Engineers from the University of Bradford have revealed the first 3D barcode for plastic products that can be integrated into a part during manufacture.
The anti-counterfeit marker is designed for use on moulded plastic parts, where a virtually invisible imprint is incorporated onto a product. The marker can then be read using a laser scanner, which the engineers say allow anything from phones to pills to be tracked and verified as authentic.
Made public at the British Science Festival in Bradford, the technology was devised by the UK SME, Sofmat Ltd, and has been developed in collaboration with engineers from the University of Bradford.
The 3D barcode is made up of tiny indentations in the surface of the product, created by pins that are integrated into its mould. Using micro actuators, the pins can be set at different heights, each step corresponding to either a letter (A-Z) or a number (0-9). The prototype – developed with funding from Innovate UK – works with a four-pin array, enabling over 1.7 million different configurations.
“The system enables very small displacements to be made in each pin – each step being just 0.4microns, 100th of the width of a human hair,” explained Dr. Ben Whiteside from the University of Bradford.
“These have to be set with a very high accuracy and with sufficient force so their position is maintained during the manufacturing process. While our system has been developed initially for products made from plastics or composites through injection moulding, it could also be used to stamp or emboss the code onto a product.”
Estimates for the total value of fakes sold worldwide each year reach as high as $1.8 trillion. Most anti-counterfeit devices are stuck onto the product or its packaging after manufacture, making them easy to copy. Because the 3D barcode is an integral part of the product itself it is very difficult to reproduce.
“A 3D barcode allows much more complexity than existing anti-counterfeit systems,” explained Sofmat Director, Dr Phil Harrison. “You can have multiple configurations, different codes on each individual product and additional details such as patterns on the heads of the pins themselves, making copying the code extremely difficult. For the first time the same technology and coding can be used on bulk packaging, individual packaging and on the actual product, making it much harder to create and ship fake products.”
The system has been verified in the laboratory using high-tech scanning devices including a white light interferometer and a laser-scanning confocal microscope to characterise the surface of the coded ‘product’ to ensure the code is accurately reproduced. A laser scanner is currently in development that will be able to read the code and wirelessly transmit the result via an app to either a phone or tablet.
“The technology behind the moulding of the 3D barcode can be used for several different industries, for example the electronics industry, the automotive industry, medical and pharmaceutuical,” explained Dr Elaine Brown, Senior Lecturer in Mechanical and Process Engineering at the University of Bradford.
“Anything that uses moulded plastics and composites could actually integrate this type of barcode technology into their products.”