Metal Cutting in Fabrication and Machining

Metal fabrication and machining are subtractive manufacturing techniques. Subtracting or removing material from metal blocks or sheets must be done skillfully and precisely. Metal cutting may sound like a basic concept, but using the right equipment is critical to the outcome of the metal piece. In this post, we discuss metal cutting for fabrication and machining.

If you are looking for more details, kindly visit our website.

Metal Cutting for Fabrication

Cutting sheet metal is a fundamental process in metal fabrication. Before the sheet metal is bent must be cut. The initial cutting creates the piece’s outline from the sheet, called a blank. Additional cutting is then performed to make holes, notches, venting, and louvers. The metal cutting is done using CNC lasers, CNC punches, and shears.

At CMD, we have various pieces of cutting equipment to meet your fabrication and machining needs.

Hydraulic Shear
A shear is a mechanical cutting method used to cut straight lines and square edges of sheet metal. This is often the first step before moving on to other processes. It may also be used to cut large pieces into small, more manageable sheets.

A shear is a powerful machine driven by a hydraulic (or mechanical) force that rapidly lowers a cutting blade to a stationary lower cutting blade to sever the sheet metal. Shears are rated to cut materials of specific thicknesses and sizes so that the blades are not damaged. The metal is placed in the front-loading area, and a hold-down bar grabs it and secures it while cutting. A back gauge can be set at a specified distance from the shear blade to control the length of the cut and ensure repeatability.

Our shears include the following:

• Cincinnati 3/8″ – 10′ 36″
• Cincinnati 1/4″ – 10′ 36″
• HTC 1/4” Hydraulic 10’

CNC Punch
A CNC punch, very much like the name sounds, uses tooling to punch into the sheet metal. The CNC punch uses a program to tell it how to move on an X and Y axis to accurately position the sheet under the punching ram. Speed, location, and feed rate are controlled via digital communication and the machine’s specialized.

The pattern can be any shape and may be punched entirely through, like holes or perforations; partially punched through, like louvers and vents; or not pierced through the metal at all, like with embossing. For high-volume parts, punching can be very cost-effective. However, for lower volumes, tooling costs may make it cost-prohibitive. Your metal fabricator will help you determine the most cost-effective fabrication method.

Our punches include:

• Amada OCTO 30 Ton CNC 8 Station with Auto Index
• Whitney 50-Ton Duplicator
• Whitney 30-Ton Duplicator
• L&J Punch Press – 90-Ton

Laser Cutting
Another way that metal is cut is with a laser cutter. A highly focused monochromatic, collimated beam supplemented with gas generates intense heat that melts or vaporizes the metal, creating a narrow kerf (cutting path) as it moves. CO2 lasers use carbon dioxide, nitrogen, and helium mixture as media for laser amplification. The laser beam is created by electromagnetically stimulating carbon dioxide molecules, which pass through a series of mirrors that increases its intensity before it is passed through the nozzle.

The edges on a laser cut are smoother, and the setup costs are lower than with a punch. However, laser cutting can leave splatters on the surface that will be removed during deburring.

A laser cutter with flying optics keeps the sheet metal stationary, and the laser moves to cut the metal. A moving material laser moves the material, and the laser is stationary. The flying optics is faster and more versatile because the bulky material is not being moved.

Our lasers include the following:

• Amada F1 – Watt – Max Sheet Size 120 x 60 – Flying Optics
• Amada Gemini – Watt – Max Sheet Size 120″ x 60″ – Flying Optics
• Amada Punch / Laser – Watt LC C1 NT with Sheet Loader

Metal Cutting for Custom Machining

Since removing material from a metal block is an entirely different process, different equipment is used. Metal machining primarily involves mills, lathes, routers, and waterjet cutters.

CNC Lathe and Turning Centers
A CNC lathe uses a computerized program to precisely rotate the workpiece on a spindle against the cutting tools to perform various operations, such as cutting, knurling, or drilling. The rotating motion of the workpiece makes this process ideal for creating an object with symmetry about the axis of rotation. The key characteristic of a lathe is that material removal occurs rotationally. They are ideal for creating objects like spheres, cylinders, or cones or for making features such as drill holes, bores, and threads.

CNC turning centers are more advanced than CNC lathes. While a lathe is typically a 2-axis machine, turning centers can have up to five and offer more versatility.

Our lathes and turning centers include:

• Mazak QTN450MY 24″ Max Dia. x 120″ Long, 8″ Y-Axis 50HP, 10HP Live Tooling
• Haas SL-30 17” Max Dia. X 34″ Max Length 30HP
• Haas SL-40 25.5” Max Dia. X 44″ Max Length 15″ Chuck 40HP Live Tooling
• Hardinge Super Precision Quest 6/42 Live Tooling Sub Spindle
• Haas SL-20 10.5” Max Dia. X 20″ Max Length
• Bridgeport EZ Path Lathe – Full CNC or Manual Control
• South Bend Manual Lathe 12″ x 50″
• Victor Lathe 16” x 60”
• Hardinge HLVH Tool Room Lathe

CNC Mill
The key characteristic of a mill is that it performs operations in a linear fashion, but it can do so across multiple axes. The CNC mill also gets its direction for how to cut the piece from a program originating from a CAD file. Milling machines can work on 3, 4, or five axes, which provides flexibility depending on the part’s complexity. The milling machine can be horizontal or vertical. Horizontal mills have a horizontal spindle running parallel to the worktable’s surface, and the cutting tool rotates around a horizontal axis to remove material from the part. They have shorter, thicker tools for making deep heavy cuts. With a vertical mill, the head runs perpendicular to the worktable’s surface, and the cutting tool rotates in a vertical spindle to remove material from the workpiece. The cutting tools are long and cylindrical for making shallower cuts on smaller parts.

Tapping, drilling, boring, and reaming milling are common functions a CNC mill performs. They can also perform more complex operations like slot and keyway cutting, planning, and die sinking.

Our milling equipment includes:

• Haas Super Mini-Mill 16” x 12” x 10”
• Haas VF-1 (Vertical) 20” x 16” x 20”
• Haas VF-3 YT/50 (Vertical) 40” x 26” x 25”
• (2) Haas VF-4 (Vertical) 50” x 20” x 25”
• Haas VF-5/40TR Trunnion Mill 38” x 26” x 25”
• Haas VF-6/50 (Vertical) 64” x 32” x 30” 4th Axis Rotary
• Haas VF-7 (Vertical) 84” x 32” x 30” 4th Axis Rotary
• Haas VF-11 (Vertical) 120” x 40” x 30” 4th Axis Rotary – full Renishaw Inspection System on machine
• Haas VF-12 (Vertical) 150” x 32” x 30”
• Haas EC500 (Horizontal) 32” x 20” x 38” with full 4th Axis Rotary System – Pallet Changer
• Haas HS-7R (Horizontal) Machining Center 84” x 66” x 60” – 10,000 lb. table, 4-Axis
• Forest Line Seramil VMC X-236” Y-94” Z-47” 5-Axis Programmable, 2.5 Degree Indexing
• Acer Knee Mill with ‘X and Y’ NC Control
• Chevalier Knee Mill with ‘X and Y’ NC Control
• Forest Liné Modumill VMC X-275″ Y-157″ Z-59″ 5-Axis Programmable, 2.5 Degree Indexing

CNC Router
Like a mill, a CNC router cuts in a linear format but across a larger working area. A router operates at a higher speed than a mill but is primarily used to cut softer metals, such as aluminum. A router’s work envelope size can be quite large and often not enclosed.

Our router:

• AXYZ Pacer – 48″ x 96″, 2 Heads – 24,000 RPM

Waterjet Cutting
A waterjet uses a high-velocity jet of water to cut through metal. The CNC-controlled cutting machine forces water through a narrow diamond, ruby, or sapphire gemmed orifice at 60,000 Psi to 94,000 PSI, which cuts the metal. The gems are highly resistant to heat, pressure, and corrosion and have a low coefficient of friction, which reduces the possibility of heat being generated from friction and pressure. Sometimes abrasives are used to aid in the cutting process. A Waterjet can easily cut materials up to 12 inches thick.

A waterjet is a cold-cutting process widely preferred in applications where a heat-affected zone around the cut impacts the metal’s microstructure. Waterjet cutting is sometimes referred to as waterjet machining because it can perform the functions of a mill, but so it is faster.

Our waterjet

• Flow Waterjet – 93,000 PSI, 6′ x 12′ Bed

CMD Are The Metal Cutting Experts

Cutting operations are essential aspects of part fabrication in the manufacturing sector. One of the main techniques for metal fabrication is sheet metal laser cutting. It is suitable for cutting pieces of metals, alloys, and non-metals.

Sheet metal laser cutting is a thermal cutting process involving beams of light (lasers) on the workpiece to melt or vaporize materials until the desired shape is obtained. This technique is one of the most effective for cutting sheet metal.

This article provides you with essential information regarding laser cutting sheet metal before utilizing it. Let’s get right into it.

Laser cutting metal involves using laser beams to melt metals and alloys, thereby causing smooth, sharp cuts. The laser cutting process consists of two operations working in synchrony.

The first involves the material absorbing the focused laser beam – the energy that causes the cut. The second involves the cutting nozzle, concentric to the lasers, providing the process gas required for the cutting. The gas protects the processing head from vapors and splashes and helps remove excesses from the kerf.

There are essentially three methods for laser cutting sheet metal.

1. Laser Beam Fusion Cutting

The laser beam fusion cutting process uses an inert gas, mostly nitrogen. The low-reaction process gas continuously vaporizes the cutting gap of the material. As the molten material gets removed, inert gas prevents oxidation at the cutting edge without interfering with the process.

This laser cutting method is suitable for cutting flat, thin sheets of aluminum alloys and stainless steel that require high aesthetic appeal and fewer finishing operations.

2. Laser Beam Sublimation Cutting

As the name suggests, laser beam sublimation cutting evaporates the material. Instead of melting the material like other laser cutting processes, they are immediately changed from solid to gas – sublimation.

Like fusion cutting, laser beam sublimation cutting uses inert gases to blow the material’s vapor out of the kerf. So, there are no oxidants on the cutting edge. It is often used in cutting organic materials like wood, leather, textiles, etc.

3. Laser Beam Flame Cutting

Laser beam flame cutting uses a combustible gas – oxygen to thrust out the molten material. The laser heats the workpiece creating spontaneous combustion after melting the material. The oxygen gas provides more energy for the cutting process through oxidation – an exothermic reaction.

Flame cutting is ideal for cutting mild steel and fusible materials such as ceramics. This cutting process may cause burns on the cutting surface since the gas is an oxidant. Proper optimization of the process parameters will help prevent the formation of burrs.

Manufacturers usually use three different kinds of lasers for cutting materials. Each laser type has distinguishing features and is best suited to cutting specific materials. Below is an overview of the three types of lasers for cutting.

You will get efficient and thoughtful service from New Hope Laser.

1. Fiber Lasers

Fiber laser cutting machines use fiberglass for cutting. They generate very high power for powerful precision cuts. This laser belongs to a family of solid-state lasers from a “seed laser” enhanced by special glass fibers.

These lasers are suitable for cutting almost all materials, from metals to alloys, non-metals including wood, glass, and plastics. Besides cutting, they are ideal for other operations like annealing and engraving.

In addition, they are the most durable lasers, having an extended service life of more than 25,000 hours and requiring less maintenance.

2. CO2 Lasers

CO2 lasers produce laser beams by running an electric current through a tube filled with a mixture of inert gases, mainly nitrogen and helium. They are the most common laser forms because they are efficient and cost-effective and cut several kinds of materials at high speed.

However, they produce less cutting power compared to fiber lasers. Hence they are not an excellent choice for sheet metal laser cutting. Typically, manufacturers prefer to use them for cutting non-metals and organic materials like wood, paper, acrylic, etc.

3. Crystal Lasers (Nd: YAG or Nd: YVO)

Crystal lasers generate their beams from either Nd: YAG (neodymium-doped yttrium aluminum garnet) or Nd: YVO (neodymium-doped yttrium ortho-vanadate, YVO4) crystals. However, the latter is more common.

These crystals produce beams with high cutting power. However, they are expensive and not durable, having a low half-life of about 8,000 to 15,000 hours. They are commonly adopted for cutting plastics, metals, and non-metals, including ceramics.

Let’s examine the benefits of laser cutting sheet metal to the manufacturing sector.

1. High-Precision and Accuracy

Laser cutting is a suitable fit for sheet metal cutting because of its extreme precision. The machines are equipped with the ability to make intricate cuts at extreme precision and accuracy. Industrially, laser cutting is the go-to technique for cutting sheet metal with specific details requiring tight tolerances.

Some cutters can make precise cuts with an accuracy of up to 0. inches. This is why it has remained a mainstay in most manufacturing companies. Since the lasers melt away the metal parts, the cutters produce little or no burring. Instead, it leaves a clean, smooth, and sharp edge.

2. Automated Process

Laser cutting runs by Computer Numerical Control (CNC) systems. Once the technical operator inputs the programs into the computer, the process runs independently. Therefore, it requires less human interference and overall labor. Also, there’s little or no margin for error with increased cutting efficiency.

3. Damage Prevention

There’s this misconception that laser cutting metal causes warping. However, that is untrue. The heat from laser cutting only affects minute portions of the material, not affecting tolerance.

Moreover, the laser cutting process is quick; the lasers heat and melt away the portions to be removed. So, the heat does not significantly affect the other parts of the material. In most cases, there is no distortion or warping of your materials.

4. Compatible With Most Materials

Another critical advantage of this subtractive manufacturing method is its ability to work with an extensive array of materials. It easily cuts through each material, whether it is copper, aluminum, stainless steel, or even titanium. After all, it involves using lasers at very high temperatures to melt the material.

5. Relatively Low Cost

Indeed, laser cutting machines are expensive. However, compared to other CNC machines, it is more cost-effective. Moreover, it’s a single machine for all – that is, a single laser cutting machine is ideal for all your cutting operations. You do not need any machine modification for different cutting operations.

In addition, it’s durable. The device makes no contact with the materials you are cutting, so there is little, or no friction nor surface wear out. Also, it does not have multiple parts, so there are fewer maintenance and servicing requirements. In general, there’s a reduced operational cost of using a laser cutter compared to other customary manufacturing tools.

6. High Versatility

Besides the compatibility of laser cutting with most materials, the process is highly versatile. Unlike other devices, you can employ a laser cutter for several cutting functions, from simple to complex cuts and those requiring tight tolerances and intricate designs. This feature makes it an excellent choice for most industries.

7. Low Energy Consumption

Indeed, laser cutters require power to heat and melt materials effectively during cutting. However, the cutting technique is more energy efficient than other cutting methods.

In addition, unlike other machines, it has fewer moving parts, which means fewer energy requirements. Also, the machine’s high speed means quick cutting, saving time and energy.

The main disadvantages of sheet metal laser cutting include the following:

1. Requires Technical Operator

To effectively use a laser cutting machine, you need an expert who understands all its features and can quickly spot a problem to make appropriate corrections in time. If you do not set up the device correctly, you can damage your materials or the machine itself. So if you want to run a laser cutting service, you need to hire a professional.

2. Limitations to Metal Thickness

Laser cutters have excellent compatibility with most materials, especially sheet metal. However, you might consider other cutting techniques when working with thick metals. In most manufacturing industries, laser cutters cut aluminum sheets with a maximum thickness of 15mm and 6mm for steel.

3. Release of Harmful Fumes and Gases

We’ve established that laser cutting involves using heat to melt the materials it cuts. As the machine melts each material, it releases harmful fumes and gases into the environment. Therefore, using these machines in a well-ventilated room is best advised.

4. High Initial Investment

The cost of procuring a high-quality laser cutter is dear. It’s more than $, almost twice the price of other cutting machines, like the water jet cutters. To run a business with a laser cutter, you must be ready to make the upfront investment.

To meet the precision and quality specifications of laser cutting for your parts, adhere to the following guideline.

1. Choose the Right Materials

The choice of material is essential for any manufacturing process. The material you select for your part depends on the properties you want for the final product. Besides metal sheets like aluminum and zinc, plastics and other polymers are good options for part fabrication, depending on your needs. Some properties manufacturers look for when choosing a material include flexibility, malleability, ductility, rigidity, etc.

2. Design With Software That Creates Vector Files

Laser cutting machines only work with vector files. Therefore use software like Adobe illustrator to vectorize your designs. These files have formats like .ai, .step, .eps, etc.

3. Remember the Kerf

Kerf is the portion of the material that evaporates as the laser beam focuses on the workpiece. When designing your part, you must factor the kerf into your designs.

4. Details Shouldn’t be Smaller Than Metal Thickness

Metal thickness is an essential factor to consider with laser cutting service. The thicker your metal sheets, the less likely the lasers penetrate.

5. Minimum Distance Between Cutting Lines

Adequate spacing is vital for obtaining the best outcomes of laser cutting. The minimum distance in sheet metal laser cutting should equal your material’s thickness. For instance, if you are cutting a 2 mm metal sheet, you should leave a space of 2 mm.

Will Laser Cutters Damage My Materials?

No. Though many think the high temperature of laser cutting may damage materials. However, laser cutters are exact and work at incredible speed, such that the beam only melts out the parts you intend to cut. Also, the high speed means that your materials are not exposed to the high temperature for too long.

Should I Outsource or Get a Laser Cutting Machine for My Sheet Metal Parts?

Laser cutting techniques are essential for various manufacturing operations. It’s a highly effective process suitable for cutting most materials, especially sheet metals.

It is better to outsource your cutting operation if you run a small-scale manufacturing service. That is, hire a service for your laser cutting needs. It will help you cut costs, which can be channeled into other aspects of production. Contact Waken for your laser cutting and sheet metal fabrication needs.

Besides Laser Cutting, What Other Processes Can I Choose for My Project?

Laser cutting is not the only high-precision cutting method for industrial manufacturing. Should you choose not to use laser cutters for your fabrication or be conflicted on how to cut out shapes into your metal sheets? Below are excellent alternatives to choose from for your manufacturing requirements.

If you are looking for more details, kindly visit metal sheet cutting machine.

• EDM – Electrical Discharge Machining
• Water jet cutting
• CNC milling
• Punchng