Soil Sensor JXBS-3001-TH-I20-1 Introduction
Soil Sensor JXBS-3001-TH-I20-1 transmitter is widely used in agricultural greenhouses, flower culture and other occasions need temperature and humidity monitoring. Three parts of the sensor input power supply, induction probe, signal output are completely isolated. safe and reliable, beautiful appearance and convenient installation.
Features
The temperature and humidity transmitter adopts high sensitivity probe, the signal is stable and the precision is high. It has the characteristics of wide measuring range, good linearity, good waterproof performance, convenient use, easy installation, long transmission distance and so on.
Materials Used:
- Austenitic 316 Stainless Steel Probe
- In the probe part, we choose austenitic 316 stainless steel as raw material, which is rust-proof, electrolytic and saline-alkali corrosion-resistant to ensure the long-term operation of the probe part. Therefore, it is suitable for all kinds of soil. It can cause abnormalities in sand and is not suitable for sand.
- Low Power Sensitive Chip
- Using top-level chips: Low power consumption, high sensitivity and signal stability.
- Epoxy Resin Vacuum Pouring
- High Temperature vacuum canning with high density epoxy resin between probe and airframe can prevent moisture from entering the airframe, and the airframe and the airproof performance is good.
- Protection Class:IP68
- In addition to the combination part, we also made waterproof and dust-proof treatment for the whole fuselage to ensure long-term operation of components, waterproof and dust-proof grade to IP68.
Sensors play a crucial role in modern agricultural farming by providing real-time data and insights that help optimize resource usage, enhance crop yield, and reduce environmental impact. The sustainability of sensors for agricultural farming can be evaluated based on several factors:
Resource Efficiency: Sensors enable precision agriculture techniques, such as variable rate application of fertilizers and water, which optimize resource usage. By applying inputs only where and when they are needed, farmers can reduce waste and minimize the environmental impact of agriculture.
Environmental Impact: Sensors can monitor soil moisture, temperature, and nutrient levels, as well as detect pests and diseases. This allows farmers to take timely and targeted actions, reducing the need for chemical inputs and minimizing the environmental footprint associated with agriculture.
Water Conservation: Water is a scarce resource in many regions, and efficient water management is essential for sustainable agriculture. Soil moisture sensors and weather stations help farmers optimize irrigation schedules, ensuring that water is used efficiently and minimizing water waste.
Energy Consumption: Some sensors require a power source to operate. The sustainability of sensor systems can be enhanced by using energy-efficient sensors and powering them with renewable energy sources like solar panels. This reduces the carbon footprint associated with sensor deployment.
Data Analysis and Integration: Sensors generate a significant amount of data, and effective analysis is crucial for sustainable farming practices. By integrating sensor data with advanced analytics, machine learning, and AI algorithms, farmers can gain valuable insights for making informed decisions, optimizing inputs, and reducing waste.
Longevity and Maintenance: The durability and maintenance requirements of sensors impact their sustainability. Long-lasting sensors that require minimal maintenance are preferable to reduce waste and ensure continuous monitoring capabilities.
Cost-effectiveness: The cost of sensor technology can impact its adoption and sustainability in agriculture. Affordable sensor solutions make it more accessible to a broader range of farmers, enabling widespread implementation and long-term sustainability.
Overall, the use of sensors in agricultural farming has the potential to significantly enhance sustainability by improving resource efficiency, reducing environmental impact, conserving water, optimizing energy usage, and enabling data-driven decision-making. However, it is important to consider the full life cycle of sensor systems, including their manufacturing, deployment, maintenance, and eventual disposal, to ensure their overall sustainability.
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