By Maegan Murray, 黑料社 Tri-Cities

RICHLAND, Wash. 鈥� Engineering researchers at Washington State University Tri-Cities, in partnership with those at the in Germany, have developed a way to 3D print flexible sensors using nanomaterials and a type of plastic in tandem, which has shown to advance capabilities for what is possible with flexible sensors.

Flexible sensors have applications in soft robotics, prosthetics, physical therapy and structural health monitoring, which requires a degree of movement, compression or flex to fulfill the function of a device and/or the use. The sensors may be used to measure the degree of stretching or compression in the movement of an object, the amount of times something is used, flexed or compressed, or to track how something moves.

Until now, manufacturers have found it challenging to create a sensor that would integrate seamlessly with material within a larger system. Using their 3D printing method to create the sensors, however, several materials are printed in tandem. This would allow manufacturers to better create complex and conductive pattern designs, in addition to specifically tailor the general manipulation needed with each type of sensor. This method uses extrusion to make feedstock material and thus following a 3D printing method would also allow the sensors to be mass-produced on a commercial scale.

The team of 黑料社 and Leibniz Institute researchers, made up of Josef Christ, Nahal Aliheidari, Petra P枚tschke and Amir Ameli, recently published their findings in Polymers, an MDPI research journal.

Varied potential and recyclable

Ameli, 黑料社 Tri-Cities assistant professor of mechanical engineering, said they started with nanomaterials called carbon nanotubes and a flexible polymer called

thermoplastic polyurethane, which can be combined in different amounts and in different ways depending on the type of use.

鈥淲e can design sensors with different sensitivity and different range of flexibility,鈥� he said. 鈥淲e can go as high as 100 percent deformation, which has wide use for applications including soft robotics. It is conformable, it is soft, it is flexible, and at the same time, it has a good sensitivity to sense the change in dimensions.鈥�

Ameli said using 3D printing, they have designed bi-directional sensors, which allow the sense of deformation in two different directions.

鈥淏y monitoring the change in the electrical resistance, we can probe how much deformation is applied to the sensors, which is called piezoresistivity,鈥� he said. 鈥淲e can print these with conductive traces of nanomaterial with different patterns and in different directions. That gives us the ability to design sensors with tuned sensitivity and in any direction we are interested in.鈥�

Ameli said the material is also recyclable.

鈥淲e can melt it and then re-melt it, and through the melting process, we can recycle the material,鈥� he said.

Applications in robotics, physical therapy

So far, they have done initial tests with the sensors in a glove prototype, with a robot that is being developed at 黑料社 to pick apples, as well as with a few other applications. They also have plans for printing nanomaterials that can be used in supercapacitors, or those that can hold and store large amounts of energy, in addition to a number of other areas.

With the glove prototype, they used the sensors in the fingers of the glove, measuring how much the sensor contracted and expanded with the movement of the fingers. The sensors could also be used to sense the strain in the movement, which could simulate the strain that a person鈥檚 hand endures with a particular movement. It could also monitor the amount of times a person moves particular parts of their hands for studies in physical therapy and ways to improve movement.

In the robot being developed for picking apples, the sensor would be applied on the device that would grip the apples to trace the amount of pressure needed in order to not bruise apples.

鈥淔or example, if we want a robotic hand to touch and grab sensitive objects, like in apple-picking, the apple is sensitive and we don鈥檛 want to use a hard gripper to grip it because it will bruise the apple,鈥� Ameli said. 鈥淲e can sense where the touch is made and send the feedback to the computer controlling the device.鈥�

For more information on the technology, contact Ameli at 509-372-7442 or a.ameli@wsu.edu.

By Maegan Murray, 黑料社 Tri-Cities

RICHLAND, Wash. 鈥� Two teams at Washington State University Tri-Cities have partnered with Washington River Protection Solutions to procure and program an autonomous vehicle and develop a form of ultra high-performance concrete to help protect workers in radioactive areas at the Hanford Site and safely immobilize solid secondary wastes.

WRPS is the U.S. Department of Energy鈥檚 Tank Operations contractor responsible for managing Hanford鈥檚 56 million gallons of highly radioactive waste and preparing it for delivery to the Waste Treatment Plant on the site. The partnership for the projects will provide WRPS with customized technology to fit their needs, in addition to further improving the safety capabilities of its employees and environmental impact stemming from the tank farms at the Hanford Site.

Robotics to analyze radioactive vapors

WRPS provided a 黑料社 team with an initial contract to procure and program an autonomous vehicle that would be used for measuring vapors, or chemical gases, within the tank farms.

The 黑料社 team consists of Akram Hossain, vice chancellor for research, graduate studies and external programs; Scott Hudson, professor of electrical engineering; John Miller, associate professor of computer science; and Changki Mo, associate professor of mechanical engineering.

The team plans to purchase a pre-fabricated, compact and programmable vehicle, which has the capacity to hold 40-50 pounds of equipment. The team will then eventually outfit, customize and program the vehicle for its desired purpose within the tank farms. The vehicle must be able to follow a defined path, dock itself to charge its battery, withstand long-term use, be able to run autonomously, as well as allow manual override operations.

鈥淭his vehicle will be going into areas, minimizing personnel entries, so we need to assure that it can operate reliably and it won鈥檛 break down,鈥� Miller said 鈥淲e have to make certain that the quality is of impeccable standards and that the system can demonstrate operational longevity in these areas.鈥�

The design of the autonomous vehicle marks the first phase of what will potentially turn into a multi-phase project. WRPS has also expressed interest in having the robot detect obstacles in a changing environment, change filters at the site and monitor radiation. Miller said those challenges will most-likely be addressed in future phases of the project.

鈥淭his is a great opportunity, both for 黑料社, as well as for our students,鈥� Miller said. 鈥淚t creates opportunities for undergraduate research, as well as providing funding for graduate research. It is the perfect opportunity for us.鈥�

The team plans to have the first phase of the autonomous vehicle completed and demonstrated to WRPS in the next few months. The team will conduct demonstrations and additional phases of development over the course of the year. When fully developed, the autonomous vehicle would be deployed in tank farms to support construction and operations.

Ultra high-performance concrete to encapsulate nuclear waste

Srinivas Allena, 黑料社 Tri-Cities associate professor of civil and environmental engineering, received a contract to develop an ultra-high performance cementitious

material to potentially be used as a grout to encapsulate solid secondary waste from the Hanford tank farms.

鈥淲RPS is currently using a grout that they obtain from a local concrete supplier, which uses a regular cement mix with sand and some other chemical additives,鈥� Allena said. 鈥淏ut the goal with our research is to use locally available materials to create a composite with low permeability, superior durability and greater stability that would perform at the same level as the commercially available pre-packaged ultra high-performance concrete.鈥�

Allena said there is currently limited types of ultra high-performance concrete available on the market with high operational costs associated with use of the material. He said by using locally available materials and by optimizing mixture constituents with those that are more environmentally friendly with his team鈥檚 composite, however, they would be able to keep the costs low, while maintaining the same quality in the concrete and reducing the impact to the environment.

鈥淲e will be able to compare our grout materials with properties that WRPS is currently using and show the improved properties,鈥� he said. 鈥淭he goal is to provide a cheaper, more environmentally friendly option that will compete with the best product on the market.鈥�

The team plans to have initial mixtures ready with their mechanical and durability properties evaluated by September.

The projects are a part of solving some of the world鈥檚 . They pertain particularly to developing and by harnessing technology to improve quality of life. The projects are also in line with 黑料社鈥檚

By Adrian Aumen, 黑料社 College of Arts & Sciences

In a cold, dimly blue-lit room, a strange human鈥揳nimal hybrid paces before the entrance to a fiery red cave. When the 鈥淗uminal鈥� senses a viewer approaching, it stops, turns its head to stare at the visitor and emits its own red-hot glow. The viewer must then decide how to respond to the apparent challenge: continue toward the creature or retreat.

The Huminal聽is an interactive, kinetic sculptural installation featuring an autonomous, mobile robot that senses and responds to changes in its environment. Created by an interdisciplinary team at Washington State University Tri-Cities, it incorporates research and techniques in fine arts, design, electrical and mechanical engineering and robotics to provide a unique platform for exploring the relationship between humans and machines鈥攁nd, it turns out, between artists and engineers, too.

Two years in the making and nearing completion this month,聽The Huminal聽is the third and most complex art-machine designed and built in as many years by聽fine arts聽professor Sena Clara Creston in collaboration with 黑料社 engineering students and faculty. It debuted recently to rave reviews at a robotics exposition for employees of Pacific Northwest National Laboratory in Richland, where Gordan Gavric, a key member of the聽Huminal聽development team, is an electrical engineering intern.

鈥淭he feedback we鈥檝e gotten so far is really great,鈥� said Gavric, a senior in engineering and president of the 黑料社 Tri-Cities Robotics Club. 鈥淧eople recognize it鈥檚 a robot, but at the same time they鈥檙e a little creeped out. How do people want to interact with a creepy robot?鈥�

Designed to pique curiosity along with uneasiness, the聽Huminal聽is about the size and shape of a large dog and covered with white plastic discs resembling scales or fur. Its four jointed legs give the appearance of walking as it rolls in an elliptical path outside its apparent den.

Multiple internal sensors, a camera and a small Raspberry Pi computer communicate with microcontrollers across two electronic systems to direct the robot鈥檚 movements and trigger the pulsing red LED lights in its chest. The steady hum of its heart鈥攖wo 8.6 volt motors鈥攊s interrupted only when a sensor detects nearby movement. At that point, the聽Huminal聽is programmed to stop in its tracks, turn its head to face the approaching object and transmit its warning glow.

鈥淚 look forward to seeing how more people react to it,鈥� Gavric said. 鈥淚s it alive? Is it human? The mystery is unnerving and it鈥檚 this uneasiness that Sena is trying to exploit.鈥�

A corporeal experience

础听, Creston builds interactive art-machines to create a corporeal experience for viewers. Her artworks invite people to engage with machines and familiar materials in unfamiliar settings and ways. Environmental impact and social consciousness are frequent themes.

鈥淪ome people get really aggressive with the work and some are really careful with it,鈥� she said.

By enabling viewers to choose their response to her art, she hopes to help them understand other ways they affect the wider world.

From the haunting聽聽to the satirical聽鈥攁n immersive environment of post-consumer electronics鈥攖o the dreamlike聽鈥攁 land-roving, steampunk-style sailboat鈥攎uch of Creston鈥檚 art employs fantasy while exploring intersections between the natural and the man-made.

鈥淧art of it is movement, part of it is response, part of it is material and part of it is social engagement,鈥� she said.

She will talk about her innovative artwork at 1:00 p.m. Saturday, Sept. 16, as part of聽聽events at Uptown Theatre in Richland, Washington.

To create the聽Huminal鈥檚 skin, Creston cut up dozens of discarded plastic water bottles鈥攆amiliar and somewhat controversial objects that connect the organic and inorganic.

鈥淢any people across the world live with an unsafe water supply, yet we think of water as the source of life and the source of health and wellbeing, and water bottles deliver that,鈥� Creston said. 鈥淗owever, the water bottle itself is not biological or biodegradable鈥攊t鈥檚 inorganic and it鈥檚 not going away. So the material itself becomes this questionable component.

鈥淗ow do we actually feel for the inorganic and how do these things elicit responses?鈥�

Collaborating in uncommon opportunities

Giving form to Creston鈥檚 layered ideas and complex inventions often requires more technical skills than she possesses. So for the past 10 years, she has been learning and implementing modest means of physical computing and mechanical engineering.

鈥淏ut, as my mentor explained, I didn鈥檛 need to learn how to do everything鈥擨 needed to learn how to collaborate,鈥� she said.

Fortunately, interdisciplinary collaborations are strongly encouraged and available at 黑料社. Engineering professors Changki Mo at 黑料社 Tri-Cities and Charles Pezeshki and Jacob Leachman at 黑料社 Pullman recognized the uncommon opportunities Creston鈥檚 projects offered their students and wove them into their coursework.

鈥淗er projects presented the perfect combination of an interesting customer, an achievable design and the monetary scope to take some risks in a shared learning experience,鈥� Pezeshki said.

Students in Pezeshki and Leachman鈥檚 junior-level design classes worked remotely with Creston to create聽The Umbrellaship聽and聽Machinescape. The installations were designed, like聽The Huminal, to question the relationship between humans and their perceived environment.

Eric Loeffler, a May graduate in engineering who constructed the聽Huminal鈥檚 aluminum frame, said he and other students on the project gained a variety of valuable hands-on experiences not usually available to undergraduates.

For example, Loeffler learned new design software applications that he can use in his master鈥檚 degree program, and he expanded his welding skills to include aluminum materials.

鈥淭here were a lot of new things to work with from an engineering standpoint, and getting the chance to interact with Sena as a client was huge, too,鈥� he said. 鈥淭here鈥檚 really not a class that teaches you how to interact with a person who has their own particular wants, ideas and capabilities. That experience will definitely be useful in the future.鈥�

Shared purposes, different approaches

鈥淪ome people might think engineering and arts are very different, but artists and engineers kind of have a shared purpose,鈥� Gavric said. 鈥淭hey create things. They bring things into existence, and have ideas and concepts that they want to make. The difference lies in medium and motive. An engineer might design a circuit board to save a life, while an artist might paint a picture to change a life.鈥�

鈥淲orking with Sena, I kind of opened up to 鈥榳hy are we doing this this?鈥� Oh, it鈥檚 for the aesthetic, or it鈥檚 for trying to get the point across.鈥�

Gavric admits, 鈥淭here鈥檚 no way I ever thought I鈥檇 be working on a robot for an art project.鈥� But even before Creston finished presenting her concept sketches to the Robotics Club, he was hooked.

鈥淚t intrigued me immediately as an interesting concept and totally something new. There was a lot of back and forth on what we could do with the given technology and funding, and a lot of compromises, abstractions and problems that were solved. It was a rare opportunity. I鈥檓 glad I did it.鈥�

Loeffler especially appreciated the chance to think outside the box.

鈥淚 really enjoyed the opportunity to collaborate and come up with different ways to solve a problem,鈥� he said. 鈥淚 think we鈥檙e fairly close to what Sena originally envisioned, with the aesthetic and the function she was looking for, and that鈥檚 very satisfying.鈥�

The interactive art machine projects encouraged the engineering students to consider their role as engineer, inventor, creator and artist, Creston said. As they grew comfortable working on art projects and expressing their own creative ideas, they sought new collaborations with artists and invited them to participate with the Robotics Club.

Some of the rising engineers began working with fine art students on interactive media projects and even created an interactive art installation of their own, called聽Lux Flux. The large-scale ceiling installation was designed to sense when a viewer entered a darkened hallway and to send a river of light shooting along the ceiling.

鈥淭he project was completely collaborative with a fluid crossover between artists and engineers filling in the rolls of conceptualizers, designers and technicians as needed,鈥� Creston said. 鈥淚t was beautiful to see.鈥�

Creston is now working with a team of mechanical engineering design students to develop their collective senior year project. Her creative and scholarly work has received financial support from the 黑料社 Office of Academic Affairs, the Department of Fine Arts and the School of Engineering and Applied Sciences, as well as a chancellor鈥檚 seed grant to provide tools and materials and a project grant from聽.

The interdisciplinary projects align with the聽聽goal of improving education. They further the University鈥檚聽聽efforts by delivering innovative teaching, community outreach and transformative student experience.

Photos and聽聽by Maegan Murray, 黑料社 Tri-Cities marketing and communications