GB2140796A - Open-celled, electrically conductive ceramic network - Google Patents

Abstract

The ceramic network is made by impregnating an organic sponge with a semi-conducting ceramic dispersion and sintering the impregnated sponge to burn out the organic sponge and vitrify the ceramic. The dispersion consists of a mixture of a copper oxide, alumina and a modifier which is a compound M where M is a carbonate of magnesium, calcium, strontium, or barium, 6-45% silicone resin and an organic solvent or from 0.5-7% of a detergent and sufficient water so that the dispersion has a viscosity at 75 DEG of from 300 to 3000 cP. The relative proportions of the modifier and of alumina are such that the atom ratio of M to Al is from 0.5:1 to 2.0:1 and wherein the proportions of the copper oxide, alumina and modifier are such that the atom ratio Cu/(Al + M) is from about 0.5-4.0. The silicone resin consists essentially of a phenyl lower alkyl silicone resin wherein the total number of phenyl and lower alkyl groups divided by the number of silicon atoms is from 0.9-1.5 and each alkyl group has not more than four carbon atoms.

Description

1 1 45 GB 2 140 796A 1

SPECIFICATION

Open-celled, electrically conductive ceramic network BACKGROUND OF THE INVENTION 1. Field of the Invention The instant invention relates to open celled electrically semi-conducting and conducting ceramic networks and methods for their production. An open celled, electrically semi-conducting ceramic network of the instant invention is useful in a variety of applications, for example: 1) as a plate of an electrostatic precipitator, particularly useful because it can be operated in a corrosive environment, 2) as an electrically energized mixer and preheater for gases and liquids, 3) as an electrical resistor, and 4) as a particulate trap in the exhaust system of a diesel engine.

2. Description of the Prior Art

Open celled ceramics, their use as catalyst supports, and methods for producing them, are disclosed in U.S. Patent No. 4,083,905. The reference discloses fabrication of the ceramic supports by flocking an organic sponge with wood or textile fibers, impregnating the flocked sponge with an organic solvent dispersion containing alumina, a silicon resin and a flux, and sintering the impregnated organid sponge at a high temperature to vitrify the ceramic and burn out the sponge.

U.S. Patent No. 4,040,998 discloses an improvement on the invention of the above described patent. The improvement involves the use of a suitable detergent to enable the production of an aqueous dispersion of the alumina, silicone resin and flux. The open celled ceramic networks disclosed in both of these references are non-conducting, electrically.

U.S. Patent Nos. 3,046,328 and 3,247,132 both disclose, electrically conducting glass seals 25 which expand during firing and, therefore, are porous. However, the seals are confined during firing so that they form a closed cell structure which is an effective gas seal.

DEFINITION The terms -percent- and---parts-,as used herein and in the appended claims, refer to 30 percent and parts by weight, unless otherwise indicated.

SUMMARY OF THE INVENTION

The instant invention is based upon the discovery of electrically semiconducting and conducting open celled ceramic networks. The ceramic network is formed by impregnating an 35 organic foam material with a semi-conducting or conducting ceramic composition, and firing the impregnated material to burn out the foam and to vitrify the ceramic. The semi-conducting or conducting ceramic composition may comprise, on a solids basis, from 45 to 80 percent of a lead-free ceramic frit, from 5 to 15 percent of mono aluminum phosphate, from 6 to 45 percent of a silicone resin, from 0.2 to 13.2 percent of a conducting carbon compound, and an organic 40 solvent or water in an amount sufficient to form a dispersion having a viscosity ranging from 300 to 3000 centipoises, and, in the latter case, from 0.5 to 7 percent of a detergent. The electrically semi-conducting or conducting ceramic composition may also comprise, on a solids basis, a modified copper and alumina composition, from 6 to 45 percent of a silicone resin, and an organic solvent or water and detergent to produce a dispersion having a viscosity ranging 45 from 300 to 3000 centipoises. The organic solvent systems and the aqueous systems both constitute dispersions.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Samples of semi-conductive and conductive open celled ceramic bodies were prepared 50 according to the following procedures.

EXAMPLE I

An organic solvent dispersion was prepared from 48.3 parts of a phenyl lower alkyl silicone resin (commercially available under the designation "DC-840 Resin"), an aqueous solution, 50 55 percent solids, containing 8.9 parts of mono aluminum phosphate, 40.9 parts of a lead free ceramic frit, 2.9 parts of conductive carbon consisting essentially of 50 percent of a calcined lampblack (commercially available under the designation "Excelsior Lam pblack- Electric Calcined) and 50 percent of graphite (commercially available under the designation "Superior Superflake Graphite No. 3735"), and toluene, as required. The lead-free ceramic frit was composed of 2.8 60 percent of A1203, 21.4 percent of S'02, 25.9 percent of B203, 11.6 percent of Na20, 4.4 percent of CaO, 1.3 percent of Li,O and 32.6 percent of ZnO. The raw materials were placed in a large mortar and mixed with a pestle; toluene was added to adjust the viscosity of the dispersion to about 1500 centipoises.

Several samples of urethane sponge, each approximately 1 inch in diameter by I inch in 65 2 GB 2 140 796A 2 length, and containing 20 pores per linear inch, were coated with a plastic adhesive dissolved in a toluene-methyl ethyl ketone solvent. The coated sponges were then flocked by applying wood flour thereto. The wood flour was in a fluidized bed; the coated sponge samples were introduced into the fluidized bed. The flocked sponges were immersed in the dispersion, described above, squeezed and released until they were thoroughly impregnated, and removed from the dispersion. The excess dispersion was removed from the impregnated sponges which were then dried at 380 degrees F for 2 hours. After drying, the ends of the impregnated sponges were coated with silver paint which is available under the designation Dupont 4398 to provide electrical contacts. The impregnated sponges were then sintered at 1080 degrees F for about 15 minutes. The sintering step burned out the urethane sponge and vitrified the lead-free dispersion. After firing, the resistance, in ohms, of three pieces of vitrified ceramic was measured. The resistivity, of each piece of the vitrified ceramic, was then calculated from Equation 1:

RA where R = the resistance, in ohms, of a body, A = the cross-sectional area in inch 2, of the body and L = the length of the body in inches.

The average resistivity of the three pieces of vitrified ceramic was 2.90 X 105 ohms-inch.

The vitrified ceramic produced as described above was conductive, but structurally weak. It 25 was strengthened significantly by applying thereto a coating of varnish (commercially available from Dow Corning under the designation "997") and drying the varnish at a temperature of 250 degrees F, and then firing the coated ceramic at 450 degrees F for approximately 3 hours.

EXAMPLES 11-Xl Additional open-celled ceramic bodies were prepared generally in accordance with the procedure and from the materials set forth in Example 1. The amounts of the silicone resin, of the A1P04, of the lead-free ceramic frit, and of the conducting carbon are reported in Table 1, as are the pores per linear inch (ppi) of the organic sponges which were impregnated and the average resistivity of three bodies produced in accordance with each Example.

TABLE 1

Sponge Composition in parts porosity Resistivity 40 (ppi) (ohms-inch) Example Frit AIPO, Silicone Resin Carbon 4.00 X 104 11 40.9 8.9 48.3 2.9 30 107 111 40.9 8.9 48.3 2-.9 4 1.68 X 45 IV 39.0 8.5 46.0 6.5 20 1.16 X 103 V 39.0 8.5 46.0 6.5 30 7.00 X 102 VI 39.0 8.5 46.0 6.5 45 1.67 X 103 Vil 37.5 8.2 44.3 10.0 30 4.10X 10 Vill 37.5 8.2 44.3 10.0 45 1.23 x 102 50 IX 36.2 7.9 42.8 13.2 20 2.85 X 103 X 36.2 7.9 42.8 13.2 -- 30 1.13 X 102 Xi 36.2 7.9 42.8 13.2 45 1.77 X 103 sponges were not flocked The data in Table 1 show that, regardless of the porosity of the sponge used, the resistivity of the bodies decreased as carbon content increased up to about 10 percent. The resistivities of the Example X and XI bodies (13.2 percent carbon) were higher, however, than the resistivities of the Example VII and Vill bodies (10.0 percent carbon). The Example X and XI bodies were 60 more friable than the other bodies, apparently because of their high carbon content. Accord ingly, their carbon content of 13.2 percent is near the upper limit on carbon content in a dispersion according to the present invention.

1 z 0 1 3 GB 2 140 796A 3 EXAMPLE XII

An aqueous dispersion which had a viscosity of about 1500 centipoises was prepared by mixing 13.8 parts of the silicone resin described in Example 1, 86.2 parts of a resistor composition and 43 parts of an aqueous solution containing 4.5 percent of a detergent. The resistor composition comprised 16.4 percent of A1203, 52.7 percent Of CU20, 28.5 percent of SrC03 as a modifier and 2.4 percent of binding clays. The detergent was of the type disclosed in U.S. Patent No. 2,586,496, a product of the acylation of an alkyhol amine.

Several samples of urethane sponge, each approximately 1 inch in diameter by I inch in length, and having 20 pores per linear inch, were coated and flocked as described in Example 1.

The flocked sponges were immersed in the above-described dispersion and thoroughly impreg- 10 nated therewith. The sponges were removed from the dispersion and the excess dispersion was removed from the sponges. The impregnated sponges were dried at 380 degrees F for 2 hours and then fired at 2000 degrees F for about 15 minutes. The firing step burned out the sponge and vitrified the ceramic resistor material. A coating of air drying silver paint was applied to the ends of the vitrified ceramic bodies to provide electrical contacts. The average resistivity of six 15 pieces of the vitrified ceramic resistor was 2.25 X 1 Or, ohms-inch.

It will be appreciated that the foregoing resistor composition (Example XII) is one disclosed in U. S. Patent No. 3,959,184, and, therefore, that a carbonate of a metal selected from the group consisting of magnesium, 6alciurn and barium can be substituted for the SrC03 modifier in the Example XII dispersion. Similarly, the proportions of the modifier M, and of alumina are 20 preferably such that the atom ratio of M to Al is from about 0.5:1 to 2. 0:1. The proportions of the copper oxide, alumina and modifier are preferably such that the numerical value of the atom ratio Cu/(Al + M) is from about 0.5 to 4.0. The temperature coefficient of resistance of the vitrified ceramic resistor is preferably between about 0.1% /degree C and - 1.0% /degree C.

The detergent described in Example X11 was required to enable suspension of the constituents 25 in the aqueous system. The aqueous solution containing the detergent could have been replaced with the amount of an organic solvent required to produce a dispersion in the organic solvent having a viscosity of about 1500 centipoises. The aqueous dispersion is preferred, however, because better impregnation of a urethane sponge can be achieved therewith than with an organic solvent dispersion. In addition, an aqueous dispersion is less volatile and safer than is 30 an organic solvent dispersion, especially when a sponge impregnated therewith is subjected to a high temperature sintering operation.

EXAMPLES XIII-XV A dispersion was prepared by mixing 39 parts of a ceramic frit, 8.5 parts of mono aluminum 35 phosphate, 46.0 parts of the silicone resin described in Example I and 6. 5 parts of the conductive carbon described in Example 1. The ceramic frit consisted of 19.9 percent of S'021 14.5 percent of 13,03, 59.2 percent of PbO and 6.4 percent of Na,O. The raw materials were mixed together with a pestle in a large mortar; toluene was added as required to adjust the viscosity of the dispersion to about 1500 centipoises.

Several samples of urethane sponge, each approximately 1 inch in diameter by I inch in length, some having 20 ppi and others having 30 ppi were coated and flocked as described in Example 1. The flocked sponges and several unflocked sponges having about 45 ppi, were immersed, one at a time, in the above-described dispersion and thoroughly impregnated therewith. The sponges were removed from the dispersion and the excess dispersion was removed from the sponges. The impregnated sponges were dried at 380 degrees F for about 2 hours and a coating of conducting silver paint was applied to the ends thereof. The dried impregnated sponges were fired at 1080 degrees F for about 15 minutes to burn out the sponge and vitrify the ceramic. The average resistivities of three vitrified ceramic pieces made in accordance with each of Examples XIII-XV are reported in Table 11.

TABLE 11

Porosity of Resistivity EXAMPLE sponge (ppi) ohms-inch 55 X111 20 2.1 X 104 XIV 30 1.6 X 103 XV 45 6.0 X 102 sponges were not flocked.

Examples XVI and XVII set forth other modes contemplated by the inventors.

4 GB2140796A 4 EXAMPLE XVI

An aqueous dispersion is prepared by mixing 27.8 parts of the silicone resin described in Example 1, 7.4 parts mono aluminum phosphate, 67.6 parts of the lead-free ceramic frit described in Example 1, 10. 1 parts of the conductive carbon described in Example I and 43 parts of an aqueous solution containing 4.5 percent detergent. The ingredients are mixed substantially according to the procedure described in Example 1, with the exception that the aqueous solution is added after the dispersion achieves a smooth consistency. The viscosity of the dispersion is adjusted, by adding water, to approximately 1500 centipoises.

A sample of urethane sponge, approximately 1 inch in diameter by I inch in length and containing 30 pores per linear inch, is coated and flocked as in Example 1. The flocked sponge 10 is thoroughly impregnated with the above-described dispersion and the excess dispersion is removed therefrom. The impregnated sponge is dried at 380 degrees F for 2 hours; the ends thereof are coated with Dupont 4398 silver paint; and the impregnated sponge is fired at 1080 degrees F for about 15 minutes. The firing step burns out the sponge and vitrifies the ceramic material.

EXAMPLE XVII

An aqueous dispersion is prepared by mixing 9.4 parts of the silicone resin described in Example 1, 7.4 parts mono aluminum phosphate, 85.3 parts of the lead free ceramic frit described in Example 1, 10. 1 parts of the conductive carbon described in Example 1, and 43 20 parts of an aqueous solution containing 4.5 percent detergent. The ingredients are mixed substantially according to the procedure described in Example 1, with the exception that the aqueous solution is added after the dispersion achieves a smooth consistency. The viscosity of the dispersion is adjusted, by adding water, to approximately 1500 centipoises.

A sample of urethane sponge, approximately 1 inch in diameter by I inch in length and containing 30 pores per linear inch, is coated and flocked as in Example 1. The flocked sponge is thoroughly impregnated with the above-described dispersion and the excess dispersion is removed therefrom. The impregnated sponge is dried at 380 degrees F for 2 hours; the ends thereof are coated with Dupont 4398 silver paint; and the impregnated sponge is fired at 1080 degrees F for about 15 minutes. The firing step burns out the sponge and vitrifies the ceramic 30 material.

Any organic sponge capable of being impregnated with the ceramic dispersion can be used in practicing the instant invention; commercially available examples including open-celled cellulose and polyurethane foam sponges. Preferably, the sponge has a substantially uniform open-celled structure to enable uniform "pick-up" of the ceramic material. Polyurethane foam is available in a large variety of open-celled sizes. Sponges having between approximately 15 and 50 pores per linear inch have been found to produce excellent results when used with the ceramic and resistor materials disclosed herein. The pick-up of the ceramic material by the organic sponge can be easily accomplished by immersing the sponge in the dispersion and alternately compressing and releasing the sponge until the dispersion has been absorbed throughout the 40 sponge material. For example, a suitable urethane sponge material is available from Scott Paper Company under the trade designation "Scott 0-Foam". Other suitable urethane sponge materials are also available from the Scott Paper Company under the trade designations "Thirsty Foam", and "Z-Foam".

Organic silicone materials which are suitable for use in the instant invention are disclosed in U. S. Patent Nos. 3,090,691 and 3,108,985. Particularly useful in the instant invention are phenyl lower alkyl silicone resins wherein the total of phenyl and lower alkyl groups divided by the number of silicon atoms is from 0.9 to 1.5. Preferably, the alkyl group has not more than 4 carbon atoms. In particular, the silicone resins available from Dow Corning Corporation under the trade designations "DC-809" and "DC-840" are suitable; these resins as commercially 50 supplied contain approximately 40 percent toluene as a solvent. Other suitable resins for use in the instant invention include, for example, the General Electric resins designated -SR 82", -SR 182" and -SR 323".

The structural strength of an open celled conductive ceramic network of the instant invention, as previously indicated, can be increased by applying a varnish to the surface thereof. It will be appreciated that any coating which imparts structural strength to the ceramic is suitable for this purpose. For example, a du Pont 5137 resistor encapsulating material has been found to strengthen the ceramic network of the instant invention. The du Pont material can be applied to the vitrified ceramic, dried at 250 degrees F and fired at about 950 degrees F for five minutes.

Examples of lead free ceramic frits, in addition to that which is described in Example 1, which 60 can be used in practicing the instant invention, have compositions which fall within the limits indicated below for one of Compositions A, B, and C.

Z 4 i GB 2 140 796A 5 Composition Constituent A B c A1,03 0-5 21 5 S'02 25-45 30 B203 17-25 5 7 Na20 10-25 10 21 K20 0-2 10 CaO 2-10 10 BaO 5-20 Li02 2-5 10 3 M90 0-2 Ti02 0-2 30 M003 0-2 15 F 0-4 4 P205 2 44 Fe203 3 20 Determinations were made of what volume percent of several of the bodies produced as described in the foregoing Examples, constituted ceramic material. The overall dimensions of the bodies were measured; the overall volume of each body was calculated. Each body was then immersed in water, and the volume of water it displaced was measured. The volume percent of ceramic material in each body was calculated by dividing the volume of displaced water by the 25 overall volume of each body and multiplying the quotient by 100. The average volume percent of ceramic material in several bodies produced from sponges having 45 ppi was 29 percent.

The average volume percent of ceramic material in several bodies produced from sponges having 20 ppi was 15.5 percent.

Different voltages were applied to the open-celled ceramic bodies produced as described in 30 Examples IV, VII, VIII and X, initial resistances of 1520, 38, 137 and 175 ohms, respectively, and temperature was determined as a function of applied voltage. A thermocouple placed in contact with each body was used to measure the equilibrium temperature of the bodies at several different applied voltages. The test data for each body are reported in Table Ill.

TABLE Ill

Applied Temperature (degrees F) Voltage Ex. IV Ex. VII Ex. VIII Ex. X 40 10. 80 93 84 94 90 135 100 110 95 235 133 155 320 - - 40 380 180 200 45 103 240 290 - - 320 360 130 - 410 - 160 - - 120 230 - 50 The data in TABLE III demonstrate that the applied voltages caused current flow and consequent heating in the bodies tested. This characteristic of bodies according to the instant invention makes them useful in a variety of applications where heating is desired. For example, 55 a plurality of gases or liquids can be mixed and heated by passing them through an electrically heated porous ceramic according to the invention, or a single gas or liquid can be so heated.

Because of its electric conductivity, a porous ceramic according to the invention can also be used as a plate of an electrostatic precipitator.

The heating characteristic referred to in the foregoing paragraphy and the open-celled configuration of a semi-conducting ceramic according to the invention make it a good candidate for use as a particulate trap in the exhaust system of a diesel engine. By comparison with gasoline engines, diesel engines, during operation, emit large amounts of particulate matter which is primarily carbonaceous. It is contemplated to direct diesel engine exhaust gas through open-celled ceramics of the invention thereby trapping the particulate matter therein. When the65 6 GB 2 140 796A 6 pores of the ceramic become plugged, the exhaust gas can be diverted around the ceramic. At this point, a voltage can be applied to the ceramic to cause heating thereof. The applied voltage would be sufficient to oxidize the carbonaceous particulate matter thereby unplugging the pores of the ceramic. When the pores are unplugged, the exhaust gases can be redirected through the 5 ceramic.

The bulk density of a vitrified ceramic according to the invention can be increased or decreased by the expedient of increasing or decreasing the viscosity of the dispersion with which a sponge or the like is impregnated. However, this expedient has limits because of problems which arise with clogging of the pores of the sponge or because the fired ceramic is excessively weak. The bulk-density can also be increased by flocking the sponge as described above, but 10 with textile fibers such as cotton or rayon. The adhesive used for flocking should provide a tacky surface and should remain sufficiently resilient that it does not interfere with impregnation of the flocked sponge with the ceramic dispersion; an adhesive such as a polyurethane coating composition has the above described characteristics. The identity of the adhesive is unimportant; it need have only the indicated characteristics. The flocking can be accomplished by conven tional methods such as spraying the fibers onto the tacky surface. However, the use of a fluidized bed is preferred since it enables uniform distribution of the fibers throughout the urethane sponge, thereby increasing the surface area and strength of the vitrified ceramic.

While several embodiments of the instant invention have been described in the foregoing examples, various changes and modifications thereof can be made without departing from the 20 spirit and scope of the invention as defined in the following claims.

Claims (9)

1.A method for producing an electrically semi-conducting open-celled ceramic resistor which method comprises the steps of impregnating an organic sponge with a dispersion having 25 a viscosity of from 300 to 3000 centipoises at 75 degrees F and consisting essentially of alumina, copper oxide, and a modifier which is a compound M where M is a carbonate of magnesium, calcium, strontium or barium wherein the relative proportions of the modifier and of alumina are such that the atom ratio of M to Al is from 0.5:1 to 2.0:1 and wherein the proportions of the copper oxide, alumina and modifier are such that the atom ratio Cu/(Al + M) 30 is from about 0.5 to 4.0, and from 6 to 45 percent, on a solids basis, of a silicone resin which consists essentially of a phenyl lower alkyl silicone resin wherein the total number of phenyl and lower alkyl groups divided by the number of silicon atoms is from 0.9 to 1.5 and each alkyl group has not more than four carbon atoms, and sintering the impregnated sponge at a temperature between 1750 degrees and 2250 degrees F for a period of time suffucient to burn 35 out the organic sponge and produce an electrically semi-conducting, virtrified ceramic.

2. A method for producing an electrically semi-conducting open-celled ceramic material which comprises the steps of impregnating an organic sponge with a dispersion consisting essentially of a mixture of copper oxide, alumina and a modifier which is a compound M where M is a carbonate of magnesium, calcium, strontium, or barium wherein the relative proportions 40 of the modifier and of alumina are such that the atom ratio of M to Al is from 0.5:1 to 2.0:1 and wherein the proportions of the copper oxide, alumina and modifier are such that the atom ratio Cu/(Al + M) is from about 0.5 to 4.0, and from 6 to 45 percent, on a solids basis, of a silicone resin which consists essentially of a phenyl lower alkyl silicone resin wherein the total number of phenyl and lower alkyl groups divided bythe numbgr of silicon atoms is from 0.9 to 1.5 and each alkyl group has not more than four carbon atoms, and from 0. 5 to 7 percent of a detergent and sufficient water so that the dispersion has a viscosity at 75 degrees F of from 300 to 3000 centipoises, and sintering the impregnated sponge at a temperature between 1750 degrees and 2250 degrees F for a period of time sufficient to burn out the organic sponge and produce an electrically semi-conducting vitrified ceramic.

3. An organic solvent system consisting essentially of a mixture of copper oxide, alumina and a modifier which is a compound M where M is a carbonate of a metal selected from the group consisting of magnesium, calcium, strontium and barium wherein the relative proportions of the modifier and of alumina are such that the atom ratio of M to Al is from 0.5:1 to 2.0:1 and wherein the proportions of the copper oxide, alumina and modifier are such that the atom ratio Cu/(Al + M) is from about 0.5 to 4.0, and from 6 to 45 percent, on a solids basis, of a silicone resin which consists essentially of a phenyl lower alkyl silicone resin wherein the total number of phenyl and lower alkyl groups divided by the number of silicon atoms is from 0.9 to 1.5 and each alkyl group has not more than four carbon atoms, said organic solvent system having a viscosity at 75 degrees F of from 300 to 3000 centipoises.

4. An aqueous dispersion consisting essentially of a mixture of copper oxide, alumina and a modifier which is a compound M where M is a carbonate of a metal selected from the group consisting of magnesium, calcium, strontium and barium wherein the relative proportions of the modifier and of alumina are such that the atom ratio of M to Al is from 0. 5:1 to 2.0:1 and wherein the proportions of the copper oxide, alumina and modifier are such that the atom ratio 1 4 7 GB 2 140 796A 7 Cu/(Al + M) is from about 0.

5 to 4.0, from 6 to 45 percent, on a solids basis, of a silicone resin which consists essentially of a phenyl lower alkyl silicone resin wherein the total number of phenyl and lower alkyl groups divided by the number of silicon atoms is from 0.9 to 1.5 and each alkyl group has not more than four carbon atoms, from 0.5 to 7 percent of a detergent, and sufficient water that said dispersion has a viscosity at 75 degrees F of from 300 to 3000 centipoises. - 5. A method as claimed in claim 1 wherein, before the organic sponge is impregnated, it is coated with an adhesive to produce a tacky surface and the tacky surface is then flocked with a material selected from the group consisting of rayon and cotton fibers and wood flour.

6. A method as claimed in claim 2 wherein, before the organic sponge is impregnated, it is 10 coated with an adhesive to produce a tacky surface and the tacky surface is then flocked with a material selected from the group consisting of rayon and cotton fibers and wood flour.

7. A method for producing an electrically semi-conducting open-celled ceramic material as claimed in claim 2 and substantially as hereinbefore described with reference to the Examples.

8. Material produced by a method, as claimed in any of claims 2, 5, 6 and 7.

9. An article having a body of material as claimed in claim 8.

Printed in the United Kingdom for Her Majesty's Stationery Office, Dd 8818935, 1984, 4235. Published at The Patent Office, 25 Southampton Buildings, London, WC2A 1 AY, from which copies may be obtained.