"Voltaglue" sticks in the wet and hardens when voltage is applied

 

NTU Asst Prof Terry Steele (right) with his researcher Gao Feng have developed a glue that hardens when an electrical voltage is applied A glue that performs at a high-level in wet environments could bring about all sorts of possibilities in areas like surgical care and ship maintenance. A somewhat common approach to this problem has been trying to replicate the freakish ability of mussels to bind themselves to boats and jetties, but a team from Singapore's Nanyang Technological University is coming at it from a slightly different angle by developing a glue that hardens when an electrical charge is applied. As the team's lead scientist Professor Terry Steele points out, most glues don't work when they're wet, in the same way that sticky tape won't stick to a wet surface because the adhesive will stick to the water rather than the surface. Steele and his team have been at work for more than a year, crafting a new form of adhesive that can perform its job in wet conditions, such as underwater or in the human body. They used hydrogels comprising carbon molecules known as carbenes, which are grafted onto tree-shaped plastic surfaces called dendrimers. Applying an electrical charge kicks the carbenes into action and sees them hook onto any nearby surfaces. A particularly promising aspect of this approach is that the length of time the voltage is applied to the gel dictates how many of these hooks the carbenes create. This means by controlling the charge you control the hardness of the glue, and in turn, its suitability for different applications. The team call this process "electrocuring." "For example, if we are gluing metal panels underwater, we want it hard enough to stick for a long time," says Steele. "However, for medical applications, we want the glue to be more rubber-like so it wouldn’t cause any damage to the surrounding soft tissues." Another attribute that could prove a huge plus of the glue, which the team has nicknamed "Voltaglue," may be the ability to reverse the process. That is, to cancel out the glue's adhesive properties to allow for simple dismantling of ship parts, for example, negating the need for nuts and bolts. Steele and his team are now working to reduce the time it takes for the glue to harden, from around half a minute down to just a few seconds. They will also conduct further research into the possibilities of making it "reversible." The research was published in the journal Nature Communications. Source: Nanyang Technological University   http://www.gizmag.com/voltaglue-adhesive-underwater-electricity-voltage/39107/

Adhesive bonding with pre-applied adhesives

 

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In industrial production, bonding plays an increasingly important role. Researchers have now succeeded in separating the processes of applying the adhesive and the actual joining, which opens up a new world of applications.

Adhesive bonding technology is an effective and inexpensive means of seamlessly joining two parts, even two made of different materials. Especially in lightweight construction, adhesive bonding is the preferred technique because many of the materials used can hardly be joined otherwise. However, since liquid adhesives need time to cure, they cannot be applied in every production step. In hopes of finding a way to eliminate the need for regularly applying liquid adhesive while joining fasteners, the automotive supplier STANLEY Engineered Fastening -- Tucker GmbH in Gießen turned to the researchers at the Fraunhofer Institute for Manufacturing Technology and Advanced Materials IFAM in Bremen. Their solution was a two-step process in which adhesive is initially deposited on one of the parts and then dried to form a non-sticky layer. During a subsequent production step, the adhesive is hardened and the two parts are bonded together.

Although two-step bonding techniques aren't new -- early postage stamps were coated with an adhesive that would only stick to envelopes once moistened -- using them for industry is. Fraunhofer IFAM researchers have successfully developed the technique to allow for a high-strength adhesive bond suitable for industrial use -- no easy task, since the adhesives must fulfill different and sometimes contradictory requirements. "Once the adhesive is applied, it can't be tacky and it has to withstand long storage times," explains chemical engineer Andreas Lühring from Fraunhofer IFAM. But the adhesive has to do more than that. "The adhesive also has to be very reactive and harden quickly during joining." The researchers' concept combines resins and hardening agents that melt at different temperatures. "We use micro-dispersion to finely distribute hardening agents with considerably higher melting points throughout the resin base," adds Professor Andreas Hartwig.

The resulting reactive, hot melt adhesive is used in the manufacture of fastening bolts, for instance. First the material is heated and then applied onto the fastener. After it cools, it solidifies again. The fastener can then be transported and stored without difficulty. To harden the actual adhesive, it must be heated to more than 150 degrees Celcius in a controlled way. "Only then is the actual hardening agent melted and the adhesive activated," explains Lühring. In this way, two parts can be bonded to each other within seconds.

"There is one disadvantage to reactive adhesives like these -- they can be stored for a long time, but not indefinitely," says Dr. Matthias Popp, group manager at Fraunhofer IFAM. That's why the researchers had added an additional, visual means of monitoring the adhesive -- if the substance has lost its functionality, it changes color.

These pre-applicable structural adhesives (PASA®) are also suitable for other applications, including a variable "construction kit" that offers adhesives based on different materials and hardening principles. The IFAM experts have altered the composition of the adhesives so that they yield the best possible productivity and characteristics for a wide variety of applications. For this development, Andreas Lühring, Andreas Hartwig and Matthias Popp received one of this year's Joseph von Fraunhofer prizes.

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The above story is based on materials provided by Fraunhofer-Gesellschaft. Note: Materials may be edited for content and length.