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<td width="208"><a href="pages/page_181.html"><img src="thumbnails/s181.jpg" width="89" height="179" border="0" hspace="14" vspace="0" alt="Collapsing voids in an elastomer provide reversible rotation"></a></td>
<td width="208"><a href="pages/page_182.html"><img src="thumbnails/s182.jpg" width="78" height="180" border="0" hspace="14" vspace="0" alt="Rotation of two center areas between collapsing voids activates grippers"></a></td>
<td width="208"><a href="pages/page_183.html"><img src="thumbnails/s183.jpg" width="180" height="114" border="0" hspace="14" vspace="0" alt="Inflation of a rubber balloon involves "snap-through" characteristic"></a></td>
<td width="208"><a href="pages/page_184.html"><img src="thumbnails/s184.jpg" width="180" height="141" border="0" hspace="14" vspace="0" alt="Test set-up for obtaining pressure-volume curves for an inflated dielectric membrane"></a></td>
<td width="208"><a href="pages/page_185.html"><img src="thumbnails/s185.jpg" width="180" height="177" border="0" hspace="14" vspace="0" alt="Pressure-volume curves for various voltages, phi, showing safe and failing snap-through conditions"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Collapsing voids in an elastomer provide reversible rotation</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Rotation of two center areas between collapsing voids activates grippers</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Inflation of a rubber balloon involves "snap-through" characteristic</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Test set-up for obtaining pressure-volume curves for an inflated dielectric membrane</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Pressure-volume curves for various voltages, phi, showing safe and failing snap-through conditions</small></td></tr></table></td>
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<td width="208"><a href="pages/page_186.html"><img src="thumbnails/s186.jpg" width="180" height="99" border="0" hspace="14" vspace="0" alt="Local debonding and buckling of a COPV (Composite Overwrapped Pressure Vessel) that might occur during an internal pressure cycle proof test (autofrettage)"></a></td>
<td width="208"><a href="pages/page_187.html"><img src="thumbnails/s187.jpg" width="180" height="137" border="0" hspace="14" vspace="0" alt="Normal concentrated impact on a doubly-curved laminated composite shell"></a></td>
<td width="208"><a href="pages/page_188.html"><img src="thumbnails/s188.jpg" width="180" height="111" border="0" hspace="14" vspace="0" alt="Computer simulation of very large post-buckling deformations of thin shells"></a></td>
<td width="208"><a href="pages/page_189.html"><img src="thumbnails/s189.jpg" width="179" height="101" border="0" hspace="14" vspace="0" alt="Huge post-buckling deformations of an axially compressed thin shell"></a></td>
<td width="208"><a href="pages/page_190.html"><img src="thumbnails/s190.jpg" width="180" height="142" border="0" hspace="14" vspace="0" alt="Computer simulation of elastoplastic tube as it falls, dents and bounces off boxes"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Local debonding and buckling of a COPV (Composite Overwrapped Pressure Vessel) that might occur during an internal pressure cycle proof test (autofrettage)</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Normal concentrated impact on a doubly-curved laminated composite shell</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Computer simulation of very large post-buckling deformations of thin shells</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Huge post-buckling deformations of an axially compressed thin shell</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Computer simulation of elastoplastic tube as it falls, dents and bounces off boxes</small></td></tr></table></td>
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<td width="208"><a href="pages/page_191.html"><img src="thumbnails/s191.jpg" width="180" height="129" border="0" hspace="14" vspace="0" alt="Large deformation of a membrane in a MEMS pump"></a></td>
<td width="208"><a href="pages/page_192.html"><img src="thumbnails/s192.jpg" width="180" height="137" border="0" hspace="14" vspace="0" alt="Thermally fluctuating shells, A and B"></a></td>
<td width="208"><a href="pages/page_193.html"><img src="thumbnails/s193.jpg" width="180" height="142" border="0" hspace="14" vspace="0" alt="Large post-buckling deformation of various shells"></a></td>
<td width="208"><a href="pages/page_194.html"><img src="thumbnails/s194.jpg" width="180" height="106" border="0" hspace="14" vspace="0" alt="Automatic partitioning of a point-set surface performed with METIS"></a></td>
<td width="208"><a href="pages/page_195.html"><img src="thumbnails/s195.jpg" width="180" height="90" border="0" hspace="14" vspace="0" alt="Strip method for solving buckling of prismatic structures such as longitudinally stiffened panels"></a></td>
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<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Large deformation of a membrane in a MEMS pump</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Thermally fluctuating shells, A and B</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Large post-buckling deformation of various shells</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Automatic partitioning of a point-set surface performed with METIS</small></td></tr></table></td>
<td width="208"><table cellspacing="0" cellpadding="5" border="0"><tr><td align="center"><small class="title">Strip method for solving buckling of prismatic structures such as longitudinally stiffened panels</small></td></tr></table></td>
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Collapsing voids in an elastomer provide reversible rotation

Rotation of two center areas between collapsing voids activates grippers

Test set-up for obtaining pressure-volume curves for an inflated dielectric membrane

Pressure-volume curves for various voltages, phi, showing safe and failing snap-through conditions

Collapsing voids in an elastomer provide reversible rotation

Rotation of two center areas between collapsing voids activates grippers

Inflation of a rubber balloon involves "snap-through" characteristic

Test set-up for obtaining pressure-volume curves for an inflated dielectric membrane

Pressure-volume curves for various voltages, phi, showing safe and failing snap-through conditions

Local debonding and buckling of a COPV (Composite Overwrapped Pressure Vessel) that might occur during an internal pressure cycle proof test (autofrettage)

Normal concentrated impact on a doubly-curved laminated composite shell

Computer simulation of very large post-buckling deformations of thin shells

Huge post-buckling deformations of an axially compressed thin shell

Computer simulation of elastoplastic tube as it falls, dents and bounces off boxes

Local debonding and buckling of a COPV (Composite Overwrapped Pressure Vessel) that might occur during an internal pressure cycle proof test (autofrettage)

Normal concentrated impact on a doubly-curved laminated composite shell

Computer simulation of very large post-buckling deformations of thin shells

Huge post-buckling deformations of an axially compressed thin shell

Computer simulation of elastoplastic tube as it falls, dents and bounces off boxes

Large deformation of a membrane in a MEMS pump

Large post-buckling deformation of various shells

Automatic partitioning of a point-set surface performed with METIS

Strip method for solving buckling of prismatic structures such as longitudinally stiffened panels

Large deformation of a membrane in a MEMS pump

Thermally fluctuating shells, A and B

Large post-buckling deformation of various shells

Automatic partitioning of a point-set surface performed with METIS

Strip method for solving buckling of prismatic structures such as longitudinally stiffened panels

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