Custom Sheet Metal Fabrication Services

The finish depends on the part’s function, operating environment, and appearance requirements. For outdoor or high-wear parts, powder coating provides the most durable protection with coating thickness from 60 to 120 microns. Aluminum parts that need corrosion resistance and a clean appearance are best suited to anodizing. Stainless steel parts for medical or food-grade applications should be passivated or electropolished.

For cosmetic parts that need a uniform satin texture, mechanical brushing is the standard choice. Chrome or nickel plating adds both corrosion protection and conductivity for electrical components.

If you’re unsure which finish to specify, our engineering team can recommend the right option during the DFM review based on your part’s end-use conditions.

Sheet metal technique refers to the set of manufacturing processes used to shape flat metal sheets into functional parts and assemblies. The most common techniques include cutting, bending, stamping, and joining.

Cutting methods range from laser cutting and waterjet cutting to plasma cutting and shearing. Laser cutting delivers the tightest tolerances, often within ±0.1 mm, and handles complex geometries without additional tooling. Waterjet cutting suits heat-sensitive materials because it generates no thermal distortion.

Bending uses press brakes to form angles and flanges in sheet metal. The bend radius, material thickness, and grain direction all affect the final result. Bend radii should be confirmed with your fabricator before design lock to avoid springback issues.

Stamping and forming are high-volume techniques. A die presses the sheet into shape in a single stroke or a series of progressive stages. Stamping is cost-effective above 1,000 units but requires upfront tooling investment.

Joining methods include welding (TIG, MIG, spot), riveting, and hardware insertion. The choice depends on the material, load requirements, and whether the assembly needs to be disassembled later.

Each technique serves a different purpose. The right combination depends on part geometry, material type, production volume, and tolerance requirements.

Yes. Sheet metal accepts a wide range of surface finishes, including painting, powder coating, anodizing, plating, and brushing.

Painting and powder coating are the most common options for color and corrosion protection. Powder coating is more durable than wet paint and doesn’t use solvents, making it the preferred choice for parts exposed to outdoor conditions or heavy handling. Standard powder coat thickness ranges from 60 to 80 microns.

Anodizing applies specifically to aluminum. It creates a hard oxide layer that resists scratching and corrosion. Type II anodizing is standard for cosmetic parts, while Type III (hard anodize) adds wear resistance for functional components.

For stainless steel, passivation removes surface contaminants and restores the chromium oxide layer that prevents rust. Electropolishing takes this a step further by smoothing the surface to a mirror-like finish, common in medical and food-grade applications.

Surface preparation matters as much as the finish itself. Deburring, cleaning, and priming ensure proper adhesion and a consistent result. Your fabricator should confirm the preparation steps before production begins.

Sheet metal fabrication works with a broad range of metals and alloys. The most widely used materials are steel, stainless steel, aluminum, copper, and brass.

Mild steel (such as SPCC or CR steel) is the most cost-effective option for structural parts, enclosures, and brackets. It’s easy to cut, bend, and weld, though it requires a protective finish to prevent corrosion.

Stainless Steel 304 and 316L are standard choices for corrosion-resistant applications. 316L performs better in chloride-rich or marine environments. Both grades are harder to form than mild steel, so bend radii and tooling wear should be factored into the design.

Aluminum 5052 and 6061 are popular for lightweight parts. 5052 offers better formability and corrosion resistance, making it the correct specification for enclosures and panels. 6061 is stronger and machines well, but it’s more prone to cracking during tight bends.

Copper and brass are selected for their electrical conductivity and thermal properties. They’re common in busbars, heat sinks, and RF shielding applications.

Material selection should match the part’s mechanical requirements, operating environment, and finishing needs. Your fabricator’s DFM review can identify the best material for your application before production starts.

Standard sheet metal thicknesses range from 0.5 mm to 6.0 mm for most fabrication projects. Material thinner than 0.5 mm is classified as foil, and material thicker than 6.0 mm is considered plate.

For steel and stainless steel, the most common gauges fall between 0.8 mm and 3.0 mm. Thinner gauges (0.5–1.0 mm) suit lightweight enclosures and cosmetic panels. Thicker gauges (2.0–4.0 mm) are used for structural brackets, chassis, and load-bearing components.

Aluminum sheet is typically specified between 0.5 mm and 5.0 mm. Thinner aluminum bends easily but dents more readily. Thicker aluminum provides rigidity but increases material cost and requires larger bend radii.

Thickness affects more than strength. It directly impacts bend radius limits, weld parameters, cutting speed, and overall part weight. A 1.5 mm stainless steel panel, for example, requires a minimum inside bend radius of roughly 1.5 mm to avoid cracking.

When selecting thickness, balance structural performance against weight and cost. Your fabricator can recommend the optimal gauge based on the part’s function and loading conditions.

Beyond the standard metals, sheet metal fabrication also works with specialty alloys and less common materials for specific performance requirements.

Titanium sheet is used in aerospace and medical applications where high strength-to-weight ratio and biocompatibility are required. Titanium Grade 2 is the most common sheet form. It’s corrosion-resistant and weldable, but significantly harder to form and cut than aluminum or steel.

Galvanized steel has a zinc coating that provides built-in corrosion protection without additional finishing. It’s widely used in HVAC ductwork, electrical enclosures, and outdoor equipment. The zinc layer does affect weldability, so joint design should account for this.

Spring steel (such as AISI 1095 or 301 stainless) is selected for parts that need to flex repeatedly without permanent deformation. Clips, retaining bands, and contact springs are typical applications.

Nickel alloys like Inconel 625 and Hastelloy handle extreme temperatures and aggressive chemical environments. These materials are common in energy, chemical processing, and marine industries. They’re expensive and difficult to machine, so they’re specified only when standard materials can’t meet the operating conditions.

Choosing a specialty material increases cost and lead time. Confirm availability and formability with your fabricator during the DFM review to avoid delays.

Accuracy depends on the cutting method, bending equipment, and material properties. Modern CNC-controlled equipment delivers repeatable precision across production runs.

For cutting, laser cutting achieves tolerances of ±0.1 mm on most materials. Fiber lasers handle thin sheets with minimal heat distortion, while CO2 lasers suit thicker gauges. Waterjet cutting holds ±0.13 mm and avoids thermal effects entirely. Plasma cutting is faster for thick steel but less precise, typically ±0.5 mm.

For bending, CNC press brakes hold angular tolerances within ±0.5° and positional tolerances within ±0.1 mm on flange lengths. Accuracy depends on material thickness, grain direction, and the number of bends in sequence. Each bend introduces a small cumulative error, so parts with multiple bends should have tolerances reviewed during DFM.

Punching and stamping operations typically achieve ±0.1 mm on hole positions and diameters. Tool wear gradually reduces accuracy over long runs, so inspection intervals matter for high-volume production.

To get the best accuracy from your fabricator, provide clear tolerances on critical dimensions and flag which features are functional versus cosmetic. Over-tolerancing every dimension increases cost without improving part performance.

Sheet metal fabrication covers a range of processes that convert flat sheets into finished parts. Here are the primary processes available through most full-service fabricators.

1. Лазерная резка: Uses a focused laser beam to cut sheet metal with high precision. Suitable for complex profiles, fine features, and tight tolerances down to ±0.1 mm.

2. CNC Punching: A turret punch press creates holes, slots, and cutouts using interchangeable tooling. It’s efficient for parts with many identical features and supports production volumes from prototype to high-volume runs.

3. Bending and Forming: CNC press brakes bend sheet metal into angles, channels, and enclosure shapes. Multi-axis back gauges ensure repeatable flange lengths across batches.

4. Сварка: TIG, MIG, and spot welding join sheet metal parts into assemblies. TIG welding produces the cleanest welds for visible surfaces. Spot welding is faster and suits high-volume structural joints.

5. Stamping: Progressive or transfer dies stamp sheet metal into complex shapes at high speed. Stamping is cost-effective for volumes above 1,000 units, with per-part costs dropping significantly at scale.

6. Hardware Insertion: PEM studs, standoffs, and clinch nuts are pressed into sheet metal to provide threaded fastening points. This eliminates the need for welded nuts and simplifies assembly.

7. Отделка: Post-fabrication processes including deburring, powder coating, anodizing, plating, and passivation. These improve corrosion resistance, appearance, and surface hardness depending on the application.

A full-service fabricator combines these processes under one roof, reducing lead times and eliminating the coordination overhead of managing multiple suppliers.