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Making Stamping Dies
Existem mais de cem tipos de materiais que podem ser usados para fazer estampagem dies, ranging from metals, plastics, inorganic non-metals, and paraffin. Let’s take a look at the actual processing and production, the stamping industry uses up to 24 kinds of mold materials. Making Stamping Dies
- 45: High-quality carbon structural steel is the most commonly used medium carbon quenched and tempered steel. Main features: good comprehensive mechanical properties, low hardenability, easy to produce cracks during water quenching. Small pieces should be quenched and tempered, and large pieces should be normalized. Application example: It is mainly used to manufacture high-strength moving parts, such as turbine impellers, compressor pistons, shafts, gears, racks, and worms. Welded parts should be preheated before welding and annealed to relieve stress after welding. Making Stamping Dies
- Q235A (aço A3): o aço carbono estrutural mais utilizado. Principais características: alta plasticidade, tenacidade e desempenho de soldagem, uma certa resistência ao frio estampagem performance, and good cold bending performance. Application example: Widely used in parts and welded structures with general requirements. Such as tie rods, connecting rods, pins, shafts, screws, nuts, ferrules, brackets, machine bases, and building structures and bridges with little force. Making Stamping Dies
- 40Cr: One of the most widely used steel grades in punching dies, it is an alloy structural steel. Main features: After quenching and tempering treatment, it has good comprehensive mechanical properties, low-temperature impact toughness, low notch sensitivity, good hardenability, and high fatigue strength can be obtained when oil cooling and parts with complex shapes are easy to be obtained when water cooling. Cracks occur. Medium cold bending plasticity, good machinability after tempering or quenching Co-infiltration, and high-frequency surface hardening. Application example: After quenching and tempering, it is used to manufacture medium-speed and medium-load parts, such as machine tool gears, shafts, worms, spline shafts, and thimble sleeves; Grinding parts, such as gears, shafts, main shafts, crankshafts, mandrels, sleeves, pins, connecting rods, screws, and nuts, intake valves, etc.; Parts, such as oil pump rotors, sliders, gears, spindles, and collars, etc.; used to manufacture heavy-duty, low-impact, wear-resistant parts such as worms, spindles, shafts, and collars, etc. after quenching and low-temperature tempering; carbon After nitriding treatment, transmission parts with large size and high low-temperature impact toughness, such as shafts and gears, are manufactured. Making Stamping Dies
- HT150: ferro fundido cinzento. Exemplos de aplicação: caixa de engrenagens, cama de máquina, caixa, cilindro hidráulico, corpo de bomba, corpo de válvula, volante, cabeçote, polia e tampa de mancal, etc.
- 35: Common materials for various standard parts and fasteners. Main features: appropriate strength, good plasticity, high cold plasticity, and acceptable weldability. Local upsetting and wire drawing can be performed in the cold state. Low hardenability, use after normalizing or quenching and tempering. Application example: It is suitable for the manufacture of parts with small sections and large loads, such as crankshafts, levers, connecting rods, shackles, various standard parts, and fasteners. Making Stamping Dies
- 65Mn: commonly used spring steel. Application example: various flat and round springs, seat cushion springs, and spring springs of small size, can also be made into spring rings, valve springs, clutch reeds, brake springs, cold coil springs, circlips, etc. Making Stamping Dies
- 0Cr18Ni9: The most commonly used stainless steel (US steel number 304, Japanese steel number SUS304). Features and applications: It is the most widely used stainless heat-resistant steel, such as food equipment, general chemical equipment, etc. Making Stamping Dies
- Cr12: aço de matriz para trabalho a frio comumente usado (aço americano número D3, aço japonês número SKD1). Características e aplicação: O aço Cr12 é um aço de matriz de trabalho a frio amplamente utilizado, que é um aço de alto carbono e alto cromo. O aço tem boa temperabilidade e boa resistência ao desgaste; porque o teor de carbono do aço Cr12 é tão alto quanto 2,3%, a tenacidade ao impacto é baixa, é fácil ser frágil e é fácil formar carbonetos eutéticos irregulares; O aço Cr12 é devido a Com boa resistência ao desgaste, é usado principalmente para fabricar punções a frio, punções, matrizes de estampagem, matrizes de cabeçalho a frio, matrizes de extrusão a frio, punções e matrizes, mangas de perfuração, medidores que exigem alta resistência ao desgaste com menor carga de impacto. , matrizes de trefilação, matrizes de estampagem, placas de laminação de roscas, matrizes de estampagem profunda e matrizes de prensagem a frio para metalurgia do pó, etc.
- DC53: As matrizes de estampagem de trabalho a frio comumente usadas importadas do Japão, o número de aço do fabricante japonês Datong Special Steel Co., Ltd.. Características e aplicações: aço para matrizes de trabalho a frio de alta resistência e tenacidade. Após o revenimento em alta temperatura, possui alta dureza, alta tenacidade e bom desempenho de corte de arame. Usado para matrizes de estampagem a frio de precisão, matrizes de desenho, matrizes de laminação de arame, matrizes de estampagem a frio e punções, etc.
- DCCr12MoV: Wear-resistant chromium steel is made in China, with lower carbon content than Cr12 steel, and Mo and V are added to improve the unevenness of carbides. Mo can reduce carbide segregation and improve hardenability, while V can refine grains and increase toughness. This steel has high hardenability, the cross-section can be completely hardenable below 400mm, and it can still maintain good hardness and wear resistance at 300~400℃. Compared with Cr12, it has higher toughness and less volume change during quenching. Making Stamping Dies
- It has high wear resistance and good comprehensive mechanical properties. Therefore, it is possible to manufacture various dies with a large cross-section, complex shapes and high impact, such as ordinary drawing dies, punching dies, punching dies, blanking dies, trimming dies, rolling dies, wire drawing dies, cold extrusion dies, Cold cutting scissors, circular saws, standard tools and measuring tools, etc. Making Stamping Dies
- SKD11: Tough chrome steel, produced by Hitachi, Ltd., Japan. Technically, the casting structure in the steel is improved, the grains are refined, the toughness and wear resistance of Cr12MoV are improved, and the service life of the mold is prolonged. Making Stamping Dies
- D2: High carbon and high chromium cold work steel, produced in the United States. It has high hardenability, hardenability, wear resistance, good high-temperature oxidation resistance, and good corrosion resistance after quenching and polishing. Heat treatment deformation is small. It is suitable to manufacture all kinds of cold working dies, cutting tools, and measuring tools that require high precision and long life, such as drawing dies, cold extrusion dies and cold shearing knives. Making Stamping Dies
- SKD11 (SLD): non-deformable toughness high chromium steel, produced by Hitachi, Ltd., Japan. Due to the increase in the content of Mo and V in the steel, the casting structure in the steel is improved, the grains are refined, and the carbide morphology is improved, so the strength and toughness (flexural strength, deflection, impact toughness, etc.) of this steel are higher than those of SKD1 and SKD1, With high D2, wear resistance has also increased, and it has higher tempering resistance. The practice has proved that the life of this steel mold has been improved compared with Cr12MoV. It is often used to manufacture molds with high requirements, such as drawing molds, molds for impact grinding wheels, etc. Making Stamping Dies
- DC53: Aço de alta tenacidade e alto cromo, produzido pela Datong Co., Ltd., Japão. A dureza do tratamento térmico é maior que SKD11. Após o revenimento em alta temperatura (520 ~ 530) ℃, pode atingir uma alta dureza de 62 ~ 63HRC. Em termos de força e resistência ao desgaste, o DC53 excede o SKD11 e a tenacidade é o dobro do SKD11. A tenacidade do DC53 raramente ocorre rachaduras e trincas na fabricação de matrizes para trabalho a frio, o que melhora muito a vida útil. A tensão residual é pequena e a tensão residual é reduzida voltando a uma temperatura elevada. Como as rachaduras e deformações após o corte do fio são suprimidas, a usinabilidade e a abrasividade excedem SKD11, e é usada para matrizes de estampagem de precisão, forjamento a frio e matrizes de estampagem profunda, etc.
- SKH-9: General-purpose high-speed steel with high wear resistance and toughness, produced by Hitachi, Ltd., Japan. For cold forging dies, slitters, drills, reamers, punches, etc. Making Stamping Dies
- ASP-23: Powder metallurgy high-speed steel, made in Sweden. Carbide distribution is extremely uniform, wear resistance, high toughness, easy processing, and heat treatment dimensional stability. Used for all kinds of long-life cutting tools such as punches, deep drawing dies, drilling dies, milling cutters, and shear blades. Making Stamping Dies
- P20: Moldes plásticos do tamanho exigido para requisitos gerais, produzidos nos Estados Unidos. Operação eletricamente erodível. O estado de fábrica é HB270~300 pré-endurecido, dureza temperada HRC52.
- 718: Moldes plásticos grandes e pequenos com altas exigências, fabricados na Suécia. Operação eletricamente erodível. Estado de fábrica pré-endurecido HB290~330, dureza temperada HRC52.
- Nak80: molde plástico de alta precisão e espelho alto, produzido pela Datong Co., Ltd., Japão. O estado de fábrica é HB370~400 pré-endurecido, dureza temperada HRC52.
- S136: Anti-corrosion and mirror-polished plastic mold, made in Sweden. Pre-hardened HB<215 in factory state, quenched hardness HRC52. Making Stamping Dies
- H13: Commonly used die-casting die for aluminum, zinc, magnesium, and alloy die-casting, hot stamping die, aluminum extrusion die, etc. Making Stamping Dies
- SKD61: Molde de fundição avançado, produzido pela Hitachi, Ltd., Japão. Através da tecnologia de redissolução do lastro, a vida útil é significativamente melhorada do que a do H13. Para matrizes de estampagem a quente, matrizes de extrusão de alumínio.
- 8407: Molde de fundição avançado, fabricado na Suécia. Para matrizes de estampagem a quente, matrizes de extrusão de alumínio.
- FDAC: Adicionado enxofre para aumentar sua facilidade de corte. A dureza pré-endurecida de fábrica é HRC38~42, que pode ser gravada diretamente sem têmpera e revenimento. É usado para moldes de pequenos lotes, moldes simples, vários produtos de resina, peças deslizantes e peças de molde com um curto prazo de entrega. Como molde de zíper, molde de armação de óculos e assim por diante.
Making stamping dies, also known as die tooling or stamping tooling, is a crucial process in metalworking and manufacturing. Stamping dies are specialized tools used to cut, form, or shape sheet metal or other materials into specific designs or parts. Here’s an overview of the steps involved in making stamping dies: Making Stamping Dies
Design and Planning:
Determine the specific requirements of the stamped part, including dimensions, tolerances, and material type.
Create a detailed design or CAD (Computer-Aided Design) drawing of the part and the stamping die, including the cavity, punch, and any necessary features.
Plan the layout of the die components, such as punches, dies, guides, and strippers.
Material Selection:
Choose the appropriate materials for the die components. Common materials for dies include tool steel, carbide, and high-speed steel, depending on the complexity and volume of work.
Ensure that the material selected can withstand the forces and wear associated with the stamping process.
Rough Machining:
Start with rough machining of the die components using milling machines, lathes, or other cutting tools. Making Stamping Dies
Rough machining creates the basic shape of the die components, leaving enough material for subsequent finishing operations.
Heat Treatment: Making Stamping Dies
Heat treat the die components to enhance their hardness and durability. This step involves processes like hardening, tempering, and stress relieving to achieve the desired material properties.
Precision Machining: Making Stamping Dies
Perform precision machining to achieve the final dimensions and surface finish of the die components. This may include grinding, milling, drilling, and honing.
Accuracy and precision are critical in this step to ensure the stamped parts meet the required specifications.
Assembly:
Assemble the die components, including the punch, die, guides, strippers, and any additional components such as springs or ejector systems.
Proper alignment and clearances between components are essential to ensure smooth and efficient stamping.
Testing and Adjustment:
Test the assembled die on a press machine to check for any issues, such as misalignment, clearance problems, or inadequate material flow.
Make necessary adjustments to optimize the die’s performance and achieve the desired part quality.
Surface Treatment:
Apply surface treatments or coatings to the die components to improve wear resistance, reduce friction, or prevent corrosion.
Trial Runs and Fine-Tuning:
Conduct trial runs on the press to stamp sample parts and fine-tune the die’s operation until it consistently produces parts within specified tolerances.
Quality Control:
Implement a rigorous quality control process to inspect stamped parts for dimensional accuracy and surface finish.
Ensure that the die maintains its performance over time with regular maintenance and replacement of worn components.
Production:
Once the stamping die is fully tested and optimized, it can be used for high-volume production of stamped parts.
Creating stamping dies is a specialized and skill-intensive process that requires precision engineering, machining expertise, and a deep understanding of materials and manufacturing principles. High-quality stamping dies are essential for producing consistent and accurate stamped parts in various industries, including automotive, aerospace, electronics, and consumer goods manufacturing.
Obrigado por seu artigo! É muito interessante!
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