For OEMs in industries like automotive, defense, and industrial equipment, balancing performance with cost and scalability is a constant challenge. While machined parts offer exceptional precision, they can be time-consuming and costly to produce, especially at high volumes. That’s where precision stamping offers a compelling alternative. By converting the right parts from machining to stamping, manufacturers can reduce costs, increase throughput, and maintain tight tolerances without compromising part integrity.
For high-volume OEMs, speed, cost, and scalability are critical, and machined parts, while precise, can be expensive and time-consuming to produce. That’s why many manufacturers explore converting suitable components to precision stamping.
Stamping offers significantly faster cycle times and lower per-part costs at scale. It also produces less material waste by forming near-net shapes from coil-fed stock. Unlike machining, stamping can integrate multiple features, such as bends, holes, or tabs, in a single operation, reducing secondary processes and improving throughput.
With precision tooling and automation, stamping delivers consistent results across long production runs. But a successful switch depends on more than just volume. Evaluating part geometry, function, tolerances, and material is essential to determine whether stamping can meet the same performance standards as machining, often with added efficiency.
Not every machined part is a candidate for stamping, but many are, particularly if the part is produced in high volumes and has a geometry that suits cold forming. Flat or shallow parts, especially those with uniform wall thicknesses and minimal undercuts, tend to be ideal. Metals like aluminum, low-carbon and high-strength steel, stainless steel, and brass also lend themselves well to stamping.
Parts like brackets, covers, shielding components, and housings — especially those used in electrical systems, enclosures, or structural subassemblies — are common examples of components that can be stamped efficiently without compromising on precision. If these parts were originally machined but meet the criteria for stamping, converting them can reduce lead times and free up machining capacity for components that truly require it.
DFM is essential when converting parts from one manufacturing process to another. Features that work in a machined environment might need modification for stamping. For example, sharp internal corners may need to be adjusted to radii that allow materials to flow better. Undercuts or inconsistent wall thicknesses might also require simplification. Partnering with a stamping manufacturer early in the redesign process helps streamline development and ensures the new design is optimized for production.
While stamping does require an upfront investment in tooling — particularly in progressive or compound dies — the return on that investment grows quickly with volume. Once the tooling is built and optimized, the per-part cost drops significantly compared to machining.
Furui Hardware’s in-house tool and die team manages this entire process, from design through build and ongoing maintenance, giving customers tight control over quality, timing, and cost.
And finally, stamping requires careful material selection. While many metals are stampable, their behavior under pressure differs from how they respond to machining. Certain materials might exhibit springback or cracking if not managed properly. Furui Hardware brings deep material expertise to the table, helping OEMs select metals that meet both performance and formability requirements.
When a part is well-suited to the process, the advantages of stamping over machining go beyond cost and speed. Precision stamping delivers tight tolerances with high repeatability — not just on the first hundred parts, but across millions. It’s also highly scalable, thanks to coil-fed automation and multi-out tooling setups.
Stamped parts often require fewer secondary operations because features can be built into the die. With that, you can eliminate the need for additional drilling, tapping, or shaping after forming. Progressive die setups also maximize material usage, reducing waste and cutting raw material costs, which is especially important for pricier metals like stainless steel or copper alloys.
At Furui Hardware, we’ve helped customers across industries make the shift from machining to stamping, delivering consistent, high-quality results in critical applications. With certifications like ISO 9001, plus a full range of in-house press and tooling capabilities, we’re built to support precision stamping programs from concept through full production.
Converting machined parts to stamped ones can be a strategic move toward greater efficiency, lower costs, and long-term scalability. But realizing those benefits requires a partner who understands both the technical demands and the production realities of precision stamping.
At Furui Hardware, we provide more than just stamping services. Our in-house tooling and engineering teams collaborate with customers from the start, offering Design for Manufacturability (DFM), prototyping, and material selection guidance to ensure a seamless transition. With decades of experience supporting the automotive industry, electronics industry, CNC equipment industry, and construction industry, we understand how to meet strict tolerances, manage complex geometries, and deliver consistent quality at scale.
When it comes to precision metal stamping and CNC machining for OEM industries, Furui Hardware is your trusted partner. From prototyping to mass production, we provide scalable, cost-efficient, and high-quality solutions tailored to your needs.
Looking to optimize your OEM manufacturing with precision stamping and machining? Contact Furui Hardware today and discover how our expertise can power your next project.
Ready to explore converting machined parts to precision stampings? Contact Furui Hardware today to find out what’s possible for your next project.
