Ceramic membrane structure and oxygen separation method

Gas separation: processes – Selective diffusion of gases – Selective diffusion of gases through substantially solid...

Reexamination Certificate

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C096S004000, C096S011000

Reexamination Certificate

active

06514314

ABSTRACT:

FIELD OF THE INVENTION
The present invention relates to a ceramic membrane structure and method of separating oxygen with the use of the ceramic membrane structure. More particularly, the present invention relates to such a ceramic membrane structure and method in which the membrane structure is formed of a mixture of an ionic conducting material and a mixed conducting material. Even more particularly, the present invention relates to such a ceramic membrane structure and method in which the membrane structure is formed by dense and porous supporting layers that are formed from the mixture of materials.
BACKGROUND OF THE INVENTION
Oxygen-selective ceramic membranes are fabricated from a ceramic that conducts oxygen ions at high temperatures. In such a ceramic membrane, the heated membrane is exposed to an oxygen-containing gas that ionizes at a cathode side of the membrane. Under a driving force of a differential oxygen partial pressure, oxygen ions are transported through the membrane to an opposite anode surface. The oxygen ions combine at the anode surface of the membrane to give up electrons that are transported through the membrane or a separate electronic pathway to ionize the oxygen at the cathode side of the membrane.
The resistance to oxygen ion transport is in part dependent on the thickness of the membrane. Therefore, very thin membranes are desirable. A recent development in ceramic membrane technology is to form a thin dense layer of ion transport material on a porous support. The dense layer conducts oxygen ions and the supporting structure functions as a percolating porous network to add structural support to the dense layer. The porous support may also be fabricated from a material that is itself capable of transporting ions so as to be active in separating the oxygen.
The materials used in forming ceramic membrane can be classified as either mixed conductors that are capable of conducting both the oxygen ions and the electrons required to initially ionize the oxygen or ionic conductors that are capable of conducting only the oxygen ions. Ionic conductors require separate electrical pathways for the conduction of the electrons.
An example of an ionic conductor with separate electrical pathways can be found in U.S. Pat. No. 5,306,411. In this patent, solid membranes are disclosed that comprise a multi-phase mixture of an electronically conductive material such as a noble metal and an ion conductive material for use in oxygen separation from air for electrochemical reactions and applications. The oxygen ion conductor facilitates all the oxygen transport and the electronic conductor does not take part in the oxygen permeation but rather, provides the required electronic pathway for electrons.
In ion conducting materials such as discussed above, a volumetric inefficiency results from the fact that part of the volume of the membrane is taken up with the electronically conductive material that does not take part in ion transport. Mixed conducting materials can therefore be said to be more efficient than ion conducing materials on a volumetric basis. However, the ceramics utilized in mixed conductors present several problems in realizing a multi-layer composite having dense and active supporting layers. One major problem is that such ceramics, commonly oxygen deficient perovskites, are not particularly robust. This problem is addressed in U.S. Pat. No. 5,911,860 which discloses the addition of a metallic or ceramic second phase to a mixed conducting perovskite to improve the mechanical strength of the material and prevent microcracking. The ceramic second phase is not present above the percolation threshold and as such, does not contribute to the separation. Hence, such a material is also not as efficient in terms of oxygen ion transport on a volumetric basis as a membrane formed of the mixed conducting perovskite alone. Moreover, even where a strong material is selected for the porous supporting layer, there can be a thermal incompatibility between the dense layer and the supporting layer which arises from the materials making up such layers having different thermal coefficients of expansion.
It is to be noted that there have been materials fabricated from a mixture of a mixed conducting phase and an ionic conducting phase where the ionic conducting phase is present above the percolation limit. For instance, in V. Dusastre et al., “Optimization of Composite Cathodes for Intermediate Temperature SOFC Applications”, Solid State Ionics, Vol. 126, p163, a two phase porous material consisting of La
0.8
Sr
0.4
Co
0.2
Fe
0.8
O
3-&dgr;
(a mixed conductor) and Ce
0.9
Gd
0.1
O
2-&dgr;
(an ionic conductor) is used to improve the cathodic polarization of an electrode in a fuel cell. In the fuel cell structure disclosed in this article, the electrode is a thin layer of material of about 10-15&mgr;m without supporting capability that is used to conduct electrons from or to an external load. The electrolyte itself thus has a higher ionic conductivity than electronic conductivity and is not designed to conduct electrons. Another example of such a two phase mixture can be found in U.S. Pat. No. 5,478,444 which discloses a mixture of an oxygen ion conducting phase such as bismuth or cerium oxides and an electronic conducting phase such as a metal or perovskite. In this patent the oxygen ion conductor facilitates all the oxygen transport and the electronic conductor does not take part in the oxygen permeation.
A further problem with perovskites, is that chemically induced strains may be introduced in a supporting structure fabricated from such materials. As the oxygen partial pressure is reduced in a membrane formed from a perovskite, such as on the anode side thereof, there is an initial expansion followed by a substantial contraction. The contraction is due to the chemical instability of the material. The transition metal cations are reduced and the perovskite structure is no longer maintained. Prolonged exposure to a reduced oxygen partial pressure can produce an irreversible transition. Such problems are exacerbated where the supporting layer is exposed to a fuel gas such as in a reactive purge or in reforming operations because part of the membrane is exposed to the lowest oxygen activity in the membrane coupled with fuel diffusing into the membrane.
As will be discussed, the present invention provides a ceramic membrane structure and a method of separating oxygen in which the membrane structure has a dense layer supported by one or more active porous layers formed of a mixture of a mixed conductor and an ionic conductor that allows for a more efficient oxygen ion transport than membranes of the prior art. Moreover, a membrane of the present invention is more chemically stable, mechanically stronger and has superior creep resistance than membranes employing mixed conductors alone.
SUMMARY OF THE INVENTION
The present invention, in one aspect, provides a ceramic membrane structure for separating oxygen from an oxygen containing feed comprising a dense layer and at least one active porous layer. It is to be noted that the term, “oxygen containing feed” as used herein and in the claims means a gaseous mixture containing oxygen such as air or a gas containing oxygen in a combined form such as water. Furthermore, the term, “dense layer” as used herein and in the claims means a layer that is essentially impervious to the passage of the oxygen molecules to be separated from the gaseous mixture as opposed to a porous layer that would permit such passage. Such a layer can be made extremely thin to lessen the degree of resistance to oxygen ion transport through such a layer. A thin dense layer, however, has to be mechanically supported. The requisite support is provided by a porous supporting layer that is active so that it can take part in the oxygen ion transport.
In the present invention, the dense layer contains at least a mixed conducting material and the at least one active porous layer is formed of a mixture having an ion conducting phase capable of predominantly conducting oxygen

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