3D laser cutting offers expanded opportunities but requires adequate technical solutions to obtain the desired quality and robustness of results.
Want more information on 45° Bevel Tube Laser Cutting Machine? Feel free to contact us.
The first laser for industrial applications appeared in 1964, emitting just 1 milliwatt (mW). By 1967, lasers with power exceeding 1,000 watts and the capability of cutting 1 mm thick steel sheet was possible. That is one million times more powerful than the first model!
Right from the start, the effectiveness of the laser in melting the metal made use of the aid of a service gas blown through a nozzle thereby removing the layers of molten metal hit by the light energy emitted by the source.
Find out more about laser cutting origins
Test piece cut with LS5 sheet laser cutting system. The dynamic control of the cutting parameters and the position of the focus allows the system to maintain the same cutting quality regardless of the complex geometry of the part: holes less than the sheet thickness, very thin cuts and cusps.
With the increase in power, over the years, the cutting thicknesses has increased to over 50 mm of steel with a 10 kW system.
Initially, the service gas was compressed air. Subsequently, oxygen was used for the oxidation reaction which significantly contributed to the heating and melting of the metal, enabling the melting of thicker materia.
Even more recently and with the increase in available power, nitrogen - an inert gas that does not contribute to heat generation - is widely used due to its characteristic of not thermally and chemically altering (oxidizing) the cut surface.
The advantage is machined parts can be painted directly without the need of further preparation.
Gear made with the LS5 sheet laser cutting system.
With respect to the entire manufacturing process, cutting cost is higher with nitrogen since nitrogen is more expensive than oxygen and requires much greater power to be used to maintain the same maximum workable thickness. Therefore, a higher initial investment will affect the hourly cost of the system and production costs.
The benefits of either choice can be assessed by using Protube software -the precise estimation tools of production times and costs. Manufacturers using laser cutting systems consider Protube to be an essential everyday tool.
Steel part from 35 mm thick steelwork, cut with a sheet laser cutting system using an 8 kW source.
Whether it is cut with compressed air, oxygen or nitrogen, in all cases, efficiency and quality of the result are connected to the way in which the assist gas is blown into the cutting groove: supplied pressure, but above all flow conditions. The more the gas maintains a linear flow with as little turbulences as possible, the more efficient the ejection of the molten metal from the cutting groove and consequently the quality of the cut itself.
With thick materials, the gas flow must penetrate deeply - in a narrow groove - and its flow inevitably becomes turbulent, before being ejected from the opposite side together with the molten metal. In recent years, technical solutions have been introduced to improve the process by widening the cutting groove to facilitate assist gas input and help to obtain the best linear flow possible.
Laser cutting head of LC5 flat-sheet & tube laser cutting system.
So far we have not specified from which direction the laser beam acts with respect to the cutting surface. The best possible direction is orthogonal (perpendicular) to the surface. In this configuration, the gas flow is centred and penetrates best into the cutting groove. There are no preferential sides nor pressure unbalancing effects due to turbulences around the groove, caused by the part of gas that cannot enter and therefore hits the immediate surrounding area. This is the configuration of all sheet metal cutting machines with rare exceptions. The laser moves on a flat, bi-dimensional (2D), surface and always cuts perpendicular to that surface.
The need to cut increasingly greater thicknesses at higher cutting speeds has been resolved over time with gradually increased power and with the ability to increase the laser beam diameter and therefore the groove width. Together this facilitates the assist gas performance and finishing of the cut edges.
Laser cutting of a metalwork sheet carried out with LS5.
Now, let’s move from sheet to tube cutting: the situation changes considerably. We are no longer faced with planar cutting trajectories but with a movement of the laser in space around an object- its thickness, and a profile including radii and edges, convex surfaces and concave angles, the later typical of the special sections.
The variation of the configuration between laser beam and tube surface has consequences on the cutting process and needs to be taken into account in order to ensure process efficiency. Therefore, the nozzle distance, focus position (where dynamically adjustable), the power required by the greatest thickness present, in correspondence with the radii, and consequently also the cutting speed, must constantly change. All this must work together to prevent burnt spots and cutting loss.
Find out more about the diffusion of metal tubes in manufacturing
Tube laser cutting carried out with Lasertube LT8.20 system.
To these factors we add the possibility to cut by tilting the head, so that the beam hits the surface in a non-orthogonal direction. We know this as 3D laser cutting.
This additional machining option present in machines equipped with a tilting head is especially useful for machining higher thicknesses. With the 3D cutting it is possible to make cuts with an angle up to 45°. For example, to obtain precise supports among several tubes or “chamfered” cuts to facilitate the subsequent welding phase because they create the space for the weld material. Even more challenging, but increasingly used, is the application of welding without filler material, possible when distance between edges to be welded is reasonably precise and constant.
If you are looking for more details, kindly visit Gantry Bevel Fiber Laser Cutting Machine.
Additional resources:
10 Things to Consider When Buying single flatform fiber laser cutting machine factory
Chamfering with LT7 laser cutting system.
However, such cuts pose difficulties and require specific technical solutions. The ability to tilt the head with respect to the surface to be cut in 3D causes the actual cut thickness to become greater than the nominal one, to a maximum bevel cut of 45 degrees, an angle at which a laser penetration depth must be taken into account and that of the assist gas which should be multiplied by square root of two.
It is also necessary to change the focus position, which poses an issue on parts with mixed 2D and 3D geometries. If focus position can be adjusted dynamically, all cases can be effectively covered by changing the focus height from one geometry to the other, otherwise it will be necessary to pre-configure a compromise focus height, with the consequence of a performance reduction in terms of cut quality or productivity.
Tubular part obtained with laser.
A further but significant effect of head tilting is the resulting geometrical inaccuracy of parts, unless suitably managed. The “kerf” that is the beam diameter and correspondingly therefore the width of the cutting groove, vary in function of the angle of incidence. This is a direct result of the shape of the laser coming out of the cutting head being conical and not cylindrical, thus determining the different imprint as tilt varies.
This parameter must be compensated for otherwise the part length will be altered and will not tightly align when matched to another part, thus hindering welding without filler material or jeopardizing the aesthetic result in the most critical cases.
The cut quality is affected by the manner the assist gas enters the cutting groove.
Support made between laser cut steel tubes.
As cutting inclination increases to the limit of 45 degrees with respect to the vertical plane, the gas meets the surface at an angle which is greater on one side compared to the other. On one side (obtuse angle) the gas will tend to slide on the tube surface instead of entering the groove, whereas on the other side (acute angle) it will trigger a greater turbulence. As a result, the gas will be less efficient and the process less stable.
Finally, let’s consider a last but no less important factor in 3D laser cutting- tube shape errors and tube axis deformation, either pre-existing or induced by the cantilever position of the tube during cutting. When the tube can be supported vertically during machining and measured to compensate for errors due to existing deformations, more precise parts will be obtained. Conversely, without these measures, wider tolerances and the expectation of higher reject numbers is to be expected.
Laser cutting of an “HEA” beam with LT14 laser-cutting system for large tubes and profiles.
So far we have learned what 3D laser cutting means, what advantages it offers and also the many technical aspects that must be managed in order to maximize the benefits this machine option has to offer. The experience and technical solutions integrated into the BLM GROUP Lasertube systems, provide our customers with a company that has been producing tube laser cutting machines for over 30 years and in 2003 were the first to introduce 3D cutting on a Lasertube. As the industry leader, we are a good starting point if you are evaluation of this option, in addition to the mechanical configuration of the machine which, however necessary, is not sufficient in itself to ensure the financial return of the greater investment required.
3D cutting - albeit constantly evolving - is a machining process not yet in widespread use but appreciated in specific sectors: where there are aesthetic needs in cutting thin materials, or where cost reduction targets are pursued in creating high thickness steel structural frame metalworks Investing in this direction means moving towards potentially interesting market niches with high added value. It is therefore worth relying on an experienced partner to assist you in evaluating the advantage of the investment, calculate risk margins and define a payback period.
These types of bevels are discussed in detail below:
1. Plain Bevel
A plain bevel describes an edge that is cut or shaped at a constant angle relative to the meeting surfaces and of generally constant width along its entire length. Plain bevels are extensively used in diverse applications for both functional and aesthetic purposes. For example, plain bevels can significantly ease the assembly or insertion of components by integrating self-location into assembly processes. Stress concentrations, spalling, and wear can be reduced by removing sharp corners or edges. This results from stresses being more evenly distributed onto the connected surfaces, minimizing the risk of cracks or edge-induced damage during assembly and operation.
Plain bevels can enhance the appearance of a part by adding visual refinement. They provide a finished and deliberate look to edges or surfaces. In many contexts, in particular, in tools or equipment whose utility involves unprotected human handling, a plain bevel can be used to remove sharpness and create a safer, blunted edge.
2. J-Prep Bevel
A J-prep (or J-groove) bevel is a particular example of a beveled edge joint preparation that is extensively used in more advanced and demanding welding applications. It is named "J-prep" because of its resemblance to the letter "J" in cross-section. A J-prep bevel is typically used for butt welds, where two materials or components are joined along a straight (or cylindrical) seam. The J-prep is beveled on one or both sides of the joint, while the other side may be left perpendicular to the joint line.
The J-prep bevel delivers some significant benefits in welding applications in higher value and higher failure risk manufacture. Some benefits include: providing an increased surface area for the weld, resulting in enhanced weld strength and integrity, facilitating deeper penetration of the weld formation into the joint ensuring greater and more comprehensive fusion between two or more parts, and enabling better access for visual inspection and quality control during the welding process and an easier assessment of completion after welding.
J-prep bevels are used in most heavy industries, including pressure vessels, reactor cores, critical infrastructure construction, shipbuilding, piping, and structural fabrication.
3. J-Prep with Back Bevel
A J-prep (or J-groove) with a back bevel differs from a standard J-prep only in that a simple angled bevel is applied to either the J-prep part or as a deeper feature on the second part to be jointed, to compliment the J-prep on the first part. The second or back bevel, is an additional bevel applied to one or both parts that improves penetration and access. The back bevel creates a slope or chamfer on the J-prep, opening the welding path with the additional bevel configuration.
The J-prep with a back bevel offers certain advantages in welding applications. Firstly, the combination of the J-prep and back bevel creates a larger weld volume compared to a simple J-prep bevel. The increased weld volume improves joint strength, weld penetration, and load-bearing capacity. The J-prep with a back bevel also allows the operator (or programmer in an automated system) greater control over the weld profile, allowing greater optimization of the weld bead shape and dimensions. Finally, The back bevel allows for better access to monitor the welding process and inspect the quality of the weld.
J-prep with back bevels are commonly used in the same industries as basic J-prep welds. The additional cost implicit in the secondary bevel process, however, is only worthwhile in higher value applications or ones in which inspection (and failure) in use carries a cost burden.
4. Compound Bevel
A compound bevel preparation details a beveled periphery or surface junction that is blended with two complimentary angled surfaces on each edge. They are used in various and unrelated applications, particularly in woodworking, machining metal components, and particularly for the visual appeal they create.
For example, in woodworking, these features are used in joinery on more advanced mitered corners or complex craftsman joints. They can create cleaner and more tight-fitting connections with better aesthetic qualities between wood components. In metal machining processes, compound bevels are occasionally utilized to create complex shapes, blending parts into tapered edges and curved surfaces, or forming attractive or technically advantageous compound angles on metal components.
5. Compound J-Prep with Back Bevel
A compound J-prep with a back bevel delineates an additionally complex form of joint preparation in welding applications. This combines the features of a J-prep bevel and a back bevel with multiple angles and slopes. Either on the J-prep bevel, on the obverse side of the joint from the J-prep, or on both edges, there is included a compound back bevel with two progressive bevels applied. This combination results in a compound joint profile with multiple angles and slopes.
The combination of the J-prep and back bevel provides a yet larger weld volume, in comparison to the simpler forms of J-prep bevel. This improves joint strength and load-bearing capacity. The multiple bevels of the compound joint configuration allow for even deeper penetration of the welding material. The compound J-prep with back bevel also allows for better control over the weld profile, enabling skilled welders to impose a desired weld bead shape and dimensions. Finally, the compound joint configuration can assist in distributing stress more evenly along the joint and outwards into the substrates, minimizing the risk of failure or stress cracking.
Compound J-prep with back beveling is most applicable where enduring weld joints in stressed conditions are crucial and often life-critical. The system is widely used where lifetime inspection opportunities are difficult. Examples are: reactor systems (chemical and nuclear), pressure vessels, critical infrastructure fabrication, shipbuilding, piping, and heavy machinery manufacturing.
What Are the Benefits of Bevel in Pipe Ends?
Beveling pipe ends offer various benefits in many applications in the context of pipe welding and installation, safety, and aesthetics. Some benefits are listed below:
- The beveled edge ensures better integration, by allowing fusion to occur through a greater depth of the joint. Providing a larger weld area that opens the depth of the joint enhances weld quality and strength.
- Ensures eased assembly and alignment, prior to the welding commencing. This close integration and deeper penetration improve joint integrity, resulting in lower leak levels, reduced defects, and less post-welding work.
How Does a Bevel Compare to a Fillet or a Chamfer?
Bevels, fillets, and chamfers are the range of edge treatments used in diverse applications. While they are closely related, they offer distinct characteristics and serve divergent purposes. A bevel is a sloping or angled surface (or sequence of surfaces). It is created by cutting or shaping an internal or external corner at an intermediate angle that generally (but not necessarily) halves the natural meeting angle of the faces that form the corner. Bevels are often used to remove sharp edges, facilitate assembly, improve weld penetration/access, and provide a desired aesthetic. To learn more, see our guide on Fillet vs. Chamfer.
Figure 2 is an example of a bevel:
For more Large-format Laser Cutting Machine supplierinformation, please contact us. We will provide professional answers.
Comments
0