Patent Description:
<CIT> describes an electrical feedthrough for an active, implantable medical device - also referred to as implantable device or therapy device. Electrical feedthroughs of this type serve the purpose of establishing an electrical connection between a hermetically sealed interior and an exterior of the therapy device. The hermetic tightness with respect to a surrounding area is an essential requirement for an electrical feedthrough. Conduit elements, which are introduced into an electrically insulating base body and via which the electrical signals run, therefore have to be introduced into the insulating base body in a gap-free manner. It turned out to be advantageous thereby to design the conduit elements as cermet. Cermets are composite materials made of powdery metal and one or several ceramics. Cermets make it possible to establish a direct substance-to-substance bond between the conduit element and the surrounding insulating ceramic base body of the feedthrough by means of co-sintering. If massive metallic conduit wires are used instead of cermets, they have to be introduced into the ceramic in complex processes, in order to create a hermetically tight connection. For the medical use of implantable medical devices, it is necessary to attain a highest possible quality with respect to this hermetic tightness.

Processes for sintering ceramics and/or cermets are known in the prior art, which usually take place in an uncontrolled gas composition, i.e. in ordinary room air. This means that the gas atmosphere, which directly surrounds the workpiece during the sintering, is usually essentially identical to the composition of the atmosphere, which is located outside of the sintering device. In addition, it is common to carry out such processes at increased pressure, in order to support the sintering process. One example of such a process is described in <CIT>. It is proposed there to carry out the process at normal pressure or elevated pressure of, for example, up to at least <NUM> bar. Due to the fact that, as is well known, commonly used ceramic materials, such as Al<NUM>O<NUM> and components of cermets, such as, for example, platinum, are inert even at high temperatures, there was no reason so far in the prior art to carry out the sintering process in a controlled gas atmosphere.

<CIT> discloses a lighting device comprising a plurality of solid state light sources and an elongated ceramic body having a first face and a second face defining a length of the elongated ceramic body, the elongated ceramic body comprising one or more radiation input faces and a radiation exit window, wherein the second face comprises said radiation exit window, wherein the plurality of solid state light sources are configured to provide blue light source light to the one or more radiation input faces and are configured to provide to at least one of the radiation input faces a photon flux of at least <NUM>* <NUM> photons/(s. mm2), wherein the elongated ceramic body comprises a ceramic material configured to wavelength convert at least part of the blue light source light into at least converter light, wherein the ceramic material comprises an A3B5O12:Ce3 + ceramic material, wherein A comprises one or more of yttrium (Y), gadolinium (Gd) and lutetium (Lu), and wherein B comprises aluminum (Al).

<CIT> describes an electrical feedthrough for a medically implantable device, comprising an electrically insulating base body and an electrical conduction element, wherein the conduction element contains a cermet, and wherein the base body and the conduction element are connected by a materially bonded sintered connection, so that the conduction element is hermetically sealed against the base body, the conduction element extends from a first surface of the base body through the base body to a second surface of the base body, wherein the conduction element has a first electrically conductive region within the first surface of the base body and a second electrically conductive region within the second surface of the base body, and at least one of the electrically conductive regions is at least partially overlaid by a layer-like contact element which contains a metal, so that the conduction element can be electrically conductively connected via the contact element.

<CIT> discloses a method of qualifying an implantable ceramic component made of high-purity dense yttria tetragonal zirconium oxide polycrystal (Y-TZP) by application of nondestructive tests. Specifically, a qualified Y-TZP ceramic component or witness sample is examined by X-ray diffraction to determine the initial monoclinic phase content. The component or witness sample is exposed to steam at <NUM> DEG C for a predetermined period of time, preferably six hours. The monoclinic phase content is determined for the post-exposure sample. The absolute difference between the initial monoclinic phase content and the post-exposure monoclinic phase content is calculated by difference. If the difference is less than <NUM>% the sample is accepted. In an alternate embodiment, the components that pass the screening test are examined by ultrasonic testing to evaluate soundness of the ceramic component. Any component that presents a flaw of greater than three microns is rejected.

<CIT> describes a carbon balance control method of a Ti(C,N)-based metal ceramic material. The method is characterized by comprising the following steps: adopting a sectional sintering process in a sintering stage at <NUM>-<NUM>; adjusting the highest temperature and the insulating time of the sectional sintering according to difference of components of original materials; introducing methane; and controlling the pressure of methane and cracking of methane at a high temperature to control the carbon potential in a sintering furnace to control carbon balance in a sintering body, so as to prepare the metal ceramic material excellent in performance. By effectively controlling a high-temperature sintering process, the carbon potential in the furnace is controlled effectively according to a reaction characteristic of carbon in the metal ceramic preparation process, so that stability of product quality and optimized material strength and toughness are achieved.

The object of the present invention is to solve one or several of the above-described and further problems of the prior art. For example, the invention provides for an improved production process for producing a ceramic workpiece, for example a cermet-containing electrical feedthrough. The present invention furthermore provides ceramic workpieces with improved properties.

These objects are solved by means of the processes and devices described herein, in particular those, which are described in the patent claims.

In addition to the embodiments described herein, the elements of which "have" or "comprise" a certain feature (e.g. a material), a further embodiment is generally always considered, in which the respective element consists solely of the feature, i.e. does not comprise any further components. The word "comprise" or "comprising" is used synonymously with the word "have" or "having" herein.

When an element is identified in the singular form in an embodiment, an embodiment is likewise considered, in the case of which several of these elements are present. The use of a term for an element in the plural form generally also comprises an embodiment, in which only an individual corresponding element is comprised.

Unless otherwise specified or excluded unambiguously from the context, it is generally possible and is hereby unambiguously considered that features of different embodiments can also be present in the other embodiments described herein. It is likewise generally considered that all features, which are described herein in connection with a process, can also be used for the products and devices described herein, and vice versa. All of these considered combinations are not listed explicitly in all cases only in the interest of a more concise description. Technical solutions, which are obviously equivalent to the features described herein, are to generally be comprised by the scope of the invention.

A first aspect of the invention relates to a process for producing a sintered workpiece, comprising sintering of a ceramic material at a temperature of at least <NUM> and in an atmosphere, in the case of which the partial pressure of atmospheric air is reduced to less than <NUM>-<NUM>-times, compared to the pressure of ambient air at the same temperature under equilibrium conditions, wherein the ceramic material comprises a cermet, and wherein the ceramic material comprises a metal oxide selected from the group consisting of alumina (Al<NUM>O<NUM>), magnesia (MgO), zirconia (ZrO<NUM>) and aluminum titanate (Al<NUM>TiO<NUM>).

According to the invention, the above-mentioned temperature is the temperature of the atmosphere, which surrounds the ceramic material. It is assumed that this temperature is essentially identical to the temperature of the ceramic material because the process is generally carried out such that the ceramic material and the atmosphere are largely in thermal equilibrium with one another.

The same applies for the further temperature values specified herein during the process, which are described herein below.

In the case of the described process, the partial pressure of atmospheric air is reduced to less than <NUM>-<NUM>-times, based on the ambient air at the same temperature under equilibrium conditions. This means that the process is carried out in an enclosed room, from which the original gas atmosphere is largely removed. This can take place by pumping out the original gas atmosphere, usually the atmospheric room air. Either the total pressure in the closed room can thereby be lowered during the sintering, or the atmospheric room air can be replaced by a different gas. In these two described cases, it is significant for the process that the originally present room air is removed from the room, so that maximally <NUM>-<NUM>-times the portion of the originally present gas atmosphere remains in the closed room, in which the sintering process takes place subsequently. For this purpose, the originally present atmosphere can be pumped out, until the pressure, measured by means of a manometer, is less than <NUM>-<NUM>-times the initial pressure, for example less than <NUM> Pa. The measurement of the pressure thereby takes place before and after the pump-out at the same temperature, for example <NUM>. The original gas atmosphere is preferably removed from the closed room at normal room temperature, for example approximately <NUM> to <NUM>, before the ceramic material is sintered at a significantly higher temperature of at least <NUM>. The ceramic material can be sintered, for example, at approximately <NUM>, <NUM>, or <NUM>. In one embodiment, the ceramic material is sintered at a temperature of from <NUM> to <NUM>, preferably <NUM> to <NUM>.

The partial pressure of atmospheric air is preferably reduced to <NUM>-<NUM>-times or less than <NUM>-<NUM>-times, based on the ambient air at the same temperature under equilibrium conditions.

As common in the technical field, sintering herein describes the connection of particles by means of heating. A fixed cohesive workpiece can thereby be created, for example from a ceramic paste.

When the removed atmospheric air is not replaced by a different gas, the sintering process is carried out at lowered pressure, so that the atmosphere during the sintering, i.e. after the heating of the ceramic material to at least <NUM>, has a total pressure of less than <NUM> Pa, preferably less than <NUM>; <NUM>; <NUM>; <NUM>; <NUM>; <NUM>; <NUM>, or less than <NUM> Pa. In this case, the pressure refers to the total pressure of the atmosphere of the gas, which directly surrounds the ceramic material, during the sintering process, for example at <NUM> or more.

The partial oxygen pressure of the gas, which directly surrounds the ceramic material, during the sintering process, for example at <NUM> or more, can be, for example, less than <NUM> Pa, preferably less than <NUM>; <NUM>; <NUM>, or less than <NUM> Pa.

The temperature of the gas atmosphere during the sintering can be, for example, approximately <NUM>, approximately <NUM>, approximately <NUM>, approximately <NUM>, approximately <NUM>, approximately <NUM>, or approximately <NUM>, <NUM>, <NUM>, <NUM>, or approximately <NUM>. In some embodiments, the temperature during the sintering is approximately <NUM> or higher, or approximately <NUM> or higher. The exact temperature during the sintering can be selected and adapted as a function of the used materials.

The heating of the ceramic material can take place with a heating rate of at least <NUM>, <NUM>, <NUM>, or more than <NUM>/h, for example <NUM> or <NUM>/h.

In one embodiment, the sintering process takes place with a decreased water content of the gas atmosphere. The atmosphere during the sintering can have, for example, a partial water pressure of less than <NUM> Pa, preferably less than <NUM>; <NUM>; <NUM>, or less than <NUM> Pa, measured at the used sintering temperature, for example at <NUM>.

The ceramic material can comprise a binding agent. The binding agent can comprise an organic polymer. An alkyl cellulose, such as, for example, methyl cellulose or ethyl cellulose, is an example for a suitable binding agent. The ceramic material can furthermore comprise a solvent. By adding the binding agent and optionally the solvent, a paste can be produced from a ceramic powder, which can be formed into a so-called green body or a green body film. Prior to the sintering, several green body films can optionally be formed into a laminate and can be firmly connected to one another under pressure, for example isostatic pressing. Prior to the sintering, i.e. prior to the heating to a temperature of at least <NUM>, the process can additionally comprise a step, in which the binding agent is removed by heating the ceramic material. In the technical field, this is also referred to as debinding. In the cases, in which the process comprises a below-described pre-sintering step, the debinding can be performed prior to this pre-sintering step. The debinding comprises, for example, the heating of the ceramic material to more than <NUM>, more than <NUM>, more than <NUM>, or more than <NUM> for several hours, for example, more than one, more than <NUM>, more than <NUM>, more than <NUM>, or more than <NUM> hours. The heating of the ceramic material can take place at a heating rate of at least <NUM>, <NUM>, <NUM>, <NUM>, <NUM>, or <NUM>/h.

Prior to the sintering, thus prior to the heating to a temperature of at least <NUM>, the process can additionally comprise a step, in the case of which the ceramic material is pre-sintered at a temperature of at least <NUM>. This step is also referred to herein as pre-sintering step and can be performed in ordinary room air, thus before the partial pressure of atmospheric air is reduced, as described above. The step can also be performed after the partial pressure of the atmospheric air is reduced. In the case of this step, the temperature of the gas atmosphere can be increased, for example, to <NUM>, <NUM>, <NUM>, or <NUM>. The ceramic material can also be pre-sintered, for example, at least <NUM> or at least <NUM>, and can subsequently be sintered at an even higher temperature. The used temperatures can be adapted, depending on the type and nature of the ceramic material. For example in the case of different materials or different particle sizes, different temperatures can be advantageous in each case. The pre-sintering step can take place at a heating rate of at least <NUM>, <NUM>, <NUM>, or more than <NUM>/h, for example <NUM> or <NUM>/h.

In some embodiments, the workpiece for sintering is heated to a temperature of more than <NUM> or more than <NUM> for the shortest possible period, for example maximally <NUM> hours. For example, the workpiece is heated to a temperature of more than <NUM>, preferably more than <NUM>, for maximally <NUM> hours or maximally <NUM> hour. The mentioned temperature is in each case determined with reference to the gas atmosphere surrounding the workpiece, whereby it is generally assumed that the ceramic material and the surrounding gas atmosphere are essentially in thermal equilibrium with one another, as already described herein. The duration of the process can be shorted by sintering at a higher temperature, so that the production of the workpiece can take place more cost-efficiently, without impacting the high quality, for example tightness, of the produced sintered workpiece.

In one embodiment, the process can be carried out, for example, as follows:.

In some embodiments, a protective gas is introduced after pumping out the original gas atmosphere, so that a total pressure of, for example, approximately <NUM> kPa or approximately <NUM> atm, is reestablished in the closed room, in which the ceramic is located during the sintering. The original gas atmosphere is thereby essentially replaced by the protective gas, so that the subsequent sintering process takes place under protective gas atmosphere. Noble gases, for example argon or helium, or purified nitrogen, are examples for suitable protective gases. The protective gas can also comprise a combination of the mentioned gases. In one embodiment, the protective gas is synthetic air (<NUM>% by volume of nitrogen, <NUM>% by volume of oxygen).

According to the present invention, the ceramic material comprises a metal oxide, preferably a metal oxide selected from the group consisting of alumina (Al2O3), magnesia (MgO), zirconia (ZrO<NUM>) and aluminum titanate (Al2TiO5), more preferably selected from the group consisting of alumina and zirconia, or a combination thereof.

According to the present invention, the ceramic material comprises a cermet. A composite material of a ceramic and a metal is referred to as "cermet". For example, a mixture of at least one ceramic powder and at least one metallic powder can be used to produce a cermet. At least one binding agent and optionally at least one solvent can be added to this mixture, in order to obtain a malleable green body. Afterwards, the binding agent and optionally the solvent are completely removed thermally or by means of evaporation during the so-called debinding. All substances, which are mentioned as ceramic materials further above herein, are generally suitable substances for the ceramic contained in the cermet.

The cermet can be electrically conductive. An electrically conductive connection generally sets in in the cermet when the metal content lies above the so-called percolation threshold, at which the metal particles in the sintered cermet are connected to one another at least pointwise, so that an electrical conduction is made possible. According to experience, the metal content can for this purpose be, for example, at least <NUM>% by volume, depending on the material selection. The cermet can comprise a precious metal. The precious metal is preferably selected from the group consisting of platinum, silver, gold, tantalum, molybdenum, and titanium.

The process can in particular be completely or partially carried out in a tool or a mold, or both, so that a shaping can be connected to the sintering process. In addition to powdery materials, a starting material for the sintering process can comprise further materials, for example one or several binding agents or one or several solvents, or both. The sintering process can take place in one step or also in several steps, wherein the sintering process can be preceded, for example, by further steps, for example one or several shaping steps, or one or several debinding steps, or both. The sintering process, in particular for a cermet, can run similarly to steps to a sintering process, which is usually used for homogenous powders. The material can be compressed during the sintering process, for example at a high temperature, so that the cermet is virtually tight, or has a maximally closed porosity. Cermets are often characterized by a particularly high hardness and wear resistance.

The process can furthermore comprise the grinding of the workpiece after the sintering and cool-down. The workpiece can be ground down, for example, by means of silicon carbide sandpaper (grain size: <NUM>). The process can furthermore comprise the deburring of the workpiece. The grinding and/or deburring can lead to a smoother surface and/or improved stability of the workpiece.

The process can comprise a HTCC (high-temperature cofired ceramic) process, as it is known from the field of electronics manufacturing. Examples of such processes are described in <CIT>, <CIT>, and <NPL>.

For example, an electrical feedthrough, which comprises a conduit element, which has a cermet, can be produced by means of the process described herein. For example, such a feedthrough can be produced as follows: At first, a green body film can be made available and can be provided with holes, for example by means of punching. The holes can be filled with a suitable cermet paste. At this stage of the production, the cermet paste can comprise at least a mixture of metal powder, ceramic powder, and an organic vehicle. Several of the green body films filled in this way can subsequently be laminated, so that the cermet-filled holes are arranged one on top of the other. They can subsequently form the conduit element. So many filled green body films can be laminated that the desired thickness of the electrical feedthrough or length of the conduit element, respectively, is reached. During the subsequent firing, the organic vehicle can be removed at first, the cermet and the ceramic base body can be cosintered during the subsequent transition to higher temperatures. In particular a hermetically tight substance-to-substance bond between the ceramic component of the cermet and the surrounding ceramic of the base body can be created thereby.

A further aspect is the use of a process described herein for producing a sintered workpiece, for example an implantable medical product, or of a portion thereof, for example an electrical feedthrough.

Further disclosed is a sintered workpiece, not claimed, which can be or is produced according to a process described herein.

The workpiece produced by means of the process described herein can be suitable or intended, for example, for installation in an implantable medical product. The medical product is selected, for example, from the group consisting of a pulse generator, medical electrode, pacemaker, cardiac synchronization device, actuator, sensor, or stimulator. The workpiece can be, for example, an electrical feedthrough for an implantable medical device.

In one embodiment, the workpiece is a sensor or a lamp, for example a deuterium lamp, or an LED.

A pulse generator can be set up, for example, to provide an electrical signal for a medical electrode or stimulator. Such a medical electrode or stimulator can be set up, for example, for the stimulation of human tissue, for example muscle tissue (including heart), nerve tissue (including brain), or tissue of the digestive tract.

The sintered workpieces, which are produced by means of the processes described herein, are preferably characterized in that the essentially do not have any microcracks, and thus have a particularly high tightness.

The sintered workpiece can be essentially free from cracks. For example, essentially no cracks with a width of more than <NUM> are present in the sintered workpiece. In one embodiment, at least <NUM>%, <NUM>%, <NUM>%, <NUM> %, or at least <NUM>% of the cracks in the sintered workpiece have a width of less than <NUM>. This can take place by analysis of the surface of the workpiece or of an exposed cross-sectional surface of the workpiece by means of a suitable measuring procedure, for example electron microscopy or atomic force microscopy. This inner cross sectional surface of the workpiece can be exposed, for example, by means of water jet cutting, as described in <NPL>.

In one embodiment, the workpiece comprises a ceramic and a cermet, wherein the ceramic and the cermet form boundary surfaces with one another. The boundary surfaces of the workpiece are thereby essentially free from cracks, in particular essentially free from cracks with a width of more than <NUM>. This can be at hand, for example, when essentially no cracks can be determined along the boundary surface between ceramic and cermet in an electron micrographic picture of an exposed cross-sectional plane of the sintered workpiece.

These sintered workpieces can have a particularly high tightness. For example, the sintered workpiece can have a helium leak rate of less than <NUM>-<NUM> atm*cm<NUM>/s. A sintered workpiece, for example an electrical feedthrough, with such a helium leak rate can be referred to as "hermetically tight". In one embodiment, the sintered workpiece has a helium leak rate of less than 5x10-<NUM> atm*cm<NUM>/s, or less than <NUM>-<NUM>, <NUM>-<NUM>, or <NUM>-<NUM> atm*cm<NUM>/s. In one embodiment, the sintered workpiece has a helium leak rate of less than <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, or less than <NUM>-<NUM> mbar/L·s.

The term "hermetically tight" clarifies that moisture and/or gases cannot permeate or can only minimally permeate through the hermetically tight element in the case of a proper use within the usual time periods (for example <NUM>-<NUM> years). A physical variable, which can describe, for example, a permeation of gases and/or moisture through a device, e.g. through the electrical feedthrough, is the so-called leak rate, which can be determined, for example, by means of leak tests. Corresponding leak tests can be performed, for example, with helium leak testers and are specified in the standard Mil-STD-<NUM> Method <NUM>. The maximally permissible helium leak rate is thereby specified as a function of the internal volume of the device to be tested. According to the methods specified in MIL-STD-<NUM>, Method <NUM>, in paragraph <NUM>, and in consideration of the volumes occurring when using the present invention and cavities of the devices to be tested, these maximally permissible helium leak rates can be, for example, between <NUM> x <NUM>-<NUM> atm·cm<NUM>/sec and <NUM> x <NUM>-<NUM> atm·cm<NUM>/sec. In the context of the invention, the term "hermetically tight" can in particular mean that the workpiece to be tested, in particular an electrical feedthrough, has a helium leak rate of less than <NUM> x <NUM>-<NUM> atm·cm<NUM>/sec. In an advantageous embodiment, the helium leak rate can be less than <NUM>-<NUM>, <NUM>-<NUM>, <NUM>-<NUM>, or less than <NUM>-<NUM> mbar/L·s. For the purpose of the standardization, the mentioned helium leak rates can also be converted into the equivalent standard air leak rate. The definition for the equivalent standard air leak rate and the conversion are specified in the standard ISO <NUM>.

The workpieces produced according to the process according to the invention can have a number of advantages, for example have a high mechanical and/or thermal capacity compared to conventional processes. The produced workpieces can have a particularly low porosity. In the cases, in which the workpiece is made from several green body films, the delamination of these individual layers can be reduced or prevented by means of the process according to the invention. In some embodiments, the produced workpieces have an improved transmission for electromagnetic radiation in the infrared and/or ultraviolet range.

The invention will be further clarified below on the basis of examples, but which are not to be considered to be limiting. It will be clear to the person of skill in the art that, instead of the features described herein, other equivalent means can be used in a similar way.

<FIG> shows a process according to the present invention in an exemplary manner. In a first step <NUM>, the partial pressure of atmospheric air is reduced to less than <NUM>-<NUM>-times the original pressure in the container, in which the ceramic material to be sintered is located. For the most part, the original pressure is approximately <NUM> atm. The total pressure of the atmosphere thereby also decreases in the container, in which the sintering of a workpiece takes place later, which comprises a ceramic material. In an optional <NUM>nd step <NUM>, a protective gas can optionally be admitted into the container. The protective gas can be, for example, argon. For example, the original total pressure can be established thereby, for example to approximately <NUM> atm. In this case, however, the partial pressure or the original, atmospheric air is still also less than <NUM>-<NUM>-times the original pressure. In this case, the gas atmosphere consists essentially of the admitted protective gas. In a <NUM>rd step <NUM>, the gas atmosphere, which surrounds the ceramic material, is brought to an increased temperature, for example at least <NUM>. The ceramic material is thereby sintered in the above-described controlled gas atmosphere.

The sintering in this controlled gas atmosphere can reduce or completely or essentially completely prevent, for example, the formation of cracks in the sintered workpiece. <FIG> shows a workpiece created by means of a sintering process. The workpiece can comprise, for example, a ceramic material <NUM> and a cermet <NUM>. Cracks <NUM> can appear at the boundary surface <NUM> between the ceramic material <NUM> and the cermet <NUM> when the gas atmosphere during the sintering of the ceramic material consists of ordinary room air at normal pressure.

The process described herein, in the case of which a ceramic material is sintered in a controlled gas atmosphere, can reduce or prevent the appearance of cracks <NUM>. <FIG> shoes a workpiece produced according to the process according to the invention. This workpiece comprises, for example, no or essentially no cracks <NUM>. When the workpiece comprises a cermet <NUM>, the workpiece comprises, for example, no or essentially no cracks <NUM> at the boundary surface <NUM> between the ceramic material <NUM> and the cermet <NUM>.

Ceramic green body films were used as ceramic precursors for the insulating base body. <NUM>% by weight of pure Al<NUM>O<NUM> films (Keral <NUM> by Keramische Folien GmbH) with a thickness of <NUM> were used for this purpose. Samples of the green body films were trimmed to <NUM> x <NUM> squares. Approximately circular holes with a diameter of <NUM> were punched by means of a mechanical punch (CPC923101 by Groz-Beckert KG) for a <NUM> diameter in an automated punching machine (MP4150 punching machine by Unichem Industries Inc. ) into the film samples. At least <NUM> film samples were prepared in this way.

The holes prepared in the above manner were filled with cermet paste using a stencil (Christian Koenen GmbH) and a screen printer (model:M2H, EKRA Automatisierungssysteme GmbH).

For the cermet paste, <NUM> of a platinum powder were mixed with <NUM> of an Al<NUM>O<NUM> powder by means of an organic binding agent on the basis of ethyl cellulose, and were homogenized by means of a <NUM>-roller mill. Pastes obtained in this way had viscosities in a range of from <NUM> to <NUM> Pa*s (measured by means of a Haake Rheostress <NUM> rheometer at <NUM>) and a fineness of grind (fog) of less than <NUM>. The rheology of the pastes was suitable for the subsequent stencil printing.

The thickness of the stencil was <NUM>. The openings of the stencil had the same dimensions and positions as the holes, which had been punched into the green body film as above. The pressure parameters were <NUM> N of squeegee pressure, squeegee speed forwards of <NUM>/s, squeegee speed backwards of <NUM>/s, and snap off of <NUM>.

<NUM> minutes after the filling of the samples, they were introduced into a dryer HHG-<NUM> (BTU International Inc. ) and were dried there for <NUM> minutes at <NUM>.

A filling of a thickness of approximately <NUM> was obtained after the printing (wet) and of approximately <NUM> after the drying. To completely fill the hole of the film, further filling steps were performed with the cermet paste. <NUM> to <NUM> film samples were completely filled with the cermet paste by performing the above filling step several times.

<NUM> layers of green body film comprising holes, which are filled in the above manner, are stacked by means of a metal alignment tool and are isostatically pressed in an oil bath at <NUM> with a pressure of <NUM> bar for <NUM> minutes (Laminator-CE-<NUM> by Autoclave Engineers), in order to obtain the desired component thickness of <NUM> prior to the sintering.

The laminate of green body films obtained in the above manner was fired in a high-temperature chamber furnace (FHT-<NUM>-<NUM>-<NUM> by the Arnold Schröder Industrieöfen GmbH), suitable for a maximum temperature of <NUM> with a chamber size of <NUM> x <NUM> x <NUM>, in order to sinter the individual layers and cermet fillings. The sintering process took place under different atmospheric conditions: (<NUM>) normal room air at normal pressure (<NUM> atm), (<NUM>) pure argon atmosphere, (<NUM>) normal room air at reduced pressure (<NUM>-<NUM> atm). The debinding of the laminate was carried out under normal room air. For this purpose, the temperature was increased from <NUM> to <NUM> at a rate of <NUM>/h. The temperature was subsequently increased to a maximum temperature in a range of from <NUM> to <NUM> at a rate of <NUM>/h under the above-mentioned different atmospheric conditions, and was kept constant at this value for a holding time in a range of from <NUM> to <NUM> hours, for example <NUM> hours. The temperature was then lowered to room temperature at a cooling rate of <NUM>/h or the natural cooling rate, which was slower. Further samples were sintered in an isostatic press at <NUM> bar and <NUM> in normal room air (<NUM>).

Sintered shaped bodies with a volume fraction of <NUM>% by volume to <NUM>% by volume of platinum in the cermet were obtained.

After the firing, the samples were ground down and were trimmed to the desired dimensions by means of a laser.

The sintered samples were ground on both sides to a thickness of from <NUM> to <NUM>.

The different samples were measured according to the "MIL-STD-<NUM> w/Change <NUM>, METHOD <NUM> test condition A4" standard. Prior to the leak test, it was ensured that the components were clean and free from residual moisture. The results are shown in Tab. <FIG> furthermore shows that all <NUM> of the measured samples, which were sintered under vacuum, still have a helium leak rate of less than <NUM> × <NUM>- <NUM> mbar * L / s even twelve months after their production.

To measure the porosity, metallographic samples were produced by embedding into epoxy resin, grinding by means of SiC paper with successively smaller grain size, as well as polishing with a diamond paste. Pictures of the sample surface treated in this way were then taken by means of an electron microscope (Zeiss Ultra <NUM>, Carl Zeiss AG). The highest possible contrast between the pores of the sample and the material (ceramic) is to be attained thereby. To evaluate the images, these greyscale images were converted into binary images by means of the Otsu method. This means that the image pixels were in each case assigned to a pore or the sample material by means of a threshold value. Based on the binary images, the porosity was subsequently determined as quotient from the number of the pixels, which represent pores, and the total number of the pixels per image. The porosity was thereby determined as arithmetic average value from <NUM> images, each taken at <NUM> samples. The results are shown in Tab. The electron microscope pictures shown in <FIG> make it clear that samples sintered at normal pressure in room air (<FIG>) or artificial air (<FIG>) have a significantly higher porosity than the samples sintered under argon atmosphere (<FIG>) or vacuum (<FIG>).

The porosity of a sample represents the ratio of cavity volume of the sample to the total volume of the sample. A sample with a total volume of <NUM><NUM> and a cavity volume of <NUM><NUM> has a porosity of, for example, <NUM> %. The percentage of the porosity is an indication in percent by volume (vol.

The grain size of the purely ceramic portion of the sintered samples is determined based on a metallographic grinding pattern obtained according to the above method according to the linear intercept method. Line patterns are used thereby, and the grain size is determined on the basis of the average cut length. The procedure is performed according to EN <NUM>-<NUM>:<NUM>. The grain size used herein is thus identical to the average grain size, which is measured in the standard and which is determined from the cut line length. The scanning electron microscope Zeiss Ultra <NUM> (Carl Zeiss AG) is furthermore used for the measurement. According to point <NUM> of the standard, microstructure pictures of <NUM> different regions of the sample are made for each measurement. In the case of the applicability of the process A (criteria see standard), one furthermore proceeds according to the first alternative under point <NUM> of the standard. The results are shown in Tab.

Claim 1:
A process for producing a sintered workpiece, comprising sintering of a ceramic material at a temperature of at least <NUM> and in an atmosphere, in the case of which the partial pressure of atmospheric air is reduced to less than <NUM>-<NUM>-times, preferably less than <NUM>-<NUM>-times or less than <NUM>-<NUM>-times, based on the ambient air at the same temperature under equilibrium conditions, wherein the ceramic material comprises a cermet, and wherein the ceramic material comprises a metal oxide selected from the group consisting of alumina (Al<NUM>O<NUM>), magnesia (MgO), zirconia (ZrO<NUM>) and aluminum titanate (Al<NUM>TiO<NUM>).