Wire EDM (Electrical Discharge Machining) and sinker EDM are machining methods used to cut complex shapes in hard metals like hardened steel. In wire EDM, a thin metal wire makes the cuts. Sinker EDM uses a shaped electrode to create the desired cut.
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Both methods involve passing an electrical discharge between the metal piece and the cutting tool, which erodes the metal into tiny particles, allowing for precise cuts and detailed shapes that are hard to achieve with traditional machining methods.
Wire EDM is best for cutting thin or delicate parts, while sinker EDM is commonly used to make molds or dies. Both EDM techniques are used in the aerospace, automotive, medical devices, and precision engineering industries.
Wire EDM, or Electrical Discharge Machining, is a precise method of cutting hard materials. It uses a thin, electrically charged wire to make accurate cuts in metals and other conductive materials. The process involves creating an electrical spark that melts the surface of the workpiece. A special fluid flows around the cutting area to remove the melted material. As the wire moves continuously, it creates sparks, forming the final product’s desired shape.
Sinker EDM (Electrical Discharge Machining) is a manufacturing process that uses a shaped electrode, usually made of graphite or copper. This electrode is placed in an electrically conductive fluid together with a workpiece. An electrical charge flows between the two, creating sparks as the electrode is near the workpiece. These sparks melt the surface material of the workpiece, and the fluid washes away the melted material. The electrode continues this process, shaping the workpiece until it is complete.
Wire EDM and sinker EDM are two types of Electrical Discharge Machining. The main difference is that wire EDM uses a thin wire as the electrode to cut through the workpiece, while sinker EDM uses a shaped electrode to form the desired shape in the workpiece.
Wire EDM is suitable for cutting intricate shapes and parts requiring tight tolerances. Sinker EDM works better for creating deeper cavities and shapes in larger workpieces. Another key difference is that wire EDM keeps a constant gap between the electrode and the workpiece. In contrast, sinker EDM submerges the electrode in a dielectric fluid to cool it and wash away debris.
Both processes have their advantages and limitations. Choosing between them depends on the requirements of the job.
Electrical Discharge Machining (EDM) is a versatile manufacturing process that produces high-precision components. The standard finishing and post-processing techniques for EDM parts include:
Deburring: This involves removing any sharp edges or burrs left from the EDM process.
Polishing: This technique improves the surface finish and reduces roughness through mechanical polishing.
Plating: A thin protective metal coating enhances corrosion resistance or improves appearance.
Heat Treatment: This process enhances the component’s hardness, strength, or other properties.
Passivation: This involves forming a protective oxide layer to prevent corrosion.
These techniques help ensure that EDM parts meet the required specifications and performance standards.
Electrical discharge machining (EDM) is a non-traditional form of precision machining that uses thermal energy instead of mechanical force to remove material from a workpiece. It is sometimes referred to as Spark Machining since it utilises electrical sparks that are near º C to º C.
Engineers often turn to EDM when machining processes such as CNC milling and CNC turning cannot produce the desired cut, such as sharp internal corners or a particularly deep cavity. However, EDM manufacturing only works for electrically conductive materials like hardened steel, titanium and aluminium.
Read on for an introductory guide on EDM machines, the various types of electrical discharge machining available, the EDM processes for each type and the type of EDM machine they use, and what EDM machining process is best for your project.
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Electrical Discharge Machining (EDM) is a non-traditional machining process that uses electrical sparks to erode a material, enabling the machining of intricate shapes in hard, conductive materials. The process involves an electrode and workpiece separated by a dielectric liquid, which breaks down at the point of the electrical discharge, creating a spark.
The Electrical Discharge Machining (EDM) process is a highly precise method of metal removal. It involves creating a path of electrical discharge between an electrode and the workpiece. The intense heat generated by the electrical sparks, which can reach temperatures of up to 12,000 degrees Celsius, melts and vaporises the material. The debris is then removed by a dielectric fluid.
Electric discharge machining can be divided into three common types, Die sinking EDM, Wire EDM and hole drilling EDM.
Die sink EDM (also known as Ram EDM, conventional EDM, or cavity-type EDM) is the best Electro Discharge Machining for creating parts with complex cavities. It is also the method chosen for solving the sharp internal corner issue when CNC machining. This method utilises graphite or copper electrodes, a dielectric fluid, and an electric spark induced between the electrode and the workpiece.
In the first step of this process, an electrode is produced in the reverse shape of the required cavity. This forms the die. A voltage is then induced between the die and the electrically conductive workpiece while submerged in a dielectric fluid like oil.
The die is slowly lowered towards the workpiece until ‘electric breakdown’ occurs and a spark jumps the ‘spark gap’. This vaporises and melts material from the workpiece while dielectric fluid subsequently carries any ejected particles away. A small amount of the electrode is also often eroded during this process.
As the series of high-frequency sparks repeatedly removes a small amount of material from the workpiece, the desired shape will begin to take place and be precisely cut out. This sinker EDM process can be depicted in the image below:
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Every aspect of this process, between the servers, power supply, and position of the electrodes, is completely controlled through precision machining.
Wire EDM, otherwise known as wire erosion, is commonly used to produce extrusion dies. It cuts using the same mechanism as die-sinking. However, the die is replaced with a very fine electrically charged wire which will work as the electrode. This machining method is comparable to a cheese cutter, making a two-dimensional cut in a three-dimensional part.
The wire is usually very thin, with a diameter of around 0.05mm to 0.35mm. A fresh wire is automatically spooled throughout the machining process to avoid using burnt wire and to ensure precise cutting. The below image illustrates the way wire is utilised in wire EDM:
This process will produce incredibly precise cuts. However, if you are looking to cut sharp inside corners, it’s important to note that wire EDM alone won’t be able to give you true square corners. The wire and spark gap will create a tiny radius of about 0.13mm to 0.15mm, but this can be smaller or larger depending on the diameter of the wire.
If that is not sufficient for your project, a small dog-bone corner can be applied to create perfectly square internal corners. Read our guide on how to machine square corners for more information on the best ways to machine sharp internal corners.
Sometimes it is necessary to start a cut from the centre of a part rather than from one of the edges. For example, machining a complex shape in the centre of an extrusion die. If that’s the case, hole drilling EDM can make a small hole for the wire to be threaded through for wire EDM machining.
As the name implies, Hole drilling EDM (or small hole drilling EDM) is used to machine holes. However, this technique can accurately machine extremely small and deep holes that don't require deburring compared to traditional hole drilling methods.
This method also uses the same fundamental principles as die-sinking EDM. However, the cut is made with a pulsing cylindrical electrode with dielectric liquid fed into the cutting area while moving deeper into the workpiece.
This method has been key to the advancement of high-temperature turbine blades, as it allows for very intricate cooling channels to be manufactured inside the turbine blades.
One of the main advantages of electrical discharge machining is that it allows for complex shapes and depths to be cut, which would be impossible with other conventional traditional machining methods. These include undercuts and perfectly square internal corners. The machining process does not create a burr, which is an additional benefit.
See our CNC machining design guidelines for more possibilities available through CNC machining and Electro Discharge Machining.
In contrast to conventional machining methods, the tool never comes into direct contact with the workpiece in this process. With no forces acting on the part, there is no distortion. This enables very thin features to be machined without the risk of breaking. Furthermore, the lack of distortion means very tight tolerances of +/- 0.012mm can be achieved.
Conventional material removal processes such as CNC milling leave machining marks on the workpiece that require post-machining finishing to remove. EDM has zero-directionality to the surface finish, making uniformly smooth surfaces possible without additional treatment. However, quick EDM processing can leave behind a slight bead blasted-like texture.
See our guide on selecting the right surface roughness for CNC machining for a more in-depth look into what the best surface roughness will be for your project.
Limited in terms of its efficiency in producing high-volume orders, EDM is very well-suited for producing small parts and prototypes due to its high levels of precision. For example, this technique is often employed within the automotive industry, where high levels of precision are required to produce intricate engine components.
A key feature of electric discharge machining is that it can machine through any material as long as it is conductive. This means that tough materials such as Inconel and Tungsten carbide can be machined.
The material removal rate is low when compared to conventional machining methods. As the manufacturing process is very power-intensive, the increase in manufacturing time impacts the overall cost. As a result of this, EDM is not an effective method to use for large-scale projects, and as such is often overlooked for alternative methods.
For a material to be processed using electrical discharge machining, it must be electrically conductive. It should also be considered that although the process is technically stress-free, machining there is still a thermal process that can alter the metallurgy of the workpiece.
For die-sinking EDM, a custom electrode that is reverse of the feature is required. At low manufacturing volumes, machining the electrode can seem expensive, however, at higher volumes, this additional cost can be absorbed across many components.
Due to the amount of electricity required in order for Electro Discharge Machining to take place, it does not represent an environmentally-conscious method of machining. As more and more companies globally look to introduce measures in order to reduce their carbon footprints, other methods of machining that require less electricity, and are therefore less harmful to the environment, are favoured over EDM.
As with all machining processes, there is a balance between cutting speed and surface finish quality. It is common for the initial cut to be faster and rougher, then the subsequent cuts made at a slower speed to produce a clean surface finish. Further tool passes can be made at slower speeds to create an excellent surface finish, but this increases machining time and thus cost.
EDM can work to very tight tolerances, +/- 0.012mm. This is why the aerospace and medical industry utilise the process.
On the whole, all conductive materials can be machined with electrical discharge machining. Certain materials, such as aerospace grade high-nickel alloys, can present some machining challenges. However, often the solution lies in changing the electrode material or machining speed. The main factors that influence the choice of electrode material are the electrode’s conductivity and resistance to erosion.
Some applications for electro-discharge machining may include:
Electrical discharge machining is an excellent method to use in conjunction with a traditional machining method such as CNC machining when parts have specific geometrical requirements. Also, the ability of the process to machine hard materials make it an attractive option when working with materials like Inconel. However, the machining process is relatively slow, so high-volume tasks are not well suited for this method. Watch this video tutorial for a visual walkthrough of the processes involved within EDM.
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