WO2022160487A1 - Modified nickel-iron composite oxygen carrier, preparation method for same, and applications thereof - Google Patents

Abstract

The present invention relates to the technical field of chemical chain combustion oxygen carriers and specifically relates to a modified nickel-iron composite oxygen carrier, a preparation method for same, and applications thereof. The preparation method of the present invention: nickel oxide, ferric oxide, and a modifier are added with water, mixed evenly, and then dried to produce a precursor, and the precursor is calcinated at 900-1000 °C for 6-9 h to produce the modified nickel-iron composite oxygen carrier. The modifier is a mixture of one or more of cerium oxide, aluminum oxide, and zirconium oxide. Per the present invention, the modifier is added on the basis of a patent application, the structural stability of the oxygen carrier is improved, increased redox activity is provided, the quality of a prepared synthetic gas and hydrogen is further increased, at the same time, the material defect of the nickel-iron composite oxygen carrier having poor cycle performance is solved, the preparation method is simple and easy, and mass production applications are favored.

Description

A kind of modified nickel-iron composite oxygen carrier and its preparation method and application 【Technical field】

The invention belongs to the technical field of chemical chain combustion oxygen carriers, and particularly relates to a modified nickel-iron composite oxygen carrier and a preparation method and application thereof.

【Background technique】

Hydrogen energy is an ideal secondary energy carrier. The main product of combustion in the air is water, which does not cause any environmental pollution. It has become an important direction of energy development in the world. However, at present, hydrogen production at home and abroad mainly comes from the reforming process of fossil fuels, and its preparation needs to go through processes such as gas purification, synthesis gas reforming, shift and pressure swing adsorption. This method is not only complicated in process, but also has high energy consumption and low hydrogen production efficiency. At the same time, the value of syngas itself is ignored, such as combustion for heat supply, power generation, or the preparation of high-value fuels such as ethanol through Fischer-Tropsch synthesis. The chemical chain technology is a new way of efficient conversion and utilization of energy. Through the coupling and series connection between different reactors, the preparation of high-purity hydrogen and high-purity syngas can be realized. Bio-oil, as a form of biomass energy with high energy density and easy storage, has received extensive attention in recent years. However, bio-oil is directly hydrogenated to produce biodiesel, and it is used for chemical chain hydrogen production or synthesis gas, which faces the phenomenon of low hydrogen purity, deactivation of oxygen carrier, agglomeration and sintering.

In the previously submitted patent application CN202011629463.6, a nickel-iron composite oxygen carrier and its preparation method and application, the inventor of the present application proposes the preparation and application of a nickel-body composite oxygen carrier, which realizes the combination of high-purity hydrogen and synthesis gas. Co-preparation, in which the purity of syngas is close to 80%, and the H ₂ /CO ratio is 2; the purity of hydrogen is also as high as 95% or more, which fully meets the industrial application and greatly promotes the high-value utilization of bio-oil. However, in the follow-up further research, it was found that the nickel-body composite oxygen carrier showed obvious sintering and agglomeration during multiple cycles, the hydrogen yield and purity decreased significantly, and its structural stability was destroyed. Do not take advantage of long-term use.

Therefore, further modification and optimization of the nickel-iron composite oxygen carrier is required.

[Content of the invention]

In view of the above defects or improvement needs of the prior art, the present invention provides a modified nickel-iron composite oxygen carrier, which improves the structural stability of the oxygen carrier by doping with modifiers such as cerium oxide, aluminum oxide, and zirconium oxide. The quality of the synthesis gas and hydrogen prepared is further improved, and the material defect of the nickel-iron composite oxygen carrier with poor circulation performance is solved at the same time.

In order to achieve the above purpose, according to one aspect of the present invention, there is provided a method for preparing a modified nickel-iron composite oxygen carrier. The modified nickel-iron composite oxygen carrier can be obtained by calcining the body at 900-1000° C. for 6-9 hours, and the modifier is a mixture of one or more of ceria, alumina and zirconia.

Preferably, the modifier is cerium oxide.

Preferably, the mass ratio of the nickel oxide, ferric oxide and the modifier is (15-25): (50-60): (15-25), preferably, the nickel oxide and the three The mass ratio of ferrous oxide is 1:4.

Preferably, the temperature of constant temperature drying is 100-120°C, and the drying time is 6-9h.

Preferably, the nickel oxide, the ferric oxide and the modifier are uniformly mixed by ball milling.

According to another aspect of the present invention, a modified nickel-iron composite oxygen carrier is provided, which is prepared according to the aforementioned preparation method.

According to another aspect of the present invention, an application of the modified nickel-iron composite oxygen carrier is provided, and the application is an application of coupling hydrogen production and synthesis gas based on chemical chain technology.

As preferably, the following steps are included:

(1) The modified nickel-iron composite oxygen carrier is mixed with bio-oil and reacted to obtain the modified nickel-iron composite oxygen carrier and synthesis gas in a reduced state;

(2) reacting the modified nickel-iron composite oxygen carrier in the reduced state with water vapor to obtain hydrogen, and the modified nickel-iron composite oxygen carrier in the reduced state is partially oxidized;

(3) The partially oxidized modified nickel-iron composite oxygen carrier is completely oxidized by air to complete the regeneration.

Preferably, water vapor is also added in the step (1), and the ratio of the liquid volume of the water vapor to the liquid volume of the bio-oil is 1.2-2.

Preferably, the reaction temperature of the step (1), step (2) and step (3) is 900°C, the bio-oil is obtained by pyrolysis of organic solid waste, and the synthesis gas is a mixed gas of CO and H2 .

The beneficial effects of the present invention are:

(1) In the present invention, a modifier is added on the basis of the patent application CN202011629463.6 to improve the structural stability of the oxygen carrier. The addition of CeO ₂ leads to the formation of Ce-Fe-O solid solution and perovskite structure CeFeO ₃ , which has higher redox activity; at the same time, it has a good supporting effect on the stable existence of NiFe ₂ O ₄ structure, thus effectively The sintering phenomenon caused by the collapse of the pore structure is prevented, the quality of the prepared synthesis gas and hydrogen is further improved, and the material defect of poor cyclic performance of the nickel-iron composite oxygen carrier is solved.

(2) The modified nickel-iron composite oxygen carrier of the present invention has higher activity, stronger target product selectivity, more prominent hydrogen production capacity, the prepared synthesis gas has a purity of 81%, and the synthesis gas yield is further improved to 2.01Nm ³ / kg (bio-oil), the purity of hydrogen is as high as 95%, and the hydrogen yield is increased to 0.724Nm ³ /kg (bio-oil), and there are no negative effects such as oxygen carrier performance decline and hydrogen yield decline in multiple cycles.

(3) the application of the modified nickel-iron composite oxygen carrier of the present invention in the co-production of hydrogen and synthesis gas, compared with the existing chemical chain technology and previous patents, not only overcomes the application defect of bio-oil in the chemical chain technology, It promotes the higher-value utilization of bio-oil, and at the same time shows excellent stability in long-term recycling, which is more in line with practical industrial applications.

【Description of drawings】

FIG. 1 is the XRD patterns of the composite oxygen carriers prepared in Examples 1-3 of the present invention and Comparative Example 1. FIG.

2 is a SEM image of the composite oxygen carrier prepared in Comparative Example 1 of the present invention.

3 is a SEM image of the composite oxygen carrier prepared in Example 1 of the present invention.

4 is a SEM image of the composite oxygen carrier prepared in Example 2 of the present invention.

5 is a SEM image of the composite oxygen carrier prepared in Example 3 of the present invention.

Fig. 6 is the test chart of the synthesis gas yield of application examples 1.1-1.4.

Fig. 7 is the hydrogen purity test chart of application examples 1.1-1.4.

Fig. 8 is the XRD test chart of the phase structure of the bio-oil reduction stage of application examples 1.1-1.4.

Fig. 9 is the test chart of the synthesis gas yield of application examples 2.1-2.4.

Fig. 10 is the hydrogen purity test chart of application examples 2.1-2.4.

Figure 11 is the XRD pattern of the composite oxygen carrier after 5 cycles of application examples 2.1-2.4.

Figure 12 is the SEM image of the composite oxygen carrier after 5 cycles of application example 2.4.

Figure 13 is the SEM image of the composite oxygen carrier after 5 cycles of Application Example 2.1.

Figure 14 is the SEM image of the composite oxygen carrier after 5 cycles of Application Example 2.2.

Figure 15 is the SEM image of the composite oxygen carrier after 5 cycles of application example 2.3.

【Detailed ways】

In order to make the objectives, technical solutions and advantages of the present invention clearer, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention, but not to limit the present invention. In addition, the technical features involved in the various embodiments of the present invention described below can be combined with each other as long as they do not conflict with each other.

Example

Example 1

A CeO ₂ modified nickel-iron composite oxygen carrier is prepared by the following method:

(1) Weigh 15g of nickel oxide (NiO) powder, 60g of iron oxide (Fe ₂ O ₃ ) powder, and 25g of cerium oxide (CeO ₂ ) powder and pour them into the ball mill jar together, and then add 200ml of deionized water to the jar , at a speed of 300r/min, ball milling for 2 hours.

(2) Pour the solution in the ball mill into a beaker, dry it in a constant temperature drying oven at 105°C for 6 hours, evaporate excess solvent water to obtain a precursor, put the precursor in a muffle furnace, and calcine at 900°C for 6 hours , to obtain a nickel-iron composite oxygen carrier, which is denoted as Ni15Fe60Ce25 composite oxygen carrier.

Example 2

A ZrO ₂ modified nickel-iron composite oxygen carrier is prepared by the following method:

(1) Weigh 15g of nickel oxide (NiO) powder, 60g of iron oxide (Fe ₂ O ₃ ) powder, and 25g of zirconia (ZrO ₂ ) powder and pour them into the ball mill jar together, and then add 200ml of deionized water to the jar , at a speed of 300r/min, ball milling for 2 hours.

(2) Pour the solution in the ball mill into a beaker, dry it in a constant temperature drying oven at 105°C for 6 hours, evaporate excess solvent water to obtain a precursor, put the precursor into a muffle furnace, and calcine it at 900°C for 6 hours hours, the nickel-iron composite oxygen carrier was obtained, which was denoted as Ni15Fe60Zr25 composite oxygen carrier.

Example 3

An Al ₂ O ₃ modified nickel-iron composite oxygen carrier is prepared by the following method:

(1) Weigh 15g of nickel oxide (NiO) powder, 60g of iron oxide (Fe ₂ O ₃ ) powder, and 25g of alumina (Al ₂ O ₃ ) powder and pour them into the ball mill jar together, and then add 200ml to the jar. Ionized water, ball milled at 300r/min for 2 hours.

(2) Pour the solution in the ball mill into a beaker, dry it in a constant temperature drying oven at 105°C for 6 hours, evaporate excess solvent water to obtain a precursor, put the precursor into a muffle furnace, and calcine it at 900°C for 6 hours hours, a nickel-iron composite oxygen carrier is obtained, which is denoted as Ni15Fe60Al25 composite oxygen carrier.

Comparative Example 1

(1) Weigh 20g of nickel oxide (NiO) powder and 80g of iron oxide (Fe ₂ O ₃ ) powder, pour them into the ball mill jar together, then add 200ml of deionized water to the jar, and at a rotational speed of 300r/min, Ball mill for 2 hours.

(2) Pour the solution in the ball mill into a beaker, dry it in a constant temperature drying oven at 105°C for 6 hours, evaporate excess solvent water to obtain a precursor, put the precursor in a muffle furnace, and calcine at 900°C for 6 hours , to obtain a nickel-iron composite oxygen carrier, denoted as Ni20Fe80 composite oxygen carrier.

Test Example

1. XRD test test. The oxygen carriers prepared in Examples 1-3 and Comparative Example 1 were subjected to XRD test, and the test results are shown in FIG. 1 . Like Ni20Fe80, the oxygen carriers modified by the three metals all have three crystal phase structures of Fe ₂ O ₃ , NiFe ₂ O ₄ and NiO, and the positions of the peaks are basically the same, which indicates that the doping of the modified metal has an effect on Ni/O. The formation of the structure between Fe has no effect; in addition, the phases of CeO ₂ , Al ₂ O ₃ and ZrO ₂ exist independently, and do not form a new phase structure with NiO or Fe ₂ O ₃ at high temperature during the preparation process .

2.SEM test. The oxygen carriers prepared in Examples 1-4 and Comparative Example 1 were carried out, and the test results are shown in Figures 2-5. The oxygen carriers doped with the three modifiers have significantly better dispersion and richer pore structure.

Application Example

1. The first set of application examples. In a fixed-bed tubular reactor, the oxygen carrier is passed into bio-oil successively to prepare synthesis gas, and then steam is used to prepare hydrogen, as described below.

Application Example 1.1 Ni15Fe60Ce25 Composite Oxygen Carrier

(1) Weigh 10g of the oxygen carrier and put it into the fixed-bed tubular reactor, heat it up to 900°C in an air atmosphere, and then blow it with nitrogen for 10min. After purging the air in the tube, use a syringe pump to pass in a total of 2.8ml, Bio-oil with a flow rate of 0.14ml/min and 3.36ml of water vapor with a flow rate of 0.168ml/min; at the same time, the content and yield of exhaust gas components were analyzed by online chromatography;

(2) When the concentration of each gas component in the chromatography is reduced to below 0.5%, 10 ml of deionized water with a flow rate of 0.165 ml/min is introduced, and the hydrogen concentration and output are analyzed by on-line chromatography.

Among them, the carrier gas flow rate (air, nitrogen) is 500ml/min; the unit of time interval for chromatographic recording of tail gas components is seconds, and the content of each component in the tail gas is calculated on the basis of 500ml/min nitrogen.

Application Example 1.2 Ni15Fe60Zr25 composite oxygen carrier.

Application Example 1.3 Ni15Fe60Al25 composite oxygen carrier.

Application Example 1.4 Ni20Fe80 composite oxygen carrier.

2. The second set of application examples. The difference between this application example and the first group of examples is that the composite oxygen carrier is tested for 5 cycles, as described below.

Application Example 2.1 Ni15Fe60Ce25 Composite Oxygen Carrier

(1) Weigh 10g of the oxygen carrier and put it into the fixed-bed tubular reactor, heat it up to 900°C in an air atmosphere, and then blow it with nitrogen for 10min. After purging the air in the tube, use a syringe pump to pass in a total of 2.8ml, Bio-oil with a flow rate of 0.14ml/min and 3.36ml of water vapor with a flow rate of 0.168ml/min; at the same time, the content and yield of exhaust gas components were analyzed by online chromatography;

(2) When the concentration of each gas component in the chromatography is reduced to below 0.5%, 10 ml of deionized water with a flow rate of 0.165 ml/min is introduced, and the hydrogen concentration and output are analyzed by on-line chromatography.

(3) Introduce air again until the oxygen component in the chromatogram reaches about 21%, which means that the oxygen carrier is completely oxidized and regenerated; then continue to repeat (1) (2) (3) until it reaches 5 times.

Among them, the carrier gas flow rate (air, nitrogen) is 500ml/min; the unit of time interval for chromatographic recording of tail gas components is seconds, and the content of each component in the tail gas is calculated on the basis of 500ml/min nitrogen.

Application Example 2.2 Ni15Fe60Zr25 composite oxygen carrier.

Application Example 2.3 Ni15Fe60Al25 composite oxygen carrier.

Application Example 2.4 Ni20Fe80 composite oxygen carrier.

Application examples 1.1-1.4 will be used to test the synthesis gas yield, and the test results are shown in Figure 6 . It can be seen from Fig. 6 that compared with Ni20Fe80, the Ni15Fe60Ce25 oxygen carrier increases the syngas yield from 1.77Nm ³ /kg to 2.01Nm ³ /kg, and the syngas purity from 78.9% to about 81%. At the same time, H ₂ /CO The ratio increased from 1.98 to 2. This positive change is due to _CeO2 not only has a strong oxygen transfer rate, but also has a higher selectivity to syngas. The synthesis gas yield of Ni15Fe60Zr25 oxygen carrier increased slightly, but H ₂ /CO decreased significantly, because ZrO ₂ is an inert carrier and does not directly participate in the reaction.

The hydrogen purity test will be carried out in application examples 1.1-1.4, and the test results are shown in FIG. 7 . It can be seen from Figure 7 that the purity and yield of hydrogen on the Ni15Fe60Ce25 modified oxygen carrier are further improved compared with the Ni20Fe80 oxygen carrier. This is because there is also a positive synergy between Fe ₂ O ₃ and CeO ₂ , and even a simple physical contact can improve the reducibility of Fe ₂ O ₃ ; in addition, the formation of Fe-Ce solid solution and the perovskite CeFeO 3 The occurrence of oxygen vacancies will greatly promote the generation of oxygen vacancies and accelerate the migration of lattice oxygen from the interior of the oxygen carrier to the surface. The Ni15Fe60Zr25 oxygen carrier showed a decrease in hydrogen purity and yield, which may be caused by the addition of the inert carrier ZrO ₂ , which reduced the content of the active component NiFe ₂ O ₄ and reduced the reduction of Fe ₂ O ₃ . Finally, through the observation of the hydrogen production ability of Ni15Fe60Al25 oxygen carrier, we found that its hydrogen yield and purity are abnormally low, which is due to the formation of inert spinel FeAl ₂ O ₄ during the reaction process, and this structure is not conducive to Fe Further reduction and oxidation of elements.

The XRD test was carried out on the phase structure of the bio-oil reduction stage of application examples 1.1-1.4, and the test results are shown in FIG. 8 . The reduced Ni15Fe60Ce25 oxygen carrier has a perovskite structure CeFeO ₃ . Compared with the Ni20Fe80 oxygen carrier, the Ni15Fe60Ce25 oxygen carrier has higher hydrogen yield and syngas yield, which is related to the appearance of this structure.

The Ni15Fe60Zr25 oxygen carrier has a large amount of Fe ₃ O ₄ structure after the reduction of bio-oil, which may be due to the addition of the inert carrier ZrO ₂ , which leads to the reduction of NiFe ₂ O ₄ inside the oxygen carrier, thereby improving the reduction difficulty of Fe ₂ O ₃ in disguise . But it can be seen that ZrO ₂ does not change in the reaction stage, which also proves that its own thermal stability is very good.

For the _Ni15Fe60Al25 oxygen carrier, the appearance of the inert spinel _FeAl2O4 was indeed found during the reduction stage, but the formation of another spinel, _AlFe2O4 , was also found _. AlFe ₂ O ₄ belongs to the high temperature phase, that is, it can only exist above 860 ℃, and it is formed by the mutual dissolution of Fe ₃ O ₄ and FeAl ₂ O ₄ at high temperature. FeAl ₂ O ₄ is very stable, and due to thermodynamic limitations, FeAl ₂ O ₄ hardly reacts with water vapor below 1123K, and the formation of AlFe ₂ O ₄ will greatly reduce the thermodynamic driving force of the redox reaction. The hydrogen capacity is significantly reduced.

The application examples 2.1-2.4 will be tested for 5 cycles of synthesis gas yield, and the test results are shown in FIG. 9 . It can be seen from Fig. 9 that the Ni15Fe60Ce25 oxygen carrier has the same yield of synthesis gas in 5 cycles, and the synthesis gas purity is maintained at about 81%; the synthesis gas yield of Ni15Fe60Zr25 oxygen carrier is the same, and the synthesis gas purity increases slightly with the increase of the number of cycles. However, the two modified oxygen carriers, Ni15Fe60Ce25 and Ni15Fe60Zr25, have higher synthesis gas purity and yield than Ni20Fe80 in multiple cycles. The yield and purity of Ni15Fe60Al25 oxygen carrier synthesis gas increased with the increase of cycle times. According to the research, it can be speculated that this may be due to the continuous increase of inert spinel FeAl ₂ O ₄ and solid solution AlFe ₂ O ₄ during multiple cycles. The oxygen release of the oxygen carrier lattice is seriously hindered, and the improvement of the synthesis gas yield and purity is caused by the reaction between more and more carbon deposits and water vapor in the FR reactor.

The hydrogen purity test will be carried out in application examples 2.1-2.4, and the test results are shown in FIG. 10 . It can be seen from Figure 10 that during the 5 cycles of hydrogen production, Ni15Fe60Ce25 not only has the highest hydrogen yield but also the hydrogen purity has been maintained at about 96%, and the performance of hydrogen and syngas production has been further improved, while showing excellent cycle stability. sex. This indicates that the doping of CeO ₂ and the formation of perovskite CeFeO ₃ ensure the cycling stability of oxygen carriers.

Ni15Fe60Zr25 also showed excellent cycle stability during 5 cycles. This is because ZrO2 has stronger structural stability and can ensure that the pore structure of the oxygen carrier does not change significantly during multiple cycles, thereby ensuring that the lattice oxygen is stable. The release rate is stable. However, the hydrogen yield and purity of Ni15Fe60Zr25 are relatively low, because ZrO ₂ does not participate in the reaction, and the structure of NiFe ₂ O ₄ decreases with the decrease of the relative mass fraction of Fe ₂ O ₃ , thus reducing the reducibility of Fe in the oxygen carrier.

Similarly, the obvious reduction of the hydrogen production capacity of the Ni15Fe60Al25 oxygen carrier is caused by the formation of two inert spinel structures, FeAl ₂ O ₄ and AlFe ₂ O ₄ during the reaction process, which has been obtained from the XRD characterization analysis in the previous section. confirmed. However, starting from the second cycle, the hydrogen production capacity of the Ni15Fe60Al25 oxygen carrier decreased significantly again, but the hydrogen yield was relatively stable in the subsequent cycles, and the hydrogen purity was maintained at about 85%. This also shows the stability of the structure of FeAl ₂ O ₄ and AlFe ₂ O ₄ from the side, which greatly alleviates the sintering phenomenon of Fe element during the reduction process.

The composite oxygen carrier after 5 cycles of application examples 2.1-2.4 was subjected to XRD test, and the test results are shown in Figure 11. The NiFe2O4 structure in the Ni20Fe80 oxygen carrier has obvious phase separation, while the crystallinity of NiFe2O4 in the three modified oxygen carriers Ni15Fe60Ce25, Ni15Fe60ZrO2 and Ni15Fe60Al25 is still high, indicating that the addition of modified metal ensures the stability of the oxygen carrier structure. However, Ni15Fe60Al25 still has the phase structure of FeAl2O4, which is unfavorable for hydrogen production. Therefore, combined with the above discussion and analysis, it can be concluded that Ni15Fe60Ce25 is the best modified oxygen carrier.

The composite oxygen carrier after 5 cycles of application examples 2.1-2.4 was tested by SEM, and the test results are shown in Figures 12-15. The Ni20Fe80 oxygen carrier has obvious pore structure collapse, and the surface agglomeration phenomenon is obvious, while the structure of the three modified oxygen carriers Ni15Fe60Ce25, Ni15Fe60ZrO2, Ni15Fe60Al25 is still stable, which shows that the addition of the three modified metals has the cycle stability of the oxygen carrier played a positive role. Among them, the pore structure of Ni15Fe60Ce25 oxygen carrier is more obvious, which is favorable for the release of lattice oxygen, and also proves the above related test results.

Those skilled in the art can easily understand that the above descriptions are only preferred embodiments of the present invention, and are not intended to limit the present invention. Any modifications, equivalent replacements and improvements made within the spirit and principles of the present invention, etc., All should be included within the protection scope of the present invention.

Claims (10)

1. A method for preparing a modified nickel-iron composite oxygen carrier, which is characterized in that: the nickel oxide, ferric oxide and modifier are mixed with water, and then dried to obtain a precursor, and the precursor is calcined at 900-1000 DEG C for 6-9h , the modified nickel-iron composite oxygen carrier can be obtained; the modifier is a mixture of one or more of cerium oxide, aluminum oxide and zirconium oxide.
2. The preparation method according to claim 1, wherein the modifier is cerium oxide.
3. The preparation method according to claim 1, wherein the mass ratio of the nickel oxide, ferric oxide and the modifier is (15-25): (50-60): (15-25), Preferably, the mass ratio of the nickel oxide to the ferric oxide is 1:4.
4. The preparation method according to claim 2 or 3, wherein the drying in step (1) is constant temperature drying, the temperature of the constant temperature drying is 100-120°C, and the drying time is 6-9h.
5. The preparation method according to claim 1, wherein the nickel oxide, the ferric oxide and the modifier are uniformly mixed by ball milling.
6. A modified nickel-iron composite oxygen carrier, characterized in that it is prepared according to the preparation method of any one of claims 1-5.
7. The application of the modified nickel-iron composite oxygen carrier according to claim 6, wherein the application is an application of coupling hydrogen production and synthesis gas based on chemical chain technology.
8. The application of the nickel-iron composite oxygen carrier according to claim 7, wherein the application of coupling hydrogen production and synthesis gas based on chemical chain technology comprises the following steps:

   (1) The modified nickel-iron composite oxygen carrier is mixed with bio-oil and reacted to obtain the modified nickel-iron composite oxygen carrier and synthesis gas in a reduced state;

   (2) reacting the modified nickel-iron composite oxygen carrier in the reduced state with water vapor to obtain hydrogen, and the modified nickel-iron composite oxygen carrier in the reduced state is partially oxidized;

   (3) The partially oxidized modified nickel-iron composite oxygen carrier is completely oxidized by air to complete the regeneration.
9. The application of the modified nickel-iron composite oxygen carrier according to claim 8, wherein water vapor is also added in the step (1), and the ratio of the liquid volume of the water vapor to the liquid volume of the bio-oil is 1.2-2.
10. The application of the modified nickel-iron composite oxygen carrier according to claim 9, wherein the reaction temperature of the step (1), step (2) and step (3) is 900°C, and the bio-oil is organic The solid waste is pyrolyzed, and the synthesis gas is a mixed gas of CO and H ₂ .

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