Post on 18-Dec-2015
Jim Cuhel
Welding Engineer
Miller Electric Mfg. Co.
Short Circuit Transfer
Time(mS)
Vo
lta
ge
(v
olt
s)
Cu
rre
nt
(am
ps
)
Typical STD MIG Waveform150 IPM .035" S-6
912 914 916 918 920 922 924 926 928 9300 0
6 50
12 100
18 150
24 200
30 250
36 300
42 350
VoltageCurrent
Short Arc RMD
Taking Control
Time(mS)
Vo
ltag
e (v
olt
s)
Cu
rren
t (a
mp
s)
Typical STD MIG Waveform150 IPM .035" S-6
912 914 916 918 920 922 924 926 928 9300 0
6 50
12 100
18 150
24 200
30 250
36 300
42 350VoltageCurrent
Time(mS)
Vo
ltag
e (v
olt
s)
Cu
rre
nt
(am
ps
)
Typical RMD Waveform150 IPM .035" S-6
108 109.5 111 112.5 114 115.5117 118.5120 121.5 1230 0
5 50
10 100
15 150
20 200
25 250
30 300
35 350
40 400VoltageCurrent
What Is RMD?
Current
Voltage
Cu
rren
t (a
mp
s)
Time (Ms)
300 301.5 303 304.5 306 307.5 309 310.50
50
100
150
200
250
300
WET
PINCH CLEAR
BLINK PREDICT
BLINK ARC
BALL
BACKGROUNDPRE-SHORT
dl
Wire
Puddle
Necking Region
neckneckneck r
Tdl
A
TdlR
2
)()(
neckweldneck r
TdlIP
22 )(
Power Density in the Necking Region
Molten Wire
Time
Pow
er in
Nec
king
Reg
ion
Necking Begins
Short Circuit Clears (standard MIG)
Detect Clearing Event
Reduce Current (hence, power)
Short Circuit Clears at Much Lower Power Level (RMD)
Heat Input
dttIe
kTVtItH anodein
)()
2
3()()( 2
Arc Heating TermResistive Heating
How Much Energy is Needed to Burn off the Incoming Wire?
First we need to bring the wire temperature from something near room temp up to the melting point of the wire:
)( ambmelt TTT Temperature Change:
Heat Input Required to Effect Temperature Change:
TMCQ wireT
(where C=specific heat of material and Mwire = Mass of the wire being heated)
Then, we need to supply sufficient energy to cause a phase transformation from solid to liquid (we need to melt it):
wiremeltmelt MHQ (where Hm=latent heat of fusion of material)
)()( meltwiremeltTTotal HTCMQQQ
So, the total* energy required to burn off the incoming wire is:
Putting This Knowledge to Use
Heat In = + I2(t)*βI(t)*α
ARC ON Little ‘l’
Little ‘l’
I(t)
dte
kTVtItH anodearcin
)
2
3()()(
I(t)*α
I2(t)*β1/2”
Σ
-Jset
Arc Heating
Resistive HeatingJset = (Heat in @ ½” Stickout)
Error Term
ARC OFF
Jset
Actual End of the Wire
Virtual Wire
Holds info from the last i2Rdt
Holds info from the second to last i2Rdt
Holds i2Rdt info from 128 samples ago
History Array (microprocessor world)
12
3
Holds i2Rdt info from 127 samples ago
Holds i2Rdt info from m samples ago
m
m+1
m-1
128127
l
Wire Segments (Real World)
Each array element represents .01” of wire(1.28” total)
dt=1/(100*v(in/sec))after each time interval (dt), each array element shifts down one position. The last one gets dumped and an empty one is inserted on top
Keeping Track of Wire Heating History
Determined by controller based upon current feedback. Calibrated to read out in units of inches times 100. This tells us how far back in time to go with our summing of array elements
N
j
j dtiContentHeat R1
2**_
Typically, there are multiple array elements per wire segment
100*__ inchesinlengthN
Tball
Width of ball pulse is adjustedin response to the heat input in the wire
Duration of Ball Phase is Modified Based Upon Heat Content of Wire
Time(mS)
Vo
ltag
e (v
olt
s)
Cu
rren
t (a
mp
s)
Typical RMD Waveform150 IPM .035" S-6
108 109.5 111 112.5 114 115.5 117 118.5 120 121.5 1230 0
5 50
10 100
15 150
20 200
25 250
30 300
35 350
40 400VoltageCurrent
Stick out variation video
Constant Voltage GMAW Comparison
RMD: 0.035” ER70S-6 on 8” Sch. 80
Conventional GMAW
Establishing Good Technique
• As with any welding process, success with RMD process requires establishing and maintaining good preparation and welding techniques.
• The following guidelines lead to proven success and increased productivity for welding pipe
Joint Configuration
• Standard 75 degree included angle• Land: 0” – 3/32”• Root Opening: 1/8”
Five Critical Items For Stainless Steels• The techniques for welding carbon are the
same for stainless alloys• To qualify procedures for welding 300 series
stainless steel piping – Without backing gas, fabricators should do the following:1.) Ensure a minimum 1/8” gap around the entire
circumference of the joint. This gap allows the shielding gas to flow through to protect the backside of the joint from oxidation
Five Critical Items Cont.
2.) Clean the pipe both inside and out to remove any contaminates or unwanted substances. Use a wire brush to clean at least 1 in. back from the edge of the joint
3.) Use only a stainless steel wire with a high silicon content, such as 316LSi or 308LSi. Higher silicon contents helps the puddle wet out and acts as a deoxidizer
Five Critical Items Cont.
4.) For optimum performance, use a “Tri-H” gas that’s 90 He/ 7 ½ Ar/ 2 ½ CO2
Alternatively, use 98 Ar/ 2 CO2
5.) For best results, use a tapered nozzle for the root pass because it localizes the shielding gas coverage. Tapered nozzles with built-in gas diffusers provide exceptional coverage
Thank You
Any Questions