ESAB LTP 450 Programming Manual

Brand: ESAB

Model: LTP 450

Type: Programming Manual

Valid for program version 2.80A, 2.81A0456 638 174 GB 050420

PROTIG 450

Programming manual

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TOCe

Rights reserved to alter specifications without notice.

1 INTRODUCTION 4...................................................

1.1 Mode of operation -- Control box 4.............................................

1.2 Sectors 4..................................................................

1.3 Display and keyset 5........................................................

2 WELDING PARAMETERS 9...........................................

2.1 Welding current 9...........................................................

2.2 Gas 11.....................................................................

2.3 Wire feed speed 11..........................................................

2.4 Preheating time 12...........................................................

2.5 Rotation speed 12...........................................................

2.6 Arc voltage control (AVC) 12..................................................

2.7 Weaving 13................................................................

3 START AND STOP 14.................................................

3.1 Start 14.....................................................................

3.2 Stop 14.....................................................................

3.3 Restart 14...................................................................

4 TO GET STARTED 14.................................................

4.1 General 14..................................................................

4.2 How to indicate a tool code 15.................................................

4.3 How to define your own tool code 16............................................

4.4 How to change languages 22..................................................

5 PROGRAM EDITING 23................................................

5.1 Entering a parameter value 23.................................................

5.2 Increasing/decreasing a parameter value 23.....................................

5.3 Creating a new sector 23......................................................

5.4 Changing the breakpoint of a sector 24..........................................

5.5 Creating a transport sector 24..................................................

5.6 Finding the home position 24..................................................

5.7 Entering a slope 25...........................................................

5.8 Moving within a program 26....................................................

5.9 Deleting in a program 26......................................................

5.10 Changing weld data during welding 27..........................................

5.11 Zeroing the control box 27.....................................................

6 PROGRAMMING EXAMPLES 28.......................................

6.1 Example 1a: 28..............................................................

6.2 Example 1b: 31..............................................................

6.3 Example 1c: 33..............................................................

6.4 Example 1d: 35..............................................................

6.5 Example 1e: 39..............................................................

7 THE LIBRARY 43.....................................................

7.1 Storing a program 43.........................................................

7.2 Recalling a program 43.......................................................

7.3 Viewing the tool code 44......................................................

7.4 Deleting a program 44........................................................

8 MANUAL MODE 45...................................................

8.1 Field of application 45.........................................................

8.2 Editing a parameter 45........................................................

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Rights reserved to alter specifications without notice.

9 PC--CARD 47.........................................................

9.1 Field of application 47.........................................................

9.2 How to install the card 47......................................................

9.3 How to recall a program 47....................................................

9.4 How to store a program 48....................................................

9.5 How to delete a program 48...................................................

9.6 How to take out the PC--card 49................................................

10 ERROR CODES 49....................................................

10.1 Error handling 49.............................................................

10.2 Incorrect editing codes 54.....................................................

11 SHOW CURRENT PARAMETER VALUES 55.............................

11.1 Field of application 55.........................................................

11.2 How to view actual parameter values 56.........................................

12 SOFTWARE UPGRADE 56.............................................

12.1 Application field 56...........................................................

12.2 Menu explanation 56..........................................................

12.3 How to upgrade 57...........................................................

12.4 Measures to be taken when the upgrading of the power source units failed 59........

12.5 Measures to be taken when the upgrading of the control box failed 60...............

13 SOFWARE KEY 60....................................................

13.1 General 60..................................................................

13.2 Locking the control box 61.....................................................

13.3 Unlocking the control box 62...................................................

13.4 Changing the code 62.........................................................

13.5 Forgotten the code? 63.......................................................

13.6 How to indicate limit values 63.................................................

14 NOTEBOOK 65.......................................................

14.1 Field of application 65.........................................................

14.2 How to enter data in the notebook 65...........................................

14.3 Example 2a: 65..............................................................

15 MANUAL WELDING 71................................................

15.1 Field of application 71.........................................................

15.2 How to create a welding program 71............................................

15.3 Example 3a: 71..............................................................

15.4 How to weld 75..............................................................

16 APPENDIX 75........................................................

16.1 Tool codes 75................................................................

16.2 Symbols 76..................................................................

16.3 Setting ranges -- welding parameters 76.........................................

17 MENU STRUCTURE 77................................................

18 TECHNICAL TERMS 78................................................

19 PROGRAMMING NOTES 80............................................

ORDERING NUMBER 83.................................................

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1 INTRODUCTION

1.1 Mode of operation -- Control box

The control box consists of four units, the working area, the library, the notebook

and the auxiliary functio n.

S In the working area the welding program is created.

S In the library the program can be stored.

During welding it is always the contents of the working area that control the

welding process. Thus it is also possible to call in a welding program from the

library to the working area.

S In the notebook you can make your own notes about special welding

parameters, for example.

S In the auxiliary fun ctio n you can:

S change languages

S view all existing error messages

S show actual parameter values

S software upgrade

S sofware key

1.2 Sectors

A welding program for welding of tubes can be divided into different parts or sectors.

Each sector corresponds to a special part of the circumference of the tube. Max.

number of sectors for one program is one hundred (100).

Sector 1

Sector 2

Sector 4

Sector 3

A sector can be assigned its own set of values for different welding parameters, such

as current, rotation speed, wire feed speed, etc. In this way the welding can be

performed using different parameter settings for different parts of the joint of the

tube.

The division into sectors is done by indicating different breakpoints along the

circumference of the tube. Each such breakpoint constitutes the starting point of a

new sector. In the figure below, the breakpoint 0.000 is the starting point of sector 1,

breakpoint 0.250 the starting point of sector 2, etc.

Sector 1

Sector 2

Sector 4

Sector 3

Breakpoint 0,000

Breakpoint 0,250

Breakpoint 0,500

Breakpoint 0,750

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LTP 450 allows welding of up to 10 turns in the same welding joint, i.e. the welding

tool can be rotated 10 times round the tube.

The breakpoints in the previous figure all start with the integer 0 which means that

they form the breakpoints of turn 1. The breakpoints of turn 2 (if there is one)

always start with th e integer 1,etc.

S Turn 1 = breakpoints 0.000 -- 0.999

S Turn 2 = breakpoints 1.000 -- 1.999

S Turn 3 = breakpoints 2.000 -- 2.999

S Turn 4 = breakpoints 3.000 -- 3.999

S Turn 5 = breakpoints 4.000 -- 4.999

S Turn 6 = breakpoints 5.000 -- 5.999

S Turn 7 = breakpoints 6.000 -- 6.999

S Turn 8 = breakpoints 7.000 -- 7.999

S Turn 9 = breakpoints 8.000 -- 8.999

S Turn 10 = breakpoints 9.000 -- 9.999

To terminate a welding program a so--called end sector is indicated.

For a sector to be counted as an end sector the following two conditions must be

fulfilled:

S There is no sector following.

S The welding current value of the sector = 0 ampere.

1.3 Display and keyset

A Display, B Soft keys, C Function keys

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Display

SECTOR 2(4)

WELD GAS

ROOT GAS

START GAS

WELD

GAS

ROOT

GAS

START

GAS

0.500

The following information is shown in the display.

a The program sector at present involved.

b The nu mber of sectors in the current program.

c The breakpoint of the sector (sector 2 in this example).

d The digit box shows the numerical valu e entered and different

numerical characters. For further information, see page 76.

e Showing that the indicated value has been borrowed from a previous

sector (in this example from sector 1).

g 5 text b o xes describing the function of the so--called so ft keys (f).

h Message line describing the actual state.

WELDING = a welding sequence is going on.

END = a welding sequence is completed.

TRANSPORT= transfer without welding.

STOP = the welding sequence was interrupted due to activation of the stop

key.

Soft

keys

By way of the soft keys ( a) the functions connected with the respective display (in

this case the GAS parameter display), the significance of which is indicated in the

text boxes (b). Depending on the display selected, up to five soft keys can be

activated.

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Function keys

Parameter keys

The welding parameters are divided into seven different groups, each group

represented by one ordinary key and a set of soft keys.

W elding current Gas

Rotation speed Wire feed speed

Arc voltage control (AVC) Weaving

Preheating time

SHIFT key

This key is used for changing the significance of other keys on the keyboard.

PLUS/MINUS keys

These keys are used for increasing/decreasing set values.

Numerical keys

These keys are used for entering the digits 0--9 and decimal point.

Other keys

SLOPE

This key is used when you want to add a slope function to a parameter and is

indicated in the following way in the display

By slope is meant a gradual change of a set value.

Slope up = gradual increase

Slope down = gradual decrease

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The following parameters can be assigned a slope function:

Current (both peak and background current) when pulsed current is used, rotation,

arc leng t h control, wire feed speed , weavin g amplitude.

A slope can be time--controlled by indicating that it shall go on for a certain number

of seconds. It can also be sector--co n trolled, making it a so--called sector slope, by

indicating between which two breakpoints it shall be located.

SECTOR

This key indicates the breakpoint of a program and moving to indicated sector.

STEP

This key is used for stepping forward in the program.

DELETE

This key is used for deleting the whole program, part of a program in the working

area, or just the figures in the digit box.

MANUAL MODE

This key is used for positioning the electrode before welding, and for making sure

that the program in the working area functions as desired.

MEMORY (library)

This key is used for entering or leaving the library and for storing a program, or for

recalling a pr ogram from the library to th e working area.

CORRECT

This key is used for correcting the position of the electrode in connection with

weaving (centre line adjustment).

MODE (au xiliary functions)

This key is used for getting to the different auxiliary functions, such as language,

error log, show actual parameter values and software upgrading.

This key is not used.

NOTEBOOK

These keys are used if you want to make notes on a welding sequence.

TOOL CODE

These keys are used if you want to view the code of the connected tool.

RESTART

These keys are used for restarting a welding sequence.

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SECTOR SLOPE

These keys are used if you want to create a sector slope.

DIRECT STOP

Pressing this key will lead to direct stop of the welding. The gas postflow takes place

according to settings in the end sector.

START

This key is used for starting a welding sequence.

STOP

This key is used for stopping a welding sequence. T he welding sequence is

terminated according to the settings in the end sector.

2 WELDING PARAMETERS

Setting ranges for the welding parameters can be found in the APPENDIX on page

76.

2.1 Weld ing current

There are four different parameters for welding current:

S PEAK CURRENT

S BACKGROUND CURRENT

S PEAK TIME (1 s)

S BACKGROUND TIME (1 s)

The values in brackets are preset values.

Peak time

Background time

Background current

Peak current

The welding current can be either pulsed or continuous (not pulsed).

If you want to weld using pulse current a value must be entered for all four

parameters. When welding with continuous current, however, you only need to enter

the value for peak current. Entering a value also for background current will result

in pulsed current with preset pulse and background times. Of course, the pulse

and background times can also be changed.

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The welding current (pulsed current) can be synchronised with the weaving motion

so that the peak current will set in when the electrode is in the extreme positions of

the weaving motion. This is called special pulsin g.

(The peak current sets in at the extreme weaving positions also when special pulsing

is not used.)

Special pulsing

By special pulsing is meant that the welding current is synchronised with the weaving

motion, i.e. you get peak current when the electrode is in an end position of the

weaving motion. Thus the peak current time is determined by the dwell time of the

respective dwell position.

Special pulsing can be used in combination with both continuous and pulsed

rotation. Special pulsing with pulsed rotation -- also called square--wave pulsing --

means that the gear ring rotates when the electrode is in an end position of the

weaving m otion.

Special pulsing with

continuous rotation

Rotation direction

Special pulsing with

pulsed rotation

Rotation direction

A = background current B = peak current

As to special pulsing, the wire feed can be either continuous or pulsed. As to pulsed

wire feed, the synchronisation with the welding current takes place in the way

described above, see the section “Wire Feed Speed“ on page 11.

SECTOR 1(4)

PEAK CURRENT

BACKGR. CURRENT

PEAK TIME

BACKGR

CURR

PEAK

TIME

0.000

BACKGR. TIME

BACKGR

TIME

SPEC.

PULS

PEAK

CURR

CONT/

To activate the function special pu lsin g , press the marked soft key in the display for

welding parameters.

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2.2 Gas

In the Shielding Gas parameter group three parameters are represented:

S WELD GAS

S ROOT GAS

S START GAS

By weld gas is meant the shielding gas on the upper side of the joint. The weld gas

parameter indicates the time the shielding gas is to flow on the upper side of the joint

before and after welding.

The values of the weld gas parameter are preset. The following values for preflow

and postflow of the weld gas apply at the start if nothing else has been indicated:

S Weld gas preflow = 2 s

S Weld gas postflow = 4 s

By root gas is meant the shielding gas on the underside of the joint. The root gas

parameter indicates the time the shielding gas is to flow on the underside of the joint

before and after welding.

Some shielding gases, for example helium (He), can cause difficulty with regard to

striking the arc. If such a shielding gas is to be used as weld gas, it could be

advisable to use another gas mixture at the start moment -- a so--called start gas.

If one value is entered for weld gas in sector 1 and one for start gas, only the start

gas is going to flow. T he weld gas starts flowing when the arc is struck.

2.3 Wire feed speed

This param eter is used to indicate the desired feed speed of the filler wire in cm /m in.

The wire feed speed can be pulsed or continuous (not pulsed).

In the Wire Feed Speed parameter group two param eters are represented:

S PEAK WIRE FEED SPEED

S BACKGROUND WIRE FEED SPEED

For welding with continuous (not pulsed) wire feed speed, only the peak wire feed

parameter shall be entered.

For welding with pulsed wire feed speed, both the peak wire feed speed and the

background wire feed speed parameters shall be entered.

The pulsed wire feed speed is always automatically synchronised with the welding

current. The wire feed speed is high using pulse current and low using background

current.

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2.4 Preheating time

Preheating is used for heating the workpiece at the starting point in order to obtain

correct penetration of the molten pool. The preheating time is defined as the time

elapsing between arc strike and start of the rotary motion. If no value has been

entered for the preheating parameter, the arc will strike at the same time a s r otation

is started.

NOTE! In the Welding Current parameter group you cannot indicate a sector slope

when preheating is involved.

2.5 Rotation speed

This parameter indicates the rotation speed of the electrode round the workpiece. It

is indicated in per mill (thousandths) of the max. rotation speed of the welding tool

used.

Just like welding current and wire feed speed, the rotation speed can be pulsed or

continuous (not pulsed).

In the Rotation Speed parameter group four parameters are represented:

S ROTATION FORWARDS

S ROTATION BACKWARDS

S PULSED ROTATION FORWARDS

S PULSED ROTATION BACKWARDS

Pulsed rotation is automatically synchronised with the welding current so that the

welding tool stands still when the peak current sets in and rotates during background

current.

2.6 Arc voltage control (AVC)

This parameter is used for automatic control of the arc when welding with a tool fitted

withanAVCunit.

Arc voltage control (AVC) means that the arc voltage, and by that the length of the

arc (i.e. the distance between the tip of the electrode and the workpiece), is

automatically controlled in the course of welding.

In the Arc Voltage Control (AVC) parameter group three parameters are represented:

S PEAK VOLTAGE (Arc voltage when using peak current)

S BACKGROUND VOLTAGE (Arc voltage when using background current)

S DELAY TIME

With the parameters peak voltage and background voltage you set the reference

value for arc voltage control when using peak current and background current. When

using continuous current only the p eak voltage parameter shall be entered.

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If no value is entered for peak voltage a value measured right after the welding start

is used as reference value.

If no value is entered for background voltage and pulsed welding current has been

selected, no arc voltage control takes place when background current is used.

NOTE! A time slope cannot be indicated in sector 1 for peak voltage and background

voltage.

In order to stabilise the arc b efore starting t he arc voltage control, a delay time can

be entered. During the delay t ime the AVC unit is locked.

If no delay time is entered the following applies:

S The d elay time will be equally long (at least 5 seconds) as the slope--up tim e (if

any) for the welding current.

If the slope--up time is shor ter than 5 seconds, the AVC unit can star t controlling

when the slope time has elapsed, but only by increasing the arc voltage (arc

length).

S If no slope--up time has been entered for the welding current, a fixed delay time

of 5 seconds applies. The AVC unit is not completely locked -- the arc voltage

(arc length) can be increased.

2.7 Weaving

Weaving is used if you want to oscillate the electrode laterally when welding with

welding tools fitted with a weaving unit.

In the Weaving parameter group four parameters are represented:

S WEAVE AMPLITUDE (5 mm)

S WEAVE SPEED (5 mm/s)

S DWELL TIME RIGHT (1 s)

S DWELL TIME LEFT (1 s)

amplitude (mm)

dwell time (s)

right

left

dwell time (s)

Weave speed (mm/s)

The values in brackets are preset values. If one of the parameter values is indicated

in the display, the preset values will come up automatically.

The weaving motion can be synchronised with the welding current (pulse current) so

that the pulse current sets in at the same time as the electrode is in dwell position.

This is also called special pulsing and is described in the section Special Pulsing

on page 10.

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3 START AND STOP

3.1 Start

To start the welding, use the START key .

It is impossible to start a welding program if another tool code has been indicated

than the one used in the program in question.

3.2 Stop

A requested welding stop over the STOP key means that the program jumps to

the following end sector, no matter which sector you are in at the moment. The

welding is terminated according to the settings of the end sector.

A requested welding stop over the DIRECT STOP key

leads to immediate stop

of the welding. The gas postflow takes place according to the time set in the end

sector.

3.3 Restart

If the welding was interrupted it is restarted with the SHIFT and START keys

Irrespective of whether the welding was stopped over the STOP

or the DIRECT STOP key , the start parameters of the preceding start

sector are used. T he program then continues from the position in the welding

program where it was interrupted.

4 TO GET STARTED

4.1 General

Some of the factors controlling the welding process are specific to each one o f the

welding tools, for example the rotation speed. T herefore, every welding program

must be connected to a tool code, associated with the tool that the program was

made up for.

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4.2 How to indicate a tool code

S Turn the mains switch on the welding power source to position 1.

S The following display comes up:

CHOOSE CONNECTED TOOL

PRB , PRC "

PRH

PRD

POC 12--60 mm

TIG HAND TORCH

A25

ENTER

Example: Yo u have con n ected PRC 33--90

S Move the marking to the line for PRB, PRC using the soft key NEXT. Choose the

desired tool and press ENTER.

A window comes up, showing available tool sizes.

S Move the marking to the size of the tool you have connected (in this example

33--90 mm) using the soft key NEXT and press ENTER.

CHOOSE CONNECTED TOOL

PRB, PRC " 8-- 17 mm

PRH 17-- 49 mm

PRD 33-- 90 mm

POC 12-- 60 mm 60-- 170 mm

TIG HAND TORCH

A25

QUIT ENTER

Result: T he new tool code is accepted and the following text is displayed:

CONNECTED TOOL: PRB, PRC 33--90 mm.

NOTE! In the event a program with another tool code should already be stored in the

working area this must first be deleted. If you want to preserve the old program, don’t

forget to save it in the library by pressing the MEM key

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The following information is displayed in the display:

ress

eso

delete existing

WARNING!

TOOLTYPE MISMATCH

program.

PROGRAM NO 1

PROGRAM MADE FOR: PRB, PRC 17-- 49 mm

CONNECTED TOOL: PRB, PRC 33-- 90 mm

DELETE

PROG.

Result: T he new tool code is accepted and the display displays: CONNECTED

TOOL:PRB,PRC33--90mm.

If no figure is entered after PROGRAM NO: _ no welding program has been recalled

from the library.

Note! If the welding data in the working area is changed, the welding program will

not match the program recalled from the library. If you wish to keep the changes,

save them as a new welding program in the library.

4.3 How to define your own tool code

To define your own tool code you m ight have to calculate some of the following

parameter factors:

ROTATION LENGTH, example A, see page 18.

SCALE FACTOR ROTATION, example B, see page 18.

SCALE FACTOR ARC VOLTAGE, example C, see page 19.

WEAVE -- PULSES/mm, example D, see page 20.

SCALE FACTOR WIRE, example E, see page 21.

SCALE FACTOR WEAVE, example F, see page 21.

NB. The values set under self--defined tool codes remain even if you choose an

ordinary tool code.

Preset

values

Parameter factor PRD A25 PRB, PRC

Rotation length 55350 55350 55350

Scale factor, rotation 846024 960000 678000

Scale factor , arc voltage 30 40 30

Weave -- pulses/mm 84 52 84

Prescaler no yes no

Scale factor, wire 120700 230826 230826

Scale factor , weave 119048 190476 119048

S Set the mains voltage switch on the power source to position 1.

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Example A: PRD 160

The following display comes up:

CHOOSE CONNECTED TOOL:

PRB, PRC

PRH

PRD "

POC 12--60 mm

TIG HAND TORCH

A25

ENTER

S Move the marking to the PRD line using the soft key next and press enter.

The following display comes up:

S Press the soft key

CHOOSE CONNECTED TOOL:

PRB, PRC

PRH

PRD " CUSTOMIZED

POC 60--170 mm

TIG HAND TORCH

A25

SET QUIT ENTER

The following display comes up:

S Press the soft key

INSERT PARAMETERS

DEFAULT PRD A 25 PRB, PRC

ROTATIONS LENGTH 55350

SCALE FACTOR ROT 678000

NEXT QUIT ENTER

Result: The PRD tool is marked.

S Enter rotation length and scale factor. For correct values, see instruction m anual

0440 100 xxx for PRD 160.

S Press the soft key quit.

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The following display comes up:

S Press the soft key

CHOOSE CONNECTED TOOL:

PRB, PRC

PRH

PRD " CUSTOMIZED

POC 60--170 mm

TIG HAND TORCH

A25

SET QUIT ENTER

Result: T he new tool code was accepted and the text CONNECTED TOOL: PRD

comes up.

NB. If there is already a program with another tool code stored in the working area,

this program must be deleted. (If you want to preserve the program, save it in the

library by pressing the MEM key

The following information is displayed in the display:

ress

eso

delete existing

WARNING!

TOO

PE MISM

TCH

ram.

PROGRAM NO 1

PROGRAM MADE FOR: PRB , PRC 17-- 49 mm

CONNECTED TOOL: PRD

DELETE

PROG.

Result: T he new tool code was accepted and in the display the text CONNECTED

TOOL: PRD comes up.

Calculating and setting the rotation

length

ROTATION LENGTH= enter number of pulses / revolution (from start point 0.000 to

1.000)

Calculating and setting the scale

factor

Example B: PRH 6--40, rotation.

S Max rotation speed (V) = 2.778 rpm

S Mechanical gear ratio of drive unit (N) = 2140:1

S Value for pulse generator signals per revolution of motor shaft (P) =15

S Max. adjustable rotation value (M) = 1000.

S The time between the pulses from the pulse generator, indicated in

micro--seconds at the desired max. speed (the data can be found in the

specification of the drive unit used).

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(T)= 60s

x 1 000 000

VxNxP

S Constant ( K) is to be indicated so that K/T = max. adjustable value in the display

(M). K = T x M = 672843

SCALE FACTOR = 672843

S Step to the following display, see example A, page 18.

S Step to parameter

INSERT PARAMETERS

FACTOR ROTATION

using the soft key

next.

DEFAULT PRD A 25 PRB, PRC

ROTATIONS LENGTH 55350

SCALE FACTOR ROT. 672843

NEXT QUIT ENTER

S Press the soft key enter.

S Enter the value 672843 for the scale factor using the numerical keys.

S Press the soft key enter.

Result: T he rotation scale factor has been set.

Calculating and setting the arc voltage scale factor (AVC)

Example C: AVC motor

S Max. armature voltage (S) =60V

S Modulated value for max. armature voltage (U) = (SCALE F ACTOR VOLTAGE /

255) x S

Recommendation: Set a low modulated value U, about 7 V and try out a voltage

scale factor.

SCALE FACTOR VOLTAGE = U x 255

=7x255¶ 30

S60

S Step to the following display, see example A, page 5.

S Step to # using the

INSERT PARAMETERS

S Press the soft key

enter.

DEFAULT PRD A 25 PRB, PRC

ROTATIONS LENGTH 55350

SCALE FACTOR ROT. 678000

NEXT QUIT ENTER

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The following display comes up:

S Press the soft key

INSERT PARAMETERS

S Enter 30 using the

numerical keys.

S Press the soft key

LE F

CTOR VOLT. 30

WEAVE -- pulses/mm. 84

PRESCALER

SCALE FACTOR WIRE 230826

SCALE FACTOR WEAVE 119048

NEXT QUIT ENTER

S Press the soft key quit.

The following display comes up:

S Press the soft key

INSERT PARAMETERS

DEFAULT PRD A 25 PRB, PRC

ROTATION LENGTH 55350

SCALE FACTOR ROT. 678000

NEXT QUIT ENTER

Result: T he scale factor for arc voltage has been set.

Calculating and setting the weaving length

Example D: PRD 100

S Weaving motor gear ratio (N) =

x43r/mm

112

S Value for pulse generator signals per revolution of motor shaft (P) =15WEAVE --

pulses/mm =NxP=127

Enter values for WEAVE LENGTH in the same way as in example C on page 19.

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ESAB LTP 450 Programming Manual

ESAB LTP 450 Programming Manual

ESAB LTP 450 Programming Manual

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