The invention relates to a method for producing a pellet, in particular for a catalytic convertor and/or static mixer. The method comprises a trimming and/or deforming of at least one layer of metal foam material into a pellet shape.

The present invention relates to a plant for oligomerizing ethylene to produce oligomerized alpha-olefins, with production of a fouling by-product in the form of a deposit, said plant comprising a reaction section comprising: —a reactor (c) for two-phase gas/liquid or single-phase all-liquid oligomerization proceeding from an optional solvent, an oligomerization catalyst and ethylene, and —cooling means associated with said reactor in the form of at least one cooling circuit external to the reactor and/or in the form of a jacket of the walls of the reactor. Packings are disposed in the reaction section in order to increase the contact surface area per unit volume that is accessible to the deposition of the byproduct.

The present invention relates to a plant for oligomerizing ethylene to produce oligomerized alpha-olefins, with production of a fouling by-product in the form of a deposit, said plant comprising a reaction section comprising: —a reactor (c) for two-phase gas/liquid or single-phase all-liquid oligomerization proceeding from an optional solvent, an oligomerization catalyst and ethylene, and —cooling means associated with said reactor in the form of at least one cooling circuit external to the reactor and/or in the form of a jacket of the walls of the reactor. Packings are disposed in the reaction section in order to increase the contact surface area per unit volume that is accessible to the deposition of the byproduct.

A packing element for use in a heat exchange or mass transfer tower includes a barrel and a plurality of fins spaced around a circumference of the barrel, each fin having a height approximately equal to a height of the barrel and a length extending radially from the barrel, a proximate end of each fin attached perpendicularly to the barrel. A protrusion extends outward from the distal end or each fin along its height. A method for mass transfer includes passing fluids through a vessel packed with randomly arranged packing elements.

A packing element for use in a heat exchange or mass transfer tower includes a barrel and a plurality of fins spaced around a circumference of the barrel, each fin having a height approximately equal to a height of the barrel and a length extending radially from the barrel, a proximate end of each fin attached perpendicularly to the barrel. A protrusion extends outward from the distal end or each fin along its height. A method for mass transfer includes passing fluids through a vessel packed with randomly arranged packing elements.

The invention relates to a catalyst filling, comprising a first layer of a planar catalyst material and a second layer of a planar catalyst material lying over said first layer, wherein the catalyst material of the first layer comprises at least two plates, which butt against each other to form an abutment edge in each case, wherein the catalyst material of the second layer comprises at least two plates, which butt against each other to form an abutment edge in each case, and wherein the plates of the second layer are designed and/or arranged relative to the plates of the first layer in such a way that the abutment edge or abutment edges of the second layer are not aligned with the abutment edge or abutment edges of the first layer.

Mechanical stirred bed reactors that incorporate a screen are described. Methods of using such reactors to process perfluoropolymers to form perfluorinated olefin monomers are also described. The reactors and methods may be used to upcycle filled perfluorinated materials.

Steam-hydrocarbon reforming reactor with a reformer tube containing ceramic-supported catalyst pellets and metal foam particles. The ceramic-supported catalyst pellets have a porous support comprising one or more of alumina, calcium aluminate, and magnesium aluminate. The metal foam particles comprise Fe and/or Ni. The ceramic-supported catalyst pellets and metal foam particles may be layered or interspersed.

An equal temperature fractional distillation chamber allows for more precise distillation by providing solid particulate matter with air spaces, such as Raschig rings, to radiate heat from the bottom of the chamber to an area where the vapors are separated. This area is unencumbered by Raschig rings or other devices and can be reduced in size, as necessary, to be less than 20% or 10% of the vertical height of the chamber. Further, a distillation key can enter from the top of the chamber and come down into the chamber with rings which encourage condensation of vapors which rise upwards. In this manner, a very controlled and accurate distillation can be achieved due to the higher heat capacity of the glass or other materials around the unencumbered region.

An equal temperature fractional distillation chamber allows for more precise distillation by providing solid particulate matter with air spaces, such as Raschig rings, to radiate heat from the bottom of the chamber to an area where the vapors are separated. This area is unencumbered by Raschig rings or other devices and can be reduced in size, as necessary, to be less than 20% or 10% of the vertical height of the chamber. Further, a distillation key can enter from the top of the chamber and come down into the chamber with rings which encourage condensation of vapors which rise upwards. In this manner, a very controlled and accurate distillation can be achieved due to the higher heat capacity of the glass or other materials around the unencumbered region.