Perfect surface finishes for 3D printed components

Mass finishing creates smoothness and luster in one single step

Walther Trowal developed the „AM post process machines“, model range AM, especially for refining the surface of components produced with additive manufacturing. The experience of the first customers using these machines shows that the mass finishing technology creates surface finishes in one single step, which meet the highest demands.

Most 3D printed components are produced by placing material layers on top of each other, creating a „staircasing“ effect on their surface with, generally, a very high initial surface roughness. For this reason, many of these components must undergo a surface smoothing or polishing operation. Also, most of the time the markings of removed support structures and sintered-on powder residue must be removed, before the components can be further processed or utilized.

Mass finishing has proven to be the ideal surface finishing method for 3D printed components: These are completely embedded in the moving grinding media so that the process is very gentle and produces absolutely homogeneous and repeatable surface finishes. Moreover, the media also reaches internal passages and undercuts in the components.

The AM post process

Depending on the size of the processing bowl, up to 100 small work pieces or single components with a size of 900 x 500 mm can be treated in the model range AM of the new „multivib“ vibrators. The work pieces are mounted on a carrier plate, which in turn is clamped to the bottom of the processing bowl by mechanical or electromagnetic means. Once the work pieces are in place, the media is filled into the processing bowl. During the process compound and water are continuously added. Three vibratory motors induce an intensive vibration into the processing bowl. Since the vibratory movement generated by the motors is overlapping, the component surface becomes smoother, while the edges are left intact. After a pre-determined cycle time the process is completed, and the finished work pieces can be removed.

Several manufacturers of automotive, aircraft and medical components are already using the new AM „multivib“ vibrators. These machines reduce the surface roughness of the raw work pieces from around Ra = 2 to 80 µm down to a value of 0.025 µm.

Maximilian Beien, sales manager at Walther Trowal, considers additive manufacturing and mass finishing as a perfect match: „Additive manufacturing and mass finishing are an ideal combination because most 3D printed components must have an excellent surface finish to fulfill their function. For example, turbine blades require an airflow with minimal friction loss. Components with stringent specifications for hardness and strength benefit from the homogeneous peening effect induced by mass finishing. This finishing method is especially advantageous for 3D printed components with bionic shapes.“

Mass finishing is suitable for a wide range of materials utilized in additive manufacturing: For example, for high performance, difficult-to-machine metals like titanium, nickel based or cobalt-chrome alloys. Furthermore, for non-ferrous metals or plastic. With all these materials Walther Trowal has decades of experience.

In this connection it should be noted that the Walther Trowal grinding media and other consumables are already approved for many materials and safety-relevant components and processes.

Beien especially points out the high cost efficiency of the „trowalizing“ process in conjunction with additive manufacturing: „Compared to electro-chemical finishing methods mass finishing achieves the desired surface smoothness and luster in one single operation. Another advantage is that the mass finishing equipment is very compact with a small footprint. The result: An excellent surface finish, surprisingly short cycle times and an overall high cost-efficiency, not only with regard to the capital expenditures but also the operating costs.

Additional information:
A proven finishing method for an innovative manufacturing technology

Topologically optimized work pieces with complex – frequently bionic – shapes often have difficult-to-reach internal passages. Manual finishing of these surface areas is not possible, especially when the work pieces are subject to strict safety and manufacturing standards, which is the case, for example, in the aerospace industry. Moreover, 3D printing is already used for serial manufacturing with continuously increasing production volumes.

Christoph Cruse, general sales manager at Walther Trowal, looks forward to assist the users of additive manufacturing with their surface finishing challenges: „A lot of things are going on in the field of additive manufacturing. For example, the production process as such must be optimized for many work pieces. For this reason, many customers are very pleased to learn that with regard to finishing the surface of AM components they do not have to invest additional development efforts but can rely on the proven „trowalizing“ finishing technology.“

The optimum parameters for the finishing process are, jointly with the customers, determined through processing trials conducted by the process engineers at the Walther Trowal test center. This also includes the selection of the most suitable grinding or polishing media and compound. The process parameters for every single work piece are stored in the PLC and can be retrieved at any time.

Based on his many years of experience with all kinds of projects, Michael Becker, the manager of the Walther Trowal test center, gladly shares his knowledge: „Compared to other finishing systems the single stage process facilitates and shortens the surface finishing operation significantly. Of course, the finishing operation can be further optimized, when all surface treatment considerations are already taken into account during the design phase for the 3D printed components and the parameterization of the printer. For example, this applies to determining the material layer thickness and the material feed rate of the printer. We gladly support our customers in resolving these issues.

Although additive manufacturing has already established itself as a system for volume production, there is a lot of potential for further technological improvement. In order to maintain its leading role in the field of surface finishing, Walther Trowal cooperates closely with the Direct Manufacturing Research Center (DMRC) at the university of Paderborn. To enable both project partners to conduct empirical studies, an AM-2 „multivibrator“ was installed at the Paderborn location.

About Walther Trowal

For more than 80 years Walther Trowal has developed, produced and sold modular and custom-engineered solutions for numerous finishing challenges in the field of surface treatment.

Initially only making vibratory finishing equipment, over the years Walther Trowal has continuously broadened its product range and today offers a wide portfolio of equipment and services for improving all kinds of surfaces, e.g. mass finishing, part cleaning, shot blasting and drying of a wide spectrum of work pieces, last but not least, the coating of mass produced small parts.

Walther Trowal offers complete surface treatment solutions: By linking the various equipment modules and automating the complete process, Walther Trowal precisely adapts the process technologies to the customer requirements. This also includes various types of peripheral equipment and process water cleaning and recycling systems. Of course, Walther Trowal also offers comprehensive pre- and after-sale service like sample processing in one of our demonstration labs and global repair and maintenance service.

Walther Trowal serves many customers in many industries around the world. For example, in the automotive and aerospace industry, medical engineering and wind power generation.

Walther Trowal GmbH & Co.KG
Georg Harnau
Rheinische Str. 35-37
42781 Haan, Germany
Phone: +49 2129 571-0
Fax: +49 2129 571-225

VIP Kommunikation
Regina Reinhardt
Dennewartstraße 25-27
52068 Aachen, Germany
Phone: +49.241.89468-24
Fax: +49.241.89468-44

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