KR101712671B1 - Oxide supported transition metal catalyst prepared by plasma - Google Patents

Abstract

The present invention overcomes the problems of the conventional oxide-supported transition metal nanocatalyst production method. It is a method of evaporating or melting metal particles using a high-temperature thermal plasma of 3000 K or more, melting or partially liquefying the oxide particles, The present invention relates to a process for producing a nano-sized oxide-supported transition metal catalyst by reacting an oxidant with a high temperature at a high temperature in the same atmosphere and at a high temperature and quenching the molten oxide particle at a high temperature to provide an oxide-supported transition metal nano- .

Description

[0001] The present invention relates to an oxide supported transition metal catalyst prepared by using a plasma,

The present invention relates to a method for preparing an oxide-supported transition metal nanocatalyst using a plasma and a property of a transition metal-based nanocatalyst prepared using the method.

As the social demand for clean fuel increases and the world enters the era of high oil prices, in addition to the conventional petrochemical industry raw material production method which depends on petroleum resources, it is possible to modify relatively rich and low-cost resources such as methane, H2, and the like. In order to efficiently perform the methane reforming process, it is necessary to develop a new catalyst material which can treat a large amount of methane at a relatively low temperature and does not reduce the activity due to problems such as carbon deposition during long operation. As a result of many researches on the metal oxide transition metal nanocatalyst as a new catalyst material having such characteristics, In such an oxide-supported transition metal-based nano catalyst, the metal acts as a main catalyst showing strong activity for conversion of methane, and the oxide serves as a carrier to inhibit sintering and growth of the metal at a high temperature, As an oxygen supply source for removing oxygen. Therefore, in order to successfully produce such an oxide-supported transition metal-based nanocatalyst, it is necessary to minimize the size of the metal particle serving as a catalyst and to disperse the metal particle uniformly in the oxide carrier to maintain the high activity even at a low temperature. There is a need to develop a method of dissolving a catalyst metal on an oxide support so as to smoothly remove carbon deposited on the surface of the metal particles by receiving oxygen stored in the oxide support. Further, in the case of the methane reforming operation, since it operates at a high temperature of 500 ° C or higher in general, it is also required to have a mechanical characteristic that ensures smooth movement of oxygen atoms through the interface between the metal and the oxide at such a high temperature, do. Impregnation, co-precipitation and sol-gel methods are widely used for the conventional oxide-supported transition metal nanocatalyst production method which can partially realize such characteristics. For example, in the impregnation method, the metal oxide or the metal oxide solution used as a catalyst is impregnated into the porous oxide support, and the metal particles remain in the pores of the oxide support by appropriate chemical treatment and heat treatment, It is a method of making catalyst. Due to such process characteristics, the nanocatalyst prepared by the impregnation method can be widely used as a representative catalyst preparation method because it can make the wide specific surface area characteristic of the porous oxide support as it is, and can be relatively easily dispersed. However, when the content of the metal increases, the impregnated metal particles may diffuse to the surface of the oxide carrier mainly by chemical and thermal post-treatment, and may be distributed in a form that covers the surface. Thus, When used as a catalyst, it is easily sintered and becomes clogged with each other, which causes the activity to be lowered. When the catalyst is used as a catalyst, it is not easily supplied with oxygen and is poisoned easily. The co-precipitation method in which metal particles are precipitated together with the oxide support in a solution in which the metal salt is dissolved, or the sol-gel method in which the sol-state metal-oxide mixture is solidified through gelation, And the mutual solubility between the metal dissolved in the solvent and the oxide is caused. Therefore, there is a limit in the amount of the metal particles successfully dissolved in the oxide support, and therefore, when the content of the metal particles is increased, all of them cause similar problems. In addition, all of the above conventional methods are in a form of seeking employment between two metal and oxide particles at a low temperature, so that the bonding force therebetween is relatively weak and not only the thermal stability is lowered at a high temperature of 500 C or more, There is a disadvantage that poisoning by carbon deposition can not be avoided.

The object of the present invention is to overcome the problems of the conventional oxide-supported transition metal nanocatalyst manufacturing method by using a high-temperature thermal plasma of 3000 K or more to evaporate or melt the metal particles, melt or partially liquefy the oxide particles, A step of preparing a nano-sized oxide-supported transition metal-based catalyst by reacting a metal vapor or a droplet with a molten liquefied oxide particle heated at a high temperature in the same atmosphere and at a high temperature and rapidly quenching the molten oxide nanoparticle, Characteristics.

In order to accomplish the above object, there is provided a technique for synthesizing an oxide-supported transition metal nano catalyst using plasma. In order to constitute a desired metal-oxide composition, the raw materials are quantitatively determined, and the quantified raw materials are pulverized, Preparing a precursor by compounding the precursor through a calcination process, and injecting the precursor obtained in this step into a thermal plasma flame generated by using a high frequency induction coupled plasma torch, Metal and oxides having different thermal conductivities, melting points and vaporization points are vaporized, melted or partially liquefied to form a complex through the interaction of these vapors, droplets and solid phases, and as they are cooled, Metal and metal oxide particles with a metal oxide layer are made evenly distributed Synthesis of oxide-supported transition metal-based nano-catalysts using plasma

As described above, the present invention has a limitation in the amount of the metal atoms incorporated in the oxide support, and thus the content of the metal particles is limited. Further, the bonding force between the metal and the oxide is relatively weak, In comparison with the conventional oxide-supported transition metal-based nanocatalyst production process and its nanocatalysts, which are disadvantageous in that thermal stability at high temperature is deteriorated and poisoning due to carbon deposition is inevitable due to the use of metal as a catalyst for partial oxidation, The invention makes it possible to increase the metal particle content to more than 50 mol% by allowing mutual bonding by high temperature fusion between the metal and the oxide and massive employment of the metal atom through the fusion, To improve the stability of passion. In the low-temperature partial oxidation, a metal oxide layer such as NiO Since for, there is an effect that despite the relatively high conversion rate at a low temperature, and can prevent poisoning by carbon deposition.

1 and 2 are electron micrographs and transmission electron micrographs taken after the plasma treatment of the precursor.
Figure 3 is an XRD picture of the Ni-CeO2 nanocatalyst obtained after precursor and plasma treatment
Figures 4A and 4B show methane conversion rates
Figure 5 shows the transmission electron micrographs at 550 degrees after 24 hours

In order to achieve the above object, the present invention provides a method for producing a metal-oxide composite, comprising the steps of: 1) quantitating the raw materials to form a desired metal-oxide composition; pulverizing and mixing the quantified raw materials by a conventional method; (2) a step of injecting the precursor obtained through this step into an ultra-high temperature (3000 K or more) thermal plasma flame produced by using a high frequency induction coupled plasma torch, and 3) Among the precursors injected into the chamber, the metal is vaporized or melted and the oxide is vaporized, melted or partially liquefied; and 4) the vaporized metal particles or the molten droplets meet or fuse in the molten / A composite is formed through a high temperature reaction, and metal particles are precipitated and solidified on the surface of the oxide through quenching thereof It characterized by a process consisting of steps to be synthesized in the form of nanoparticles of polymer.

In addition, the oxide-supported transition metal nanocatalyst that can be produced using the above process has a structure in which metal and metal oxide particles having a size of 10 nm or less adhere to the surface of an oxide carrier having a size of 50 nm or less, And a metal oxide layer formed by impregnation with a support and solid solution. The metal content of the Ni-based nanocatalyst can be 30% or more (based on the molar ratio).

When the oxide-supported transition metal-based nano catalyst having the above characteristics is applied to a methane partial oxidation process performed at a CH4: O2 ratio of 2: 1, the methane conversion is 70% or more at 550.degree. Or more. Further, even when the methane partial oxidation step is carried out at 550 DEG C for a long period of time, it is characterized by almost no poisoning by carbon deposition.

In the process of producing the nano-sized metal-oxide composite, the precursor is prepared by uniformly mixing nano-metal raw materials having a size of 1 μm or less with nano-oxides having a size of 1 μm or less by a ball mill or the like, By injecting the carrier gas such as Ar into the plasma, the above object can be efficiently achieved. In this case, since there is no separate impurity such as a solvent contained in the precursor, unlike the impregnation method, the precipitation method, and the sol-gel method, there is an advantage that a chemical post treatment or a heat treatment step for drying the solvent is not necessary . On the other hand, a solution containing a metal for catalyst is injected into a porous oxide such as a general impregnation method, mixed in a slurry state, primary processed into a solid powder dried with particles of a predetermined size by a spray dryer or the like, Nitrogen, compressed air, or the like, and then supplied to the inside of the thermal plasma flame. In this case, the plasma is used as a heat source for drying the solvent in addition to the heat source for the above process. In addition, in the case where a specific substance which is difficult to be realized as a solid phase powder is added during the preparation of the precursor, or when the precursor is not smoothly transported due to the nature of the precursor processed in powder form, The above object can be achieved by a liquid phase in the form of a slurry well dispersed in a solvent suitable for realization, or a precursor in the form of a gas.

Hereinafter, the effects of the present invention will be described in detail by way of examples.

The following examples are intended to illustrate the specific application of the present invention, and the scope of the present invention is not limited to the examples.

[Example 1] Ni: Synthesis of Ni-CeO2 nanocatalyst with a molar ratio of CeO2 of 1: 1

1 and 2 show the results of a plasma treatment of a precursor in which a 200-nm-class Ni and a 200-nm-class CeO2 were quantified at a molar ratio of 1: 1 in order to synthesize a Ni-CeO2 nanocatalyst, (FE-SEM) and transmission electron microscope (TEM) photographs, and Fig. 3 is an XRD picture of the Ni-CeO2 nanocatalyst obtained after the plasma treatment with the precursor. 1, the overall size of the Ni-Ce2 nanocatalyst synthesized by plasma synthesis is 50 nm or less. From the results of EDX analysis of each position in FIG. 2 and FIG. 2, it can be seen that, as described above, Ni of the size of 10 nm or less is dispersed in the form of fused and dispersed, and these interfaces have mutually solid forms such as Ni-Ce-O. The plasma heat source used here is a 25.5 kW high-frequency thermal plasma, and the operating conditions are shown in Table 1 below.

From the XRD data in FIG. 3, it can be seen that the Ni-based particles present on the CeO2 surface have a small amount of Ni and most of the NiO-type as shown in FIG. 2 since the Ni content is relatively large. The CeO2 nanocatalyst shows that Ni and NiO particles having a size of 10 nm or less on the surface of CeO2 oxide of 50 nm or less are well dispersed in a 50% molar ratio with fusion and mutual employment at high temperature. In the methane reforming process, metal particles such as Ni usually catalyze a partial oxidation process (CH4 + 1 / 2O2 -> CO + 2H2) of methane in a temperature range between 500 ° C and 700 ° C, It is known to act as a complete combustion catalyst (CH4 + 2O2 -> CO2 + 2H2O) at high temperatures above 700 ℃. Accordingly, although it is known that there is no NiO activity in a normal low-temperature (500 ° C. to 700 ° C. or lower) methane partial oxidation process, when Ni particles are strongly bonded to the oxide support and Ni ++ ions are solidified with CeO 2 or the like, It is also known that vacancy occurs and this oxygen vacancy produces active oxygen species which is active at low temperature. Therefore, the NiO phase formed at the interface can participate in the methane partial oxidation process by reactive oxygen at low temperature. In the case of the plasma process in which Ni particles and CeO2 particles are melted and bonded at high temperature as in the present process, Compared with the conventional impregnation method and coprecipitation method, the amount of Ni ++ ion incorporated into CeO2 is greatly increased, so that the active oxygen species exhibiting activity at a low temperature is rapidly increased so that the conversion rate of methane is 70% or more . Since the NiO phase thus formed is readily reduced at low temperature by hydrogen, the presence and the effect of the Ni-CeO2 nanocatalyst can be evaluated by reducing the synthesized Ni-CeO2 nanocatalyst with hydrogen and conducting a methane partial oxidation test. FIG. 4 is a graph showing the result of performing the partial oxidation of methane after the reduction of the synthesized Ni-CeO2 nanocatalyst with hydrogen. According to this graph, the conversion rate of methane is 20% It can be seen that the over temperature shifts from 500 ° C. to 600 ° C., and it is understood from these that the NiO phase exhibited relatively high activity in the low temperature region.

As described above, the process for producing an oxide-supported transition metal-based nanocatalyst using the high-temperature thermal plasma of the present invention is advantageous in that, compared with the conventional low-temperature drying method such as impregnation method, precipitation method, sol- The synthesized Ni-CeO2 nanocatalyst and the like can be used not only for the partial oxidation of methane at a low temperature (550 deg. C) due to metal particles such as Ni but also for NiO and the like which are resistant to carbon poisoning (550 ° C) partial oxidation process by the oxide layer. As a result, it is possible to obtain a high-temperature (550 ° C) high methane conversion rate (70% It can be seen that the activity is not deteriorated even in operation and poisoning by carbon deposition is extremely small.

Claims (8)

In order to constitute a desired metal-oxide composition, the raw materials are quantitatively analyzed, and the quantified raw materials are pulverized and mixed and calcined to be compounded through a calcination process. Preparing a sphere,
Injecting the precursor obtained in this step into the thermal plasma flame generated by using the high frequency induction coupled plasma torch,
Forming a complex by means of thermal plasma flame, wherein the metals and oxides having different thermal conductivities, melting points and vaporization points are vaporized, melted or partially liquefied and these vapor, droplet and solid phase interactions interact;
And synthesizing nanoparticles in the form of a composite in which metal and metal oxide particles having a metal oxide layer are distributed while being cooled on the surface of the oxide,
The present invention relates to a transition metal-based nano-catalyst synthesis technique for supporting an oxide using plasma, characterized in that the precursor is injected into a plasma flame in the form of a slurry liquid delete delete delete In order to constitute a desired metal-oxide composition as a transition metal nano catalyst supporting an oxide using a plasma, the raw materials are quantitatively analyzed, and the quantified raw materials are pulverized and mixed and calcined to compound the precursor Preparing,
Injecting the precursor obtained in this step into the thermal plasma flame generated by using the high frequency induction coupled plasma torch,
Forming a complex by means of thermal plasma flame, wherein the metals and oxides having different thermal conductivities, melting points and vaporization points are vaporized, melted or partially liquefied and these vapor, droplet and solid phase interactions interact;
And synthesizing nanoparticles in the form of a composite in which metal and metal oxide particles having a metal oxide layer are distributed while being cooled on the surface of the oxide,
The precursor is injected into the plasma flame in the form of a slurry liquid
Transition metal nanocatalyst in the form of a metal-oxide complex having an average size of 10 nm to 50 nm,
delete 6. The nanocatalyst according to claim 5, which is characterized by having a metal oxide layer formed by solidification of metal-oxide interfacial metal atoms into an oxide, 6. The method according to claim 5, wherein in the methane partial oxidation test carried out at a molar ratio of CH4: O2 = 2: 1, the catalyst exhibits a methane conversion of at least 70% at 550 DEG C,

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