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Activated carbon decolorization, fast and without filtration

Activated carbon is a common choice for removing impurities or capturing compounds from a product batch. However, the carbon may itself foul the product and be difficult to separate. The rotating bed reactor offers a clean way to deploy activated carbon that removes the need for time-consuming filtration and extends the lifetime of the solid phase.  

Flexible deployment with the plug-in rotating bed reactor

The rotating bed reactor (RBR) is a combined tool for chemical transformations and liquid transfer operations, reducing or eliminating the need for external pumps. Filled with a catalyst or adsorbent, and rotated by a motor, the RBR brings the liquid to be processed in contact with the solid-phase at high flow rates. Due to the high flow rate generated, the RBR can not only treat the liquid in the reaction vessel, but also transfer it into the vessel for processing.

Automatic processes for efficient production

Automation of large-scale processes is often a requirement for economically viable chemical processes. The benefits of scale are best harvested at high throughputs and 24/7 operation. This leads to the demand for process automation, and the elimination of hands-on work.

Dramatically improved deionization with a rotating bed reactor

Removing ions from liquids is common in industry and society. Ions are remediated in applications ranging from the production of pharmaceuticals to the treatment of communal waste streams. Likewise, the nuclear energy sector deals with the removal of ionic radioactive substances from water on a daily basis.

Decolourization more efficient in rotating bed reactor than in fixed bed reactor

A fixed bed reactor (FBR), also known as a packed bed reactor or column, is a traditional technology for processes such as adsorption or heterogeneous catalysis. Achieving the required level of purification or conversion means running the liquid through the reactor at a sufficiently low flow rate, and the throughput of a fixed bed reactor is therefore often limited.

Rotating bed reactor faster than stirred tank reactor for a mass transfer limited reaction

Mass transfer limited reactions can create problems for applications like the synthesis of chemical products or the manufacture of active pharmaceutical ingredients. Poor yields, high side-product formation or impractically long reactions are potential issues. Efficient reactor design can greatly improve the mass transfer and remove the limitation to a minimum.

High-viscosity applications made faster

Liquids with high viscosity create problems for heterogeneous applications in traditional reactors. Packed bed reactors (columns) suffer from huge back pressures, and stirred tank reactors (STR) exhibit reduced reaction rates due to poor mixing. Both issues lead to longer processing times and expensive operations.

Processing an IBC with a rotating bed reactor

The IBC, also called “tote”, is a common storage container in many industries. In a chemical manufacturing plant or a waste treatment facility there might be hundreds of these or more, with a capacity of approximately 1,000 liters (275 gallons). Whether they are filled with raw material, finished product or waste, the transfer of liquids to and from IBCs can be cumbersome or even hazardous.

Removing organic molecules from large volumes of water

Organic molecules contaminate many products and waste streams, and are a common target for remediation. Activated carbon is a widely used adsorbent to capture organic molecules from aqueous solutions (like wastewater), and offers a very wide range of applications thanks to its unspecific method of adsorption. At the same time, activated carbon can cause fouling of another kind by the particles breaking down into smaller fines. This dust-like material is very cumbersome to remove from the liquid afterwards.

Improving reactions in emulsions using a rotating bed reactor

When working with an emulsion (and particularly with a heterogeneous catalyst) the mass transfer between the phases is critical. Insufficient mixing leads to lower interfacial area per volume, and in turn to poor mass transfer across the phases.

In-tank deployment of large scale rotating bed reactor

How can this process be scaled up? This is perhaps the most important question to consider when developing a chemical process. If it cannot be done on large scale, all the time and resources invested in laboratory work will be unrewarded. Pumping liquids through massive columns or separating solids from a large batch can be unsurmountable challenges that bring a halt to a new project before it has even left the starting blocks.

Mass transfer revolutionized

The SpinChem rotating bed reactor (RBR) can eliminate poor mass transfer in heterogeneous reactions during chemical syntheses and biotransformations, preserve catalyst activity, and facilitate recycling of solid phases. This brochure presents our technology and its applications.

Pesticide remediation in extracts and oils

Pesticide residue can ruin a batch of a botanical extract, creating large problems for producers. Curated adsorbents, specifically chosen for your situation, can be used to remediate the pesticides. With a rotating bed reactor, you are equipped to respond to contaminants showing up on your test results.

Recycling of immobilized enzymes using rotating bed reactor technology

Biocatalysis is a useful method for the synthesis of small chiral molecules, offering new possibilities for the synthesis of active pharmaceutical ingredients and other compounds. The rotating bed reactor has been established as an efficient way to deploy enzymes in production as well as research and development.

Rotating bed reactor for immobilized enzymatic reactions

In pharmaceutical manufacturing and other industries, traditional methods are burdened by unsustainable use of solvents and transition metal catalysts. The use of enzymes is pursued as an alternative, offering greener synthetic routes and better results due to improved specificity. However, enzymes are costly and reusing them for many cycles is practically a requirement for process economy. This essentially means that the enzymes must be immobilized on a solid support so that they can be separated from the product.

Rotating bed reactors completely avoid grinding of molecular sieves

When using of solid-phase catalysts or adsorbents in reactors, the physical degradation of the materials is a common problem. The traditional stirred tank reactor inflicts mechanical damage to the particles, which causes attrition, fines that are difficult to separate, and loss of the functionality of the solid-phase.

Simple scale-up using flexible reactors

Research and development quickly takes new directions, and the requirements on a laboratory may vary with every new project. Limiting yourself to equipment with a narrow scope of conditions and applications may become expensive, since new equipment must be acquired for anything out of scope. With budgets quickly consumed by other projects, the need for new equipment may mean significant delays and a reduced capability to take on emerging opportunities.

Treatment of Viscous Solutions in a Mettler-Toledo EasyMax™ 102

Heterogeneous reactions involving viscous solutions put high demands on equipment and materials. Columns face high pressure drops and require powerful pumps and durable solid phase particles. Stirred tank reactors do not face the same problem, but the high liquid viscosity and low particle density will have a negative impact on reaction kinetics and require tedious filtration to separate the solids afterwards.

Heavy metal remediation in extracts and oils

Plants accumulate heavy metals from the soil in which they grow, and consequently the metals are found in any extracts produced from them. If the soil contains high levels of heavy metals, the resulting concentrate may be unfit for human consumption, and need remediation.

Lipase-catalyzed hydrolysis in 750 L using a rotating bed reactor

Biocatalysis offers many benefits in the production of chemicals and active pharmaceutical ingredients. One major challenge has been the deployment of immobilized enzymes in an efficient way on large scale. The rotating bed reactor offers a convenient way to scale a biocatalytic process.

How the loading of solids influences reaction speed

Sometimes you don’t want to pack the entire rotating bed reactor full with your solid-phase material. Fully loading might simply be wasteful, or you may want to experiment with your reaction conditions. But how does the amount of solids in the rotating bed reactor influence the reaction performance? Can you use only 10% of the full capacity?

Phenol scavenging using ion-exchange resin

Scavenging of soluble undesirable compounds and substances onto solid phase is used in a wide range of applications. In this example, a rotating bed reactor (RBR) is used to capture low concentrations of a phenol onto readily available Strong Anion Exchange (SAX) resin as a scavenger.

A molecular structure representation symbolizing biocatalysis and heterogeneous chemical reactions in industrial enzyme systems.

Cellulose-bead immobilized enzymes as biodegradable and renewable catalysts

Environmentally benign and safe synthesis is enabled by highly active biocatalysts. To bolster economic and ecological aspects, catalyst reuse is essential and achieved by heterogenization of otherwise soluble enzymes onto solid supports. Here, this is demonstrated on novel renewable and non-polluting cellulose beads.