Hitachi SJ700-2 Bedienungsanleitung

1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274

Zur Seite of

Richtige Gebrauchsanleitung

Die Vorschriften verpflichten den Verkäufer zur Übertragung der Gebrauchsanleitung Hitachi SJ700-2 an den Erwerber, zusammen mit der Ware. Eine fehlende Anleitung oder falsche Informationen, die dem Verbraucher übertragen werden, bilden eine Grundlage für eine Reklamation aufgrund Unstimmigkeit des Geräts mit dem Vertrag. Rechtsmäßig lässt man das Anfügen einer Gebrauchsanleitung in anderer Form als Papierform zu, was letztens sehr oft genutzt wird, indem man eine grafische oder elektronische Anleitung von Hitachi SJ700-2, sowie Anleitungsvideos für Nutzer beifügt. Die Bedingung ist, dass ihre Form leserlich und verständlich ist.

Was ist eine Gebrauchsanleitung?

Das Wort kommt vom lateinischen „instructio”, d.h. ordnen. Demnach kann man in der Anleitung Hitachi SJ700-2 die Beschreibung der Etappen der Vorgehensweisen finden. Das Ziel der Anleitung ist die Belehrung, Vereinfachung des Starts, der Nutzung des Geräts oder auch der Ausführung bestimmter Tätigkeiten. Die Anleitung ist eine Sammlung von Informationen über ein Gegenstand/eine Dienstleistung, ein Hinweis.

Leider widmen nicht viele Nutzer ihre Zeit der Gebrauchsanleitung Hitachi SJ700-2. Eine gute Gebrauchsanleitung erlaubt nicht nur eine Reihe zusätzlicher Funktionen des gekauften Geräts kennenzulernen, sondern hilft dabei viele Fehler zu vermeiden.

Was sollte also eine ideale Gebrauchsanleitung beinhalten?

Die Gebrauchsanleitung Hitachi SJ700-2 sollte vor allem folgendes enthalten:
- Informationen über technische Daten des Geräts Hitachi SJ700-2
- Den Namen des Produzenten und das Produktionsjahr des Geräts Hitachi SJ700-2
- Grundsätze der Bedienung, Regulierung und Wartung des Geräts Hitachi SJ700-2
- Sicherheitszeichen und Zertifikate, die die Übereinstimmung mit entsprechenden Normen bestätigen

Warum lesen wir keine Gebrauchsanleitungen?

Der Grund dafür ist die fehlende Zeit und die Sicherheit, was die bestimmten Funktionen der gekauften Geräte angeht. Leider ist das Anschließen und Starten von Hitachi SJ700-2 zu wenig. Eine Anleitung beinhaltet eine Reihe von Hinweisen bezüglich bestimmter Funktionen, Sicherheitsgrundsätze, Wartungsarten (sogar das, welche Mittel man benutzen sollte), eventueller Fehler von Hitachi SJ700-2 und Lösungsarten für Probleme, die während der Nutzung auftreten könnten. Immerhin kann man in der Gebrauchsanleitung die Kontaktnummer zum Service Hitachi finden, wenn die vorgeschlagenen Lösungen nicht wirksam sind. Aktuell erfreuen sich Anleitungen in Form von interessanten Animationen oder Videoanleitungen an Popularität, die den Nutzer besser ansprechen als eine Broschüre. Diese Art von Anleitung gibt garantiert, dass der Nutzer sich das ganze Video anschaut, ohne die spezifizierten und komplizierten technischen Beschreibungen von Hitachi SJ700-2 zu überspringen, wie es bei der Papierform passiert.

Warum sollte man Gebrauchsanleitungen lesen?

In der Gebrauchsanleitung finden wir vor allem die Antwort über den Bau sowie die Möglichkeiten des Geräts Hitachi SJ700-2, über die Nutzung bestimmter Accessoires und eine Reihe von Informationen, die erlauben, jegliche Funktionen und Bequemlichkeiten zu nutzen.

Nach dem gelungenen Kauf des Geräts, sollte man einige Zeit für das Kennenlernen jedes Teils der Anleitung von Hitachi SJ700-2 widmen. Aktuell sind sie genau vorbereitet oder übersetzt, damit sie nicht nur verständlich für die Nutzer sind, aber auch ihre grundliegende Hilfs-Informations-Funktion erfüllen.

Inhaltsverzeichnis der Gebrauchsanleitungen

  • Seite 1

    HIT A CHI INVERTE R SJ700-2 SERIES INSTRU CTION M A NU A L Read thr ough this I nstruct ion Manua l , and ke ep it h and y for f u ture refer ence. NT204AX[...]

  • Seite 2

    Introductio n Thank you f or purcha s ing the Hita chi SJ700 -2 Ser ies Inverter . This Instruct i on Manua l des cri bes how to han dle and maintain the Hitach i SJ70 0 Ser ies In v erter . Read this Instruct i on Manua l care f ully be f ore us i ng the i n vert er , and then keep it han dy for thos e wh o opera te, maintain , and insp ect the in[...]

  • Seite 3

    Safety In str uctions i Safety In str uctions Be su re to read th is Ins tructi on Manu al and appe nded documents t horou ghly be f ore i nst al ling, op erating, maintain i ng, or i nsp ecting the in v erter . In this Ins t ruction Man ual, s afety ins t ructions are c l ass i fied into tw o l evels, na m ely W AR NING an d CAUTION. : I ndicates [...]

  • Seite 4

    Safety In str uctions ii 2. Wiring W ARNING - Be s ure to grou nd the inver ter . Ot herw i s e, you run the r isk o f electric sho ck or fire. - Commi t wiring w ork to a qualified e l ectrician. Otherw i se, you run the r isk o f electric sh ock or fire. - Before w i ring, make sure that the pow er sup ply i s of f. Othe rw ise, you run the r i s[...]

  • Seite 5

    Safety In str uctions iii 3. Operatio n W ARNING - W h il e pow er i s s upp li ed to the in v erter , do not touch an y terminal or i nterna l part o f the in v er ter , check signa ls, or conne ct or disco nnect any w i re or co nnector . Otherw i se , you run the ris k of electri c sho ck or fire. - Be s ure to close the ter mi nal block cover b[...]

  • Seite 6

    Safety In str uctions iv 4. Maintena n ce, ins p ection, and p arts re plac ement W ARNING - Before ins pecting the in v erter , be sure to turn o ff t he po we r su pply and w ai t f or 10 minu tes or m ore. Otherw ise, you run the r i sk o f electric s hock. (Be f ore inspe ction, confirm that the Charge la m p on th e inverter is of f and the DC[...]

  • Seite 7

    Safety In str uctions v Precautions Concerning Electromagnetic Co mpati bility (EMC ) The SJ700 s eri es inverter con f orms to the requi re m ent s of Electro m agnetic Co m p atibil ity (EMC) Direc tive (2004 /108/EC). How ev er , w hen using the in v erter i n Euro pe, you m us t comp ly w ith the fol low ing sp ecifi cations and require m ents [...]

  • Seite 8

    Safety In str uctions vi Precautions Concerning Compliance wit h UL and CUL S tan dards (S tand ards to be m e t : UL508C and CS A C22.2 No. 14- 05) The SJ700 s eri es inverter is an op en-type AC in v erter w ith 3-phas e i nput and ou tput, intended for us e i n an enclos ure. The inver ter sup plies both voltag e and f r eque ncy , both of which[...]

  • Seite 9

    Safety In str uctions vii 9. This Ins truction Manu al ind i cates the s i zes o f the d istribution f use and c i rcuit breaker that mu st be conne cted to this i n verter . The fol lowing t able list s the in v ers e time and current ratings of the cir cuit breake rs ( with rated v o l tage of 600 V) to be conn ected to the indi v idual inv erter[...]

  • Seite 10

    Contents viii Chapter 1 Overview 1.1 Insp ection o f the Purcha se d Produ ct ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 1 - 1 1.1.1 Insp ecting the produ ct ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・[...]

  • Seite 11

    Contents ix 4.1.14 Cumulative pow er m on itoring (d01 5, b078, b07 9) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 4 4.1.15 Cumulative opera tion RU N time monitoring (d016 ) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 4 4.1.16 Cumulative pow er-on time m o[...]

  • Seite 12

    Contents x 4.2.30 Overl oad restriction/over load not i ce (b021 to b026 , C00 1 to C008, C02 1 to C026, C040 , C041, C1 1 1) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 39 4.2.31 Overcurrent res trai nt (b0 27) ・・・・[...]

  • Seite 13

    Contents xi 4.2.75 Re v ers e rotation signa l (R VR) (C 021 to C02 6) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 70 4.2.76 Major failure signa l (MJA) (C0 21 to C026 ) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 70 4.2.77 W i[...]

  • Seite 14

    Contents xii 4.3.15 S pee d/pos i ti on sw it ching func tion (SPD) ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ 4 - 108 4.3.16 Zero-return func tion ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・?[...]

  • Seite 15

    Contents xiii A pp endix Appe ndix ・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・・ ・・・・・・・・・・・・ A - 1 In d ex Index ・・・・・・・・・・・・・・・・・・・・・?[...]

  • Seite 16

    Chapter 1 Overview This chapter describes the inspection of the purchased product, the product warranty , and the names of p arts. 1.1 Inspection of the Purchased Product ··············· 1 - 1 1.2 Method of Inquiry and Product W arranty ········· 1 - 2 1.3 Exterior Views and Names of Pa rts ·················[...]

  • Seite 17

    [...]

  • Seite 18

    Chapter 1 Overview 1 - 1 1.1 Inspection of the Purchased Product 1.1.1 Inspecting the product After unp acking, inspect the prod uct as described below . If you find the product to be abnormal or defective, cont act your supplier or local Hit achi Distributor . (1) Check the product for damage (including falling of part s and dent s in the inverter[...]

  • Seite 19

    Chapter 1 Overview 1 - 2 1.2 Method of Inquiry and Product W arranty 1.2.1 Method of inquiry For an inquiry about produ ct damage or faults or a quest ion about the product, not ify your supplier of the following information: (1) Model of your inverter (2) Serial number (MFG No.) (3) Date of purchase (4) Content of inquiry - Location and condition [...]

  • Seite 20

    Chapter 1 Overview 1 - 3 1.3 Exterior V iews and Names of Parts The figure below shows an exterior view of the inverter (model SJ700-150LFF 2/HFF2 to SJ700-220LFF2/HFF2). Exterior view of shipped inverter For the wiring of the main circuit and con trol ci rcuit terminals, open the terminal block cover . For mounting optional circuit boards, open th[...]

  • Seite 21

    Chapter 2 I nst al lation and W iring T his ch apt er describes how to instal l the in verter and the wiring of main circuit and control signal termin als wi th typical exam ples of wiring. 2.1 Inst al lation ・・・・・・・・・・・・・ ・・・・・・・・・・・・・・・・・・ 2 - 1 2.2 W ir ing ・・・・・・・・・[...]

  • Seite 22

    [...]

  • Seite 23

    Chapter 2 Inst allat ion an d Wiring 2 - 1 2.1 Inst allat ion CA UT ION - Ins ta ll the inver ter on a non- f l amma ble sur f ace, e.g. , met al. Otherw ise, you run the ri sk o f fire. - Do no t place flammab le materia ls near the ins tal led in verter . Othe rw ise, you run the r i sk o f fi re . - W hen carrying the inverter , do not ho l d it[...]

  • Seite 24

    Chapter 2 Inst allat ion an d Wiring 2 - 2 2.1.1 Precautions for ins t allation (1) T rans portation The in v erter us es plastic p arts . W hen carry i ng the i n verter , han dle i t care f ully to pre v ent da m age t o the p art s. Do not carry the in v erter by hold i ng the front or ter minal block co v er . Doing so may cau s e the inverter [...]

  • Seite 25

    Chapter 2 Inst allat ion an d Wiring 2 - 3 (6) I ns tallation m ethod and pos i tion Ins tall the inverter v ert ically and s ecurely with screw s or bolts on a surface that is free from v i bra tions and that can be ar the inverter w eight. I f the in v erter is not ins tall ed vertically , its coo ling per f or m ance ma y be deg raded and trippi[...]

  • Seite 26

    Chapter 2 Inst allat ion an d Wiring 2 - 4 Se ct ion to be cut of f Joint 2.1.2 Backing pl a te (1) F or models with 22 kW or less cap aci ty On the back ing p late, cut the j oints around each s ection to be cut o ff with cutting pl iers or a cu t ter , remove the m , and then per f or m the wir ing. (2) F or the mo dels w i th 30 k W or less cap [...]

  • Seite 27

    Chapter 2 Inst allat ion an d Wiring 2 - 5 2.2 Wiring W ARNING - Be s ure to grou nd the inver ter . Ot herw i s e, you run the r isk o f electric sho ck or fire. - Commi t wiring w ork to a qualified e l ectrician. Otherw i se, you run the r isk o f electric sh ock or fire. - Before w i ring, make sure that the pow er sup ply i s of f. Othe rw ise[...]

  • Seite 28

    Chapter 2 Inst allat ion an d Wiring 2 - 6 2.2.1 T erminal connection di a gram and explanation of termin als and switch setti ngs 3 - phase powe r supply 200 V cl a ss: 200 t o 240 V +10%, - 15% (50/60 Hz ± 5%) 400 V cl a ss: 380 t o 480 V +10%, - 15% (50/60 Hz ± 5%) Jumper W hen c onn e ctin g s eparate power su pplies t o main and control circ[...]

  • Seite 29

    Chapter 2 Inst allat ion an d Wiring 2 - 7 (1) Ex planat i on o f main circuit ter mi nals Symbol T erminal name D e script ion R, S, T (L1, L2, L3) Main power inp ut C o nn e ct to the AC p ower s upply . Leave th ese ter minals unc onn ected wh en usi ng a reg ener ative conv erter (HS 900 s eries). U, V , W (T1, T2, T3) Inverter ou tput C o nn e[...]

  • Seite 30

    Chapter 2 Inst allat ion an d Wiring 2 - 8 Symbol T erminal nam e Descr iption E lectr ic property Contact input Functio n selection and logic switching PLC I ntel li gent input (comm on) T o switc h the control l ogic between sink logic and sour ce logi c, change the jum per connecti on of this (PLC) termi nal to another term inal on the control c[...]

  • Seite 31

    Chapter 2 Inst allat ion an d Wiring 2 - 9 A bo ut the emergency stop f unction (dis abled by the f actory setting) - The e m ergency s top function s huts off the inverter ou tput (i.e. s top s the switching opera tion of the main circuit ele ments ) in res pon se to a command f ro m a ha rdw are ci rcuit via an i ntelligent input ter mi nal w ith[...]

  • Seite 32

    Chapter 2 Inst allat ion an d Wiring 2 - 10 Note: If th e data o f an opt i onal oper ator (S R W or SR W -EX) is c opied: If op e r ator d a t a is c opied t o your SJ70 0 s eries inv e rt er w hose s lid e s witc h S W 1 is ON f r o m anot her SJ7 00 s e r ies invert e r w hose s lide switch SW 1 is OFF or an SJ3 00 s eries inver t e r , th e dig[...]

  • Seite 33

    Chapter 2 Inst allat ion an d Wiring 2 - 1 1 2.2.2 Wiring of the main circui t (1) W ir i ng ins t ructions Before w i ri ng, be s ure to con f irm that the Ch arge l amp o n the inverter i s of f. W hen t he inverter po w er has bee n turned on once, a d angerous high v olta ge re m ains in the internal cap aci tors f or some ti me after po w er-o[...]

  • Seite 34

    Chapter 2 Inst allat ion an d Wiring 2 - 12 3) DC reactor conne ction ter minals (PD and P) - Use these ter m inals to connect the opt ional DC po w er factor reactor (DCL). As the factory s etting, ter mi nals P and PD are con necte d by a jumper . Remo v e this to connect the DCL. - The cable leng th betw een the i nv e r ter and DCL must b e 5 m[...]

  • Seite 35

    Chapter 2 Inst allat ion an d Wiring 2 - 13 (2) Layout o f main circu i t termina l s The figures below s ho w the ter mi nal layout on the ma in circui t termina l block of the inver ter . T er m inal l ayout Inverte r mode l SJ700-0 55 to SJ700-0 75LFF2 SJ700-0 55 to SJ700-0 75HFF 2 R0 and T0: M 4 Gr o und t ermin al: M6 Other t erminals: M6 RB R[...]

  • Seite 36

    Chapter 2 Inst allat ion an d Wiring 2 - 14 T er m inal l ayout Inverte r mode l SJ700-3 00LFF R0 and T0: M 4 Gr o und t ermin al: M6 Other t erminals: M8 SJ700-3 00HFF R0 and T0: M 4 Gr o und t ermin al: M6 Other t erminals: M6 R (L1) S (L2) T (L3) PD (+1) P (+) N (-) U (T1) V (T2) W (T3) R0 T0 G G SJ700-3 70LFF SJ700-3 70HFF R0 and T0: M 4 Gr o u[...]

  • Seite 37

    Chapter 2 Inst allat ion an d Wiring 2 - 15 T er m inal l ayout Inverte r mode l R (L1) S (L2) T (L3 ) PD (+1) P (+) N (-) U (T1 ) V (T2) W (T3) R 0 T 0 charg e l um p G G SJ700-5 50LFF2 R0 and T0: M 4 Gr o und t ermin al: M8 Other t erminals: M10 R e ferenc e: L eakage c urrent b y inverter with mod el EMC filter enabl ed or dis abled (ref er ence[...]

  • Seite 38

    Chapter 2 Inst allat ion an d Wiring 2 - 16 Power suppl y Magnetic contactor Motor Inverte r (3) Applicable periphe ral equ i pment See It e m (4), "R eco mm ende d cable gauge s, w iring acce sso rie s, and crimp ter minals." Note 1: The periphe ral equ ipmen t desc ribed he re i s applic able whe n the i nverte r conne cts a stan dard H[...]

  • Seite 39

    Chapter 2 Inst allat ion an d Wiring 2 - 17 (4) Recomm end ed cable gaug es , wiring acces s ories, and crim p terminals Note: F or co m p liance w i th CE and UL st anda rds, see the sa fety precaut i ons concerning EMC an d the compliance with UL and CU L st anda rds und er Saf ety In structions. The tab le be low lists t he s pecifications of ca[...]

  • Seite 40

    Chapter 2 Inst allat ion an d Wiring 2 - 18 2.2.3 Wiring of the control circuit (1) Wiring instruct ions 1) T ermi na l s L and CM1 are co mm on to I/O s ignals an d isolated f rom ea ch other . Do not conn ect the se comm on ter minals to each other or groun d them. Do not grou nd thes e termi na l s v ia any e x terna l devices . (Check tha t the[...]

  • Seite 41

    Chapter 2 Inst allat ion an d Wiring 2 - 19 (4) Connecting a progra mm able contro ll er to intel ligent inpu t termina ls W he n using the inte rnal i n terface power sup ply When us ing an ex ternal powe r supp ly (R e mo ve the ju mper fr om th e contr ol circuit t ermin al block.) Sink log ic Source lo gic (5) Conn ecting a progra mm ab le con [...]

  • Seite 42

    Chapter 2 Inst allat ion an d Wiring 2 - 20 2.2.5 Selecti on and wiri ng of re genera tiv e braki ng resistor (on 5.5 kW to 22 kW model s) The SJ700-2 se ries inverter models w i th cap acit ies of 5.5 to 22 k W ha v e an interna l regen erative bra king circuit. Conn ecting an opt i onal regene rati ve braking res i stor to RB and P ter mi nals in[...]

  • Seite 43

    Chapter 3 Operation This chapter describes typical methods of operating the inverte r , how to operate the digit al operator , and how to make a test run of the inverter . 3.1 Operating Methods ··········································· 3 - 1 3.2 How T o Operate the Digital Oper ator ··········?[...]

  • Seite 44

    [...]

  • Seite 45

    Chapter 3 Operation 3 - 1 3.1 Operating Methods W ARNING - While power is su pplied to the inverter , do not touch any terminal or internal part of the inverter , check signals, or connect or disconne ct any wire or connec tor . Otherwise, you run the risk of elect ric shock or fire. - Be sure to close the termin al block cover before turning on th[...]

  • Seite 46

    Chapter 3 Operation 3 - 2 Y ou can operate the inverter in different ways, depen ding on how to input the operation and frequency-setting commands a s described below . This section describes the features of operatin g methods and the items required for operation. (1) Entering operation and frequen cy-setting commands from the digit al operator Thi[...]

  • Seite 47

    Chapter 3 Operation 3 - 3 3.2 How T o Operate the Digit al Operator (OPE-S) 3.2.1 Names and functions of component s Name Function POWER lamp Lights when the control circuit po wer is on. ALARM lamp Lights to indicate that the inverter has tripped. RUN (operation) lamp Light s to indica te that the inverter is operating. PRG (program) lamp Lights w[...]

  • Seite 48

    Chapter 3 Operation 3 - 4 3.2.2 Code display system and key operations This section describes typical exampl es of digital operator operatio n (in basic and full display modes) a nd an example of special digit a l operator operation in extended function mode U. The initial display on the monitor screen after po we r-on depends on the setting of fun[...]

  • Seite 49

    Chapter 3 Operation 3 - 5 (1) Example of operation in basic disp l ay mode ("b037" = "04" [factory setting]) - Only basic p arameters can be displayed in basic display mode. (All p arameters in monitor mode, four parameters in fun ction mode, or 20 parameters in extended function mode) - Other pa rameters are not displayed. T o [...]

  • Seite 50

    Chapter 3 Operation 3 - 6 Key operation and transitio n of the codes on display Key operation and trans ition of the monitore d data on display Pressing the or key respectively scrolls up or down the code displayed in code display mode or increases or decreases th e numerical data displayed in dat a display mode. Press the or key until the desired [...]

  • Seite 51

    Chapter 3 Operation 3 - 7 (2) Example of operation in full display mode ("b037" = "00") All param eters can be displayed in full display mode. The display sequence of parameters matches their sequence shown in Chapter 8, "Li st of Data Settings." Pressing the or key respectively scrolls up or down the code displayed in[...]

  • Seite 52

    Chapter 3 Operation 3 - 8 (3) Code/data display and key operatio n in extended function mode U The extended function mod e U differs in operati on from other exten ded function modes because the extended function mode U is used to register (or a utomatically record) other extended-function codes as user-specified U p arameters. *1 The content of th[...]

  • Seite 53

    Chapter 3 Operation 3 - 9 (4) Procedure for directly specif ying or selecting a code - Y ou can specify or select a code or dat a by ent ering each digit of the code or dat a instead of scrolling codes or dat a in the monitor , function, or extended function mode. - The following sho ws an example of the procedure for changing the monitor mod e cod[...]

  • Seite 54

    Chapter 3 Operation 3 - 10 3.3 How T o Make a T est Run This section describes ho w to make a test run of t he inverter that is wired and connected to external devices in a general way as shown below . For the detail ed method of using the digit al operator , see Section 3.2, "How T o Operate the Digit al Operator ." (1) When entering ope[...]

  • Seite 55

    Chapter 3 Operation 3 - 1 1 - Use the and/or key to change the displayed value to "00" for forward operation or "0 1" for reverse operation, and then press the key once to determine the operation direction. (The display revert s to [F004].) 7) Set the monitor mode. - T o monitor the output frequency , display the func tion code [...]

  • Seite 56

    Chapter 3 Operation 3 - 12 (Operating procedure) 1) Confirm that all wirings a re correct. 2) T urn on the earth-leakage breake r (ELB) to supply power to the inverter . (The POWER lamp [red LED] of the digital operator g oes on.) 3) Select the control ci rcuit terminal block as the device to input frequency-setting commands by the frequency source[...]

  • Seite 57

    Chapter 4 Explanation of Functions This chapter describes the functions of the inverter . 4.1 Monitor Mode ··················································· 4 - 1 4.2 Function Mode·················································· 4 - 7 4.3 Functi[...]

  • Seite 58

    [...]

  • Seite 59

    Chapter 4 Explanation of Functions 4 - 1 4.1 Monitor Mode 4.1.1 Output frequency monitoring When the output frequency monitoring function (d001) is selecte d, the inverter displays the output frequency . The inverter displays "0.00" when the frequency output is stopped. The Hz monitor lamp light s up while the inverter is displaying the o[...]

  • Seite 60

    Chapter 4 Explanation of Functions 4 - 2 4.1.5 Intelligent input terminal st atus When the intelligent input terminal st atus function (d005) is selecte d, the inverter displays the st ates of the i nputs to the intelligent input terminals. The internal CPU of the inverter checks each intelligent input for si gnificance, and the inverter displays a[...]

  • Seite 61

    Chapter 4 Explanation of Functions 4 - 3 4.1.8 Actual-frequency monitoring The actual-frequency monitoring functio n is effective only when a motor equipped with an encod er is connected to the inverter and the feedback option board (SJ-FB) is mounted in the i nverter . When the actual-frequency monitorin g function (d008) is selected, the inverter[...]

  • Seite 62

    Chapter 4 Explanation of Functions 4 - 4 4.1.14 Cumulative power monitoring When the cumulative power mo nitoring function is sel ected, the inverter displays the cumulative value of electric power input to the inverter . Y ou can also convert the value to be displayed to gain data by setting the cumulative input power display gain setting (b079 ).[...]

  • Seite 63

    Chapter 4 Explanation of Functions 4 - 5 4.1.19 Life-check monitoring When the life-check monitoring function (d002) is selected, the inverter displays the operating life st atus of two inverter part s output from corresponding intelligent output term inals by using LED se gments of the monitor . The two targe ts of life-check monito ring are: 1: L[...]

  • Seite 64

    Chapter 4 Explanation of Functions 4 - 6 4.1.27 T rip monitoring 1 to 6 When the trip monitoring function (d081 to d086) is sel ected, the inverter displays the trip history dat a. The la st six protective trips the inve rter made can be displayed. Select the trip monitoring 1 (d081) to disp lay the data on the most recent trip. (Display content s)[...]

  • Seite 65

    Chapter 4 Explanation of Functions 4 - 7 4.2 Function Mode 4.2.1 Output frequency setting The output frequency setting function allows you to set the inverter output frequency . Y ou can set the inverter output frequency with this function (F001) only when you have specified "02" for the freque ncy source setting (A001). For other methods[...]

  • Seite 66

    Chapter 4 Explanation of Functions 4 - 8 4.2.4 Frequency source setting The frequency source setting function al lows you to select the method to input the frequency-setting command. Motor rotation direction is i nverted when -10 to 0V is given as frequency command to 02-L terminals. Item Function co de Data Description (00) (V alid only when the O[...]

  • Seite 67

    Chapter 4 Explanation of Functions 4 - 9 4.2.6 Stop mode selection The stop mode selection function all ows you to select one of two methods of stopping the motor when a stop co mmand is input from the digital operat or or via the control circuit terminal block. One is to decelerate the motor accordin g to the specified deceleration time and then s[...]

  • Seite 68

    Chapter 4 Explanation of Functions 4 - 10 4.2.8 Acceleration/deceleration time setting - S pecify a longer time for slower acceleration o r deceleration; specify a shorter time for quicker acce leration or deceleration. - The time set with this function is the time to accelerate (or decelerate) the motor from 0 Hz to the maximum frequency (or vice [...]

  • Seite 69

    Chapter 4 Explanation of Functions 4 - 1 1 4.2.9 Base frequency setting (1) Base frequency and m otor voltage - With the base frequency setting and A VR voltage select functions, adjust the inverter outpu ts (frequency an d voltage) to the motor ratings. - The base freque ncy is the nominal frequency of the motor . Set a base frequency that meet s [...]

  • Seite 70

    Chapter 4 Explanation of Functions 4 - 12 4.2.1 1 External analog input setting (O, OI, and O2) The inverter has the following three types of external analog input terminals: O-L terminal: 0 to 10 V OI-L terminal: 4 to 20 mA O2-L terminal: -10 to 10 V The table bel ow lists the settings of the external analog input termi nals. Item Function code Da[...]

  • Seite 71

    Chapter 4 Explanation of Functions 4 - 13 4.2.12 Frequency operation function The frequency operation function allows you to use the result of an arithmetic operation on two frequency commands a s the actual frequency command or PID feedback dat a. T o use the operation result as the actual freque ncy command, specify "10" for the frequen[...]

  • Seite 72

    Chapter 4 Explanation of Functions 4 - 14 4.2.13 Frequency addition function The frequency addition function allows you to add or subtra ct the value specified as the frequency to be ad ded (A145) to or from the frequency value of a select ed frequency command. T o use this function, assign function "50" (ADD) to an intelligent input term[...]

  • Seite 73

    Chapter 4 Explanation of Functions 4 - 15 (2) S tart/end frequency settings for the O2-L terminal Item Function code Range of data Description Remarks 02 start frequency A1 1 1 -400. to 400.(Hz) Setting of the start frequency 02 end frequency A1 12 -400. to 40 0.(Hz) Setting of the end frequency 02 start-frequency rate A1 13 -100. to 100.(%) Settin[...]

  • Seite 74

    Chapter 4 Explanation of Functions 4 - 16 4.2.17 V/F characteristic curve selection The V/F characteristic cu rve sele ction function allows you to set the output voltage/output frequency (V/f) characteri stic. T o switch the V/F characteristic curve selection among the 1st, 2nd, and 3rd settings, assign functio n "08" (SET) and "17&[...]

  • Seite 75

    Chapter 4 Explanation of Functions 4 - 17 (3) Free V/f characteristic setting The free V/f characteristic setting fu nction allows you to set an arbitrary V/f characteristic by specifying the voltages and frequencies (b100 to b1 13) for the seve n points on the V/f characteristic curve. The free V/f frequencies (1 to 7) set by this function must al[...]

  • Seite 76

    Chapter 4 Explanation of Functions 4 - 18 4.2.18 T orque boost setting The torque boost setting function allows you to compen sate for the voltage drop due to wiri ng and the primary resist ance of the motor so as to improve the motor torque at low speeds. When you select automatic torque bo ost by the torque boost selection (A041/A241 ), adjust th[...]

  • Seite 77

    Chapter 4 Explanation of Functions 4 - 19 (2) Automatic torque boost When automatic torque boost (da ta "01") is sele cted by the torque boost sele ction (A041/A241), the inverter automatically adjust s the output frequency and volt age according to the load on the motor . (During actual operatio n, the automatic torque boost is usually c[...]

  • Seite 78

    Chapter 4 Explanation of Functions 4 - 20 4.2.19 DC braking (DB) setting The DC braking function allows you to apply DC braki ng to the motor according to the load on the motor . Y ou can control DC braking in two ways: the external control through signal input to intelligent input terminals and th e internal control to be performed automatically w[...]

  • Seite 79

    Chapter 4 Explanation of Functions 4 - 21 (2) External DC braking Assign function "07" (DB) to terminal function (C001 to C00 8). T urn the DB terminal on and off to control the dire ct braking, regardless of the setting of DC braking e nable (A051). Adjust the braking force by adjusting the DC bra king force setting (A054). When you set [...]

  • Seite 80

    Chapter 4 Explanation of Functions 4 - 22 (3) Internal DC braking (A051: 01) Y ou can apply DC braking to the motor even without ent ering braking signals via the DB terminal when the inverter sta rts and stop s. T o use the internal DC br aking function, specify "01" for the DC braking enable (A051). Use function "A057" to set [...]

  • Seite 81

    Chapter 4 Explanation of Functions 4 - 23 (4) Internal DC braking (triggered only when the output frequency reaches a set frequen cy) (A051: 02) Y ou can also operate the internal DC braking function so that DC braking is applied to the motor when the inverter output frequency falls to the DC braking frequency setting (A052) o r below . When the in[...]

  • Seite 82

    Chapter 4 Explanation of Functions 4 - 24 4.2.20 Frequency upper limit setting The frequency upper limit setting function allows you to place upper and lower limit s on the inverter output frequency . This function restrict s the input of frequency commands that specify any frequencies ou tside the upper and lo wer limit s. Always set the upper lim[...]

  • Seite 83

    Chapter 4 Explanation of Functions 4 - 25 4.2.21 Jump frequency function The jump frequency function allows you to operate the inverter so that it avoids the resonant frequ ency of the machine driven by the same. Since the inverter avoids the motor o peration with a consta nt output frequency within the specifi ed range of the frequencies to jump w[...]

  • Seite 84

    Chapter 4 Explanation of Functions 4 - 26 4.2.23 PID function The PID function allows you to use the i nverter for the process control on fluid flow , airflow , and pressure. T o enable this function, specify "01 lenabled" or "02 inverted dat a output enabled" for function "A071". Y ou can disable the PID function with[...]

  • Seite 85

    Chapter 4 Explanation of Functions 4 - 27 (2) PID operation 1) P operatio n The proportional (P) operation st ands for the operati on in which the change in op eration quantity is in proportion to the change in t arget value. 2) I operation The integral (I) operation stand s for the operation in which the operation quantity incre ases linearly over[...]

  • Seite 86

    Chapter 4 Explanation of Functions 4 - 28 When you specify the 02 RS485 communicatio n for the PV source setting (A076), transfer dat a as described below . 1) When the ASCII mode is selected (C078 = 00) Use the 01 command for data transfe r . T o transfer feedback data, set the most-significant byte of frequency dat a to "1". Example: Wh[...]

  • Seite 87

    Chapter 4 Explanation of Functions 4 - 29 If the inverter is under the normal PID control and the PID operation result i s a negative value, the frequency command to the inverter will be limited to 0 Hz. However , when "02" (enabling the inverted output) is set for the PID Function Enable (A071 ), the PI D operation result to be output to[...]

  • Seite 88

    Chapter 4 Explanation of Functions 4 - 30 F002/F202/F302: Acceleration (1) time setting, 1st/2nd/3rd motors F003/F203/F303: Deceleration (1) time setting, 1st/2nd/3rd motors A092/A292/A392: Acceleration (2) time setting, 1st/2nd/3rd motors A093/A293/A393: Deceleration (2) time setting, 1st/2nd/3rd motors A094/A294: Select method to switch to Acc2/D[...]

  • Seite 89

    Chapter 4 Explanation of Functions 4 - 31 4.2.25 Acceleration/deceleration curve selection Y ou can set different patterns of motor a cceleration and deceleration according to the type of system to be driven by the inverter . Use functions "A097" and "A098" to select acceleration and deceleration patterns, respectively . Y ou ca[...]

  • Seite 90

    Chapter 4 Explanation of Functions 4 - 32 (2) Curve const ant (swelling degree) S pecify the swelling degree of the acceleration curve with refe rence to the following graphs: The acceleration or deceleration time may be shorte ne d midway through the acceleration or deceleration according to the S-curve pattern. If the LAD cancellation (LAC) fun c[...]

  • Seite 91

    Chapter 4 Explanation of Functions 4 - 33 4.2.27 Retry or trip af ter instant aneous power failure (1) Retry (rest art) after instant aneous power failure Y ou can select tripping or retrying (restarting) the mot or operation as the inverter operation to be performed at the occurrence of instant aneous power failure or undervolt age. If you specify[...]

  • Seite 92

    Chapter 4 Explanation of Functions 4 - 34 *1 If the inverter trips because of overvoltage or over current while decelerating t he motor , the inverter will display error code "E16" (inst antaneous power failu re), and the motor will st art free-running. If this error occurs, prolong the deceleration time. *2 If a DC voltage (P-N) is suppl[...]

  • Seite 93

    Chapter 4 Explanation of Functions 4 - 35 (2) Output of the alarms for instant aneous power failure and undervolt age in the stopped state Use function "b004" to specify whether to out put an alarm when inst antaneous power failure or undervoltage occurs. The inverter outputs the al arm providing t he control power remains in the inverter[...]

  • Seite 94

    Chapter 4 Explanation of Functions 4 - 36 (3) Restartin g methods - Restart with matching frequency The inverter detects the freque ncy and rotation dire ction based on the residual v oltage in the motor , and then restart s the motor based on the detected frequency . - Rest art with input frequency The inverter start s the output with the frequenc[...]

  • Seite 95

    Chapter 4 Explanation of Functions 4 - 37 4.2.29 Electronic thermal protection The electronic thermal prot ection function allows you to protect the motor against overheating. Make settings of this functio n based on the rated current of the motor . The inverter will trip for overheat protection accord ing to the settings. This function provides op[...]

  • Seite 96

    Chapter 4 Explanation of Functions 4 - 38 (b) Consta nt-torque characteristi c Make this setting when dri ving a constant-torq ue motor with the inverter . (Example) Setting on the SJ700-150LF ( rated current: 64 A) When "b012" is 64 A, and output f requency is 2.5 Hz: (c) Free setting of electronic thermal ch aracteristic T o protect the[...]

  • Seite 97

    Chapter 4 Explanation of Functions 4 - 39 4.2.30 Overload restriction/overload notice (1) Overload restrictio n function - The overloa d restriction function allows you to make the inverter monitor the motor current during accele ration or constant-spe ed operation and automatically reduce the output frequency according to the decel eration rate at[...]

  • Seite 98

    Chapter 4 Explanation of Functions 4 - 40 (2) Overload nitice function The overload notice function allows you to make t he inverter output an overload n otice signal before tripping because of overload. Y ou can use this function effectively to prevent the machine (e.g., a conveyor)driven by the inverter from being overloaded and prevent the conve[...]

  • Seite 99

    Chapter 4 Explanation of Functions 4 - 41 4.2.32 Over volt age supression during deceleration - The over volt age supression functi on allows you to prevent the inverter from tripping because of the overvolt age that can be cau sed by the energy regenerated by the motor during de celeration. - Y ou can enable or disable the function by setting the [...]

  • Seite 100

    Chapter 4 Explanation of Functions 4 - 42 4.2.33 St art frequency setting The start freq uency setting function allows you to specify the inverter output frequency that the inverter initially outputs wh en an operation command is input. Use this function mainly to adjust the start torque. If the start frequency (b0 82) is set too high, the inve rte[...]

  • Seite 101

    Chapter 4 Explanation of Functions 4 - 43 4.2.35 Carrier frequency setting The carrier frequency setting function (b083) all ows you to change the carrier frequency of the PWM wave form output from the inverter . Increasing the carrie r frequency can lo wer the metal lic noise from the motor , but may increase the inverter noise and current leakage[...]

  • Seite 102

    Chapter 4 Explanation of Functions 4 - 44 4.2.36 Automatic carrier frequency reduction - The automa tic carrier frequency redu ction function automatically reduces the carrier freque ncy according to the increase in output curre nt. - T o enable this function, specify " 01" for automatic carrier frequency reduction selection (b089). Item [...]

  • Seite 103

    Chapter 4 Explanation of Functions 4 - 45 4.2.37 Dynamic braking (BRD) function The dynamic braking (BRD) function is p rovided in the SJ700-220LFF/HFF and ot her models that have the b uilt-in BRD circuit. With this function, the energy regen erated by the motor is con sumed by an external resistor (i.e., the energy is converted to heat). Y ou can[...]

  • Seite 104

    Chapter 4 Explanation of Functions 4 - 46 4.2.39 Intelligent input terminal setting Y ou can assign the functions described below to intelligent input terminals [1] to [8]. T o ass ign the desired functions to the terminals, specify the desired dat a listed in the table below for terminal settings "C001" to "C008". For example, [...]

  • Seite 105

    Chapter 4 Explanation of Functions 4 - 47 Function code Data Description Reference item Page 51 F-TM: Forcible-te rminal operation Forc ible-terminal operation function 4-51 52 A TR: Permission of torque command input T orque control function 4-98 53 KHC: Cumulative power clearance Cumulative power monitoring function 4-4 54 SON: Servo On Servo on [...]

  • Seite 106

    Chapter 4 Explanation of Functions 4 - 48 (1) Binary operation mode Assign functions "02" (CF1) to "05" (CF4) individually to the terminal [1] to [8] functions (C001 to C008) to make multispeed s 0 to 15 available for sele ction. S pecify the desired frequencies for speeds 1 to 15 by setting multispe eds 1 to 15 (A021 to A035). [...]

  • Seite 107

    Chapter 4 Explanation of Functions 4 - 49 4.2.42 Jogging (JG) command setting The jogging command setting function al lows you to set and finely tune the motor-stopping position. T o use this function, assign function "06" (JG) to an intelligent input terminal. (1) Jog frequency setting Since the inverter operates the motor with a full vo[...]

  • Seite 108

    Chapter 4 Explanation of Functions 4 - 50 4.2.43 2nd/3rd motor control function (SET and SET3) This motor control function allows you to switch the inverter settings to control three diff erent types of motors. T o use this function, assign function "08" (SET) and "17" (SET3) to two of the terminal [1] to [8] functions (C001 to [...]

  • Seite 109

    Chapter 4 Explanation of Functions 4 - 51 4.2.44 Sof tware lock (SFT) function The softwa re lock function allows you to specify whether to disable rewriting of the data set for function al items. Use this function to protect the data again st accidental rewrit ing. Y ou can select the functional items to be lo cked and the method of locki ng as de[...]

  • Seite 110

    Chapter 4 Explanation of Functions 4 - 52 4.2.47 Free-run stop (FRS) function The free-run stop (FRS) function all ows you to shut of f the inverter output to let the motor start free-runnin g. Y ou can effectively use this function when stopping the motor with a mechanical brake (e.g., ele ctromagnetic brake). If an attempt is made to forcibly sto[...]

  • Seite 111

    Chapter 4 Explanation of Functions 4 - 53 (Example 3) Restarting with active matching frequenc y 4.2.48 Commercial power source switching (CS) function The commercial power sou rce switching function allows you to switch the power supply (between the inverter and commercial power supply) to your system of which the load causes a consi derable momen[...]

  • Seite 112

    Chapter 4 Explanation of Functions 4 - 54 4.2.49 Reset (RS) function The reset function allows you to recover the inverter from a trippe d state. T o perform resetting, press the STOP/RESET key of the digital operator or turn the RS terminal off. T o use the control circuit terminal for resetting, assi gn function "18" (RS) to an intellig[...]

  • Seite 113

    Chapter 4 Explanation of Functions 4 - 55 (Example 1) (Example 2) (Example 3)If you select "01" (sta rting with matchi ng frequency) as the resta rt mode after reset (C103), you can also make the inverter start the motor with matchin g frequency after the power reset. When "00" (starting with 0 Hz) is selected as the restart mod[...]

  • Seite 114

    Chapter 4 Explanation of Functions 4 - 56 4.2.50 Unattended st art protection (USP) function The unattended sta rt protection function allows you to make the inverter trip with error code "E13" displayed if the inverter p ower is turned on when an operation com mand has been turned on. Y ou can recover the inverter from tripping by perfo [...]

  • Seite 115

    Chapter 4 Explanation of Functions 4 - 57 4.2.52 External trip (EXT) function The external trip function allows you to make the inverter trip according to the error (trip) signal generated by an external system. T o use this function, assign function "12" (EXT) to one of the terminal [1] to [8] functions (C001 to C008). When the EXT termi[...]

  • Seite 116

    Chapter 4 Explanation of Functions 4 - 58 4.2.54 Control gain switching function (CAS) The control gain switching function all ows you to set and switch between two types of gains and time co nstant s for the speed control system (with proportional and integral com pensations) when the V/F characteristic curve select ion is the sensorless vector co[...]

  • Seite 117

    Chapter 4 Explanation of Functions 4 - 59 The speed control norma lly incorporat es the proportional integrated compensation (PI control), and the motor speed is controlled so that the difference between the frequenc y specified by the fre quency command and the actual motor speed is zer o. However , a specific operation mode (called dro oping oper[...]

  • Seite 118

    Chapter 4 Explanation of Functions 4 - 60 4.2.58 Intelligent output terminal setting Y ou can assign the functions described below to the intelligent output terminals [1 1] to [15] (C021 to C025) and the alarm rel ay terminal (C026). The intelligent output terminals [1 1] to [15] are used for open-collector output, and the alarm relay terminal is u[...]

  • Seite 119

    Chapter 4 Explanation of Functions 4 - 61 Data Description Reference item Page 53 MJA: Major failure Major failure signal 4-70 54 WCO 55 WCOI 56 WCO Window comparators function 4-71 4.2.59 Intelligent output terminal a/b (NO/NC) selection The intelligent output terminal a/ b (NO/NC) selection function allows you to specify a-contact or b-cont act o[...]

  • Seite 120

    Chapter 4 Explanation of Functions 4 - 62 4.2.60 Running signal (RUN) While the inverter is operati ng, it output s the running (RUN) signal via an intelligent output terminal ([1 1] to [15]) or the alarm relay terminal. T o use this signal function, assi gn fu nction "00" (RUN) to one of the intelligent output terminals [1 1] to [15] (C0[...]

  • Seite 121

    Chapter 4 Explanation of Functions 4 - 63 (1) Signal output when the const ant-speed frequency is reached (01: F A1) The inverter outputs the si gnal when the output frequen cy reaches the freq uency specified by a frequency setting (F001, A020, A220, or A320) or multispeed setting (A021 to A035). (2) Signal output when the set frequen cy is exceed[...]

  • Seite 122

    Chapter 4 Explanation of Functions 4 - 64 4.2.62 Running time over and power-on time over signals (RNT and ONT) The inverter outputs the o peration time over (RNT) signal or the plug-in time over (ONT) signal when the time specified as the run/power-on warning time (b034) is exceeded. Item Function code Range of data Description Run/power-on warnin[...]

  • Seite 123

    Chapter 4 Explanation of Functions 4 - 65 4.2.64 Over-torque signal (OTQ) The inverter outputs the o ver-t orque signal when it detect s that the estimated motor output torque exceeds the specified level. T o enable this function, assign function "07" (OTQ: over-torque signal) to an intelligent outp ut terminal. This function is ef fectiv[...]

  • Seite 124

    Chapter 4 Explanation of Functions 4 - 66 Intelligent output terminals When "4 bits" is selected When "3 bits" is selected 14 13 12 1 1 AC3 AC2 AC1 AC0 F actor code Cause of trippi ng Factor code Cause of tripping 1 1 0 1 E20, E21 T emperature er ror due to low cooling-fan speed T emperature er ror - - 1 1 1 0 E24 Phase loss[...]

  • Seite 125

    Chapter 4 Explanation of Functions 4 - 67 Item Function code Data or range of data Description 33 LOG1: Logical operation r esult 1 (C142, C143, and C144) 34 LOG2: Logical operation r esult 2 (C145, C146, and C147) T erminal function 35 LOG3: Logical operation r esult 3 (C148, C149, and C150) 36 LOG4: Logical operation r esult 4 (C151, C152, and C1[...]

  • Seite 126

    Chapter 4 Explanation of Functions 4 - 68 4.2.69 Cooling-fan speed drop signal (W AF) The inverter outputs the cooling -fan speed drop (W AF) signal when it detects that the rot a tion speed of its internal cooling fan has fallen to 75% or less of the full speed. If "01" has been selected for the cooling fan control (b 092), the inverter [...]

  • Seite 127

    Chapter 4 Explanation of Functions 4 - 69 4.2.72 Low-current indication (LOC) signal The inverter outputs the lo w-current indication (LOC) signal when the inverter output current falls to the low-current indication signa l detection level (C039) or less. Y ou can select one of the two signal output modes wi th the low-cu rrent indication signal ou[...]

  • Seite 128

    Chapter 4 Explanation of Functions 4 - 70 4.2.75 Reverse rot ation signal (RVR) The inverter continues to output the forward rotation (R VR) signal while it is driving the motor for rev erse operation. The RVR sig nal is turned of f while the inverter is dr iving the motor for forward operation or stoppin g the motor . Item Function code Dat a or r[...]

  • Seite 129

    Chapter 4 Explanation of Functions 4 - 71 4.2.77 Window comp arators (WCO/WCOI/WCO2) (detection of terminal disconnection: ODc/OIDc/O2Dc) - The windo w comparator f unction outputs signals when the values of analo g inputs O, OI, and O2 are within the maximum and minimum limits sp ecified for the window comp arator . Y ou can monitor analog inputs [...]

  • Seite 130

    Chapter 4 Explanation of Functions 4 - 72 4.2.78 Output signal delay/hold function The output signal delay/ hold function allo ws you to set on-delay and off-delay times for each output terminal. Since every output signa l is turned on or of f immediately when the relevant condition is satisfied, signal chatteri ng may occur if signal outputs confl[...]

  • Seite 131

    Chapter 4 Explanation of Functions 4 - 73 4.2.81 FM terminal Y ou can monitor the inverter output frequency and output current via the FM terminal on the control circuit terminal block. The FM terminal is a pulse output terminal. (1) FM siginal sele ction Select the signal to be output from the FM terminal among those shown below . If you select &q[...]

  • Seite 132

    Chapter 4 Explanation of Functions 4 - 74 4.2.82 AM and AMI terminals Y ou can monitor the inverter output frequency and output current via the AM and AMI terminals on the control circuit block. The AM terminal outputs a n analog voltage signal (0 to 10 V). The AMI terminal outputs a n analog current signal (4 to 20 mA). (1) AM siginal selection /A[...]

  • Seite 133

    Chapter 4 Explanation of Functions 4 - 75 4.2.83 Initialization setting The initialization function allows y ou to initialize the adjusted settings on the inverter to restore the factory se ttings. Y ou can also clear the trip history data alone. The settings of initialization are descri bed below . The settings of "P100" to "P131&qu[...]

  • Seite 134

    Chapter 4 Explanation of Functions 4 - 76 4.2.84 Function code display restriction The function code display restriction function allo ws you to arbitrarily switch the display mode or the display co ntent on the digital operato r . Item Function code Data Description 00 Full display 01 Function-specific display 02 User setting 03 Data comparison di[...]

  • Seite 135

    Chapter 4 Explanation of Functions 4 - 77 No. Display condition Parameter displayed when the display condition is met 27 One of C001 to C008 = 05 a nd A019 = 00 A028 to A035 28 One of C001 to C008 = 06 A038 and A03 9 29 One of C001 to C008 = 07 A053 to A055 and A059 30 One of C001 to C008 = 08 F202, F 203, A203, A204, A220, A244, A246, A247, A261, [...]

  • Seite 136

    Chapter 4 Explanation of Functions 4 - 78 (4) Basic display mode The monitor displays basic p arameters. (The monitor display is the factory setting.) The following t able lists the p arameters that can be di splayed in basic display mode: No. Code displaye d Item 1 d001 to d104 Monitoring indi cation 2 F001 Output frequenc y setting 3 F002 Acceler[...]

  • Seite 137

    Chapter 4 Explanation of Functions 4 - 79 4.2.86 Automatic user-parameter setting The automatic user-para meter setting function allows you to make t he inverter automatically store the p ara meters you readjusted sequen tially as user pa rameters "U001" to "U012". Y ou can use the stored data as a readjustment history . T o ena[...]

  • Seite 138

    Chapter 4 Explanation of Functions 4 - 80 4.2.89 Optimum accel/decel operation function The optimum accel/decel operat ion funct ion eliminates the need for acceleration time and deceleratio n time settings for the motor operation by the inverter . Convent ional inverters required you to adjust the acceleration and deceleration time according to th[...]

  • Seite 139

    Chapter 4 Explanation of Functions 4 - 81 4.2.90 Brake control function The brake control function allows y ou to make the inverter cont rol an external brake used for a lif t or other machines. T o enable this function, specify "01" (enabling t he brake control function) for the Brake Control Enable (b120). This function operates as desc[...]

  • Seite 140

    Chapter 4 Explanation of Functions 4 - 82 When using the brake cont rol function, assign the following signal function s to intelligent input and intelligent output terminals as ne eded. (1) T o input a signal indicating that the brake is rel eased from the external brake to the inverter , assign the braking confirmation signal (44: BOK) to one of [...]

  • Seite 141

    Chapter 4 Explanation of Functions 4 - 83 4.2.91 Deceleration and stopping at power failure (nonstop deceleration at inst ant aneous power failure) The nonstop deceleration at inst antane ous power failure is the function making the inverter decel erate and stop the motor while maintaini ng the voltage below the overv oltage level when an inst anta[...]

  • Seite 142

    Chapter 4 Explanation of Functions 4 - 84 <2> DC volta ge constant control du ring nonstop op eration at moment ary power failure (b050 = 02: no restoration, b050 = 03: restoration to be done ) - If momentary power failure occurs or the main ci rc uit DC voltage drop s during inverter operation, the inverter decelerates the motor while m aint[...]

  • Seite 143

    Chapter 4 Explanation of Functions 4 - 85 4.2.92 Offline auto-tuning function The offline au to-tuning function allows you to make the inverter automatically measure and set t he motor const ants tha t are required for the sensorless vecto r control, 0Hz-range sensorless vector control, and vector control with sensor . When using the inverter to pe[...]

  • Seite 144

    Chapter 4 Explanation of Functions 4 - 86 c) All brakes are released. d) During auto-tuning, insuf ficient torque may cause a problem in the load driven by the motor (for example, a lift may slide down). Therefore, remove the motor from the machine or other load, and perform auto-tuning with the motor alone . (The moment of inertia [J] measured by [...]

  • Seite 145

    Chapter 4 Explanation of Functions 4 - 87 4.2.93 Online auto-tuning function The online auto-tuning function allows you to compe nsate the motor constant s for alterations caused by the rise of motor temperature and other f actors to ensure stable mo tor operation. The online auto-tuning function applies o nly to the 1st motor and 2nd motor control[...]

  • Seite 146

    Chapter 4 Explanation of Functions 4 - 88 4.2.95 Motor const ant s selection Adjust the motor const ant settings to the motor to be driven by the inverter . When using a single inverter to drive mu ltiple moto rs in the control mode based on VC, VP , or free V/f characteristic, calculate the tot al capa city of the moto rs, and specify a value clos[...]

  • Seite 147

    Chapter 4 Explanation of Functions 4 - 89 4.2.96 Sensorless vector control The sensorless vector control function estimates and controls the motor speed and output torque on the basi s of the inverter output voltage and outp ut current and the motor constant s set on the inverter . This function enabl es the inverter to accurately operate the motor[...]

  • Seite 148

    Chapter 4 Explanation of Functions 4 - 90 4.2.97 Sensorless vector , 0 Hz domain control The 0Hz domain sensorless vecto r (SL V) control function incorporates Hit achi’s own torque control system and enables high-torque operat ion in the 0Hz range (0 to 3 Hz). This control function is best suited for driving a lifting machine, e.g., crane or hoi[...]

  • Seite 149

    Chapter 4 Explanation of Functions 4 - 91 4.2.98 T orque monitoring function The torque monitoring function allows you to monitor the estimated motor output torque when the V/F characteristic curve selection is the sensor less ve ctor control, 0Hz-range sensorless vector control, or vector control with sensor . T o monitor the output torque on the [...]

  • Seite 150

    Chapter 4 Explanation of Functions 4 - 92 4.2.100 T orque limit ation function The torque limit ation function allows you to limit the motor output torque when "03" (sensorle ss vector control), "04" (0Hz-range sensorless vector cont rol), o r "05" (vector control with sensor) is specified for the V/F characteristic cu[...]

  • Seite 151

    Chapter 4 Explanation of Functions 4 - 93 When "00" (quadrant-specific setting mo de) is specified for the torque limit selection (b040 ), the torque limits 1 to 4 apply as show n below . When "01" (terminal-swit ching mode) is specified for the torqu e limit selection (b040), the torque limit s 1 to 4 are set as shown in the ex[...]

  • Seite 152

    Chapter 4 Explanation of Functions 4 - 94 4.2.102 T orque LAD stop function The torque LAD stop funct ion is effectiv e when "03" (sensorless vector control), "04" (0Hz-range sensorl ess vector control), or "05" (vector control with sens or) is sp ecified for the V/F characteristic curve selection (A04 4/A244). This fu[...]

  • Seite 153

    Chapter 4 Explanation of Functions 4 - 95 4.2.104 Easy sequence function - Y ou can create a user program with EzSQ (the programming sof tware dedicated to the SJ700) on a personal computer , and download the program to your SJ700 series inverter . Thus, you can convert your inverter to a special machine on whi ch user-defined functions are install[...]

  • Seite 154

    Chapter 4 Explanation of Functions 4 - 96 4.3 Functions A vailable When the Fee dback Option Board (SJ-FB) Is Mounted 4.3.1 Functions requiring the SJ-FB - The feedback option board (SJ-FB) is generally required in the following cases: <1> When "05" (V2: vector control with sensor) is specified for V/F characteristic curve selection[...]

  • Seite 155

    Chapter 4 Explanation of Functions 4 - 97 4.3.3 V ector control w ith encoder feedback - T o use this control function, specify "05" (V2) for the V/F characteristic curve sele ction (A044). (Y ou can specify the vector control with sensor only when the 1st motor cont rol is selected.) - Before using this function, be sure to make optimum [...]

  • Seite 156

    Chapter 4 Explanation of Functions 4 - 98 4.3.4 T orque biasing function The torque biasing function allows you to make the in verter bias the torque command generated during the operatio n in speed control mode. Y ou can effectively use this function for inverter applications to a lif t or other elevating machines. Item Function code Data or range[...]

  • Seite 157

    Chapter 4 Explanation of Functions 4 - 99 (Control block diagram ) 4.3.6 Pulse train position control mode - T o use this function, specify "05" (V2) for V/F char acteristic curve selection, 1 st motor (A044) and "01" (pulse train position contro l mode) for the control pulse setting (P012). - Y ou can choose the input source of[...]

  • Seite 158

    Chapter 4 Explanation of Functions 4 - 100 *2 The following timing charts show the det ailed operations in pulse train input mode. 1) MD0: 90 ° -phase-shift p ulse train SAP SAN SBP SBN 正転 逆転 (パルス列入力) 検出 パルス数 時間 2) MD1: Forward/reverse operation command with p ulse train (パルス?[...]

  • Seite 159

    Chapter 4 Explanation of Functions 4 - 101 4.3.7 Electronic gear function The electronic gear function allows you to set a gain on the position command or position feedb ack data to adjust the ratio between the main motor and sub-m otor speeds during the synchronous operation of the motors. Item Function code Data or range of data Description 00 Po[...]

  • Seite 160

    Chapter 4 Explanation of Functions 4 - 102 <Example of use: Synchronous ope ration> On the inverter (master inverter) for the main moto r , specify either the speed control or pulse train po sition control mode. On the inverter (slave inverter) for the sub-moto r , specify the pulse train position control mode. <Example of settings> - M[...]

  • Seite 161

    Chapter 4 Explanation of Functions 4 - 103 4.3.8 Motor gear ratio setting function The motor gear ratio setting function all ows you to make the inverter effe ctively control a specific machine in which an encod er is installed at the opposite end of the motor . S pecify the actual pulse count of the encoder as t he encoder pulse-per-revolution (PP[...]

  • Seite 162

    Chapter 4 Explanation of Functions 4 - 104 4.3.1 1 Home search function The home search function allows you to make the inv erter locate the motor shaft at a specifi ed position. Y ou can use this function, for example, to stop a meta l-cutting machine to replace the tool attached to the main spi ndle. When using the home search function, be sure t[...]

  • Seite 163

    Chapter 4 Explanation of Functions 4 - 105 Note 1: Since the inverter position s the motor shaft within two turns while decelerating the moto r , do not specify a high frequency as the home search speed. Otherwise, the inverter ma y trip during home search because of the overvoltage prote ction function. Note 2: For setting the home search stop pos[...]

  • Seite 164

    Chapter 4 Explanation of Functions 4 - 106 4.3.12 Absolute position control mode - T o use the absolute positi on control mode function, specify "05" (V2) for V/F characteristic curve selectio n, 1st motor (A044) and "02" (APR: absolute position control ) for the control pulse setting (P012). - If "03" (high-resolution[...]

  • Seite 165

    Chapter 4 Explanation of Functions 4 - 107 Multistage speed/position determination time C169 0. to 200. X10ms Position setting monitor d029 -1073741823 to + 107374182 3 Position feedback monitor d030 -1073741823 to + 107374182 3 54 SON: Servo-on 66 CP1: Position setting selection 1 67 CP2: Position setting selection 1 68 CP3: Position setting selec[...]

  • Seite 166

    Chapter 4 Explanation of Functions 4 - 108 4.3.14 Multist age position switching function (CP1/CP2/CP3) - When functions "66" (CP1) to "68" (CP3) are assig n ed to terminal [1] function (C001) to terminal [8] function (C008), you can select a positio n setting from multistage position s 0 to 7. - Use multista ge position setting[...]

  • Seite 167

    Chapter 4 Explanation of Functions 4 - 109 4.3.16 Zero-return function (ORG , ORL) - One of three types of zero-return oper ations can be selected by zero-retu rn mode selection (P068). When a zero-return operati on ends, the curr ent position counter is cleared (to 0). - Use zero-return direction sele ction (P069) to select the dire ction of zero-[...]

  • Seite 168

    Chapter 4 Explanation of Functions 4 - 1 10 4.3.17 Forward/reverse drive stop function (FOT/ROT) - The forward/reverse drive stop func tion allows you to prevent motor operation from deviating from the specified control ra nge according to signals from the control range limit switches. - When the FOT terminal is turned on, the torque for forward ro[...]

  • Seite 169

    Chapter 4 Explanation of Functions 4 - 1 1 1 4.3.20 Servo-on function The servo-on function allows you to set the inverter in a speed-servo locking st ate with a si gnal input via an input terminal during operation. This fun ction is ef fective when "05" (vector control with sensor) is specified as the V/F characteristic curve selection ([...]

  • Seite 170

    Chapter 4 Explanation of Functions 4 - 1 12 4.3.21 Pulse train frequency input The pulse train frequency input functio n allows you to use the pulse train input via the SAP or SAN terminal a s a frequency command or PID feedback dat a in each control mode. (Y ou can use this function in every control m ode.) S pecify the input frequency correspondi[...]

  • Seite 171

    Chapter 4 Explanation of Functions 4 - 1 13 4.4 Communication Functions The inverter can engage in RS485 comm unications with an external control system that is connected to the TM2 terminal block (on the control circuit termi nal block board) of the inverter . The SJ700 series inve rter shar es the ASCII c ommunication protocol with the SJ300 and [...]

  • Seite 172

    Chapter 4 Explanation of Functions 4 - 1 14 Connectio n As illustrated below , connect the inverters in paralle l to the external control system, and conne ct the RP and SN te rminals with a jumper on the inverter at the end of the network. (Similarly jumper the RP and SN terminals when only one inverter is con nec ted to the external control syste[...]

  • Seite 173

    Chapter 4 Explanation of Functions 4 - 1 15 (3) Communication te st mode Use the communication test mode to check the hardware of the RS485 commu nication train. (Procedure for communicat ion test) 1) Remove all cable s from the TM2 terminal block to perform a loo pback test. 2) Make the followin g setting with the digital operato r of the inverter[...]

  • Seite 174

    Chapter 4 Explanation of Functions 4 - 1 16 4.4.1 Communication in ASCII mode (1) Communication protocol The communication between the inverte r and external c ontrol system is based on the followin g protocol: (1): Frame that is sent from the exte rnal control system to the inverter (2): Frame that is sent from the inve rter to the external contro[...]

  • Seite 175

    Chapter 4 Explanation of Functions 4 - 1 17 The commands are described bel ow . (i) 00 comm and: This command instruct s the inverter to drive the motor (for forward or reverse rotation) or stop the motor . (T o use this command, set "A002" to "03" [RS485].) - T ransmission fram e Frame format STX S tation No. Command Data BCC C[...]

  • Seite 176

    Chapter 4 Explanation of Functions 4 - 1 18 (iii) 02, 12 command: This command turns the specified intelligent input termin als on or of f. - T ransmission fram e Frame format STX S tation No. Command Data BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target invert[...]

  • Seite 177

    Chapter 4 Explanation of Functions 4 - 1 19 Note 6: The table bel ow lists the function s of the intelligent input terminals and correspon ding hexadecimal dat a for 12 command. (For det ails, see t he explanation of the intelligent input terminal functions.) Data (hexadecimal) Description Data (hexadecimal) Description 0000000000000001 00000000000[...]

  • Seite 178

    Chapter 4 Explanation of Functions 4 - 120 (iv) 03 command: This command reads all monitored dat a from the inverter . - T ransmission fram e Frame format STX S tation No. Command BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter 2 b ytes 01 to 32 Comma[...]

  • Seite 179

    Chapter 4 Explanation of Functions 4 - 121 (v) 04 command: This command reads the st atus of the inverter . - T ransmission fram e Frame format STX S tation No. Command BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter 2 b ytes 01 to 32 Command Command [...]

  • Seite 180

    Chapter 4 Explanation of Functions 4 - 122 (vi) 05 command: This command reads the trip history data from the inverter . - T ransmission fram e Frame format STX S tation No. Command BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter 2 b ytes 01 to 32 Com[...]

  • Seite 181

    Chapter 4 Explanation of Functions 4 - 123 (vii) 06 command: This command reads a specified setting item from the inverter . - T ransmission fram e Frame format STX S tation No. Command Parameter B CC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter 2 b yt[...]

  • Seite 182

    Chapter 4 Explanation of Functions 4 - 124 (viii) 07 command: Thi s command writes dat a to a specified setting item in the inverter . - T ransmission fram e Frame format STX S tation No. Command Parameter Data BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target i[...]

  • Seite 183

    Chapter 4 Explanation of Functions 4 - 125 (x) 09 command: This command checks whether set dat a can be stored in the EEPROM in the inverter . - T ransmission fram e Frame format STX S tation No. Command BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter[...]

  • Seite 184

    Chapter 4 Explanation of Functions 4 - 126 (xii) 0B command: This command recalculates the const ants set i n the inverter . This command must be issued when the base freque ncy or the setting of parameter "H***" ha s been changed for the RS485 communi cation. - T ransmission fram e Frame format STX S tation No. Command BCC CR Description[...]

  • Seite 185

    Chapter 4 Explanation of Functions 4 - 127 (2) Positive and negative response s (i) Positive response - Response frame Frame format STX S tation No. ACK BCC CR Description Data size Setting STX Control code ( S tart of T eXt) 1 byte STX (0x02) S tation No. S tation number of control-target inverter 2 b ytes 01 to 32 ACK Contro l code (acknowledgem [...]

  • Seite 186

    Chapter 4 Explanation of Functions 4 - 128 (3) How to calculate the bl ock check code (BCC) (Example) When using the 01 command (fre quency-setting command ) to set the inverter output frequency to 5 Hz (the st ation No. of the inverter is 01): The content s of "S tation No." to "Dat a" are conver ted into ASCII data, and the AS[...]

  • Seite 187

    Chapter 4 Explanation of Functions 4 - 129 4.4.2 Communication in Modbus-RTU mode (1) Communication protocol The communication between the inverte r (slave) and ex ternal control system (master) is base d on the following protocol: (1): Query frame that is sent from the external control system to the inverter (2): Response frame that is sent from t[...]

  • Seite 188

    Chapter 4 Explanation of Functions 4 - 130 The formats of the query and response frames are describe d below . Message configuration: Query Header (silent interval) Slave address Function code Data Error check code T railer (silent interval) (i) Slave address The slave address is a number 1 to 32 that is assi gned to the inverter (slave) beforehand[...]

  • Seite 189

    Chapter 4 Explanation of Functions 4 - 131 (iv) Error check code The Modbus-RTU protocol uses the cyclic redundan cy check (CRC) as the error check method. The CRC code is the 16-bit data generat ed for a data block that has an arbitrary dat a length (in units of 8 bits). A generative polynomial for CRC-16 (X 16 + X 15 + X 2 + 1) is used to generat[...]

  • Seite 190

    Chapter 4 Explanation of Functions 4 - 132 Message configuration: Resp onse (i) T ime required for communication After the inverter receives a query , the inverter waits for the sum of the silent interval (corresponding to the transmission of 3.5 characters) and the com munication wait time (C078) before sendin g a response. After receiving a respo[...]

  • Seite 191

    Chapter 4 Explanation of Functions 4 - 133 (4) Explanation of function codes (i) Reading the coil st atus [01h] This function reads the coil st atus (on or off). (Example) When reading the st atus of the intelligent input termi nals [1] to [6] of the inverter at slave address "8": Assume that the intelligent input termin als are in the st[...]

  • Seite 192

    Chapter 4 Explanation of Functions 4 - 134 (ii) Reading registers [03h] This function reads a speci fied number of regist ers b eginning at a specified register add ress. (Example) When reading the trip history dat a from the inverter at slave address "5": Assume that the conditions of the p ast three trips are as follo ws: SJ700 command [...]

  • Seite 193

    Chapter 4 Explanation of Functions 4 - 135 (iii) Writing dat a to a specified coil [05h] This function writes data to a specified coil The following t able shows the updating of the coil st atus. Coil status OFF → ON ON → OFF Updating data (upper digit) FFh 00h Updating data (lower digit) 00h 00h (Example) When sending an operatio n command to [...]

  • Seite 194

    Chapter 4 Explanation of Functions 4 - 136 (v) Performing a loopback test [08h] The loopback test function is used to check the co mmunication between the external co ntrol system (master) and the inverter (slave). (Example) When performing a loopback test with the inverter at slave ad dress "1": The diagnosis subcode o nly conforms to th[...]

  • Seite 195

    Chapter 4 Explanation of Functions 4 - 137 (vii) Writing dat a to multiple registers [10h] This function writes dat a to sequential registers. (Example) When setting "3,000 Hz" as the Acceleration (1) time (F002) in the inverter at slave addre ss "1": Since register "1 103h" and "1 104h" to store the Accelera[...]

  • Seite 196

    Chapter 4 Explanation of Functions 4 - 138 (5) Enter command (stori ng the updates of register dat a) Neither the command (06h) to write dat a to a regist er nor the command (10h) to write data to multiple registers can store the updates they made in the internal memory of the inverter . T urning the inverter power off wit hout storing the updates [...]

  • Seite 197

    Chapter 4 Explanation of Functions 4 - 139 (6) List of registers The "R/W" column of the list indicates whether t he coi ls and registers are read-only or rea dable and writable. "R" indicates a read-only coil or registe r . "R/W" indicates a readable and writ able coil or register . (i) List of coils Coil No. Item R/W[...]

  • Seite 198

    Chapter 4 Explanation of Functions 4 - 140 Coil No. Item R/W Setting 0035h LOG2 (logical operation result 2) R 1: ON, 0: OFF 0036h LOG3 (logical operation result 3) R 1: ON, 0: OFF 0037h LOG4 (logical operation result 4) R 1: ON, 0: OFF 0038h LOG5 (logical operation result 5) R 1: ON, 0: OFF 0039h LOG6 (logical operation result 6) R 1: ON, 0: OFF 0[...]

  • Seite 199

    Chapter 4 Explanation of Functions 4 - 141 (ii) List of registers (frequenc y settings and trip monito ring) Register No. Function name Function code R/W Monitoring and setting items Data resolution 0001h F001 (high) R/W 0002h Frequency source setting F001 (lo w) R/W 0 to 40000 (valid when A001 = 03) 0.01 [Hz] 0003h Inverter st atus A - R 0: Initia[...]

  • Seite 200

    Chapter 4 Explanation of Functions 4 - 142 Register No. Function name Function code R/W Monitoring and setting items Dat a resolution 003Ah T rip monitoring 5 (factor) See the list of inverter t rip factors below - 003Bh T rip monitoring 5 (inverter status) See the list of inverter trip factors below - 003Ch Trip monitoring 5 (frequency) (high) 003[...]

  • Seite 201

    Chapter 4 Explanation of Functions 4 - 143 List of inverter trip factors Upper part of trip factor code (indicating the factor) Lo wer pa rt of trip factor code (indicating the inverter status) Name Code Name Code No trip factor 0 Resetting 0 Overcurrent protection during constant-speed operation 1 S topping 1 Overcurrent protection during decel er[...]

  • Seite 202

    Chapter 4 Explanation of Functions 4 - 144 (iii) List of regi sters (monitoring) Register No. Function name Function code R/ W Monitoring and setting items Dat a resolution 1001h d001 (high) 1002h Output frequency monitoring d001 (low) R 0 to 40000 0.01 [Hz] 1003h Output current monitoring d002 R 0 to 9999 0.1 [A] 1004h Rotation direction minitorin[...]

  • Seite 203

    Chapter 4 Explanation of Functions 4 - 145 (v) List of register s (functio n modes) Register No. Function name Function code R/ W Monitoring and s etting items Dat a resolution 1201h Frequency source setting A001 R/W 0 (keypad potentiometer), 1 (control circuit terminal block), 2 (digital operator), 3 (RS485), 4 (option 1), 5 (option 2), 6 (pulse t[...]

  • Seite 204

    Chapter 4 Explanation of Functions 4 - 146 Register No. Function name Function code R/W Monitori ng and s etting items Data resolution Register No. 1236h (Reserved) - - Inaccessible - 1237h (Reserved) - - Inaccessible - 1238h Jog frequency setting A038 R/W "S tart frequency" to 999 0.01 [Hz] 1239h Jog stop mode A039 R/W 0 (free-running af[...]

  • Seite 205

    Chapter 4 Explanation of Functions 4 - 147 Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 125Fh PID Function Enable A071 R/W 0 (disabling), 1 (enabling), 2 (enabling inverted-data output) - 1260h PID propo rtional gain A072 R/W 2 to 50 0.1 1261h PID integral time constant A073 R/W 0 to 36000 [...]

  • Seite 206

    Chapter 4 Explanation of Functions 4 - 148 Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 12B0h Operation-target frequency selection 2 A142 R/W 0 (digital operator), 1 (keypad potentiometer), 2 (input via O), 3 (input via OI), 4 (external communication), 5 (option 1), 6 (option 2), 7 (pulse t[...]

  • Seite 207

    Chapter 4 Explanation of Functions 4 - 149 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1301h Selection of restart mode b001 R/W 0 (tripping), 1 (starting with 0 Hz), 2 (starting with matching frequency), 3 (tri pping after deceleration and stopping with matching frequency), 4 (restarting wi[...]

  • Seite 208

    Chapter 4 Explanation of Functions 4 - 150 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1326h Reduced voltage start selection b036 R/W 0 (minimum reduced voltage start time) to 255 (maximum reduced voltage start time) - 1327h Function code display restriction b037 R/W 0 (full display), 1 (fu[...]

  • Seite 209

    Chapter 4 Explanation of Functions 4 - 151 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1354h (Reserved) - - Inaccessible - 1355h Start frequency adjustment b082 R/W 10 to 999 0.01 [Hz] 1356h Carrier f requency setting b083 R/W 5 to 150 0.1 [kHz] 1357h Initialization mode (parameters or trip[...]

  • Seite 210

    Chapter 4 Explanation of Functions 4 - 152 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1401h T erminal [1] funct ion C001 R/W - 1402h T erminal [2] funct ion C002 R/W - 1403h T erminal [3] funct ion C003 R/W - 1404h T erminal [4] funct ion C004 R/W - 1405h T erminal [5] funct ion C005 R/W -[...]

  • Seite 211

    Chapter 4 Explanation of Functions 4 - 153 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1415h T erminal [1 1] fun ction C021 R/W - 1416h T erminal [12] fun ction C022 R/W - 1417h T erminal [13] fun ction C023 R/W - 1418h T erminal [14] fun ction C024 R/W - 1419h T erminal [15] fun ction C025[...]

  • Seite 212

    Chapter 4 Explanation of Functions 4 - 154 Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 142Ah C042 (high) R/W 142Bh Frequency arrival setting for accel. C042 (lo w) R/W 0 to 40000 0.01 [Hz] 142Ch C043 (high ) R/W 142Dh Frequenc y arrival setting for decel. C043 (lo w) R/W 0 to 40000 0.01 [H[...]

  • Seite 213

    Chapter 4 Explanation of Functions 4 - 155 Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 1470h (Reserved) R/W - 1471h AM bias adjustment C109 R/W 0 to 100 1 [%] 1472h AMI bias adjustment C1 10 R/W 0 to 100 1 [%] 1473h Overload setting (2) C1 1 1 R/W 0 to 2000 0.1 [%] 1474h to 147Ch (Reserved[...]

  • Seite 214

    Chapter 4 Explanation of Functions 4 - 156 Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 1501h Auto-tuning Setting H001 R/W 0 (disabling auto-tuning), 1 (auto-tuning without rotation), 2 (auto-tuning with rot ation) - 1502h Motor data selection, 1st motor H002 R/W 0 (Hitachi standard dat a),[...]

  • Seite 215

    Chapter 4 Explanation of Functions 4 - 157 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1601h Operation mode on expansion card 1 error P001 R/W 0 (tripping), 1 (continuing operation) - 1602h Operation mode on expansion card 2 error P002 R/W 0 (tripping), 1 (continuing operation) - 1603h to 1[...]

  • Seite 216

    Chapter 4 Explanation of Functions 4 - 158 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1633h Motor poles setting for RPM P049 R/W 0 (0 pole), 1 (2 poles), 2 (4 poles), 3 (6 poles), 4 (8 poles), 5 (10 poles), 6 (12 poles), 7 (14 poles), 8 (16 poles), 9 (18 poles), 10 (20 poles), 1 1 (22 pole[...]

  • Seite 217

    Chapter 4 Explanation of Functions 4 - 159 Register No. Function name Function code R/W Monitoring and setting items Data resolution Register No. 1681h Easy sequence u ser parameter U (27) P127 R/W 0 to 65530 1 1682h Easy sequence u ser parameter U (28) P128 R/W 0 to 65530 1 1683h Easy sequence u ser parameter U (29) P129 R/W 0 to 65530 1 1684h Eas[...]

  • Seite 218

    Chapter 4 Explanation of Functions 4 - 160 (vi) List of registers (2nd control setting s) Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 2103h F202 (high) R/W 2104h Acceleration (1) time setting, 2nd motor F202 (low) R/W 1 to 360000 0.01 [sec.] 2105h F203 (high) R/W 2106h Deceleration time, 2[...]

  • Seite 219

    Chapter 4 Explanation of Functions 4 - 161 Register No. Function name Function code R/W Monitori ng and s etting items Data resolution Register No. 230Ch Electronic thermal setting (calculated within the inverter from current output), 2nd motor b212 R/W 200 to 1000 0.1 [%] 230Dh Electronic thermal characteristic, 2nd motor b213 R/W 0 (reduced -torq[...]

  • Seite 220

    Chapter 4 Explanation of Functions 4 - 162 (viii) List of registers (3rd control settings) Register No. Function name Function code R/W Monitori ng and setting items Data resolution Register No. 3103h F302 (high) R/W 3104h Acceleration (1) time setting, 3rd motor F302 (low) R/W 1 to 360000 0.01 [sec.] 3105h F303 (high) R/W 3106h Deceleration (1) ti[...]

  • Seite 221

    Chapter 5 Error Codes This chapter describes the error codes of the inverter , error indications by the functions, and troubleshooting methods. 5.1 Error Co des and T roubleshoot ing ···················· 5 - 1 5.2 W arning Codes ················································· 5 [...]

  • Seite 222

    [...]

  • Seite 223

    Chapter 5 Error Codes 5 - 1 OC.Drive OC.Decel OC.Accel Over .C Over .L OL.BRD Over .V EEPROM 5.1 Error Codes and T roubleshooting 5.1.1 Error Codes Name Description Display on digital operator Display on remote operator T roubleshooting and co rrective action Reference page During cons tant- speed operation Check whether the load has fluctuated sha[...]

  • Seite 224

    Chapter 5 Error Codes 5 - 2 Under .V CT CPU EXTERNAL USP GND.Flt OV . SRC Inst.P-F OH.stF AN OH.fin Name Description Display on digital operator Display on remote operator Troubleshooting a nd correctiv e action Referen ce page Undervoltage If the inverter inpu t volt age drops, the control circuit of the inverter canno t function normally . Theref[...]

  • Seite 225

    Chapter 5 Error Codes 5 - 3 to GA.COM PH.fail Main.Cir IGBT TH BRAKE EMR OL-LowSP NET .ERR OP1-0 OP1-9 Name Description Display on digital operator Display on remote operator Troubleshooting a nd correctiv e action Referenc e page Gate array communica- tion error If an error occurs in the communication between the internal CPU and ga te array , the[...]

  • Seite 226

    Chapter 5 Error Codes 5 - 4 Name Description Display on digital operator Display on remote operator Troubleshooting a nd correctiv e action Reference page Option 2 error The inverter detect s errors in the option board mounted in the optional slot 2. For details, refer to the instructi on manual for the mounted option board. Check whether the optio[...]

  • Seite 227

    Chapter 5 Error Codes 5 - 5 5.1.2 Option boards error codes When an option board is mounted in the optional port 1 (located near the operator connecto r), the error code display format is "E6*. " (on the digit al operator ) or "OP1-*" (on the remote operator). Whe n it is mounted in the optional port 2 (located near the cont rol[...]

  • Seite 228

    Chapter 5 Error Codes 5 - 6 2) Error indications by protective function s with the digit al option board (SJ-DG) mounted Name Description Display on digital operator Display on remote operator ERR1*** SJ-DG error If timeout occurs during the communication between the inverter and di gital option board, the inverter will shut off its output and disp[...]

  • Seite 229

    Chapter 5 Error Codes 5 - 7 OP1-9 OP2-9 OP1-2 OP2-2 OP1-0 OP2-0 OP1-1 OP2-1 3) Error indications by protective functions with the DeviceNet option boa rd (SJ-DN) mounted Name Description Display on digital operator Display on remote operator Troubleshooti ng and corre ctive action Reference page DeviceNet communicatio n error If the disconnection d[...]

  • Seite 230

    Chapter 5 Error Codes 5 - 8 4) Error indications by protective func tions with the easy sequence function u sed Name Description Display on digital operator Display on remote operator ERR1*** Invalid instruction - T he inverter will display the err or code shown on the right if an invalid instruction is found in a do wnloaded program. (*1) - T he i[...]

  • Seite 231

    Chapter 5 Error Codes 5 - 9 5.1.3 T rip conditions monitoring : Resetting : Initial ization at power-on or w ith the reset term inal turned o n : S top ping the motor : Decelerating or operat ing the motor at constant s peed : Acceleratin g the motor : S tatus after receiving a zero-frequency operati on command : S tarting the mot or : Applying DC [...]

  • Seite 232

    Chapter 5 Error Codes 5 - 10 5.2 W arning Codes The following t able lists the warni ng codes and the content s of parameter readju stments: W arning code T arget function c ode Condition Basic function code 001/ 201 Frequency upper limit setting (A061/A261) > 002/ 202 Frequency lower limit setting (A062/A262) > 004/ 204/ 304 Base frequency set[...]

  • Seite 233

    Chapter 6 Maintenance and Inspection This chapter describes the precautions and procedures for the maintenance and inspection of the inverter . 6.1 Precautions for Maintenance and Inspection ......................................................... 6-1 6.2 Daily and Periodic Inspections ......................... 6-2 6.3 Ground Resistance T est with[...]

  • Seite 234

    [...]

  • Seite 235

    Chapter 6 Maintenance and Inspection 6 - 1 6.1 Precautions for Maintenance and Inspection W ARNING - Before inspecting the inverter , be sure to turn off the power supply and wait for 10 minutes or more. Otherwise, you run the risk of electric shock. (Before inspection, confirm that the Charge lamp on the inverter is of f and the DC voltage between[...]

  • Seite 236

    Chapter 6 Maintenance and Inspection 6 - 2 6.2 Daily and Periodic Inspections Inspection cycle Periodic Part to inspect Inspection item Detail of inspectio n Daily Annual Biennial Inspection method Criterion T est equipment Environment Check the ambient temperature, humidity , and dust. { See Section 2.1, "Inst allation." The ambient temp[...]

  • Seite 237

    Chapter 6 Maintenance and Inspection 6 - 3 6.3 Ground Resist ance T est with a Megger When testing an external circuit with a m egger , disconnec t all the external circuit cables from t he inverter to prevent it from being exposed to the test voltage. Use a tester (in high-resist ance range mode) for a co nduction test on the control circuit. Do n[...]

  • Seite 238

    Chapter 6 Maintenance and Inspection 6 - 4 6.5 Method of Checking the Inve rter and Converter Circuit s Y ou can check the quality of the inverter and converter circuits by u sing a tester . (Preparation ) 1) Remove the external power supply cables from term inals R, T , and T , the motor cables from terminals U, V , and W , and the regenerative br[...]

  • Seite 239

    Chapter 6 Maintenance and Inspection 6 - 5 6.6 DC-Bus Cap acitor Life Curve 10 20 30 40 50 0 -10 1 2 3 4 5 6 7 8 9 1 A mbient temp erature (ºC) When energ ized 24 ho urs a d ay Capacitor life (nu mber of years) Note 1: The ambient temperature indicates the temp erature measured at a posit ion ab out 5 cm distant from the bottom center of the inver[...]

  • Seite 240

    Chapter 6 Maintenance and Inspection 6 - 6 6.8 Methods of Measuring the Input/Ou tput V olt ages, Current, and Power This section describes the measuring instrument s gener ally used to measure the input and output voltage s, output current, and output pow er of the inverter . I R I S I T E R E T E S W I2 W I3 W I1 R T S U V W I U I V I W E U E W E[...]

  • Seite 241

    Chapter 7 S pecifications This chapter describes the specifications and external dimensions of the inverter . 7.1 S pecific ations ................................................... 7-1 7.2 External di mensions ......................................... 7-4[...]

  • Seite 242

    [...]

  • Seite 243

    Chapter 7 Specifications 7 - 1 7.1 Specifications (1) S pecifications of the 200 V class model Model name (type name) SJ700-XXXLFF ,LFU 055 075 1 10 150 185 220 300 370 450 550 Max. applicable motor capacity (4-pole) (kW) 5.5 7.5 1 1 15 18.5 22 30 37 45 55 200V 8.3 1 1.0 15.9 22.1 26.3 32.9 41.9 50.2 63.0 76.2 Rated capacity (kV A) 240V 9.9 13.3 19[...]

  • Seite 244

    Chapter 7 Specifications 7 - 2 (3) Common specification s of 200 V cl ass and 400 V class models (continued) Model name (type name) SJ700-XXXXXFF .FEFFUF 055 L/H 075 L/H 1 10 L/H 150 L/H 185 L/H 220 L/H 300 L/H 370 L/H 450 L/H 550 L/H S tandard operator Setting with 1 and 2 keys External signal 0 to +10 VDC, -1 0 to +10 VDC (input impedance: 10k ?[...]

  • Seite 245

    Chapter 7 Specifications 7 - 3 (3) Common specifications of 200 V class and 4 00 V class models (continued ) Model name (type name) SJ700-XXXXXFF .FEFFUF 055 L/H 075 L/H 1 10 L/H 150 L/H 185 L/H 220 L/H 300 L/H 370 L/H 450 L/H 550 L/H Ambient temperature, storage temperature, humidity -10 ° C to +50 ° C (ambient), -20 ° C to +65 ° C (sto rage),[...]

  • Seite 246

    Chapter 7 Specifications 7 - 4 7.2 External dimensions SJ700-055 to1 10LFF2/LFUF2 / HFF2/HFEF2/HFUF2 SJ700-150 to 220 LFF2/LF UF2 / HFF2/HFEF2/HFUF2 3 - Cable hole (42 x 42.5) 3 - Cable hole (33 x28)[...]

  • Seite 247

    Chapter 7 Specifications 7 - 5 SJ700-300 LFF2/LFUF2 / HFF2/ HFEF2/HFUF2 SJ700-370-450 LFF2/LFUF2 / HFF2/HF EF2/HFUF2, 550 HFF2/HFEF2/HFUF2 5 - Cable hole ( φ 25) 5 - Cable hole ( φ 41)[...]

  • Seite 248

    Chapter 7 Specifications 7 - 6 SJ700-550 LFF2/LFUF2 5 - Cable hole ( φ 41)[...]

  • Seite 249

    Chapter 8 List of Dat a Settings This chapter lists the dat a settings for the various functions of the inverter . 8.1 Precautions for Data Se tting ................8-1 8.2 Monitoring Mode...................................8-1 8.3 Function Mode .....................................8-2 8.4 Extended Func tion Mode .....................8-3[...]

  • Seite 250

    [...]

  • Seite 251

    Chapter 8 List of Dat a Settings 8 - 1 8.1 Precautions for Dat a Setting The default display mode limits the screens (parameters) that can be displayed on the monitor . T o enable the display of all par ameters, specify "00" (full display) for the function code display restriction (b037). T o enable the parameters to be changed while the [...]

  • Seite 252

    Chapter 8 List of Dat a Settings 8 - 2 Code Funct ion name Monitored data or setting Default Setting during operation (allowed or not) Change during operation (allowed or not) Page d025 User monitor 0 -2147483647 to 2147483647 (upper 4 digits including “-“) − − − d026 User monitor 1 -2147483647 to 2147483647 (upper 4 digits including “-[...]

  • Seite 253

    Chapter 8 List of Dat a Settings 8 - 3 8.4 Extended Function Mode Default Code Function name Monitor ed data or setting _FF _ FEF _ FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page A001 Frequency source setting 00 (keypad potentiometer) (*1), 01 (control circuit terminal block), 02 (digital operator), 03 ([...]

  • Seite 254

    Chapter 8 List of Dat a Settings 8 - 4 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page A041 T orque boost method selection 00 (manual torque boost), 01 (automatic torque boost) 00 ¯ ¯ A241 T orque boost method selection, 2nd motor 00 (manual[...]

  • Seite 255

    Chapter 8 List of Dat a Settings 8 - 5 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page A081 AVR function select 00 (always on), 01 (always off), 02 (off during deceleration) 02 00 00 ¯ ¯ AV R A082 AVR voltage select 200 V class: 200, 215, 22[...]

  • Seite 256

    Chapter 8 List of Dat a Settings 8 - 6 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page b001 Selection of r estart mode 00 (tripping), 01 (starting with 0 Hz), 02 (star ting with matching frequency), 03 (tripping after deceleration and stopping[...]

  • Seite 257

    Chapter 8 List of Dat a Settings 8 - 7 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page b034 Run/power-on warning t ime 0. to 9999. (0 to 99990), 1000 t o 6553 (10000 to 655300) (hr) 0. ¯ { 4-64 b035 Rotational direction restriction 00 (enabli[...]

  • Seite 258

    Chapter 8 List of Dat a Settings 8 - 8 Default Code Function name Monitor ed data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page b078 Cumulative input power data clearance Clearance by setting "01" and pressing the STR key 00 { { b079 Cumulative input power display gain set[...]

  • Seite 259

    Chapter 8 List of Dat a Settings 8 - 9 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page C001 T erminal [1] function (*2) 18 (*2) ¯ { C002 T erminal [2] function 16 ¯ { C003 T erminal [3] function (*2) 06 (*2) ¯ { C004 T erminal [4] function [...]

  • Seite 260

    Chapter 8 List of Dat a Settings 8 - 10 Default Code Function name Monit ored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page C021 T erminal [11] function 01 ¯ { C022 T erminal [12] f unction 00 ¯ { C023 T erminal [13] f unction 03 ¯ { C024 T erminal [14] f unction 07 ¯ { C02[...]

  • Seite 261

    Chapter 8 List of Dat a Settings 8 - 1 1 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page C038 Low-current indication signal output mode selection 00 (output during acceleration/deceleration and constant-speed operation), 01 (output only during[...]

  • Seite 262

    Chapter 8 List of Dat a Settings 8 - 12 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page Te r mi nal C1 11 Overload setting (2) 0. 0 to 2.00 x "rated current" (A) R ated current of inverter { { 4-40 C121 [O] input zero calibration 0. [...]

  • Seite 263

    Chapter 8 List of Dat a Settings 8 - 13 Default Code Funct ion name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page H001 Auto-tuning Sett ing 00 (disabling auto-t uning), 01 (auto-tuning without rotation), 02 (auto-tuning with rotation) 00 ¯ ¯ H002 Motor data selectio[...]

  • Seite 264

    Chapter 8 List of Dat a Settings 8 - 14 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page H050 PI proportional g ain for 1st motor 0. 0 to 999.9, 1000. 100.0 { { H250 PI proportional gain for 2nd motor 0.0 to 999.9, 1000. 100.0 { { H051 PI integ[...]

  • Seite 265

    Chapter 8 List of Dat a Settings 8 - 15 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page P001 Operation mode on expansion card 1 error 00 (tripping), 01 (continuing operation) 00 ¯ { P002 Operation mode on expansion card 2 error 00 (tripping),[...]

  • Seite 266

    Chapter 8 List of Dat a Settings 8 - 16 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page P060 Multistage position setting 0 Position setting range reverse side to forward side (upper 4 digits including “-“) 0 { { P061 Multistage position se[...]

  • Seite 267

    Chapter 8 List of Dat a Settings 8 - 17 Default Code Function name Monitored data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page P1 16 Easy sequence user pa rameter U (16) 0. to 9999., 1000 to 6553 (10000 to 65535) 0. { { P1 17 Easy sequence user pa rameter U (17) 0. to 9999., 1000 t[...]

  • Seite 268

    Chapter 8 List of Dat a Settings 8 - 18 Default Code Function name Monitor ed data or setting _FF _FEF _FUF Setting during operation (allowed or not) Change during operation (allowed or not) Page U001 User-selected funct ion 1 no/d001 to P131 no { { U002 User-selected funct ion 2 no/d001 to P131 no { { U003 User-selected funct ion 3 no/d001 to P131[...]

  • Seite 269

    Appendix A - 1 Upgrading from the SJ300 Series The SJ300 series inverter is upwardly compatibl e with the SJ700 series inverter . Therefore, you can: - mount the control circuit terminal block board of the SJ300 series in the SJ700 series without removing the connected cables, - copy the parameter settings from the SJ300 serie s into the SJ700 seri[...]

  • Seite 270

    Appendix A - 2 (2) Copying the p arameter settings If you use an optional remote operator (SR W-O J or SRW -OEX), you can copy (import) the parameter settings from the SJ300 series into the S J700 se ries. Note, however , that you cannot copy the parameter settings from th e SJ700 series to the SJ 300 series beca use the SJ700 series has many new f[...]

  • Seite 271

    In d ex Index - 1 A a/b ......................................................... 4-47 , 4 -61 Absolu te pos ition co ntrol . .. ... .. ... .. ... .. .. 4-106, 4-107 acce leration/ de cele r ati on pat t erns .. ... .. ... .. ... .. .. 4-32 acce leration curve consta nt ... ... .. ... .. ... .. ... .. ... ... 4-32 acce leration time.... ... .. ... [...]

  • Seite 272

    In d ex Index - 2 fre que ncy a dd itio n .......................................... 4 -15 freque ncy a rrival se t ting for acce l . .. .. ... .. ... .. ... .. 4-61 freque ncy a rrival se t ting for de cel.. ... .. ... .. ... ... .. 4-61 fre que ncy limi t................................................ 4-25 fre que ncy lowe r li mit..............[...]

  • Seite 273

    In d ex Index - 3 O O............................................................. 2-7, 2-1 8 O2 .................................................. 2-7, 2 -18 , 4-1 2 O2D c.............................................................. 4-7 1 OD ........................................................ 4-28 , 4 -29 Odc ................................[...]

  • Seite 274

    In d ex Index - 4 T T e achin g ....................................................... 4- 1 10 te st ru n .......................................................... 3 -10 the rmis tor .................................................4-4, 4-7 0 TH M .............................................................. 4-38 3-w ire inp ut .................[...]