gefran 1000 Manuel D'utilisation page 14

Configuration Phase 2 (CFG2)
Access to phase CFG2 is conditioned by the closing of jumper 3 / J13 on the CPU
board on components side (see Hardware Configuration).
Pro/: Software protection level in range 0-31 as per the table.
Pro Setpoint Allarms
0 DISPLAY <> DISPLAY <> DISPLAY <> DISPLAY <> DISPLAY <>
1 DISPLAY <> DISPLAY <> DISPLAY <> DISPLAY <>
2 DISPLAY <> DISPLAY <> DISPLAY <> DISPLAY <>
3 DISPLAY <> DISPLAY <> DISPLAY <>
4 DISPLAY <> DISPLAY <> DISPLAY <>
5 DISPLAY <> DISPLAY <>
6 DISPLAY <> DISPLAY
7 DISPLAY DISPLAY
DISPLAY = DISPLAY
+8 to disable the ON-OFF function from the panel keys
+16 to inhibit the AUTO/MAN function (only for instruments with AUTO/MAN function):
only power display in Automatic remains displayed.
Standard protection level 19. Phase CFG2 parameters are not subject to software
protection (access to phase CFG2 depends only on state of jumper 3/J13(HW
config.).
_AI/: Alarm output function.
Configuration of symmetrical deviation alarms requires setting of positive setpoints
only. For correct function, negative values are not allowed (even if settable).
0 = Alarms 1 and 2 direct absolute (relay energized when alarm limit is exceeded).
1 = Alarm 1 deviation, Alarm 2 absolute, both direct.
2 = Alarm 1 absolute, Alarm 2 deviation, both direct.
3 = Alarm 1, Alarm 2 direct deviation.
4 = Alarm 1 reverse absolute (relay energized below alarm limit),
Alarm 2 direct absolute.
5 = Alarm 1 reverse deviation, Alarm 2 direct absolute.
6 = Alarm 1 reverse absolute, Alarm 2 direct deviation.
7 = Alarm 1 reverse deviation, Alarm 2 direct deviation.
8 = Alarm 1 direct absolute, Alarm 2 reverse absolute.
9 = Alarm 1 direct deviation, Alarm 2 reverse absolute
10 = Alarm 1 direct absolute, Alarm 2 reverse deviation.
11 = Alarm 1 direct deviation, Alarm 2 reverse deviation.
12 = Alarm 1, Alarm 2 reverse absolute.
13 = Alarm 1 reverse deviation, Alarm 2 reverse absolute.
14 = Alarm 1 reverse absolute, Alarm 2 reverse deviation.
15 = Alarm 1, Alarm 2 reverse deviation.
By adding 16 to the selected function code (ex. 9+16 setting 25), AL1 becomes sym-
metrical deviation: in this case, a direct alarm corresponds to an alarm with relay ener-
gized outside the "window", while a reverse alarm corresponds to an alarm with relay
energized inside.
By adding 32, AL2 becomes symmetrical deviation.
By adding 48, both alarms become symmetrical deviation.
Out/: Main output function (Heat/Cool) and AL1 (PD) enable HB alarm and selection
of temperature scale (°C or °F)
Set code for selected combination of functions as per the table..
Nr. Al.HB AL1 OUT
0 Disabled NO PD HEAT
1 Enabled NO PD HEAT
2 Disabled PD HEAT
3 Enabled PD HEAT
4 Disabled NO PD COOL
5 Enabled NO PD COOL
6 Disabled PD COOL
7 Enabled PD COOL
By adding the following 6 STEPS to the 16 combinations, you can get various combi-
nations for AL3.
+0 AL3 NORMAL DIRECT ABSOLUTE
+16 AL3 NORMAL DIRECT DEVIATION
+32 AL3 NORMAL REVERSE ABSOLUTE
+48 AL3 NORMAL REVERSE DEVIATION
+80 AL3 DIRECT DEVIATION WINDOW*
+112 AL3 REVERSE DEVIATION WINDOW*
When limit AL3 = 0 or is negative, AL3 remains energized or de-energized at all times.
Note: The PD alarm cannot be symmetrical.
7 • PROGRAMMING
Phase 0 It, dt CFG1
<> = SETTING
Scale Nr. Al.HB AL1 OUT
°C 8 Disabled NO PD HEAT
°C 9 Enabled NO PD HEAT
°C 10 Disabled PD HEAT
°C 11 Enabled PD HEAT
°C 12 Disabled NO PD HEAT
°C 13 Enabled NO PD HEAT
°C 14 Disabled PD HEAT
°C 15 Enabled PD HEAT
TyP/ Type of input probe or linear scale.
Cod. 1000
0 J 0...800°C/32...999°F
1 K 0...999°C/32...999°F
2 N 0...999°C/32...999°F
3 S 0...999°C/32...999°F
4 R 0...999°C/32...999°F
5 T -100...400°C/-148...752°F
6 PT100 -199...400°C/-199...752°F
7 PT100 -19,9...99,9°C/-19,9...99,9°F
8 0-50mV no decimals (xxx)
9 0-50mV 1 decimals (xx.x)
10 0-50mV 2 decimals (x.xx)
11* PT100 -19,9...99,9°C/-3,8...99,9°F
12 10-50mV no decimals (xxx)
13 10-50mV 1 decimals (xx.x)
14 10-50mV 2 decimals (x.xx)
* Hardware version for RTD input with double resolution for greater stability of tenth of
degree. This version does not allow reconfiguration of the input type. For TC probes type S
and R, precision is in the instrument class (0.5%) for temperatures >200°C.
Ct.A / AL1 Cycle time in range 0...200 sec.
dt.A / AL1 Derivative time in range 0.00...9.99 min. (1000)
0.00...19.99 min (1001-1101).
oFt / Input offset adjustment
for 1001/1101:
-300/300 for type 0,1,2,3,4,5,6,8
-30.0/30.0 for type 7,9,11
-3.00/3.00 for type 10
for 1000:
-199/300 for type 0,1,2,3,4,5,6,8
-19.9/30.0 for type 7,9,11
-1.99/3.00 for type 10
LO.S / Minimum value of setpoint and absolute alarms in scale range of selected
probe. Start of linear scale for probe type 8, 9, 10, 12, 13, 14.
Hl.S / Maximum value of setpoint and absolute alarms in scale range of selected
probe. End of linear scale for probe type 8,9,10, 12, 13, 14.
rEL/ Setting of alarm output state in case of broken probe (message Sbr/Err on dis-
play), according to table:
rEL Output AL1
0 ON
1 ON
2 OFF
3 OFF
4 ON
5 ON
Scale
6 OFF
°F
7 OFF
°F
Note: In case of broken probe, each relay assumes the set state (ON = energized,
°F
OFF = de-energized), which does not depend on the type of alarm (direct or reverse).
°F
A.r.F/ Selection of alarm output function.
°F Let you assign one of the following functions to each alarm output: Normal Alarm, HB
Alarm, LBA Alarm, Alarm disabled (OFF logic state).
°F
Choose one of the 63 combinations according to the table:
°F
Ar.F Output AL1 Output AL2
°F
0 AL1
1 HB
2 LBA
3 OFF
4 AL1
5 HB
6 LBA
7 OFF
By setting +0 output AL3 has function AL3
By setting +16 output AL3 has function HB
By setting +32 output AL3 has function LBA
By setting +48 output AL3 is always OFF
14
1001/1101
J 0...800°C/32...1472°F
K 0...1300°C/32...1999°F
N 0...1300°C/32...1999°F
S 0...1600°C/32...1999°F
R 0...1600°C/32...1999°F
T -100...400°C/-148...752°F
PT100 -200...400°C/-328...752°F
PT100 -199,9..199,9°C/ -199,9..199,9°F
0-50mV no decimals (xxxx)
0-50mV 1 decimals (xxx.x)
0-50mV 2 decimals (xx.xx)
PT100 -19,9...199,9°C/-3,8...199,9°F
10-50mV no decimals (xxxx)
10-50mV 1 decimals (xxx.x)
10-50mV 2 decimals (xx.xx)
Output AL2 OUTPUT AL3
ON ON
ON OFF
ON ON
ON OFF
OFF ON
OFF OFF
OFF ON
OFF OFF
Ar.F Output AL1 Output AL2
AL2 8 AL1
AL2 9 HB
AL2 10 LBA
AL2 11 OFF
HB 12 AL1
HB 13 HB
HB 14 LBA
HB 15 OFF
LBA
LBA
LBA
LBA
OFF
OFF
OFF
OFF