| |
Types of Laser Cutting
- is
a process that uses an intense laser beam to cut part shapes out of
sheet material. The parts remain flat because the heat distortion is
minimal.
- is a process that uses carbon dioxide as the main
lasing medium. CO2 lasers use a mixture of gases—such
as helium and nitrogen, with CO2 being the most predominant—to
create a cut quality similar to that of milled edges of mild steels
and can operate in continuous wave (CW) or pulses.
- is
the process of ablating target materials, typically low vaporization
temperature and low thermal conduction materials, through direct vaporization.
- is
a process that uses the noble gas compounds for lasing. Excimer lasers
generate light in ultraviolet to near-ultraviolet spectra.
- is
a process in which gas is used as the activating agent.
- provides cut edges covered with melted and
resolidified metal comprised of the same metal mixture of the material.
Thus it has the same resistance to corrosion and is useful for food
processing facilities, chemical plants and sign production.
- include
all of the processes that use industrial lasers to cut metal or other
materials.
- is
the process of creating a hole in material with a laser beam.
- uses
lasers to etch into a surface.
- is
the process of marking the material without cutting all the way through
using reduced power.
- is
the removal of material brought about by laser material interaction.
Laser machining is a term that includes laser drilling, laser cutting,
laser grooving, laser marking or laser scribing.
- is
a process in which material is indelibly marked at very fast speeds
(milliseconds per character). Laser marking is flexible, programmable
and environmentally clean.
- is
the process of using a laser beam to connect two or more pieces of
metal together by melting the areas to be joined and allowing them
to resolidify.
- is
the process in which large organic dye molecules are used as the active
lasing medium.
- ,
also known as “fusion,” is the laser cutting process that
creates a melt, which a gas jet blows out of the melt zone, typically
with air. The resultant cut edge is of high quality but is covered
with microscopic ripples.
- is a process in which mirrors are used to reflect
the laser beam to the cutting head while the work piece material
remains fixed.
- is
a kind of laser cutting utilizing multiple axes instead of one. The
advantage of multi-axis laser cutting is the capability of cutting
three-dimensional shapes, while the disadvantages are the higher expense
over flat bed cutting, longer set up times and increased safety hazards.
- is
a process in which the oxygen does the actual cutting, and the laser
beam maintains the reaction.
- is
a cutting process that uses single or train pulses, as opposed to continuous
wave lasers. These pulses supply greater power at shorter intervals.
- is a process utilizing semiconductor materials as
the active medium.
- is
a process in which the active medium of the laser (typically not semiconductor
lasers) is in a solid state.
Laser Cutting Terms
–
The elimination of material with an industrial laser by evaporation, vaporization
or melting.
– A steel alloy
containing a primary iron component minus any other metals necessary to
make stainless steel.
– A device consisting
of a series of hollow tubes and mirrors that supplies the beam in a CO2
laser.
– A gas used to facilitate
the cutting process and to blow melted material through the cut area.
Oxygen is usually utilized for cutting ferrous metals, and any inert gas
produces oxide-free cut edges.
– The decrease in
radiation power or energy as the beam is passing through a scattering
or absorbing medium.
– A group of rays that
may be convergent, divergent or parallel.
– The diameter
of a circular beam at a particular point in which the intensity lowers
to a fraction of its maximum value.
– The spread
of the beam angle, expressed in milliradians. One radian equals 3.4 minutes
of arc or nearly 1 mil.
–
A computer that controls the machine's movement. CNC controls motion tables
or position the work piece beneath the focused laser beam. (http://www.cnc-machining.biz)
– Carbon or mild
steel made with coatings like zinc plating, mill scale, paint, rust or
identification marks. Reduced cutting speeds and more dross on the bottom
of the cutting edge are the result.
– The capability
of a laser beam not to spread significantly (low divergence) with distance.
– An optical device
consisting of two lenses separated by the sum of their focal length that
is used to provide a desired beam diameter to meet beam delivery specifications.
– The continuous-emission
mode of a laser, as opposed to the pulsed operation mode.
– Metals
that exhibit an extreme reflectivity to laser light and have high thermal
conductivities. These two characteristics lower the cutting speeds and
the highest thickness of material that can be cut.
– A solid crystalline
material with a regular array of atoms utilized as laser sources.
– Also called
“piercing,” it is the use of the laser in the pulsed mode
for hole drilling with air or oxygen as the assist gas.
– A characteristic
that determines the size of the material to be cut. Bed sizes are commonly
4' X 8' and some are as big as 5' X 10'.
– A measurement that
is dependent on the properties of the material cut, the lens focal length
and the type of gas in the laser. The width of a cut from a laser will
usually be between 0.1 and 0.4 mm.
– The amount of time
required for the completion of the laser process.
– The operating
span of the focused laser beam calculated as a function of the focal length
of the lens, the wavelength and the diameter of the unfocused beam. A
shorter focal length gives a smaller depth of field.
– Undesirable variations
of either amplitude or frequency of laser output.
– Solidified melt on the
lower edge of the laser cut. Higher amounts of dross result from surface
rust, poor quality steel and incorrect process parameters but can be reduced
by increasing the oxygen pressure and pulsed laser cutting.
– The actual length
of time that the laser beam is cutting, drilling, welding or heat-treating,
as compared to the cycle time.
– A laser
or laser system closed off to prevent hazardous optical radiation from
escaping the enclosure.
– The rate at which
the cutting head moves.
– The position of
maximum energy concentration of a focused laser beam. Focal point is determined
by measuring where the laser beam has the least diameter and the refracted
light rays of a lens conjoin.
– A coaxial assist gas utilized to attain
extreme power levels required for cutting particular metals, usually nitrogen,
oxygen and argon.
– A device that blows
gas into the cutting zone to clear away molten metals or other materials.
At times, the gas reacts chemically with the work piece to create heat
and increase the cutting speed.
– A
small area next to the cut zone that undergoes changes in material properties
as a result of heat conducted into the work piece as it is cut.
– An interference phenomena
captured on a plate or film that can contain large amounts of information
and from which 3D images can be constructed.
– The slit, notch or groove
produced by a laser cutter or the width of such a cut. The kerf is reliant
on the work piece thickness, the properties of the material, the lens
focal length and the kind of cutting gas in the laser.
–
Kinds of steels particularly manufactured for laser cutting applications.
These steels maintain the strength of standard materials, but with reduced
amounts of impurities like sulphur and silicon, and can be cut to a greater
highest thickness at faster speeds.
– Also called
“laser cavity,” it consists of the optical mirrors, pumping
system and active medium. Laser resonators can be stable or unstable based
on whether the oscillating beam converges into the cavity or spreads out
from the cavity
– A legal phrase
indicating a laser or laser system or any other product that integrates
or is intended to integrate a laser or laser system.
– An optic that is either
refractive or reflective and affects the convergence of rays of light
at a point. The depth of focus and power density of a lens can change
with differences in laser beam diameters.
– The temperature
at which a material melts. Materials having high melting points must be
cut more slowly with a laser, since more energy is needed to melt them.
– A method that
creates very short laser pulses by making the phase differences of many
modes or frequencies in the laser cavity fixed (locked).
– Lasers that
provide high-power, short pulses for particular industrial applications.
– Lasers that are like Nd:glass lasers
in that they are both pumped by flashlamp and beam transmissions through
fiber optics, but the ND:YAG laser light can achieve finer detail work.
It is also better than the CO2 laser on highly reflective material.
– A component of the
gas jet in laser cutting that constricts the assist gas and directs it
to a columnar flow.
– Laser output
per unit area, expressed in watts per square centimeter (W/cm2).
– A single, irregular
burst of a laser, in contrast to a continuous beam. True pulses attain
greater peak powers than what a continuous wave output can do.
– The speed
at which pulses are produced, expressed in pulses per second.
– The degree to
which a material reflects laser light. Extremely reflective material such
as aluminum and copper alloys are harder to cut, necessitating lowered
work speeds.
– A sheet of base
material that may or may not have an interconnection pattern.
– Laser
whose pulse duration time is below one nanosecond.
– The conversion
of a solid or liquid into a vapor. Lasers vaporize the metal or material
they are cutting.
|
|
