unstiffened cylindrical shells

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<td width="208"><a href="pages/page_421.html"><img src="thumbnails/s421.jpg" width="166" height="180" border="0" hspace="14" vspace="0" alt="Phase diagrams for various mach number, M"></a></td>
<td width="208"><a href="pages/page_422.html"><img src="thumbnails/s422.jpg" width="126" height="180" border="0" hspace="14" vspace="0" alt="(a) Dimensionless displacement, W/h, versus time and (b) phase diagrams for varous outer surface temperatures"></a></td>
<td width="208"><a href="pages/page_423.html"><img src="thumbnails/s423.jpg" width="166" height="180" border="0" hspace="14" vspace="0" alt="Bifurcation diagram fo FG square curved panel with different naterial fraction powers, n, under changing flow dynamic pressure, Lambda, for Mach numberm M = 6"></a></td>
<td width="208"><a href="pages/page_424.html"><img src="thumbnails/s424.jpg" width="180" height="89" border="0" hspace="14" vspace="0" alt="Finite element modeling of local corrosion in a pipe"></a></td>
<td width="208"><a href="pages/page_425.html"><img src="thumbnails/s425.jpg" width="180" height="130" border="0" hspace="14" vspace="0" alt="Axisymmetric free vibration of a thick tube"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Phase diagrams for various mach number, M</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">(a) Dimensionless displacement, W/h, versus time and (b) phase diagrams for varous outer surface temperatures</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Bifurcation diagram fo FG square curved panel with different naterial fraction powers, n, under changing flow dynamic pressure, Lambda, for Mach numberm M = 6</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Finite element modeling of local corrosion in a pipe</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Axisymmetric free vibration of a thick tube</small></td></tr></table></td>
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<td width="208"><a href="pages/page_426.html"><img src="thumbnails/s426.jpg" width="124" height="180" border="0" hspace="14" vspace="0" alt="Tubes under angled axial compression"></a></td>
<td width="208"><a href="pages/page_427.html"><img src="thumbnails/s427.jpg" width="66" height="180" border="0" hspace="14" vspace="0" alt="Three types of tubes under axial impact applied at various angles"></a></td>
<td width="208"><a href="pages/page_428.html"><img src="thumbnails/s428.jpg" width="91" height="180" border="0" hspace="14" vspace="0" alt="Load-Endshortening-curves for obliquely impacted axially compressed tubes"></a></td>
<td width="208"><a href="pages/page_429.html"><img src="thumbnails/s429.jpg" width="151" height="180" border="0" hspace="14" vspace="0" alt="The pipe is dented before bending is applied"></a></td>
<td width="208"><a href="pages/page_430.html"><img src="thumbnails/s430.jpg" width="122" height="180" border="0" hspace="14" vspace="0" alt="Nonlinear (large deformation and elastic-plastic material behavior) finite element model of the pipe and indenter"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Tubes under angled axial compression</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Three types of tubes under axial impact applied at various angles</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Load-Endshortening-curves for obliquely impacted axially compressed tubes</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">The pipe is dented before bending is applied</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Nonlinear (large deformation and elastic-plastic material behavior) finite element model of the pipe and indenter</small></td></tr></table></td>
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<tr align="center" valign="middle">
<td width="208"><a href="pages/page_431.html"><img src="thumbnails/s431.jpg" width="156" height="180" border="0" hspace="14" vspace="0" alt="Comparison of results from test and finite element model of the pipe denting process"></a></td>
<td width="208"><a href="pages/page_432.html"><img src="thumbnails/s432.jpg" width="180" height="110" border="0" hspace="14" vspace="0" alt="Bending of the previously dented pipe"></a></td>
<td width="208"><a href="pages/page_433.html"><img src="thumbnails/s433.jpg" width="179" height="129" border="0" hspace="14" vspace="0" alt="dentedbentpipe5png"></a></td>
<td width="208"><a href="pages/page_434.html"><img src="thumbnails/s434.jpg" width="180" height="112" border="0" hspace="14" vspace="0" alt="Representation of a protein microtubule inside cytoplasm"></a></td>
<td width="208"><a href="pages/page_435.html"><img src="thumbnails/s435.jpg" width="68" height="180" border="0" hspace="14" vspace="0" alt="Axially compressed laminated composite cylindrical shells with Variable Angle Tow (VAT)"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Comparison of results from test and finite element model of the pipe denting process</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Bending of the previously dented pipe</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">dentedbentpipe5png</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Representation of a protein microtubule inside cytoplasm</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Axially compressed laminated composite cylindrical shells with Variable Angle Tow (VAT)</small></td></tr></table></td>
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Phase diagrams for various mach number, M

(a) Dimensionless displacement, W/h, versus time and (b) phase diagrams for varous outer surface temperatures

$Bifurcation diagram fo FG square curved panel with different naterial fraction powers, n, under changing flow dynamic pressure, Lambda, for Mach numberm M = 6$

Finite element modeling of local corrosion in a pipe

Axisymmetric free vibration of a thick tube

Phase diagrams for various mach number, M

(a) Dimensionless displacement, W/h, versus time and (b) phase diagrams for varous outer surface temperatures

Bifurcation diagram fo FG square curved panel with different naterial fraction powers, n, under changing flow dynamic pressure, Lambda, for Mach numberm M = 6

Finite element modeling of local corrosion in a pipe

Axisymmetric free vibration of a thick tube

Three types of tubes under axial impact applied at various angles

Load-Endshortening-curves for obliquely impacted axially compressed tubes

The pipe is dented before bending is applied

Nonlinear (large deformation and elastic-plastic material behavior) finite element model of the pipe and indenter

Tubes under angled axial compression

Three types of tubes under axial impact applied at various angles

Load-Endshortening-curves for obliquely impacted axially compressed tubes

The pipe is dented before bending is applied

Nonlinear (large deformation and elastic-plastic material behavior) finite element model of the pipe and indenter

Comparison of results from test and finite element model of the pipe denting process

Representation of a protein microtubule inside cytoplasm

Axially compressed laminated composite cylindrical shells with Variable Angle Tow (VAT)

Comparison of results from test and finite element model of the pipe denting process

Bending of the previously dented pipe

dentedbentpipe5png

Representation of a protein microtubule inside cytoplasm

Axially compressed laminated composite cylindrical shells with Variable Angle Tow (VAT)

unstiffened cylindrical shells

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