Z-pinning is a technique to insert reinforcing fibres (also called Z-pins or Z-fibres) along the Z-direction of continuous

fibre-reinforced plastic Fibre-reinforced plastic (FRP; also called fibre-reinforced polymer, or in American English ''fiber'') is a composite material made of a polymer matrix reinforced with fibres. The fibres are usually glass (in fibreglass), carbon (in carbon-fibre ...

s. Z-pins can be made of metal or precured unidirectional composite fibres. It is designed for use within

pre-preg Pre-preg is a composite material made from "pre-impregnated" fibers and a ''partially cured'' polymer matrix, such as epoxy or phenolic resin, or even thermoplastic mixed with liquid rubbers or resins. The fibers often take the form of a weave ...

technology; there is extensive experimental evidence that Z-pinning dramatically improves the resistance of the composite structure to

delamination Delamination is a mode of failure where a material fractures into layers. A variety of materials, including Lamination, laminate Composite material, composites and concrete, can fail by delamination. Processing can create layers in materials, suc ...

. The figure on the right shows a Z-pin inserted in between the fibres of the material. The pin spreads the fibres and creates an oval shaped gap that is filled with

resin A resin is a solid or highly viscous liquid that can be converted into a polymer. Resins may be biological or synthetic in origin, but are typically harvested from plants. Resins are mixtures of organic compounds, predominantly terpenes. Commo ...

. The Z-pin prevents the composite from delamination. When a load is applied the cracks will typically form along the line of the opening.

Benefits

Z-pinning is a versatile technique that can be applied to many materials that will benefit from added strength and durability. They are especially effective when used in materials that are subject to

, because the Z-pins can counteract this problem. Z-pinning has been used in aircraft manufacturing to add strength. By Z-pinning the materials on an aircraft, such as the wings, it can have a much higher resistance to damage during flight. Also, if the aircraft does suffer from a minor crack, the Z-pinning will prevent it from catastrophic failure. Z-pins can also be used for automotive applications. The pins can be inserted into

carbon fibre Carbon fiber-reinforced polymers (American English), carbon-fibre-reinforced polymers ( Commonwealth English), carbon-fiber-reinforced plastics, carbon-fiber reinforced-thermoplastic (CFRP, CRP, CFRTP), also known as carbon fiber, carbon comp ...

parts to increase the strength of them. If the front splitter of a car was constructed with Z-pins, it would be able to withstand significantly more impacts because the Z-pins would hold it together even with a minor crack. This allows the carbon fibre parts to remain light while still being strong. Testing of different size Z-pins has indicated that larger pins lead to an increase in strength. A 1% increase in the size of the Z-pin increases toughness by up to 6 to 25 times. However, too large of a pin can disrupts the fibres of the material more leading to it fracturing.

Z-Pin production

There are many methods of creating Z-pins. Typically, Z-pins are pre- cured and then inserted into composites. One process consists of pulling a continuous-fibre tow through a bath of liquid resin using a

pultrusion Pultrusion is a continuous process for manufacture of fibre-reinforced plastics with constant cross-section. The term is a portmanteau word, combining "pull" and "extrusion". As opposed to extrusion, which pushes the material, pultrusion pulls th ...

machine. The fibre is then pulled out of the bath through the die which creates the shape and size of the pin. The pin is next sandwiched in a vertical orientation in foam to finish the process. The pin may be coated or treated as an additional step depending on the application. This process is one of the more efficient and cost effective ways of producing Z-pins because it can be easily adapted to different pin sizes.

Manufacturing with Z-Pins

Z-pins have many ways of being inserted into the material of choice. The most common method is a process using an ultrasonic hammer. The hammer compresses the

foam Foams are two-phase materials science, material systems where a gas is dispersed in a second, non-gaseous material, specifically, in which gas cells are enclosed by a distinct liquid or solid material. Note, this source focuses only on liquid ...

that encases the pins and pushes the pins into the material. The hammer induces high frequency vibrations to the pin as it compresses. The vibrating chamfered tip of the Z-pins locally heats up and softens the resin allowing the Z-fibre to penetrate the preform with minimal disruption of the long fibres. The remaining pin and

laminate Simulated flight (using image stack created by μCT scanning) through the length of a knitting needle that consists of laminated wooden layers: the layers can be differentiated by the change of direction of the wood's vessels Shattered windshi ...

above the surface are removed to create a smooth and even surface The surface can be finished with a coating to seal the Z-pins inside the material. A hand-held ultrasonic gun can also be used to insert Z-pins on a small scale production. This is ideal for testing materials containing Z-pins because they can be easily inserted into any location on the material.

References

External links

Cranfield University page with Z-pinning unit description
{{DEFAULTSORT:Z-Pinning Composite material fabrication techniques

Benefits

Z-Pin production

Manufacturing with Z-Pins

See also

References

External links