Apparatus of catalytic gasification for refined biomass fuel at low temperature and the method thereof

a technology of biomass fuel and catalytic gasification, which is applied in the direction of combustible gas purification/modification, physical/chemical process catalysts, bulk chemical production, etc., can solve the problems of reducing requiring a lot of energy, and requiring a large amount of energy, etc., to achieve the reduction of the oxygen consumption required to maintain the operation temperature, the effect of compact apparatus and low cos

Inactive Publication Date: 2007-05-03
KOREA INST OF ENERGY RES
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0031] According to the present invention, the gasification of a fuel which is initiated at a temperature lower than that of a single fuel material may be conducted at a temperature which is further decreased by using a catalyst. Thereby, oxygen consumption required to maintain the operation temperature is decreased, thus a desired fuel may be inexpensively produced. In addition, since the operation temperature of a gasifier is low, little heat is released and a slagging treatment system is not needed, thereby realizing a compact apparatus. In addition, a gas product obtained by using a smaller amount of air in the present invention has the same caloric value as a gas product resulting from conventional gasification using oxygen, therefore generating economic benefits.
[0032] The present invention pertains to clean energy producing techniques for converting a highly refined mixture comprising sludge and coal into an inexpensive gas fuel having a high caloric value.
[0033] The gasification of the refined mixture comprising sludge/coal/oil is initiated, along with a material having a high initiation temperature of gasification, at a temperature lower than that of a single component. Thus, gasification may be performed for a short time, hence achieving rapid gasification.

Problems solved by technology

Generally, although gasification is used to maximally convert solid fuel into gas fuel, it may be limitedly applied in a partial gasification process.
Since the gasification of coal is typically performed at a high temperature, it requires a lot of energy.
Consequently, the system is too large or is complicated.
Further, a pure oxygen or air separating device for the production of a gas having high caloric value is used, thereby increasing the driving cost or mounting cost.
Hence, the partial oxidation in the absence of a catalyst is disadvantageous because high-temperature air or enriched oxygen must be used to achieve high-temperature gasification.
Further, expensive heat resistant material suitable for high-temperature reactions should be used, and also, the reactor has a short service life.
Furthermore, about 2˜5% of the free carbon that is produced by high-temperature partial combustion using a fixed-bed reactor is deposited, and the reaction efficiency is gradually decreased, thus requiring additional cost for removing the deposited material.
However, the above gasification is limited to use for waste containing a higher ash content or catalytic poison.
However, si

Method used

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  • Apparatus of catalytic gasification for refined biomass fuel at low temperature and the method thereof
  • Apparatus of catalytic gasification for refined biomass fuel at low temperature and the method thereof
  • Apparatus of catalytic gasification for refined biomass fuel at low temperature and the method thereof

Examples

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example 1

Improvement Of Gas Generation Efficiency BY Catalytic Gasification

[0069] For gasification of SOCA (Sludge-Oil-Coal Agglomerates) in the presence of a catalyst mixture comprising Fe2O3 and CaO, the catalyst mixture and SOCA were uniformly mixed at a weight ratio of 3.4:1 under operation conditions similar to gasification in the absence of a catalyst, thus obtaining a gas product. The state of the product is shown in FIG. 4. The gasification in the presence of the catalyst mixture was initiated at 230° C., which was considerably lower than 560° C. required for gasification in the absence of a catalyst. In addition, compared to gasification in the absence of a catalyst, CO conversion was lower, and more hydrocarbons were generated. In particular, almost all hydrocarbons generated were confirmed to be methane gas. In the gasification in the absence of a catalyst, hydrocarbons were generated at 850° C. or more, and CO was generated at 1050° C. or more. However, when using a catalyst mix...

example 2

Less Generation Of Tar and Fuel-N Pollutant By Two-Stage Catalytic Gasification

[0070] As shown in FIG. 5, when a CaO catalyst, which is an oxide of an alkali earth metal, was used in the first stage gasification and an NiO catalyst was used in the second stage catalytic reformation, CO was similarly generated but a slightly larger amount of hydrocarbon was generated, compared to gasification using only CaO as the first stage catalyst Thereby, the reaction was completed in a shorter time. However, as is apparent from Table 1 below, in the case where calcium oxide was used as a first stage catalyst and NiO or MnO2 was used as a second stage catalyst, the generation of tar, NH3 and HCN was remarkably lower than when using only a first stage catalyst. It was considered that tar was reformed and fuel-N was converted into N2. In addition, the MnO2 catalyst was inferior in tar reformation to the NiO catalyst, by which fuel-N was converted not into ammonia but into HCN. Thus, the NiO catal...

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Abstract

Disclosed is a gasification technique for converting biomass, which is difficult to treat, into clean gas fuel able to be burned in a cogeneration system. The gasification technique includes first stage fluidized-bed catalytic gasification, and second stage gasification of tar and catalytic reforming to convert nitrogen in tar, and HCN in a flammable gas into NH3, unlike conventional gasification techniques. In addition, since the temperature of a total gasification process is lower than a melting point of ash, powdery ash is generated and thus easily treated. Also, little heat is released due to the low process temperature, and therefore, a compact reactor may be designed to produce gas having a high caloric value. Further, the generated tar is recovered and reused in other processes, and the gas fuel contains a small amount of ammonia.

Description

TECHNICAL FIELD [0001] The present invention relates, in general, to gasification techniques for using biomass having a low inorganic ash content and a high nitrogen content as clean fuel in a local heating system of a big city. [0002] In particular, the present invention relates to an apparatus and method for manufacturing a gas fuel via clean gasification of a selectively refined mixture (SOCA: Sludge-Oil-Coal Agglomerates) comprising biomass organic waste, heavy oil, and coal. [0003] As such, the gas fuel obtained after clean gasification is a clean gas fuel usable in gas combustors, such as gas engines, gas turbines, vapor turbine generators, fuel cells, boilers, etc., or in heating devices. In addition, the biomass is organic solid materials, which include industrial waste such as sewage sludge, pulp sludge, etc., living waste such as home waste, excretions, etc., agricultural waste, livestock excretions, or wood chips. BACKGROUND ART [0004] Generally, gasification techniques h...

Claims

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Application Information

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IPC IPC(8): C10L3/00
CPCB01J23/02B01J23/34B01J23/745B01J23/75B01J23/78B01J37/04C01B2203/0272C10J3/54C10J3/56C10J2200/158C10J2300/0916C10J2300/093C10J2300/0946C10J2300/0956C10J2300/0973C10J2300/0983C10J2300/0989C10J2300/1846C10J2300/1869C10J2300/1884C10J2300/1892C10K1/024C10K1/046C10K1/18C10K1/20C10J3/482C10J3/84C10K1/026C10K1/08C10K3/02C10K3/023C10J2300/1693Y02P20/52C10G1/00
Inventor KANG, SUNG-KYUSHIN, HYUN-DONG
Owner KOREA INST OF ENERGY RES
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