ENGLISH
111
6.6.5
GI: Integral gain coefficient
In the event of significant pressure drops on sudden increases in flow, or a slow system response, increase the value of GI. Otherwise,
in the event of pressure oscillations around the setpoint, reduce the value of GI.
A typical example in which the value of GI should be reduced is that in which the inverter is located far from the electric
pump. This distance causes hydraulic elasticity which influences control of PI and therefore pressure regulation
.
IMPORTANT:
To obtain satisfactory pressure settings, both values GP and GI should be adjusted.
6.6.6
FS: Maximum rotation frequency
This sets the maximum pump rotation frequency.
This sets a maximum rpm limit and can be set between FN and FN - 20%.
FS, in any conditions of regulation, ensures that the electric pump is never controlled at a frequency higher than the set value.
FS can be automatically reconfigured following modifications to FN, when the above ratio is not verified (e.g. if the value of FS is less
than FN - 20%, FS will be reset to FN - 20%).
6.6.7
FL: Minimum rotation frequency
FL is used to set the minimum pump rotation frequency. The minimum admissible value is 0 [Hz], and the maximum is 80% of FN; for
example, if FN = 50 [Hz], FL can be set between 0 and 40[Hz].
FL can be automatically reconfigured following modifications to FN, when the above ratio is not verified (e.g. if the value of FL is
greater than 80% of the set FN value, FL will be reset to 80% of FN).
Set a minimum frequency according to the pump manufacturer's specifications
.
The inverter will not control the pump at a frequency below FL; this means that if the pump, at the frequency FL, generates
a pressure above the set point, there will be a pressure overload in the system.
6.6.8
Setting the number of inverters and reserves
6.6.8.1
NA: Active inverters
This sets the maximum number of inverters involved in pumping
It can be set with a value between 1 and the number of inverters present (max. 8). The default value for NA is N, i.e. the number of
inverters in the series; this means that if inverters are removed or inserted in the series, NA always has the same number as that of
the inverters, as read automatically. If a value other than N is entered, the system sets to the maximum number of inverters that can
be involved in pumping.
This parameer is used when there is a limited number of pumps to be kept in operation, and if one or more inverters are to be kept as
reserves (see IC: Configurazione della riserva section 6.6.8.3 and the following examples).
In the same menu page, the user can view (without the option of modification) a further two system parameters related to this value,
i.e. N, the number of inverters detected automatically by the system, and NC, the maximum number of simultaneous inverters.
6.6.8.2
NC: Simultaneous inverters
This sets the maximum number of inverters that can operate simultaneously.
It can be set with a value from 1 to NA. By default NC is set with the value NA; this means that whatever increase applied to NA, NC
is always set with the value of NA. If a different value from NA is set, the system sets to the set maximum number of simultaneous
inverters. This parameter is used when there is a limited number of pumps to be kept in operation (see IC: Configurazione della riserva
section 6.6.8.3 and the following examples).
In the same menu page, the user can view (without the option of modification) a further two system parameters related to this value,
i.e. N, the number of inverters detected automatically by the system, and NA, the number of active inverters.
Summary of Contents for AD 1.0 AC
Page 13: ...ITALIANO 11 Figura 2 Fissaggio e distanza minima per la circolazione d aria...
Page 74: ...ENGLISH 72 Figure 2 Fixture and minimum clearance for air circulation...
Page 135: ...FRAN AIS 133 Figure 2 Fixation et distance minimum pour la circulation de l air...
Page 196: ...DEUTSCH 194 Abbildung 2 Befestigung und Mindestabstand f r die Luftzirkulation...
Page 257: ...ESPA OL 255 Figura 2 Fijaci n y distancia m nima para la circulaci n del aire...
Page 269: ...ESPA OL 267 Figura 13 Ejemplo de conexi n de las entradas...
Page 312: ...310 IEC 60634 1...
Page 313: ...311 1 6 1 1...
Page 317: ...315 1 2 1 1 1 1 2 5 2 1 2 1 2 2...
Page 318: ...316 2...
Page 319: ...317 2 2 3 3 15 2 2 1 1a 2a...
Page 320: ...318 4a 5b 1b 127 240 240 480 3 6 3b...
Page 324: ...322 2 2 2 GP GI 6 6 4 6 6 5 8 A B C D...
Page 332: ...330 3 14 64 X 128 4 MODE SET 12 9 MODE 1 SET 11 3 EEprom SET 6 SET MODE 3 1 11...
Page 333: ...331 3 2 1 2 3 2 1 MODE SET MODE 10 2 2 5 5 5 2 2 12...
Page 335: ...333 3 2 2 13 SET 15 15 14 16...
Page 337: ...335 17 15 15 3 4 PW 6 6 16 GO SB...
Page 338: ...336 4 4 1 Link 8 4 2 4 2 1 Link Link 16 18 Link...
Page 367: ...365 OC 10 6 OF 10 6 33 8 8 1 PMW 4 2 8 2 8 3 8 3 SET EE EEprom FLASH...
Page 379: ...NEDERLANDS 377 Afbeelding 2 Bevestiging en minimumafstand voor luchtrecirculatie...
Page 440: ...SVENSKA 438 Fig 2 Fasts ttning och min utrymme f r luftcirkulation...
Page 501: ...T RK E 499 ekil 2 Hava sirk lasyonu tesisat ve minimum a kl k...
Page 556: ...554 IEC 364 1 inverter...
Page 557: ...555 1 Inverter inverter inverter 6 inverter 1 1...
Page 561: ...559 1 2 1 1 inverter inverter 1 1 2 5 inverter 2 1 inverter 2 1 2 2 C...
Page 562: ...560 2...
Page 563: ...561 2 2 3 3 inverter 15 inverter 2 2 1 inverter inverter 1a 2a...
Page 564: ...562 4a 5b 1b V 127 240 240 480 mm 3 6 3b azione...
Page 568: ...566 2 2 2 inverter inverter GP GI 6 6 4 6 6 5 inverter 8 A B C D...
Page 576: ...574 3 14 oled 64 X 128 4 MODE SET 12 inverter 9 MODE 1 SET 11 3 EEprom SET 6 SET MODE 3 1 11...
Page 577: ...575 3 2 1 2 3 2 1 MODE SET Setpoint MODE 10 ONOMA TOY MENOY 2 Setpoint 2 5 5 5 2 2 12...
Page 581: ...579 17 15 15 3 4 Password inverter password password inverter password PW 6 6 16 GO SB FAULT...
Page 623: ...ROM N 621 Figura 2 Fixarea i distan a minim pentru circula ia aerului...
Page 684: ...POLSKI 682 Rys 2 Mocowanie oraz minimalna odleg o na potrzeby cyrkulacji powietrza...
Page 745: ...MAGYAR 743 2 bra R gz t s s minim lis t vols g a szell z leveg kering se rdek ben...
Page 800: ...798 IEC 364 1...
Page 801: ...799 1 3 1 1...
Page 805: ...803 1 2 1 1 1 1 2 5 2 1 2 1 2 C...
Page 806: ...804 2...
Page 807: ...805 2 2 3 3 15 2 2 1 1 2a...
Page 808: ...806 4a 5b 1b V 127 240 240 480 3 6 3b...
Page 812: ...810 2 2 2 GP GI 6 6 4 6 6 5 8 A B C D...
Page 817: ...815 V 36 36 12V A 3 3 3 3 2 13 9 11 8 13...
Page 819: ...817 3 14 64 X 128 4 MODE SET and 12 9 MODE 1 SET 11 3 EEprom SET 6 SET MODE 3 1 11...
Page 820: ...818 3 2 1 2 3 2 1 10 2 2 5 5 5 2 2 12...
Page 824: ...822 15 3 4 GO SB FAULT...
Page 825: ...823 4 4 1 8 4 2 4 2 1 16 18...
Page 862: ...ESKY 860 Obr zek 2 P ipevn n a minim ln vzd lenost kv li cirkulaci vzduchu...
Page 917: ...915 IEC 60634 1...
Page 918: ...916 1 6 1 1...
Page 922: ...920 1 2 1 1 1 1 2 5 2 1 2 1 2 2...
Page 923: ...921 2...
Page 924: ...922 2 2 3 3 15 2 2 1 1a 2a...
Page 925: ...923 4a 5b 1b 127 240 240 480 3 6 3b...
Page 929: ...927 2 2 2 GP GI 6 6 4 6 6 5 8 A B C D...
Page 931: ...929 10 4 20 6 4 20 PR 6 5 7 4 20 2 18 J5 GND 1 J5 GND o IN 11 J5 4 20 7 OUT 8 10 11 IN...
Page 935: ...933 13 J5 I1 11 17 16 18 16 17 I2 11 15 16 18 15 16 I3 11 14 13 18 13 14 I4 11 12 13 8 12 13 9...
Page 937: ...935 3 14 64 X 128 4 MODE SET 12 9 MODE 1 SET 10 3 EEprom SET 6 SET MODE 3 1 11...
Page 938: ...936 3 2 1 2 3 2 1 MODE SET MODE 10 2 2 5 5 5 2 2 11...
Page 940: ...938 3 2 2 13 SET 15 15 14 16...
Page 942: ...940 17 14 15 3 4 PW 6 6 16 GO SB FAULT...
Page 943: ...941 4 4 1 Link 8 4 2 4 2 1 Link Link 16 18 Link...
Page 946: ...944 4 3 1 2 1 4 3 1 3 SET MODE LA RC MS FS SO AE O1 1 O2 2 4 4 2 2 4 2 5 4 5 ET 6 6 9 FL...
Page 969: ...967 10 0 Mode Set PW 0 PW 2 7 3 6 6 16 1 PW PW PW PW 0 PW 0 0 PW PW PW PW PW 0 PW...