Tips for Making Sheet-Metal Parts

Follow these straightforward guidelines to create durable parts that exactly meet your design’s requirements.

 

In sheet-metal fabrication, parts are formed from metal sheets by punching, cutting, stamping, and bending. 3D CAD files are created using a host of different CAD packages and then converted into machine code, which controls machines that precisely cut and form the sheets into the final parts. Sheet-metal parts are known for their durability, which makes them great for a wide variety of applications. Parts for low-volume prototypes and high-volume production runs are most cost-effective due to large initial setup and material costs.

 

Below are some tips and guidelines for designing sheet-metal parts. If you follow the design advice and maintain the tolerances expressed in this article, you are more likely to end up with parts that meet the needs of your designs.

 

Wall Thickness

Parts should maintain a uniform wall thickness throughout their entirety, but this should be easy because parts are formed from a single sheet of metal.

 

Bends

Sheet-metal brakes bend sheets into a part’s desired geometry. Bends in the same plane should be designed in the same direction to avoid having to reorient the part during manufacturing, which will save money and time. Another trick is to keep the bend radius consistent to keep parts more cost-effective. Thick parts tend to become inaccurate, so they should be avoided if possible.

 

Rule of thumb: To prevent parts from fracturing or distorting, make sure to keep the inside bend radius at least equal to the sheet’s thickness.

 

Curls

Holes should be placed away from the curl at least a distance equal to the radius of the curl plus the material’s thickness. Bends should be at least six times the material’s thickness plus the radius of the curl.

 

Rule of thumb: Outside radius of curls must be at least twice the sheet’s thickness.

 

Countersinks

Countersinks must be separated from each other by a distance of at least 8 times the material thickness, from an edge by at least 4 times the material’s thickness, and from a bend by at least 3 times the material’s thickness.

 

Rule of thumb: The maximum depth for a countersink is 3.5 times the material’s thickness.

 

Hems

Hems are folds to the edge of a part that create rounded, safe edges. Hems may be open, flat, or tear-dropped, and tolerances depend on the hem’s radius, material thickness, and features near the hem. It should be noted that flat hems should be avoided because they risk fracturing the material at the bend.

 

Rule of thumb: For open hems, the inside diameter should at least equal to the material thickness (larger diameters tend to lose their circular shapes); and the return length should be at least 4 times the material’s thickness. Tear-dropped hems must maintain an inside diameter of at least equal to the material’s thickness, an opening of at least ¼ the material’s thickness, and the return length should also be at least 4 times the material’s thickness.

 

Holes and Slots

Holes and slots may become deformed if positioned near a bend. The minimum distance that holes should be placed from a bend is a function of the material thickness, bend radius, and the hole’s diameter. Holes should be at least 2.5 times the material thickness plus the bend radius away from any bends. Slots should be placed 4 times the material’s thickness plus the bend radius away from the bend.

 

Be sure to put holes and slots at least twice the material’s thickness from an edge to avoid a “bulging” effect. And holes should be separated from each other by at least 6 times the material’s thickness.

 

Rule of thumb: Keep hole and slot diameters at least as large as the material’s thickness. Higher-strength materials require larger diameters.

 

Notches and Tabs

Notches must be at least one-eighth of an inch (3.175 mm) away from each other. For bends, notches must be at least 3 times the material’s thickness plus the bend radius. Tabs must be at least 0.04 inches (1 mm) from one another or the material’s thickness, whichever is greater.

 

Rule of thumb: Notches must be at least 0.04 inches (1 mm) thick or as thick as the material, whichever is greater. A tab should not be any longer than 5 times its width. Tabs must be at least 0.126 inches (3.2 mm) thick, or two times the material’s thickness, whichever is greater. Tab length should be no larger than 5 times its width.

 

Corner Fillets and Relief Cuts

Sheet-metal parts may have sharp corners, but designing a fillet of ½ the material’s thickness will make parts more cost-effective.

 

Relief cuts help parts avoid “overhangs” and tearing at bends. Overhangs become more prominent for thicker parts with smaller bend radii, and may even be as large as one half of the material’s thickness. Bends made too close to an edge may cause tearing.

 

Rule of thumb: Relief cuts for bends must be at least one sheet’s thickness in width, and be longer than the bend radius.

 

If you have any interest in sheet metal process, I recommend you to visit the website of Tailift Co., Ltd. – they are the professional manufacturer for kinds of high-quality sheet metal machines and punch presses. To get more information of sheet metal machine series, please do not hesitate to check out their website and feel free to contact with Tailift.

 

Article Source: https://www.machinedesign.com/mechanical/tips-making-sheet-metal-parts

What Is a CNC Punch Press?

Punch Presses are generally used in the Sheet metal industry; however they may be employed in other types of industry where the process of punching out shapes of different materials is required.

 

The punch press is used for cutting and forming material into various shapes and sizes and is a type of machine press. These presses may be very large CNC operated machines which hold large complex die sets, or they may be small manually operated machines which only hold one simple die.

 

Die sets usually consist of ‘female’ dies and ‘male’ punches, and when pressed together with the desired material placed between them, may form a hole or even deform the material (workpiece) into the desired shape of form. The punch is fixed to the end of a ram which moves up and down during the punching process in a vertically linear motion, and the dies and punches are removable to enable different shapes and holes to be formed into the workpiece.

 

There are mainly two types of common machines and these are generally large frame metal pieces of equipment. These are C type frames and portal type frames. On the C type frame there is a hydraulic ram set at the top part which allows the punching process to be carried out. On the portal type frame, the ram is cantered within the frame to prevent frame distortion and deflection.

 

Punch press machines all have a bed or table with rollers or brushes incorporated into them to enable the workpiece or the sheet of metal to travel with low friction. Brushes are mainly employed when minimal scratching or similar marks are not desirable, and the brushes provide a suitable finish to the material. Brushed aluminum or highly polished steels are an example of this process.

 

Punch presses are machines used for processing sheets of material, usually sheet metal, and they perform the operation of forming or stamping the sheet material at specified areas. Many of these machines will have a system by which they are controlled, and CNC operations allow for automatic modes determined by a pre-built program.

 

A punch press is characterized by some basic parameters and these will include:

 

  • Type of tool shop

 

  • Tool shop capacity

 

  • Size of working area

 

  • The working force (20 tons for example)

 

There are different types of CNC punch presses and they include the hydraulic punch press, the mechanical punch press and the flywheel driven press. Punch presses are often referred to by their tonnage, and the sizing tooling needed for a specific task is a straight forward process as the tonnage required to form and cut most materials is well known.

 

Since 1989, Tailift developed the first CNC punch press machine. We have built the reputation as one of Asia’s top manufacturers and suppliers of sheet metal working machines. Our CNC punch presses are outstanding machines for punching and forming. If you are interested in learning more information about punch press, welcome to visit the website of Tailift or contact with us directly!

 

 

Article Source: http://EzineArticles.com/3813785