Environmental Monitoring System: How Can Cellular Routers Solve the Power Supply and Communication Dilemmas of Field Equipment?
Driven by the "dual carbon" goals, environmental monitoring systems are accelerating their evolution towards intelligence, real-time operation, and full coverage. However, field monitoring sites generally face two core pain points: unstable power supply and unreliable communication. Taking a provincial-level environmental monitoring project as an example, among the more than 300 water quality monitoring points deployed in mountainous areas and along riverbanks, nearly 40% experienced data loss due to power outages or communication failures, directly impacting pollution tracing and governance decision-making. As the "nerve center" connecting devices to the cloud, cellular routers are becoming a key tool for solving field monitoring dilemmas through technological integration and innovative design.
Field monitoring equipment often faces difficulties in accessing mains power, low solar power generation efficiency, and short battery lifespans. For instance, a monitoring station at a sewage outlet in a chemical industrial park used a traditional solar power system, which led to battery over-discharge and equipment shutdown for up to 72 hours due to continuous rainy weather, directly causing data interruptions. More severely, in remote areas where equipment maintenance cycles can last for months, issues such as battery aging and line degradation further exacerbate power supply risks.
Core pain points:
Insufficient power supply continuity: Solar/wind energy is highly weather-dependent, and mains power is costly.
Low energy storage efficiency: Lead-acid batteries have short cycle lives, and lithium batteries are expensive.
High maintenance costs: Low frequency of manual inspections and delayed fault responses.
The complex communication environment in the field, including signal blockage in mountainous areas, electromagnetic interference along rivers, and dispersed equipment deployment, leads to data transmission delays or losses. For example, PM2.5 sensors deployed in mountainous areas for an atmospheric monitoring project had a data upload success rate of only 65% due to weak 4G signals and required manual periodic collection of data from storage cards, resulting in low efficiency. Additionally, traditional routers are prone to crashes and interface loosening in extreme temperature and humidity environments, further affecting communication stability.
Core pain points:
Insufficient signal coverage: Weak public network signals in remote areas and high costs of dedicated network construction.
Lack of network redundancy: Single-link failures causing data interruptions.
Poor environmental adaptability: High temperatures, humidity, and vibrations accelerate equipment aging.
Cellular routers build a "power supply-communication-intelligence" trinity support system for field monitoring by integrating technologies such as multi-energy power supply management, multi-mode communication, and edge computing. Taking the USR-G809s cellular router as an example, its design philosophy and functional characteristics directly address the pain points of field monitoring:
3.1 Power Supply Innovation: Multi-Energy Collaboration and Intelligent Management
Multi-energy input support: The USR-G809s supports DC9-60V wide-voltage input, compatible with solar, wind, mains power, and backup batteries. It achieves energy priority switching through an intelligent power management module. For example, it prioritizes solar power for charging and operation when sunlight is sufficient and automatically switches to mains power or batteries at night or during rainy weather to ensure 24-hour equipment operation.
Low-power design: The router adopts a Qualcomm industrial-grade chip, reducing power consumption by 30% compared to traditional products. Combined with the energy storage battery of the solar system, it extends equipment battery life. For instance, a river monitoring station using the USR-G809s maintained continuous operation for five consecutive rainy days, with the data integrity rate increasing to 99%.
Remote power monitoring: Through the USR Cloud platform, operation and maintenance personnel can monitor equipment voltage, current, remaining battery level, and other parameters in real time to provide early warnings of power failures. For example, when the battery voltage falls below a threshold, the system automatically sends an alert message to guide on-site personnel in battery replacement.
Five network ports + dual serial port design: The USR-G809s provides 2 SFP optical ports, 8 RJ45 electrical ports, 1 RS232, and 1 RS485 interface, enabling simultaneous connection to multiple types of devices such as water quality sensors, weather stations, and cameras. It uploads data to the cloud via Ethernet or 4G/5G. For example, an atmospheric monitoring station connected in series PM2.5, SO2, wind speed, and direction sensors through the router to achieve "one-machine multi-sampling."
Dual-SIM dual-mode communication: It supports 4G/5G networks from three major operators and can be configured with dual-SIM card redundancy. When the primary card signal is weak, it automatically switches to the secondary card. If the public network is completely interrupted, short-distance data return can be achieved through low-power wide-area network (LPWAN) technologies such as LoRa. For example, a mountainous monitoring station adopted a "4G+LoRa" hybrid networking approach, increasing the data upload success rate to 98%.
VPN private network encryption: It supports encryption protocols such as IPSec and OpenVPN to ensure secure data transmission. For example, a chemical industrial park monitoring system encrypted and transmitted data to the environmental protection bureau platform through a VPN tunnel, preventing data leakage or tampering.
Local data processing: The USR-G809s has a built-in Python secondary development environment, supporting simple analyses such as data cleaning and threshold judgment at the router end. For example, when the water quality COD value exceeds a warning threshold, the router can trigger a local alarm light to flash and immediately upload the alert information to the cloud, shortening response times.
Protocol conversion capability: It supports industrial protocols such as Modbus RTU/TCP, OPC UA, and PPI, enabling seamless connection to monitoring equipment from different brands. For example, in a project, Siemens PLCs and Schneider electricity meters achieved protocol conversion through the router and were uniformly uploaded to an energy management platform, avoiding "data islands" caused by protocol incompatibility.
Remote operation and maintenance management: Through the USR Cloud platform, operation and maintenance personnel can remotely configure router parameters, upgrade firmware, and diagnose faults, reducing on-site maintenance visits. For example, a marine platform monitoring system remotely restarted the router through a 4G network to resolve interface loosening caused by humidity, reducing annual operation and maintenance costs by 40%.
Pain points:
Monitoring points are distributed along mountainous riverbanks, making mains power access difficult and solar power generation inefficient.
Weak 4G signals, high data upload delays, and no redundant links.
Solutions:
Deploy USR-G809s cellular routers, paired with solar power systems (monocrystalline silicon panels + lithium batteries), to achieve a "solar priority, battery backup" power supply mode through intelligent power management, extending equipment battery life to 7 days.
Adopt a "4G+LoRa" hybrid networking approach: The primary link uses 4G for data upload, and the backup link transmits critical data (such as COD exceedance alerts) via LoRa to nearby base stations, which then forward the data to the cloud.
Effects:
The data integrity rate increased from 65% to 99%, and the fault response time was shortened from 24 hours to 10 minutes.
Annual operation and maintenance costs were reduced by 35%, and the project passed the environmental protection bureau's acceptance and was awarded the title of "Demonstration Project."
Pain points:
Monitoring equipment from various brands (Siemens, Honeywell, Focused Photonics, etc.) with incompatible protocols.
Strong electromagnetic interference in the park causing frequent router crashes.
Solutions:
Deploy USR-G809s cellular routers, connect sensors from various brands via RS485 interfaces, and use protocol conversion functions to uniformly convert them to Modbus TCP protocol for upload to the platform.
The router adopts a metal casing and EMC Level 3 protection design, improving electromagnetic interference resistance by 50% and passing a -40℃~75℃ wide-temperature test to adapt to the extreme environment of the chemical industrial park.
Effects:
Equipment compatibility issues were completely resolved, and data collection efficiency increased by 80%.
The annual router failure rate decreased from 15% to 2%, earning the park's title of "Best Equipment Supplier."
| Parameter | USR-G809s | Traditional Cellular Router |
| Power Supply Range | DC9-60V wide-voltage input | Only supports 12V/24V fixed voltage |
| Communication Interfaces | 2 optical + 8 electrical ports + dual serial ports + dual SIM cards | Usually 4 electrical ports + single serial port + single SIM card |
| Protocol Support | Modbus RTU/TCP, OPC UA, PPI, etc | Only supports Modbus TCP |
| Edge Computing Capability | Python secondary development, supports local data processing | No development environment, only acts as a data forwarder |
| Environmental Adaptability | -40℃~75℃, EMC Level 3 protection | -20℃~60℃, EMC Level 2 protection |
Mountainous/river monitoring: Prioritize routers supporting LoRa or Beidou short messaging to solve signal coverage issues.
Chemical/metallurgical industrial parks: Choose routers with EMC Level 3 protection and explosion-proof certification to adapt to strong electromagnetic and flammable environments.
Marine/polar monitoring: Select routers with wide-temperature design (-40℃~85℃) and IP68 protection rating to resist salt spray and low temperatures.
The complexity of field environmental monitoring places stringent requirements on equipment power supply and communication. Cellular routers are upgrading from "data channels" to "intelligent hubs" through the integration of multi-energy management, multi-mode communication, and edge intelligence technologies, providing stable, efficient, and secure support for environmental monitoring systems. The USR-G809s cellular router has become the preferred solution for field monitoring projects due to its excellent environmental adaptability, rich interface and protocol support, and powerful edge computing capabilities.
