A hopper including a buffer compartment defined by side walls, a top end including an opening for receiving solid particles, and a bottom end including an opening for dispensing the solid particles from the buffer compartment. The buffer compartment includes a plurality of essentially vertically positioned cooling plate-like elements for cooling the solid particles in the buffer compartment. A system including hopper, methods of operating the hopper or system, and production of solid particles.

The present invention provides a char collector (1) for a pyrolysis system (2), the pyrolysis system (2) featuring a pyrolysis reactor (17) comprising a hot char outlet (3), the char collector comprises a container (4) and a longitudinal char conveyor unit (5), and the container (4) comprises a chamber (6), a first inlet (7) connectable to the hot char outlet (3) and a first outlet (8), wherein the first inlet (7) is arranged in an upper portion of the chamber (6) and the first outlet (8) is arranged in a lower portion of the chamber (6); and the char conveyor unit (5) comprises a first end section (9) connected to the first outlet (8), a second end section (10) featuring a second outlet (11) for cooled char and a conveying mechanism (12) configured to transport char from the first end section (9) to the second outlet (11) during use; wherein the second outlet (11) is at a level above the first outlet (8), such that a gas trap is formed between the first inlet (7) and the second outlet (11) when the chamber (6) is filled with water up to a level above the first outlet (8) during use.

A method and a control unit for evaluating lifting force of a gas phase of a substantially vertical upward two-phase flow of a first fluid in a heat exchanger. The first fluid comprises the gas phase and a liquid phase. The method comprises determining that the lifting force of the gas phase is insufficient for lifting the liquid phase based on hot end approach of the heat exchanger and/or on pressure drop of the first fluid over the heat exchanger. The control unit is configured to determine that the lifting force of the gas phase is insufficient for lifting the liquid phase based on hot end approach of the heat exchanger and/or on pressure drop of the first fluid over the heat exchanger. A heat exchanger assembly comprising a heat exchanger and the control unit.

A system for producing American Petroleum Institute Standards Group III Base Stock from vacuum gas oil, by injecting hydrogen, heating, partially saturating the vacuum gas oil through a plurality of hydrogen reactors connected in series with a liquid hourly space velocity (LHSV).sup.1 of from 0.5 to 2.5, forming a saturated heated base oil, and coproduct. The system fractionates the saturated heated base oil to while simultaneously refluxing a cooled fuel oil fraction forming an American Petroleum Institute Standards Group III Base Stock with less than 0.03% sulfur, with greater than 90% saturates and a viscosity index greater than 120 as defined by ASTM D-2270, a viscosity from 2 to 10 centistokes as defined by ASTM D-445 a boiling range from 600 degrees F. to 1050 degrees F., and a cold crank viscosity (CCS) between 1200 and 5000 centipoise at 25 degrees C. and as defined by ASTM D-5293.

A feed system for a reactor, a reactor assembly comprising such a feed system, and a method of supplying a feed material to a reactor with a feed system are provided. The reactor may be a pyrolysis reactor, such as a fluidised bed pyrolysis reactor. A method of pyrolysing a feed material is also provided. The feed system may comprise a feed conduit extending from an inlet to an outlet, and may have a first section including the inlet and a second section including the outlet. The first section may accommodate an auger. The second section may comprise at least one plug forming zone in which feed material is compressed into a substantially gas-tight plug during operation. There may be a temperature regulator for controlling the temperature in the second section. The temperature regulator may comprise a cooling jacket.

A system of product gas collecting conduits for a steam reformer, containing a plurality of reaction tubes within a reformer housing, for the production of synthesis gas, comprising: a) a product gas collecting conduit arranged outside the reformer housing of the steam reformer, b) several port tubes arranged along the length of the conduit for connecting one reaction tube each to the product gas collecting conduit, c) at least one windshield for the protection of the product gas collecting conduit against wind and draft.

Reactor (1) for partial oxidation of a fuel (2) with an oxidant (3) to a synthesis gas (4) comprising CO and H2, the reactor (1) includes: a vessel (5) enclosing a reaction chamber (6) for the partial oxidation of said fuel (2) in the presence of said oxidant (3); a burner (7) arranged to feed said fuel (2) and said oxidant (3) to said reaction chamber (6); said burner (7) comprises: a first passage (9) for said oxidant (3) and a second passage (2) for said fuel (2), said first (9) and said second passage (11) are coaxially arranged one around the other; an ignition mean (13) and a flame detection sensor (14), wherein said ignition mean (13) and said flame detection sensor (14) are movable within the burner between a start-up position (30) proximal to the reaction chamber (6) and a second retracted position (31) distanced from said reaction chamber (6).

Provided herein is a unidirectional blow down system for a high-pressure tubular reactor with a hyper that minimizes the tube wall metal temperature during a decomposition event wherein the system prevents the reactor walls from reaching a temperature capable of causing the tube metal to austenize. Also provided are methods of designing and methods of operating a unidirectional blowdown system.

Systems and methods for delivering active ingredients, such as pharmaceutically active ingredients, to substrates are described herein. The active ingredients are delivered as fluids to a fluid-dispensing device for the creation of one or more drops for deposition onto substrates such as for the creation of microdoses. The invention further includes microdoses made by such processes.

The expanded bed direct-contact system uses a multistage expanded bed chamber for heat exchange between heated particles, falling under the force of gravity, and an upwardly directed stream of cool fluid. As the heated particles fall through a plurality of vertically-arrayed stages of the multistage expanded bed chamber and exchange thermal energy with the stream of cool fluid, a stream of heated fluid, and a volume of cooled particles, are produced. Porous plates are respectively received within the stages of the multistage expanded bed chamber for increasing residence time of the particles, and the porous plates, as well as the plurality of stages, are connected to one another by a plurality of downcomers, each also formed from a porous material.