Additively manufactured mandrels

Innovations in tooling for making hollow parts provide composite manufacturers new opportunities.

3D-printed sacrificial core for duct
photos courtesy Massivit 3D Printing Technologies Ltd.

Additive manufacturing (AM) can disrupt industrial processes and facilitate achieving innovative, cost-effective, and speedy outcomes when compared to traditional production processes. Coinciding with the rapid growth in demand for products made from composite materials – which are inherently stronger, lighter, and more environmentally resistant than conventional materials – AM is today set to revolutionize composite production in the defense, aerospace, and additional industries. In these sectors it can (among other things) be used to create mandrels for ducts and vents for air, fluid, and energy management applications.

Mandrels are an essential tool when making hollow composite parts and components. During the manufacturing process, the mandrel is inserted into the end of a tube or pipe and held in place while the object is being formed around it. This ensures the finished product retains its shape and size.

Traditionally, the most common type of mandrel is made from steel, but aluminum and other metals can also be used. Such mandrels, however, can have limited applications and can be expensive. However, manufacturing processes can be simplified and optimized using AM to produce mandrels as sacrificial tools for composite manufacturing.

Composite materials, used extensively across many manufacturing sectors, are materials made of two or more distinct components. These components can be metals, polymers, ceramics, fibers, and various other substances, depending on the application. Composite materials are used in various industrial applications because they offer benefits over traditional materials such as being lightweight, allowing for fuel efficiency, and exhibiting increased strength, stability, resistance to wear, and resistance to weathering and environmental damage.

Composite materials are easier to fabricate and mold into complex shapes than metal, plastic, and ceramics. By combining different types of materials, engineers can create materials meeting specific requirements and provide lasting service to many industries. With the growing demand for composite materials, these versatile materials will continue to play an important role in industry for years to come.

Conventional vs AM mandrel production

Traditional mandrel making methods have existed for centuries and are still in use today. The three main traditional methods of making mandrels are casting, forging, and machining.

Casting is the most common method of making industrial mandrels. In this process, molten metal is poured into a mold in the shape of the desired mandrel. The metal cools and hardens, and the mandrel is then removed from the mold. In the forging process, a piece of metal is heated until it’s malleable, and then it’s shaped into the desired mandrel using hammers and other tools. In the machining process, a piece of metal is cut or milled into the desired shape using lathes, milling machines, or other machine tools.

There are inherent disadvantages of using conventional mandrel production technologies – they’re often time consuming, labor intensive, can generate a lot of waste material, and they’re limited in the geometric complexity that can be achieved.

Encapsulated 3D-printed mandrel with skin in bath

AM can create mandrels with complex geometries that would be difficult or impossible to produce using traditional methods. AM offers a more flexible approach to create mandrels with intricate designs and internal features extremely quickly, without needing expensive cutting tools. Traditional mandrel production methods also require multiple parts to be produced if there are complex geometries or overhangs, otherwise it wouldn’t be possible to remove the mandrel core. Producing multiple parts means extra cost, is time-consuming, and opens the possibility of errors and reworking.

The benefits of using AM to make mandrels include lower tooling costs, shorter lead times, and greater flexibility in design. Additively manufactured mandrels can be made quickly and easily from a digital file, making them ideal for short-run or one-off production runs. Additionally, they offer designers greater freedom in shape and geometry compared to traditional techniques.

The solution

Massivit 3D has developed a proprietary printing process for producing strong and durable mandrels. This solution for producing composite parts offers significant advantages over traditional manufacturing methods and enables the production of high-quality composite parts with reduced lead times and lower costs.

One key advantage of using AM to make mandrels is it allows more complex designs than traditional machining methods. With AM, there are no constraints on the geometric shapes produced, meaning mandrels can be made with very intricate designs. This opens a whole new range of possibilities for mandrel designs and means they can be tailor-made to suit the specific needs of a particular application.

As the demand for composite parts increases, so does the need for more efficient and cost-effective production solutions. Massivit has developed the Massivit 10000 AM system to meet these requirements. The machine uses Cast In Motion (CIM) technology in combination with Massivit 3D’s patented Gel Dispensing Printing (GDP) method. It allows direct casting of the mold into a 3D-printed sacrificial shell. To achieve this, the Massivit 10000 uses a dual-head system, ultra-fast patented technology, and for the mandrels uses water-breakable material that crumbles in water. These allow manufacturers to produce complex mandrels within a matter of hours instead of weeks.

Massivit’s water-breakable material is suited to mandrel production. Obviously, one notable feature of the material is that it crumbles in water, allowing the mandrel to be easily removed from the final product after production. The material is also lightweight (making it easy to handle and transport during the production process); strong and durable (allowing it to be used for a variety of mandrel applications); environmentally friendly (minimizing waste when compared to subtractive methods and minimizing the need for extensive material storage); and speedy, with mandrels printing in a matter of hours.

Case study

Massivit 10000 3D-printed sacrificial mandrel with carbon skin.

To illustrate the disruptive nature of the Massivit 3D approach to mandrel production, this case study looks at the process steps involved in the manufacture of a mandrel for the company Kanfit which serves the defense and aerospace sectors. The commissioned mandrel needed to be printed in Massivit’s water-breakable material, and the outer surface of the printed mold needed to be very smooth.

First, a CAD model of the mandrel with dimensions X 381mm, Y 191mm, and Z 567mm was created. To make it optimally aligned to Massivit’s 3D printing technology, the flange area of the model was extended digitally for better layup fabrication, and the wall of the mold was designed with three printing contours with a final width of 5.4mm to withstand the vacuum pressures at the fabrication stage. From the finished CAD file, the G-code of the mandrel was created on the Massivit Smart slicer software. The print was designed to use minimum time and material and took in total only eight hours. The mandrel was produced using Massivit’s water-breakable DIM WB photo polymer material.

The part was then post-processed. The surface was sandpapered, and one coat of epoxy was applied to make the surface of the mandrel airtight.

For the layup stage, the mandrel was set up on a rotating jig, enabling the application of epoxy and carbon-fiber sheets (six in total) around the tool. Once coated in carbon-fiber, the mold entered the vacuum process, where it remained under vacuum pressure for three hours. It was then removed and allowed to rest for 24 hours before the final cure.

Carbon air duct skin produced from 3D-printed mandrel.

The finished mold was placed in plain water for 24 hours, and all remains of the water-breakable material were removed from the skin. The mandrel was then trimmed and validated in the quality control department before release.

Using AM to produce the mandrel around which composite parts in such applications are made introduces a simplification and streamlining of the process of composite production when compared to legacy mandrel production.

Summary

Mandrels made using AM have the potential to revolutionize the way composite parts and components are made. Mandrels produced using AM offer several advantages over traditionally manufactured mandrels. They are lighter, more precise, and can be easily customized to fit the specific needs of each part. This results in faster production times and a reduction in waste. In addition, mandrels made using AM can be produced from advanced materials such as Massivit’s water-breakable material which simplifies removal.

This enables the production of composite parts that are of higher quality and more reliable. The future of composite part manufacturing is bright with the advent of additively manufactured mandrels using this technology and Massivit’s 10000 printer.

Massivit 3D Printing Technologies Ltd.


About the author: Oleg Yermanok is application engineering manager, Massivit 3D.

August 2024
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