One recent project involved coming up with a solution to help Soldiers carry a heavy piece of sensor equipment in the field.

These injection molding machines are perfect for use at home. Read on to see the best DIY desktop injection molding machines!

"If a Soldier comes back wounded, we'd have that data on our side where we could possibly build prosthesis that are exactly how the Soldier used to look -- instead of sculpting it and scanning it," Moore said.

"I see it expanding in the materials," he said. "I see the speed increasing and the sizes of the parts increasing. There are also a lot of fascinating medical applications, which kind of overlap with what we'd like to do in the Army in the future."

Medical personnel may use 3D laser scans on a Soldier before he or she is deployed. This would ensure all physical features are on file.

The lab is an element of the U.S. Army Research, Development and Engineering Command, which has labs and research centers across the country. Army scientists, researchers and engineers reach out to the team as needed.

ABERDEEN PROVING GROUND, Md. (Oct. 3, 2012) -- When you walk into this research lab you hear the overpowering hum of massive machines with robotic parts swinging past viewing windows as technicians spray objects with lasers attached to limber metallic arms.

"It is kind of a magical thing," Moore said. "Seeing people who have never seen it before come through the lab finally get it and understand it ... you can see it in their face. They think it's something from the future."

"Instead of depositing ink on a page, the print head deposits a photo polymer onto the platform. A photo polymer is liquid until it's exposed to ultraviolet light and then it polymerizes, or solidifies, into a plastic," Ruprecht said. "Just like your ink-jet printer can mix colors together to get a different color, we can mix materials together. So we can make a rigid plastic or adjust the shore value and make it the stiffness that you want. You can also make parts that have two different materials embedded in each other."

"The Army Research Lab asked us to develop a holder for a heavy handheld sensor called a Mine Hound, which is used as an improvised explosive device detection sensor," Moore said. "They wanted something that would cradle the handle so it's putting more weight on the Soldiers' vest and back as opposed to just their forearm."

"In the end we'll raise the platform up and we'll have the printed object encapsulated in powder," Moore said. "We pull it out, shake off the excess powder and then we've got a part."

"The fact that we could do this many designs and print them out and have them in their hands in one week gave them the option to choose between what works best for their application," Moore said. "This is a good example of how we use the technology every day.

"We're going to make 10 of them for testing," he said. "Once we have their approval we're going to do the rapid tooling and use injection molding to make several thousand of the holders."

The team's 3D printers churn out new objects day and night. Researchers use a variety of techniques to get the job done. Some printers use lasers, others spray heated plastic through print heads. One system uses a vat of "goo" to hold the object in place as it creates it layer by minuscule layer.

Fifty years ago what goes on in this lab would have been considered science fiction, but what these Army researchers do is scientific fact.

"If you take a look at this equipment, how could you not like the job?" he asked. "I make stuff every day. I make something from nothing with state-of-the-art technology. The future is definitely fascinating."

"It's allowed us to develop items for the warfighter quicker," said Rapid Technologies Branch Chief Rick Moore, Edgewood Chemical Biological Center. "We're able to come up with concepts and designs using our [computer-aided design] software, print them out and have them in an engineer's hand the next day."

"We are deftly pushing what we like to call rapid tooling," Moore said. "It uses these technologies to build molds as opposed to conventional machining a mold."

These artisan engineers create three-dimensional objects out of plastic and metal in printers that seem like Star Trek replicators.

Injection molding is a more conventional manufacturing technique; however, the team uses 3D printing technology to augment, test and even make molds that otherwise would add weeks or months to the process.

One massive printer uses a carbon dioxide laser to precisely melt powder. As one layer solidifies, the platform drops a little, a fresh layer of powder is spread and the laser goes to work on the next layer.

Three-dimensional objects are created with computer-aided design, or CAD, programs, but Moore and his team also use lasers to "read" an object to create a 3D file. This process allows them to reverse engineer practically anything.

"Every day we're building parts for the customer whether it is an exploded fragment or munitions," Moore said. "The more our customers use 3D printing, the more they're relying on it to do their testing before they do the manufacturing. So, it's become an every day thing."

3D printing may have been pioneered in the 1980s and brought to the market in the mid-1990s, but combining the processes with more powerful software and accurate lasers offers potential for future manufacturing techniques.

For example, an Army technician scans part of a protective mask. As the laser passes over every millimeter of the object, the computer plots points in 3D space. On-screen the mask immediately comes into view as a three-dimensional object. Sending the file to the printer results in a solid copy you can hold in your hand within a few hours.