The invention relates to a pressure loss production device (1) having a process gas inflow (2) that has a process gas inflow inlet (5), a process gas inflow outlet (6), a process gas inflow longitudinal center axis (A-A), and a process gas inflow cross-sectional surface (7), having a process gas distributor (3) that has a process gas distributor longitudinal center axis (B-B), a process gas distributor cross-sectional surface (8), a process gas distributor inlet (10) arranged on a first end face (9) and a process gas distributor outlet (12) arranged on a second end face (11), and having a process gas outflow (4) that comprises a process gas outflow inlet (13), a process gas outflow outlet (14), a process gas outflow longitudinal center axis (C-C), and a process gas outflow cross-sectional surface (15), wherein the process gas inflow (2) is connected with the first end face (9) of the process gas distributor (3), and the second end face (11) of the process gas distributor (3) is connected with the process gas outflow (4), in such a manner that a continuous flow path (16) is formed, wherein the process gas inflow (2) and process gas outflow (4) are arranged, relative to one another, in such a manner that the process gas inflow longitudinal center axis (A-A) and the process gas outflow longitudinal center axis (C-C) are arranged offset from one another, and to its use in a reactor system (31).

Disclosure relates to modified sulfur, preparation method thereof, preparation equipment thereof. The modified sulfur has spinnability or includes micro-structures such as fiber-, film- and network-like structure. The modified sulfur can be prepared by inducing polymerization with ultrasonic or ageing. The modified sulfur has various excellent features such as anticorrosiveness, waterproofing, strength, and fast drying and can control the features depending on its viscosity or polymerization degree. In addition due to the above features, the modified sulfur can be applied to anticorrosive or waterproofing material and can prepare anticorrosive or waterproofing material which has good workability, hardening, salt spray resistance, and weldability exceeding a certain level, and specially improved adhesiveness. Furthermore, when applying the modified sulfur to asphalt composition, gelation and depression are reduced, properties such as bending strength and tensile strength are improved, and it is possible to obtain asphalt composition with good working stability at RT.

Disclosure relates to modified sulfur, preparation method thereof, preparation equipment thereof. The modified sulfur has spinnability or includes micro-structures such as fiber-, film- and network-like structure. The modified sulfur can be prepared by inducing polymerization with ultrasonic or ageing. The modified sulfur has various excellent features such as anticorrosiveness, waterproofing, strength, and fast drying and can control the features depending on its viscosity or polymerization degree. In addition due to the above features, the modified sulfur can be applied to anticorrosive or waterproofing material and can prepare anticorrosive or waterproofing material which has good workability, hardening, salt spray resistance, and weldability exceeding a certain level, and specially improved adhesiveness. Furthermore, when applying the modified sulfur to asphalt composition, gelation and depression are reduced, properties such as bending strength and tensile strength are improved, and it is possible to obtain asphalt composition with good working stability at RT.

A method for reacting a reaction object with a liquid containing the reaction object in contact with a granular porous body. The upper limit D (mm) of the particle diameter of the granular porous body is determined from D=0.556×LN (T)+0.166 in a column flow method in non-circulation type, and determined from D=0.0315×T+0.470 in the column flow method in a circulation type and a shaking method. The granular porous body includes a skeleton body including an inorganic compound having a three-dimensional continuous network structure, and has a two-step hierarchical porous structure including through-holes formed in voids in the skeleton body, and pores extending from a surface to an inside of the skeleton body and dispersed on the surface. A functional group having affinity with the metal ion is chemically modified on a surface of the granular porous body.

A method for reacting a reaction object with a liquid containing the reaction object in contact with a granular porous body. The upper limit D (mm) of the particle diameter of the granular porous body is determined from D=0.556×LN (T)+0.166 in a column flow method in non-circulation type, and determined from D=0.0315×T+0.470 in the column flow method in a circulation type and a shaking method. The granular porous body includes a skeleton body including an inorganic compound having a three-dimensional continuous network structure, and has a two-step hierarchical porous structure including through-holes formed in voids in the skeleton body, and pores extending from a surface to an inside of the skeleton body and dispersed on the surface. A functional group having affinity with the metal ion is chemically modified on a surface of the granular porous body.

A system for vibrational loading is provided. The system includes: one or more pilot plant reactor tubes; at least one vibrator attached to and configured to impart vibrational energy to a corresponding at least one of the reactor tubes during the vibrational loading; and a portable reactor loading station. The loading station includes: a base structure; a plurality of rolling members attached to the base structure which is configured to contact and roll across a horizontal surface while remaining attached to the base structure and separate the base structure from the horizontal surface; a frame attached to and extending vertically from the base structure; and one or more clamps attached to the frame to secure the reactor tubes in a vertical orientation. The clamps are attached to the frame through corresponding elastomeric members vibrationally isolating the secured reactor tubes from the frame during the vibrational loading.

A system for vibrational loading is provided. The system includes: one or more pilot plant reactor tubes; at least one vibrator attached to and configured to impart vibrational energy to a corresponding at least one of the reactor tubes during the vibrational loading; and a portable reactor loading station. The loading station includes: a base structure; a plurality of rolling members attached to the base structure which is configured to contact and roll across a horizontal surface while remaining attached to the base structure and separate the base structure from the horizontal surface; a frame attached to and extending vertically from the base structure; and one or more clamps attached to the frame to secure the reactor tubes in a vertical orientation. The clamps are attached to the frame through corresponding elastomeric members vibrationally isolating the secured reactor tubes from the frame during the vibrational loading.

Providing a method for generating and releasing 1-MCP gas from a complex carrier through the use of a 1-MCP generator that enables the application of at least one physical, releasing force to a carrier complex and/or mixture comprising water and the carrier complex, or the interaction of steam with a carrier complex and/or mixture comprising water and the carrier complex, over a determined period of time.

Disclosure relates to modified sulfur, preparation method thereof, preparation equipment thereof. The modified sulfur has spinnability or includes micro-structures such as fiber-, film- and network-like structure. The modified sulfur can be prepared by inducing polymerization with ultrasonic or ageing. The modified sulfur has various excellent features such as anticorrosiveness, waterproofing, strength, and fast drying and can control the features depending on its viscosity or polymerization degree. In addition due to the above features, the modified sulfur can be applied to anticorrosive or waterproofing material and can prepare anticorrosive or waterproofing material which has good workability, hardening, salt spray resistance, and weldability exceeding a certain level, and specially improved adhesiveness. Furthermore, when applying the modified sulfur to asphalt composition, gelation and depression are reduced, properties such as bending strength and tensile strength are improved, and it is possible to obtain asphalt composition with good working stability at RT.

Disclosure relates to modified sulfur, preparation method thereof, preparation equipment thereof. The modified sulfur has spinnability or includes micro-structures such as fiber-, film- and network-like structure. The modified sulfur can be prepared by inducing polymerization with ultrasonic or ageing. The modified sulfur has various excellent features such as anticorrosiveness, waterproofing, strength, and fast drying and can control the features depending on its viscosity or polymerization degree. In addition due to the above features, the modified sulfur can be applied to anticorrosive or waterproofing material and can prepare anticorrosive or waterproofing material which has good workability, hardening, salt spray resistance, and weldability exceeding a certain level, and specially improved adhesiveness. Furthermore, when applying the modified sulfur to asphalt composition, gelation and depression are reduced, properties such as bending strength and tensile strength are improved, and it is possible to obtain asphalt composition with good working stability at RT.