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THE ENGINEER’S DESIGN MANUAL
for LASER PLASTIC WELDING
PART 1 – ABSORBING POLYMER LASER WELDING

TABLE OF CONTENTS
Introduction Page 3
Overview of Traditional Joining Technologies Page 4
Advantages of Laser Plastic Welding Page 5
APLW Method Page 6
The 4 Pillars Pages 7-11
Materials Page 11-13
Joint Design Pages 14-18
Clamping Technology Pages 19-25
Beam Properties and Delivery Pages 26-28
General Design Guidelines Pages 29-33
Common Pitfalls Page 34
Typical Project Roadmap Page 34
FAQ Page 35
Material Matrix Page 36
TABLE OF CONTENTS

The goal of this Design Manual is to educate designers and engineers on through-transmission laser welding
technology, give them the keys to design their products for the Laser Plastic Welding method, and to
disseminate general knowledge about this technology in an unbiased approach.
This manual is Part 1 of a 2 Part series: Part 1 – Absorptive Polymer Laser Welding (APLW) and Part 2 –
Transparent Polymer Laser Welding (TPLW). The two technologies are somewhat similar but have enough
differences to create the need for a separate approach. It is highly recommended to read through the APLW
manual before moving onto the TPLW manual as only the differences in the TPLW method will be covered.
IMPORTANT—please keep in mind this is purely a set of guidelines. Every application will require its own,
nuanced approach and some—or all—of your application’s requirements may fall outside of the scope of this
guide.
Before you make any design adaptations or changes to mold tooling, etc., I highly recommend you consult a
laser welding expert for a complete review of your application design and production needs. You can find out
more about this service here: www.daxham.com/services.
To your success,
Dax Hamilton
Laser Polymer Welding Expert
+1.503.686.4684 | info@daxham.com
THE GOAL OF THIS MANUAL
INTRODUCTION

While Laser Polymer (Plastic) Welding really isn’t a new technology, it is still
not quite as well-known or widely adopted as legacy joining solutions, such
as gluing, fasteners, snap fits, and ultrasonic welding. It is interesting to
note that the German automotive industry was one of the first to adopt this
technology around 19 years ago. In spite of the fact that it was—and still
is—a revolutionary technology, it took many years for other industries to
adopt it.
While traditional methods have their place, it is a good idea to look at how
implementing laser plastic welding could be beneficial and overcome some
of the highlighted issues. The below list is only a few of the most common
methods that laser welding has its advantages over:
SNAP FEATURES
• Require complex injection mold tooling
• Extra space is typically required in the part.
FASTENERS
• Require added cost
• Creates extra, superfluous features in part
GLUE
• Messy and difficult to automate
• Lacks precision
• Often requires lengthy drying periods
ULTRASONIC WELDING
• Significant rate of damage
• Not good for sensitive electronics
• Potential to mar visible surfaces
OVERVIEW OF TRADITIONAL
JOINING TECHNOLOGIES

Laser Polymer Welding delivers the following advantages (among others
of course):
• Precise control of the welding area
• Aesthetically pleasing weld seams – visually OK on “class A” surfaces
• Ability to hold tighter tolerances in the joining process
• No damage to surrounding materials or sensitive electronics
• A perfectly hygienic method of bonding – no particulates generated
• Ability to miniaturize designs
• Joining of 3D and complex shapes
• Removal of costly and cumbersome part features
• Eliminate consumables – fasteners, glue, etc.
• Drastically improve quality
• Bonding strength virtually as strong as the base material
• Lower total cost of ownership – thinking holistically
Laser Polymer Welding picks up where other joining
technologies leave off…
If there is a need to eliminate quality problems and miniaturize designs,
all while avoiding damage to sensitive electronics then Laser Polymer
Welding is the right choice for your design!
ADVANTAGES OF LASER POLYMER
WELDING
With that said, if the current joining technology is working well for the
application and there are no specific issues that are prevalent, then laser
welding may not be the best approach due to the relatively high cost to
implement it over one of the traditional bonding methods. As system
builders become more advanced, the cost to implement will go down.

There are several terms that have been coined for this subject to-date; “laser plastic welding”, “plastic laser
welding”, “through transmission welding”, laser transmission welding, and “laser polymer welding”, (which will
all be referred to synonymously throughout this manual), however, the main concept is the same … A method
of joining two plastics by subsequent transmission and absorption of laser energy.
APLW METHOD:
ABSORPTIVE POLYMER LASER WELDING
Another way to describe it: laser plastic welding is a
cutting-edge means of joining two thermoplastics
together via a laser beam in the near-infrared
spectrum.
In the case that two plastics are clamped tightly
together, the laser beam penetrates the upper layer
and is absorbed by the lower layer which in turn is
heated by the laser energy and transfers this heat to
the upper layer which results in both of the plastics
melting and mixing to form a bond that is virtually as
strong as the base material.

There are four, main guiding principles to this method of laser plastic
welding. While many other design and engineering factors can affect the
ability to laser weld a component, these four pillars are absolute
requirements for all laser plastic welded applications.
HOW IT WORKS
When two plastics are clamped tightly together, a laser beam in the
1000nm range penetrates the upper layer and is absorbed by the lower
layer which in turn is heated by the laser energy and transfers this heat
to the upper layer resulting in both of the plastics melting and mixing to
form a bond that is virtually as strong as the base material.
THE 4 PILLARS OF APLW

The first layer of material that the laser beam shines through (IR
Transparent Layer) must allow a certain portion of the laser energy to
pass through. It is widely recommended that at the very least, about 5%
of this energy passes through to be able to effectively heat the lower
absorbing layer before degradation or burning occurs in the IR
Transparent Layer.
There have been some applications where less than 1% of the energy
passes through but special welding parameters need to be used in order
to create a stable process and avoid any surface degradation or burning.
Of course, there are various misconceptions about the term
“transmissive and/or transparent” when it concerns laser plastic
welding. The first is that the material does not have to be clear or
transparent to the human eye, it just needs to pass the respective
wavelength of the laser. Most consumer electronics devices and
automotive components don’t employ the luxury of having a “clear”
transparent layer and need to be opaque in whatever color the
designer/stylist/marketer selects. In most common laser polymer
welding applications, the wavelength used is around 980nm, (1 micron)
which is supplied by a solid state semiconductor diode laser source.
PILLAR #1
IR TRANSPARENT UPPER LAYER
Pro Tip:
To provide the widest flexibility in weld parameters—and therefore ease
of success—a transmission rate of at least 5% is recommended. However,
it is possible to go as low as 1% in certain circumstances.

The absorbing layer of plastic serves as the most important layer of the
two. This is because the inception of the welding process happens at
this layer. As the laser contacts this layer, the plastic heats up to the
point where this heat is transferred to the upper layer and both plastics
melt and mix as long as there is tight mechanical contact between the
two. Part of this is due to thermal expansion of both plastics as they
heat and expand into each other, ensuring a good mixing of the
materials at the joint interface.
In order for the process to work, the absorbing layer needs to be doped
with a compound that absorbs the infrared laser energy. The most
common dopant is carbon black, and is doped in at 0.5% - 1% by volume
depending on the base resin as well as joint geometry. It is cheap and
easy to come by but the resulting plastic in most cases is either grey or
black.
Titanium dioxide is also used in conjunction with carbon black when
colors other than black or grey are desired. Certain pigments can be
added with the right mixtures of TIO2 and carbon black to be able to get
virtually any color desired. If a translucent absorbing layer is required,
there are a couple of different suppliers of a compound which is doped
into the plastic and absorbs the infrared energy but still allows the plastic
to be somewhat clear (translucent).
BASF has a product called Lumogen and Crystalyn has a product called
Clearweld, both of which have a greenish hue which might be a
prohibitive factor for some. There is also a product that is virtually clear
when doped into the base resin, from a supplier called Brilliance Laser
Inks.
PILLAR #2
IR ABSORBING LOWER LAYER

In general, like thermoplastics weld very well to themselves and there
shouldn’t be any issues with weldability in this case. Most laser plastic
welding applications are able to use like materials. However, there are
cases that call for two different materials to be welded together.
Tight mechanical contact between the parts that are to be
welded is probably the most critical factor when it concerns
getting a good and stable process. The importance of
clamping cannot be stressed enough.
It is vital to select the correct clamping style for the design
of the part, whether it be a glass plate, all-metal clamping
mask, or a combination of the two. The part itself needs to
be able to handle the resulting forces applied while
clamping to avoid issues with deflection which may result in
sporadic un-welded areas along the weld seam.
In some cases, a thin transparent silicone sheet in between
the part and the clamping fixture will mitigate any non-
planar surfaces and allow for full contact between the two
pieces. The fixture or part nest is also a key item in the
package as the fixture needs to provide rigidity under the
part to allow proper transfer of clamping forces through the
part to the fixture. It is absolutely essential that the fixture
contacts the underside of the part in all areas where there
is a weld seam.
PILLAR #3
TIGHT MECHANICAL CONTACT
PILLAR #4
MATERIAL COMPATIBILITY

Whether it be for mechanical reasons, biocompatibility, structural, etc.,
when welding dissimilar materials to each other, two factors need to be
considered:
CHEMICAL COMPATIBILITY
The first factor is that the two plastics need to have relatively similar
chemical compatibility (surface energy and polymer chains). For
example, silicone is not going to weld to polycarbonate as their chemical
compatibility is just too different, let alone their melt temperatures.
PROCESS WINDOW (MELT TEMPERATURE OVERLAP)
The next factor is the “process window” of the plastic. This process
window needs to have at least a 50 deg C overlap with the process
window of the other plastic you intend to weld. To clarify this, there is a
point at which the plastic begins to melt called the glass transition
temperature, and then a point at which the plastic degrades or
decomposes. The goal here is when selecting the materials, the two
plastics have a 50 Deg C process window overlap in order to sustain a
good and stable process. The greater the process window overlap the
more stable the process will be.
MATERIALS
Selecting the proper materials for your project can be a daunting
task and there are many factors to consider with respect to laser
plastic welding. In most cases however, it is recommended to test
the desired materials for their relative weldability before continuing
with full part design.
As mentioned before, like thermoplastics will typically weld well to
each other. The Material Matrix chart will show the weldability of
some common dissimilar materials but it is best to obtain actual
sample coupons and test them in the lab to verify compatibility.

The masterbatch and compound suppliers can produce resin grades that
are laser welding compatible for both the transparent and absorbing
component, as well as color-matched to your specific application. Some
are listed below for you:
COLOR MATCHING
Virtually any color combination can be set up to work for laser plastic
welding. Companies such as the ones listed above can help you dial in
your color preferences to be absorbing to the laser as well as
transmissive. Even black to black and white to white are possible.
Please keep in mind that IR Transparent dyes or pigments are not
recommended for semi-crystalline materials such as PEEK or LCP. These
materials should only be used in their natural state (IR Transparent layer
only).
Glass fills (beads or fibers) also drastically reduce the transmissive
properties of the material. For example, PBT can have up to 30% glass
fill, however, the transparent layer shouldn’t be thicker than about 2mm.
One thing to note is that with this material in particular, injection mold
temperatures have a drastic effect on the transmissivity (such as cooling
too fast or too slow, etc.) If you are specifying a grade of polyamide
(Nylon), no more than about 30% GF should be used.
If an IR transparent black or other color is desired in a glass filled part,
the transmissivity will need to be checked as the dye + the glass fills
drastically reduce the transmissivity. Again, semi crystalline materials
should not be dyed or pigmented.
• RTP Company • A. Schulman
• PolyOne • Clariant
Orient Corporation
Black to Black

ADDITIVE SELECTION CHART
Please refer to the appendix of this document for a larger version of this chart or visit:
www.daxham.com
AMORPHOUS SEMI-CRYSTALLINE
MATERIAL STATE LASER WELDABLE? MATERIAL STATE LASER WELDABLE?
NATURAL YES NATURAL YES
CLEAR YES CLEAR YES
GLASS FILL <40% GLASS FILL <20%
DYES OR PIGMENTS YES, MINIMUM 3% LET DYES OR PIGMENTS NO
OTHER ADDITIVES <5% LOADING OTHER ADDITIVES NO
MATERIAL COMPATIBILITY CHART
Reference the below chart when selecting additives

The first step in designing for laser plastic welding is to identify what
major constraints you have in developing your product. Asking the
below questions can help with the design process:
• Are you locked into certain types of material considerations such as
biocompatibility or structural?
• Does the product you are designing have to withstand a certain
mechanical fatigue or pressure?
• Is your product highly visual, or perhaps the colors or styling are
dictated by the marketing team?
• Are there UV or other material properties that will influence the
mechanical structure and selection of materials?
It is important to answer these questions before venturing down the
path of joint design for laser plastic welding as you could end up backing
yourself into a corner quite easily.
JOINT DESIGN
Lap Joint Sacrificial Rib
Butt Joint
Radial Style
Typical Joint Profiles for Plastics Bonding

DESIGNING FOR STRENGTH
The first subject this design guide will tackle is designing for strength.
When the main object is to design for mechanical integrity and strength
of the part, this will trump most of the visual criteria.
Mechanical design considerations:
• Structural – Thick absorbing and transparent layer, relatively wide
(>2mm) side walls, ribs or other stiffening features in both the
absorbing and transparent layers
• Leak integrity – Does the part need to pass a standard such as the
IP66 salt spray or other harsh environment testing?
• Burst Pressure – Is a specific burst pressure necessary for hermetic
integrity?
• What forces are acting on the part? Burst, chemical, thermal cycling,
etc.
• Where is the part seam or joining line going to be?
• Is melt flash going to be an issue if it protrudes outside the edges of
the part?
• Typically with large welding ribs and a large amount of collapse during
welding, there tends to be some flash that will be visible after
welding.
• It is recommended to use as wide of a sacrificial rib as possible
without giving up wall thickness of the housing
For Example:
100mm x 75mm housing to lid application requiring an IP rated
“tightness” specification, and a flash hiding feature…
A recommended design form factor could be a 2mm-3mm wide
sacrificial rib with 0.3-0.4mm of collapse during the welding
process to ensure a good connection and material transfer
between both joining partners. Cross-Section of Standard Sacrificial Rib
and Flash Hiding Feature

AESTHETIC DESIGN CONSIDERATIONS
Once strength and integrity have been considered we can then turn our
attention to the visual form and “looks” of the component.
Some things to consider:
• Color selections – are my parts required to meet a color matching
standard?
• 3D profile of part – is there some contour that I cannot deviate from
such as radii in the potential weld area?
• Geometry of the weld seam
• Are sink marks OK? Sometimes sink marks occur after the welding
process that are visible to the trained eye.
• Coatings, paint, etc? Are there any coatings that get applied either
before or after the laser welding process?
• Damage to part during clamping – could there be potential for parts
to get scratched or blemished in some way during clamping?
• Hide the flash or excess material – is there a visual requirement for
the part to hide or eliminate any excess material ooze or flash from
the outside environment?
Sometimes both aesthetic and structural properties must be considered
and compromises between the two will have to be made.
JOINT PROFILES
When designing a part for laser plastic welding, the designer must
decide if a “sacrificial welding rib” is needed or not. If so, special care
must be taken when including this feature.
You can compare the sacrificial rib to that of the energy director for
those of you familiar with ultrasonic welding, with the exception that the
rib needs to be flat at the top instead of pointed. There are many
different ways to design the joint for optimal process.
Actual Laser Plastic Welded Car Taillight
Image courtesy of Motortrend

The first thing to take into consideration when selecting a
joint profile is to fully understand if the goal is structural or
aesthetic. If the part needs to withstand a certain burst
pressure or has structural demands such as an actuator or
electromechanical device, in almost every case, a weld rib
is needed to overcome any variations from the injection
molding process and ensure a good, strong, and hermetic
bond. This is especially true with parts that have a complex
labyrinth of fluid channels.
FLAT-TO-FLAT (LAP JOINT)
When joining flat to flat parts, no sacrificial rib is needed, or
in some special cases a much smaller rib can be designed
into the absorbing part… 0.1mm or less.
Lap Joint Examples
Small Rib Sometimes Used in Microfluidic Devices

RADIAL WELD – INTERFERENCE FIT
When designing for a radial style weld interface, typically just a good
interference fit will suffice. A 1%-2% interference fit on diameter should
be a good rule of thumb to start with. For example, a 10mm diameter
round part should have 0.01mm-0.02mm of interference to get a good
weld.
NO BUTT JOINTS!
With APLW, butt joints do not work. This is due to clamping constraints
but most importantly due to the absorbing layer degrading under laser
energy before transferring any usable heat to the transparent layer.
Further, two absorbing layers would not work because there is no way to
ensure a good transfer of material after heating between the two,
referring to APLW, with clamping and subsequent heat transfer.
In certain cases, if you have two absorbing resins, butt welding is
possible (see image at right, courtesy of Orient Corporation)
HIDING FLASH
There are certain features that can be designed into the part on the
transparent layer to hide any excess melted material or flash that is a
result of the welding process. The most common is to add a flange that
shields the welding area from view. See below:
Flash Hiding Feature Examples
Radial Joint Cross Section
Butt Welding Example
Courtesy of Orient Corporation

Clamping and contact of the two parts to be joined is a vast area with
many facets and is by far the most important aspect of laser plastic
welding. Clamping will have far reaching effects on your process both in
development as well as in high-volume production.
The goal of clamping in laser plastic welding is to provide a tight
mechanical connection ensuring contact between the two components
that are to be joined, thus eliminating any potential gaps. As mentioned
before, one of the 4 pillars of Laser Plastic Welding is a tight mechanical
connection. Without the parts being clamped tightly together, the laser
energy would burn and degrade the absorbing layer before it transferred
the heat to the upper transparent layer.
Clamping is everything in laser plastic welding, it will make or break
your process, every time and needs serious consideration. The part
must be able to handle the mechanical force that is transferred by the
clamping system. If not designed properly, warping will occur resulting
in an imperfect weld seam.
An important point to consider when selecting a clamping method is
that anything in between the laser aperture (F-Theta lens, Beam
Expander, Diffractive Optic) and the welding surface (glass or plastic) has
a tendency to attract impurities from the air which settle on the surface
and superheat and burn when hit by the laser. This causes micro
fractures on the surface which gradually decreases the amount of laser
energy that gets through. With that being said, there are several
different clamping methods known to laser plastic welding and each
have their advantages and disadvantages.
CLAMPING TECHNOLOGY

WINDOW CLAMP TOOLING
The first clamping technology is also the most simple. It is mainly used
for prototyping in a lab scenario. It involves the use of a flat piece of
clear acrylic PMMA, PC, or glass to exert mechanical force on the surface
of the part to be welded.
Laser access is, for the most part, unobstructed and this concept makes
for a great and inexpensive means of testing parts in the lab and even in
some limited batch run scenarios. If using plastic, it can also be easily
machined to conform to the part surface anomalies whether it be 3D
contours or other features.
Glass can also be used in clamping. Quartz glass is machinable with
diamond coated tools and borosilicate glass is typically ground to shape
and in certain cases this can provide a cost-effective, limited-life
production solution. You could expect to get around 500-1000 parts
with each new piece of glass if you have a good preventative
maintenance (cleaning) schedule. In the case where glass is used,
certain coatings can also be applied to limit back-reflection and aid in the
laser transmission.
Window Clamping Tool Example - Cross Section

ALL METAL CLAMPING – OUTER ONLY
The next type of clamping involves using an all metal outer clamping
mask which contacts between 0.5mm and 1mm of the outer perimeter
of the part to be welded. Typically these types of clamps are made from
tool steel or stainless steel.
For a production scenario, this clamping method is a step up from having
an acrylic or glass clamp in-between the laser and the welding surface
that can potentially be contaminated. However, the drawback of this
type of clamping method is that as the plastic heats up, it tends to warp
and since the clamp is only on the perimeter of the part, the inner area
of the part stays put and the outer perimeter where the clamp contacts,
moves down and warps the edges, see illustration below:
Image Courtesy of:
http://www.sciencedirect.com/science/article/pii/S1875389213000679
Metal Outer Clamping Tool Example - Cross Section

HYBRID TOOLING
The next clamping technology is a somewhat of a hybrid between full
production tooling and prototype tooling. It consists of mounting an
inner metal clamping mask and an outer metal clamping mask to a piece
of clear PMMA or PC. This leaves a channel that is open for the laser to
pass through.
This acts as a sort of hybrid production clamping technology. While the
warping issues of the outer profile metal clamp are overcome, there is
still the surface for dust to settle and become burned by the laser. This
type of clamping is best suited for ramp up prototype runs where the
intent is to go into production with the part but a low-cost upfront
tooling investment is desired. Later a full metal production clamping
device can be developed.
Hybrid Clamping Tool Example - Cross Section

ALL METAL CLAMPING DEVICE
Finally, we have what is widely considered as the best means of clamping
for a maintenance free production scenario. It utilizes thin metal ribs to
connect metal inner and outer stamps so that there is no medium for
the laser to be obstructed by.
This type of clamping negates all of the issues pertaining to deformation
of the sides and lid portion of the part as well as any particulates settling
on glass or plastic surfaces.
There is virtually no maintenance necessary with this type of tooling and
it is a good option for high volume manufacturing. The most common
question surrounding the this type of tool is: Will the laser be shadowed
by the metal ribs? The answer is: Yes, to a degree it is, however, there
are a couple of factors that minimize any potential shadowing effect that
may occur.
The first is what is sometimes called “beam wrapping”. Beam wrapping
is the effect where the laser sort of “wraps” itself around the metal rib
and the majority of the laser beam surface area is transmitted to the
part, see image on the following page.
All Metal Clamping Tool Example

The next factor is similar to what happens when TIG welding metal, the
object is to push the molten bead along during the welding process with
the TIG torch. This also happens while welding plastics, the molten
plastic is “pushed” under the metal rib as the beam is guided around the
profile of the weld path – especially when using the quasi-simultaneous
welding technique, where the beam is directed around the weld path
many times in a short period of time. These factors combined with
some optimization of the weld parameters will virtually eliminate any
effect of shadowing caused by the metal rib in the laser path.
CLAMPING FORCE
A very important point to consider is that the parts must be structurally
sound enough to handle the forces being applied and transmitted
through the part during clamping. The typical range of clamping force
applied is between 2-3 Newtons per square millimeter of welding joint
surface area.
Beam Wrapping - Illustration
TIG Welding Bead
Image courtesy of: www.hotrod.com

This is good place to start when doing your structural analysis. Good
support is needed directly under the weld joint both in the part itself as
well as the fixture the part is placed in for the welding process. Proper
support will ensure minimal warping or bowing of internal features and
thus resulting in an inconsistent welding seam. This is one of the most
important aspects to laser plastic welding and is often overlooked when
designing for this technology.
APPLICATIONS OF EACH TYPE OF TOOLING
Quick prototyping of sample coupons and flat surfaced parts
• Acrylic or glass upper clamp
• Universal part nest – modular fixture
Prototyping of most parts – contoured surface or not
• Acrylic or glass upper clamp
• Custom machined part nest or 3D printed
Prototyping and multi part runs
• Hybrid upper clamp
• Custom machined part nest
Production
• All metal style upper clamp
1940nm welding (Transparent Polymer)
• Borosilicate glass upper clamp
Radial welding
• Use mirror tooling
• Fixturing either in rotary device or nested
Pro Tip:
A layer of silicone sheet (1mm thick or so) can be applied in between the glass or plastic
clamping window when welding large complex patterned welds (2D only). This helps
overcome any warping issues and allows for an even clamping force over the whole
surface of the part. The same silicon layer can be added to the part nest to allow for
free-alignment.

Several optical components work together in a laser plastic welding
system to form and focus the laser beam. With that result, there are 4
different methods of beam delivery and ways to get the laser to the part.
They are summarized below.
CONTOUR WELDING
Method of beam delivery utilizing a galvanometer scanning unit, or CNC
control, where the laser is directed along a programmed 2D (X and Y
axis) welding path one time with enough energy to heat the materials
and properly weld at the joint interface. There is no collapse or
movement of the transparent part. This method is feasible for flat to flat
(lap joint) style parts where an energy director is not required.
3D CONTOUR
Method of beam delivery where the laser is directed along a
programmed 3D (X, Y, and Z axis) welding path one time with enough
energy to heat the materials and properly weld at the joint interface.
This can be achieved by either using a multi-axis robotic arm to move the
laser along the path, by means of a 3D galvanometer scanning unit, or
even CNC motion control. (A car taillight is a good example of this.)
In some cases, a 2D galvanometer scanning unit can be used if certain
guidelines are met. This type of beam delivery method is used on larger
free-form curved parts where geometry would inhibit the beam access.
QUASI-SIMULTANEOUS
Method of beam delivery utilizing a galvanometer scanning unit similar
to Contour Welding except that the laser is directed along the
programmed 2D path at a high rate of speed, enough times to achieve a
preset collapse or melting travel distance of the transparent part. This
simulates the entire weld profile being lased – simultaneously.
BEAM PROPERTIES AND DELIVERY
Contour Welding Concept
QS Welding Concept

When a welding rib or “energy director” is needed, this is the only type
of beam delivery that can be used aside from simultaneous. The reason
for this is that as one section of the part begins to heat enough to start
melting, the clamping mechanism cannot collapse that area because the
remaining majority of the part is not melted and will not allow the clamp
to travel downward in the Z direction.
SIMULTANEOUS
This is a method where the laser energy is delivered by multiple optical
fibers placed strategically around the profile to be welded. To ensure a
homogenous blending of the individual fibers, the laser energy
projecting from the fibers is diffused by means of wave guide to the
welding surface of the part.
SHAPED BEAM – DIFFRACTIVE OPTICAL ELEMENT
The laser can be focused into certain shapes or profiles by means of a
“Diffractive Optical Element” to allow a more efficient coverage of the
welding area. This is achieved by means of precision optics such as
prisms, lenses, light guides, etc. DOE’s are now being used to create a
“top hat” profile which greatly decreases burning potential in low
transmissive materials.
The laser beam itself is a very interesting phenomena in that it can be
directed, channeled, focused and guided to a precise position, in a
perfectly repeatable manner. In the event where features on a part
cannot be accessed by conventional means, IE (2D scanner, 3D scanner,
CNC motion control, or robot, etc) then precisely placed mirrors can be
used to direct the beam to access that particular feature.
MIRRORS AND BEAM GUIDANCE
Simultaneous Welding Concept

CONICAL MIRRORS FOR RADIAL WELDS
Mirrors also make a great, robust, and quick way to weld around a
circular part in a radial style weld joint. The mirror would be in a conical
shape and a conventional 2D scanner could be used to direct the beam
around the conic and eventually mirrored to the part. This works well
for radial welding applications.
When welding round contoured parts or radial style weld joints, the use
of mirrors in conjunction with clamping and fixturing can be very
valuable.
RADIAL WELD TOOLING
When it comes to radial welds the clamping force is provided not by
tooling, but actually the interference fit designed into the parts
themselves.
Radial welds can be done in 2 different ways, 1. parts held horizontal and
mechanically spun while the laser is held stationary, as seen below 2. the
parts are fixtured vertically and a conical mirror, acting like a collar
around the part, is used to direct the laser around the joining area.
DIRECTED MIRRORS FOR WELDING UNDER OBSTRUCTIONS
In certain cases, parts may have features that restrict laser access from
the top, shadow the beam path, or even obstruct it completely. In these
instances, mirrors with particular shapes and strategically placed, can be
used to direct the beam around or even under such obstructions.
Radial Style Welding With Mirror

UNIFORM LID THICKNESS
It is recommended that the transparent layer is of uniform thickness
around the profile of the weld joint. If multiple or varying thicknesses
are used, the chance for varied laser power at the welding surface is
increased, which can cause an unstable process. Granted, there is some
level of programmable control at specific areas around the weld profile
that can alleviate some of these affects, however, it is best to keep
thicknesses uniform.
MINIMUM POSSIBLE THICKNESS
As the thickness of the transmissive layer increases, the less the
percentage of laser energy gets through. It is recommended that the
transmissive layer stays as thin as possible taking into consideration
injection molding constraints as well as structural needs. Typical
thickness of the transmissive layer is between 1mm-3mm. If additives
such as glass fills are used or IR transparent pigments, this greatly
reduces the amount of laser energy able to pass through the part and
therefore reduces the thickness this layer can be.
GENERAL GUIDELINES

UNIFORM JOINT WIDTH
It is required in laser plastic welding that the width of the welding rib
around the part stay uniform. This means no dimensional changes or
variation. All sharp corners must be filleted so that the rib width stays
uniform. The laser beam must overlap the welding joint by a minimum
of 0.5mm on either side. If the joint width was to vary or get wider, the
laser would potentially not be able to fully melt the plastic in one pass.
The same holds true for sharp corners.
PLANAR JOINTS
It is highly recommended that the welding profile lies on a single plane.
When design or styling requirements demand a profiled or curved
surface and resulting weld joint, certain criteria must be taken into
consideration which will be covered later in this guide.
Focalplane/beamwaist
RayleighLength
RAYLEIGH LENGTH AND MAXIMUM
DEVIATION
Since the beam is in the shape of an
hourglass when focused, there exists a
certain region at the center of the beam
waist which is called the Rayleigh length.
Inside of this area the laser beam is
effectively still focused enough to
properly weld. This can to certain
extents allow some 3D or non-planar
welding.
“In optics and especially laser science,
the Rayleigh length or Rayleigh range is
the distance along the propagation
direction of a beam from the waist to
the place where the area of the cross
section is doubled.” (source: Wikipedia)

CURVED UPPER SURFACES AND REFRACTION/REFLECTION
When welding 3D or non-planar parts, too aggressive of a radius or curve
will act as a mirror and the laser will not penetrate due to redirection of
the light—think of the spoon in a glass of water optical effect.
MUCH TIGHTER CONTROL OF INJECTION MOLD TOLERANCES
One critical item to consider when implementing laser plastic welding is
the need for much tighter control of the injection molding process. This
means that tolerances need to get smaller! It is recommended that the
tolerance stack up is no greater than 0.2mm for flatness. Dimensionally
the parts can vary a bit but no greater than about 0.5mm. Gaps
between the two pieces need to be less than 0.1mm in order to create a
stable welding process.
Reflection Effect
Image For Reference Only
Refraction Example

NO EJECTOR PIN MARKS OR GATES IN WELD AREAS
It is recommended that no marks reside in the area where the welding is
to take place. This includes material gates, ejector pin marks, injection
mold slide marks and other surface irregularities. Some of these
instances are unavoidable and should therefore be relocated to another
area where they wont interfere with the welding. The main thing is that
there are no gaps between the parts caused by these surface
irregularities, which will cause burning in the welding area and not allow
heat transfer and the two plastics to join properly.
CENTERING FEATURES IN PART
It is important to design certain features into the transparent part that
will locate it to the absorbing side. This will help the two parts locate to
each other and avoid misalignment. Centering features will also help to
keep the transparent part on the absorbing part during the
manufacturing process. Sometimes during the part-transfer step in a
fully automated production line, the parts could shift and separate from
each other before welding can occur. This technique can also be
designed into the welding joint itself.

BEAM ANGLES AND REFRACTION
When designing for laser plastic welding, care must be taken if a part has
features that protrude off of the welding plane. This includes bosses and
other features that could potentially shadow the laser and keep it from
reaching the welding area. In addition to beam shadowing, one must
take into consideration the angle of incidence of the laser. See diagram
below. This will vary with the type of laser and optics and is a result of
the distance between the focal plane of the laser and the aperture or F
Theta lens as well as the size of the scan field. This can be calculated
with some simple trig or in the CAD system using the below concept.
CALCULATE ANGLE OF INCIDENCE
The angle of incidence is calculated with the following steps:
• Figure out the focal height of the laser beam (Use F-Theta
specification)
• Figure out the maximum dimensions of the part
• Solve for angle of incidence
Calculating the angle of incidence allows for figuring out the draft
necessary and positioning for protruding part features. It is also
necessary when designing inner-stamp tooling or all metal style tooling
to calculate the draft allowing for laser clearance.

By following the recommendations in this guide you will avoid most problems
with laser plastic welding, however, here is a list of common pitfalls to avoid:
• Non compatible or non weldable material selection
• Poorly transmissive upper layer – fills (glass, TIO2) or dyes, etc.
• Bad injection molded components – loose tolerances
• Parts deform under clamping pressure
• Internal part features obstructing welding collapse
• Internal/external features refracting beam
• 3D surfaces refracting laser
Phase 1
q Select materials – verify OK
q Joint design recommendation (this typically takes 2-3 iterations)
q Proto tooling concept
Phase 2
q Sample coupons test welded in lab
q Proto tooling designed and built
q Proto welding and DOE – (typically less than 200 parts)
q Lock in materials and joint design
q Research laser welding system supplier that is best suited for the application
Phase 3
q Purchase system and production tooling
q Supplier acceptance testing of production system
q Installation and commissioning at manufacturing site
q Ramp up of production line
q Follow up service and support
COMMON PITFALLS
A TYPICAL PROJECT ROADMAP

FREQUENTLY ASKED QUESTIONS
Can I use my existing joint geometry, for example… Ultrasonic welding?
• No, because the apex of the triangular energy director used in US welding will tend to burn first before
effectively transferring the heat needed to melt the opposing layer of plastic. A new joint profile is
needed and consists of a flat top profile as pictured earlier in this design guide.
How can I inspect my laser plastic welded component for joint integrity?
• By using an Infrared inspection system either integrated into the welding process or in a standalone form
factor. An IR inspection system specifically set up for inspecting plastic welded components can “see
thru” the laser transparent layer and effectively analyze the bonding area with special software. More
info at: www.blackhawkIR.com
Will the laser damage the plastic or components inside or outside of the welding rib area?
• No, this is one of the major advantages of laser plastic welding, LPW has a very small heat affected zone
and since the beam is precisely controlled, it stays within the set boundary.
What is the maximum thickness the transparent layer can be?
• The transparent layer should be as thin as possible, however, when structural cases or other design
constraints present themselves, the maximum thickness depends ultimately on the transmissiity of the
material. For example, in a clear PC, the thickness can be up to about 10mm and still weld just fine.
Can you weld opaque plastics?
• Yes, as long as the plastic transmits the laser energy in the appropriate wavelength. RTP Company and
others can compound virtually any color desired to be laser transmissive.
How much clamping force is needed?
• 2-3 Newtwons per square millimeter of weld joint surface area.

DAXHAM Lasersolutions
+1.503.686.4684
INFO@DAXHAM.COM

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