JXBS-3001-PH-I20
JXBS-3001-PH-I20 transmitter is widely used in applications where pH value monitoring is required, such as soil pH measurement. The input power supply, sensor probe,
and signal output of the sensor are completely isolated. Safe and reliable, beautiful appearance and convenient installation.
Features
The probe of this product adopts PH electrode, with stable signal and high precision. It has the characteristics of wide measurement range, good linearity, good waterproof performance, easy to use, easy to install, and long transmission distance.
- Port Description
- Wide voltage power input can be 12-24V. When connecting the 485 signal line, please note that the two lines of A / B cannot be reversed, and the addresses of multiple devices on the bus must not conflict.
Power |
Brown |
Power Supply + |
Black |
Power Supply – |
Communication |
Yellow(Grey) |
Voltage/ Current Output Positive |
Blue |
Voltage/ Current Output Negative |
Sensors play a crucial role in modern agricultural farming by providing real-time data on various parameters such as soil moisture, temperature, humidity, light intensity, and crop health. The sustainability of sensor technology in agricultural farming depends on several factors:
Resource Efficiency: Sensors can enhance resource efficiency by optimizing irrigation, fertilization, and energy usage. By providing accurate information about soil moisture levels, farmers can optimize water usage, reducing waste and conserving water resources. Similarly, sensors can monitor nutrient levels in the soil, allowing farmers to apply fertilizers precisely where they are needed, reducing excess usage and minimizing environmental impact.
Precision Agriculture: Sensors enable precision agriculture practices, where farmers can apply inputs such as water, fertilizers, and pesticides with greater accuracy and only when required. This reduces the overall amount of inputs used, minimizing the environmental footprint and potential negative impacts on ecosystems.
Disease and Pest Management: Sensors can help in early detection of plant diseases and pests by monitoring environmental conditions and crop health parameters. This allows farmers to take prompt action, reducing the need for widespread pesticide use and enabling targeted interventions.
Data-Driven Decision Making: Sensors generate vast amounts of data, which, when analyzed properly, can provide valuable insights for decision making. By utilizing data analytics and machine learning algorithms, farmers can optimize their farming practices, leading to improved efficiency and reduced environmental impact.
Environmental Monitoring: Sensors can also be used to monitor environmental factors such as air quality, water quality, and weather conditions. This information can help farmers assess the impact of their farming practices on the surrounding environment and take appropriate measures to mitigate any negative effects.
However, it is important to consider the sustainability of the entire lifecycle of sensor technology. This includes factors such as the materials used in sensor production, energy requirements for sensor operation, and the management of sensor waste at the end of their life cycle. Efforts are being made to develop more sustainable sensor technologies, including the use of eco-friendly materials, energy-efficient designs, and recyclable components.
Overall, the use of sensors in agricultural farming has the potential to enhance sustainability by improving resource efficiency, reducing chemical inputs, enabling precision agriculture, and promoting data-driven decision making. However, it is essential to consider the broader context and ensure that sensor technology is implemented in a sustainable and responsible manner.
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