An equipment for the production of bicarbonates is provided. It has a reactor tank, a safety valve, a manometer, an electric engine, a solute feeding pipe, a water inflow spigot, gas inflow spigot, a propeller, a sampling pipe with spigot, an outflow pipe, a support structure and cooling cladding located around the cylindrical part of the equipment. Also disclosed is an embodiment of the above-mentioned equipment having a solute hoisting system comprising a micronized carbonate powder stock, a conveyor belt for feeding the powder to the semi-automatic electric scale, an electric engine for the conveyor belt, a metal support structure, a conveyor belt for feeding the weighed powder to the reactor, an electric engine for the conveyor belt.

In various embodiments, a microreactor features a corrosion-resistant microchannel network encased within a thermally conductive matrix material that may define therewithin one or more hollow heat-exchange conduits.

A continuous chemical reactor may include a primary reaction unit and at least one secondary reaction unit. The primary reaction unit has a stirring device and a first temperature regulating device, and a feed inlet provided at an upper portion thereof. The secondary reaction unit is sleeved outside the primary reaction unit, and a reaction chamber is formed therebetween. By adding reaction materials to the primary reaction unit via the feed inlet and adjusting the temperature of the reaction materials by the first temperature regulating device, the reacted materials enter the reaction chamber, and the heat generated in the reaction chamber can be used to adjust the temperature of the materials in the primary reaction unit to more effectively use the heat, and the product after reaction can be discharged from a discharge hole at the lower end of the secondary reaction unit, thereby achieving continuous production.

A synthesis process comprising steam reforming a gaseous hydrocarbon feedstock (11); exothermically reacting the resulting synthesis gas; removing heat from said exothermal reaction by producing steam (32); using said steam as heat input to the steam reforming, wherein the steam reforming comprises: a) forming a mixture (30) containing steam and hydrocarbons by at least the step of adding a first stream of water (26) to the hydrocarbon feedstock (11); b) heating said mixture (30) by indirect heat exchange with synthesis gas; c) reforming said mixture after said heating step b).

A reactor for performing a gas/liquid biphasic high-pressure reaction with a foaming medium, comprising an interior formed by a cylindrical, vertically oriented elongate shell, a bottom and a cap, wherein the interior is divided by internals into a backmixed zone and a zone of limited backmixing, wherein the backmixed zone and the zone of limited backmixing are consecutively traversable by the reaction mixture, wherein the backmixed zone comprises means for introducing gas and liquid and a gas outlet and also comprises at least one mixing apparatus selected from a stirrer, a jet nozzle and means for injecting the gas, and the zone of limited backmixing comprises a reaction product outlet, a first cylindrical internal element which in the interior extends in the longitudinal direction of the reactor and which delimits the zone of limited backmixing from the backmixed zone, backmixing-preventing second internal elements in the form of random packings, structured packings or liquid-permeable trays arranged in the zone of limited backmixing and a riser tube whose lower end is arranged within the backmixed zone and whose upper end opens into the zone of limited backmixing so that liquid from the backmixed zone can ascend into the zone of limited backmixing via the riser tube, wherein flow into the zone of limited backmixing enters from below. The reactor is configured such that the high-pressure reaction space is optimally utilized and contamination of workup steps or subsequent reactions arranged downstream of the high-pressure reaction with foam is substantially avoided. The invention further relates to a process for performing a continuous gas/liquid biphasic high-pressure reaction in the reactor.

In various embodiments, a microreactor features a corrosion-resistant microchannel network encased within a thermally conductive matrix material that may define therewithin one or more hollow heat-exchange conduits.

Methods for liquefaction of carbonaceous materials, including methods that use electromagnetic radiation. Systems for liquefaction of carbonaceous materials. The systems may include a circulation conduit for mixing reactants, and/or a heating apparatus that relies on electromagnetic radiation.

An apparatus (10) and the use thereof for preheating at least one fluid are proposed. The apparatus (10) has a solid heating body (12). Channels (16) for passage of the fluid are formed in the heating body (12). The heating body (12) is heatable. The heating body (12) is designed to heat the fluid to a target temperature within a target time, wherein the target temperature is at least a temperature at which a predetermined chemical reaction of the fluid takes place with a predetermined conversion within a predetermined time. The target time is shorter than the predetermined time. The heating body (12), for preheating of the fluid, is heated to the target temperature and the fluid is passed through the channels (16) within the target time.

Designs for electrically heated reactors are disclosed. In one embodiment, a cylindrical reactor design to provide high temperature heat for an endothermic steam methane reformer without combustion includes: a cylindrical shell, one or more parallel internal cylindrical return tubes, baffles perpendicular to the axis of the shell, electrical heating elements disposed parallel to the shell axis and arranged in one or more rings extending through one or more baffles, and fitted with annular gas entrance and cylindrical gas outlet plena attached to one end of the device.

The invention is directed to a urea plant with a high pressure synthesis section and a recovery section. The high pressure synthesis section comprises a reactor, a stripper and a condenser, wherein the reactor operates at a higher pressure than the stripper and the condenser. The plant further includes a compression unit between the condenser and the reactor. The compression unit utilizes mechanical energy recovered from a decompression unit positioned downstream of the stripper and upstream of the recovery section.