Преимущества процесса холодной экструзии
Blog Details Cold extrusion is to put the metal blank in the cold extrusion cavity, at room temperature, through the press fixed punch to apply pressure to the blank, so that the metal blank to produce plastic deformation and parts processing method. China has been able to cold extrusion of lead, tin, aluminum, copper, zinc and their alloys, low carbon steel, medium carbon steel, tool steel, low alloy steel, and stainless steel, and even bearing steel, high carbon and high aluminum alloy tool steel, high-speed steel, and other metals can be cold extrusion of a certain amount of deformation.In extrusion equipment, our country has the ability to design and manufacture extrusion presses. In addition to the general mechanical press, hydraulic press, cold extrusion press, friction press,, and high-speed high-energy equipment have been successfully used for hard extrusion production. Define Extrusion is a process that forces the gold chips to produce plastic flow through the gap between the punch and the die or the die outlet to make the hollow parts or the parts whose section is smaller than the blank section.If the blank is extruded without heat, it is called cold extrusion.Cold extrusion is one of the processing technology of no chip and less chip parts, so it is an advanced technology in the plastic processing of gold chips. If the blank is pressed by heating it to a temperature below the recrystallization temperature, it is called warm extrusion. Warm extrusion still has the advantage of fewer chips. Advantages Accurate sizing The general dimension accuracy of cold extruded parts developed in our country is up to 8 ~ 9 grades. If ideal lubrication is used, it is second only to the fine polishing surface. Therefore, parts manufactured by the cold extrusion method generally do not need to be reworked, and a small number only need to be finished (grinding). Save materials. Save materials The utilization rate of cold extruded materials can usually reach more than 80%. Such as the Jiefang brand automobile piston pin dynamic cutting material utilization rate of 43.3%, and with cold extrusion material utilization rate increased to 92%; For example, after the universal joint bearing sleeve is changed to cold extrusion, the material utilization rate is increased from 27.8% to 64%. It can be seen that the cold extrusion method can save a lot of steel and non-ferrous metal materials in the production of machine parts High production efficiency The efficiency of producing mechanical parts by cold extrusion is very high, especially in the production of large batch parts. The production by cold extrusion is several times, dozens of times, or even hundreds of times as compared with cutting. For example, cold-extruded piston pins for automobiles are 3.2 times more productive than machined ones, and cold-extruded piston pin automatons are now used to further increase productivity. The productivity of one cold extrusion automaton is equivalent to that of 100 regular lathes or 10 four-spindle automatic lathes. Wide application Such as special-shaped sections, internal teeth, special-shaped holes, and blind holes, These parts are difficult to complete by other processing methods, but it is very convenient to process with cold extrusion. High strength Because the cold extrusion adopts the cold deformation strengthening characteristic of metal materials, that is, the metal blank is in the state of three-way compressive stress during the extrusion process, and the material is compact and has continuous fiber flow direction after deformation, so the strength of the parts is greatly improved. In this way, low-strength materials can be used instead of high-strength materials. For example, in the past, 20Cr steel was used to manufacture liberation brand piston pins by cutting. Now, 20 steel is used to manufacture piston pins by cold extrusion. After the performance test, the cold extrusion method is higher than the cutting method to manufacture piston pins. If you have any needs for cold extrusion, ple feel free to contact Prototek, Tags: Social Network: Recently Posts Online Help! +(86) 0791-86372550 WANT TO DISCUSS IN DETAIL Contact Our Consultant Now CONTACT NOW
The Difference Between Casting and Forging
Blog Details In metalworking, casting, and forging stand as two fundamental processes, each with its significance and application. This article explores the distinctions between casting and forging, elucidating their respective processes and advantages. Casting Process Definition and Procedure: Casting stands as a foundational method in metalworking, involving the pouring of molten metal into a prepared mold to achieve the desired shape upon solidification. The process begins with the preparation of the mold, which can be made from various materials such as sand, metal, or ceramics, depending on the specific requirements of the casting. Pattern Making: Before the mold can be formed, a pattern of the intended part must be created. This pattern serves as a replica of the final product and is typically made from wood, metal, or plastic. Skilled pattern makers craft these patterns precisely to ensure the accurate reproduction of the desired shape and dimensions. Mold Preparation: Once the pattern is ready, the mold-making process commences. For sand casting, a two-part mold is commonly used, consisting of a cope (top half) and a drag (bottom half). The pattern is placed within the drag, and sand is packed around it to create the mold cavity. After the cope is placed over the drag and the mold is securely closed, molten metal is poured into the cavity through a gating system. Metal Melting and Pouring: The choice of metal for casting depends on factors such as desired properties, cost, and availability. Commonly used metals include iron, steel, aluminum, and copper alloys. These metals are melted in a furnace at temperatures exceeding their respective melting points and then poured into the mold cavity. Solidification and Cooling: Once the molten metal is poured into the mold, it begins to solidify, taking on the shape of the cavity. The cooling rate and solidification process influence the final microstructure and properties of the casting. After solidification is complete, the mold is opened, and the casting is removed, ready for further processing or finishing. Finishing Operations: After casting, the parts may undergo additional finishing operations to remove excess material, smooth rough surfaces, and achieve the desired dimensional accuracy. These operations may include machining, grinding, sandblasting, and heat treatment, depending on the application’s specific requirements. Advantages and Considerations: Casting offers several advantages, including the ability to produce complex shapes, cost-effectiveness for large production runs, and the versatility to work with a wide range of metals and alloys. However, it also presents challenges such as porosity, shrinkage, and dimensional variability, which must be carefully managed through proper design and process control. Forging Process Definition and Procedure: Forging is a metalworking process that involves shaping metal through the application of compressive force. Unlike casting, which involves pouring molten metal into a mold, forging works with solid metal blanks, known as billets or ingots, that are heated to a suitable temperature and then shaped using mechanical or hydraulic presses, hammers, or dies. Heating: The forging process typically begins with heating the metal to a temperature above its recrystallization point but below its melting point. This heating softens the metal, making it more malleable and easier to shape without causing it to liquefy. The temperature and heating time vary depending on the type of metal and the desired properties of the final forged part. Forming: Once heated to the appropriate temperature, the metal blank is placed on the forging equipment, such as a hammer or press. The metal is then subjected to compressive forces, which cause it to deform and take on the shape of the die or mold. The shaping process may involve multiple forging operations, with intermediate heating steps as needed to maintain the metal’s ductility. Types of Forging: Forging can be categorized into several types based on the method used to apply force and shape the metal. These include: Open-Die Forging: In this method, the metal is shaped between flat dies or anvils, allowing for greater flexibility in producing a variety of shapes and sizes. Closed-Die Forging: Also known as impression-die forging, this method uses dies with pre-cut cavities to impart specific shapes and dimensions to the metal. Roll Forging: This process involves passing the metal between two rotating rolls to shape it into the desired form gradually. Cooling and Finishing: After the forging process is complete, the forged part can cool gradually, either in air or by quenching in water, oil, or polymer baths, depending on the material and desired properties. This controlled cooling helps to relieve internal stresses and enhance the mechanical properties of the forged part. Once cooled, the part may undergo additional finishing operations such as machining, grinding, or heat treatment to achieve the desired surface finish, dimensional accuracy, and mechanical properties. Advantages and Considerations: Forging offers several advantages, including producing parts with superior mechanical properties, such as higher strength, toughness, and fatigue resistance, compared to cast or machined parts. Additionally, forging allows for tighter dimensional tolerances and finer surface finishes, reducing the need for secondary machining operations. However, forging also requires specialized equipment and skilled labor, and the initial tooling costs can be higher than other manufacturing processes. Differences Between Casting and Forging Casting and forging are two distinct metalworking processes with characteristics, advantages, and applications. Understanding the differences between these processes is crucial for selecting the most appropriate method based on the specific requirements of a given application. Material Characteristics: Casting: Casting involves pouring molten metal into a mold and solidifying it to form the desired shape. As a result, cast parts typically exhibit a uniform composition and grain structure throughout the piece. However, casting can introduce porosity and internal defects, particularly in complex geometries or large parts, which may affect the mechanical properties of the final product. Cast parts tend to have lower strength and ductility than forged ones, making them suitable for applications where dimensional accuracy and surface finish are more critical than mechanical performance. Forging: Forging, on the other hand, involves shaping solid metal blanks by applying compressive forces. This process compacts the metal grains, aligning them