JP6130817B2 - Apparatus for producing organic substance, method for producing organic substance, synthesis gas production method, and synthesis gas production apparatus - Google Patents

Description

  The present invention relates to an apparatus for producing an organic substance, a method for producing an organic substance, a synthesis gas production method, and a synthesis gas production apparatus.

  In recent years, practical application of a method for producing a chemical substance such as ethanol by microbial fermentation of a synthesis gas containing carbon monoxide synthesized from, for example, an exhaust gas from an ironworks has been studied (for example, Patent Document 1). reference).

International Publication No. 2011-087380

  However, the actual situation is that an apparatus for producing an organic substance has not been put into practical use at present and has not been sufficiently studied.

  A main object of the present invention is to provide a novel apparatus capable of suitably producing an organic substance.

  An organic material manufacturing apparatus according to the present invention includes a synthesis gas generation furnace, an organic material synthesis unit, a synthesis gas purification unit, and piping. The synthesis gas generation furnace generates synthesis gas. The organic material synthesis unit generates an organic material from the synthesis gas. The synthesis gas purification unit is connected between the synthesis gas generation furnace and the organic material synthesis unit. The synthesis gas purification unit is configured by a pressure fluctuation adsorption type adsorption part or a temperature fluctuation adsorption type adsorption part that reduces the impurity concentration in the synthesis gas. The piping connects the synthesis gas purification unit and the organic material synthesis unit. The piping has a first piping and a second piping. The first pipe connects the synthesis gas purification unit and the organic material synthesis unit. The second pipe connects the first part of the first pipe and the second part on the downstream side of the first part. The apparatus for producing an organic substance according to the present invention further includes a first flow rate adjustment valve and a second flow rate adjustment valve. The first flow regulating valve is arranged between the first part and the second part of the first pipe. The second flow rate adjustment valve is arranged in the second pipe. The gas ventilation resistance in the second pipe is different from the gas ventilation resistance in the portion located between the first portion and the second portion of the first pipe.

  In addition, the impurity said here means all the things which may have a bad influence on a production | generation in an organic substance production | generation process. Examples of impurities include benzene, toluene, xylene, and the like.

  In the organic substance manufacturing apparatus according to the present invention, the gas ventilation resistance in the second pipe is greater than the gas ventilation resistance in the portion located between the first part and the second part of the first pipe. It may be high.

The apparatus for producing an organic substance according to the present invention may further include a ventilation resistance adjusting unit that adjusts the gas ventilation resistance of the second pipe.

  The organic substance manufacturing apparatus according to the present invention may further include an orifice arranged in the second pipe.

In the manufacturing apparatus of an organic substance according to the present invention may be those organic materials synthesis unit to produce organic matter by microbial fermentation.

  In the organic substance manufacturing apparatus according to the present invention, the organic substance synthesis unit may generate an organic substance from synthesis gas using a metal catalyst.

  In the method for producing an organic substance according to the present invention, the organic substance is produced by using the organic substance producing apparatus.

The synthesis gas production apparatus according to the present invention includes a synthesis gas purification unit configured by a pressure fluctuation adsorption type adsorption unit or a temperature fluctuation adsorption type adsorption unit to which a synthesis gas containing impurities is supplied, and a synthesis gas purification unit. Piping for discharging the synthesized gas. The piping connects the first piping connected to the synthesis gas purification unit , the first portion of the first piping, and the second portion downstream of the first portion. Piping. The syngas production apparatus according to the present invention includes a first flow rate adjusting valve disposed between the first part and the second part of the first pipe, and a second pipe disposed in the second pipe. And a flow rate adjusting valve. The gas ventilation resistance in the second pipe is different from the gas ventilation resistance in the portion located between the first portion and the second portion of the first pipe.

  In the syngas production apparatus according to the present invention, the gas ventilation resistance in the second pipe is greater than the gas ventilation resistance in the portion located between the first portion and the second portion of the first pipe. It may be high.

The apparatus for producing synthesis gas according to the present invention may further include a ventilation resistance adjusting unit that adjusts the gas ventilation resistance of the second pipe.

  The synthesis gas production apparatus according to the present invention may further include an orifice disposed in the second pipe.

  The method for producing a synthesis gas according to the present invention produces an organic substance using the synthesis gas production apparatus.

  ADVANTAGE OF THE INVENTION According to this invention, the novel apparatus which can manufacture an organic substance suitably can be provided.

It is a schematic diagram of the manufacturing apparatus of the organic substance which concerns on one Embodiment of this invention.

  Hereinafter, an example of the preferable form which implemented this invention is demonstrated. However, the following embodiment is merely an example. The present invention is not limited to the following embodiments.

  FIG. 1 is a schematic view of an organic substance manufacturing apparatus 1 according to this embodiment. A manufacturing apparatus 1 shown in FIG. 1 is an apparatus for manufacturing an organic substance from waste containing a carbon source such as waste plastic. The produced organic substance may be an oxygen-containing organic substance. The organic substance to be produced may be, for example, alcohol, organic acid, fatty acid, fat or oil, ketone, biomass, sugar or the like. Specific examples of alcohols, organic acids, fatty acids, fats and oils, ketones, biomass, and sugars include ethanol, acetic acid, and butanediol.

  The use of the produced organic substance is not particularly limited. The produced organic substance can be used as a raw material for plastics and resins, for example, and can also be used as a fuel.

  In addition, although this embodiment demonstrates the example which produces | generates a synthesis gas from a waste material, a synthesis gas does not need to be produced | generated by partially oxidizing a waste material etc. For example, synthesis gas discharged from an ironworks or the like may be used.

  The manufacturing apparatus 1 includes a synthesis gas generation furnace 11. The synthesis gas generation furnace 11 is supplied with waste containing an organic substance containing a carbon source such as plastic or resin. In the synthesis gas generation furnace 11, the waste is partially oxidized to generate synthesis gas containing carbon monoxide. Usually, synthesis gas contains hydrogen gas and nitrogen gas in addition to carbon monoxide.

  The synthesis gas is supplied to a fermenter 18 as an organic substance synthesis unit. The fermenter 18 contains microorganisms and water. Microorganisms produce organic substances from synthesis gas by fermentation. For this reason, in the fermenter 18, an organic substance is manufactured from synthesis gas by microbial fermentation. For example, specific examples of the microorganism suitably used for producing alcohol such as ethanol include anaerobic carboxydotrophic bacteria such as Clostridium.

  The fermenter 18 is connected to a refiner 19. The product in the fermenter 18 is transferred to the refiner 19. In general, the fermenter 18 generates other organic substances in addition to the organic substance to be manufactured. The refiner 19 purifies the product in the fermenter 18. Thereby, the target organic substance can be obtained.

  In this embodiment, a fermenter that generates an organic substance by microbial fermentation is used as the organic substance synthesis unit. However, the present invention is not limited thereto. For example, you may provide the organic substance synthesis | combination part which produces | generates an organic substance from a synthesis gas using a metal catalyst.

  A synthesis gas purification unit 12 is connected between the synthesis gas generation furnace 11 and the fermenter 18. The synthesis gas purification unit 12 reduces the impurity concentration in the synthesis gas. The synthesis gas purification unit 12 includes a pressure fluctuation adsorption part (PSA) or a temperature fluctuation adsorption type adsorption part (TSA). The synthesis gas purification unit 12 supplies the purified synthesis gas to the fermenter 18.

  The synthesis gas purification unit 12 and the fermenter 18 are connected by a pipe 13. The pipe 13 includes a first pipe 13a and a second pipe 13b. The first pipe 13 a connects the synthesis gas generation furnace 11 and the fermenter 18. A first flow rate adjustment valve 15 is provided between the first portion 13a1 of the first pipe 13a and the second portion 13a2 located on the downstream side of the first portion 13a1. . The first flow rate adjusting valve 15 adjusts the flow rate in the portion between the first portion 13a1 and the second portion 13a2 of the first pipe 13a. A tank 14a is provided between the first flow regulating valve 15 and the second portion 13a2.

  The second pipe 13b is connected to the first part 13a1 and the second part 13a2 of the first pipe 13a. A second flow rate adjustment valve 16 is provided in the second pipe 13b. The flow rate in the second pipe 13 b is adjusted by the second flow rate adjustment valve 16. A tank 14b is provided between the second flow rate adjustment valve 16 and the second portion 13a2.

  The synthesis gas ventilation resistance between the first part 13a1 and the second part 13a2 of the first pipe and the synthesis gas ventilation resistance of the second pipe 13b are different from each other. Specifically, in this embodiment, the ventilation resistance adjusting unit 17 is provided in the second pipe 13b. The ventilation resistance adjusting unit 17 causes the synthesis gas ventilation resistance in the second pipe 13b to be higher than the synthesis gas ventilation resistance between the first part 13a1 and the second part 13a2 of the first pipe. Yes.

  The ventilation resistance adjusting unit 17 can be configured by, for example, a valve, an orifice, or the like.

  In the present embodiment, the synthesis gas production apparatus 2 includes a synthesis gas generation furnace 11, a synthesis gas purification unit 12, a ventilation resistance adjustment unit 17, first and second flow rate adjustment valves 15 and 16, and a tank 14a. , 14b.

  In the manufacturing apparatus 1, when the first flow rate adjustment valve 15 is released and the second flow rate adjustment valve 16 is closed, the synthesis gas passes through only the first pipe 13a having a relatively low ventilation resistance and is fermented. Is supplied to the vessel 18. On the other hand, when the first flow control valve 15 is closed and the second flow control valve 16 is released, the synthesis gas is supplied to the fermenter 18 through the second pipe 13b having a relatively high ventilation resistance. The In this manner, the back pressure of the synthesis gas purification unit 12 can be adjusted by opening and closing the first and second flow rate adjustment valves 15 and 16.

  Here, in the production apparatus 1, as described above, the synthesis gas purification unit 12 is configured by a pressure fluctuation adsorption part (PSA) or a temperature fluctuation adsorption type adsorption part (TSA). In these pressure fluctuation adsorption parts (PSA) and temperature fluctuation adsorption type adsorption parts (TSA), the residence time changes by changing the back pressure, so the composition of the synthesis gas discharged from the synthesis gas purification unit 12 changes. .

  Specifically, for example, in the present embodiment, the ventilation resistance in the second pipe 13b is higher than the ventilation resistance of the part located between the first part 13a1 and the second part 13a2 of the first pipe 13a. . Therefore, when the first flow control valve 15 is released and the second flow control valve 16 is closed, the synthesis is relatively low in hydrogen concentration, high in carbon monoxide concentration, and high in carbon dioxide concentration. Gas is supplied to the fermenter 18. On the other hand, when the first flow control valve 15 is closed and the second flow control valve 16 is released, the synthesis gas has a relatively high hydrogen concentration, a low carbon monoxide concentration, and a low carbon dioxide concentration. Is fed to the fermenter 18. Thus, in the manufacturing apparatus 1, by controlling the opening degree of the first and second flow control valves 15 and 16, the synthesis gas having a desired composition, that is, the synthesis gas suitable for the microorganisms in the fermenter 18 is used. Can be supplied to the fermenter 18. Therefore, an organic substance can be produced with high efficiency.

  In the present embodiment, the example in which the ventilation resistance adjusting unit 17 is provided has been described. For example, the ventilation resistance in the first pipe 13a and the ventilation resistance in the second pipe 13b can be obtained by changing the flow path area. May be different.

DESCRIPTION OF SYMBOLS 1 Manufacturing apparatus 2 Syngas manufacturing apparatus 11 Syngas production furnace 12 Syngas refinement | purification part 13 Piping 13a 1st piping 13a1 1st part 13a2 2nd part 13b 2nd piping 14a, 14b Tank 15 1st flow rate Adjusting valve 16 Second flow adjusting valve 17 Ventilation resistance adjusting unit 18 Fermenter 19 Purifier

Claims (14)

A synthesis gas generation furnace for generating synthesis gas;
An organic material synthesis unit for generating an organic material from the synthesis gas;
A synthesis gas purification unit that is connected between the synthesis gas generation furnace and the organic substance synthesis unit and includes a pressure variation adsorption type adsorption unit or a temperature variation adsorption type adsorption unit that reduces the impurity concentration in the synthesis gas. When,
A pipe connecting the synthesis gas purification unit and the organic substance synthesis unit;
With
The piping is
A first pipe connecting the synthesis gas purification unit and the organic substance synthesis unit;
A second pipe connecting the first part of the first pipe and the second part downstream of the first part;
Have
A first flow regulating valve disposed between the first part and the second part of the first pipe;
A second flow rate regulating valve arranged in the second pipe;
Further comprising
Wherein the flow resistance of the gas in the second pipe, varies with each other and the ventilation resistance of the gas in the portion located between said first portion and said second portion of said first pipe,
A first tank provided between the first flow control valve and the second portion;
Wherein between the second portion and the second flow rate control valve that provides a second tank, the manufacturing apparatus of an organic material. The apparatus for producing an organic substance according to claim 1, wherein the back pressure of the synthesis gas purification unit is adjusted by opening and closing the first flow rate adjustment valve and the second flow rate adjustment valve. . The second ventilation resistance of the gas in the pipe is higher than the flow resistance of the gas in the portion located between said first portion and said second portion of said first pipe, according to claim 1 or 2 The manufacturing apparatus of the organic substance as described in. The organic substance manufacturing apparatus according to claim 3 , further comprising a ventilation resistance adjusting unit configured to adjust a gas ventilation resistance of the second pipe. Further comprising a second orifice disposed in the pipe manufacturing apparatus of an organic material according to claim 3 or 4. The organic material combining unit, to generate the organic matter by microbial fermentation apparatus for producing an organic substance according to any one of claims 1-5. The said organic substance synthesis | combination part is a manufacturing apparatus of the organic substance as described in any one of Claims 1-5 which produces | generates the said organic substance from the said synthesis gas using a metal catalyst. Method for producing an organic substance using the manufacturing apparatus of an organic substance according to any one of claims 1-7. A synthesis gas purification unit constituted by a pressure fluctuation adsorption type adsorption part or a temperature fluctuation adsorption type adsorption part, to which a synthesis gas containing impurities is supplied;
Piping for discharging the synthesis gas generated by the synthesis gas purification unit;
With
The piping is
A first pipe connected to said synthesis gas purification unit,
A second pipe connecting the first part of the first pipe and the second part downstream of the first part;
Have
A first flow regulating valve disposed between the first part and the second part of the first pipe;
A second flow rate regulating valve arranged in the second pipe;
Further comprising
Wherein the flow resistance of the gas in the second pipe, varies with each other and the ventilation resistance of the gas in the portion located between said first portion and said second portion of said first pipe,
A first tank provided between the first flow control valve and the second portion;
Wherein the second flow rate control valve that provides a second portion the second tank during the manufacturing apparatus of the synthesis gas. The syngas production apparatus according to claim 9, configured to adjust a back pressure of the synthesis gas purification unit by opening and closing the first flow rate adjustment valve and the second flow rate adjustment valve. . The second ventilation resistance of the gas in the pipe is higher than the flow resistance of the gas in the portion located between said first portion and said second portion of said first pipe, according to claim 9 or 10 The synthesis gas production apparatus described in 1. The synthesis gas production apparatus according to claim 11 , further comprising a ventilation resistance adjusting unit that adjusts a gas ventilation resistance of the second pipe. Wherein the further comprising a second orifice disposed in the pipe, apparatus for producing synthesis gas according to claim 11 or 12. A method for producing a synthesis gas using the synthesis gas production apparatus according to any one of claims 9 to 13 .

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