Carrier FLOTRONIC II 30GN040-420 Bedienungsanleitung

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Richtige Gebrauchsanleitung

Die Vorschriften verpflichten den Verkäufer zur Übertragung der Gebrauchsanleitung Carrier FLOTRONIC II 30GN040-420 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 Carrier FLOTRONIC II 30GN040-420, 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 Carrier FLOTRONIC II 30GN040-420 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 Carrier FLOTRONIC II 30GN040-420. 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 Carrier FLOTRONIC II 30GN040-420 sollte vor allem folgendes enthalten:
- Informationen über technische Daten des Geräts Carrier FLOTRONIC II 30GN040-420
- Den Namen des Produzenten und das Produktionsjahr des Geräts Carrier FLOTRONIC II 30GN040-420
- Grundsätze der Bedienung, Regulierung und Wartung des Geräts Carrier FLOTRONIC II 30GN040-420
- 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 Carrier FLOTRONIC II 30GN040-420 zu wenig. Eine Anleitung beinhaltet eine Reihe von Hinweisen bezüglich bestimmter Funktionen, Sicherheitsgrundsätze, Wartungsarten (sogar das, welche Mittel man benutzen sollte), eventueller Fehler von Carrier FLOTRONIC II 30GN040-420 und Lösungsarten für Probleme, die während der Nutzung auftreten könnten. Immerhin kann man in der Gebrauchsanleitung die Kontaktnummer zum Service Carrier 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 Carrier FLOTRONIC II 30GN040-420 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 Carrier FLOTRONIC II 30GN040-420, 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 Carrier FLOTRONIC II 30GN040-420 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

    Controls, Operation, and T roubleshooting with Microprocessor Controls and Electronic Expansion V alves CONTENTS Page SAFETY CONSIDERA TIONS ..................2 GENERAL ...................................2 MAJOR SYSTEM COMPONENTS ............2 - 5 Processor Module ...........................2 Low-V oltage Relay Module ...................4 Electroni[...]

  • Seite 2

    SAFETY CONSIDERA TIONS Installing, starting up, and servicing this equipment can be hazardous due to system pressures, electrical compo- nents, and equipment location (roof, elevated structures, etc.). Only trained, qualified installers and service mechanics should install, start up, and service this equipment. When working on this equipment, obse[...]

  • Seite 3

    789 456 123 – 0• STAT EXPN HIST CLR SCHD SRVC SET TEST ENTR FUSE 1 LOC AL/ ENABLE SW1 STOP CCN FUSE 3 FUSE 2 F U S E F U S E F U S E CB5 CB6 EQUIP GND 99NA505322 D COMM 1 COMM 3 PWR XX S1 S2 XX POINT NUMBER OF FIRST CHANNEL COMM 3 PWR LV EXV ST A TUS COMM ST A TUS COMM 1 2 3+ 4- HK35AA002 Potter & Brumfield CZ770 5VDC GFI - CO ( 5 AMP MAX )[...]

  • Seite 4

    also controls the EXV driver module (as appropriate), com- manding it to open or close each EXV in order to maintain the proper superheat entering the cylinders of each lead com- pressor . Information is transmitted between the processor mod- ule and relay module, the EXV driver module, and the key- pad and display module through a 3-wire communica[...]

  • Seite 5

    The TXV is set at the factory to maintain approximately 8 to 12° F (4.4 to 6.7° C) suction superheat leaving the cooler by monitoring the proper amount of refrigerant into the cooler . All TXVs are adjustable, but should not be adjusted unless absolutely necessary . When TXV is used, thermistors T7 and T8 are not required. The TXV is designed to [...]

  • Seite 6

    T able 4A — Capacity Control Steps, 040-070 UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 040 (60 Hz) A1†,B1 1 25 A1* — — 25 0 A 1 — — 3 75 A1*, B1 — — 4 100 A1,B1 — — 040 (60 Hz) A1†,B1** 1 25 A1* 25 B1* 2 5 0A 1 5 0B 1 3 75 A1*,B1 75 A1,B[...]

  • Seite 7

    T able 4A — Capacity Control Steps, 040-070 (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 045 (50 Hz) 050 (60 Hz) A1†**,B1** 1 18 A1†† 20 B1†† 2 31 A1* 38 B1* 3 4 4A 1 5 6B 1 4 56 A1††,B1* 64 A1,B1†† 5 73 A1††,B1 82 A1,B1* 6 87 A1*[...]

  • Seite 8

    T able 4A — Capacity Control Steps, 040-070 (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 060 (50 Hz) 070 (60 Hz) A1†**,B1 | 1 16 A1†† 16 B1†† 2 33 A1* 33 B1* 3 5 0A 1 5 0B 1 4 66 A1††,B1 66 A1,B1†† 5 83 A1*,B1 83 A1,B1* 6 100 A1,B1 10[...]

  • Seite 9

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 080, 230B (60 Hz) A1†,B1† 1 22 A1* 30 B1* 2 3 4A 1 4 4B 1 3 52 A1*,B1* 52 A1*,B1* 4 67 A1*,B1 63 A1,B1* 5 78 A1,B1 78 A1,B1 6 89 A1*,A2,[...]

  • Seite 10

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 090, 245B (60 Hz) A1†,B1† 1 18 A1* 18 B1* 22 7 A 1 2 7 B 1 3 35 A1*,B1* 35 A1*,B1* 4 44 A1*,B1 44 A1,B1* 5 53 A1,B1 53 A1,B1 6 56[...]

  • Seite 11

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 090, 245B (50 Hz) A1†,B1†** 1 — — 7 B1†† 2 — — 14 B1* 3— — 2 1 B 1 4 — — 29 A1,B1†† 5 — — 36 A1,B1* 6[...]

  • Seite 12

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 100, 255B, 270B (60 Hz) A1†**,B1†** 1 8 A1†† 8 B1†† 2 16 A1* 16 B1* 3 2 3A 1 2 3B 1 4 31 A1††,B1 31 A1,B1†† 5 39 [...]

  • Seite 13

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 1 10, 290B, 315B (60 Hz) A1†,B1† 1 14 A1* 14 B1* 22 1 A 1 2 1 B 1 3 29 A1*,B1* 29 A1*,B1* 4 36 A1*,B1 36 A1,B1* 5 43 A1,B1 43 A1,[...]

  • Seite 14

    T able 4B — Capacity Control Steps, 080-1 10 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 1 10, 290B, 315B (50 Hz) A1†**,B1† 1 8 A1†† — — 2 17 A1* — — 32 5 A 1 — — 4 33 A1††,B1 — — 5 42 A1*,B1 ?[...]

  • Seite 15

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 130 (60 Hz) A1†,B1† 1 2 3 4 5 6 7 8 9 10 11 14 21 28 35 42 58 64 71 87 93 100 A1* A1 A1*,B1* A1*,B1 A1,B1 A1*,A2,B1* A1*,A2,B1 A1,A2,B1 A[...]

  • Seite 16

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 130 (50 Hz) A1†**,B1† 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 6 10 14 22 31 35 39 40 49 53 57 65 74 78 82 83 91 96 100 A1?[...]

  • Seite 17

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT 30GN CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 150, 230A, 245A, 255A (60 Hz) A1†**,B1† 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 6 11 15 24 33 38 42 49 53 58 66 75 80 85 91 95 1[...]

  • Seite 18

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 150, 230A, 245A, 255A (50 Hz) A1†,B1†** 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 — — — — — — — — — — — — — ?[...]

  • Seite 19

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 170, 270A, 330A/B (60 Hz) A1†,B1†** 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 — — — — — — — — ?[...]

  • Seite 20

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 170, 270A, 330A/B, 360B (50 Hz) A1†**,B1† 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 5 9 14 14 19 23 28 28 33 37 [...]

  • Seite 21

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 190, 290A, 360A/B, 390B (60 Hz) A1,B1 1 2 3 4 5 6 13 25 41 56 78 100 A1 A1,B1 A1,A2,B1 A1,A2,B1,B2 A1,A2,A3,B1,B2 A1,A2,A3,B1,B2,B3 13[...]

  • Seite 22

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 190, 290A, 360A, 390B (50 Hz) A1,B1** 1 2 3 4 5 6 7 8 9 10 11 12 — — — — — — — — — — — — — — — — — ?[...]

  • Seite 23

    T able 4C — Capacity Control Steps, 130-210 and Associated Modular Units (cont) UNIT SIZE CONTROL STEPS LOADING SEQUENCE A LOADING SEQUENCE B % Compressors % Compressors Displacement Displacement (Approx) (Approx) 210, 315A, 390A, 420A/B (60 Hz) A1**,B1** 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 8 11 17 22 25 28 33 36 48 52 56 59 63 67 [...]

  • Seite 24

    Head Pressure Control EXV UNITS (All 30GN units except 040 and 045 with op- tional brine) — The microprocessor controls the condenser fans in order to maintain the lowest condensing temperature possible, thus the highest unit ef f iciency . Instead of using the conventional head pressure control methods, the fans are con- trolled by the position [...]

  • Seite 25

    T able 5 — Condenser Fan Sequence F AN ARRANGEMENT 30GN F AN NUMBER(S) F AN CONT ACTOR (FC) CONTROLLED BY 040-050 1 FC-A1 Compressor A1 2 FC-B1 Compressor B1 3 FC-A2 First Stage Microprocessor 4 FC-B2 Second Stage Microprocessor 060,070 1 FC-A1 Compressor A1 2 FC-B1 Compressor B1 3, 4 FC-A2 First Stage Microprocessor 5, 6 FC-B2 Second Stage Micro[...]

  • Seite 26

    T able 6 — Keypad and Display Module Usage FUNCTION KEYS USE ST A TUS — For displaying diagnostic codes and current operating information about the machine. HISTOR Y — For displaying run time, cycles and previous alarms. SERVICE — For entering specific unit configura- tion information. TEST — For checking inputs and outputs for proper o[...]

  • Seite 27

    T able 8 — Accessing Functions and Subfunctions OPERA TION KEYP AD DISPLA Y EXP ANSION ENTR Y RESPONSE T o access a function, press RESET RESET SETPOINTS subfunction no. and function name key . Display shows sub- function group. T o move to other elements, scroll up or down using arrow keys. NOTE: These displays do not show if control is not con?[...]

  • Seite 28

    T able 9 — Keypad Directory (cont) ST A TUS (cont) SUBFUNCTION KEYP AD ENTR Y DISPLA Y COMMENT 4 ST AGE ST AGE Capacity Staging Information COOL X Number of Requested Stages CAPT X Percent of T otal Capacity CAP A X Percent Circuit A T otal Capacity CAPB X Percent Circuit B T otal Capacity A V AIL X Percent Available Capacity A V A X Percent Circ[...]

  • Seite 29

    T able 9 — Keypad Directory (cont) ST A TUS (cont) SUBFUNCTION KEYP AD ENTRY DISPLA Y COMMENT 7 PRESSURE PRESSURE Refrigerant System Pressure (psig) MM DD YY Date of Last Calibration DP A X Circuit A Discharge Pressure (psig) SP A X Circuit A Suction Pressure (psig) XXXX XXX Circuit A Discharge/Suction (psig) OP A X Circuit A Oil Pressure Differe[...]

  • Seite 30

    T able 9 — Keypad Directory (cont) ST A TUS (cont) SUBFUNCTION KEYP AD ENTR Y DISPLA Y COMMENT 10 OUTPUTS (cont) EXVB X EXVB Percent Open** HGBA X† Hot Gas Bypass Relay Circuit A (on/off)** HGBB X† Hot Gas Bypass Relay Circuit B (on/off)** MMA X† Motormaster T A Output Percent** MMB X† Motormaster B Output Percent** TEST T o use T est fun[...]

  • Seite 31

    T able 9 — Keypad Directory (cont) TEST (cont) SUBFUNCTION KEYP AD ENTR Y DISPLA Y COMMENT 2 COMPRESSORS AND UNLOADERS (cont) CP A3 X† T est Compressor A3 (on/off)** CP A4 X† T est Compressor A4 (on/off)** CPB1 X T est Compressor B1 (on/off) CPB2 X† T est Compressor B2 (on/off)** CPB3 X† T est Compressor B3 (on/off)** CPB4 X† T est Comp[...]

  • Seite 32

    T able 9 — Keypad Directory (cont) SCHEDULE (cont) SUBFUNCTION KEYP AD ENTRY DISPLA Y COMMENT 3 PERIOD 1 (cont) FRI X Friday Flag (yes/no) SA T X Saturday Flag (yes/no) SUN X Sunday Flag (yes/no) HOL X Holiday Flag (yes/no) T o toggle between inputs (Y es/No) Press: (no) or (yes) 4 PERIOD 2 PERIOD 2 Period 2 T ime Schedule 5 PERIOD 3 ... 9 PERIOD[...]

  • Seite 33

    T able 9 — Keypad Directory (cont) SERVICE (cont) SUBFUNCTION KEYP AD ENTR Y DISPLA Y COMMENT 3 F ACTOR Y CONFIGURA TION (cont) XXXXXXXX Configuration Code 5 XXXXXXXX Configuration Code 6 XXXXXXXX Configuration Code 7 4 FIELD CONFIGURA TION FLD CFG Adjustable Field Configuration ENO X CCN Element Address BUS X CCN Bus Number BAUD X CCN Baud R[...]

  • Seite 34

    T able 9 — Keypad Directory (cont) HISTOR Y SUBFUNCTION KEYP AD ENTRY DISPLA Y COMMENT 1 RUN TIME RUN TIME Run Time Information HR X T otal Hrs Unit Has a Comp Operating HRA X Circuit A Run Time HRB X Circuit B Run Time HA1 X Circuit A, Comp A1 Operating Hours HA2 X Circuit A, Comp A2 Operating Hours** HA3 X Circuit A, Comp A3 Operating Hours** H[...]

  • Seite 35

    T able 9 — Keypad Directory (cont) SET POINT T o read a set point, go to proper subfunction and read desired set point. T o change a set point, enter new set point value, then press . LOCAL/ENABLE-STOP-CCN switch must be in LOCAL/ENABLE or ST OP position. SUBFUNCTION KEYP AD ENTRY DISPLA Y COMMENT 1 SET POINTS SET POINT Unit Set Point CSP1 X Chil[...]

  • Seite 36

    ST A TUS FUNCTION — This function shows the rotating display , current status of alarm and alert (diagnostic) codes, capacity stages, operating modes, chilled water set point, all measured system temperatures and pressures, superheat val- ues, pressure switch positions, analog inputs, and switch in- puts. These subfunctions are defined on pages [...]

  • Seite 37

    T able 10 — Operational and Mode Display Codes The operating modes are displayed by name or code num- ber , to indicate the operating status of the unit at a given time. The modes are: CODE DESCRIPTION LOCAL OFF Unit is of f. LOCAL/ENABLE-STOP-CCN switch is in OFF position, or LOCAL/ENABLE-STOP-CCN switch may be in LOCAL position with external ON[...]

  • Seite 38

    Keypad entry allows the operator to make the following checks by using : • LID display check. Proper display is 8.8.8.8.8.8.8.8. • Operation of alarm relay . • Operation of condenser fans. • Operation of chilled fluid pump. • Operation of liquid line solenoids. • Operation of the hot gas bypass relays. • Operation of EXVs. T o drive [...]

  • Seite 39

    Example 4 — Reading and Changing Chilled Fluid Set Point KEYP AD DISPLA Y COMMENTS ENTR Y RESPONSE SET POINT System set points CSP1 44.0 Present occupied chilled fluid set point is 44.0 F CSP1 42.0 Press the . Display shows new occupied chilled fluid set point is 42.0 F CSP2 44.0 Present unoccupied chilled fluid set point is 44.0 F CSP2 50.0 P[...]

  • Seite 40

    Example 5 B—4t o2 0m Aa n d Internally or Externally Powered Reset In this example, the unit set point is reset from full load at 4 mA to a maximum reset value of 10 F (5.5 C) at 20 mA. Internally powered 4 to 20 mA option is used in this example. NOTE: T o use externally powered reset, when CR TYP appears, press so CR TYP 4 appears in the displa[...]

  • Seite 41

    Fig. 6 — Cooling External T emperature Reset LEGEND COMM — Communications Bus PWR — Power SW — Switch NOTE: For specific connection points, see Fig. 25 - 29. F i g .7—4 IN/4 OUT Options Module Wiring for Reset, Demand Limit, and Dual Set Point 41[...]

  • Seite 42

    Example 6 — Changing Reset T ype T o change type of reset, first log on as shown in T able 12. Also refer to Set Point Function section, page 38, for information on entering reset set points using reset feature. KEYP AD DISPLA Y COMMENTS ENTR Y RESPONSE FLD CFG Field configuration subfunction of service function CSPTYP 0 Scroll past single cool[...]

  • Seite 43

    At field configuration step, select 4 to 20 mA loadshed by entering (internally powered) or (externally pow- ered) when the LSTYP 0 display appears. See Example 7B. Then enter set points as follows. In this example, set points are coordinates of the demand limit curve shown in Fig. 9. Example 7A — Using Demand Limit (First Log On as Shown in T [...]

  • Seite 44

    Factory Configuration Codes — allows entry into the factory configuration subfunction. Under this subfunc- tion, there are 7 groups of configuration codes that are down- loaded at the factory . Each group is made up of 8 digits. If processor module is replaced in the field, these 7 groups of configuration codes must be entered through the ke[...]

  • Seite 45

    T able 13 — Factory Configuration Keystrokes T o change a configuration enter the new configuration and press while on the correct configuration. SUB- KEYP AD DISPLA Y COMMENTS FUNCTION ENTR Y 3 F ACTORY CFG F ACT CFG F ACTORY CONFIGURA TION CODES XXXXXXXX Configuration Code 1 XXXXXXXX Configuration Code 2 XXXXXXXX Configuration Code 3 XXX[...]

  • Seite 46

    NOTE: This is true only if the occupied period starts at 00:00 (midnight). If the occupied period starts at a time other than midnight, then the occupied period must end at 00:00 hours (midnight) and new occupied period must be programmed to start at 00:00 in order for the chiller to stay in the occu- pied mode past midnight. The time schedule can [...]

  • Seite 47

    Periods 4 and 5 can be programmed in the same manner , flagging Thursday and Friday yes for period 4 and Saturday yes for period 5. For this example, periods 6, 7, and 8 are not used: they should be programmed OCC 00.00, UNO 00.00. NOTE: When a day is flagged yes for 2 overlapping periods, occupied time will take precedence over unoccupied time. [...]

  • Seite 48

    Unit Shutoff — T o shut unit of f, move LOCAL/ENABLE- STOP-CCN switch to ST OP position. Any refrigeration cir- cuit operating at this time continues to complete the pum- pout cycle. Lag compressors stop immediately , and lead compressors run to complete pumpout. Complete Unit Stoppage — Complete unit stoppage can be caused by any of the follow[...]

  • Seite 49

    T able 16 — Alarm and Alert Codes DISPLA Y ALARM DESCRIPTION ACTION T AKEN CIRCUIT RESET PROBABLE CAUSE OR ALERT BY CONTROL PUMPDOWN METHOD 0 — No Alarms or Alerts Exist — — — — 1 Alert Compressor A1 failure Circuit A shut down No Manual High-pressure switch trip, or wiring error . 2, 3, 4 Compressor A2, A3, A4 failure Compressor shut d[...]

  • Seite 50

    T able 16 — Alarm and Alert Codes (cont) DISPLA Y ALARM DESCRIPTION ACTION T AKEN CIRCUIT RESET PROBABLE CAUSE OR ALERT BY CONTROL PUMPDOWN METHOD 63 Alarm Complete unit shutdown Alarm only — Auto. Check individual alarms 64 Alert Loss of charge, circuit A Circuit cannot start — Auto. Refrigerant leak or transducer failure 65 Loss of charge, [...]

  • Seite 51

    Code 21 Reset thermistor failure (applies only to installa- tions having external temperature reset) (alert) If temperature measured by this thermistor is outside range of –40 to 240 F (–40 to 1 16 C), reset function is disabled and unit controls to normal set point. If temperature returns to the acceptable range, reset function is automaticall[...]

  • Seite 52

    The voltage supplied to the processor is polarized. When checking for proper voltage supply , be sure to consider this polarity . If voltage appears to be within acceptable toler - ance, check to be sure the transformer supplying PS1 is not grounded. Gr ounding the supply transformer can result in serious damage to the contr ol system. Code 29 LOCA[...]

  • Seite 53

    Loss of communication can be attributed to a grounded transformer with a secondary voltage of 21 vac supplying the PSIO, DSIO-L V , or 4 IN/4 OUT ; the 12.5-vac trans- former supplying the DSIO-EXV module, or the 24-vac trans- former supplying PS1 for the transformers. These transformers should not be gr ounded, or serious damage to controls can r [...]

  • Seite 54

    If oil pressure dif ferential is less than set point for more than 2 minutes at start-up, or more than one minute during normal operation, af fected circuit shuts down without going through pumpout process. Reset is manual with LOCAL/ ENABLE-STOP-CCN switch, and start-up follows normal sequence. Factory configured dif ferential oil pressure is 6 p[...]

  • Seite 55

    LOCAL/ENABLE-STOP-CCN switch. Most probable cause of this fault is shutdown or failure of chilled fluid pump to start. Other possibilities are improper configuration or wir- ing errors. Code 55 Cooler pump interlock failure — Contacts closed when pump is of f (alarm) If the unit is configured for cooler pump control and cooler pump interlock, [...]

  • Seite 56

    vapor). T o control refrigerant flow for dif ferent operating con- ditions, sleeve moves up and down over orifice, thereby chang- ing orifice size. Sleeve is moved by a linear stepper motor . Stepper motor moves in increments and is controlled di- rectly by the processor module. As stepper motor rotates, motion is transferred into linear movemen[...]

  • Seite 57

    reading correctly . Connect a calibrated gage to lead compressor suction or discharge pressure connection to check transducer reading. e. Make sure transducer leads are properly connected in junction box and at processor board. Check trans- former 5 output. Check voltage transducer 5 vdc 6 .2 v . When above checks have been completed, check ac- tua[...]

  • Seite 58

    T able 17 — Thermistor T emperature (°F) vs Resistance/V oltage Drop; Flotronic™ II TEMPERA TURE VOL T AGE RESIST ANCE (F) DROP (V) (OHMS) −25.0 4.821 98010 −24.0 4.818 94707 −23.0 4.814 91522 −22.0 4.806 88449 −21.0 4.800 85486 −20.0 4.793 82627 −19.0 4.786 79871 −18.0 4.779 77212 −17.0 4.772 74648 −16.0 4.764 72175 −15.[...]

  • Seite 59

    T able 18 — Thermistor T emperature (°C) vs Resistance/V oltage Drop; Flotronic™ II TEMPERA TURE VOL T AGE RESIST ANCE (C) DROP (V) (Ohms) −40 4.896 168 230 −39 4.889 157 440 −38 4.882 147 410 −37 4.874 138 090 −36 4.866 129 410 −35 4.857 121 330 −34 4.848 1 13 810 −33 4.838 106 880 −32 4.828 100 260 −31 4.817 94 165 −30 [...]

  • Seite 60

    Pressure T ransducers — A single style of pressure transducer is used for both high- and low-pressure sensing on Flotronic™ II chillers. However , this transducer must be calibrated before the unit will operate. On new units, this will have been done at the factory in order to test run the unit. If a transducer or PSIO is replaced in the field[...]

  • Seite 61

    Fig. 15 — Thermistor Locations (Circuits A and B, Lead Compressor Only) FLUID-SIDE TEMPERA TURE THERMISTOR T2 (ALL UNITS) COMPRESSOR SUCTION GAS TEMPERA TURE THERMISTORS T7 AND T8 (ALL UNITS) AND FLUID-SIDE TEMPERA TURE THERMISTOR T1 (ALL UNITS) Fig. 16 — Thermistors 61[...]

  • Seite 62

    TRANSDUCER REPLACEMENT Transducers are installed directly in the refrigerant cir- cuit. Relieve all refrigerant pressure using standard re- frigeration practices before removing. 1. Relieve refrigerant pressure using standard refrigeration practices. 2. Disconnect transducer wiring at transducer by pulling up on locking tab while pulling weathertig[...]

  • Seite 63

    Control Modules Turn controller power of f before servicing controls. This ensures safety and prevents damage to controller. PROCESSOR MODULE (PSIO), 4 IN/4 OUT MODULE (SIO), LOW -VOL T AGE RELA Y MODULE (DSIO-L V), AND EXV DRIVER MODULE (DSIO-EXV) — The PSIO, DSIO and SIO modules all perform continuous diagnostic evaluations of the condition of [...]

  • Seite 64

    PROCESSOR MODULE (PSIO) (Fig. 20) Inputs — Each input channel has 3 terminals; only 2 of the terminals are used. Application of machine determines which terminals are used. Always refer to individual unit wiring for terminal numbers. Outputs — Output is 24 vdc. There are 3 terminals, only 2 of which are used, depending on application. Refer to [...]

  • Seite 65

    If accessory unloaders are desired, an accessory unloader package is used. Package includes a suction cutof f unloader head package. The 24-v coil in the package can be used for 040-1 10, 130 (60 Hz), and associated modular units (T able 1). A 1 15 v or 230 v coil must be used for 130 (50 Hz), 150-210, and associated modular units (T able 1). Coil [...]

  • Seite 66

    T able 19 — T roubleshooting SYMPTOMS CAUSE REMEDY COMPRESSOR DOES NOT RUN Power line open Reset circuit breaker . Control fuse open Check control circuit for ground or short. Replace fuse. High-Pressure Switch (HPS) tripped Move LOCAL/ENABLE-STOP-CCN switch to ST OP position then back to RUN or CCN position. T ripped power breaker Check the cont[...]

  • Seite 67

    5. Using test function, check unloaders. Press . Key- pad display reads OUTPUTS. Press until display reads UNA2 OFF . Press . Relay energizes. Press and relay deenergizes. Press until display reads UNB2 OFF . Press . Relay energizes. Press and relay deenergizes. 6. When unloader check has been performed, return LOCAL/ ENABLE-STOP-CCN to proper posi[...]

  • Seite 68

    LEGEND C— Contactor PWR — Power CB — Circuit Breaker SW — Switch COMM — Communications Bus TRAN — Transformer HGBPR — Hot Gas Bypass Relay U— Unloader *Or HGBPR-A. †Or HGBPR-B. LEGEND COM — Communications Bus TB — T erminal Block HGBPR — Hot Gas Bypass Relay TRAN — Transformer NO — Normally Open U— Unloader SNB — Snu[...]

  • Seite 69

    FIELD WIRING Refer to Fig. 25-35 for field wiring. NOTE: Contacts must be rated for dry circuit application, capable of reliably switching a 5 vdc, 1 mA to 20 mA load. Fig. 25 — Demand Limit — T wo External Switch Inputs Fig. 26 − Demand Limit — 4-20 mA Signal (Externally Powered) Fig. 27 — Demand Limit — 4-20 mA Signal (Internally Pow[...]

  • Seite 70

    REPLACING DEFECTIVE PROCESSOR MODULE The replacement part number is printed on a small label on the front of the PSIO module. The model and serial num- bers are printed on the unit nameplate located on an exterior corner post. The proper software and unit configuration data is factory installed by Carrier in the replacement module. Therefore, when[...]

  • Seite 71

    [...]

  • Seite 72

    Copyright 1995 Carrier Corporation Manufacturer reserves the right to discontinue, or change at any time, specifications or designs without notice and without incurring obligations. Book 2 Ta b 5 c PC 903 Catalog No. 563-079 Printed in U.S.A. Form 30GN-3T Pg 72 7-95 Replaces: 30G-1T[...]