1、Common Bending Dies

The common bending dies are shown in the figure below. To extend the life of the dies, rounded corners should be used in part design whenever possible.

For edges with a height that is too small, even with bending dies, it is not conducive to forming. Generally, the bending edge height L should be at least 3 times the thickness (including the wall thickness).

Processing of  Steps

For some sheet metal Z-shaped steps with a lower height, manufacturers often use simple dies on stamping presses or hydraulic presses for processing. For small batches, segment difference dies can also be used on bending machines, as shown in the figure below. However, the height H should not be too high, generally it should be within (0–1.0) times the thickness. If the height is between (1.0–4.0) times the thickness, consider using a die with an unloading structure according to the actual situation.

The step height of this die can be adjusted by adding shims, so the height H is arbitrarily adjustable. However, there is a disadvantage: the length L dimension is not easy to ensure, and the verticality of the vertical edge is not easy to guarantee. If the height H is large, consider bending on a bending machine.

 

Bending Machines

There are two types of bending machines: ordinary and CNC (numerical control). Due to high precision requirements and irregular bending shapes, sheet metal bending for communication equipment generally uses CNC bending machines. The basic principle is to use the bending die (upper die) and V-groove (lower die) of the bending machine to bend and shape the sheet metal parts.

Advantages: Easy clamping, accurate positioning, and fast processing speed.

Disadvantages: Low pressure, only capable of processing simple shapes, and lower efficiency.

Basic Principles of Shaping

The basic principle of shaping is shown in the figure below.

Bending Die (Upper Die)

The form of the bending die is shown in the figure below. During processing, it is mainly selected according to the shape required by the workpiece. Manufacturers usually have a variety of bending die shapes, especially those with a high degree of specialization, who customize many shapes and specifications of bending dies for various complex bends.

The lower die generally uses a V-groove with V=6t (t is the material thickness).

There are many factors that affect bending processing, including the upper die radius, material, thickness, lower die strength, and lower die mouth size. To meet product requirements and ensure the safe use of the bending machine, manufacturers have already standardized the bending die series. We need to have a general understanding of the existing bending dies during the structural design process. See the figure below, the left side is the upper die, and the right side is the lower die.

**Basic Principles of Bending Processing Order**:

  1. Bend from the inside out.
  2. Bend from small to large.
  3. Bend special shapes first, then general shapes.
  4. The previous process should not affect or interfere with subsequent processes.

The current bending forms are generally shown in the figure below.

2、Bending Radius

When bending sheet metal, there must be a bending radius at the bending point, which should not be too large or too small and should be appropriately selected. A too small bending radius can easily cause cracking at the bend, while a too large bending radius can cause the bend to rebound.

The preferred bending radius (inner radius) for various materials of different thicknesses is shown in the table below.

The data in the table above is preferred and for reference only. In fact, the fillet of the manufacturer’s bending die is usually 0.3, and a few bending dies have a fillet of 0.5.

For ordinary low-carbon steel plates, anti-rust aluminum plates, brass plates, and copper plates, an inner fillet of 0.2 is no problem, but for some high-carbon steel, hard aluminum, and super-hard aluminum, this bending fillet will cause bending fracture or outer fillet cracking.

3、Bending Springback

Springback angle Δα = b – a, where b is the actual angle of the workpiece after springback, and a is the die angle.

**Size of the Springback Angle**

The springback angle for a single 90-degree free bending is shown in the table below.

 

Factors Affecting Springback and Measures to Reduce It

 

  1. The mechanical properties of the material: The size of the springback angle is directly proportional to the yield point of the material and inversely proportional to the elastic modulus E. For sheet metal parts with high precision requirements, to reduce springback, materials should be chosen as low carbon steel as much as possible, and high carbon steel and stainless steel should not be chosen.
  2. The relative bending radius r/t: The larger the value, the smaller the degree of deformation, and the larger the springback angle Δα. This is an important concept. The fillet of sheet metal bending should be as small as possible within the allowable range of material performance, which is conducive to improving accuracy. It is especially important to avoid designing large radii, as shown in the figure below, which poses great difficulty for production and quality control.

 

4、Minimum Bending Edge Calculation for One-time Bending

The starting state of L-shaped bending is shown in the figure below.

The starting state of Z-shaped bending is shown in the figure below.

 

The minimum bending dimensions L for Z-shaped bending of sheet metal of different material thicknesses are shown in the table below.

Competition in the sheet metal processing industry is becoming increasingly fierce. If companies want to remain invincible, they must continue to improve their processing technology. In some bending applications such as precision stainless steel, aluminum alloy, aerospace parts and copper plates, users are no longer satisfied with the functionality of the product, and have higher requirements for its processability and aesthetics. Traditional bending processes are more likely to damage the surface of the work piece. The surface in contact with the mold will form an obvious indentation or scratch. Since the mark cannot be removed, the part will be scrapped. Therefore, users have an increasingly strong demand for no-mark bending.we also call it mark-free bending

The impact of press brake die parameters on bending indentation

  • The opening width of V

When coming to bend metal sheets of different thicknesses, the V opening width of lower die is also different.

Under the conditions of the same plate thickness and the same upper die, the larger the size of the V opening, according to the principle of three-force balance, the smaller the pressure between the metal plate and the shoulder of the V opening, the smaller the friction force, and the naturally smaller the indentation depth. Therefore, it is recommended to use a slightly larger V opening lower die.

  • The R-value of the rounded corner

The R value of the V-shaped shoulder radius is different, and the friction force on the plate during the bending process is different.

The larger R value of the V-opening shoulder, the smaller pressure between the plate and the V-opening shoulder, and the lighter the indentation, and vice versa.

In the figure 1,the WILA tools press Indentation on the same sheet metal but different R value(Ra<Rb),Obviously, the bending indentation of Ra is more significant than Rb.

Therefore, it is recommended to use a lower die with a slightly larger shoulder radius.

The solution for no-mark bending

1.Protective cloth or foil

From the perspective of friction, the upper and lower molds can be separated by a foil to avoid direct contact between the molds with the plate, and a non-marking pressing film foil can be used to separate the upper and lower molds. This mainly acts as a buffer between the workpiece and the shoulder of the lower mold, reduces the friction coefficient, and offsets the pressure between the mold and the plate, thereby preventing the workpiece from having indentations when it is bent.

It has the advantages of low cost and easy use. When using it, just put the no-mark pressing film on the lower mold.

Figure 2 The test results show that the use of non-marking pressing film can effectively avoid bending marks.

2.Tools with plastic inserts

From the perspective of friction pair, it is possible to consider changing the V-groove shoulder to no-metallic material which is softer than the plate, such as polyurethane, nylon, etc., while ensuring the original required extrusion effect.

high-strength nylon material combinate with an extended mold. It is usually used for bending aluminum plates with a thickness of 0.4~0.5mm in specific occasions, will have a better results.

3.Rotabend bottom tools

Rotabend bottom tools helps reduce marking.lts hardened rotor wingsreduce friction.which using rotating supports to enable high quality sheet metal forming,we called Unmarked bending of tension spring in China

Thanks to the tightest tolerances, CNC deep hardening of the contact surfaces and the rotatable V-neck, it is easy to produce parts with short flanges using rotary wing dies to maximally reduce the marks on the work piece when bending the sheet metals.

The advantage of Rotabend bottom tools:

(1) Holes and grooves are produced without deformation in the area close to the bend centerline.

(2) Indentations on the surface of the work piece are reduced when it is bent.

(3) Very small bend fillets can be obtained.

(4) The rotor and contact surfaces are hardened to ensure a long service life and precision.

(5) The rotor is easy to disassemble and assemble, making it easy to clean and maintain.

(6) The strict tolerance requirements during mold processing ensure the ultimate precision during bending operations.

(7) The compact mold size design ensures maximum bending freedom.

(8) The same mold can be used to bend plates of various thicknesses.

(9) It can be used in combination with certain customized lower molds to perform 90° bends

4.Ball mark free bending mold

Based on the principle of reducing the friction coefficient of the friction pair between the sheet and the V groove, the sliding friction pair of the sheet and the shoulder of the V groove can be transformed into a rolling friction pair, thereby greatly reducing the friction force to which the sheet is subjected.This can effectively avoid bending indentation.

Bending is a process of folding and bending flat panels, which follows the cutting process in the entire manufacturing chain. The workpiece is placed on a die with a V-shaped opening. A wedge-shaped tool (upper tool) presses the workpiece into the V-shaped opening and bends the sheet to the required angle in this manner.

Most bending parts are made using processes and methods such as free bending, die bending, and edge folding and pressing. The operation follows the same principle: the punch presses the workpiece into the lower die of the die. Therefore, the bending machine that performs the above processes and methods is called a die bending machine.

1. **Free Bending**

The punch presses the workpiece into the die without pressing it against the die wall. As the punch descends, the edge of the workpiece bends upwards and forms an angle. The deeper the punch presses the workpiece into the die, the smaller the angle becomes. At this time, there is a gap between the punch and the die.

Free bending is also known as a path-dependent process. Each angle requires a specific path. The machine tool control system calculates the path and the corresponding punch force simultaneously. The path and punch force depend on the mold, material, and product characteristics (angle, length).

2. **Die Bending**

The punch fully presses the workpiece into the die, leaving no gap between the die, workpiece, and punch. This process is called die closing.

The punch and die must fit together precisely. Therefore, each angle and shape requires the corresponding mold components. Once the workpiece is fully pressed in, the punch cannot continue to move downward. The machine tool control system continues to increase the punch force until it reaches the specified value. The pressure applied to the workpiece increases, thereby presenting the outline of the punch and die. The angle gradually solidifies under high pressure, almost completely eliminating the rebound problem.

3. **Flanging Bending**

The bending arm built into the machine is made of C-shaped profiles, with lower and upper bending molds installed on it. During bending, the C-shaped profile moves up and down or performs a small range of elliptical motion, that is, flipping. The arm bending machine operates semi-automatically, known for its speed and flexibility, even small batch production is completed without inferiority. In addition, through flanging bending technology, it is also possible to use the same mold to achieve efficient bending of various radius sizes on a single part.

4. **Edge Folding and Pressing**

The edge of the sheet is usually completely bent (such as the edge of a box), and then the edges are parallel to each other. As a result, the finished piece is more stable or forms an edge protection. Subsequently, the edges usually need to be hung with other parts. Edge folding and pressing are completed in two steps: first, the operator pre-bends a 30° angle, and then the workpiece is reinserted and pressed to close the angle. If there is a gap between the edges, it is called folding. In pressing, the bent edges are completely squeezed against each other. Folding is path-dependent, while pressing is force-dependent.

**Industry Applications**

Whether it’s a microwave oven, washing machine, or stove – most household appliances are made up of structures using very thin sheets and a large amount of forming processing, which must withstand many years of use. Therefore, white goods manufacturers need production partners who provide stamping and bending machines to flexibly process sheet metal parts. Since household appliances always have many visible parts, processing without surface damage or indentation is essential. The commonly used galvanized sheet is beneficial to stamping because the zinc layer is pulled to the top of the edge during the stamping process, preventing future corrosion. The washing machine drum in particular requires high-quality welding to prevent damage to clothing.

Laser welding is convincing with its high-quality results.

Switch cabinet housings, plug-ins, and the casings of electrical equipment itself – all of these are made of sheet metal structures. The laser cutting machines, stamping presses, and bending machines can process thin plate parts with many edges, often very complex. The flexible processing methods of Tongkuan machine tools can be used for pressing in components, forming processing, and profile processing. Laser welding technology also saves time and cost for customers in the electronics industry because it achieves high-quality seams, almost without any follow-up work.

 

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