Electric heating – Heating devices – With heating unit structure
Reexamination Certificate
2000-10-25
2001-11-20
Walberg, Teresa (Department: 3742)
Electric heating
Heating devices
With heating unit structure
C219S270000, C219S548000, C219S541000
Reexamination Certificate
active
06320167
ABSTRACT:
BACKGROUND INFORMATION
The present invention relates to a sintered pin heater which is made of a ceramic composite structure and which has an essentially enclosed insulating layer and an external conducting layer.
German Published Patent Application No. 35 12 483 describes a ceramic heating element made of Si
3
N
4
/MoSi
2
composites having a proportion of 35-75 mole percent of Si
3
N
4
, the average particle diameter of the used Si
3
N
4
powder being twice as large as that of the used MoSi
2
powder. The average particle diameter of the MoSi
2
powder is 2 &mgr;m or smaller.
However, the utilization of this powder combination leads to satisfactory strengths only if an axial hot-pressing or a hot isostatic pressing process is used. However, this method has the disadvantage that a hard machining requiring considerable outlay must be carried out subsequently.
German Published Patent Application No. 35 19 437 describes an electrical, ceramic heating device, likewise using Si
3
N
4
/MoSi
2
powders, the electrically insulating part being made of powders whose average particle diameter is 1-50 &mgr;m. The conductive powder has the same or a larger average particle diameter than the insulating powder. The conductive part of the heating device is designed in such a manner that the electrically conductive powder is not larger than half the average size of the electrically insulating powder. In this case, as well as in German Published Patent Application No. 35 12 483, this powder combination leads to products having a sufficient strength only if an axial hot-pressing or a hot isostatic pressing process is used with the above-mentioned disadvantages.
German Patent No. 37 34 274 describes ceramic composites on the basis of silicon nitride, aluminum nitride, and &bgr; sialon in combination with secondary phases from different silicides, carbides, borides, and nitrides of transition-metal elements. Depending on the secondary phase content, these materials possess selectively adjustable electrical properties. The adjustable specific values for the electrical resistance of these materials at room temperature lie between 1·10
13
to 1·10
−4
&OHgr;cm and exhibit a positive dependence on the temperature (PTC effect). The strength level of these composites produced in this manner does not lie below 200 MPa. The method used there for manufacturing highly heat-resistant composites is to be considered a uniaxial hot-pressing which, in particular, has disadvantages with respect to the shaping of bodies manufactured from these composites, as mentioned above. Further disadvantages are that bodies made therewith can have anisotropic material properties because of the pressing direction and that the method is only usable as batch process, i.e., not as continuous process. Moreover, this method requires high temperatures and pressures.
Also described in German Patent No. 37 34 274 is the implementation of a ceramic heater or a sheathed-element glow plug using Si
3
N
4
/MoSi
2
composites having sintered-in metal wires as supply leads.
OBJECT AND ADVANTAGES OF THE INVENTION
The object of the present invention is to provide a pin heater having a high strength during whose manufacture a hard machining requiring considerable outlay can be omitted.
The object of the present invention is achieved by a sintered pin heater which is made of a ceramic composite structure and has an essentially enclosed insulating layer and an external conducting layer, the insulating layer being obtainable from 51-57 mass percent of Si
3
N
4
with d
50
being preferably less than 0.7 &mgr;m, 37-42 mass percent of MoSi
2
with d
50
being preferably less than 2-5 &mgr;m, 2.4-2.8 mass percent of Al
2
O
3
with d
50
being 0.2-0.3 &mgr;m, and 3.2-3.6 mass percent of Y
2
O
3
with d
50
being preferably 0.5-1.0 &mgr;m, and the conducting layer being obtainable from 38-42 mass percent of Si
3
N
4
with d
50
being preferably less than 0.7 &mgr;m, 53-58 mass percent of MoSi
2
with d
50
being preferably less than 2-5 &mgr;m, 1.8-2.0 mass percent of Al
2
O
3
with d
50
being preferably 0.2-0.3 &mgr;m, and 2.4-2.7 mass percent of Y
2
O
3
with d
50
being preferably 0.5-1.0 &mgr;m.
The electrically insulating material which forms the insulating layer has a specific electrical resistance of 10
5
-10
6
. The electrically conductive material which forms the conducting layer has a specific electrical resistance of 1·10
−3
-5·10
−3
&OHgr;.
It is generally known that, apart from the concrete chemical composition of the composite materials, the electrical properties, are determined by the specific particle-size ratios of the used powders. With regard to both the used materials, their quantitative proportions, and in particular, due to their average particle diameter, the specific selection according to the present invention enables the manufacture of electrically insulating and electrically conducting composites which, subsequent to sintering, have a 4-point bending strength of at least 500 MPa at room temperature, and which remains nearly unchanged up to a temperature of 1000° C.
In particular, the use of the very fine, highly sinter-active Si
3
N
4
raw material having an average particle diameter of less than 0.7 &mgr;m, and the use of the MoSi
2
raw material having an average particle diameter of 2-5 &mgr;m, for both manufacturing the electrically insulating material and the electrically conducting material, result in these particularly advantageous properties of the sintered pin heater.
Using the method described in German Published Patent Application No. 197 22 321, it is possible for combinations of these materials to be prepared, shaped and gas-pressure sintered. The sintering process is made up of at least two stages, the first sintering being carried out under inert gas, and the last sintering being carried out under a nitrogen partial pressure of 2-10·10
5
Pa, the temperature of the first sintering stage being lower than that of the last sintering stage. In this context, a pressure of atmospheric pressure and a maximum temperature of 900° C. is preferred in the first sintering stage. In the last sintering stage, a sintering temperature between 1700 and 1900° C. is preferred.
Moreover, the last sintering stage can be carried out at variable temperature and/or variable nitrogen partial pressure in such a manner that, in the constitution diagram, the ceramic composite structure contains the pure phases of the insulating component and of the conducting component.
Furthermore, the sintering can be carried out in a range of the nitrogen partial pressure having an upper limit Y
1
=log p (N
2
) and a lower limit Y
2
=log p (N
2
), where the upper limit Y
1
and the lower limit Y
2
are expressed according to the following functions:
Y
1
=7.1566 ln(
T
)−52.719
and
Y
2
=9.8279 ln(
T
)−73.988,
T being the sintering temperature of ≦1900° C. and being input in ° C. In this context, the nitrogen partial pressure p (N
2
) is indicated in bar.
For manufacturing the conducting composite component, powders are used which have the same morphological properties as the powders used for manufacturing the non-conducting composite component.
The two composite components are preconditioned by grinding in a mixing manner. Subsequently, injection-moldable polymer compounds made of the respective composite components are manufactured from a special polypropylene and cyclododecane, are kneaded under protective gas at high temperature and are granulated by cooling while continuously kneading. Using injection molding (CIM=ceramic injection molding), preferably using two-component injection molding, a ceramic body is formed from the polymer compound material which will constitue the conducting layer, and the other polymer compound material is injected subsequently in a second step.
In a first annealing step, the organic binder is removed (debindering), and a pre-sintering up to 900° C. under 10
5
Pa nitrogen is carried out. The main sintering takes place under a defined N
2
partial pressur
Lindemann Gert
Lindner Friederike
Kenyon & Kenyon
Patel Vinod D
Robert & Bosch GmbH
Walberg Teresa
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