What is Plain Milling?
Plain milling (also known as slab milling) is a subtractive manufacturing process which means it involves removing portions of material from a workpiece to form the desired product.
However, unlike the conventional subtractive manufacturing process, the process requires that the rotating axis of the cutting tool is parallel to the surface of the workpiece.
In plain milling, the workpiece is usually fixed on a worktable.
This worktable moves and feeds the workpiece against the cutter, allowing machinists to create a plain, flat, and horizontal surface parallel to the axis of the cutting tool.
How Does Plain Milling Machining Process Work?
The plain milling process involves the following steps.
1. Choosing A Suitable Tool.
The first step in the plain milling process is choosing a suitable milling cutter. Heavy-duty cutters are perfect for substantial material removal while light-duty cutters remove a small quantity of material.
Also, light-duty cutters operate at a lower table speed and high tool speed and vice versa. Once you’ve selected the appropriate cutter, it is fitted on the milling machine spindle.
2. Workpiece Setup.
Next, the workpiece is secured on the milling machine. This can be done using a universal vise or an adjustable angle plate.
Correct positioning of the workpiece allows for precision and accuracy in the milling process.
3. Cutting Parameters.
The quality of the end product depends on several factors namely spindle speed, milling feed rate, and depth of the cut.
Suitable cutting parameters will depend on the workpiece material, tool capabilities, and desired finish.
4. Speed.
If the cutter is rotating too fast, it may get destroyed or produce a rough surface finish. On the other hand, slow cutting speeds may mean an inefficient machining process.
5. Milling Feed Rate (Table Feed).
The feed rate refers to the velocity at which the cutter advances against the material. The tool must advance at the right pace to generate consistent and precise cuts.
6. The Depth Of The Cut.
Refers to how deep the tool is pushed into the workpiece with each pass. This parameter affects the performance and efficiency of the machining operation.
7. Milling Operation.
Once the milling machine gets going, the cutter will rotate at a specific speed known as the spindle speed.
The plain milling cutter removes material from the workpiece producing precise shapes and dimensions of final products.
Depending on the orientation of the tool, milling machines are classified into vertical and horizontal milling machines.
In a horizontal milling machine, the spindle is parallel to the worktable. Conversely, a vertical mill has a spindle that is perpendicular to the table.
Types of Plain Milling Cutters
The plain milling process is more about the cutters than anything else. It is the distinguishing factor between the milling types.
In this section, we will discuss two types of plain milling cutters: heavy-duty and light-duty plain milling cutters.
Heavy-Duty Plain Milling Cutters
These types of cutters provide a better helical angle than light-duty cutters, and they also have fewer teeth.
Heavy-duty cutters are mostly employed on either vertical or horizontal machines with a rigid setup for more precision.
The helical angle of this type of milling cutter ranges from 25 to 45 degrees. It is suited to removing larger amounts of material than light-duty cutters due to their fewer teeth.
What’s more, the feature of heavy-duty plain milling cutters gives a coarser cut, which is better for heavier materials.
Thus, this cutter mainly gives a better shaping finish while reducing the amount of vibration.
Light-Duty Plain Milling Cutters
These light-duty milling cutter tools have more teeth but a lesser helical angle. Therefore, they come in handy for smaller milling machines used to achieve a finer finish.
This means that they function best when there is a smaller removal of material and higher precision needed. Light-duty cutters give more precise control and a smoother surface finish.
Choosing a Plain Milling Cutter
So, is it to choose the right plain milling cutter? The simple answer is yes. Your chosen cutter will affect the efficiency of the milling operation as well as the quality of the finished products or parts.
The choice between light-duty cutters and heavy-duty cutters depends on the specific plain milling job.
Heavy-duty milling cutters have fewer teeth and are ideal for removing a large amount of material.
They are suitable for cutting operations where the workpiece’s surface finish is not a primary concern.
Conversely, light-duty cutters are appropriate for removing small quantities of material and milling operations that prioritize a fine surface finish.
The plain milling cutter material is also an important factor to consider. High-speed steel tools are a cost-effective option that is less susceptible to tool wear.
Cutting tools made from rigid materials, such as cemented carbides and cutting ceramic, are perfect for high-performance plain milling operations.
Tips for an Effective Plain Milling Process
For an effective plain milling process, here are some considerations necessary for a successful plain milling process.
Please note, ensure that there is good stability and fixation in the workplace before you begin any plain milling process. Use clamps, vices and fixtures to prevent shakes and vibration during plain milling.
Maintain Components is Necessary
It is essential to maintain and sharpen the cutter used in the plain milling process before and after the procedure.
This practice helps to prevent workpiece damage, minimize wear on the tool, and ensure precise cutting.
Adjust the Cutting Speed, Feed Rates, and Depth of Cut
It is important to always adjust these parameters to optimize the results. Adjust the cutting speed of the plain milling cutter to suit the workpiece material, ensure the feed rates match the cutter design, and set the depth of cut to suit the desired finish.
Avoid Milling Defects
The best way to maximize efficiency is to avoid plain milling mistakes. Thus, ensure to always adjust cutting parameters to suit the material, and use stabilizing tools and setups to prevent vibration and tool deflection.
Advantages of Plain Milling
#1. High Precision and Accuracy.
One of the foremost benefits of Plain Milling is its ability to achieve high precision and accuracy. The process allows for tight tolerances and fine finishes, making it ideal for creating parts that require exact measurements and smooth surfaces.
This precision is crucial in industries like aerospace and automotive, where even the slightest deviation can have significant implications.
#2. Versatility.
Plain Milling is incredibly versatile. It can be used on a wide range of materials, from metals to plastics, and can produce various shapes and sizes.
Whether it’s a simple flat surface or a complex geometric shape, Plain Milling can easily handle it.
This versatility makes it a go-to process for many sectors, including electronics, medical devices, and industrial machinery.
#3. Cost-Effectiveness.
Despite its high precision, Plain Milling is also cost-effective. The process is efficient, reducing waste, saving time, and lowering production costs.
This cost-effectiveness is especially beneficial for large-scale manufacturing, where even minor savings can add up to significant amounts.
#4. Compatibility with CNC Technology.
Plain Milling integrates with CNC technology, allowing for automated and highly accurate machining.
CNC Plain Milling enhances precision, consistency, and speed, making it possible to produce complex parts with minimal human intervention.
This compatibility with modern technology is a huge plus in an era where automation and efficiency are key.
#5. Reduced Manual Labor.
With the integration of CNC technology, Plain Milling reduces the need for manual labor.
This speeds up the manufacturing process and minimizes the risk of human error, ensuring that each part is machined to perfection.
#6. Improved Surface Finish.
The process can produce surfaces that are smooth to the touch, which is essential for both functional and aesthetic purposes.
This level of finish is fundamental in consumer goods and medical devices, where the end-user experience is paramount.
Applications of Plain Milling
Plain milling is used in many industries in the production of tools and to speed up overall operations. Industries like aerospace, automotive, construction, and medical devic all benefit from this milling process.
#1. Aerospace Industry.
Plain milling comes in handy for the production of aircraft parts in the aerospace industry. For example, fuselage sections, wings, and engine blocks are products of plain milling.
It also helps in the manufacturing of gears, curved heads, and structures that make up the aircraft.
#2. Automotive Industry.
Plain milling is one of the bedrock operations in the automotive industry as it helps in the manufacturing of automobile parts.
The process helps in the high-volume production of engine components and finishing fibers. It also helps to produce gearboxes and cylinder blocks.
#3. Construction Industry.
The production of large structural parts in the construction industry is done with the plain milling process.
Components like plates, beams, and metal rollers are all products of this high-precision process.
#4. Medical Industry.
The plain milling process is used in the manufacturing of many medical devices. The high precision of the process is required when making most medical instruments and implants.
Comparing Plain Milling With Other Milling Processes
Plain milling is a popular machining technique used in manufacturing both metal and non-metal parts.
Besides slab milling, other milling processes also use rotary cutters to remove material from a workpiece.
Understanding the different milling operations is crucial when choosing a suitable process for a specific project.
Plain Milling vs Face Milling
As we’ve already discussed, plain milling is used in machining a flat surface parallel to the cutting tool axis.
Contrarily, in face milling, the flat surface is perpendicular to the spinning axis of the cutting tool.
Due to this orientation, plain milling allows for more of the cutting edge to be in contact with the workpiece surface.
Therefore, this technique is suitable for removing a large amount of material while face milling is ideal for fine surface finishes.
Plain Milling vs Slot Milling
As the name suggests, slot milling is a process used in creating slots in workpieces. These slots come in different shapes and sizes and this determines the proper milling cutters.
For example, T-slots and dovetail slots will have different tooling requirements.
The main difference between slot and slab milling is that the latter focuses on flat surfaces while the former is specific to different types of slots and grooves.
Plain Milling vs Form Milling
Form milling is a machining process that involves creating irregular contours using formed milling cutters.
These contours may consist entirely of curves or both curves and straight lines.
Unlike plain milling which is all about flat surfaces, form milling caters to unique designs and contoured shapes.
Also, form milling cutters are typically 20 to 30% slower than surface milling cutters.
Plain Milling vs End Milling
End milling is a specialized milling technique in which the cutter has cutting edges on both its periphery and tip.
While plain milling is the go-to process for flat surfaces, end milling is used to machine features such as slots, grooves, profiles, contours, and mixed forms.
Plain Milling vs Gang Milling
Gang milling is a machining technique that uses two or more milling cutters simultaneously.
Therefore, in a single pass, this process is capable of machining multiple surfaces of a workpiece.
Gang milling utilizes a range of cutters including end mills, face mills, and even plain milling cutters.
With plain milling, a single cutting tool is used in machining a workpiece’s surface.