Treatise on Materials Science and Technology, Volume 1 |
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Page 99
For small numbers of elements , then , the strength of the composite must rise
with increasing numbers of elements which is intuitively obvious for very small
numbers . We note further from Table IV that as the flaw density exponent m
increases ...
For small numbers of elements , then , the strength of the composite must rise
with increasing numbers of elements which is intuitively obvious for very small
numbers . We note further from Table IV that as the flaw density exponent m
increases ...
Page 100
The increase in composite strength with increasing numbers of elements (
constant volume fraction of reinforcement ) is clearly seen in Fig . 6 . Another , but
less perfect , verification was obtained by testing different widths of glass fiber ...
The increase in composite strength with increasing numbers of elements (
constant volume fraction of reinforcement ) is clearly seen in Fig . 6 . Another , but
less perfect , verification was obtained by testing different widths of glass fiber ...
Page 110
of the strength maximum , the length of the critical crack for fracture instability
decreases with increasing exponent m ( decreasing element variability ) . This
increase is partly due to the rise in the composite strength with increasing m . As
the ...
of the strength maximum , the length of the critical crack for fracture instability
decreases with increasing exponent m ( decreasing element variability ) . This
increase is partly due to the rise in the composite strength with increasing m . As
the ...
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addition alloys analysis angle applied approach associated assumed atoms average becomes bond boundary calculated complex composite concentration consider constants contribution crystal curvature curve decrease defined dependence deposition determined developed direction discussed displacement distance distribution dynamical effect elastic electron elements energy equal equation exist experimental fibers force fracture function given gives grain grain boundaries Group growth growth path illustrated increase indicate interaction interface internal friction interstitial iron laminate lattice layer length material matrix measured mechanism metal microstructural molecules nitrogen normal nucleation observed obtained occur oxygen particles peak phase plane position possible potential present produce properties region reinforcing relaxation respectively shown in Fig shows single Snoek peak solid solution strain strength stress structure substitutional surface Table temperature tungsten unit values volume waves
Bibliographic information
| Title | Treatise on Materials Science and Technology, Volume 1 Treatise on Materials Science and Technology, ScienceDirect (Online service) |
| Editor | Herbert Herman |
| Publisher | Academic Press, 1972 |
| Original from | the University of Michigan |
| Digitized | 29 Nov 2007 |
| Export Citation | BiBTeX EndNote RefMan |