RSS Feed for directionality https://solvonauts.org/%3Faction%3Drss_search%26term%3Ddirectionality RSS Feed for directionality Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite This micrograph has been taken transverse to the directionality and hence the directionality present in the pearlite is not apparent http://core.materials.ac.uk/search/detail.php?id=1242 http://core.materials.ac.uk/search/detail.php?id=1242 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite This micrograph has been taken transverse to the directionality and hence the directionality present in the carbide is not apparent http://core.materials.ac.uk/search/detail.php?id=1243 http://core.materials.ac.uk/search/detail.php?id=1243 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite This micrograph has been taken transverse to the directionality and hence the directionality present in the pearlite is not apparent http://dspace.jorum.ac.uk/xmlui/handle/10949/3695 http://dspace.jorum.ac.uk/xmlui/handle/10949/3695 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite This micrograph has been taken transverse to the directionality and hence the directionality present in the carbide is not apparent http://dspace.jorum.ac.uk/xmlui/handle/10949/3696 http://dspace.jorum.ac.uk/xmlui/handle/10949/3696 Normalised low carbon manganese steel, showing directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://core.materials.ac.uk/search/detail.php?id=1240 http://core.materials.ac.uk/search/detail.php?id=1240 Normalised low carbon manganese steel, showing directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://core.materials.ac.uk/search/detail.php?id=1241 http://core.materials.ac.uk/search/detail.php?id=1241 Normalised low carbon manganese steel, showing directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://dspace.jorum.ac.uk/xmlui/handle/10949/3693 http://dspace.jorum.ac.uk/xmlui/handle/10949/3693 Normalised low carbon manganese steel, showing directionality Low carbon steel with a microstructure consisting mostly of ferrite Manganese is added to steel to remove oxygen and sulphur It causes a reduction in the resulting grain size and hence the steel is tougher and stronger This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://dspace.jorum.ac.uk/xmlui/handle/10949/3694 http://dspace.jorum.ac.uk/xmlui/handle/10949/3694 1.103 Civil Engineering Materials Laboratory (MIT) 1.103 Civil Engineering Materials Laboratory (MIT) Includes audio video content AV special element video This course introduces the concepts techniques and devices used to measure engineering properties of materials There is an emphasis on measurement of load deformation characteristics and failure modes of both natural and fabricated materials Weekly experiments include data collection data analysis and interpretation and presentation of results Includes audio video content AV special element video This course introduces the concepts techniques and devices used to measure engineering properties of materials There is an emphasis on measurement of load deformation characteristics and failure modes of both natural and fabricated materials Weekly experiments include data collection data analysis and interpretation and presentation of results http://ocw.mit.edu/courses/civil-and-environmental-engineering/1-103-civil-engineering-materials-laboratory-spring-2004 http://ocw.mit.edu/courses/civil-and-environmental-engineering/1-103-civil-engineering-materials-laboratory-spring-2004 Normalised low carbon steel, showing directionality Wrought iron contains a very low amount of carbon The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectic temperature virtually all of the austenite will have transformed to ferrite The remainder of the microstructure consists of stringers of slag which are unaffected by normalisation http://core.materials.ac.uk/search/detail.php?id=1238 http://core.materials.ac.uk/search/detail.php?id=1238 Normalised low carbon steel, showing directionality Wrought iron contains a very low amount of carbon The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectic temperature virtually all of the austenite will have transformed to ferrite The remainder of the microstructure consists of stringers of slag which are unaffected by normalisation http://core.materials.ac.uk/search/detail.php?id=1239 http://core.materials.ac.uk/search/detail.php?id=1239 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite surrounding the lighter ferrite This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://core.materials.ac.uk/search/detail.php?id=1244 http://core.materials.ac.uk/search/detail.php?id=1244 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite surrounding the lighter ferrite This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://core.materials.ac.uk/search/detail.php?id=1245 http://core.materials.ac.uk/search/detail.php?id=1245 Normalised low carbon steel, showing directionality Wrought iron contains a very low amount of carbon The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectic temperature virtually all of the austenite will have transformed to ferrite The remainder of the microstructure consists of stringers of slag which are unaffected by normalisation http://dspace.jorum.ac.uk/xmlui/handle/10949/3691 http://dspace.jorum.ac.uk/xmlui/handle/10949/3691 Normalised low carbon steel, showing directionality Wrought iron contains a very low amount of carbon The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectic temperature virtually all of the austenite will have transformed to ferrite The remainder of the microstructure consists of stringers of slag which are unaffected by normalisation http://dspace.jorum.ac.uk/xmlui/handle/10949/3692 http://dspace.jorum.ac.uk/xmlui/handle/10949/3692 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite surrounding the lighter ferrite This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://dspace.jorum.ac.uk/xmlui/handle/10949/3697 http://dspace.jorum.ac.uk/xmlui/handle/10949/3697 Normalised low carbon manganese steel, taken transverse to directionality Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite surrounding the lighter ferrite This sample has been normalised recrystallising the ferrite The pearlite is unable to do this and consequently retains its directionality http://dspace.jorum.ac.uk/xmlui/handle/10949/3698 http://dspace.jorum.ac.uk/xmlui/handle/10949/3698 1.103 Civil Engineering Materials Laboratory (MIT) This course introduces the concepts techniques and devices used to measure engineering properties of materials There is an emphasis on measurement of load deformation characteristics and failure modes of both natural and fabricated materials Weekly experiments include data collection data analysis and interpretation and presentation of results http://www.core.org.cn/OcwWeb/Civil-and-Environmental-Engineering/1-103Spring2004/CourseHome/index.htm http://www.core.org.cn/OcwWeb/Civil-and-Environmental-Engineering/1-103Spring2004/CourseHome/index.htm Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place This sample has been normalised removing the directionality caused by casting http://core.materials.ac.uk/search/detail.php?id=1248 http://core.materials.ac.uk/search/detail.php?id=1248 Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place This sample has been normalised removing the directionality caused by casting http://core.materials.ac.uk/search/detail.php?id=1249 http://core.materials.ac.uk/search/detail.php?id=1249 Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place Micrograph was taken transverse to direction of casting therefore no directionality is seen http://core.materials.ac.uk/search/detail.php?id=1252 http://core.materials.ac.uk/search/detail.php?id=1252 Low carbon steel from wood screw thread. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the thread of a wood screw some directionality is observable due to the shaping of the item http://core.materials.ac.uk/search/detail.php?id=1256 http://core.materials.ac.uk/search/detail.php?id=1256 Low carbon steel from wood screw thread. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the thread of a wood screw some directionality is observable due to the shaping of the item http://core.materials.ac.uk/search/detail.php?id=1257 http://core.materials.ac.uk/search/detail.php?id=1257 Low carbon steel from bottom of wood screw. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the bottom of a wood screw some directionality is observable due to the item being rolled http://core.materials.ac.uk/search/detail.php?id=1258 http://core.materials.ac.uk/search/detail.php?id=1258 Low carbon steel from bottom of wood screw. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the bottom of a wood screw some directionality is observable due to the item being rolled http://core.materials.ac.uk/search/detail.php?id=1259 http://core.materials.ac.uk/search/detail.php?id=1259 Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place This sample has been normalised removing the directionality caused by casting http://dspace.jorum.ac.uk/xmlui/handle/10949/3701 http://dspace.jorum.ac.uk/xmlui/handle/10949/3701 Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place This sample has been normalised removing the directionality caused by casting http://dspace.jorum.ac.uk/xmlui/handle/10949/3702 http://dspace.jorum.ac.uk/xmlui/handle/10949/3702 Normalised carbon steel Low carbon steel with a microstructure consisting mostly of ferrite with the darker pearlite regions around the ferrite grains Upon cooling the steel the ferrite forms initially either on austenite grain boundaries or inclusions This causes carbon to be partitioned into the austenite Eventually the remaining austenite will be at the eutectoid condition and the transformation to pearlite will then take place Micrograph was taken transverse to direction of casting therefore no directionality is seen http://dspace.jorum.ac.uk/xmlui/handle/10949/3705 http://dspace.jorum.ac.uk/xmlui/handle/10949/3705 Low carbon steel from wood screw thread. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the thread of a wood screw some directionality is observable due to the shaping of the item http://dspace.jorum.ac.uk/xmlui/handle/10949/3709 http://dspace.jorum.ac.uk/xmlui/handle/10949/3709 Low carbon steel from wood screw thread. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the thread of a wood screw some directionality is observable due to the shaping of the item http://dspace.jorum.ac.uk/xmlui/handle/10949/3710 http://dspace.jorum.ac.uk/xmlui/handle/10949/3710 Low carbon steel from bottom of wood screw. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the bottom of a wood screw some directionality is observable due to the item being rolled http://dspace.jorum.ac.uk/xmlui/handle/10949/3711 http://dspace.jorum.ac.uk/xmlui/handle/10949/3711 Low carbon steel from bottom of wood screw. Low carbon steel The resulting microstructure is therefore virtually all of the ferrite phase since upon reaching the eutectoid temperature virtually all of the austenite will have transformed to ferrite This sample is taken from the bottom of a wood screw some directionality is observable due to the item being rolled http://dspace.jorum.ac.uk/xmlui/handle/10949/3712 http://dspace.jorum.ac.uk/xmlui/handle/10949/3712 1.103 Civil Engineering Materials Laboratory (MIT) This course introduces the concepts techniques and devices used to measure engineering properties of materials There is an emphasis on measurement of load deformation characteristics and failure modes of both natural and fabricated materials Weekly experiments include data collection data analysis and interpretation and presentation of results https://ocw.mit.edu/courses/civil-and-environmental-engineering/1-103-civil-engineering-materials-laboratory-spring-2004 https://ocw.mit.edu/courses/civil-and-environmental-engineering/1-103-civil-engineering-materials-laboratory-spring-2004