The firearm industry has made major advancements in production. The progression of this industry can be traced back to the precision machining process. From surface finish to tool life to material used, machining firearm components relies heavily on efficiency and accuracy.
Previously, when machining firearms, some processes were manual or utilized numerous different tools; however, as tooling innovations have developed, the process of machining has evolved. Often, tools now are far superior to those used in previous firearm production methods. This provides the opportunity to combine operations into a single cutting tool, eliminating the need for additional tooling in the machine shop.
In addition, new innovations in tooling provide manufacturers with a better output like improved surface finish or decreased cycle time.
Standardizing the industry
Nevertheless, there is still a need to work toward standardizing tooling in the firearm industry. While manufacturers often have their own take on radius, angle change, and other parameters, standardization is becoming more common. For example, a standard reamer could be used for all 1-in. diameter holes in an AR upper receiver; however, there could still be a delay in acquiring the tools if specific reamers are needed because of the needs of different specs.
Holemaking and hole finishing are part of the machining process for numerous firearm components. One example of this would be revolver cylinders, which in some cases require a three-step process: pre drill, pre ream and finish ream. Form is critical throughout these applications because it must match the bullet casing. Other firearm components that need holemaking and hole finishing applications include AR upper receivers, gas blocks and bolt carriers, which house the firing pin and bolt itself.
In deciding what type of material to use in firearm components, manufacturers must consider a few characteristics: weight, strength and aesthetic. Consider steel as an example. It is durable and versatile, making it easier to manipulate into the small parts needed within firearms, yet it is a heavier material. While this does present some challenges, it also provides better control and repeatable accuracy. Conversely, when using aluminum, strength and durability are compromised for the benefit of less weight; therefore, it is best to consider a type of aluminum alloy.
Ultimately, the materials used must be reliable because of the stress they are put under, the heavy usage and the strict requirements of the industry itself. While firearms are often heat treated, it is best to complete holemaking applications prior to this; after being heat treated, the material is typically too hard for drills because it is as if machinists are asking two like materials to get along. Instead, the drill should be harder than the material you are drilling; something that is challenging to achieve.
Tool life is vital
Whether it is alloys, titaniums or another high-grade exotic material, tool life is vital in the holemaking and finishing applications. One of the key needs of manufacturing firearms is sequential, repeatable processes; thus, tool life is needed to maintain optimal production cycles. Although tool life issues like dulling or breaking can sometimes be easily resolved by switching to a different geometry or coating, there are times where greater changes need to be implemented. Chatter, for example, can cause poor tool life, so manufacturers would need to evaluate their fixturing, work holding or machine maintenance in general. Performing machine maintenance or replacing tooling ultimately impacts production time, so it is best to utilize rigid machines and high-grade materials when possible.
Surface finish is one of the most important elements when machining firearm components such as bolt carriers, upper and lower receivers, and silencers. More specifically, surface finish is key for firearm chambers because of the need to accept the incoming cartridge, which determines the accuracy of the rifle and the load being fired on target. When drilling or reaming, surface finish is critical—the smoother the surface finish the less friction and less wear. Clearly, there needs to be a smooth and consistent finish free of burrs; otherwise, this becomes a fracture point. Ultimately, surface finish impacts the functionality of the machined firearm while negatively impacting the life of the barrel as well.
At the same time, there needs to be consistent wear coming from the finishing tools and on the finished part itself so that there is no excessive friction or wear. Here, CNC operations provide the most accuracy and consistency while creating a process that can be easily replicated. Not only do manual processes produce an inconsistent surface finish, but they also are more costly to production and the well-being of the operator—both of which impact product quality. Therefore, CNC machining improves the performance and life of the firearms because of the ability to remove microscopic peaks and valleys in the material.
Machining firearms clearly requires precision and efficiency. Whether drilling or reaming, it is necessary for machine shops and manufacturers to develop a process that is repeatable, sequential and effective in producing the high standards—like that of surface finish—needed in the firearm industry.
For technical support in holemaking or finishing applications in the firearm industry, phone 330-343-4283 ext. 7611 or visit www.alliedmachine.com.
Related Glossary Terms
Substances having metallic properties and being composed of two or more chemical elements of which at least one is a metal.
Condition of vibration involving the machine, workpiece and cutting tool. Once this condition arises, it is often self-sustaining until the problem is corrected. Chatter can be identified when lines or grooves appear at regular intervals in the workpiece. These lines or grooves are caused by the teeth of the cutter as they vibrate in and out of the workpiece and their spacing depends on the frequency of vibration.
- computer numerical control ( CNC)
computer numerical control ( CNC)
Microprocessor-based controller dedicated to a machine tool that permits the creation or modification of parts. Programmed numerical control activates the machine’s servos and spindle drives and controls the various machining operations. See DNC, direct numerical control; NC, numerical control.
- precision machining ( precision measurement)
precision machining ( precision measurement)
Machining and measuring to exacting standards. Four basic considerations are: dimensions, or geometrical characteristics such as lengths, angles and diameters of which the sizes are numerically specified; limits, or the maximum and minimum sizes permissible for a specified dimension; tolerances, or the total permissible variations in size; and allowances, or the prescribed differences in dimensions between mating parts.
Rotating cutting tool used to enlarge a drilled hole to size. Normally removes only a small amount of stock. The workpiece supports the multiple-edge cutting tool. Also for contouring an existing hole.