Selection of Critical Thermal/Structural Design Parameters for a Metal/Composite Joint in a Composite Electronics Enclosure

Abstract

An experiment was designed to determine the critical design parameters for a metal/composite joint in a composite electronic enclosure where both thermal and mechanical performance are important. A combination bolted and bonded single-lap joint that simulates the interface between the thermal wall and the card guide was studied under static loading with power supplied through a surface-mounted chip resistor. The following parameters were varied: fiber orientation, type of thermally conductive pitch fiber, type of adhesive, adhesive thickness, bolt spacing, bolt size, and input power. Load, strain, and temperature from five thermocouples were collected during a tensile test with a 0.02 in/ min. strain rate. A fractional factorial experimental design was used. A dual failure mechanism was consistently recorded: failure of the adhesive bond followed by bolt shear failure. Initial screening results indicated that a configuration can be achieved that significantly enhances both mechanical and thermal performance.

References

1. Hart-Smith, L. J. 1974. "Analysis and Design of Advanced Composite Bonded Joints," NASA CR-112235, August.

2. Hart-Smith, L. J. 1973. 'Adhesive-Bonded Single-Lap Joints," NASA CR-112236, January.

3. Grosfeld, H. and O. Ishai . 1982. "The Effect of Cyclic Loading on Residual Stresses and Strains in a Bonded Joint," International Journal of Adhesion and Adhesives, July.

4. Adams, R. D. and N. A. Peppiatt . 1994. "Stress Analysis of Adhesive-Bonded Lap Joints," Journal of Strain Analysis, 9(3):185-196.

5. Mall, S. , W. S. Johnson and R. A. Everett . 1982. "Cyclic Debonding of Adhesively Bonded Composites," Nasa Technical Memorandum 84577, November.

6. Renton, W. J. and J. R. Vinson . 1975. "Fatigue Behavior of Bonded Joints in Composite Materials Structures," J. Aircraft, 12(5):442-447.

7. Privics, J. 1974. "Two Dimensional Displacement-Stress Distributions in Adhesive Bonded Composite Structures," Journal of Adhesion, 6:207-228.

8. Gali, S. and 0. Ishai . 1978. "Interlaminar Stress Distribution Within an Adhesive Layer in the Nonlinear Range," Journal of Adhesion, 9:253-266, "The Nonlinear Range," Journal of Adhesion, 9:253-266.

9. Ishai, O. , D. Pertz and S. Gali . 1977. "Direct Determination of Inter laminar Stresses in Polymeric Adhesive Layer," Experimental Mechanics (July):265-270.

10.

10. Sage, G. N. and W. P. Tiu . 1982. "The Effect of Glue-Line Voids and Inclusions on the Fatigue Strength of Bonded Joints on Composites," Composites, July.

11.

11. Oplinger, D. W. 1975. "Stress Analysis of Composite Joints," Advances in Joining Technology, J. U. Burke , ed.

12.

12. Oplinger, D. W. 1975. "On the Structural Behavior of Mechanically Fastened Joints in Composite Structures," Advances in Joining Technology, J. U. Burke , ed.

13.

13. Ojalvo, I. 1976. "Survey of Mechanically Fastened Splice-Joint Analysis," Advances in Joining Technology, J. J. Burke and A. E. Gorum , eds., Chestnut Hill, MA: Brook Hill Publishing Company.

14.

14. Hart-Smith, L. J. 1976. "Bolted Joints in Graphite-Epoxy Composites," NASA CR-144899, June.

15.

15. Crews, J. H. 1981. "Bolt-Bearing Fatigue of a Graphite/Epoxy Laminate," Joining of Composite Materials, ASTM STP 749, K. T. Kedward , ed., American Society for Testing and Materials, pp. 131-144.

16.

16. Goland, M. and E. Reisner . 1944. "The Stresses in Cemented Joints," Journal of Applied Mechanics, New York, NY, pp. A17-A22.

17.

17. Mylonas, C. 1954. "Experiments on Composite Models with Applications to Cemented Joints," Proceedings of the Society for Experimental Stress Analysis, April 1954, Cincinnati, Ohio, XII(2):129-142.

18.

18. Mathews, F. L. , P. F. Kilty and E. W. Godwin . 1982. 'A Review of the Strength of Joints on Fibre-Reinforced Plastics," Composites, January.

19.

19. Diamond, W. J. 1989. Practical Experiment Designs. New York: Van Nostrand Reinhold.

20.

20. John, P. W. M. 1971. Statistical Design and Analysis of Experiments. New York: Macmillan Company.

21.

21. Lueng, L. M. and Chung . 1989. "Zero-Stress Film Adhesive for Substrate Attach," Hybrid Circuits, January.

22.

22. IMP User's Guide. 1995. Version 3.1, Cary, NC: SAS Institute Inc., February.

23.

23. Kim, D. C. 1996. "Quality Improvement of Mixed-Type Problems Involving Multiple Quality Characteristics," Doctoral Thesis, The George Washington University School of Engineering and Applied Science, May.

24.

24. Bailey, L. E. 1995. "Fractional Factorial Experiment for Screening Design Parameters for Thermal and Mechanical Performance of a Metal/Composite Joint," Masters Thesis, The George Washington University School of Engineering and Applied Science, January.