DuPont & EnTech Use VisSim/Real Time for Dynamic Process Control Simulation

Authors: Extracted from a paper by Hank Graeser (DuPont) and Andy Waite (EnTech)

In a joint effort, engineers from E. I. DuPont de Nemours and EnTech Control Engineering used Visual Solutions' VisSim control system design software, and its real-time option VisSim/Real-Time, to develop a high-fidelity dynamic simulation model of DuPont's non-woven sheet manufacturing facility in Richmond, Virginia.

The model consists of approximately 31,500 blocks and 250 differential equations and simulates roughly a half dozen interrelated processes. It is used by DuPont's control and design engineers to verify process dynamics during product transitions; develop and tune control strategies; and explore possible design changes to enhance control performance. In addition, system operators train on the model to maintain proficiency and learn new procedures without impacting plant operations.

"High Fidelity modeling of a large scale project can be done with VisSim. From a financial standpoint, itís extremely worthwhile to the process control community. There are tremendous cost savings in reduced downtime due to offline tuning and control design as well as operator training."

According to Hank Graeser, senior engineer at DuPont,"VisSim is a highly intuitive environment for developing large scale high-fidelity process models. The DuPont Spruance model, developed in VisSim, has saved the company an estimated one million dollars to date.We developed the model in a third of the time it would normally take using conventional methods. VisSim's block diagram interface made it easy to document and maintain the model.Every time we use the model for control design and off-line tuning, DuPont saves significant dollars as plant down time is reduced. We also train our operators using the VisSim model."

Aerial view of the DuPont non-woven sheet manufacturing facility in Richmond, Virginia.

DuPont paper machine simulation in VisSim, showing Reel scanner trends. Reel scanner position, reel ash, dry weight, and moisture scan averages are displayed.

The Ideal Simulation Software As DuPont engineers drew up the specifications for the model, EnTech engineers were tasked with finding the best simulation software with which to build it.

The sheer scope of the model, which included the entire DuPont facility 15 tanks; 20 sets of pumps, lines, and valves; refiners; headbox and drainage table; vacuum devices, dryer cylinders, and scanning sensors; and other minutiaewarranted a simulation software package capable of modeling and simulating large, multivariable dynamic processes with a high degree of fidelity.

The software had to be interactive and graphically oriented so that dynamic information could be presented in an intuitive manner. In addition, the block set had to include a complete selection of continuous, discrete, transfer function, Boolean, arithmetic, and I/O blocks.

Other key requirements included the capability to run in simulated time, real time, and continuous time; drive real-time analog and digital I/O; stop and continue simulations; initialize all state variables; and extend the block set with custom blocks written in C, for enhanced speed and additional functionality.

Because system operators would also use the simulation model for training purposes, the ability to create realistic control panels with controller faceplates, dynamic tank levels, and built-in alarms was also important.

Based on these requirements, the simulation software that best met EnTech's needs was VisSim and the VisSim/Real-Time companion software.

These "algebraic loops" involve the on-line iteration from the last known flow and are solved using algebraic loop time constants of typically 1 second, which provides an adequate safety margin compared to the high-fidelity specification of 3 seconds.

In the resulting simulation, the time constant spread ranges from a fast value of 1 second to that of the mixing time constant for some tanks of 20 minutes. This time constant spread, even though quite large, means that the simulation avoids some of the pitfalls of "stiff systems of differential equations" which are very difficult to solve numerically.

The final simulation model is organized in a multi-layer format in which detailed simulation subelements collapse into "compound blocks." There are 900 compound blocks, in about six layers, organized in an easy-to-follow, process-oriented layout.

Predicting The Future
The DuPont model is an excellent example of how a dynamic multivariable process control model can be developed and utilized using VisSim and VisSim/Real-Time. Graeser and other DuPont engineers have observed a "close match" between model and actual plant data. Based on these results, they are confident that the DuPont model can be used as a "life-cycle" tool to faithfully predict the effects of future design decisions before modifications are actually made to the plant.

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