Remote monitoring of pipes, valves, tanks and vaults provides another path toward efficiency.
- By Curt Goldman
- Sep 01, 2009
Operations managers in the water and wastewater industry are looking for ways to be more efficient. Wireless remote monitoring can provide one option for corrosion control using existing supervisory control and data acquisition (SCADA) networks and automation.
Corrosion has the potential to affect the integrity of the roughly 2.3 million miles of pipe carrying water and wastewater and their corresponding valves, tanks, vaults, and structures. Many facilities use cathodic protection (CP) systems, but these are often in remote locations, making them difficult to operate and maintain, let alone push to peak performance. They also can be vulnerable to theft, land use disputes, and homeland security.
Remote monitoring of critical corrosion-prone infrastructure can help prevent the leaks, lost revenue, groundwater contamination, and other adverse scenarios affecting overall water quality, supply and public safety. Many facility managers are looking to new communications technologies – such as cell phone and satellite – to help provide answers to their remote pipeline monitoring issues. Unfortunately, ever changing cell phone technologies left facilities scrambling to stay ahead of telemetry obsolescence. Using satellite technology also limits facility options because of the lack of system ownership. In addition, homeland security issues are leading more managers to reconsider communications systems outside the firewall. Many have or are considering implementing their own systems in an effort to boost network protection of vital assets.
Systems using unlicensed frequency hopping spread spectrum (FHSS) wireless CP extend current technology, enabling more facilities to monitor more assets, more efficiently. FHSS, developed in the 1930s, is based on the concept that most radio frequencies are underutilized. It allows multiple users to simultaneously operate across a spectrum of frequencies. Effective, safe, trouble-free data communications exist when all radios within the network operate at the same frequency and then all hop to new frequencies at the same time and in the same hopping pattern. FreeWave Technologies introduced FHSS into cathodic protection in 2007. Its system automatically monitors and reports key corrosion protection, such as pipe-to-soil potential; rectifier output voltage, amperage, and rectifier input power status.
Key advantages of the system include:
- Minimal network interferences
- Maximum network security;
- System flexibility;
- Firewall protection;
- Data ownership;
- Open protocol communication; and
- Infinite repeatability.
- No monthly recurring costs needed to operate the system as in cellular and satellite technology.
These FHSS wireless field-located CP RMUs receive and record voltages, currents, and other IO data, which are then collected by a computer in a central office or through a SCADA system for operator evaluation. This data collection feature alerts operators to system requirements and enables them to keep critical equipment online. In addition, these RMUs track ambient temperature and, if connected to a solar power-generation system, will report back-up battery supply voltage.
Facilities that already own and operate a SCADA network can easily integrate remote monitoring devices through existing remote terminal units, programmable logic controllers, or radio networks. Those that don’t have SCADA can deploy, low-cost data logging software (see screen capture, left) readily available for less than the cost of a desktop computer.
Some manufacturers offer no-obligation, demonstrations of their remote
monitoring systems. A test drive is easy to implement by first selecting a half dozen test points and a central office location and providing the manufacturer or vendor with site coordinates. For these demonstrations, data can either be collected using the data logger software or coordinated with a CP RMU provider that can help design a plan to integrate the equipment into existing SCADA architecture.
Normal test drive intervals depend on the size and type of system; however, 30/60/90-day demonstrations are not uncommon.
A large municipal water company recently deployed a new advancement in spread spectrum wireless data communication technology, which holds the promise of robust, cost-effective remote monitoring. Leveraging existing SCADA infrastructure, it hopes to extend remote monitoring to critical CP systems as well.