Carbon Based Refractories

Emad Mohamed M. EWAIS

doi:10.2109/jcersj.112.517

journal article Jan 01, 2004

Carbon Based Refractories

Emad Mohamed M. EWAIS

Journal of the Ceramic Society of Japan Vol. 112 No. 1310 pp. 517-532 · Ceramic Society of Japan

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References

150

[1]

1) “Refractories manual,” American Foundrymen's Society, Inc. Des Plaines, Illinois 60016-2277 (1989).

[2]

2) Shaw, K., “Classification of refractories,” Hand book of refractories and their uses, Applied Science Publishers Ltd., London (1972) pp. 74-75.

[3]

3) Refractories products-classification of dense shaped refractory products, ISO 1109 (1975).

[4]

4) Classification of shaped heat-insulating refractory products, ASTM C155-88 (92).

[5]

5) Coope, B., “The world magnesia industry,” Ind. Min., [2], 21-31 & 43-48 (1987).

[6]

6) Routschka, G. and Barthel, H, “Classification,” Pocket manual refractory materials, Vulkan-Verlag, Essen/Germany (1997) pp. 6-9.

[7]

7a) Classification of dense shaped refractory products, BS EN 12475-1: (1998).

[8]

7b) Classification of dense shaped refractory products, BS 57225-1.2: (1998).

[9]

8) Classification of dense shaped refractory products-Special products, BS EN 12475-4: (1999).

[10]

9) Routschka, G. and Barthel, H., “Refractory Base Materials,” Pocket Manual Refractory Materials, Vulkan-Verlag, Essen/Germany (1997) pp. 2-2.

[11]

12) Nagruse, Y., Transactions ISIJ, Vol. 24, pp. 785-798 (1984). 10.2355/isijinternational1966.24.783

[12]

13) Semler, C. E., The ongoing evolution of refractories technology, “http://www.ceramic-journals.com/english/objekte/cn00_1.htm” (2000).

[13]

14) Shaw, K., “Carbon and graphite,” Handbook of Refractories and their uses, Applied Science Publishers Ltd., London (1972) pp. 140-145.

[14]

15) Cooper, C. F., Refract J. Vol. 6 (1980).

[15]

16) Russell, F. S., Refract. J., Vol. 6, pp. 7-10 (1982).

[16]

17) Cooper, C. F., Chem. Ind., Vol. 18, pp. 678-685 (1982).

[17]

18) Ho, C. Y., Powell, R. W. and Liley, P. E., J. of Physical and Chemical Reference Data, Vol. 1, pp. 279-429 (1972). 10.1063/1.3253100

[18]

19) Bauer, J. B., Schmidt-Whitley, R. D., Dumas, D., Du Mesnildot, B. and Kiehl, J. P., “New solutions for problem areas of blast furnace linings,” Interceram., Special Issue, pp. 25-32 (1983).

[19]

20) Piel, K. T., “Carbon and graphite bricks/blocks,” Pocket manual refractory materials, Vulkan-Verlag, Essen/Germany (1997) pp. 69-74.

[20]

21) Elderfield, R. N., “Blast-furnace refractories: Blast-furnace carbon: A reappraisal,” ISI publication 116, London (1968) pp. 25-35.

[21]

22) Chester, J. H., “Refractories: Production and properties,” Handbook published the iron and steel institute, London (1973).

[22]

23) Mortl, G. and Starzacher, A., “Lining proposals for hearth and hearth wall of blast furnaces,” Interceram, Special Issue, pp. 72-75 (1983).

[23]

24) Wilkening, S., “Some of topical problems of the carbon lining of the blast furnaces,” AIME Iron making proc., Vol. 36 (1979).

[24]

25) Miyamoto, M., Onoye, T. and Anarita, K., “Effect of alkalis and zinc on the wear of blast furnace refractories and tuyere displacement,” Transaction ISIJ, Vol. 21, pp. 839-845 (1981).

[25]

26) McKee, D. W. and Chatterji, D., Carbon, Vol. 16, pp. 53-57 (1987). 10.1016/0008-6223(78)90116-1

[26]

27) Krol, L., “Characterisic of the destructive action of alkalis on blast furnace carbon and graphite lining,” AIME Iron Making Proc., Vol. 37 (1978).

[27]

28) Chester, J. H., “Refractories for iron-and steelmaking,” Handbook published the metals society, London (1974).

[28]

29) Barthel, H., “Carbon-containing magnesia and magnesia-carbon bricks,” Pocket Manual Refractory Materials, Vulkan-Verlag, Essen/Germany (1997) pp. 139-152.

[29]

30) Blakeley T. H. and Earp, F. K., “Tars and pitches as binders for carbon and graphite,” Industrial carbon and graphite, London, 24th-26th September (1957) pp. 173-177.

[30]

31) Hughes, R. H. and Morena, R., “Pitch bonded refractory,” United state patent No. 4, 184, 883, January 22 (1980) pp. 1-14.

[31]

32) Bowman, R. C., Lang, E. J. and Grazen, F. S., “Resin composition and process for bond solid particles,” US Patent No. 3, 852, 232, December 3 (1974) pp.1-16.

[32]

34) Geber, A. H., “Mixtures of phenolic novalacks for use with refractory aggregates and methods for making same,” US Patent No. 5, 760, 104, June 2 (1998) pp. 1-22.

[33]

35) Geber, A. H., “Curative for phenolic novalacs,” US Patent No. 6, 046, 252, April 4 (2000) pp. 1-15.

[34]

38) Lyer, R. and Shah, R. C., “Phenolic resin binders for foundry and refractory uses,” US Patent 4, 740, 535, April 26 (1988) pp. 1-15.

[35]

39) Barthel, H. and Kaltner, E., “The effect of carbon in carbon-containing magnesia bricks on the wear in basic oxygen furnaces,” Reprint 1st Int. Conf. Refract., Tokyo (1983) pp. 91-104.

[36]

40) Itotagawa, S., Hashimoto, S. and Munekane, K., Refractories (Tokyo), Vol. 46[1], pp. 18-21 (1994).

[37]

42) Torigoe, A., Tada, H., Nomura, O. and Otani, T., Refractories (Tokyo), Vol. 48[11], pp. 598-598 (1996).

[38]

43) Yamamura, T., Nomura, O., Tada, H. and Torigoe, A., “Carbon-containing refractory and process for producing the same,” US Patent No. 6, 136, 227, October 24 (2000) pp.1-12.

[39]

44) Ruh, E., “Magnesia-carbon refractories, history, development, types & applications,” International Ceramic Monographs, Vol. 1[2], pp. 772-793 (1994).

[40]

45) Spencer, D. R. F., Refract. J., Vol. 3, pp. 12-13 (1979).

[41]

46) Hardly, C. W. and Warman, M. O., “BOS vessel linings-experience with magnesia carbon in the united kingdom,” Radex-Rrundsch., Vol. 3-4, pp. 457-463 (1987).

[42]

48) Ruh, E., et al, International Ceramic Monographs, Vol. 1[2], pp. 772-793 (1994).

[43]

49a) Classification of dense shaped refractory products-Basic containing less than 7% residual carbon, BS EN 12475-2: (1998).

[44]

49b) Classification of dense shaped refractory products-Basic containing less than 7% residual carbon, BS 7225-1-1.3: (1998).

[45]

50a) Classification of dense shaped refractory products-Basic containing from 7% to 30% residual carbon, BS EN 12475-3: (1998).

[46]

50b) Classification of dense shaped refractory products-Basic containing from 7% to 30% residual carbon, BS 7225-1-1.4: (1998).

[47]

51) Riepl, K. and Barthel, H., “Large-crystal magnesia clinker for advanced refractories, an update and overview,” UNITCER'91 Proc. Achen, 2nd ed. (1991) pp. 97-102.

[48]

52) Jhunjhunwala, R., Sahu, M. M. and Mishra, R., “Magnesia carbon refractories-The proven lining material for basic oxygen furnaces,” Proceedings of International Symposium on Refractories: Refractory raw Materials & High Temperature Performance Refractory Products, August (1988) pp. 475-488.

[49]

53) Watanabe, A., Okamura T. and Saeki, G., “Carbon-bonded magnesia carbon bricks,” US Patent No. 4, 431, 745, February 14 (1984) pp. 1-7.

[50]

54) Matsui, K. and Kawano, F., Refractories (Tokyo), Vol. 45[6], pp. 555-566 (1993).

Showing 50 of 150 references

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Details

Published: Jan 01, 2004
Vol/Issue: 112(1310)
Pages: 517-532

Authors

E

Emad Mohamed M. EWAIS

Refractory & Ceramic Materials Lab., Central Metallurgical R & D Institute (CMRDI)

Cite This Article

Emad Mohamed M. EWAIS (2004). Carbon Based Refractories. Journal of the Ceramic Society of Japan, 112(1310), 517-532. https://doi.org/10.2109/jcersj.112.517

Carbon Based Refractories

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