50/60Hz, compatible with all international market power standards(110V;220V;260V;50/60Hz). |
| Working environment | Temperature:(5-50)℃;relative humidity:≤85% RH(non-condensation) |
| Power Consumption | <20W |
| Storage environment | Temperature:(-20-70)℃;relative humidity:≤85%RH(non-condensation) |
| Installation | Wall mounted (with the preset back cover) |
| Cabinet weight | ≤10kg |
| Cabinet dimension | 570*mm*380mm*130mm(H×W×D) |
Calibration is a crucial step in ensuring the accuracy of the sensor readings. Before calibrating the sensor, it is essential to gather all the necessary equipment, including calibration solutions, a clean container, and a magnetic stirrer. The first step in the calibration process is to prepare the calibration solutions according to the manufacturer’s instructions. Once the solutions are ready, place the sensor in the first calibration solution and allow it to stabilize for a few minutes.
After the sensor has stabilized, adjust the calibration settings on the device to match the calibration solution. Repeat this process for the second calibration solution. Once both calibration solutions have been used, the sensor should be calibrated and ready for use. It is recommended to calibrate the sensor regularly to ensure accurate readings.
In addition to calibration, it is essential to maintain the sensor properly to prolong its lifespan and ensure accurate readings. One of the most crucial maintenance tasks is cleaning the sensor regularly. To clean the sensor, remove it from the water and rinse it with clean water to remove any debris or buildup. Avoid using harsh chemicals or abrasive materials, as they can damage the sensor.
| Model | CM-230S Ecomonical conductivity monitor |
| Range | 0-200/2000/4000/10000uS/cm |
| 0-100/1000/2000/5000PPM | |
| Accuracy | 1.5%(FS) |
| Temp. Comp. | Automatic temperature compensation based on 25℃ |
| Oper. Temp. | Normal 0~50℃; High temp 0~120℃ |
| Sensor | Standard:ABS C=1.0cm-1 (others are optional) |
| Display | LCD Screen |
| Zero Correction | Manual correction for low range 0.05-10ppm Set from ECO |
| Unit Display | uS/cm or PPM |
| 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 | 48×96×100mm(H×W×L) |
| Hole Size | 45×92mm(H×W) |
| Installation Mode | Embedded |
After cleaning the sensor, it is essential to store it properly to prevent damage. Store the sensor in a clean, dry place away from direct sunlight and extreme temperatures. It is also recommended to store the sensor in a protective case to prevent damage during transportation or storage.
Another important maintenance task is checking the sensor for any signs of damage or wear. Inspect the sensor regularly for any cracks, corrosion, or other damage that may affect its performance. If any damage is found, it is essential to replace the sensor immediately to ensure accurate readings.
Regularly calibrating and maintaining the Atlas Scientific dissolved oxygen sensor is essential for accurate readings and reliable performance. By following the steps outlined in this article, you can ensure that your sensor provides accurate and reliable data for your monitoring needs. Remember to calibrate the sensor regularly, clean it properly, and store it correctly to prolong its lifespan and ensure accurate readings. With proper calibration and maintenance, the Atlas Scientific dissolved oxygen sensor can be a valuable tool for monitoring oxygen levels in various applications.
