Real-time plug-flow reactor dynamics
Adjustable feed flow, feed concentration, and feed/coolant temperature with live closed-loop response.

PiReact-T is a real-time tubular (plug-flow) reactor simulator that models the reaction and thermal dynamics of chemistry moving through a tubular reactor. Built by PiControl Solutions, PiReact-T is process control simulation software for chemical engineering students, process and control engineers, DCS/PLC technicians, and researchers. It reproduces residence time, reaction kinetics, and the axial temperature profile along the tube in real time, so users can change feed rate, feed composition, and coolant conditions and watch the reactor respond exactly as a plant unit would.
Tubular reactors run some of the least forgiving chemistry in a plant: cracking, polymerization, and other exothermic reactions where a mismanaged feed or coolant upset can build a hot spot that runs away in seconds. PiReact-T lets engineers watch that hot spot form, move along the tube, and collapse on a simulator first, building the reaction-kinetics and thermal-profile intuition needed before anyone touches a live reactor.
PiReact-T simulates the real-time dynamics of a tubular (plug-flow) reactor — residence time, reaction kinetics, and the axial temperature profile along the tube — so engineers can observe hot-spot formation, conversion, and thermal-runaway risk under realistic plant conditions. PiReact-T runs on standard Windows hardware, requires no DCS hardware, and ships with pre-built reactor configurations plus a custom-reactor builder for matching specific plant geometry and chemistry. Because it models the same reaction-engineering concepts used in advanced process control work, the skills transfer directly from simulator to plant.
Adjustable feed flow, feed concentration, and feed/coolant temperature with live closed-loop response.
Watch hot-spot formation and movement along the length of the tube in real time.
Arrhenius rate expressions, reaction order, and heat of reaction for different chemistries.
Define tube length, diameter, jacket cooling, and catalyst loading to match real plant geometry.
Feed flow, feed and coolant temperature, and conversion in a layout familiar to plant operators.
Operator-facing interface for international training programs.
Industrial plants use PiReact-T to train process and control engineers, and DCS/PLC technicians, on tubular reactor behavior before they operate or tune controls on a live reactor. Because PiReact-T reproduces hot-spot formation and thermal-runaway risk in real time, engineers build the intuition needed to recognize a developing upset within industrial process control systems.
Engineering colleges and universities use PiReact-T to teach chemical reaction engineering, residence time distribution, and reactor design in undergraduate and graduate process control courses. PiReact-T replaces static plug-flow design equations with hands-on, real-time simulator practice, and it has been adopted by chemical engineering departments teaching reaction engineering worldwide.
PiReact-T's feature set is built for one outcome: engineers who can recognize and respond to reactor thermal risk before it becomes a real one.
Simulates residence time, reaction rate, and heat release in real time as feed and coolant conditions change.
Reflects actual reactor timing, so engineers see conversion and temperature response the way it occurs in the plant, not as a static design curve.
Live view of temperature along the full length of the tube, including hot-spot location and magnitude.
Makes an otherwise invisible thermal risk visible, the core skill for recognizing a developing runaway before it happens.
Arrhenius rate constants, activation energy, reaction order, and heat of reaction, adjustable per exercise.
Lets instructors and trainers reproduce the specific chemistry an engineer will actually operate.
Define tube length, diameter, jacket cooling arrangement, and catalyst loading.
Matches simulated reactor geometry to real plant equipment for site-specific training.
Feed flow, feed and coolant temperature, and conversion in an operator-familiar layout.
Removes the interface learning curve, so trainees focus on reactor behavior, not navigation.
Operator-facing interface in multiple languages.
Supports international plant operations and global training programs.
Tubular reactor design is usually taught with steady-state plug-flow equations: conversion as a function of residence time, solved once, for one set of conditions. Real reactors do not stay at steady state. Feed-rate swings, catalyst deactivation, and coolant upsets move the hot spot along the tube in real time, and the exothermic chemistries that run in tubular reactors, cracking and polymerization among them, can go from stable to runaway in the time it takes to read a trend screen.
A plug-flow design equation gives one conversion number for one residence time. It never shows how a hot spot forms, moves, or grows when feed or coolant conditions change, the behavior that actually determines whether a reactor stays safe.
Arrhenius rate expressions and heat-of-reaction terms are just numbers in a textbook problem until an engineer sees the exotherm accelerate in real time and has to respond before it runs away.
OJT on a production tubular reactor means learning hot-spot response on equipment where a mismanaged upset can mean off-spec product, a safety trip, or worse. Plants would rather that learning curve happen somewhere else.
PiReact-T removes the structural problem: real-time reaction and thermal dynamics, a visible axial temperature profile, and no production reactor at risk.
PiReact-T is one of several real-time unit operation simulators PiControl builds for reactor, column, and heat-transfer training — pair it with simulators for the equipment your reactor feeds and follows.
Downstream of many tubular reactors is a distillation column. PiDistill models continuous distillation column dynamics, tray hydraulics, and reboiler/condenser response, so engineers can train on the full reaction-to-separation train.
Reactor effluent almost always passes through a heat exchanger network before it reaches storage or the next unit. PiHEx simulates multi-unit heat exchanger networks with cross-coupling between hot and cold streams.
Once engineers understand reactor behavior in PiReact-T, SIMCET builds the PID tuning skill needed to actually control the temperature and flow loops on that reactor, with a testing-and-grading module for certification.
Engineers train on PiReact-T across every sector PiControl serves — each runs different reactor chemistry, and PiReact-T's custom reactor builder reproduces the exact tube geometry and kinetics their own plant runs.
PiReact-T is deployed in industrial plants and engineering colleges across 40+ countries, part of the same PiControl simulator family used for reactor, column, and heat-transfer training worldwide. Read more in our customer success stories.
Request the PiReact-T installer and licensing details for your plant or department.
See PiReact-T run in real time and watch a hot spot form and respond to a coolant change live. A PiControl engineer will demonstrate the simulator on reactor dynamics relevant to your plant or curriculum, and map out a training path for your team.