DE10223250A1 - Fiber reinforced ceramic material moldings are produced by pressing a raw material under temperature and pressure - Google Patents

Abstract

Producing moldings out of fibre reinforced ceramic material, comprises pressing the moldings under temperature and pressure. The raw material (20) contains fibres which are electrically conducting. The process temperature is adjusted by direct resistance heating. The raw material is connected to an electricity source (28) which has a control unit (30). The raw material is located in a mold (22) which has an associated die (24).

Description

Method and device of the generic type are known. Such methods are, for example in DE 44 38 455 C1, DE 198 34 571 A1 and DE 100 14 418 A1 described. Here, in particular fiber-reinforced molded body made of fiber-reinforced Preforms with a porous carbon matrix, in particular made from C / C bodies, in which fibers, Fiber bundles or fiber agglomerates on the basis of carbon, nitrogen, boron and / or silicon with at least one carbonizable binder and if necessary, additional surcharge or Fillers are mixed into a molding compound. This molding mass, which is present as a raw mass, becomes a green compact, which then is pyrolyzed, the at least one binder a porous carbon matrix is converted and the resulting fiber-reinforced preform with molten metal or silicon is infiltrated. The liquid is stored here Metal or silicon into the pores. in the Case of infiltration of preceramic Carbon bodies with silicon are created by the reaction the actual ceramic for silicon carbide.

It is known that the molded body as a full body or as Shaped body with recesses and / or cavities manufacture. In the case of the formation of recesses and / or cavities are in the raw mass cores integrated, either as lost cores or as removable, possibly reusable cores are trained.

The present invention relates to Production of all moldings, that is with or without recesses or cavities. Further The invention relates to all moldings fiber-reinforced ceramic materials independently regardless of the fiber material used whether the molded body with after carbonization infiltrates liquid metal or silicon becomes.

It is known that the bulk of the fiber-reinforced ceramic materials under pressure and The effect of temperature is pressed to the moldings. Here are for setting desired properties defined pressure and temperature profiles to be observed during pressing.

It is known the temperature input on the raw mass as well as on the pre-consolidated molded body external heat sources. Here is disadvantageous that the entry of heat in the Shaped body or the raw mass Heat transfer resistance between the heat source and the molded body is to be overcome. On the one hand, this leads to Energy losses and on the other hand inaccuracies in the Temperature curve, since the heat input from the outside to inside the molded body. This can Inhomogeneities within the finished molded body occur that affect its properties. Another disadvantage of the known methods is that that for heating the molded body to the desired process temperature, which is usually between approximately 120 ° C and 280 ° C during pressing the raw mass is relatively long residence times required are. This leads to a relatively long one Manufacturing time of the shaped bodies.

Since the moldings, in particular as brake disks, Clutch discs or the like are used, is a production in the largest possible number desirable. However, this is due to the currently relatively long heating phases not possible, so that the production of the molded body with the known Manufacturing process is relatively expensive.

The invention is therefore based on the object Method and device of the generic type To create kind by means of which shaped bodies fiber-reinforced ceramic materials more effectively, the means especially faster, and therefore are cheaper to produce.

According to the invention, this object is achieved by a Method with the features mentioned in claim 1 solved. The fact that an electrically conductive Pulp is used and the Process temperature through an electrical Direct (resistance) heating is set, is advantageously possible a very precise and even heating achieve. In particular, the raw mass is immediate heated directly, so overcoming one Heat transfer resistance through indirect heating is eliminated. The efficiency of such heating is thus significantly higher. Direct heating also leads to a significantly faster achievement of required process temperatures so that the of the Warming dependent cycle time in the manufacture of the Shaped body can be significantly reduced.

In a preferred embodiment of the invention provided that the raw mass for electrical Direct heating is supplied with a controllable current. This advantageously achieves that Regulation of the strength of the current has an immediate impact be taken to the current process temperature can. It is known from general electrical engineering that the temperature is dependent on the electrical Resistance of the raw mass and the amount of the current. The electrical resistance in turn is dependent on another of a cross section of the current Conductor. By pressing the raw mass through The cross-section of the raw mass changes under pressure, so that a change in the electrical resistance occurs. By a preferably provided regulation of the current in Dependence on pressure can be a very accurate one Temperature control of the process temperature can be set.

It is also preferred if the regulation of the current depending on a determined, in particular measured actual temperature of the raw mass. This can essentially be in actual time, that is without delay, an immediate Temperature control so that defined, Have reproducible process conditions set.

In a further preferred embodiment of the invention it is provided that the regulation of the current by means of of a thyristor controller. This will in a simple way to adjust the heating voltage and / or heating current, in particular depending on Actual temperatures, possible. The actual temperatures can by the temperature sensor as a voltage signal Thyristor controller are supplied, so that here immediate regulation is possible. This will Process temperatures exactly, that means to the second, adjustable. In particular, it can be quasi in actual time the heating voltage or the heating current and thus the process temperature to the current one Pressure curve can be adjusted.

The task is further accomplished with a device solved the features mentioned in claim 5. The fact that the raw mass to adjust the Process temperature with a high current source directly is contactable, it is advantageously possible a very compact device for the production of moldings Provide generic type that a direct Heating the pulp to be processed allows. Introducing and transferring Amounts of heat, and the associated losses, on the Pulp is therefore not necessary. hereby there is also a simplification of the Construction of the entire device.

Especially when the high current source is a Is a transformer, can be easily controlled Regulation of primary voltage respectively Primary current the secondary voltage respectively Set the secondary current and thus the heating current exactly.

Further preferred configurations of the invention result from the rest, in the subclaims mentioned features.

The invention is in one Embodiment with reference to the accompanying drawings explained. Show it:

Fig. 1 shows schematically in a block diagram the process for the production of moldings and

Fig. 2 is a schematic representation of the device for the production of moldings.

Description of the embodiment

Fig. 1 shows in a block diagram the essential process steps for the production of moldings from fiber-reinforced ceramic materials. In a first step 10 , a raw mass is produced which contains, for example, carbon fibers and / or carbon fiber bundles and / or carbon threads, which have optionally been coated with carbon or carbon-containing compounds. The raw material also contains at least one carbonizable binder and, if appropriate, further additives or fillers.

In a second step 12 , the raw mass is portioned into a press mold.

In a subsequent step 14 , the raw mass is pressed under the action of a pressure p and the action of a temperature T. Here, a desired course of the pressure p and a desired course of the temperature T are set over time. The temperature T is about 120 ° C to 280 ° C, while the pressure p can be about 0 to 200 kp / cm ² .

In a next step 16 , the molded body is pyrolyzed or carbonized. A temperature T ₂ of approximately 750 ° C. to approximately 1100 ° C. acts here.

In a next step 18 , the carbonized molded body is infiltrated with molten metal or silicon.

This is followed by a high-strength fiber-reinforced one Ceramic body, for example as a brake disc, Clutch disc or the like can be used.

The method comprising steps 10 to 18 is generally known, so that the description of details is omitted here. Shaped bodies with a defined contour and optionally with defined recesses and / or cavities can be obtained. In order to achieve the cavities, it is known to introduce cores into the molding compound - in step 12 - which cores can be designed as lost cores or removable, possibly reusable cores.

The subject matter of the invention relates to the application of the process temperature in step 14 . For this purpose, high-current direct heating of the raw mass previously introduced into the mold is carried out. This is possible because the carbon fibers or carbon fiber bundles or carbon threads have an electrical conductivity. When an electric current is applied to the raw mass, heat is generated due to the instantaneous electrical resistance of the raw mass. Since the simultaneous or possibly time-delayed action of the pressure p causes the raw material to solidify or compact, its electrical resistance changes, so that a constant heating current leads to a change in the process temperature.

Using these physical principles, it is now possible to set the course of the heating current I _H and thus the course of the process temperature T ₁ as a function of the course of the pressure p. In this case, both desired changes in the process temperature T ₁ can be set and possibly unwanted changes in the process temperature T ₁ can be corrected at certain times, that is, avoided.

Fig. 2 shows schematically a device for producing the molded body from fiber-reinforced ceramic materials. Here, the raw mass is designated 20, which results in the later molded body. The raw mass 20 is arranged in a press mold 22 , wherein a pressing pressure p can be exerted on the raw mass 20 via the dies 24 indicated here. The pressing pressure p is set by a press control device 26 . The press control unit 26 in this case contains a specification for the nominal course of the pressing pressure p _{is intended.}

The raw mass is simultaneously connected in the press mold to a high current source 28 , which is formed in particular by a transformer. The raw mass 20 is connected as a resistor in the secondary circuit of the transformer.

The primary circuit of the transformer 28 is supplied from a controller 30, which _{is to} the pressure p as a function of the current path and then tuned course of the process temperature T _set regulates the primary voltage. The actual temperature of the raw mass 20 is continuously measured via a temperature sensor 32 and also made available to the control unit 30 as a signal. It is clear that the high-current transformer 28 can be controlled via the control device 30 as a function of the pressure curve p _soll and the temperature curve T _{1, soll} and the instantaneous process temperature T _ist so that a desired heating current I _{H is} set. This is, for example, between 6000 A and 14000 A. The heating voltage U _H in the secondary circuit of the transformer 28 is, for example, 0 V to 4 V.

The process temperature can be regulated, for example, via a thyristor controller which is integrated in the control unit 30 , the signal corresponding to the instantaneous process temperature T _being fed directly to the thyristor controller.

It is clear that the arrangement described here only schematically enables an exact course of the process temperature T _1, which is matched to the course of the pressing pressure p. LIST OF REFERENCE NUMERALS 10 step
12 step
14 step
16 step
18 step
20 raw mass
22 mold
24 matrices
26 press control unit
28 transformer
30 control unit
32 temperature sensor
p pressing pressure
p _{is the} course of the pressure
T temperature
T ₁ course of the process temperature
T ₂ temperature
T _{is the} current process temperature
T _{should be} process temperature
I _H heating current
U _H heating voltage

Claims (8)

1. A process for the production of moldings from fiber-reinforced ceramic materials, the fiber-reinforced ceramic materials being pressed as a raw mass under the action of pressure and temperature to the shaped bodies, characterized in that a fibrous mass having at least electrically conductive components is used as the raw mass ( 20 ) Process temperature (T ₁ ) is set by an electrical direct (resistance) heating. 2. The method according to claim 1, characterized in that the raw mass ( 20 ) with a controllable heating current (I _H ) is applied. 3. The method according to any one of the preceding claims, characterized in that the heating current (I _H ) is controlled as a function of the current pressing pressure (p). 4. The method according to any one of the preceding claims, characterized in that the heating current (I _H ) _is controlled as a function of an instantaneous actual temperature (T _ist ) of the raw mass ( 20 ). 5. Device for the production of moldings from fiber-reinforced ceramic materials, with at least one press mold for receiving a raw mass of the fiber-reinforced ceramic material, with a pressure generating device for applying a pressure to the raw mass and a heating device for applying a process temperature to the raw mass, characterized by a high current source ( 28 ) with which the raw material ( 20 ) for setting the process temperature (T ₁ ) can be contacted directly. 6. The device according to claim 5, characterized in that the high current source ( 28 ) is a transformer, in whose secondary circuit the raw mass is connected as an electrical resistor. 7. The device, that the primary circuit of the transformer is fed by a control unit (30) according to any one of the preceding claims, characterized in that the control inputs includes at which _(to p) the desired pressing pressure, the desired process temperature (T _{1, to} ) and the actual process temperature (T _{1, is} ) corresponding signals. 8. Device according to one of the preceding claims, characterized in that the control device ( 30 ) comprises a thyristor controller which can be controlled by the signal corresponding to the actual process temperature (T _{1, is} ).