QRP Plug Flow Reactor for QR

PLUG FLOW REACTOR FOR QR - QRP

創新系統

The Plug Flow Reactor for QR, "QRP", designed by EDIBON, allows studying and investigating the kinetics of reactions and flow behavior in chemical systems. A plug flow reactor is a type of tubular reactor that assumes the assumption of no axial mixing of components along its length.

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一般說明

The Plug Flow Reactor for QR, "QRP", designed by EDIBON, allows studying and investigating the kinetics of reactions and flow behavior in chemical systems. A plug flow reactor is a type of tubular reactor that assumes the assumption of no axial mixing of components along its length.

This type of reactor requires the application of a series of specific formulas over a volume differential instead of over the total volume, as is the case with perfectly mixed reactors. This reactor enables the determination of key kinetic equations, such as the basic hydrolysis of ethyl acetate, which is fundamental for the design and optimization of industrial processes. It facilitates comparative analysis between theoretical and experimental conversion values, enhancing understanding of chemical processes. Additionally, it examines the effect of flow rate and feed concentration on reaction efficiency and selectivity. Its ability to investigate the influence of temperature on laminar flow characterization is essential for optimizing chemical processes under variable conditions.

Furthermore, it studies the reactor’s response to disturbances, such as pulses and step changes, providing vital information for the design and control of industrial chemical processes.

In summary, the piston flow reactor enables a wide range of practices and experiments, making it an invaluable tool for researchers, educators, and industry professionals seeking to understand and optimize complex chemical processes.

To work with this reactor, the Base and Service Unit, "QUS", is required, which supplies the necessary reagents and thermostatic water for proper operation.

練習和指導練習

手册中包含的指导实践练习

  1. Determination of the residence time distribution of the reactor.
  2. Effect of flow rate and feed concentration on the determination of flow pattern.
  3. Study of the reactor response to different perturbations: step and pulse change.
  4. Effect of flow rate and feed concentration on the steady state conversion.
  5. Demonstration of the flow pattern in the reactor and comparison with the theoretical model.
  6. Determination of the steady state conversion of a second order reaction.
  7. Understanding the principles of tracer techniques in flow pattern characterisation.
  8. Conductivity measurement system: conductimeter.

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