Claims
- 1. A method for the preparation of a product by heating a charge of reactants to a high temperature wherein said reactants undergo a reaction to form said product, at least one of said reactants and said product having a low thermal conductivity, said reaction having a high heat of reaction, which method comprises
- --providing a furnace configuration comprising an outer shell which enables control of gaseous atmosphere inside the furnace during operation, an induction means adjacent said outer shell, a thermal insulating layer insulating said induction means, a charge receiving space within said insulating layer for receiving said charge, said charge being placed in the charge receiving space such that the charge occupies a volume defined between an inner limit of the charge and an outer limit of the charge, said inner limit of the charge being defined as a part of the charge which is farthest from said insulating layer, induction susceptor means positioned within said charge receiving space, said induction susceptor means having a coupling portion that provides a continuous conductive path for induced current within said susceptor means,
- --energizing said induction means to thereby heat said susceptor means and to cause the charge located adjacent said susceptor means to increase in temperature and to undergo said reaction of said charge to produce said product and to form a progressing zone front for substantially completely-reacted charge, wherein said progressing zone front emanates away from said susceptor means as time elapses,
- --wherein said susceptor means is positioned within said charge in said charge receiving space such that a cross-sectional center of area of said susceptor means in a radial direction is within about 30-90% of a radial distance from the inner limit of the charge to the outer limit of the charge and the charge of reactants located between the inner limit of the charge and an inner part of said susceptor means has substantially reacted when the progressing zone front reaches said outer limit of the charge.
- 2. A method in accordance with claim 1 wherein the susceptor means is at least one substantially hollow cylinder.
- 3. A method in accordance with claim 1 wherein said susceptor means comprises at least two susceptors positioned in the charge such that when said induction means is energized a progressing zone front for substantially completely-reacted charge emanates away from each of said at least two susceptors and a progressing zone front emanating away from a susceptor reaches the inner limit of the charge or a progressing zone front emanating away from an adjacent susceptor prior to reaching the outer limit of the charge.
- 4. A method in accordance with claim 3 wherein the at least two susceptors are stacked in a vertical arrangement with spacing means located between adjacent susceptors to maintain said adjacent susceptors in spaced relationship.
- 5. A method in accordance with claim 4 wherein said spacing means are formed as part of said susceptors.
- 6. A method in accordance with claim 1 wherein gas generated during said reaction escapes from said furnace via a gas exit means.
- 7. A method in accordance with claim 6 wherein said charge is placed in said charge receiving space such that at least one elongate space is present in said charge and the at least one elongate space acts as a chimney along which said gas escapes.
- 8. A method in accordance with claim 7 wherein said elongate space is located around a central axis of said furnace.
- 9. A method in accordance with claim 3 wherein the at least two susceptors are substantially annular.
- 10. A method in accordance with claim 1 or claim 3 wherein said susceptor means comprises an inductive coupling portion and a conducting portion extending radially from said coupling portion to conduct heat generated in said coupling portion into the charge.
- 11. A method in accordance with claim 10 wherein the conducting portion of said susceptor means has a higher thermal conductivity than the charge or product.
- 12. A method in accordance with claim 1 wherein the product is a refractory hard material.
- 13. A method in accordance with claim 12 wherein said refractory hard material is titanium diboride and said charge of reactants includes TiO.sub.2, a source of boron and a source of carbon.
- 14. A method in accordance with claim 1 wherein said method is operated in a batch-wise manner.
- 15. A method of controlling a furnace configuration having an outer shell, an electromagnetic induction means adjacent said shell, an insulating layer insulating said induction means, a charge receiving space within the insulation layer, a charge positioned in said charge receiving space, whereby the charge occupies a volume defined between an inner limit of the charge and an outer limit of the charge, said inner limit of the charge being defined as a part of the charge which is farthest from said insulating layer, and an induction susceptor means, said induction susceptor means being positioned within said charge such that a cross-sectional center of area of the susceptor means in a radial direction is within the range of about 30 to 90% of a radial distance from the inner limit of the charge to the outer limit of the charge, said method comprising the steps of
- (i) heating said susceptor means up to a predetermined temperature,
- (ii) increasing a temperature of the susceptor means after a progressing zone front for completely reacted charge has progressed away from a surface of said susceptor means such that the charge which has not yet substantially completely reacted is of a temperature which remains below said predetermined temperature, and
- (iii) continuing to increase the temperature of the susceptor means while maintaining the temperature in advance of the progressing zone front below said predetermined temperature until a maximum temperature of the susceptor means is reached or the progressing zone front reaches the outer limit of the charge.
- 16. The method in accordance with claim 15 wherein the susceptor means is positioned such that the progressing zone front reaches the inner limit of the charge prior to reaching the outer limit of the charge.
- 17. The method in accordance with either of claims 15 or 16 wherein the cross-sectional center of area of the susceptor means in a radial direction is within the range of about 60-85% of the radial distance from the inner limit of the charge to the outer limit of the charge.
- 18. A high temperature furnace configuration for use in preparing products by heating a charge of reactants to a high temperature wherein said reactants undergo a reaction to form said products, at least one of said charge and said products having a low thermal conductivity, said reaction having a high heat of reaction, said furnace configuration comprising;
- an outer shell which enables control of gaseous atmosphere inside the furnace during operation,
- an induction means adjacent said outer shell,
- a thermal insulating layer insulating said induction means,
- a charge receiving space within the insulating layer for receiving said charge,
- said charge being placed in the charge receiving space such that the charge occupies a volume defined between an inner limit of the charge and an outer limit of the charge, said inner limit of the charge being defined as a part of the charge which is farthest from said insulating layer,
- induction susceptor means positioned within said charge receiving space, said induction susceptor means having a coupling portion that provides a continuous conductive path for induced current within said susceptor means,
- said induction susceptor means being positioned within said charge in said charge receiving space such that a cross-sectional center of area of the susceptor means in a radial direction is within the range of about 30%-90% of a radial distance from the inner limit of said charge to the outer limit of the charge,
- wherein a progressing zone front for substantially completely reacted charge emanates away from the induction susceptor means and the charge located in a volume of the charge receiving space defined between the inner limit of the charge and an inner part of the induction susceptor means has substantially reacted when the progressing zone front reaches an external limit of the charge.
- 19. The furnace configuration in accordance with claim 18 in which the progressing zone front reaches the inner limit of the charge prior to reaching the outer limit of the charge.
- 20. The furnace configuration in accordance with claim 18, wherein the susceptor means is at least on substantially hollow cylindrical susceptor.
- 21. The furnace configuration in accordance with claim 18, wherein said susceptor means comprises at least two susceptors, each of said at least two susceptors having a progressing zone front for substantially completely reacted charge emanating away therefrom, the at least two susceptors positioned in the charge such that a progressing zone front emanating away from a susceptor reaches the inner limit of the charge or a progressing zone from emanating away from an adjacent susceptor prior to reaching the outer limit of the charge.
- 22. The furnace configuration in accordance with claim 18, 19 or 21, wherein said cross-sectional center axis of area of said susceptor means is positioned within the range of about 60-85% of the radial distance from the inner limit of the charge to the outer limit of the charge.
- 23. The furnace configuration in accordance with claim 21, wherein the at least two susceptors are substantially annular.
- 24. The furnace configuration in accordance with claim 18 or 21, wherein said susceptor means comprises an inductive coupling portion and a conducting portion extending radially from said coupling portion to conduct heat generated in said coupling portion into the charge.
- 25. The furnace configuration in accordance with claim 24, wherein the conducting portion of said susceptor means has a higher thermal conductivity than the charge or product.
- 26. The furnace configuration in accordance with claim 24, wherein the conducting portion extends radially inwardly from said coupling portion.
- 27. The furnace configuration in accordance with claim 18, wherein the configuration is used for the production of transition metal borides.
- 28. The furnace configuration in accordance with claim 18, wherein the charge receiving space is annular shaped.
- 29. The furnace configuration in accordance with claim 18, further comprising a gas exit means to allow gases produced during operation of said furnace configuration to escape from said furnace configuration.
- 30. A high temperature furnace configuration having an outer shell which enables control of gaseous atmosphere inside the furnace during operation, an induction means adjacent said outer shell, an insulating layer insulating said induction means from said outer shell, a charge receiving space within the insulating layer for receiving a charge and an induction susceptor means positioned within said charge receiving space, the susceptor means comprising a coupling portion for inductively coupling to said induction means and a conducting portion extending radially from said coupling portion to conduct heat generated in said coupling portion into a charge within the charge receiving space, said coupling portion and said conducting portion being made of the same material.
- 31. The high temperature furnace configuration in accordance with claim 30, wherein the susceptor means comprises at least one substantially annular susceptor.
- 32. The high temperature furnace configuration in accordance with claim 30 or claim 31, wherein the coupling portion extends sufficiently in an axial direction of the furnace configuration to allow inductive coupling with said induction means.
- 33. The high temperature furnace configuration in accordance with claim 30 or claim 31, wherein the conducting portion of said susceptor means has a higher thermal conductivity than the charge or product.
- 34. A high temperature furnace configuration having an outer shell which enables control of gaseous atmosphere inside the furnace during operation, an induction means adjacent said outer shell, an insulating layer insulating said induction means from said outer shell, a charge receiving space within the insulating layer for receiving a charge and an induction susceptor means positioned within said charge receiving space, the susceptor means comprising a coupling portion for inductively coupling to said induction means and a conducting portion extending radially from said coupling portion to conduct heat generated in said coupling portion into a charge within the charge receiving space, wherein said conducting portion extends radially inwardly from said coupling portion.
- 35. A high temperature furnace configuration having an outer shell which enables control of gaseous atmosphere inside the furnace during operation, an induction means adjacent said outer shell, an insulating layer insulating said induction means from said outer shell, a charge receiving space within the insulating layer for receiving a charge and an induction susceptor means positioned within said charge receiving space, the susceptor means comprising a coupling portion for inductively coupling to said induction means and a conducting portion extending radially from said coupling portion to conduct heat generated in said coupling portion into a charge within the charge receiving space, wherein the conducting portion and coupling portion of the susceptor means are formed as a single component.
- 36. The high temperature furnace configuration in accordance with claim 30, wherein said susceptor means occupies a total volume of less than 20% of a total volume of the charge.
- 37. The method in accordance with claim 15, wherein the temperature of the susceptor means is altered by altering power input to said induction means.
- 38. A method in accordance with claim 1, wherein said method is operated in substantially continuous manner.
Priority Claims (1)
Number |
Date |
Country |
Kind |
PJ8931 |
Mar 1990 |
AUX |
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Parent Case Info
This application is a continuation-in-part of Ser. No. 07/793,375 filed on Jan. 2, 1992, now abandoned.
US Referenced Citations (2)
Number |
Name |
Date |
Kind |
1655983 |
Brace |
Jan 1928 |
|
3696223 |
Metcalf et al. |
Oct 1972 |
|
Foreign Referenced Citations (3)
Number |
Date |
Country |
891263 |
Mar 1962 |
GBX |
1430382 |
Mar 1976 |
GBX |
2082879 |
Mar 1982 |
GBX |
Continuation in Parts (1)
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Number |
Date |
Country |
Parent |
793375 |
Jan 1992 |
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