Copper Sheet Bending Radius

The bend radius you select may not be available if the geometry of the part will not allow us to bend with the specific tooling required to achieve that radius.

Copper sheet bending radius.

Bending angles greater than 90 degrees. To use the tables below. Since commercial sheet metal bending can be done with less concern for stresses caused during forming operation the radius can be near zero for thin sheet metal. Types of copper and properties.

Like previous scenarios let s start by calculating leg length 1. In this case the minimum radius equals the respective sheet thickness. Bending is one of the most common sheet metal fabrication operations. It is possible to choose other bends if you require but additional lead time and tooling charges may apply.

The minimum bend radius data shown in these charts is measured to the inside of the bend. 060 soft h00 cold rolled h01 cold rolled high yield h02 half hard h03 three quarter hard and h04 hard. A is the bending angle in the above equation so. To calculate the neutral axis distance from the inner face t we can subtract inside bend radius from r.

For steel the factor is 1. The force must exceed the material s yield strength to achieve a plastic deformation. The copper most commonly used for sheet and strip applications complies with astm b370. And by having t and the sheet thickness t we can calculate the k factor as follow.

The bend radii listed are standard minimum if manufacturing for aircraft and aerospace applications. Most frequently expensive sheet metal bending tools called brakes are used to bend sheet metal but you can also complete this task without one. If copper has to be bent a factor of 1 5 must be used. A soft metal can be especial ly troublesome when bending tubing smaller than 3 4 inch in diameter a tight radius bend for copper is any bend with a radius equal to or less than approximately 2 5 times the tube s od that s 2 5d in tube fabricating jargon.

This is done through the application of force on a workpiece. The d of bend is the result of dividing the bend s centerline radius. Also known as press braking flanging die bending folding and edging this method is used to deform a material to an angular shape. As the extensibility ductility of harder steels is lower than that of softer steels the minimum bending radius of materials with high strength is also larger than for less strong steel.

If your bend radius needs to be adjusted a member of engineering design services team will contact you before your design is manufactured. We go beyond the general rules of sheet metal bending as our customers want tight bend radii for sheet metal parts.