U.S. patent application number 14/699456 was filed with the patent office on 2015-09-03 for method of welding two sides of a joint simultaneously.
The applicant listed for this patent is Lincoln Global, Inc.. Invention is credited to Michael S. Flagg, Timothy M. O'Donnell.
Application Number | 20150246408 14/699456 |
Document ID | / |
Family ID | 40622738 |
Filed Date | 2015-09-03 |
United States Patent
Application |
20150246408 |
Kind Code |
A1 |
O'Donnell; Timothy M. ; et
al. |
September 3, 2015 |
Method Of Welding Two Sides Of A Joint Simultaneously
Abstract
A system for arc welding two sides of a joint simultaneously is
disclosed. By customizing welding waveforms and the distance
between two or more electrodes, weld currents can be designed to
transfer current to and through one or more electrodes in addition
to the current traditionally passed only to the common node.
Inventors: |
O'Donnell; Timothy M.;
(Chesterland, OH) ; Flagg; Michael S.; (Aurora,
OH) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Lincoln Global, Inc. |
City of Industry |
CA |
US |
|
|
Family ID: |
40622738 |
Appl. No.: |
14/699456 |
Filed: |
April 29, 2015 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11969540 |
Jan 4, 2008 |
9044818 |
|
|
14699456 |
|
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60986461 |
Nov 8, 2007 |
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Current U.S.
Class: |
219/130.5 ;
219/130.1 |
Current CPC
Class: |
B23K 33/004 20130101;
B23K 9/1062 20130101; B23K 9/188 20130101; B23K 9/025 20130101;
B23K 9/092 20130101 |
International
Class: |
B23K 9/18 20060101
B23K009/18; B23K 9/025 20060101 B23K009/025; B23K 9/10 20060101
B23K009/10 |
Claims
1-9. (canceled)
10. A system for arc welding two sides of a joint simultaneously,
comprising: a first power source connected to and supplying a first
welding waveform to a first electrode; a second power source
connected to and supplying a second welding waveform to a second
electrode; a first and second base metal positioned such that a
weld joint is to be welded on a first side and a second side; the
first electrode is positioned to weld the first side; the second
electrode is positioned to weld the second side; the first and
second electrodes move along the weld joint in the same direction
and at or near the same speed; and current transfers from the first
electrode to the second electrode, or from the second electrode to
the first electrode.
11. The system of claim 10, wherein the first electrode leads the
second electrode by up to 6 inches.
12. The system of claim 10, wherein the first electrode leads the
second electrode by up to 12 inches.
13. The system of claim 10, wherein the second welding waveform is
out of phase with the first welding waveform by some degree other
than 45.degree., 60.degree., 90.degree., 120.degree., 180.degree.,
or 270.degree..
14. The system of claim 10, wherein the weld is a butt weld.
15. The system of claim 14, wherein the weld is a butt weld in the
2G position.
16. The system of claim 10, wherein the weld is a fillet weld.
17. The system of claim 16, wherein the weld is a fillet weld in
the 2F position.
18. The system of claim 10, wherein a computer takes as inputs
simulated representations of the first and second welding
waveforms, which are supplied to a simulation circuit in the
computer that predicts at least the current flowing from the first
electrode to the second electrode, or the current flowing from the
second electrode to the first electrode.
19. A method, comprising: positioning a first workpiece proximate
to a second workpiece to define a joint between the first and
second workpieces, the first workpiece having a surface facing the
second workpiece to define a first side of the joint and an
opposing second side of the joint, the first workpiece surface
further defining a joint length extending along a length of the
first workpiece and defining a joint depth extending between the
first and second joint sides; disposing a first electrode to face
the joint from the first joint side and simultaneously disposing a
second electrode to face the joint from the second joint side;
receiving energy at the first electrode from a first energy source
to arc weld the first and second workpieces from the first joint
side and simultaneously receiving energy at the second electrode
from a second energy source to arc weld the first and second
workpieces from the second joint side; and receiving energy at the
first electrode from the second energy source to arc weld the first
and second workpieces from the first joint side.
20. The method of claim 19, wherein receiving energy at the first
electrode from the second energy source further comprises reducing
energy received at the first electrode from the first energy
source.
21. The method of claim 19, further comprising: receiving energy at
the second electrode from the first energy source to arc weld the
first and second workpieces from the second joint side.
22. The method of claim 21, wherein receiving energy at the second
electrode from the first energy source further comprises reducing
energy received at the second electrode from the second energy
source.
23. The method of claim 19, wherein receiving energy at the first
electrode from the second energy source further comprises receiving
said energy via the second electrode.
24. The method of claim 21, wherein receiving energy at the second
electrode from the first energy source further comprises receiving
said energy via the first electrode.
Description
CROSS-REFERENCE TO RELATED APPLICATION
[0001] This application is based upon and claims the benefit of
priority from U.S. Provisional Application 60/986,461 filed on Nov.
8, 2007 in the United States Patent and Trademark Office, the
disclosure of which is incorporated herein by reference in its
entirety.
BACKGROUND
[0002] 1. Field of the Invention
[0003] The present invention relates to the art of electric arc
welding and improved methods of welding two sides of a joint
simultaneously.
[0004] 2. Background
[0005] Submerged arc welding is a welding method where the arc
creating the weld is shielded from atmospheric conditions by being
submerged in a blanket of granular flux. In addition, the flux
becomes molten during the welding process and provides a path for
the current to travel to the metal workpiece (or "base") being
welded. Submerged arc welding can be performed with a DC or AC
power source and typically uses high output currents. Where AC
power sources are used, square wave sources are often employed.
Using AC square waves rather than sinusoidal waves reduces the
likelihood of having to re-strike the electrode to create an arc
again.
[0006] Making welds on two sides of a piece of base metal can be
difficult and prone to more defects and greater distortion than
normal. In particular, welding both sides of a base for butt welds
and fillet welds is complex for a number of reasons. FIGS. 1A-C
show two plates of base metal joined with a butt weld. FIGS. 2A-C
show two plates of base metal joined with a fillet weld. The edges
to be welded are often welded flat as shown in FIGS. 1A and 2A or
ground to a beveled edge as shown in FIGS. 1B and 2B. An example of
a completed butt weld is shown in FIG. 1C and a completed fillet
weld in FIG. 2C. Butt welds and fillet welds often require welding
on two sides as shown in FIGS. 1A-C and 2A-C. These two-sided welds
have been created by welding one side at a time or welding both
sides simultaneously.
[0007] One method of welding two sides of a base metal is to weld
both sides with two DC electrodes at the same time where both
electrodes are either DC positive or DC negative. However, placing
two DC electrodes close together often leads to arc blow, Arc blow
occurs when a magnetic field interferes with the arc, causing it to
wander as the weld is made. Arc welding often employs high currents
that create strong magnetic fields near the arc and ground
currents. These magnetic fields can push the arc around and create
a wandering weld bead rather than a tight, controlled weld bead.
Logically, arc blow presents a significant problem for a two-sided
weld using a DC power source because the two arcs are close enough
that their magnetic fields can interfere with each other. This has
been solved by using a "leading" electrode and a "lagging"
electrode, where the two electrodes are separated by usually at
least four feet. That is, the two opposing electrodes travel along
the weld joint at the same rate and in the same direction, but the
leading electrode is positioned in front of the lagging electrode
by at least four feet. The electrodes are separated to prevent arc
blow and held at the same DC potential to force the current to flow
through the base to the common node of the circuit.
[0008] This leading-lagging DC method, however, is prone to
defects. For example, the weld pool from the leading electrode
begins to cool and can start to solidify by the time the lagging
electrode reaches it. This can introduce cracks in the weld bead.
In addition, the separation between the electrodes and weld pools
creates an uneven distribution of heat as the weld is created and
the metal begins to solidify. This uneven heat distribution can
cause distortion because the weld solidifies unevenly or can bend
under the weight of the heavy metal base. Thus, while this solution
provides a relatively quick weld, it is prone to defects.
[0009] The most common method with butt welds involves welding one
side first, performing a back gouging step, and then welding the
second side. This method can be performed using either DC or AC
power sources, but is customarily performed with DC power supplies.
The weld starts by affixing a backing to the location of the weld,
which is often a copper plate (FIGS. 3A and 4A). Next, the first
side of the base is welded--often with deep penetration and a high
deposition rate depositing a significant amount of weld material
(FIG. 3B). Many times, the butt weld is prepared by beveling the
first side of the base, which then usually requires multiple passes
to fill the open space (FIGS. 4A and 4B). After welding the first
side, the backing is removed and the second side is "back gouged".
Back gouging cuts a bevel in the second side and removes a mix of
metal from the base and some material deposited during the first
weld (FIGS. 3C and 4C). After the second side is back gouged, it
can finally be welded (FIGS. 3D and 4D). This solution provides a
strong weld that is relatively free of defects, but it requires
significant material and is a slow process. Currently, using DC
positive with back gouging is the method most commonly used for
butt welds in the 2G position.
[0010] A solution is needed to weld both sides of a base
simultaneously and create a strong weld that is not prone to
cracking or distortion. Such a solution would save welders the
significant extra costs in labor and equipment currently caused by
slower processes.
SUMMARY
[0011] In one embodiment, a method of arc welding two sides of a
joint simultaneously comprises: supplying a first welding waveform
to a first electrode using a first power source; supplying a second
welding waveform to a second electrode using a second power source;
welding a weld joint that requires a first side and a second side
to be welded; welding the first side with the first electrode;
welding the second side with the second electrode; transferring
current from the first electrode to the second electrode, or from
the second electrode to the first electrode; and moving the first
and second electrodes along the weld joint in the same direction
and at or near the same speed.
[0012] In another embodiment, a system for arc welding two sides of
a joint simultaneously comprises: a first power source connected to
and supplying a first welding waveform to a first electrode; a
second power source connected to and supplying a second welding
waveform to a second electrode; a first and second base metal
positioned such that a weld joint is to be welded on a first side
and a second side; the first electrode is positioned to weld the
first side; the second electrode is positioned to weld the second
side; the first and second electrodes move along the weld joint in
the same direction and at or near the same speed; and current
transfers from the first electrode to the second electrode, or from
the second electrode to the first electrode.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIGS. 1A-1C illustrate a weld created in the 2G
position.
[0014] FIGS. 2A-2C illustrate a weld created in the 2F
position.
[0015] FIGS. 3A-3D illustrate a back gouged 2G weld.
[0016] FIGS. 4A-4D illustrate another back gouged 2G weld.
[0017] FIG. 5 depicts a submerged arc welding process.
[0018] FIG. 6 depicts a system designed to weld both sides of a
joint simultaneously according to an embodiment of the present
invention.
[0019] FIGS. 7A-7B depict close-up views of the weld in a system
designed to weld both sides of a joint simultaneously in an
embodiment of the present invention.
[0020] FIG. 8 depicts a simplified circuit representation of a
system designed to weld both sides of a joint simultaneously in an
embodiment of the present invention.
[0021] FIGS. 9A-C illustrate several voltage waveforms used in the
circuit of FIG. 8.
DETAILED DESCRIPTION
[0022] FIG. 5 depicts a submerged arc welding process. A spool of
welding wire (not shown) supplies wire 500 to electrode 501 where
it is electrically connected to the welding power source (not
shown). Wire 500 passes through electrode 501 and protrudes as
electrode wire 502. As the weld proceeds, the metal in electrode
wire 502 is consumed, requiring wire 500 to be continually fed
through electrode 501. This process is called "submerged" because
granular flux 509 shields electrode wire 502 and arc 503 from
atmospheric conditions. Granular flux 509 becomes molten near arc
503 and later solidifies as slag 508. Weld pool 505 contains melted
metal from base 504 and electrode wire 502. As weld pool 505 cools,
it begins to solidify in transition region 506 and results in a
solid weld bead 507. Electrical contact 510 is connected to one
terminal of the welding power supply and electrode wire 502 is
connected to the other terminal of welding power supply, which
completes the electrical circuit and allows current to flow from
electrode wire 502 through base 504 to contact 510.
[0023] In one embodiment, two electrodes are placed across from
each other to weld a joint simultaneously from both sides of the
joint. FIG. 6 shows a system designed to weld both sides of a joint
simultaneously according to this embodiment. First welder 600 and
second welder 609 provide AC power to perform the weld and contain
programmable power sources capable of providing AC power at a
variety of phase angles. First electrode 604 is connected to
positive terminal 601 of first welder 600 via cable 603. Second
electrode 605 is connected to positive terminal 608 of second
welder 609 via cable 606. Electrodes 604 and 605 are positioned
across from each other and proceed along the path of the weld joint
(shown by the arrows) at the same rate. In one embodiment,
electrodes 604 and 605 are positioned directly across from each
other. In another embodiment, electrode 604 leads electrode 605 by
some distance. In yet another embodiment, electrode 604 can proceed
along the weld joint at a different rate than electrode 605. In the
end of the process, base 611 and base 612 will be welded together.
Common node 610 connects negative terminal 602, negative terminal
607, base 611, and base 612. Welders 600 and 609 are attached to
controller 613 via cables 614 and 615, respectively. Controller 613
coordinates the welding waveforms produced by welders 600 and 609
so that the phase angle between the two welding waveforms is
maintained. In other embodiments welders 600 and 609 communicate
wirelessly with or without controller 613, or communicate via a
cable without controller 613.
[0024] Weld programs can be supplied to welders 600 and 609 through
a variety of methods including, for example: controls in or
attached to the welder, controller 613, an external computer, a
personal digital assistant (PDA), or a welding teach pendant. A
weld program is a sort of recipe where an operator defines the
parameters used to perform the weld (e.g., peak-to-peak voltage,
shape of welding waveform, DC offset, or phase angle).
[0025] Further, in the embodiment depicted in FIG. 6, electrodes
604 and 605 are placed sufficiently close to promote the transfer
of current from one electrode to the other. Positioning electrode
604 across from electrode 605 allows current to flow between the
two electrodes depending on the respective potentials of electrodes
604 and 605. Thus, this arrangement allows the welding current to
be (a) routed from first electrode 604 to second electrode 605, (b)
routed from second electrode 605 to first electrode 604, or (c)
routed from electrodes 604 and 605 to common node 610 through base
611 and base 612. By varying the two welding waveforms associated
with electrodes 604 and 605, the current through the base material
(bases 611 and 612) can be controlled or effectively shut off while
welding. This gives the operator the option of creating two welding
waveforms that allow most or all of the weld current to transfer
between electrodes 604 and 605 via the weld pool in the weld
created at the interface of bases 611 and 612. Controlling the
amount and timing of the currents flowing between electrodes 604
and 605 or through bases 611 and 612 allows for highly customized
weld programs. The weld can be customized to dictate how much heat
is applied to bases 611 and 612 and how long the heat is generated
per cycle. The weld can be further customized to dictate how fast
wire 500 is being deposited. Prior solutions never afforded the
level of customization attainable in the present embodiments.
[0026] Welders 600 and 609 are capable of operating in several
operating modes. Welders 600 and 609 can control the weld by
manipulating the amount of voltage, current or power supplied to
the weld circuit. Accordingly, the term "welding waveform" refers
to the voltage, current or power supplied to the weld circuit by an
individual welder. For ease of explanation, the discussion below
focuses on welding waveforms where the voltage is varied over time.
Additional embodiments, however, are equally applicable where the
current or power supplied from welder 600 or 609 varies over
time.
[0027] By adjusting one or more weld parameters a welding operator
can customize one or more of the following three current flows: (a)
from electrode 604 to electrode 605; (b) from electrode 605 to
electrode 604; or (c) through bases 611 and 612 to common node 610.
The weld parameters that can be adjusted include: the phase angle
between two welding waveforms, DC offset, frequency, magnitude,
balance, or shape of one or both welding waveforms. These
parameters can be adjusted alone or in combination to produce
welding waveforms that create customized current flows. In AC
welding applications, the "balance" of the welding waveform
indicates the percentage of each cycle where the waveform is
positive. For example, a voltage welding waveform with an 80 volt
peak-to-peak square wave with 25% balance and +10 volts DC offset
will be +50 volts for 25% of each cycle and -30 volts for 75% of
each cycle. Square wave shaped welding waveforms are commonly used
in AC arc welding, but many shapes can be used (e.g., sine,
triangle, or sawtooth).
[0028] In one embodiment, a computer is used to adjust the weld
parameters and supply weld programs to welders 600 and 609. This
allows the operator to adjust the parameters that will affect the
welding waveforms through a single interface. After creating a
customized weld program on the computer, the weld program can be
transferred to multiple welding systems easily through known
communication devices (e.g., wired or wireless network connections,
a PDA, or welding teach pendant). In another embodiment, a computer
calculates the expected current flow for the three currents
explained in the preceding paragraph by creating a simulation of
the weld circuit. By using circuit simulation software, the
operator can predict the current flows in the weld circuit based on
welding waveforms created by adjusting the weld parameters. This
allows the operator to postpone the actual weld operation until he
has adjusted the weld parameters such that the simulator indicates
that the desired current flows can be achieved.
[0029] FIGS. 7A and 7B depict close-up views of the weld system
depicted in FIG. 6. Here, the cross-sectional view of the weld
shows base 700, which represents the interface of bases 611 and
612. In addition, electrode 604 creates weld pool 704 and electrode
605 creates weld pool 705. Weld pools 704 and 705 can merge as a
common weld pool as shown in FIG. 7A or be separate weld pools as
shown in FIG. 7B. In FIGS. 7A and 7B, arc 604A and electrode wire
604W correspond to electrode 604, while arc 605A and electrode wire
605W correspond to electrode 605. FIG. 7A illustrates one
embodiment where electrodes 604 and 605 are positioned directly
across from each other. This position allows for good current
transfer between and through the electrodes.
[0030] FIG. 7B illustrates another embodiment where electrode 604
leads electrode 605 by some distance. In an exemplary embodiment of
the invention, the distance between leading electrode 604 and
lagging electrode 605 in FIG. 7B is sufficient to allow current to
transfer (i.e., current flow) between the two electrodes. When
electrode 604 leads electrode 605 by up to 6 inches, good current
transfer between and through the electrodes exists. However,
sufficient current flow between and through electrodes 604 and 605
can still exist when the electrodes are separated by up to 12 or 18
inches. Clearly, the distance between electrodes 604 and 605 where
current flow is good can vary depending on several factors. For
example, thicker base metals 611 and 612 generally have lower
resistance, different metals have different resistance values, or
the cooling rate of a metal can affect the resistance in the path
between electrodes 604 and 605. Generally, however, the resistance
between electrode 604 and electrode 605 increases as the distance
between them increases. Moreover, weld pool 704 can begin to
solidify if electrodes 604 and 605 are separated by too much
distance. In one embodiment of the leading-lagging configuration in
FIG. 7B, leading electrode 604 is placed approximately 2 to 3
inches ahead of lagging electrode 605. Test welds created with this
2 to 3 inch lead created well-shaped weld beads with good slag
release and tensile strength properties. In addition, the results
of this 2 to 3 inch test weld indicate that this embodiment
performed well when subjected to a Charpy impact test. In another
exemplary embodiment, lag is up to 2 inches.
[0031] FIG. 7A depicts a common weld pool shared by weld pools 704
and 705. In FIG. 7B, weld pools 704 and 705 are shown as being
separate. In one embodiment, weld pools 704 and 705 of FIG. 7A are
separate where, for example, the base metals are thicker or of
different metals, the weld penetration is lower, or the metal cools
rapidly. In another embodiment, weld pools 704 and 705 of FIG. 7B
are shared in a common weld pool where, for example, the base
metals are thin or of different metals, the weld penetration is
high, the distance between electrodes 604 and 605 is relatively
short, or the metal cools slowly. Welding with a common weld pool
shared by weld pools 704 and 705 is beneficial because it allows
for good current transfer.
[0032] FIG. 8 depicts a simplified circuit representation of the
welding system of FIG. 6. Here, V.sub.1 represents the voltage
supplied by first welder 600, R.sub.1 represents the resistance
between first welder 600 and weld pool 704 (largely due to the
resistance at the arc), and i.sub.1 represents the current through
electrode 604. Similarly, V.sub.2 represents the voltage supplied
by second welder 609, R.sub.2 represents the resistance between
second welder 609 and weld pool 705 (largely due to the resistance
at the arc), and i.sub.2 represents the current through electrode
605. Finally, V.sub.3 represents the voltage drop from weld pools
704 and 705 to common node 610, R.sub.3 represents the resistance
between weld pools 704 and 705 and common node 610 (R.sub.3 is
smaller than R.sub.1 or R.sub.2 because bases 611 and 612 are good
conductors), and i.sub.3 represents the current through bases 611
and 612 to common node 610.
[0033] FIG. 9A illustrates one embodiment where V.sub.1 and V.sub.2
are both 60 Hz 60 volt peak-to-peak square waves with a 60% wave
balance. However, V.sub.2 is out of phase with V.sub.1 by
180.degree. (i.e., V.sub.2 lags V.sub.1). At time point t=A,
V.sub.1 is -30 volts and V.sub.2 is +30 volts, which causes all of
the current to flow from i.sub.2 back through i.sub.1 with
effectively no current running through i.sub.3. That is, current is
flowing from positive terminal 608 through second electrode 605 and
first electrode 604 to positive terminal 601 (with almost no
current flow towards common node 610). At time point t=B, V.sub.1
is +30 volts and V.sub.2 is also +30 volts, which causes all of the
current flow from i.sub.1 and i.sub.2 to feed into i.sub.3. That
is, all current flows from electrodes 604 and 605 through bases 611
and 612 to common node 610. At time point t=C, V.sub.1 is +30 volts
and V.sub.2 is -30 volts, which causes all of the current to flow
from i.sub.1 through i.sub.2 with effectively no current running
through i.sub.3. That is, current is flowing from positive terminal
601 through first electrode 604 and second electrode 605 to
positive terminal 608 (with almost no current flow towards common
node 610).
[0034] FIG. 9B illustrates one embodiment where V.sub.1 and V.sub.2
are both 60 Hz 80 volt peak-to-peak square waves where V.sub.1 has
a 60% wave balance and V.sub.2 has a 40% wave balance and V.sub.2
is out of phase with V.sub.1 by 144.degree.. At time point t=D,
V.sub.1 is +40 volts and V.sub.2 is -40 volts, which causes all of
the current to flow from i.sub.1 through i.sub.2 with effectively
no current running through i.sub.3. That is, current is flowing
from positive terminal 601 through first electrode 604 and second
electrode 605 to positive terminal 608 (with almost no current flow
towards common node 610). At time point t=E, V.sub.1 is -40 volts
and V.sub.2 is +40 volts, which causes all of the current to flow
from i.sub.2 back through i.sub.1 with effectively no current
running through i.sub.3. That is, current is flowing from positive
terminal 608 through second electrode 605 and first electrode 604
to positive terminal 601 (with almost no current flow towards
common node 610). In test welds, the welding waveforms in this
embodiment created well-shaped weld beads with good slag release
and little arc blow.
[0035] FIG. 9C illustrates one embodiment where V.sub.I and V.sub.2
are both 60 volt peak-to-peak square waves with a 50% wave balance.
In addition, V.sub.1 is a 60 Hz waveform, V.sub.2 is a 120 Hz
waveform, and V.sub.2 is completely in phase with V.sub.1. At time
point t=F, V.sub.1 is +30 volts and V.sub.2 is also +30 volts,
which causes all of the current flow from i.sub.1 and i.sub.2 to
feed into i.sub.3. That is, all current flows from electrodes 604
and 605 through bases 611 and 612 to common node 610. At time point
t=G, V.sub.1 is +30 volts and V.sub.2 is -30 volts, which causes
all of the current to flow from i.sub.1 through i.sub.2 with
effectively no current running through i.sub.3. That is, current is
flowing from positive terminal 601 through first electrode 604 and
second electrode 605 to positive terminal 608 (with almost no
current flow towards common node 610). At time point t=H, V.sub.1
is -30 volts and V.sub.2 is +30 volts, which causes all of the
current to flow from i.sub.2 back through i.sub.1 with effectively
no current running through i.sub.3. That is, current is flowing
from positive terminal 608 through second electrode 605 and first
electrode 604 to positive terminal 601 (with almost no current flow
towards common node 610). Finally, at time point t=I, V.sub.1 is
-30 volts and V.sub.2 is also -30 volts, which causes the current
to flow from i.sub.3 into i.sub.1 and i.sub.2. That is, all current
flows from common node 610 through bases 611 and 612 then splits
into two branches of current flowing into electrodes 604 and 605.
In test welds, the welding waveforms in this embodiment created
well-shaped weld beads with good slag release and little arc
blow.
[0036] As evidenced by the embodiments explained above, the system
depicted in FIG. 6 allows for highly customizable current flows (a)
from electrode 604 to electrode 605; (b) from electrode 605 to
electrode 604; and (c) through bases 611 and 612 to common node
610. The current flows can be highly customized by altering one or
more of the following: the phase angle between V.sub.1 and V.sub.2;
the DC offset of V.sub.1 and/or V.sub.2; the frequency of V.sub.1
and/or V.sub.2; the magnitude (e.g., peak-to-peak voltage) of
V.sub.1 and/or V.sub.2; the balance of V.sub.1 and/or V.sub.2; or
the shape of the waveform for V.sub.1 and/or V.sub.2 (e.g., square
wave, sine wave, or triangular wave). Altering any one or a
combination of the above parameters will result in different
voltage waveforms for V.sub.1 and V.sub.2, which will result in
different amounts of current flowing in i.sub.1, i.sub.2 and
i.sub.3 (i.e., between electrodes 604 and 605 and through bases 611
and 612). The system can be further customized by using multiple
arcs on one or both sides of the weld.
[0037] In contrast to the embodiment depicted in FIG. 6, first and
second welders 600 and 609 can also be connected as follows:
positive terminal 601 to common node 610, negative terminal 602 to
electrode 604, positive terminal 608 to common node 610, and
negative terminal 607 to electrode 605.
[0038] In one embodiment, welders 600 and 609 are Power Wave.RTM.
AC/DC 1000.TM. welders manufactured by The Lincoln Electric
Company, which can be programmed to supply AC waveforms that are
out of phase anywhere between 1.degree. and 359.degree.. In another
embodiment, base 612 can be rotated 90.degree. and welded as a
fillet weld rather than a butt weld. In one embodiment, the butt
weld is created in the 2G weld position. In another embodiment, the
fillet weld is created in the 2F weld position.
[0039] It is noted that although the present invention has been
discussed above specifically with respect to welding applications,
the present invention is not limited to this and can be employed in
any similar applications. While the invention has been described in
terms of various specific embodiments, those skilled in the art
will recognize that the invention can be practiced with
modification within the spirit and scope of the claims.
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