What is Machining?
Machining is a manufacturing process that involves shaping a piece of material to a final desired shape by removing material in a controlled manner. Since machining processes utilize machine tools like machining centers and work by removing material, they are often termed as subtractive manufacturing processes, unlike additive manufacturing, which involves а controlled addition of material.
Machining processes can work on a large number of materials, including metals, plastics, wood, glass, and more. The workability of machining processes on this vast range gives these processes applications in numerous industries.
History of Machining
The history of machining processes dates back a few centuries. In the 18th century, machining processes pertained to repairing machines and equipment by using hard-working processes such as wood carving or metalworking using forging. To be precise, the term ‘machinists’ existed, but ‘machining tools’ didn’t.
Machining tools came into existence later in the middle of the 20th century. This happened due to the emergence of machining processes such as drilling, turning, boring, milling, broaching, planing, sawing, reaming, taping, and more. These processes were done with manually operated machining tools such as simple lathes, drilling tools, cutting tools, or drill presses. Over the years, with the emergence of computers and various technologies, all the machining processes got associated with Computer Numerical Control (CNC).
How Does Machining Work?
The concept of machining is to start with a bigger piece of material than the required part, and then remove the material with a controlled cutting tool. In the modern manufacturing world, machining tools are controlled by Computer Numerical Control (CNC) technologies. It is a structured process that starts with a conceptual design of the desired shape and then proceeds with the execution of design on the machining tools.
Stages of the Machining Process
The machining process for any component goes through these steps in this very order:
Creating Blueprints
Firstly, it is important to create a conceptual idea of the part that is required. This is done through engineering drawings and blueprints of the part, with the intended dimensions mentioned on the blueprints. When specifying the dimensions, it is important to keep in mind the workability of materials and their mechanical strength. For instance, a wall should have a minimum thickness or the part can collapse in the machining stage itself.
Creating CAD Models
Once the blueprints of the part are ready, it needs to be converted into a digital 3D model. This is done by using Computer Aided Design (CAD) software. This is the job of a programmer. More complex parts require complex CAD programs.
The CAD models are converted to Computer Aided Manufacturing (CAM) programs. The CAM program is the language that the CNC-koneeseen understands. CAD programs can also tell if there are any issues with the design that will give errors in the machining process.
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The machine setup is carried out by the operator and involves adjusting the tooling and mounting the workpiece materials on the CNC machine. The setup can vary based on the type of machining process that will undergo. Setup also includes transferring the CAD instructions to the machine.
Program Execution
Once the machine is ready, the operator executes the program. The machine then works on shaping the program to the final part. It can be done in a number of ways, depending on the particular machine being used. After execution, the final part is ready and unmounted by the operator. Based on the requirement, it can be then sent for secondary machining processes.
Applications of Machining
Machining tools are used in every kind of industry for creating a wide array of parts. Some of the common types of equipment made and applications of machining processes are:
Bicycle framesEnginesSmartphone and laptop casesScientific projectsAerospace partsMilitary and firearms equipmentMedical and surgical equipmentmany other parts
What are the Different Types of Machining Processes?
There are many types of machining processes and operations, each with its own purpose and design. Here is a brief overview of these different machining processes:
Sorvaus
In turning, the workpiece rotates around a central axis while the cutting tool shaves off material from it. This method is used for the symmetrical shaping of a workpiece. The cutting tool can be controlled by the computer. Some applications of the turning process are:
Engine componentsMachine componentsShaftsThreadsTapers
Jyrsintä
Milling involves a rotating cutting surface moving against the workpiece to create different shapes of planes. The cutting shapes can range from simple straight cuts to angled and inclined surfaces for particular purposes. There are many different milling tools to accomplish this, such as bed mill, column mill, gantry mill, C-frame mill, knee mill, turret mill, ram-type mill, and more. Some applications of milling tools are:
GearsSlotting and GroovesAerospace componentsAgricultural equipmentAutomotive partsEnergy sector
Poraus
Drilling tools are one of the simplest types of machining equipment. Their purpose is to move around the workpiece and create holes using drill presses. The holes are done for inserting screws, secondary assembling, or just for aesthetics. Applications of drilling are:
Screw holesFuel injector bodiesHeat exchanger tubesFluid assembly endsAircraft landing gear
Boring
Boring tools enlarge previously drilled holes in the workpiece. This is done either with a single-point cutting tool or an assortment of such tools. In a way, boring is a counterpart to turning, the major difference being that boring works on the internal diameter while turning tools work on the external diameter. Common applications of this process can be seen in barrels of firearms or engine cylinders. Applications of boring are:
Engine cylinders in the automotive industryCranes and end loadersMiningFirearms
Reaming
Reaming is a process for slightly widening the diameter of a drilled hole and adding an internal surface finish to it. This process is used when a hole of a very precise diameter or surface finish is required, which drilling tools cannot provide. The usual process to create a precise hole using reaming is to drill an undersized hole and then use reaming for widening the hole to the precise width and finish. Applications of reaming are:
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CNC-koneistus
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Drilling tools:
There are many different types of drilling tools, such as:
Hand drillHand drill with braceStandard electric drillHammer drillBenchtop drill
In every drill, there is the option to use varying end bits depending on the requirement. Some common bits options are:
Twist bitsMasonry bitsDowel bitsFlat bitsAugers
Boring tools:
While boring is a simple task, it can use a number of tools for customization. Some common boring tools are:
Rough boring headsFine boring headsTwin cutter boring headsDigital boring headsSpecialty boring headsModular boring tools
What are the Advantages of Machining?
Machining techniques have been in use for so long because of the countless benefits they have to offer against any other manufacturing process, such as additive manufacturing. Some of the benefits of machining techniques are:
Versatile Process: Machining is a highly versatile process when it comes to the number of materials it can work on. While additive manufacturing methods generally work on only plastics, machining is not limited to any such case. It can work on metals and nonmetals alike, as we will see in the later section about the material application of machining operations.Precision: CNC-työstö provides a precision that cannot be matched by any other method. It is easy to achieve machining tolerances of around 0.001″. Even lower tolerances are possible by using specialty tools of precision machining.Surface Finishing: Machining operations provide multiple options when it comes to surface finishing. Additionally, the machining process is quite smooth which can eliminate the requirement for any later secondary finishing stages, saving time and costs.High-Density Machining: Many situations, especially in the aerospace and defense industry, require parts made out of the toughest materials out there. These materials are hard to shape with other manufacturing methods. However, machining can work on these high-density materials with ease.Labor Saving: The machining manufacturing process in this day and age is automated and controlled by computers. There is no requirement for manual handling of the tools. This saves labor to a large extent and human resources can be replaced to high priority intellectual applications.Production Rate: Machining can provide a high production rate, suitable for mass production. The rate can be adjusted and lower quantities can be extracted out of the machining operations for use cases such as prototyping or tooling.Consistency: Machining operations have high repeatability and consistency. This is because of the fact that the tools are controlled by a computer, so the movement and working of tools will be the same without any human error involved. This is very beneficial for mass production where customers look for consistent products.Higher Profits: Due to the exponentially faster production and lower labor costs, manufacturers can take out higher profits from the manufacturing process. Machining operations also have lesser infrastructure requirements, leading to lower expenses.
What are the Disadvantages of Machining?
While machining is the core pillar of modern manufacturing, there can be some disadvantages to the process such as:
Limitation to Machinable Surface: There is a limitation to the number of surfaces that can be machined in a workpiece. The area under the clamps and the side touching the worktable often aren’t reachable by the rotating cutting tool. To machine these surfaces, the operator needs to unmount the workpiece, change its orientation, and mount it again.Operator Skill: While the human labor in machining is highly reduced, there is a higher emphasis on operator skill. An unskilled operator can lead to low-quality production, damage to the workpiece, or even damage to the machine. Additionally, the machining of complex products also requires a skilled programming team.Initial Cost: The initial cost of industrial machining setups can be very high. Multi-axis milling machines are great for the rapid production of complex parts, but the high cost of these machines discourages manufacturers from buying these machines.
These disadvantages to machining can be easily avoided by outsourcing the machining requirements to a third-party manufacturer. XTJ is the best solution in this regard, with the most advanced equipment and a highly experienced team.
What Materials Can Be Machined?
There is no limit when it comes to the materials that can undergo machining processes. Some of the popular options are:
Alumiini
The low weight and high strength of aluminum make it an attractive material for many manufacturers. This is why it is one of the most common types of machining materials. Machining works on all grades of aluminum such as Aluminum 6061, 7075, 6082, 5083, etc.
Teräs
Steel, an alloy of iron and carbon, is a very versatile and rugged material. There are many different varieties of steel obtained after altering the amount of carbon in the composition. All these variations of steel are machinable. Some common examples are stainless steel, carbon steel, mild steel, etc.
Messinki
While brass is an expensive material, it also undergoes machining very often. Some common applications of brass machining are in art pieces and sculpting.
Titaani
Titanium is one of the hardest metals out there. Machining of titanium parts is done when the requirements call for the high strength and density characteristics of titanium.
Puu
WoodWoodworking machine shops have been prevalent for a long time. Machining of wood is commonly done for furniture making, carving, and many other applications.
Muovit
Plastics comprise a wide class in themselves. All varieties of plastics, including thermoplastics and thermosetting plastics, can undergo machining. Machining of plastics provides a higher precision than other methods such as injection molding or 3D printing.
Machining Terminology
Due to the technical nature of machining, people in the industry need to be aware of the terminology used in machine shops.
There are many different types of machining, so the complete list of terms is quite vast. Here are some commonly used terms:
Adapter: Adapts a tool of a particular size into a machine of different size requirementAllowance: Used to denote the difference in the measurements of two mating partsApron: The part of a machine (usually lathe) that contains and protects the gears, clutches, and other componentsAxis: The imaginary line that passes through the center of an object around which it can rotate. Used to denote the capability of a CNC machine (such as a 5-axis milling machine).Bearings: Used between moving parts to highly reduce frictionTool/Bit: Part made of titanium or hardened steel used for generating the cutting actionBurr: Sharp edges and corners on the final part after machiningChamfer: Curved surface cut on the edges or corners of a workpiece Coolant: Liquid filled in a CNC machine to reduce heat buildup and increase workabilityHeadstock: Fixed end of a CNC machineSetup: Tasks done before starting the machining, such as adjusting settings and mounting the workpiece.Stock: Materials used to make the final part
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