V Die for Press Brake

Precision V Die for Press Brake and High-Performance V Tooling

In the sheet metal fabrication industry, the accuracy of every bend depends on the quality of your bottom tools. A high-performance v die for press brake is essential for achieving precise angles and minimizing material marking. Whether you are using a single-V, double-V, or multi-V configuration, selecting the right press brake v die and v tooling is critical for maintaining consistency across high-volume production runs.

Engineering Excellence in Press Brake V Die Design

The geometry of a v die for press brake determines the minimum flange length and the internal radius of the bend. Our press brake v die range is manufactured from premium 42CrMo alloy steel, ensuring maximum resistance to high tonnage pressure. Each v tooling component undergoes deep induction hardening to maintain its structural integrity, preventing the "v-opening" wear that leads to angular inaccuracies over time.

Versatility with Custom V Tooling Solutions

Not all bending projects are standard. As a specialized manufacturer, we offer custom v die for press brake options tailored to your specific material thickness and machine specifications. Our v tooling is CNC-ground to extremely tight tolerances, allowing for seamless integration with European, American, or New Era style clamping systems. Choosing the correct press brake v die width ensures a smooth bending process and reduces the risk of cracked workpieces.

Don't let inferior tools limit your shop's potential. Our v die for press brake solutions provide the durability and precision you need to tackle complex bending tasks. From standard replacement parts to bespoke v tooling designs, we are your trusted partner for high-performance press brake v die technology.

Core Components & Basic Working Principle of Press Brake Dies

Upper Die

: Installed on the movable slider of the bending machine, it is the active pressure-applying component. Its shape (standard straight edge, sharp corner, gooseneck, arc, etc.) determines the outer contour of the bent part of the workpiece;

Lower Die

: Fixed on the workbench of the bending machine, it is the fixed support component, mainly using a V-shaped groove (V-groove) as its structure. The width of the V-groove directly affects the bending force, fillet size, and forming effect of the sheet metal;

Working Principle

: The metal sheet is placed on the lower die, and the slider drives the upper die to press down vertically. The sheet is forced to conform to the contours of the upper and lower dies and undergoes irreversible plastic deformation. After reaching the preset stroke and pressure, the bending and forming are completed. After forming, the upper die returns to its original position, and the workpiece can be removed.

Characteristics of Press Brake Dies

High Rigidity and Wear Resistance of Molds

: The main material is alloy structural steel (such as 42CrMo), processed through heat treatment processes such as tempering and quenching, ensuring sufficient hardness (generally HRC45-HRC50), load-bearing capacity, and wear resistance to withstand the enormous extrusion force and friction during the bending process;

Mold Customization

: According to the different bending requirements of the workpiece (angle, shape, size, material thickness), the punch can be customized into special shapes such as arc, gooseneck, and irregular shapes, and the die can be processed into V-grooves of different widths (such as 8mm, 16mm, 24mm) or special groove types;

High Matching Degree between Mold, Equipment, and Workpiece

: The specifications of the mold (height, shank type, installation size) must be fully compatible with the clamping system, slider stroke, and rated tonnage of the bending machine; the forming dimensions must be consistent with the workpiece drawing requirements to ensure bending accuracy and pass rate;

Standardization and Serialization

: Conventional bending machine molds have general standard specifications (matching common bending machine brands such as Amada, Trumpf, and Wille), and can be purchased and used directly; special molds can be customized according to the actual processing needs of the enterprise.

Common Classifications of Press Brake Dies

Classification by Forming Shape

Standard Straight Edge Molds

: Suitable for conventional straight edge bending, the most widely used;

Sharp Angle Molds

: Suitable for small angle bending or springback compensation, meeting the needs of high-precision sharp angle forming;

Gooseneck Molds (Bending Knife)

: Suitable for U-shaped grooves and deep channel workpiece processing, which can avoid the already bent edges of the workpiece and prevent interference;

Arc Molds

: Suitable for arc and rounded corner bending and forming, such as arc-shaped workpieces and transition rounded corner processing;

Irregular Shaped Molds

: Customized according to special workpiece drawings, suitable for bending requirements of irregular shapes.

Classified by Application Scenario

Standard Sheet Metal Bending Dies

: Suitable for ordinary sheet metals such as low-carbon steel and galvanized steel, offering high cost-effectiveness;

High-Strength Steel Bending Dies

: Thickened design and high-hardness materials, suitable for difficult-to-bend materials such as stainless steel and high-strength alloy plates;

Thin Material Specific Dies

: Precision machined to prevent warping, deformation, and scratching during the bending of thin materials.

Method for selecting Press Brake Dies

The key points for selecting press brake tooling are matching material characteristics, bending processes, workpiece requirements, and equipment parameters—none of which can be dispensed with. The following five key points cover all critical technical aspects of the entire selection process, ensuring both bending accuracy and die life. Beginners can directly refer to them for precise selection.

1: Adaptation to Material Characteristics (Key to Avoiding Springback and Cracking)

Differences in Springback Characteristics of Different Metal Materials

The selection of press brake tooling must first match the tensile strength and springback characteristics of the processed material, which is the core of ensuring accurate bending angles. Ordinary mild steel has minimal springback; when bending to 90°, an 86°~88° punch can be used for compensation. Stainless steel and high-strength steel have significant springback, requiring an 85° punch or targeted adjustment of the punch angle to avoid angular deviations of the workpiece after bending.

Basic Principles for Matching Material Thickness with Dies

Material thickness directly determines the force-bearing condition and bending effect of the die. Thin, medium-thick, and thick materials require corresponding die specifications to avoid die damage or workpiece forming defects, meeting the needs of long-tail keyword searches such as "matching of material thickness and press brake tooling" on Google. The commonly used material for press brake tooling is 42CrMo, After tempering and surface induction hardening, its hardness typically reaches HRC 45-50. It has excellent strength and toughness, effectively preventing fracture under high pressure.and the following is its international standard comparison table.

2: Adhere to the "8x Principle" (Selection Standard for Lower Die V-Notch Width)

Core Formula and Application Scenarios of the "8x Principle"

The "8x Principle" is the core industry formula for bending machine die selection: "Lower die V-notch width V = 8 × material thickness T". As the optimal selection standard under ideal conditions, it is applicable to bending most medium-thick plates (3-8mm), ensuring smooth bending fillets and avoiding workpiece cracking.

Adjustment Techniques for V-Notch Width of Materials with Different Thicknesses

Not all materials strictly follow the 8x Principle; the V-notch width needs to be flexibly adjusted according to material thickness: for thin plates (T＜3mm), it can be reduced to V=6T to obtain a smaller fillet radius; for thick plates (T＞8mm), it needs to be increased to V=10T~12T to reduce bending force, preventing die bursting and inner-side cracking of workpieces.

3: Pressure Tonnage Limitation

Calculation Formula and Application of Bending Pressure Tonnage

During selection, it is imperative to ensure that the die can withstand the actual output pressure of the bending machine; overloading is strictly prohibited, as it will cause die bursting and equipment damage. The calculation of pressure tonnage needs to combine material thickness, material tensile strength, and lower die V-notch width, and the die with corresponding bearing capacity should be selected after accurate calculation.

Key Points for Matching Die Bearing Capacity with Equipment Tonnage

The actual output tonnage of the bending machine must be less than the rated bearing capacity of the die, with a certain safety margin reserved (10%-15% is recommended). For bending thick plates and high-strength steel, thickened dies or segmented dies should be selected to disperse bending pressure and extend die service life.

4: Punch Shape Selection

Conventional Punch Types and Application Scenarios

The punch shape must perfectly match the final shape of the workpiece to avoid interference or forming defects. Different punches correspond to different bending needs: standard punches are suitable for conventional straight-edge bending and have the widest application; sharp-angle punches are suitable for small-angle bending or springback compensation; gooseneck punches are suitable for processing U-shaped grooves and deep channels, as they can avoid the already bent edges of the workpiece.

Key Points for Customizing Punches for Special Workpieces

For workpieces with circular or irregular shapes, arc punches or customized irregular punches should be selected. Combined with accurate workpiece drawings, the die contour must be completely matched with the workpiece to ensure bending forming accuracy.

5: Installation and Equipment Compatibility

Matching of Bending Machine Die Shank Types

The die shank type must be fully compatible with the clamping system of the bending machine. Common shank types include Amada/Promecam, New Standard, and Trumpf/Wila. The equipment clamping method should be confirmed before selection to avoid problems such as insecure die installation and positioning deviation.

Adaptation Principles for Equipment Stroke and Die Height

The die height must match the slide stroke and worktable opening height of the bending machine. An excessively high die will lead to insufficient slide stroke, making it impossible to complete bending; an excessively low die will affect workpiece loading and unloading and reduce production efficiency. At the same time, the compatibility between the die installation interface and the equipment should be confirmed to ensure convenient installation and accurate positioning.

Precautions for Selecting Press Brake Dies:

1. Do not ignore material springback, otherwise it will lead to inaccurate bending angles;

2. The "8x rule" must be followed, otherwise it will cause workpiece cracking and mold damage;

3. Ensure equipment compatibility, otherwise it will lead to installation failure.

42CrMo International Standard Comparison Table (Essential for Selection)

Country/Standard Organization	Standard Code	Corresponding Grade
China (GB)	GB/T 3077	42CrMo or 42CrMo4
USA (AISI/ASTM)	ASTM A29	4140
International Organization for Standardization (ISO)	ISO 683-1	42CrMo4
Germany (DIN)	DIN EN 10083	1.7225 (or 42CrMo4)
Japan (JIS)	JIS G4105	SCM440
UK (BS)	BS 970	708M40 (EN19)

Press Brake v die drawing