KR102094646B1 - Highly efficient steam reforming hydrogen production apparatus with hydrodesulfurization - Google Patents

Abstract

Unlike a large-scale plant for producing hydrogen, thermal efficiency of hydrogen production is very important in a small hydrogen production device used in a fuel cell or a hydrogen station. In addition, because of the frequent operation stop and restart due to the characteristics of the device, not only the ease of operation, but also a process after the operation must reach desired conditions quickly and be stable. Also, desulfurization performance must be excellent so that natural gas, LPG, naphtha, etc. can be used as raw materials. In the present invention, the thermal efficiency is maximized, the desulfurization performance is enhanced, and a method to quickly reach a desired operating condition after the process is proposed.

Description

Highly efficient steam reforming hydrogen production apparatus with hydrodesulfurization}

The present invention relates to a hydrogen production apparatus in which thermal efficiency is maximized and desulfurization performance is enhanced in a hydrogen production process by steam reforming.

The hydrogen production device is a device that supplies hydrogen or reformed gas (reformate: H ₂ , CO, CO ₂ , CH ₄ ), and is generally used to optimize the thermal energy of raw material desulfurization devices, steam reforming reactors, water gas reactors, and processes. It consists of a heat exchange network.

Unlike a large-scale plant for producing hydrogen, a small hydrogen production device used in a fuel cell or a hydrogen station is very important in the thermal efficiency of hydrogen production.

In addition, due to the frequent operation stop and restart due to the characteristics of the device, not only the ease of operation but also the process after operation starts must reach the desired condition quickly and be stable.

In addition, the desulfurization performance must be excellent so that natural gas, LPG, naphtha, etc. can be used as raw materials.

Accordingly, as described in the following patent documents, attempts have been made to modify or dispose a hydrogen production device, and to construct various heat exchange networks and flow paths, but they are still insufficient in terms of desulfurization performance, stability, and efficiency of the entire hydrogen production device.

Korean Patent Registration No. 130033 Korean Patent Registration No. 1832136 Korean Patent Publication No. 2007-0099644 Korean Patent Publication No. 2017-0096333

In the present invention, the thermal efficiency was maximized, the desulfurization performance was enhanced, and a method capable of stably operating under desired operating conditions after the operation of the process was proposed.

Hydrogen production apparatus according to the present invention for solving the above problems,

Hydrogen desulfurizer for hydrodesulfurizing the raw hydrocarbon; A reforming reactor in which the raw material moisture mixed with the hydrocarbon material desulfurized from the hydrogen desulfurizer is introduced, and heated by a burner to perform a steam reforming reaction; An aqueous gas reactor for converting carbon monoxide to an aqueous gas with respect to the reformed gas from the reforming reactor; And PSA (pressure swing adsorption) for hydrogen separation,

A heat exchanger 4 for exchanging heat with the combustion exhaust gas discharged from the burner to overheat the raw material moisture with a single phase water vapor before mixing with the desulfurized hydrocarbon raw material;

A heat exchanger 1 that heats the mixture of the desulfurized hydrocarbon raw material and the superheated steam with a reforming gas discharged from the reforming reactor and introduces the reforming reactor;

A heat exchanger 3 for exchanging heat with external air so that the reformed gas that has passed through the heat exchanger 1 is cooled before being introduced into the water gas reactor;

A heat exchanger 7 for exchanging heat with cooling water so that the conversion gas generated from the water gas reactor is reduced before being introduced into the PSA; And

In order to heat the mixture of the hydrocarbon raw material and the hydrogen recycled from the PSA by heat exchange with reforming gas, it is provided between the heat exchanger 1 and the heat exchanger 3

And a heat exchanger 2.

It is preferred to further include a heat exchanger 5 disposed between the water gas reactor and the heat exchanger 7 to heat the PSA exhaust gas by exchanging heat with the conversion gas.

It is more preferable that the heat exchanger 6 that heats the raw material moisture by exchanging heat with the conversion gas is replaced or further included.

The heat exchanger 6 is preferably disposed between the heat exchanger 5 and the heat exchanger 7.

It is preferable that a part of the hydrocarbon raw material, air heated in the heat exchanger 3, and exhaust gas of the PSA are supplied to the burner.

The exhaust gas of the PSA is preferably heated by the heat exchanger 5 disposed between the water gas reactor and the heat exchanger 7.

The heat exchangers 1 to 7 are finned tube heat exchangers, plate type heat exchangers, multitube hairpin types or shell and tube type heat exchangers. It is preferred.

The hydrocarbon raw material is preferably a gaseous or liquid hydrocarbon containing at least one of natural gas, LPG and Naphtha.

The reforming reactor includes a catalytic reaction part filled with a catalyst to enable the mixture to flow,

The catalyst filled in the catalytic reaction part is preferably ruthenium or nickel supported on an alumina or silica carrier.

The catalyst in the hydrogen desulfurization group may include one or more metals or metal oxides or emulsions selected from cobalt, zinc, copper, molybdenum, and nickel; Zeolite; Or it is preferable to contain activated carbon.

The amount of raw water vapor supplied to the reforming reactor is preferably mixed in a ratio of water vapor to carbon molar ratio of 1: 2.5 to 4.0.

It is preferable that the catalyst in the water gas reactor is an iron-chromium catalyst or a copper-zinc catalyst.

In the present invention, the desulfurization performance is enhanced by a hydrogen desulfurization method, and heat efficiency is maximized by adding a heat exchanger, and stable operation is possible under desired operating conditions after the process starts.

1 schematically shows an example of a hydrogen production apparatus according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, embodiments of the present invention may be modified in various other forms, and the scope of the present invention is not limited to the embodiments described below.

In describing the present embodiments, the same name and code are used for the same configuration, and thus additional descriptions that overlap are omitted below. In the figures referenced below, the accumulation ratio is not applied.

The hydrogen production device of the present invention is a device for producing hydrogen or reformed gas (H ₂ , CO, CO ₂ , CH ₄ ), and generally includes a hydrogen desulfurization group for hydrodesulfurizing the raw hydrocarbons and a hydrocarbon raw material desulfurized from the hydrogen desulfurization group. The reformed reactor in which the mixed raw material moisture is introduced and heated by combustion to perform a steam reforming reaction, a water gas reactor for converting carbon monoxide into a water gas from the reformed gas, a PSA for hydrogen separation, and a process It consists of a heat exchange network to optimize thermal energy.

Specifically, referring to FIG. 1, a hydrogen desulfurizer for hydrodesulfurizing a raw hydrocarbon; A reforming reactor in which the raw material moisture mixed with the hydrocarbon material desulfurized from the hydrogen desulfurizer is introduced, and heated by a burner to perform a steam reforming reaction; An aqueous gas reactor for converting carbon monoxide to an aqueous gas with respect to the reformed gas from the reforming reactor; And a PSA for hydrogen separation,

A heat exchanger 4 for exchanging heat with the hot exhaust gas discharged from the burner to overheat the raw material moisture with a single phase water vapor before mixing with the desulfurized hydrocarbon raw material;

A heat exchanger 1 that heats the mixture of the desulfurized hydrocarbon raw material and the superheated steam with a reforming gas discharged from the reforming reactor and introduces the reforming reactor;

A heat exchanger 3 for exchanging heat with external air so that the reformed gas that has passed through the heat exchanger 1 is cooled before being introduced into the water gas reactor;

A heat exchanger 7 for exchanging heat with cooling water so that the conversion gas generated from the water gas reactor is reduced before being introduced into the PSA; And

In order to heat the mixture of the hydrocarbon raw material and the hydrogen recycled from the PSA by heat exchange with reforming gas, a heat exchanger 2 provided between the heat exchanger 1 and the heat exchanger 3 is included.

Furthermore, it is preferable that the hydrogen production apparatus of the present invention further comprises a heat exchanger 5 disposed between the water gas reactor and the heat exchanger 7 to heat the PSA exhaust gas by heat exchange with the conversion gas.

In addition, in the hydrogen production apparatus of the present invention, it is more preferable that the heat exchanger 6 that heats the raw material moisture, for example, demineralized water by heat exchange with the conversion gas, is replaced or further included.

In this case, the heat exchanger 6 is more preferably disposed between the heat exchanger 5 and the heat exchanger 7.

In the hydrogen production apparatus of the present invention, it is preferable that a part of the hydrocarbon raw material not supplied to the hydrogen desulfurizer, the air heated in the heat exchanger 3, and the exhaust gas of the PSA are supplied to the burner.

In this case, the exhaust gas of the PSA is preferably heated by the heat exchanger 5 disposed between the water gas reactor and the heat exchanger 7.

The heat exchangers 1 to 7 may be finned tube heat exchangers, plate type heat exchangers, multitube hairpin types or shell and tube type heat exchangers. You can. More preferably, a multitube hairpin type heat exchanger with a finned tube having a true counter current method and a twisted tape vortex generator is preferably used. Can be used.

The hydrocarbon raw material may be a gaseous or liquid hydrocarbon including natural gas, LPG, Naphtha, and the like. Preferably, natural gas can be used, and the natural gas is divided into two parts: raw material (Feed) and fuel (Fuel), the raw material is provided to the hydrogen desulfurizer, and the fuel is provided to the burner.

The hydrocarbon raw material supplied to the hydrogen desulfurizer is mixed with hydrogen recycled from the PSA and heated up by heat exchange with reforming gas in the heat exchanger 2 disposed between the heat exchanger 1 and the heat exchanger 3.

The main component of the catalyst poison of the reforming reactor and water gas reactor catalyst is the sulfur component. Therefore, it is necessary to completely remove the sulfur component in natural gas or LPG as a reaction raw material. The sulfur component in natural gas is easily removed by the physical adsorbent at room temperature. However, the sulfur component inside LPG is not removed by physical adsorption.

In the present invention, after the sulfur component is converted to hydrogen sulfide by a hydrogen desulfurization reaction using hydrogen, the sulfur component is completely removed using a chemical adsorbent such as ZnO. In this case, as the hydrogen desulfurization catalyst used, for example, metals such as cobalt, zinc, copper, molybdenum, nickel, or metal oxides or emulsions, zeolites or activated carbons can be used, and depending on the reaction raw material or process conditions, Hydrodesulfurization is performed at temperature.

Such a hydrogen desulfurization method has excellent performance compared to a physical adsorption method, and thus, an equal or higher effect can be obtained even in a compact adsorption device. As shown in FIG. 1, the reaction raw material is mixed after recirculating a part of the produced hydrogen, heated through the heat exchanger 2 to 300 deg. C, which is the operating temperature of the hydrogen desulfurizer, and then desulfurized by entering into the hydrogen desulfurizer.

At this time, the amount of hydrogen used is 10 to 500 times based on the sulfur content of the raw material, it is possible to control the recycle amount according to the sulfur content of the raw material.

The desulfurized raw material is mixed with water vapor that has passed through the heat exchanger 4 and then heat-exchanged with the reformed gas in the heat exchanger 1 to enter the reforming reactor.

The reformed reactor is supplied by mixing the desulfurized reaction raw material and the raw material water vapor, and the raw material water vapor is exchanged by using the combustion flue gas of the reforming reactor burner and heat exchanger 4 to overheat the demineralized water to 160 ~ 350 ℃. To make the superheated water vapor, it is possible to preheat using heat exchanger 6 to further increase the thermal efficiency and stably generate water vapor. In the heat exchanger 6, heat efficiency is maximized by exchanging demineralized water at room temperature with a conversion gas (Reformate 2) to preheat to 40 to 100 ° C.

After the desulfurized raw material and raw material steam are mixed, they are heat-exchanged in a reforming reactor (Reformate 1) and heat exchanger 1 from the reforming reactor and heated to 400 to 600 ° C to be supplied to the reforming reactor.

The raw material moisture contained in the raw material by the temperature rise by the heat exchange as described above does not flow into the reforming reactor in two phases, liquid phase and gas phase, and maintains a single phase in the vaporized state while sufficiently vaporizing. Introduced to provide optimum reaction conditions for reforming catalysts.

At this time, the amount of raw water vapor supplied to the reforming reactor is preferably mixed at a ratio of steam to carbon molar ratio (S / C: 1: 2.5 to 4.0), where the S / C ratio is less than 2.5. When the reforming catalyst is poisoned by carbon due to lack of water vapor, there is a problem that performance is deteriorated, and when it exceeds 4.0, it is not preferable because there is a problem that thermal efficiency decreases due to excessive water vapor injection.

The reforming reactor prepares a high-concentration hydrogen-containing gas by contacting the mixture with a reforming catalyst and steam reforming. A burner for heating the reforming reactor from the outside is provided under the reforming reactor.

The reforming reactor includes a catalyst filled to allow the mixture to flow, and the filled catalyst is preferably supported by ruthenium or nickel on an alumina or silica carrier.

The steam reforming of hydrocarbons in the reforming reactor is carried out by the following reaction.

C _m H _n + mH ₂ O → mCO + (m + n / 2) H ₂

CO + 3H ₂ ↔ CH ₄ + H ₂ O

CO + H ₂ O ↔ CO ₂ + H ₂

The reforming reactor is heated and heated by a burner, and maintains an operating temperature of 700 to 850 ° C to supply the heat of reaction necessary for catalytic reaction.

The temperature of the exhaust gas discharged after heating the reforming reactor is introduced into the heat exchanger 4 at 600 to 700 ° C., and the reformed gas (CO, CO ₂ , CH ₄ , H ₂ ) converted through the reforming reaction is 500 to 600. It is introduced to the water gas reactor through heat exchangers 1 to 3 at a temperature of ℃.

The reformed gas heats up with the raw material of the reforming reactor in the heat exchanger 1 to lower the temperature, supplies heat to the hydrogen desulfurizer raw material through the heat exchanger 2, and preheats the air supplied to the burner in the heat exchanger 3 and finally It is adjusted to a temperature suitable for a water gas reactor, 170 ° C to 200 ° C. The water gas reaction is thermodynamically better as the temperature is lower, but when it is too low, the reaction rate is slowed down. Therefore, the reforming gas is started at 170 ° C to 200 ° C in the water gas reactor.

The water gas conversion reaction in the water gas reactor is known in the art and consists of CO + H ₂ O ↔ CO ₂ + H ₂ . The water gas reactor is filled with a water gas conversion catalyst that converts carbon monoxide in the reformed gas to carbon dioxide and hydrogen, and a catalyst that is an oxide of iron-chromium or copper-zinc-based oxide may be preferably used as the water gas conversion catalyst.

Since the water gas reaction is an exothermic reaction, and the thermodynamically lower temperature is better, the outlet temperature of the reactor is controlled to 265 ° C or less.

The conversion gas (Reformate 2) generated in the water gas reactor is exchanged in the cooling water and the heat exchanger 7 to be adjusted to a temperature suitable for PSA introduction. As shown in FIG. 1, the conversion gas from the water gas reactor is generally 250 to 260 ° C, but in the case of the PSA, a hydrogen separation device connected to the rear end, the separation efficiency is better when the temperature of the conversion gas is lower and 40 ° C or less Is asking. For higher separation efficiency, heat exchanger 7 is usually used to lower the temperature with cooling water. In this case, it results in wasting the thermal energy held by the conversion gas.

Therefore, in the present invention, two heat exchangers were additionally used to improve thermal efficiency and process stability. Through the heat exchanger 5, the PSA exhaust gas used as the fuel of the reforming reactor burner was able to recover some heat from the conversion gas.

In addition, through the heat exchanger 6, demineralized water used as raw water vapor was used to recover some heat from the conversion gas.

That is, the hydrogen production apparatus of the present invention further comprises a heat exchanger 5 between the water gas reactor and the heat exchanger 7, to heat the PSA exhaust gas by exchanging heat with the conversion gas.

In addition, it is more preferable that the hydrogen production apparatus of the present invention further includes a heat exchanger 6 that heats the demineralized water by heat exchange with the conversion gas. In this case, the heat exchanger 6 is preferably disposed between the heat exchanger 5 and the heat exchanger 7.

In addition, the PSA flue gas preheated in the heat exchanger 5 was supplied to the burner of the reformer reactor to be configured to recover heat. The material supplied to the burner of the reforming reactor is composed of natural gas as fuel, LPG, etc., air heated in the heat exchanger 3 and PSA exhaust gas heated in the heat exchanger 5.

Pressure swing adsorption (PSA) is a process generally employed for hydrogen separation in the art, and pressure swing adsorption separation means adsorption and removal of impurities other than hydrogen by a adsorbent from a high-concentration hydrogen-containing gas, resulting in high purity hydrogen. It is a method of purification.

The high purity hydrogen separated from the PSA is stored in a hydrogen storage tank or used without a storage device to be used as a hydrogen fuel for a fuel cell or a hydrogen electric vehicle, and the exhaust gas from the PSA is used as a burner fuel for heating the reforming reactor. Recycled to maximize thermal efficiency.

Although the embodiments of the present invention have been described in detail above, the scope of rights of the present invention is not limited to this, and various modifications and variations are possible without departing from the technical spirit of the present invention as set forth in the claims. It will be apparent to those of ordinary skill in the field.

Claims (12)

Hydrogen desulfurizer for hydrodesulfurizing the raw hydrocarbon; A reforming reactor in which the raw material moisture mixed with the hydrocarbon material desulfurized from the hydrogen desulfurizer is introduced, and heated by a burner to perform a steam reforming reaction; An aqueous gas reactor for converting carbon monoxide to an aqueous gas with respect to the reformed gas from the reforming reactor; And hydrogen production apparatus including a pressure swing adsorption (PSA) for hydrogen separation,
A heat exchanger 4 for exchanging heat with the combustion exhaust gas discharged from the burner to overheat the raw material moisture with a single phase water vapor before mixing with the desulfurized hydrocarbon raw material;
A heat exchanger 1 for heat exchange of the mixture of the desulfurized hydrocarbon raw material, hydrogen recycled from PSA, and the superheated steam with reforming gas discharged from the reforming reactor and introducing the reforming reactor;
A heat exchanger 3 for exchanging heat with external air so that the reformed gas that has passed through the heat exchanger 1 is cooled before being introduced into the water gas reactor;
A heat exchanger 7 for exchanging heat with cooling water so that the conversion gas generated from the water gas reactor is reduced before being introduced into the PSA;
A heat exchanger 2 provided between the heat exchanger 1 and the heat exchanger 3 to heat the mixture of the hydrocarbon raw material and the hydrogen recycled from the PSA by heat exchange with the reformed gas and then introduce the hydrogen desulfurizer; And
And a heat exchanger 5 disposed between the water gas reactor and the heat exchanger 7 to heat the PSA exhaust gas by exchanging it with the conversion gas. delete The apparatus for producing hydrogen according to claim 1, wherein the heat exchanger 6 that heats the raw material moisture by heat exchange with the conversion gas replaces or additionally includes the heat exchanger 7. The hydrogen production apparatus according to claim 3, wherein the heat exchanger (6) is disposed between the heat exchanger (5) and the heat exchanger (7). The hydrogen production apparatus according to claim 1, wherein a part of the hydrocarbon raw material, air heated in the heat exchanger 3, and exhaust gas of the PSA are supplied to the burner. The hydrogen production apparatus according to claim 5, wherein the exhaust gas of the PSA is heated by the heat exchanger (5) disposed between the water gas reactor and the heat exchanger (7). According to claim 1 or 3, wherein the heat exchangers 1 to 7 are finned tube heat exchangers, plate type heat exchangers, multitube hairpin types or cell and tube. Hydrogen production device, which is a heat exchanger of shell and tube type. The apparatus for producing hydrogen according to claim 1, wherein the hydrocarbon raw material is a gaseous or liquid hydrocarbon containing at least one of natural gas, LPG, and naphtha. The method of claim 1, wherein the reforming reactor includes a catalytic reaction part filled with a catalyst to enable the mixture to flow,
The catalyst filled in the catalytic reaction unit is a ruthenium (ruthenium) or nickel hydrogen production device that is supported on alumina (alumina) or silica (silica) carrier. According to claim 1, The catalyst in the hydrogen desulfurization group is at least one metal or metal oxide or emulsion selected from cobalt, zinc, copper, molybdenum and nickel; Zeolite; Or a device for producing hydrogen containing activated carbon. The hydrogen production apparatus according to claim 1, wherein the amount of raw water vapor supplied to the reforming reactor is mixed in a ratio of water vapor to carbon molar ratio of 1: 2.5 to 4.0. The hydrogen production apparatus according to claim 1, wherein the catalyst in the water gas reactor is an iron-chromium catalyst or a copper-zinc catalyst.

Images