search.noResults

search.searching

dataCollection.invalidEmail
note.createNoteMessage

search.noResults

search.searching

orderForm.title

orderForm.productCode
orderForm.description
orderForm.quantity
orderForm.itemPrice
orderForm.price
orderForm.totalPrice
orderForm.deliveryDetails.billingAddress
orderForm.deliveryDetails.deliveryAddress
orderForm.noItems
modulating materials,” said Dr. William Benard, senior campaign scientist in mate- rials development with the U.S. Army Research Laboratory in Adelphi, Mary- land. “For example, dynamic alloying, or even changing the properties of a particu- lar alloy by modulating the process as we print.” In other words, to add particular properties to the object, a printer could deposit different types of metals in close proximity, and they’d be alloyed as a laser melts them.


“You already have some degree [of control in manipulating materials] in conven- tional manufacturing, and so we’ll profile the material at different places,” Benard said. “When you cast something, it’s not going to be identical, but you don’t have very much option to control it. It’s largely a function of the process and the part geometry. Tere are some things you can do to sort of nudge [the material] here and there. But with additive, there’s really this unprecedented potential.” To have real control of each voxel, he said, “is really far down the road.”


Tis is not only about shapes but also about the composition of materials and the deliberate blending of materials to gain a particular result. Te desired goal, Benard said, is “that the material might perform a substantively different function. So a good example is in electronics pack- aging. We may print a volume that has both conductive elements and dielectric elements.”


Dielectrics, Benard said, are materials that both resist against electricity and have some capacity to store it. What


interests scientists about dielectrics is what is known as the dielectric constant and the strength of the dielectric. “We care about both,” he said, “but we care about the dielectric constant for the design of the normal operating performance of a device (antenna, capacitor, etc.), while the dielectric strength sets the operating bounds—essentially how much charge we can safely apply before the device fails catastrophically.”


With that in mind, he said, “We might place a microchip and then print around that to get a solid volume, which would make it much more mechanically robust. We could print in the electrical contact as part of the volume, as opposed to having it be a discrete wire.”


Tat means that additive manufacturing has the potential to “design electronics with embedded antennas, for instance. So we can use … metal traces to now make antennas.


“But we may want different dielectrics, and now we’re going to use different-property materials on the dielectric side, depend- ing on what the properties of the antenna need to be. Tere have also been demon- strations of embedding things like wave guides. Tat can be optimal wave guides, akin to a fiber, and these can all be embed- ded in a structural member. So you could theoretically use glass fiber both as a reinforcing agent, to make the member stronger but also for optical communica- tions at the same time.”


But as wonderful as that flexibility and manipulability of materials in design


sounds, Benard was quick to caution that we’re not there yet, because creating such structures also brings in variables that have to be foreseen.


To illustrate that in the context of the antenna, he said, “I’m using my fiber optic as a structural member, but I’m also using it for communications. But now, as I strain the lever arm that it’s reinforcing, that may modulate the properties of the fiber, which will affect my communica- tions. It gets into a very complex space. It gives lots of opportunity for high perfor- mance. Tere’s also a lot of opportunity for unintended consequences.”


For Benard, one of the most important things that the Army can do as it moves forward with additive manufacturing is to create the digital design tools that will be necessary for structures that are complex not only in their geometry, but also in materials. Tat’s why “we’re build- ing digital design tools to help manage that complexity and help understand what the impacts are going to be,” he said.


Because of this approach to an object as a volume, giving designers the inherent abil- ity to digitally explode it into a million or more tiny voxels, “there’s all kinds of func- tions and ways you can build these in all different sizes and scales.” Tere’s “a lot of opportunity, but also a lot of complex- ity that you’ve now got to manage on the design side. Very exciting, but very chal- lenging at the same time.”


—STEVE STARK


HTTPS: / /ASC.ARMY.MIL


85


SCIENCE & TECHNOLOGY


Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44  |  Page 45  |  Page 46  |  Page 47  |  Page 48  |  Page 49  |  Page 50  |  Page 51  |  Page 52  |  Page 53  |  Page 54  |  Page 55  |  Page 56  |  Page 57  |  Page 58  |  Page 59  |  Page 60  |  Page 61  |  Page 62  |  Page 63  |  Page 64  |  Page 65  |  Page 66  |  Page 67  |  Page 68  |  Page 69  |  Page 70  |  Page 71  |  Page 72  |  Page 73  |  Page 74  |  Page 75  |  Page 76  |  Page 77  |  Page 78  |  Page 79  |  Page 80  |  Page 81  |  Page 82  |  Page 83  |  Page 84  |  Page 85  |  Page 86  |  Page 87  |  Page 88  |  Page 89  |  Page 90  |  Page 91  |  Page 92  |  Page 93  |  Page 94  |  Page 95  |  Page 96  |  Page 97  |  Page 98  |  Page 99  |  Page 100  |  Page 101  |  Page 102  |  Page 103  |  Page 104  |  Page 105  |  Page 106  |  Page 107  |  Page 108  |  Page 109  |  Page 110  |  Page 111  |  Page 112  |  Page 113  |  Page 114  |  Page 115  |  Page 116  |  Page 117  |  Page 118  |  Page 119  |  Page 120  |  Page 121  |  Page 122  |  Page 123  |  Page 124  |  Page 125  |  Page 126  |  Page 127  |  Page 128  |  Page 129  |  Page 130  |  Page 131  |  Page 132  |  Page 133  |  Page 134  |  Page 135  |  Page 136  |  Page 137  |  Page 138  |  Page 139  |  Page 140  |  Page 141  |  Page 142  |  Page 143  |  Page 144  |  Page 145  |  Page 146  |  Page 147  |  Page 148  |  Page 149  |  Page 150  |  Page 151  |  Page 152