Plasma Arc Machining: Learn Diagrams, Construction, Working Principle, Benefits and Applications
Plasma Arc Machining (PAM) is at the forefront of cutting-edge, non-traditional machining technologies, combining speed, precision, and versatility.
This advanced process uses a high-temperature plasma arc to shape and cut conductive materials, from metals to alloys. By producing a superheated plasma jet with temperatures exceeding 20,000°C, PAM quickly melts and removes material from the workpiece, enabling the creation of complex shapes and contours with minimal deformation of the workpiece.
This discussion will reveal all about Plasma Arc Machining, including its diagrams, how it works, parts, advantages, and disadvantages.
1.Plasma Arc Machining
Plasma arc machining uses a high-temperature ionized gas plasma to erode material. The high-velocity plasma jet melts and vaporizes the workpiece, producing complex cuts with minimal heat-affected zones.
It is used in aerospace and metalworking, and is valued for its precision machining of materials such as titanium and nickel alloys, which can improve manufacturing capabilities.
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2.What is Plasma Arc Machining?
Material can be removed from a workpiece using plasma arc machining. During this process, material from the workpiece is melted and removed using a high-velocity stream of hot gas. Plasma jet is another name for this high-speed moving heated gas.
When heated to over 5000°C, the gas or air begins to ionize into positive, negative, and neutral ions. Ionized gases such as air have a temperature range of 11,000 to 28,000 degrees Celsius and are called plasma.
Arc heating of the gas or air creates plasma, which is then used to remove material from the workpiece. Hence, the entire process is called plasma arc machining.
In this process, material is removed from the workpiece by melting it with high-velocity hot air. The metal used as the workpiece determines the gas used in plasma arc machining.
Plasma arc machining is used to cut alloy steel, stainless steel, aluminum, nickel, copper, and cast iron.
3.How Plasma Arc Machining Works
The plasma arc machining (PAM) process uses ionized plasma as a medium to transfer intense heat. This ionized plasma is created by passing a gas through an arc formed between a cathode and an anode. The resulting high-temperature plasma jet quickly melts the metal, thereby helping to efficiently remove material from the workpiece.
4.Plasma Arc Machining Process
The basic principle is that a copper nozzle with a small aperture confines the arc formed between the electrode and the workpiece. This increases the temperature and speed of the plasma as it leaves the nozzle.
The temperature of the plasma exceeds 20,000 degrees Celsius and its speed is almost as fast as sound. The plasma gas flow rate is increased during cutting so that the deeply penetrating plasma jet can cut the material and remove the molten material in the outflowing plasma.
A plasma gun is used for plasma arc machining. The chamber of the plasma gun contains a tungsten electrode. In this case, the tungsten electrode is connected to the negative terminal of the DC power supply. Therefore, the tungsten acts as the cathode. The nozzle is connected to the positive terminal of the DC power supply, so the nozzle of the plasma gun acts as the anode.
When we energize the system, an arc is formed between the cathode tungsten electrode and the anode nozzle. When the gas contacts the plasma, the gas atoms and arc electrons collide, resulting in ionized gas.
In this way, the plasma state we expect for plasma arc machining is achieved. Now, this plasma is directed at the workpiece at high speed and the machining operation begins. One thing to remember is that a significant potential difference is required to achieve the plasma state.
High temperatures are required throughout the process. Since the nozzle releases hot gases, it can overheat. Using a water jacket avoids overheating.
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5.Components of Plasma Arc Machining
Plasma Arc Machining (PAM) involves three basic components: a power supply unit that produces a high voltage DC current, a torch assembly consisting of a converging nozzle and electrode, and a gas supply system.
The arc formed between the electrode and the workpiece ionizes the gas, forming a high temperature plasma that eats away the material for precision cutting and welding applications.
The different parts of Plasma Arc Machining include:
1) Plasma Gun
A plasma gun uses various gases such as nitrogen, hydrogen, argon, or a mixture of gases to produce plasma. It consists of a chamber that houses a tungsten electrode connected to the negative pole, while the nozzle of the plasma gun is connected to the positive pole of the DC power supply.
Supplying the gun with the required gas mixture initiates a strong arc between the anode and cathode. The collision of electrons and gas molecules causes ionization, which generates a lot of heat within the plasma.
2) Power Supply
Using a DC power supply, the two terminals of the plasma gun are developed to produce a significant potential difference between the cathode and the anode. This high potential difference ensures the generation of a powerful arc that effectively ionizes the gas mixture and converts it into plasma.
3) Cooling Mechanism
In order to control the heat generated during the process and the constant flow of hot gases from the nozzle, a cooling mechanism is integrated into the plasma gun. This mechanism usually uses a water jacket, which surrounds the nozzle and effectively dissipates the excess heat through a water jet.
4) Workpiece
Plasma arc machining has the versatility to process a wide range of materials. Different metals, including aluminum, magnesium, carbon, stainless steel and various alloy steels, can be effectively processed using this precise and adaptable machining technology.
6.Construction of Plasma Arc Machining
The plasma arc cutting torch consists of a chamber in which a tungsten electrode is firmly mounted. This tungsten electrode acts as a cathode and is connected to the negative terminal of the DC power supply. For the plasma arc machining process, a dedicated plasma gun is essential, which has its own chamber.
The chamber contains another tungsten electrode, which also acts as a cathode and is connected to the negative terminal of the DC power supply. There is a copper nozzle at the bottom of the chamber, which acts as an anode and is connected to the positive terminal of the DC power supply.
The rest of the combustion chamber is made of insulating material and acts as an insulator. The gas enters the combustion chamber through a small channel located on the right side.
It is worth noting that although the hot gases flow through the cathode and anode, they remain cool due to effective water cooling. A carefully designed water circulation system surrounds the torch to ensure efficient cooling during operation.
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7.How plasma arc processing works
- When direct current is connected to the circuit, a strong arc is generated between the cathode (electrode) and the anode (nozzle). Subsequently, gas is introduced into the chamber, and the gas selection includes hydrogen, nitrogen, argon, or a mixture tailored to the metal being processed. The gas is then heated to extremely high temperatures, ranging from 11,000°C to 28,000°C, using the arc formed between the cathode and anode. When the arc interacts with the gas, the electrons collide with the gas molecules, causing them to break down into individual atoms.
- Due to the high temperature of the arc, some atoms lose electrons, resulting in ionization, which turns the gas into plasma (an electrically charged state). This ionized gas releases a large amount of heat energy. The plasma jet is directed at the workpiece at high speed, and the arc provides several benefits. It further increases the temperature of the ionized gas, aligns the beam almost parallel, and increases the velocity of the gas.
- Once the plasma jet reaches the workpiece, it effectively melts the material, while the high-velocity gas effectively blows away the molten metal. This plasma arc machining process effectively removes material from the workpiece and has shown its significant practicality in a variety of industrial applications.
8.Advantages of Plasma Arc Machining
Plasma Arc Machining (PAM) has several noteworthy advantages that are essential to understand:
- Versatility: PAM can easily process hard and brittle metals, making it suitable for a wide range of metal materials.
- Universal applicability: Almost all types of metals can be plasma arc machined, and the range of applications is very wide.
- Increased cutting rate: One of the main advantages is the ability to achieve higher cutting rates, which ensures increased productivity and efficiency.
- Excellent dimensional accuracy: PAM excels at machining small cavities, provides excellent dimensional accuracy, and can complete complex and precise work.
- Simple and efficient: The plasma arc machining process is simple to execute, and its efficiency helps to simplify manufacturing operations.
- Important role in jet engine repair: PAM plays an important role in the automatic repair of jet engine blades, demonstrating its importance in key industries such as aerospace.
9.Disadvantages of plasma arc machining
In addition to the advantages of plasma arc machining (PAM), some of its disadvantages must be addressed:
- High equipment cost: PAM requires a variety of specialized equipment, which is expensive and requires a large initial investment when implemented.
- Inert gas consumption: The process consumes a large amount of inert gas such as nitrogen or argon, which increases operating costs.
- Narrow surface: PAM produces narrow and unnecessary surfaces, which may be undesirable in some applications.
- Surface changes: One disadvantage is that the surface of the workpiece changes, which may require additional finishing or post-processing steps.
- Safety precautions: Due to the intense heat and potential hazards associated with plasma arc machining, operators or persons involved in the process must take appropriate safety precautions.
- Eye protection: PAM emits strong light that can cause damage to human eyes. Operators must wear appropriate goggles or helmets with protective filters to protect their eyes during operation.
10.Applications of Plasma Arc Machining
Plasma Arc Machining (PAM) is widely used in a variety of professional applications, especially in the following fields:
- Cryogenic and high temperature alloys: PAM is widely used in the machining of cryogenic and high temperature corrosion resistant alloys due to its ability to effectively process challenging materials.
- Titanium Plate Cutting: PAM is ideal for cutting titanium plates up to 8 mm thick, providing precise and efficient processing capabilities.
- Aerospace and Defense: PAM plays a vital role in the aerospace and defense industry and is used in nuclear submarine piping systems and welding steel rocket engine casings, where precision and reliability are critical.
- Stainless Steel Tubes and Tube Mills: PAM is a primary material for applications related to stainless steel tubes and tube mills, which can be precisely cut and formed.
- Medical Device Manufacturing: PAM is also used to manufacture medical devices, especially complex and precise components, where versatility and accuracy are critical.
- Automotive and Power Generation: The automotive industry utilizes PAM to manufacture critical components such as engine parts and exhaust systems. In addition, power generation equipment also benefits from PAM’s ability to work with high-temperature materials.
This blog discusses plasma arc machining, how it works, its parts, advantages and disadvantages, and various applications.