The subject matter of the invention is a device for the hydrolysis of at least one compound. The device comprises a first cylindrical section having a diameter D.sub.max, a central duct, an outer duct which surrounds the central duct coaxially, an outlet having a diameter D.sub.A, and a second section which tapers towards the outlet and into which the ducts issue. The second section has, in cross-section along a longitudinal axis A.sub.L of the device, a profile which is described by two radii R1 and R2 which merge tangentially into each other, where 0.2<R1/D.sub.A<4.0 and 0.3<R2/D.sub.A<5.0. The invention also relates to a method for the hydrolysis of at least one compound. In the method, the device is used to conduct water at least through the outer duct and to conduct the compound to be hydrolysed through the central duct and/or through at least one intermediate duct and to mix them with each other at least partially in the second section. The compound and the water are in liquid form.

A reactor includes: a heat exchange section including: a first flow channel configured to flow a reaction fluid and a second flow channel configured to flow a heat medium; an introduction path for a temperature sensor, extending from an insertion opening provided on a side surface of the heat exchange section to the first flow channel or the second flow channel; a pipe for a temperature sensor, connected to a side surface of the heat exchange section and communicating with the introduction path through the insertion opening; and a jig provided in the pipe. The jig is provided with a guide hole extending from the base end toward the tip end and opened toward the insertion opening of the introduction path. The guide hole is provided with a tapered hole directed from the base end toward the tip end.

Heterogeneous catalytic reactors and methods of their use. The reactors include heat transfer features that help establish a temperature gradient along an axial length of the reactors during use. The inventive reactors also include two or more different species of catalyst materials that are arranged within the reactors such that a given species of catalyst material is positioned at a temperature that will provide for improved or optimal catalytic performance.

The subject matter of the invention is a device for the hydrolysis of at least one compound. The device comprises a first cylindrical section having a diameter D.sub.max, a central duct, an outer duct which surrounds the central duct coaxially, an outlet having a diameter D.sub.A, and a second section which tapers towards the outlet and into which the ducts issue. The second section has, in cross-section along a longitudinal axis A.sub.L of the device, a profile which is described by two radii R1 and R2 which merge tangentially into each other, where 0.2<R1/D.sub.A<4.0 and 0.3<R2/D.sub.A<5.0. The invention also relates to a method for the hydrolysis of at least one compound. In the method, the device is used to conduct water at least through the outer duct and to conduct the compound to be hydrolysed through the central duct and/or through at least one intermediate duct and to mix them with each other at least partially in the second section. The compound and the water are in liquid form.

A chemical reactor for use in a chemical process wherein a reactant and/or a target product is prone to produce undesirable byproducts through secondary reactions. The reactor is configured with a first flow passage for passing a flow of an overly reactive reactant; a permeable first wall for controlled flow of the overly reactive reactant into a second flow passage providing a flow of a second reactant; a permeable second wall having a catalyst supported on an inner surface thereof for catalyzing reaction of the reactants flowing in the second flow passage; the permeable second wall passing through a flow containing the target product; and a non-permeable third wall defining a third flow passage for exiting the product mixture. The reactor can be employed in selective oxidation, oxidative dehydrogenation, and alkylation processes to reduce the formation of byproducts.

Chemical processors are configured to reduce mass, work in conjunction with solar concentrators, and/or house porous inserts in microchannel or mesochannel devices made by additive manufacturing. Methods of making chemical processors containing porous inserts by additive manufacturing are also disclosed.

A method for conveying a reaction tube unit including a vertical reaction tube and a gas supply pipe provided at a distance from an inner wall of the vertical reaction tube along a longitudinal direction thereof, the method includes: arranging a buffer inside the reaction tube between the inner wall and the gas supply pipe to alleviate a collision; placing the reaction tube unit attached with the buffer on a carriage via a vibration isolator; and conveying the reaction tube unit by moving the carriage.

A sequestration system includes: an electrolysis part having an electrolysis cell having an anode, a cathode, an anode flow path facing on the anode, and a cathode flow path facing on the cathode; and a reaction part configured to switch a first operation and a second operation, the first operation including producing solid carbon using a catalyst from a first raw material containing a first fluid to be introduced from the cathode flow path, and the second operation including performing a reaction of a second raw material containing a second fluid to be introduced from the anode flow path and solid carbon to be deposited on the catalyst to remove at least a part of the deposited solid carbon from the catalyst.

A method for conveying a reaction tube unit including a vertical reaction tube and a gas supply pipe provided at a distance from an inner wall of the vertical reaction tube along a longitudinal direction thereof, the method includes: arranging a buffer inside the reaction tube between the inner wall and the gas supply pipe to alleviate a collision; placing the reaction tube unit attached with the buffer on a carriage via a vibration isolator; and conveying the reaction tube unit by moving the carriage.

This disclosure provides a method for quantum dots ligand exchanges and an apparatus of the same. The method includes providing a first ligand modified quantum dot, a second ligand and a first polymer. The method includes mixing the first ligand modified quantum dot, the second ligand and the first polymer in a solvent to perform the first ligand exchange, so as to obtain a second modified quantum dot. The first polymer contains a first functional group, which can have a first reaction with the first ligand, but do not react with the second ligand under the same conditions.