Sulzer Technical Review Issue 3 / 2018

Using digital technologies to create spare parts

July 26, 2018

Digitalization, realized by a specialist parts manufacturer such as Sulzer, is the key to rapid, precise repairs. Repairing critical equipment can be a time-consuming task, especially if it has been in service for a long time and original parts are difficult to source. In West Virginia, US, Sulzer reengineers and produces new casting parts for a wide range of rotating equipment using additive manufacturing technologies.

Two Sulzer employees in the foundry pouring metal in a mold
Author Stephen Dunlevy
Author: Stephen Dunlevy, Chattanooga TN, United States

Original equipment manufacturers (OEMs) will always do their best to provide a comprehensive array of spare parts for their products. However, after equipment has been in service for decades, the OEM may not be able to deliver this level of support. The manufacturer may have been acquired by another entity or ceased producing parts for this machine and have no further reserves on stock.

Click here to see a video about our US Parts Manufacturing Center.

Laser scanning for precise manufacturing

Replacing and repairing parts is important to maintain the equipment and to keep efficiencies at the required levels. When larger pieces of equipment are involved, their role is often more critical. Making a timely repair is very important in terms of downtime. Sulzer had this scenario in mind when it acquired Sturm Machine Co. in Barboursville, West Virginia, a few years ago to form the Sulzer US Parts Manufacturing Center.


As a provider of turnkey solutions, Sulzer is equipped with the latest technology and facilities to reverse engineer exact replica parts or create upgraded parts using design revisions, modern materials and advanced machining techniques. From three-dimensional (3D) laser scanning to the on-site foundry and the computer-controlled machining equipment, the service center in Barboursville can deliver precision parts with minimal lead time.


Creating a set of 3D engineering drawings is now much less time-consuming thanks to handheld laser scanners that can measure items quickly and very accurately. Sulzer has invested in both FARO systems and the HandySCAN 700. The latter is a very compact device that is accurate to 30 µm.


When creating replacement parts for crucial pieces of equipment, speed is of the essence and the sooner the 3D drawing is created, the better. Using the latest generation of laser scanners enables Sulzer’s engineers to gather 480’000 points of data every second. Seven intersecting laser lines ensure that even the most complex geometry is captured accurately.


Go and measure on-site

For equipment that cannot be easily moved, on-site engineers can visit customers’ premises to offer specialist advice and take essential measurements to create new engineering drawings. Sulzer uses multiple portable coordinate measuring machines (CMMs) and laser scanners for on-site data acquisition (Fig. 1). These allow dimensions to be repeatable within 0.025 mm (0.001 in.).

Once they have acquired the basic dimensional data, design engineers can then fine-tune the design of the new component. For example, they can adjust the geometry of an impeller to avoid damage to the casing or make sure clearances are optimal. The designers can also make alterations to the original design to account for changes in the application or performance needs.


3D precision data acquisition of parts
Fig. 1 Precision data acquisition allows dimensions to be repeated within 0.025 mm (0.001 in.).

Additive manufacturing for molds

Traditionally, casting a new component involved creating a wooden pattern of the original and putting it into a sand casting box. This is a very time-consuming process and it can take weeks to finalize it. It is also subject to considerable inaccuracies, especially if the wooden patterns are stored for any length of time and become distorted.

Now, designers can export the engineering drawings in a number of file formats, which can be utilized by a wide variety of machine tools and robots. One method is to utilize a 3D sand printer that uses the data to rapidly build a mold of the new component. Using layers of sand and adhesive, the 3D printer can create a mold that can withstand the high temperatures of molten metal that will form the new component (Fig. 2).
Creating new components using sand for a 3D printed mold
Fig. 2 Creating new components using sand for a 3D printed mold.

Speed up with patternless casting

During the mold creation process, Sulzer’s design engineers use computational fluid dynamics to predict the flow of gases within the mold as the molten metal is poured. It is essential that the gases have effective escape routes, or vents. Trapped gases would lead to weaknesses in the new component. The vents can be incorporated into the 3D CAD drawing and included easily in the sand printing process.

The 3D sand printer is one of Sulzer’s latest investments in state-of-the-art additive manufacturing technology that provides complete precision molds and cores. The process takes about 48 hours to complete, but depending on the size of the components, multiple molds can be printed at the same time, making it more efficient.

Another method of creating a mold, which is often used for making casings, involves two halves, known as the cope and the drag, which are brought together to create the finished shape. Today, the process starts with a solid block of sand that is machined using a multi-axis CNC robot milling tool to create a precision mold as laid out in the 3D CAD drawings (Fig. 3).

A multi-axis CNC robot creating a precise mold.
Fig. 3 A multi-axis CNC robot can create precise molds and cores.

To produce a wooden pattern for the sand casting box the traditional way takes 2–6 weeks, depending on the complexity of the pattern form. Using a 3D sand printer does not need a pattern – the mold is printed directly and finished in 48–60 hours. Machining a precision mold from a sand block takes 2–4 hours.

The on-site foundry at Sulzer’s service center is central to creating new parts, and it is capable of pouring 100 different alloys for castings up to 450 kg (1’000 pounds). The designers determine the exact composite of the metal alloy by the component and its application; advanced metallurgy knowledge enables Sulzer to offer new components with better durability than the originals.

The right dimensions thanks to CNC machining

Once the basic building blocks for a new component have been created, the machine shop takes over to establish the final dimensions. The Sulzer management has recently invested over USD 2 million in machine upgrades and modernization, which enables the current facilities to deliver parts to precise, high tolerances.

The machine shop is equipped with CNC vertical turning lathes for impellers and bowls, horizontal shaft lathes, milling equipment and grinders. This makes Sulzer capable of delivering complex components (Fig. 4). The shop also provides extensive quality control procedures and equipment to ensure that every part is manufactured to the highest standards.

Specialist cleaning and polishing equipment complete to the casting process.
Fig. 4 Specialist cleaning and polishing equipment complete the process.

Quality control ensures highest reliability

In addition, the service center can provide heat treatment, certified material reports, chemical analysis, and a range of material tests and non-destructive testing (NDT). This ensures the reliability of the parts and compliance to customer specifications.

As a leading integrated maintenance provider, Sulzer offers a comprehensive range of services for electrical and mechanical equipment that can minimize downtime and improve reliability. Our facility in West Virginia is fully equipped to create new parts for any repair and retrofitting projects where speed and precision are essential.

Sulzer Technical Review


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