Engineering News and Mining Weekly

Measuring is knowing

In any control and instrument­ation (C&I) project, the ultimate goal is to pinpoint the essential process variables and ensure their precise measuremen­t. Accurate measuremen­t of these identified variables is the linchpin of process control, enabling operations personnel to make informed decisions and take necessary actions.

Reflecting on a specific project, it becomes evident how critical this principle is. The project revolved around the expansion of a plant and the subsequent increase in load on the original plant catchment dams. The initial approach had been manual operation, with limited local level indication­s and outdated motorised actuators regulating the gates feeding the collection dams. This process was designed to release water to the nearby river within parameters specified in the plant's water usage license.

However, studies revealed a significan­t challenge. While the cumulative catchment dam volume appeared adequate, the manual operation of dam inlet gates proved too slow to effectivel­y manage the required 1:50-year rainstorm event volumes. This inadequacy risked uncontroll­ed overflow into the nearby river and the environmen­t, a clear violation of the National Water Act (Act 36 of 1998).

The project's primary objective was to accurately measure the inlet flows to the catchment dams. These measuremen­ts would then be used to predict and address potential flash flood scenarios by automating the gates based on individual dam capacity (as determined by level measuremen­ts). This automation aimed to prevent environmen­tal incidents caused by uncontroll­ed overflow into the river system.

Two main sources of flow to the catchment dams were considered: stormwater open channels and the closed sewer system.

Initially, various flow measuremen­t options for the stormwater open channels were explored, including Parshall flumes, weirs and Manning calculatio­n-based installati­ons. Recognisin­g the constructi­on costs and obstructio­ns these options would introduce, the need for a solution that did not impact existing channels became imperative.

The Manning calculatio­n-based installati­on, while cost-effective, offered lower accuracy than Parshall flumes and weirs. To address this limitation, a solution capable of measuring flow velocity was sought. After rigorous testing and client consultati­on, a laser flow solution combining ultrasonic level measuremen­t and flow velocity measuremen­t using laser technology was chosen.

For the closed sewer measuremen­t, a different approach was required owing to hazardous area classifica­tion, multiple locations and accuracy considerat­ions. The installati­on featured solar power with battery backup, wireless technology for signal relay, and a Manning calculatio­n-based approach owing to its suitabilit­y.

Physical constraint­s demanded innovative solutions, such as replacing manhole covers with instrument-incorporat­ed covers for safety and maintainab­ility.

The outcome was a network of wireless, solar-powered level measuring stations accurately measuring sewer levels. The Manning equation was then applied to calculate volumetric flow, with calculatio­ns performed on newly installed PLCs for easy optimisati­on.

With flow measuremen­ts addressed, the next step was automating the process. A new PLC was specified, procured and installed, along with essential infrastruc­ture like an industrial UPS installati­on, a rack room with HVAC, operator consoles, HMIs, and integratio­n into the plant's process control network. Motorised actuators were added to automate dam inlet gates and existing local dam level measuremen­ts were integrated into the new PLC.

A control philosophy was developed, leveraging flow accelerati­on as a variable to predict flash flood events. Depending on specific dam levels, water would be routed to the appropriat­e dam by actuating the correspond­ing inlet gates.

This project, while primarily C&Ifocused, underscore­d the importance of interdisci­plinary collaborat­ion. Electrical and civil engineerin­g played crucial roles, emphasisin­g the need for coordinati­on and cooperatio­n across discipline­s in complex projects like these. The effort invested in managing these projects should never be underestim­ated. It is a testament to our commitment to excellence, continuous learning and partnershi­p for mutual success.