Korea Research Institute of Chemical Technology

Daejeon, South Korea

Korea Research Institute of Chemical Technology

Daejeon, South Korea

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Patent
Samsung, Chungnam National University and Korea Research Institute of Chemical Technology | Date: 2016-09-23

An electrically conductive composite including: a polymer matrix including a cellulose, and a plurality of electrically conductive carbon nanoparticles dispersed in the polymer matrix, wherein the electrically conductive carbon nanoparticles have a multiple hydrogen bonding moiety covalently bound to a surface thereof.


Patent
Cj Cheiljedang Corporation and Korea Research Institute of Chemical Technology | Date: 2017-02-15

The present disclosure relates to the preparation of a useful compound, which can be used as an intermediate for preparing an important compound in the industrial field from a homoserine-based compound, and provides a process for treating a homoserine-based compound, capable of mass-producing a useful compound from a homoserine-based compound in a simple manner with excellent efficiency.


Patent
Korea Research Institute of Chemical Technology and Hanwha Chemical Corporation | Date: 2017-01-04

A method for preparing trichlorosilane according to an embodiment of the present invention comprises the steps of: supplying surface-modified metal silicide and metal grade silicon to a reaction unit; supplying silicon tetrachloride and hydrogen to the reaction unit; and supplying a product, which is generated by a reaction of metal grade silicon, silicon tetrachloride , and hydrogen in the presence of metal silicide in the reaction unit, to a separation unit, and separating a trichlorosilane component. In cases where a silicon tetrachloride hydrochlorination reaction is performed using the method for preparing trichlorosilane according to the embodiment of the present invention, the yield of trichlorosilane can be raised.


The present invention relates to a beta zeolite catalyst for the preparation of a BTEX (benzene, toluene, ethylbenzene, xylene) mixture from polyaromatic hydrocarbons and a preparation method of the same. The beta zeolite catalyst of the present invention demonstrates the high conversion of polyaromatic hydrocarbons and the high BTEX production yield by containing the optimum contents of the group VIB metals and cocatalysts, so that it can be effectively used as a beta zeolite catalyst for the production of BTEX.


Patent
Korea Research Institute of Chemical Technology | Date: 2016-10-11

The present invention relates to a method and apparatus for preparation of lactide using a lactide purification process, comprising introducing an aqueous solution comprising lactic acid into a reactor filled with a catalyst and reacting the same to produce crude lactide vapor; and purifying the crude lactide vapor to produce lactide crystals, wherein a first purification comprises collecting and crystallizing the crude lactide vapor using a first solvent to produce lactide crystals, and separating the lactide crystal from a residue through filtration.


The present invention relates to a pyrimidine-2,4-diamine derivative or a pharmaceutically acceptable salt thereof, and a pharmaceutical composition for prevention or treatment of cancer comprising the same as an effective ingredient. A compound according to the present invention has the good effect of inhibiting anaplastic lymphoma kinase (ALK) activity, whereby a therapeutic effect on cancer cells having an anaplastic lymphoma kinase (ALK) fusion protein such as EML4-ALK, NPM-ALK, etc. can be enhanced and it is expected that a recurrence of cancer will be effectively inhibited. As such, the compound can be effectively used in a pharmaceutical composition for prevention or treatment of cancer.


Patent
Korea Research Institute of Chemical Technology | Date: 2017-06-14

The present invention relates to a method for producing high-efficiency methanol capable of reducing emission of carbon dioxide, and more particularly, to a method for producing high-efficiency methanol, including: a first step of preparing mixed gas by using steam and natural gas as reaction raw materials and converting C_(2+) hydrocarbon contained in the natural gas into methane on a catalyst; a second step of preparing a synthetic gas including carbon monoxide, carbon dioxide, and hydrogen by reforming the mixed gas in a reformer reactor filled with a reforming catalyst; and a third step of preparing methanol by using the synthesis gas as the reaction raw material and reacting the synthesis gas, wherein an appropriate of carbon dioxide is injected into any one of the reformer reactor of the second step and the methanol synthesis reactor of the third step or divisionally injected into both the reformer reactor of the second step and the methanol synthesis reactor of the third step, the unreacted synthesis gas emitted in the methanol synthesis process of the third step is recalculated to both the second step process and the third step process or only to the third step process again to be reused as the raw material, some unreacted synthesis gas is used as gas for combustion of a heating furnace for supplying reaction heat required in the second step together with the natural gas, and heat of high-temperature post-combustion gas emitted from the heating furnace is efficiently recovered and used by a series of heat exchangers, thereby maximizing carbon efficiency and heat efficiency of the overall process while reducing the use amount of the natural gas.


Patent
Korea Research Institute of Chemical Technology | Date: 2017-06-07

The present invention provides a naphtha and methanol mixed catalytic cracking reaction process involving a simultaneous cracking reaction of naphtha and methanol using a circulating fluidized-bed reactor comprising a reactor, a stripper, and a regenerator, wherein the naphtha is supplied from the bottom part of the reactor at a position between 0% 5% of the total length of the reactor, and the methanol is supplied from the bottom part of the reactor at a position between 10% 80% of the total length of the reactor. The catalytic cracking reaction process provided by the invention uses the circulating fluidized-bed reactor and can crack naphtha and methanol simultaneously by having different introduction positions for the naphtha and methanol in the reactor, which is advantageous for heat neutralization, so that energy consumption can be minimized and also the yield of light olefins can be improved by suppressing the production of light saturated hydrocarbons such as methane, ethane and propane.


The present invention relates to a novel compound, to a pharmaceutically acceptable salt or optical isomer thereof, to a method for preparing same, and to a pharmaceutical composition for the prevention or treatment of viral diseases containing same as an active ingredient. The novel compound according to the present invention not only has low cytotoxicity but also has excellent antiviral activity against picornavirus such as coxsackievirus, enterovirus, echovirus, poliovirus and rhinovirus, and thus can be effectively used as a pharmaceutical composition for the prevention or treatment of viral diseases such as infantile paralysis, acute hemorrhagic conjunctivitis, viral meningitis, hand-foot-and-mouth disease, vesicular disease, hepatitis A, myitis, myocarditis, pancreatitis, diabetes, epidemic myalgia, encephalitis, cold, herpangina, foot-and-mouth disease, asthma, chronic obstructive pulmonary disease, pneumonia, sinus infection, or otitis media.


Patent
Korea Research Institute of Chemical Technology | Date: 2017-03-17

The present invention provides a method for separating high purity methane gas from biogas, which comprises the steps of: compressing and cooling biogas (step 1); and separating carbon dioxide by introducing the biogas compressed and cooled in step 1 into a four-stage polymer separation membrane system in which the residue stream of the first polymer separation membrane is connected to the second polymer separation membrane, the residue stream of the second polymer separation membrane is connected to the third polymer separation membrane, and the permeate stream of the second polymer separation membrane is connected to the fourth polymer separation membrane (step 2).

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