5 Must-Have Features in a Metal Custom

19 Mar.,2024

 

Are the sheet metal parts you’re designing actually able to be made on the shop floor?

When engineers submit a drawing or model to a precision sheet metal fabrication shop, there’s often a disconnect between the design itself and the manufacturability of the part. At Ameritex, we’re always upfront about any changes we need to make to the initial design—and this communication is key to developing lasting partnerships with our customers.

During these conversations, we’ve come to realize that many of the engineers we work with are eager to learn more about designing for manufacturability (DFM) and sheet metal fabrication. They want to know that they can send their model to a shop and feel confident that it’ll be made according to their exact specifications.

That’s why we’ve made it our ongoing mission to help set engineers up for success right from the start. The good news is that there are some easily avoidable mistakes that can easily improve your sheet metal part designs.

When you avoid these common mistakes, you’ll know that what you’re designing ultimately translates to the shop floor.

Top 5 Problems with Sheet Metal Part Designs

Problem 1: Flanges are too short for the particular material thickness.

In most cases, we use a press brake with a v-shaped die to bend sheet metal parts. During the bending process, it’s important to have enough material to reach all the way across the die, otherwise, there’s nothing to catch it and create the bend.

The v-size is typically set to 5-8 times the thickness of the material, and the die ultimately determines how short the flanges can be. As a general rule of thumb, we recommend multiplying your material thickness by 8 and designing your flanges to be only about half of that measurement so that the material will reach the other side.

Too shortPlenty of length















Problem 2: Features are too close to bends.

Similar to the problem with flanges being too short, the v-die determines everything when it comes to designing features into a part. If the features are too close to the area undergoing the bending forces, they’ll become stretched or deformed once the material is bent.

Round or square holes designed too close to a bend will be stretched into ovals or rectangles, respectively. Extrusions (like louvers for electrical enclosures designed too close to a bend will be crushed by the tool. Pressed-in hardware can also become damaged during the bending process.

To prevent this issue from occurring, any features you include should be designed outside the die by a considerable amount.

A good rule of thumb is 1.5 times the thickness of the material plus the inside radius of the bend. This usually equates to 3 or 4 times the thickness of the material when using 5 to 8 times material thickness for die size but will increase as bend radius and die sizes increase.

Problem 3: The parts are too deep to be bent on standard tooling.

When designing parts that are bent in multiple places, like a box or an enclosure, engineers frequently provide drawings with all sides bent. By the time we get to the third flange, the sides are too long for a standard press brake to handle. If our precision sheet metal fabrication shop receives this type of drawing or model, we have no choice but to break it apart so that we can fabricate it.

We encourage engineers to design each side no more than 8” tall (6” for most efficient bending) and, if the goal is to have us build to the exact design, go ahead and separate the smallest sides to begin with. If we’re going to have to weld a side on, we always want it to be the smallest side requiring the least amount of labor to save our customers on cost and lead time.

Problem 4: Features collide when flat.

Many of the drawings and models we receive include features that collide when their part is unfolded (i.e., translated to a flat sheet of metal). We typically encounter this issue with parts that have complex contours or when an engineer is trying to close a gap on a part where aesthetics matter, like for an architectural application.

Fortunately, there are easy ways around this problem. SOLIDWORKS will warn you when it’s happening, so be sure to pay attention to those alerts and adjust your design accordingly. If you need a solution and want to guarantee that we can make it happen on the shop floor, we recommend welding or bolting on another piece of material.

Problem 5: Awkward flat patterns and wasted material.

When it comes to low-volume sheet metal fabrication, custom metal shops usually work with standard size 4’-5’ wide sheets. If you’re designing a part with an awkward size or shape that does not fit well on standard sheets, or a part with large cutout features—you may end up paying extra money for wasted material.

Our typical solution for this problem is to split the design into two pieces and weld those pieces together after cutting to make better use of the available material. So if you want your part made exactly as you design it, we recommend evaluating the flat pattern and, if necessary, designing the piece to be split apart and welded or fastened back together.


Hopefully, this advice will help you feel more confident designing sheet metal parts for manufacturability. Next time you need sheet metal fabrication services, give us a shot! We’ll always jump through hoops to get you the parts you need.

There is probably no industry people operate in that does not involve some sort of machinery or pieces of equipment made of metal. Metals are vital and they come in different shapes and forms – as important raw materials, incredibly useful infrastructures, decorative interior elements, and even as complex medical instruments like the scalpel.

Without the sophisticated metalworking processes we’ve developed, none of these applications would be possible today. Let’s look at what makes metal processing a fundamental part of the industrialized world. 

We’ll discuss the 4 main techniques that are part of shaping metals into the building elements of industrial machinery, the exquisite decorative elements, and geometrically accurate shapes that you can find everywhere around you. In doing so, you’ll be a step closer to gaining valuable insight into the metalworking processes that can be useful next time you’re contracting a metal piece for your home.

What Is Metalworking? 

Metalworking consists of processes and techniques that shape or reshape metal parts into separate parts, constructions, objects, and large-scale structures. Metalworking encompasses a wide range of works across multiple industrial sectors. 

For the marine industry, metalworks include one type of metal processing, decorative ironworks another, and precision metal manufacturing completely different. 

The wide umbrella of categories and techniques that the process includes prompts a few questions. What categories of metalworking are there? And which are some of the main metalworking techniques? 

Let’s start with answering the first question. 

The 5 Fundamental Metalworking Processes

Fabricating metal pieces usually involves incorporating either one or a combination of forming, casting, cutting, joining, and machining. These are the most general categories of the metalworking process. 

Here’s what each of the processes involves. 

1. Forming

As the name suggests, forming aims to shape metal parts and objects into desired structures, through mechanical deformation. 

Forming is performed without adding or removing material, and the weight of the metal piece remains unchanged. Forming is possible thanks to the metals’ physical properties, specifically malleability and plasticity, which allow us to permanently deform the physical shape of the materials. 

Forming can further be divided into several subprocesses such as:

2. Bending 

During this process, the metal sheet is bent by placing it over a die block that punch-presses the material and shapes it to the die. Bending is used in applications that require accuracy and smooth surfaces. 

3. Forging

The processes encompass elements from bending and rolling, although forging is the more artistic side of a metal bending process.

It can be done both manually (heating the material and hammering it into the desired shape) or semi-manually, through the use of high-pressure machinery that compresses the metal, allowing craftsmen to bend and shape it.

Forging itself can be further divided into several categories like cold forging, warm forging, and hot forging, where the temperature of the element during work varies. 

Forging is one of the oldest and most influential metalworking processes in our industrial history. It has been at the forefront of our technological development ever since we first discovered we could work metals. 

Today, forging finds various applications in the iron and steel industries, and it’s an important process in the making of decorative and functional interior and exterior wrought iron pieces. 

4. Drawing 

In the process of drawing, the metal sheet is fixed into a place over a cavity-shaped die and punched to form hollow shaped components. The punch presses down and draws it into the cavity. The metal sheet ends up deformed to the external shape of the die.

5. Roll Forming

During roll forming, the metal is passed through consecutive sets of rollers while pairs of rollers continuously form and bend the sheets into the required, cross-sectional shape. 

It’s a gradual process that takes time to form the metal into the exact shape. 

Roll forming is used to manufacture elements with long lengths or for large production runs.

6. Casting 

The casting process involves the creation of a mold (made of stone, plaster, or sand) with a certain shape in which molten metal is then poured. As the metal cools down and turns solid it takes the shape of the mold it has been poured into.

Metal casting, much like forging, is an ancient metalworking process we’ve been applying since 4000 BCE. Today it’s a vital process that serves heavy industries like the automotive and marine but is also used for making tools, jewelry, and sculptures.

7. Cutting

Metal cutting is also a pretty straightforward term used to describe the process where larger pieces of metal are separated by a cutting tool into smaller pieces. 

Depending on the cutting tool, metal cutting can be subdivided into saw cutting, shearing, waterjet cutting, and laser cutting

Saw cutting refers to the mostly manual technique of using a type of saw to cut through the metal.

Shearing relies on the force of a punch to cut at a specific point. It usually uses two tools (upper and lower) placed between the metal sheet which are then either punched or dyed into the sheet and cut.

Waterjet cutting uses the energy of high-speed, high-pressured, and high-density water that is projected into a small nozzle. The water is so pressurized that it reaches a speed approximately three times the speed of sound, which ends up forming a water jet with destructive force.

It’s a process used for metals that are sensitive to extreme temperatures and temperature changes.

Laser cutting uses lasers to cut metals. It works by directing a high-power laser, through optics and CNC (computer numerical control) to the material. 

8. Machining 

Metal machining involves techniques that shape raw metal pieces into finished products. Machining utilizes cutting processes (like CNC machines for laser cutting) but also includes processes like turning, drilling, milling, and extrusion. 

During milling, an operator bores perforations into the metal. 

Drilling on the other hand cuts holes into the sheet or piece with the use of circular bits.

Turning describes the operation, where a metal piece is placed into a spinning platform, and a technician makes radial cuts with different tools as the metal spins.

And finally, extrusion is the process in which a ram forces billets (solid metal bars with square or circle cross-sections) through a die, so cylindrical parts, such as pipes or electrical wires can be formed. 

9. Joining 

Metal joining is an important part of the metalworking processes because many of the final metal products are too large or complicated to be fabricated as a single piece. This results in the need for several metal pieces to be joined together to form the required metal component or machine.

Joining can be performed by two prominent processes- mechanical and liquid-solid-state. Mechanical joining includes additional elements like screws, nuts, and bolts, and liquid-solid-state joining concerns processes like adhesive bonding, brazing, soldering, and welding. 

The Bottom Line

Metal fabrication might not be such a prevalent part of the common knowledge but we believe it’s an important topic that more people need to have a basic understanding of. 

Understanding how metal pieces are created will give you valuable insight into a trade that has been the backbone of the industrial revolution and modern society. 

It will also help you gain practical knowledge that will help navigate better your work with metalworks contractors, like Cacciola Iron Works. 

Anthony Cacciola’s team of ironworks craftsmen has been helping homeowners in the New York and New Jersey areas make the best choice for their custom-made wrought iron gates and fences, doors, and railings. 

Are you interested in how we apply our metalworking knowledge to practice? Get in touch today.

5 Must-Have Features in a Metal Custom

The 5 Fundamental Metalworking Processes

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