Continuous flow reactors are specialized laboratory reactors that continuously flow reagents through a reaction vessel rather than relying on batch processing. There are numerous types of continuous reactors available including tubular reactors, continuous stirred tank reactors (CSTR reactors), and plug flow reactors. Continuous flow reactors provide increased safety and reproducibility of reactions with their precise control over reaction parameters such as temperature, pressure, and residence time. Continuous reactors also allow for an increase in throughput since their continuous reaction allows for the production of large quantities of product. When comparing continuous reactors be sure to compare flow rates as this can affect residence time and reaction kinetics. Many models of continuous reactors also offer various interfacing options and inline monitoring capabilities with built-in alarms to monitor your reactions.
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| Company | Parr Instrument Company | Parr Instrument Company |
| Item | Continuous Flow Tubular Reactor with Touchscreen Control | 5400 Continuous Flow Tubular Reactors |
| Reviews | | |
| Catalog Number | 5420 | 5401 / 5402 / 5403 / 5404 |
| Price | | |
| Description | Parr's new Continuous Flow Tubular Reactor with Touchscreen Control was designed with researchers in mind. In addition to accommodating Parr's standard line of 5400 Tubular Reactors, it offers a compact footprint, easy set-up, and integrated touchscreen control with alarm interlocks. Whether for Parr's new Continuous Flow Tubular Reactor with Touchscreen Control was designed with researchers in mind. In addition to accommodating Parr's standard line of 5400 Tubular Reactors, it offers a compact footprint, easy set-up, and integrated touchscreen control with alarm interlocks. Whether for production, research, or teaching unit operations, this system has an impressive collection of capabilities, all at a budget-friendly price.
Features include: - Capacity for use of traditional or non-traditional solid catalysts
- Reactor ID's from 1/4" to 1.5" (7 to 38 mm), with length to 24" (600 mm)
- Pressure ratings to 5000 psi (345 bar)
- Temperature ratings to 550 °C
- Gas and Liquid Feeds, Pressure control, Condenser, and Gas/Liquid Separator
- Touchscreen with PID temperature control, gas and liquid feed control, and full data logging with integrated alarm interlocks
- Fully assembled and ready to operate out of the box
... Read More | Single-phase flow in a tubular reactor can be upward or downward. Two-phase flow can be co-current up-flow, counter-current (liquid down, gas up) or, most commonly, co-current down-flow.
Tubular reactors can have a single wall and be heated with an external furnace or they can be jacketed for Single-phase flow in a tubular reactor can be upward or downward. Two-phase flow can be co-current up-flow, counter-current (liquid down, gas up) or, most commonly, co-current down-flow.
Tubular reactors can have a single wall and be heated with an external furnace or they can be jacketed for heating or cooling with a circulating heat transfer fluid. External furnaces can be rigid, split-tube heaters or be flexible mantle heaters. Tubular reactors are used in a variety of industries: - Petroleum
- Petrochemical
- Polymer
- Pharmaceutical
- Waste Treatment
- Specialty Chemical
- Alternative Energy
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| Temperature Range | up to 550 °C | up to 550C |
| Pressure Range | up to 5000 psi | up to 3000 psi |
| Type | Continuous Flow Tubular | Continuous flow Tubular (Pipe, Packed-bed, Trickle-bed, Bubble-column, Ebulating-bed) |
| Interior Dimensions | Reactor ID's from 1/4" to 1.5" | 1/2" to 1.5" |
| Reactions | Inquire | Carboylation, Dehydrogenation, Hydrogenation, Hydrocracking, Hydroformulation, Oxidative decomposition, Partial oxidation, Polymerization, Reforming |
| Applications | Carbonylation, Dehydrogenation, Hydrogenation, Hydrocracking, Hydroformulation, Oxidative decomposition, Partial oxidation, Polymerization, and Reforming | Carbonylation, Dehydrogenation, Hydrogenation, Hydrocracking, Hydroformulation, Oxidative decomposition, Partial oxidation, Polymerization, and Reforming |
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