TRANS MAINS - Unité de transfert automatique Emko - Free user manual and instructions

USER MANUAL TRANS MAINS Emko

CE UK CA EAC

TRANS-MAINS

AUTOMATIC TRANSFER & LOAD SHARE UNIT WITH MAINS User Manual

CONTENTS

1. Introduction Page 4

1.1 General Specifications.... Page 4
1.2 Warranty.... Page 4
1.3 Maintenance Page 4

2.Installation.... Page 5

2.1 Unit Configuration Page 5
2.2 Panel Mounting...... Page 5

Figure 2.1 Front View...... Page 5

Figure 2.2 Panel Cut-Out.... Page 5

2.3 Electrical Connection.... Page 6

3. Definition Of Front Panel And Accessing To The Parameters...... Page 8

3.1 Front Panel Description.... Page 8
3.2 Changing And Saving Parameter Values Page 17

4.Operation Page 19

4.1 Stop Mode Page 19
4.2 Manual Mode Page 19

4.2.1 Manual Start Page 19
4.2.2 Manual Stop Page 19

4.3 Auto Mode Page 20

4.3.1 Auto Start Sequence.... Page 20
4.3.2 Auto Stop Sequence.... Page 20

4.4 Test Mode Page 20
4.5 Multiple Mains.... Page 21

5.Parameters...... Page 22

5.1 Operator Parameters...... Page 22

5.1.1 Mains Page 22
5.1.2 Generator.... Page 22

5.2 Technician Parameters.... Page 23

5.2.1 System Page 23
5.2.2 Mains Page 34
5.2.3 Generator.... Page 35
5.2.4 Engine.... Page 36
5.2.5 Inputs Page 38
5.2.6 Outputs.... Page 42
5.2.7 Timers.... Page 51
5.2.8 Expansion Modules.... Page 52
5.2.9 Synchronization.... Page 54
5.2.10 Logic Controller.... Page 60
5.2.11 User Adjustment.... Page 66

6.The Feature Of Exporting Of The Internal Data & Event Logs...... Page 67

7. Logic Controller.... Page 71

8. Specifications.... Page 80

9. Other Informations...... Page 81

Manufacturer's Name : EMKO ELEKTRONIK A.S.

Manufacturer's Address : Bursa Organize Sanayi Bölgesi, Fethiye OSB Mah. Turkuaz Cad. No:15 16215 Bursa, TÜRKİYE

This declaration is issued under the sole responsibility of the manufacturer.

Product Name : Transfer S&ytochronising & Automatic

Type Number : TRANS-MAINS

Product Category : Electrical equipment for measurement, control and laboratory use

The product(s) that are stated above are fully in conformity with the essential requirements of Council Directives:

2014 / 35 / EU The Low Voltage Directive

2014 / 30 / EU The Electromagnetic Compatibility Directive

2011 / 65 / EU The Restriction of Hazardous Substances (RoHS 2) Directive

2015 / 863 / EU Amendment to Annex II of Directive 2011/65/EU

2017 / 2102 / EU Amendment to Annex II of Directive 2011/65/EU

This declaration is based on the full compliance of the products with the following European standards:

EN 61010-1:2010+A1:2019 Safety Requirements for Electrical Equipment for Measurement, Control and Laboratory Use

EN 61326-1:2021 Electrical Equipment for Measurement, Control and Laboratory Use - EMC Requirements

EN 60947-6-1:2005/A1:2014 Low - Voltage Switchgear and Controlgear - Part 6-1: Multiple Function Equipment - Transfer Switching Equipment

EN 50581:2012 Technical Documentation for The Assessment of Electrical and Electronic Products With Respect to The Restriction of Hazardous Substances

When and Where Issued Authorized Signature

25 October 2023 Name : Arzu ATAN

BURSA-TÜRKİYE Position : Quality Manager

1. Introduction

1.1 General Specifications

TRANS-MAINS is a mains control, synchronising and automatic transfer unit.

The unit is designed to synchronise the gensets (controlled by TRAN-SYNCRO units) with mains supplies. The unit controls the change over from mains supply to genset supply or runs gensets in parallel with the mains to provide no-break, peak lopping and peak shaving power solutions.

General Specifications:

• Load sharing with genset (up to 32 gensets)
• Busbar voltages and frequency measurements
• Bus failure detection
• Peak lopping (mains or genset)
• Power export to mains
• Mains de-coupling protection with R.O.C.O.F and vector shift methods
• Volts, frequency and phase matching
• Synchroscope display
• Logic Controller functionality for PLC
• Black or gray theme selection for 4."3 TFT LCD screen

The unit is extensively programmable through the front panel, with password protection on two levels. Operational parameters can also be monitored and controlled from a PC via a built-in USB communication port.

The unit monitors mains & bus operation and gives warning of any faults that are detected. If a fault is detected, the unit shuts down the engine and shows the failure message on the LCD display and activates the internal sounder.

The unit has got the “Event Log” feature. The unit records the last 500 events along with the date-time value and measurement values at the moment of the event.

1.2 Warranty

EMKO Elektronik warrants that the equipment delivered is free from defects in material and workmanship. This warranty is provided for a period of two years. The warranty period starts from the delivery date. This warranty is in force if duty and responsibilities which are determined in warranty document and instruction manual performs by the customer completely.

1.3 Maintenance

Repairs should only be performed by trained and specialized personnel. Cut power to the device before accessing internal parts.

Do not clean the case with hydrocarbon-based solvents (Petrol, Trichlorethylene etc.). Use of these solvents can reduce the mechanical reliability of the device. Use a cloth dampened in ethyl alcohol or water to clean the external plastic case.

2. Installation

Before beginning installation of this product, please read the instruction manual and warnings below carefully.

A visual inspection of this product for possible damage occurred during shipment is recommended before installation. It is your responsibility to ensure that qualified mechanical and electrical technicians install this product.

If there is danger of serious accident resulting from a failure or defect in this unit, power off the system and separate the electrical connection of the device from the system.

Keep the power off until all of the wiring is completed so that electric shock and trouble with the unit can be prevented.

2.1 Unit Configuration

The unit can be programmed using the buttons and LCD display on the front panel or PC Software.

2.2 Panel Mounting

The unit is designed for panel mounting. Fixing is by two screw fixings.

1- Insert the unit in the panel cut-out from the front.
2- Insert the fixings in the slotted at the corners of the unit and tighten the fixing screws to secure the unit against the panel.

During the equipment is putted in hole on the metal panel while mechanical installation some metal burrs can cause injury on hands, you must be careful.

Figure 2.1 Front View Figure 2.2 Panel Cut-Out

2.3 Electrical Connection

TRANS-MAINS three phase connections schematic

graph TD
    A["Conf. Input-13"] --> B["23"]
    C["Conf. Input-12"] --> D["24"]
    E["Conf. Input-11"] --> F["25"]
    G["Conf. Input-10"] --> H["26"]
    I["Conf. Input-9"] --> J["27"]
    K["Conf. Input-8"] --> L["28"]
    M["Conf. Input-7"] --> N["29"]
    O["Conf. Input-6"] --> P["30"]
    Q["Conf. Input-5"] --> R["31"]
    S["Conf. Input-4"] --> T["32"]
    U["Bus closed aux. (Conf. Input-3)"] --> V["33"]
    W["Mains closed aux. (Conf. Input-2)"] --> X["34"]
    Y["Emergency stop (Conf. Input-1)"] --> Z["35"]
    AA["BATTERY+"] --> AB["51"]
    AC["BATTERY+"] --> AD["52"]
    AE["Conf. Output-9"] --> AF["53"]
    AG["Conf. Output-8"] --> AH["54"]
    AI["Conf. Output-7"] --> AJ["55"]
    AK["Conf. Output-6"] --> AL["56"]
    AM["Conf. Output-5"] --> AN["57"]
    AO["Conf. Output-4"] --> AP["58"]
    AQ["Conf. Output-3"] --> AR["59"]
    AS["Conf. Output-2"] --> AT["60"]
    AU["Conf. Output-1"] --> AV["61"]
    AW["FUSSE-8"] --> AX["FUSE-7"]
    AY["BATTERY+"] --> AZ["62"]
    BA["EARTH"] --> BB["63"]

    BC["PROMAMING USB HOST"] --> BD["21 20 19 18 17 MAX 300V~"]
    BE["EHERNET RJ45"] --> BF["3 MAINS CURRENT MAX 300V~"]
    BG["RJ45"] --> BH["FUSE-1 FUSE-2 FUSE-3"]

    BI["Mains VOLTS"] --> BJ["8 7 6 5 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"]

    BK["Mains Contactor Output (MGB)"] --> BL["8A"]
    BL --> BM["M Mains Output (MGB)"]

    BN["Battery+"] --> BO["TRASTROR OUTPUTS MAX: 1 A"]
    BP["Battery+"] --> BQ["TRASTROR OUTPUTS MAX: 15 A"]

    BQ --> BR["L1 LOAD CURRENT MAX: 300V~"]
    BS["L1 LOAD CURRENT MAX: 300V~"] --> BT["FUSE-4 FUSE-5 FUSE-6"]
    BU["L1 LOAD CURRENT MAX: 300V~"] --> BV["FUSE-4 FUSE-5 FUSE-6"]

    BW["FUSSE-8"] --> BX["FUSSE-7 FUSE-8"]

    BY["FUSSE-8"] --> CA["FUSSE-7 FUSE-8"]

    CB["FUSSE-7 FUSE-8"] --> CC["FUSE-7 FUSE-7 FUSE-8"]

    CE["FUSE-7 FUSE-8"] --> CF["FUSE-7 FUSE-7 FUSE-8"]

    CG["FUSE-7 FUSE-8"] --> CH["FUSE-7 FUSE-7 FUSE-8"]

    CI["FUSE-7 FUSE-8"] --> CJ["FUSE-7 FUSE-7 FUSE-8"]

    CK["FUSE-7 FUSE-8"] --> CL["FUSE-7 FUSE-7 FUSE-8"]

    CM["FUSE-7 FUSE-8"] --> CN["FUSE-7 FUSE-7 FUSE-8"]

    CO["FUSE-7 FUSE-8"] --> CP["FUSE-7 FUSE-7 FUSE-8"]

    CEF["FUSE-7 FUSE-8"] --> CGF["FUSE-7 FUSE-7 FUSE-8"]

    CEG["FUSE-7 FUSE-8"] --> CEH["FUSE-7 FUSE-7 FUSE-8"]

    CEI["FUSE-7 FUSE-8"] --> CEJ["FUSE-7 FUSE-7 FUSE-8"]

    CEJ["FUSE-7 FUSE-8"] --> CEK["FUSE-7 FUSE-7 FUSE-8"]

    CEL["FUSE-7 FUSE-8"] --> CEM["FUSE-7 FUSE-7 FUSE-8"]

    CEM["FUSE-7 FUSE-8"] --> CEN["FUSE-7 FUSE-7 FUSE-8"]

    CEO["FUSE-7 FUSE-8"] --> CEP["FUSE-7 FUSE-7 FUSE-8"]

    CEQ["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CER["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CES["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEU["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEV["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEW["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEX["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEY["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEZ["FUSE-7 FUSE-8"] --> CEQF["FUSE-7 FUSE-7 FUSE-8"]

    CEYF["FUSSE -2 A.T"] --> CEQF
    CEYG["FUSSE -2 A.T"] --> CEQH
    CEYI["FUSSE -2 A.T"] --> CEQJ
    CEYK["FUSSE -2 A.T"] --> CEQL
    CEYM["FUSSE -2 A.T"] --> CEQN
    CEYO["FUSSE -2 A.T"] --> CEQP
    CEYQ["FUSSE -2 A.T"] --> CEQQ
    CEYR["FUSSE -2 A.T"] --> CEQS
    CEYS["FUSSE -2 A.T"] --> CEQT
    CEYU["FUSSE -2 A.T"] --> CEQT
    CEYT["GENERATOR BUS"] --> CEQF
    CEQT --> CEQT

    style A fill:#f9f,stroke:#333
    style B fill:#ccf,stroke:#333
    style C fill:#cfc,stroke:#333
    style D fill:#fcc,stroke:#333
    style E fill:#fcc,stroke:#333
    style F fill:#fcc,stroke:#333
    style G fill:#fcc,stroke:#333
    style H fill:#fcc,stroke:#333
    style I fill:#fcc,stroke:#333
    style J fill:#fcc,stroke:#333
    style K fill:#fcc,stroke:#333
    style L fill:#fcc,stroke:#333
    style M fill:#fcc,stroke:#333
    style N fill:#fcc,stroke:#333
    style O fill:#fcc,stroke:#333
    style P fill:#fcc,stroke:#333
    style Q fill:#fcc,stroke:#333
    style R fill:#fcc,stroke:#333
    style S fill:#fcc,stroke:#333
    style T fill:#fcc,stroke:#333
    style U fill:#fcc,stroke:#333
    style V fill:#fcc,stroke:#333
    style W fill:#fcc,stroke:#333
    style X fill:#fcc,stroke:#333
    style Y fill:#fcc,stroke:#333
    style Z fill:#fcc,stroke:#333

1- Connect the unit as shown in the appropriate diagram. Be sure to connect the battery supply the right way round. External fuse is recommended. Stranded cable cross section: 1,5mm ^2 ; Solid cable cross section: 2,5mm ^2 , The stripping length is 7 to 9 mm. Supply cables must comply with the requirements of IEC 60277 or IEC 60245.
2- The first and last units must be fitted with a 120 ohm resistor across H and Screened cable must be used for connecting the communication. The screen is grounded at one end ONLY.
3- Current transformers secondary should be grounded. The CT of 5VATs is carried in a sealed burden of 0.5VA on the CT.

graph TD
    MAINS-1["MAINS-1"] --> LOAD-1["LOAD-1"]
    MAINS-2["MAINS-2"] --> LOAD-2["LOAD-2"]
    MAINS-32["MAINS-32"] --> LOAD-32["LOAD-32"]

    MAINS-1 --> TransMainsUnit1["Trans-Mains Unit"]
    MAINS-2 --> TransMainsUnit1
    MAINS-32 --> TransMainsUnit1

    TransMainsUnit1 --> BusMonitoring1["Bus Monitoring"]
    TransMainsUnit1 --> BusMonitoring2["Bus Monitoring"]

    TransSyncroUnit1["Trans-Syncro Unit"] --> GCBGBCBMCB["GCBGBCBMCB"]
    TransSyncroUnit1 --> GCBGBCBMCB
    TransSyncroUnit1 --> GCBGBCBMCB

    GCBGBCBMCB --> G1["G1"]
    GCBGBCBMCB --> AVR_AVR
    GCBGBCBMCB --> GOV_GOV
    GCBGBCBMCB --> GEN_MONITORING1["GEN.Monitoring"]

    GCBGBCBMCB --> CAN_OPENCAN_OPEN1["CAN OPENCAN OPEN"]

    TransSyncroUnit1 --> GCBGBCBMCB["GCBGBCBMCB"]
    TransSyncroUnit1 --> GCBGBCBMCB

    GCBGBCBMCB --> G2["G2"]
    GCBGBCBMCB --> AVR_AVR
    GCBGBCBMCB --> GOV_GOV
    GCBGBCBMCB --> GEN_MONITORING2["GEN.Monitoring"]

    GCBGBCBMCB --> CAN_OPENCAN_OPEN2["CAN OPENCAN OPEN"]

    GCBGBCBMCB --> G32["G32"]
    GCBGBCBMCB --> AVR_AVR
    GCBGBCBMCB --> GOV_GOV

    TransSyncroUnit1 --> GCBGBCBMCB["GCBGBCBMCB"]
    TransSyncroUnit1 --> GCBGBCBMCB

    GCBGBCBMCB --> CAN_OPENCAN_OPEN2

    GCBGBCBMCB --> CAN_OPENCAN_OPEN2

    GCBGBCBMCB --> BUSMonitoring1["Bus Monitoring"]
    GCBGBCBMCB --> BUSMonitoring2["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring3["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring4["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring5["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring6["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring7["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring8["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring9["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring10["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring11["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring12["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring13["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring14["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring15["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring16["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring17["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring18["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring19["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring20["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring21["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring22["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring23["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring24["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring25["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring26["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring27["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring28["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring29["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring30["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring31["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring32["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring33["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring34["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring35["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring36["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring37["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring38["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring39["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring40["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring41["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring42["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring43["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring44["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring45["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring46["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring47["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring48["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring49["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring50["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring51["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring52["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring53["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring54["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring55["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring56["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring57["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring58["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring59["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring60["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring61["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring62["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring63["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring64["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring65["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring66["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring67["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring68["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring69["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring70["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring71["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring72["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring73["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring74["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring75["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring76["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring77["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring78["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring79["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring80["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring81["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring82["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring83["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring84["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring85["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring86["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring87["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring88["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring89["Bus Monitoring"]

    GCBGBCBMCB --> BUSMonitoring90["Bus Monitoring"]

    GCBGBC8CMB

CAN OPEN LINK (MULTILINK). 120 OHM SCREENED CABLE

3. Front Panel Description And Accessing To The Parameters

3.1 Front Panel Description

LCD display Description

480x272 pixels 4.3" colored TFT.

Use the buttons to select which Data display page (screen) is to be displayed. Next and Previous

When the Alarm (!) shortcut button is pressed, the Warning & Alarm display page is displayed.

When the Event log (LOG) shortcut button is pressed, the Event Log display page is displayed.

Data display pages on the LCD display;

Busbar Page1:

Busbar Page2:

Mains Page1:

Mains Page2:

Mains Page3:

V1: Bus voltage L1-N

V2: Bus voltage L2-N

V3: Bus voltage L3-N

V12: Bus voltage L1-L2

V23: Bus voltage L2-L3

V31: Bus voltage L3-L1

Hz: Bus frequency

Phase seq.: Bus phase sequence

V1: Bus voltage L1-N

V2: Bus voltage L2-N

V3: Bus voltage L3-N

V12: Bus voltage L1-L2

V23: Bus voltage L2-L3

V31: Bus voltage L3-L1

Hz: Bus frequency

V1: Mains voltage L1-N

V2: Mains voltage L2-N

V3: Mains voltage L3-N

V12: Mains voltage L1-L2

V23: Mains voltage L2-L3

V31: Mains voltage L3-L1

I1, I2, I3: Mains current L1, L2, L3

PF1, PF2, PF3: Mains power factor L1, L2, L3

Hz: Mains frequency

Phase seq.: Mains phase sequence

ROCOF: Rate of change of mains frequency

Vector Shift: Vector shift of mains frequency

P1, P2, P3: Mains active power L1, L2, L3

Pt: Mains total active power

Q1, Q2, Q3: Mains reactive power L1, L2, L3

Qt: Mains total reactive power

S1, S2, S3: Mains apparent power L1, L2, L3

St: Mains total apparent power

kWh: Mains active energy

KVArh: Mains reactive energy

Mains Page4:

Mains Page5:

Mains Page6:

Power Supply Page1:

Power Supply Page2:

V1: Mains voltage L1-N
V2: Mains voltage L2-N
V3: Mains voltage L3-N
V12: Mains voltage L1-L2
V23: Mains voltage L2-L3
V31: Mains voltage L3-L1
Hz: Mains frequency

I1, I2, I3: Mains current L1, L2, L3
P1, P2, P3: Mains active power L1, L2, L3
Pt: Mains total active power

Q1, Q2, Q3: Mains reactive power L1, L2, L3

Qt: Mains total reactive power

S1, S2, S3: Mains apparent power L1, L2, L3

St: Mains total apparent power

Battery voltage: Battery supply voltage

Vbat: Battery supply voltage

Input & Output Status Page:

Exp. Input & Output Status Page:

Synchroscope Page:

Load Page:

Inputs: Input status information. If an input is active, the related box is displayed as "green", otherwise "gray".

1: 2:conf. in-1, Conf. in-2, Conf. in-3,
4: 606f. in-4, Conf. in-5, Conf. in-6,
7: 8:Conf. in-7, Conf. in-8, Conf. in-9,
10: Cbn1.2n-10, Conf. in-11, Conf. in-12,
13: Conf. in-13

Outputs: Output status information. If an output is active, the related box is displayed as "green", otherwise "gray".

1: Conf. out-1, Conf. out-2, Conf. out-3,
4: 5:conf. out-4, Conf. out-5, Conf. out-6,
7: 8:conf. out-7, Conf. out-8, Conf. out-9,
10: MCB, GBCB

Inputs: Exp. input status information. If an input is active, the related box is displayed as "green", otherwise "gray".

1: Exp: conf. in-1, Exp. conf. in-2, Exp. conf. in-3,
4: 5×6: conf. in-4, Exp. conf. in-5, Exp. conf. in-6,
7: &xp. conf. in-7, Exp. conf. in-8.

Outputs: Exp. output status information. If an output is active, related box is displayed as "green", otherwise "gray".

1: Exp: conf. out-1, Exp. conf. out-2, Exp. conf. out-3,
4: 5×6: conf. out-4, Exp. conf. out-5, Exp. conf. out-6,
7: Exp. conf. out-7, Exp. conf. out-8.

Bus f: Bus frequency

Mains f: Mains frequency

Bus V: Bus voltage

Mains V: Mains voltage

°: The difference between bus phase and mains phaseΔ

I1: Load L1 current (if the load CT was fitted)

Load kW: Load total active power

Load kVAr: Load total reactive power

Load PF: Load average power factor

Mains kW: Mains total active power

Mains kVAr: Mains total reactive power

Mains PF: Mains average power factor

Busbar kW: Busbar total active power

Busbar kVAr: Busbar total reactive power

Busbar PF: Busbar average power factor

Sequencing Page1:

Sequencing Page2:

Canopen Link Page:

GPRS Page:

Ethernet Page1:

Device ID: Value of "09.04.001.Device number" parameter. Priority: Value of "09.09.005.Mains priority" parameter.

01: The genset-1 is connected to the "CAN OPEN" link, in auto mode and off load.

02: The genset-2 is connected to the "CAN OPEN" link, in manual mode and off load.

03: The genset-3 is not connected to the "CAN OPEN" link.

16: The genset-16 is not connected to the "CAN OPEN" link.

Device ID: Value of "09.04.001.Device number" parameter. Priority: Value of "09.09.005.Mains priority" parameter.

17: The genset-17 is not connected to the "CAN OPEN" link.

18: The genset-18 is not connected to the "CAN OPEN" link.

19: The genset-19 is not connected to the "CAN OPEN" link.

32: The genset-32 is not connected to the "CAN OPEN" link.

Number of genset on the link: Number of gensets on the "CAN OPEN" link.

Number of mains on the link: Number of mains on the "CAN OPEN" link.

Signal Quality: Signal Quality level indicator

Operator Name: Operator name

IP: Device IP value

APN: Access point name of the operator

LAT: Latitude value of device's position

LNG: Longitude value of device's position

IP address: Device IP address.

Subnet mask: Subnet mask.

Gateway address: Gateway IP address.

DNS address: DNS address.

MAC address: Device MAC address.

Device TCP port: Device TCP port number.

Cloud server: Cloud server name.

Cloud port: Cloud port number.

Ethernet Page2:

SNMP port: SNMP port number.

SNMP trap port: SNMP trap port number.

SNMP trap addr: SNMP trap server address.

SNMP community: SNMP community name.

Date & Time Page:

Date: Day, Month, Year.

Time: Hour, minute, second.

Warning & Alarm display pages on the LCD display;

Warning & Alarm Page:

1/2: The first message of current alarms.

Emergency stop!: This message indicates that an emergency stop alarm has occurred.

Event Log display pages on the LCD display;

Event Log Page:

Spare-1 error: This message indicates that a spare-1 alarm has occurred. (Event history: 13/01/2020 date, 10:55:06 time).

V1, V2, V3: Mains voltage L1-N, L2-N, L3-N

I1, I2, I3: Mains current L1, L2, L3

Hz: Mains frequency

kW: Mains total active power

kWh: Mains active energy

Events (from 1 to 500) can be displayed sequentially with the Next and Previous buttons.

Example-1: Displaying all pages.Data display

Example-2: Displaying all Warning&Alarm pagesdisplay

Example-3: Displaying all Event Log pagesdisplay

LCD display language selection

English Display

3.2 Changing And Saving Parameters Values

Operation Screen

graph TD
    A["MAINS"] --> B["When the Prog button is pressed, the parameters section is asked for accessing to parameters."]
    B --> C["Press the Up or Down buttons to select the section you wish to view/change."]
    C --> D["PROGRAM"]
    D --> E["Press the Enter button."]
    E --> F["TECHNICIAN SETTING"]
    F --> G["Enter password with cursor (Right, Left, Up and Down) buttons."]
    G --> H["TECHNICIAN SETTING"]
    H --> I["Press the Enter button to confirm password. If the password is incorrect, the unit will drop out of program mode."]
    I --> J["TECHNICIAN SETTING"]
    J --> K["Press the Up or Down buttons to select the main parameter group you wish to view/change."]
    K --> L["TECHNICIAN SETTING"]
    L --> M["Press Enter button to access to all parameters page in currently main parameter group."]
    M --> N["Press Enter button to access to all parameters in currently parameter page."]

graph TD
    A["02.01 MAINS VOLT LEVEL\n001.Under volt trip\n002.Under volt return\n003.Over volt trip\n004.Over volt return"] --> B["Press the Enter button to view parameter value."]
    C["02.01 MAINS VOLT LEVEL\n001.Under volt trip\n325 Vac"] --> D["Press Enter button to confirm the changed value."]
    E["02.01 MAINS VOLT LEVEL\n001.Under volt trip\n002.Under volt return\n003.Over volt trip\n004.Over volt return"] --> F["When the Escape button is pressed any time, previous page can be accessed."]
    G["02.MAINS\n01.Volt level\n02.Frequency level\n03.Actions"] --> H["Operation Screen\nMAINS\nV1: V 230 V12: V 400 Hz 50.0\nV2: V 230 V23: V 400 Hz 50.0\nV3: V 230 V31: V 400 Hz 50.0\nI1: A170.0 PF1: 1.00 Phase seq.: L1-2-3\nI2: A170.0 PF2: 1.00 L1-2-3\nI3: A170.0 PF3: 1.00 On load"]

4. Operation

Selection of the unit's operating mode is done via the mode buttons on the front panel or via the remote monitoring and control software.

4.1 Stop Mode

The Stop mode is activated by pressing the "Stop" button.

In this mode, the unit will remove the generator before circuit breaker (GBCB) the start request from the gensets.

Any latched alarms that have been cleared are reset when this mode is entered.

The gahsets be started by the unit when in this mode. If remote start signals are given or the mains supply fails, the start request is not sent to the getiste Auto mode is entered.

The (if a)res "GIB03.002MGBure at stop mode"

parameter is selected as "Disable") or wildbe arrangingterbegineds is OK or not (if the "02.03.002.Mains failure at stop mode" parameter is selected as "Enable"

4.2 Manual Mode

The Manual mode is activated by pressing the "Man" button.

This mode allows the user to start and stop the gensets manually, and change the state of the mains circuit breaker (MCB) and the generator bus .circuit breaker (GBCB)

4.2.1 Manual Start

When in manual mode, the gensets will not start automatically.

To begin the genset starting sequence;

• Press the "Start" button.
• The unit will issue a "Remote start" signal to the gensets over the "CAN OPEN" link.
• The gensets will stachronize and close to the Busbar.

- The "Best Butebager ready" will stand t over the "CAN OPEN" link he "Busbar Ready" Led on the unit will light on.

- Now, the load may be transferred manually by using the MCB and GBCB buttons. If the soft transfer mode is active; Press the GBCB. The load is ramped to the generator bus, the mains circuit breaker ( ) is MCB de-energized. Press the MCB button. The load is ramped to the mains, the generator bus circuit breaker (GBCB) is de-energized.

4.2.2 Manual Stop

To begin the genset stopping sequence;

• Press the "Stop" button.
• The unit will stop issue a "Remote start" signal to the gensets over the "CAN OPEN" link.
• The generator bus circuit breaker (GBCB) will de-energized.
• The all gensets will stop.

Note: The unit decides, whether the Busbar breaker (GBCB) is used or not, according to the configuration of the GBCB feedback input (Bus closed auxiliary input). If no feedback is configured, it is assumed that GBCB is not present in the system.

4.3 Auto Mode

The Auto mode is activated by pressing the "Auto" button.

This mode allows the gensets to be automatically started and stopped and run parallel to the mains without the need for user intervention.

4.3.1 Auto Start Sequence

If the unit is in auto mode and there is a starting request, the start sequence will begin.

The starting requests may be from the following sources;

• Mains supply out of limits.
• High mains load condition (when the "0-pa1003rd configuration code automatic peak lopping system like that "0-Import Power").
• When the "09a1600steroid configured dealways parallel operation like that "1-Export Power" or "2-Contant Power".
• Activation of an configurable input that has been configured to "0-Remote start on load" or "1-Remote start off load".
• Activation of an input that has been configured to "2-Auxiliary mains failure".
• Activation of the exercise scheduler.
• Activation of the informed mains interruption feature.

If a start request is still present at the end of the start delay timer;

• The unit will issue a “Remote start” signal to the gensets over the “CAN OPEN” link.
• The gensets will start, synchronize and close to the Busbar.
• The all started gensets will issue the "Busbar ready" signal over the "ANOPEN" link "Busbar Ready" Led on the unit will light on.
• Now, the load is transferred automatically. If required, the generator bus is first synchronised with the mains supply over the "CAN, CIREN" damping occurs when required.
• The unit controls the generator bus to provide the configured power (according to the contents of the "09and.003p±andents) control load 04Loaain control set supply.

4.3.2 Auto Stop Sequence

If there are no starting requests at the end of the return delay timer;

• The load is transferred back from the generator bus to the mains supply
• The unit will stop issue a "Remote start" signal to the gensets over the "CAN OPEN" link.
• The all gensets will stop

4.4 Test Mode

The Test mode is activated by pressing the "Test" button.

This mode allows for testing of the gensets off load. All alarm circuits will operate so that any faults will be reported. If a mains failure occurs while the unit is in this mode, the unit will revert to Auto mode and will transfer the load to the generator bus.

4.5 Multiple Mains

In a multiple mains system, the gensets are controlled by more than one unit and used to provide power to multiple loads.

• If one mains supply has failed, the gensets are started, synchronised and paralleled together. Then the generator bus is closed to feed the related load and the gensets share power equally on a percentage basis.
  The gensets are automatically started and stopped according to actual load levels allowing economic use of the available gensets.
• If more than one mains supply has failed, their related loads are transferred to the gensets in sequence according the priority order.
• If one mains supply returns, the unconnected to that mains supply will synchronise the gensets with the mains and perform a no-break transition. The gensets continue to supply power to the remaining loads.
• If more than one mains supply returns at the same time, the with the highest priority will take control of the gensets and perform mains supply. This is the units operate in priority order providing no-break returns back to their related mains supplies.

Note-1: In this system, the gensets are controlled by Trans-Syncro units.

Note-2: The gensets are not paralleled with any mains supply in a multiple mains system. Paralleling with mains supply is only done in a single mains system

graph TD
    A["Generator 1"] --> B["Load-1"]
    C["Generator 2"] --> D["Load-2"]
    E["Generator 3"] --> F["Load-32"]
    G["Generator 4"] --> H["Load-32"]
    I["Generator 5"] --> J["Load-32"]
    K["Generator 6"] --> L["Load-32"]
    M["Generator 7"] --> N["Load-32"]
    O["Generator 8"] --> P["Load-32"]
    Q["Generator 9"] --> R["Load-32"]
    S["Generator 10"] --> T["Load-32"]
    U["Generator 11"] --> V["Load-32"]
    W["Generator 12"] --> X["Load-32"]
    Y["Generator 13"] --> Z["Load-32"]
    AA["Generator 14"] --> AB["Load-32"]
    AC["Generator 15"] --> AD["Load-32"]
    AE["Generator 16"] --> AF["Load-32"]
    AG["Generator 17"] --> AH["Load-32"]
    AI["Generator 18"] --> AJ["Load-32"]
    AK["Generator 19"] --> AL["Load-32"]
    AM["Generator 20"] --> AN["Load-32"]
    AO["Generator 21"] --> AP["Load-32"]
    AQ["Generator 22"] --> AR["Load-32"]
    AS["Generator 23"] --> AT["Load-32"]
    AU["Generator 24"] --> AV["Load-32"]
    AW["Generator 25"] --> AX["Load-32"]
    AY["MAINS-1"] --> Z
    AZ["MAINS-2"] --> AA
    BB["MAINS-32"] --> AC
    BC["MAINS-1"] --> AD
    BD["MAINS-2"] --> AE
    BF["MAINS-32"] --> AG

5. Parameters

5.1 Operator Parameters

5.1.1 Mains

The unit uses the above parameters to decide whether the mains is okay or fail.

If the mains voltage is above the "Over volt trip" parameter or is below the "Under volt trip" parameter, the "Mains Okay Led" will light off.

If the mains voltage is below the "Over volt return" parameter and is above the "Under volt return" parameter, the "Mains Okay Led" will light on.

In Automatic mode, the unit uses these parameters to switch the load between the mains and gensets.

The unit uses the above parameters to decide whether the mains is okay or fail.

If the mains frequency is above the "Over freq trip" parameter or is below the "Under freq trip" parameter, the "Mains Okay Led" will light off.

If the mains frequency is below the "Over freq return" parameter and is above the "Under freq return" parameter, the "Mains Okay Led" will light on.

In Automatic mode, the unit uses these parameters to switch the load between the mains and gensets.

5.1.2 Generator

All Warnings Are Latched En/Dis (003.All warning are latch)

ENABLE: Warnings and pre-alarms will latched when triggered. To reset the alarm either an external reset must be applied to one of the inputs or the 'Reset' pushbutton operated, once the triggering condition has cleared.

DISABLE: Normal operation, the warnings and pre-alarms (except spare inputs, because they have their latching or non-latching selections) will automatically reset once the triggering condition has cleared.

5.2 Technician Parameters

5.2.1 System

Mains Current Transformer Ratio (001.Mains CT ratio)

Mains current transformer's transfer ratio (Primary current/Secondary current) value must be entered to this parameter.

Example:

If Current Transformer Primary=500A and Current Transformer Secondary=5A, Current Transformer Ratio should be entered CT Primary/CT Secondary=100.

Load Current Transformer Ratio (002.Load CT ratio)

Load current transformer's transfer ratio value must be entered to this parameter.

Note: The load CT is only required in a multiple mains system.

If the load CT fitted, the unit transfers the right amount of load to the mains before disconnecting the gensets. It prevents the gensets being "shock loaded".

Voltage Transformer Ratio (003.H ratio)

Defines the scaling factor applied to voltage readout and associated fault conditions.

This PT ratio is for additional voltage transformers mounted the unit.

Type of AC System (004. Type of AC System

This parameter is used to detail the type of AC system to which the unit is connected:

1 phase 2 wire, 3 phase 4 wire, 2 phase 3 wire L1-L2, 2 phase 3 wire L1-L3.

System Phase Sequence (005.Phase sequence

DISABLE: the mains and busbar phase sequence checking disabled.

L123 or L321: if the mains phase sequence is faulty, the "Mains phase sequence wrong" warning is given and the mains contactor is deenergized. if the busbar phase sequence is faulty, the "Busbar phase sequence wrong" warning is given.

Mains kW Rating (006.Mains kW rating)

This parameter specifies the mains active power rating, which is used as a reference value for related functions. This parameter is used for many functions including mains power and load share functions.

Mains kVAr Rating (007.Mains kVAr rating

This parameter specifies the mains reactive power rating, which is used as a reference value for related functions. This parameter is used for many functions including mains power and load share functions.

System Nominal Voltage (010.Nominal voltage)

This parameter specifies the nominal value of mains and busbar voltages. (Phase to phase)

System Nominal Frequency (011) Nominal frequency

This parameter specifies the nominal value of mains and busbar frequency.

Note: dis = disable

Hardware Breaker Selection (001.Type of Breaker)

0- Breakers: Mains and Busbar breakers breakers only close drives and if close drive off, will open.

Parameters; BUSBAR CLOSE BREAKER CONTACT TYPE, BUSBARTIMER(if busbar closed input selected), BUSBARTIMER(if Close Input selected), MAINS

BREAKER CONTACT TYPE, MAINS CLOSE TIMER(if mains closed input selected), MAINS OPEN TIMER(if mains closed input selected), TRANSFER TIME.

Example: If Hardware Breaker Selection parameter is selected as 0;

1- User Configured: Mains and Busbar breakers have only close drives, when want to breaker close, close breaker output on and after 1 sec. open breaker output on and after breaker close pulse time open breaker output will off. When want to breaker open, close breaker output and open breaker output will off.

Parameters; BUSBEBREAKER CONTACT TYPE, CLOSE TBUSTRAR busbar

closed input selected), OPENARVER (closed input selected), MAIN CLOSE

BREAKER CONTACT TYPE, MAINS CLOSE TIMER(if mains closed input selected), MAINS OPEN TIMER(if mains closed input selected), BREAKER CLOSE PULSE TIME, TRANSFER TIME.

Note-1 : NO / NC : Normally Open / Normally Close

3 : The unit decides, whether the Busbar breaker (GBCB) is used or not, according to the configuration of the GBCB feedback input (Bus closed auxiliary input). If no feedback is configured, it is assumed that GBCB is not present in the system. In such a system, the related Busbar breaker parameters ("01.02.002", "01.02.003", "01.02.004", "01.02.005" and "01.02.006") are not functional.

Example: If Hardware Breaker Selection parameter is selected as 1;

2- Motorised Breakers (Compact Type): User can select this option for the compact type breakers. Parameters; BUSBAR CLOSE BREAKER CONTACT TYPE, BUSBAR CLOSE BREAKER RELAY TYPE, BUSBAR CLOSE TIMER(if busbar closed input selected), BUSBAR OPEN BREAKER RELAY TYPE, BUSBAR OPEN TIMER(if busbar closed input selected), MAINS CLOSE BREAKER CONTACT TYPE, MAINS CLOSE BREAKER RELAY TYPE, MAINS CLOSE TIMER(if mains closed input selected), MAINS OPEN BREAKER RELAY TYPE, MAINS OPEN TIMER(if mains closed input selected), BREAKER CLOSE PULSE TIME(if Gen Close Breaker Relay Type or Main Close Breaker Relay Type parameter is selected as 1), BREAKER OPEN PULSE TIME(if Gen Open Breaker Relay Type or Main Open Breaker Relay Type parameter is selected as 1), TRANSFER TIME, SPRING LOADING TIME, RETRY NUMBER.

Example-1: MCB Close Diagram.

If Hardware Breaker Selection parameter is selected as 2 (motorised breakers (compact type)), MAINS CLOSE BREAKER RELAY TYPE parameter is selected as 1 (PULSE) and MAINS OPEN BREAKER RELAY TYPE parameter is selected as 1 (PULSE);

MbCt: Mains close timer

brCP: Breaker close pulse time

brOP: Breaker open pulse time

sPLD: Spring loading time

rtNB: Retry number

graph TD
    A["MCB close command"] --> B["sPLD"]
    B --> C["brCP"]
    C --> D["MrCt"]
    D --> E["MrCt"]
    E --> F["sPLD"]
    F --> G["brCP"]
    G --> H["MrCt"]
    H --> I["sPLD"]
    I --> J["brCP"]
    J --> K["MrCt"]
    K --> L["t[s"]]
    M["MCB open command"] --> N["brOP"]
    N --> O["MbCt"]
    O --> P["MrCt"]
    P --> Q["sPLD"]
    Q --> R["brCP"]
    R --> S["MrCt"]
    S --> T["sPLD"]
    T --> U["brCP"]
    U --> V["MrCt"]
    V --> W["t[s"]]
    X["Feedback input"] --> Y["brOP"]
    Y --> Z["MbCt"]
    Z --> AA["MrCt"]
    AA --> AB["sPLD"]
    AB --> AC["brCP"]
    AC --> AD["MrCt"]
    AD --> AE["sPLD"]
    AE --> AF["brCP"]
    AF --> AG["MrCt"]
    AG --> AH["t[s"]]
    AI["MCB fail to close alarm"] --> AJ["brOP"]
    AJ --> AK["MbCt"]
    AK --> AL["MrCt"]
    AL --> AM["sPLD"]
    AM --> AN["brCP"]
    AN --> AO["MrCt"]
    AO --> AP["sPLD"]
    AP --> AQ["brCP"]
    AQ --> AR["MrCt"]

Example-2: MCB Open Diagram.

If Hardware Breaker Selection parameter is selected as 2 (motorised breakers (compact type)), MAINS CLOSE BREAKER RELAY TYPE parameter is selected as 1 (PULSE) and MAINS OPEN BREAKER RELAY TYPE parameter is selected as 1 (PULSE);

MbOt: Mains open timer

brOP: Breaker open pulse time

3- Motorised Breakers (Open Type): User can select this option for the open type breakers. Parameters; BUSBAR CLOSE BREAKER CONTACT TYPE, BUSBAR CLOSE BREAKER RELAY TYPE, BUSBAR CLOSE TIMER(if busbar closed input selected), BUSBAR OPEN BREAKER RELAY TYPE, BUSBAR OPEN TIMER(if busbar closed input selected), MAINS CLOSE BREAKER CONTACT TYPE, MAINS CLOSE BREAKER RELAY TYPE, MAINS CLOSE TIMER(if mains closed input selected), MAINS OPEN BREAKER RELAY TYPE, MAINS OPEN TIMER(if mains closed input selected), BREAKER CLOSE PULSE TIME(if Gen Close Breaker Relay Type or Main Close Breaker Relay Type parameter is selected as 1), BREAKER OPEN PULSE TIME(if Gen Open Breaker Relay Type or Main Open Breaker Relay Type parameter is selected as 1), TRANSFER TIME, SPRING LOADING TIME, RETRY NUMBER.

Example-1: MCB Close Diagram.

If Hardware Breaker Selection parameter is selected as 3 (motorised breakers (open type)), MAINS CLOSE BREAKER RELAY TYPE parameter is selected as 1 (PULSE) and MAINS OPEN BREAKER RELAY TYPE parameter is selected as 1 (PULSE);

MbCt: Mains close timer

brCP: Breaker close pulse time

sPLD: Spring loading time

rtNB: Retry number

graph LR
    A["Feedback input"] --> B["MCB close command"]
    B --> C["MCB fail to close alarm"]
    C --> D["Time axis t[s"]]
    D --> E["rINB"]
    E --> F["Time axis t[s"]]
    F --> G["Time axis t[s"]]
    G --> H["Time axis t[s"]]
    H --> I["Time axis t[s"]]
    I --> J["Time axis t[s"]]
    J --> K["Time axis t[s"]]
    K --> L["Time axis t[s"]]
    L --> M["Time axis t[s"]]
    M --> N["Time axis t[s"]]
    N --> O["Time axis t[s"]]
    O --> P["Time axis t[s"]]
    P --> Q["Time axis t[s"]]
    Q --> R["Time axis t[s"]]
    R --> S["Time axis t[s"]]
    S --> T["Time axis t[s"]]
    T --> U["Time axis t[s"]]
    U --> V["Time axis t[s"]]
    V --> W["Time axis t[s"]]
    W --> X["Time axis t[s"]]
    X --> Y["Time axis t[s"]]
    Y --> Z["Time axis t[s"]]
    Z --> AA["Time axis t[s"]]
    AA --> AB["Time axis t[s"]]
    AB --> AC["Time axis t[s"]]
    AC --> AD["Time axis t[s"]]
    AD --> AE["Time axis t[s"]]
    AE --> AF["Time axis t[s"]]
    AF --> AG["Time axis t[s"]]
    AG --> AH["Time axis t[s"]]
    AH --> AI["Time axis t[s"]]
    AI --> AJ["Time axis t[s"]]
    AJ --> AK["Time axis t[s"]]
    AK --> AL["Time axis t[s"]]
    AL --> AM["Time axis t[s"]]
    AM --> AN["Time axis t[s"]]
    AN --> AO["Time axis t[s"]]
    AO --> AP["Time axis t[s"]]
    AP --> AQ["Time axis t[s"]]
    AQ --> AR["Time axis t[s"]]
    AR --> AS["Time axis t[s"]]
    AS --> AT["Time axis t[s"]]
    AT --> AU["Time axis t[s"]]
    AU --> AV["Time axis t[s"]]
    AV --> AW["Time axis t[s"]]
    AW --> AX["Time axis t[s"]]
    AX --> AY["Time axis t[s"]]
    AY --> AZ["Time axis t[s"]]
    AZ --> BA["Time axis t[s"]]
    BA --> BB["Time axis t[s"]]
    BB --> BC["Time axis t[s"]]
    BC --> BD["Time axis t[s"]]
    BD --> BE["Time axis t[s"]]
    BE --> BF["Time axis t[s"]]
    BF --> BG["Time axis t[s"]]
    BG --> BH["Time axis t[s"]]
    BH --> BI["Time axis t[s"]]
    BI --> BJ["Time axis t[s"]]
    BJ --> BK["Time axis t[s"]]
    BK --> BL["Time axis t[s"]]
    BL --> BM["Time axis t[s"]]
    BM --> BN["Time axis t[s"]]
    BN --> BO["Time axis t[s"]]
    BO --> BP["Time axis t[s"]]
    BP --> BQ["Time axis t[s"]]
    BQ --> BR["Time axis t[s"]]
    BR --> BS["Time axis t[s"]]
    BS --> BT["Time axis t[s"]]
    BT --> BU["Time axis t[s"]]
    BU --> BV["Time axis t[s"]]
    BV --> BW["Time axis t[s"]]
    BW --> BX["Time axis t[s"]]
    BX --> BY["Time axis t[s"]]
    BY --> BZ["Time axis t[s"]]
    BZ --> CA["Time axis t[s"]]
    CA --> CB["Time axis t[s"]]
    CB --> CC["Time axis t[s"]]
    CC --> CD["Time axis t[s"]]
    CD --> CE["Time axis t[s"]]
    CE --> CF["Time axis t[s"]]
    CF --> CG["Time axis t[s"]]
    CG --> CH["Time axis t[s"]]
    CH --> CI["Time axis t[s"]]
    CI --> CJ["Time axis t[s"]]
    CJ --> CK["Time axis t[s"]]
    CK --> CL["Time axis t[s"]]
    CL --> CM["Time axis t[s"]]
    CM --> CN["Time axis t[s"]]
    CN --> CO["Time axis t[s"]]
    CO --> CP["Time axis t[s"]]
    CP --> CPB["mbCt"]
    CPB --> CPn["mbCP"]
    CPn --> CPm["mbCP"]
    CPm --> CPnB["mbCP"]
    CPnB --> CPnA["mbCP"]
    CPnA --> CPnB["mbCP"]
    CPnB --> CPnC["mbCP"]
    CPnC --> CPnA["mbCP"]
    CPnA --> CPnB["mbCP"]
    CPnB --> CPnC["mbCP"]
    CPnC --> CPnA["mbCP"]
    CPnA --> CPnB["mbCP"]
    CPnB --> CPnC["mbCP"]
    CPnC --> CPnA["mbCP"]

Example-2: MCB Open Diagram.

If Hardware Breaker Selection parameter is selected as 3 (motorised breakers (open type)), MAINS CLOSE BREAKER RELAY TYPE parameter is selected as 1 (PULSE) and MAINS OPEN BREAKER RELAY TYPE parameter is selected as 1 (PULSE);

MbOt: Mains open timer

brOP: Breaker open pulse time

Busbar Close Breaker Contact Type (002.Busbar close breaker cont.type)

The polarity of the closing output can be set as "Normally Open" or "Normally Closed" with this parameter.

Busbar Close Breaker Relay Type (003.Busbar close breaker relay typ)

The signal of the closing output can be set as "Normal" or "Pulsed" with this parameter.

Bus Close Timer (004.Busbar close timer)

This is used to monitor the closure of the busbar contactor or breaker. It will only operate if an auxiliary input is configured as 'Busbar Closed Auxiliary' and connected to the auxiliary on the busbar contactor or breaker. Once a busbar closed signal is issued the 'busbar close timer' is initiated. Should the 'Busbar Closed Auxiliary' input become active the timer the 'busbar close timer' is cancelled. If the timer expires and the 'Busbar Closed Auxiliary' has not become active the unit will issue a 'busbar failed to close' alarm.

Busbar Open Breaker Relay Type (005.Busbar open breaker relay type)

The signal of the opening output can be set as "Normal" or "Pulsed" with this parameter.

Bus Open Timer (006.Busbar open timer)

This is used to monitor the opening of the busbar contactor or breaker. It will only operate if an auxiliary input is configured as 'Busbar Closed Auxiliary' and connected to the auxiliary on the busbar contactor or breaker. Once a busbar open signal is issued the 'busbar open timer' is initiated. Should the 'Busbar Closed Auxiliary' input become in-active the timer 'busbar open timer' is cancelled. If the timer expires and the 'Busbar Closed Auxiliary' has not become in-active the unit will issue a 'busbar failed to open' alarm.

Mains Close Breaker Contact Type (007.Mains close breaker cont.type)

The polarity of the closing output can be set as "Normally Open" or "Normally Closed" with this parameter.

Mains Close Breaker Relay Type (008.Mains close breaker relay type)

The signal of the closing output can be set as "Normal" or "Pulsed" with this parameter.

Mains Close Timer (009.Mains close timer)

This is used to monitor the closure of the mains contactor or breaker. It will only operate if an auxiliary input is configured as 'Mains Closed Auxiliary' and connected to the auxiliary on the mains contactor or breaker. Once a mains closed signal is issued the 'mains close timer' is initiated. Should the 'Mains Closed Auxiliary' input become active the timer the 'mains close timer' is cancelled. If the timer expires and the 'Mains Closed Auxiliary' has not become active the unit will issue a 'mains failed to close' alarm.

Mains Open Breaker Relay Type (010.Mains open breaker relay type)

The signal of the opening output can be set as "Normal" or "Pulsed" with this parameter.

Mains Open Timer (011.Mains open timer)

This is used to monitor the opening of the mains contactor or breaker. It will only operate if an auxiliary input is configured as 'Mains Closed Auxiliary' and connected to the auxiliary on the mains contactor or breaker. Once a mains open signal is issued the 'mains open timer' is initiated. Should the 'Mains Closed Auxiliary' input become in-active the timer the 'mains open timer' is cancelled. If the timer expires and the 'Mains closed auxiliary' has not become in-active the unit will issue a 'mains failed to open' alarm.

Breaker Close Pulse Time (012.Breaker close pulse time)

This is used to determine the duration of the Mains and Busbar close signals. This timer is only used if Pulsed outputs are configured to be used.

Breaker Open Pulse Time (013.Breaker open pulse time)

This is used to determine the duration of the Mains and Busbar close signals. This timer is only used if Pulsed outputs are configured to be used.

Transfer Time (014.Transfer time)

This is used to allow for fixed duration transfer breaks when switching from mains to busbar and back. It can be used to ensure that the supply is removed from the load for fixed period of time to allow pumps/motors to come to rest etc.

Spring Loading Time (015.Spring loading time)

When the unit give open command to the (BCB or MCB) breaker and after that the unit want to give close command the same breaker, this time for between open and close commands, because if there is no delay between open and close commands can be problem the motorized switches.

Retry Number (016.Retry number)

The unit try to close (BCB or MCB) breaker number of this parameter. If each try there is no close feedback, after last try the alarm will be activated.

Language Selection (Language)

Language selection: English or Turkish.

Auto (202A) time croll time

The scroll time between all data display pages.

Auto (2021) Monsber croll number

The number of data display pages that will be scrolled.

Scroll Time For Error Messages (004mesg croll time)

Error messages are displayed the last line of LCD Display. If more than one error condition is present, each of them is displayed during time defined by Auto Scroll Timer parameter.

Theme Selection (005.Theme selection)

The background color of the LCD screen can be selected as black or gray with this parameter.

Slave Address (001.Slave address)

This parameter is used for the ModBus Slave ID.

Baud Rate (002.Baud rate)

This parameter is used for the ModBus communication speed. Baud rate adjustable from 1200-38400.

Timeout (005.Timeout)

This parameter is used for the modem hardware reset. If the data communication is interrupted and this situation continues as this parameter, the modem hardware reset is performed.

Slave Address (001.Slave address)

This parameter is used for the ModBus Slave ID.

Baud Rate (002.Baud rate)

This parameter is used for the ModBus communication speed. Baud rate adjustable from 1200-38400.

ModBus ASCII/RTU Selection (005.ASCII/RTU selection)

This parameter is used for the ModBus communication protocol.

Data logging:

The unit will log data in either an internal memory (limited to 500 records) or an external USB host according to the selection of Data log memory parameter.

The logging period is adjustable between 0.1 and 999.9 minutes via the Data log period parameter.

The log directory structure is in an external USB host;

graph TD
    A["Datalog"] --> B["SN 12345678_2016"]
    B --> C["20161231.csv"]
    B --> D["20161230.csv"]
    B --> E["20160101.csv"]
    B --> F["20151231.csv"]
    B --> G["20151230.csv"]
    B --> H["20150101.csv"]
    C --> I["End"]

The below registers are logged;

Bus V1, Bus and Bus Frequency,

Mains ,Mains 2,Mains 3and Mains frequency,

Mains I1, Mains I2, Mains I3,

Mains kWh,

Battery voltage

Day of week (004.Week)

1=Monday, 2=Tuesday, 3=Wednesday, 4=Thursday, 5=Friday, 6=Saturday, 7=Sunday.

Save setting to default (001.Save setting to def.)

If this parameter is selected as "Yes", the unit's currently parameters save as default sets. After this parameter is reset automatically to "No".

Reset default sets (002.Reset default sets)

If this parameter is selected as "Yes", the unit's parameters back to default sets. After this parameter is reset automatically to "No".

Reset factory sets (003.Reset factory sets)

If this parameter is selected as "Yes", the unit's parameters back to factory sets. After this parameter is reset automatically to "No".

Operator Password (001. Operator password)

Use this option to change the Operator password. This password allows access to operator parameters section.

Technician Password (002.Technician password)

Use this option to change the Technician password. It allows access to both operator and technician parameters section.

Tcp Client Mode (001.Tcp client mode)

DISABLE: Cli er disabbe s d.

ENABLE: Cli eabode s en d. The unit will be send a connection request to the server (PC or Cloud) using the built-in ethernet port.

ModBus Protocol Selection (002.ModBus protocol

This parameter is used to select the ModBus protocol of the internet port. This parameter can be selected as "ASCII", "RTU" or "TCP". Note: The "ASCII" option means the "ModBus ASCII Over TCP/IP" protocol. ModBus TCP/IP over the protocol. The "TCP" option means the "ModBus TCP/IP" protocol.

These 4 parameters define the IP address of the bthe.net port . Note: The IP address consists of 4 parts. The first part of the IP address, that is, the leftmost part, should be entered in the "003.IP address byte1" parameter. The last part of the IP address, that is, the rightmost part, should be entered in the "006.IP address byte4" parameter.

These 4 parameters define the Subnet mask of the ethibrinet port . Note: The Subnet mask consists of 4 parts. The first part of the Subnet mask, that is, the leftmost part, should be entered in the "007.Syberet mask " parameter. The last part of the Subnet mask, that is, the rightmost part, should be entered in the "010.Syberet mask " parameter.

These 4 parameters define the Gateway address of the bthlerinet port . Note: The Gateway address consists of 4 parts. The first part of the Gateway address, that is, the leftmost part, should be entered in the "011.Galiteway byte1" parameter. The last part of the Gateway address, that is, the rightmost part, should be entered in the "014.Galiteway byte4" parameter.

These 4 parameters define the DNS address of the DNID-based reset

Note:

consists of 4 parts. The first part of the DNS address, that is, the leftmost part, should be entered in the

"015aDNS press by test part of the DNS address, that is, the rightmost part,

should be entered in the "018aDNS stress byte4

Device TCP Port (019.Device TCP port)

This parameter determines the server port number of the built-in port

answer ModBus queries coming to this port.

SNMP Enable Selection (020.\$NMP enable

DISABLE: SNMP communication is disable

ENABLE: SNMP communication is enabled. The unit will be offer SNMP communication using the built-in ethernet port. Note: The unit supports "V1.0" and "V1.1" versions of the SNMP.

By using the SNMP "Get" command, all measurement values (voltage, current, power, etc.), input-output status information, button information, led information, alarm bits and some special program parameters can be read.

By using the SNMP "Set" command, the operating mode of the unit can be changed and operations such as starting-stopping-loading the generator can be performed.

SNMP Port (021.\$NMP port

This parameter determines the SNMP port number of the built-wile oprt

answer SNMP queries coming to this port. Note: Changing this parameter becomes only effective after restarting the unit.

SNMP Trap Port (022.SNMP trap port

This parameter determines the SNMP trap port number of the entire port

condition occurs, the unit will send a trap message to the trap server address using this port number.

condition occurs, the unit will send a trap message to this trap server address using the trap port number. Note: The SNMP trap server address consists of 4 parts. The first part of the SNMP trap server address, that is, the leftmost part, should be entered in the "023.SNMP trap server address byte1" parameter. The last part of the SNMP trap server address, that is, the rightmost part, should be entered in the "026.SNMP trap server address byte4"

5.2.2 Mains

The unit uses the above parameters to decide whether the mains is okay or fail.

If the mains voltage is above the "Over volt trip" parameter or is below the "Under volt trip" parameter, the "Mains Okay Led" will light off.

If the mains voltage is below the "Over volt return" parameter and is above the "Under volt return" parameter, the "Mains Okay Led" will light on.

In Automatic mode, the unit uses these parameters to switch the load between the mains and gensets.

The unit uses the above parameters to decide whether the mains is okay or fail.

If the mains frequency is above the "Over freq trip" parameter or is below the "Under freq trip" parameter, the "Mains Okay Led" will light off.

If the mains frequency is below the "Over freq return" parameter and is above the "Under freq return" parameter, the "Mains Okay Led" will light on.

In Automatic mode, the unit uses these parameters to switch the load between the mains and gensets.

Mains Failure Detection En/Dis (001.Mains failure detection)

ENABLE: The unit will monitor the mains supply. If the mains supply go out side of limits, the unit will initiate its automatic mains failure sequence. (If no inputs is selected as a remote start)

DISABLE: The unit will not monitor the mains supply.

Look Mains Failure at Stop Mode En/Dis (002.Mains failure at stop mode)

ENABLE: As soon as the unit detects a mains failure the mains circuit breaker (MCB) will be opened to remove the supply from the load. This is to prevent damage to the load in case of single-phase failure.

DISABLE: In the event of a mains failure the unit will attempt to maintain the supply to the load for the incoming AC mains supply until the busbar is available to go on load. In the event of a busbar failure the unit will default back to the incoming AC mains supply.

Always Look Mains Return Delay (003.Always return delay)

ENABLE: The unit will always wait the Mains Return Delay parameter before transferring the load back to mains.

DISABLE: The unit will wait the Mains Return Delay parameter while only the busbar is available to go on load before transferring the load back to mains.

5.2.3 Generator

Calendar Disable or Enable (001.Disable/enable select)

DISABLE: The unit will not monitor the working calendar parameters. If the mains supply go out side of limits, the unit will initiate automatic mains failure sequence.

ENABLE: The unit will monitor the working calendar parameters. If the mains supply go out side of limits, the unit will initiate automatic mains failure sequence only within the set "Start and Stop time parameters".

Note-1: If the "Start time parameter" of any day is set to "0.00" and the "Stop time parameter" is set to "23.59", the unit will initiate automatic mains failure sequence when the mains supply go out side of limits within that day.

Note-2: If the “Start and Stop time parameters” of any day are set the same, the unit will not initiate automatic mains failure sequence when the mains supply go out side of limits within that day.

All Warnings Are Latched En/Dis (003.All warning are latch)

ENABLE: Warnings and pre-alarms will latched when triggered. To reset the alarm either an external reset must be applied to one of the inputs or the 'Reset' pushbutton operated, once the triggering condition has cleared.

DISABLE: Normal operation, the warnings and pre-alarms (except spare inputs, because they have their latching or non-latching selections) will automatically reset once the triggering condition has cleared.

5.2.4 Engine

Under Volt Warning Set (001.Under volt)

If the battery voltage falls below the value in this parameter and this situation continues for the time defined in the parameter "003.Under volt delay", the device turns on the yellow "Warning" led and displays the "Battery low warning!" warning message on the screen.

Under Volt Warning Reset (002.Under volt reset)

If the battery voltage exceeds the value in this parameter, the device turns off the yellow "Warning" led and removes the "Battery low warning!" warning message on the display.

Under Volt Warning Delay (003.Under volt delay)

If the battery voltage falls below the value in the parameter "001.Alt sýnýr" during the time defined in this parameter, the device turns on the yellow "Warning" led and displays the "Battery low warning!" warning message on the screen.

Over Volt Warning Set (004. Over volt)

If the battery voltage rises above the value in this parameter and this situation continues for the time defined in the parameter "006.Over volt delay", the device turns on the yellow "Warning" led and displays the "Battery high warning!" warning message on the screen.

Over Volt Warning Reset (005. Over volt reset)

If the battery voltage falls below the value in this parameter, the device turns off the yellow "Warning" led and removes the "Battery high warning!" warning message on the display.

Over Volt Warning Delay (006. Over volt delay)

If the battery voltage rises above the value in the parameter "004.Over volt" during the time defined in this parameter, the device turns on the yellow "Warning" led and displays the "Battery high warning!" warning message on the screen.

The unit communicates with the expansion IO modula via the CanBus peripheral.

The user can adjust the above parameters to see if there is a problem with this communication.

CAN Fault Actions (001.CAN fault actions)

This parameter must be activated in order for the device to detect CanBus communication error. Whether the generator will be stopped or not in case of communication failure can be set in this parameter.

Note: dis = disable

CAN Fault Activation (002.CAN fault activation)

CanBus communication error monitoring start can be set with this parameter.

CAN Fault Delay (003.CAN fault delay)

CanBus communication error delay can be set with this parameter.

Test Mode Selection (001.Disable/enable select)

DISABLE: Test mode disable.

ENABLE: Test mode enable.

Exercise Disable or Enable (001.Disable/enable select)

DISABLE: The exercise function is disabled. The unit will not monitor the exercise parameters.

ENABLE: The unit will monitor the exercise parameters.

When the start time of any day is reached, the unit will start the generator.

When the stop time of the same day is reached, the unit will stop the generator.

Note-1: If the “Start and Stop time parameters” of any day are set the same, the exercise function for that day will be passive.

Note-2: If the "Start time parameter" of any day is set larger than the "Stop time parameter", the exercise function for that day will be passive.

5.2.5 Inputs

Note-1 : x = 1(input-1), 2( )input, 4(input-5)(input-6)put input-4(input ), 8(i5put ), -6 -7 -8 9(input-9, 10(input ), 101(input ), 112(input ) or-12(input ) -13 .

Note-2: dis = disable

Note-1 : x = 1(exp. input-1), 2(exp. input-2), 3(exp. input-3), 4(exp. input-4), 5(exp. Input-5), 6(exp. input-6), 7(exp. Input-7) or 8(exp. Input-8).

Note-2: dis = disable

CONFIGURABLE INPUTS SELECTIONS

0 REMOTE START ON LOAD

In AUTO mode, if one of the configurable inputs are selected as 0 (Remote Start On Load), the unit doesn't perform the mains failure control in order to start the gens. Auto mode, if one of the configurable inputs are selected as 0 (Remote Start Cnolds) input is active, then the unit will perform the start sequence and transfer load to the gensets. If the input is passive, the unit will perform the stop sequence.

1 RESERVED

2 AUXILIARY MAINS FAIL

The unit will monitor the incoming single or three phase supply for Over Voltage, Under Voltage, Over Frequency or Under Frequency. It may be required to monitor a different mains supply or some aspect of the incoming mains not monitored by the unit. If the devices providing this additional monitoring are connected to operate this input, the unit will operate as if the incoming mains supply has fallen outside of limits, the gensets will be instructed to start and take load. Removal of the input signal will cause the unit to act if the mains has returned to within limits.

3 BUS BREAKER OPEN/CLOSE

If this input is activated in manual mode, the load will be supply from the gensets.

If this input is passive in manual mode, the load will be disconnected from the gensets.

4 SIMULATE HORN RESET BUTTON

This input mimic's the operation of the 'Horn Reset' button and is used to provide a remotely located Horn Reset push button.

5 SIMULATE ALARM RESET BUTTON

This input mimic's the operation of the 'Alarm Reset' button and is used to provide a remotely located Alarm Reset push button.

6 SIMULATE AUTO BUTTON

This input mimic's the operation of the 'Auto' button and is used to provide a remotely located Auto mode push button.

7 SIMULATE TEST BUTTON

This input mimic's the operation of the 'Test' button and is used to provide a remotely located Test mode push button.

8 SIMULATE MANUAL BUTTON

This input mimic's the operation of the 'Manual' button and is used to provide a remotely located Manual mode push button.

9 SIMULATE START BUTTON

This input mimic's the operation of the 'Start' button and is used to provide a remotely located start push button.

10 SIMULATE STOP BUTTON

This input mimic's the operation of the 'Stop' button and is used to provide a remotely located Stop push button.

11 BUS CLOSED AUXILIARY

This input is used to provide feedback to allow the unit to give true indication of the contactor or circuit breaker switching status. It should be connected to the lead-switching device auxiliary contact.

Note: The unit decides, whether the Busbar breaker (GBCB) is used or not, according to the configuration of the GBCB feedback input (Bus closed auxiliary input). If no feedback is configured, it is assumed that GBCB is not present in the system.

12 BUS LOAD INHIBIT

This input is used to prevent the unit from loading the generator bus. If the bus is already on load, activating this input will cause the unit to unload the generator bus. Removing the input will allow the bus to be loaded again.

Note: This input only operates to control the generator bus switching device if the unit load switching logic is attempting load the gensets. It will not control the generator-switching device when the mains is on load.

13 MAINS CLOSED AUXILIARY

This input is used to provide feedback to allow the unit to give true indication of the contactor or circuit breaker switching status. It should be connected to the generator load switching device auxiliary contact.

14 MAINS LOAD INHIBIT

This input is used to prevent the unit from loading the mains supply. If the manis supply is already on load, activating this input will cause the unit to unload the mains supply. Removing the input will allow the mains to be loaded again.

15 AUTO RESTORE INHIBIT

When module in the AUTO mode. In the event of a remote start or mains failure, the gensets will be instructed to start and take load. On removal of the remote start signal or mains return, the unit will continue to run the gensets on load until this AUTO RESTORE INHIBIT input is removed. Once the input is removed the unit will transfer the load back to the mains supply and follow a normal gensets stop sequence. This input allows the unit to be fitted as part of a system where the manual restoration to mains is controlled remotely or by an automated system.

16 AUTO START INHIBIT

This input is used to provide an over-ride function to prevent the unit from starting the gensets in the event of a remote start or mains out of limits condition occurring. If this input is active and a remote start signal or mains failure occurs the unit will not give a start command to the gensets. If this input signal is then removed, the unit will operate as if a remote start or mains failure has occurred, starting and loading the gensets. This function can be used to give an 'AND' function so that a genset will only be called to start if the mains fails and another condition exists which requires the genset to run. If the 'Auto Start Inhibit' signal become active once more it will be ignored until the unit has returned the mains supply on load and shutdown.

17 PANEL LOCK

This input is used to provide security to the installation. If the panel lock input is active, the unit will not respond to operation of the mode select or start buttons. This allows the unit to be placed into a spesific mode (such as Auto) and than secured. The operation of the unit is not affected and the operator will still be able to view the various instrumentation pages etc.

18 SCHEDULED RUNS(EXERCISE) INHIBITED

This input is used to prevent the gensets for starting in the event of a programmed scheduled (exercise) run occurring. While the input is active no scheduled runs will occur. If the input is active when a schedule run is called for, and is removed during the running period the genset will start and complete any remaining scheduled running time.

19 TOP PRIORITY

When this input is active, the unit gets the highest priority independently on the Priority parameter.

20 FORCE BREAK TRANSFER

This input is used to enable break transfer. When this input is activated, the load is transferred after a short interruption according to the content of "01p2a1m1etransfer time

21 FORCE NO-BREAK TRANSFER

This input is used to enable no-break transfer. When this input is activated, the load is transferred uninterruptedly. The load is supplied from both the mains and the gensets until the time in "09.10.002.No break transition time" parameter expires.

22 FORCE SOFT TRANSFER

This input is used to enable soft transfer. When this input is activated, the load is transferred with ramp.

This input is used to enable parallel operation. When this input is activated, the load is shared between the mains and the gensets according to the content of "0pacoosteroad control mode

24 MAINS BREAKER OPEN/CLOSE

If this input is activated in manual mode, the load will be supply from the mains. If this input is passive in manual mode, the load will be disconnected from the mains.

25 EMERGENCY STOP (FOR CONFIGURABLE INPUT-1)

This input is used as the emergency stop input.

26 EMERGENCY STOP NO-LATCHING (FOR CONFIGURABLE INPUT-1)

This input is used as the non-latching emergency stop input.

5.2.6 Outputs

CONFIGURABLE OUTPUTS SELECTIONS:

0 NOT USED

Output is not used

1 RESERVED

2 ALARM RESET

The output indicates that an alarm reset being performed. Once the alarm reset has been completed, the output become inactive again. The output could be used to give an external reset signal to external systems.

3 AUDIBLE ALARM

The output indicates that the internal sounder is operating. It may be use for external sounder.

4 AUTO START INHIBIT

This output indicates that a digital input that has been configured as 'auto start inhibit' is active.

5 AUXILIARY MAINS FAILURE

This output indicates that a digital input that has been configured as 'auxiliary mains failure' is active.

6 BATTERY HIGH VOLTAGE

This output indicates that a battery high voltage alarm has occurred.

7 BATTERY LOW VOLTAGE

This output indicates that a battery low voltage alarm has occurred.

8 CALLING FOR SCHEDULED RUN(EXERCISE)

This output indicates that a scheduled run(exercise) has been called for. If the unit is in the 'auto' and mains okay, the unit will change mode to 'test' and the generator will run if no shutdown alarms are present.

9 RESERVED

10 RESERVED

11 RESERVED

12 COMMON ALARM

This output indicates that a warning, electrical trip or shutdown alarm has been activated.

13 COMMON ELECTRICAL TRIP ALARM

This output indicates that an electrical trip alarm has been activated. This output can only be reset by removal of the fault and by then pressing the RESET button.

14 COMMON SHUTDOWN ALARM

This output indicates that a shutdown alarm has been activated. This output can only be reset by removal of the fault and by then pressing the RESET button or by using an external 'alarm reset' input.

15 COMMON WARNING ALARM

This output indicates that a warning alarm has been activated. This output is normally self-resetting on removal of the fault.

16 RESERVED

17 RESERVED

18 RESERVED

19 RESERVED

20 RESERVED

21 RESERVED

22 DELAYED ALARMS ACTIVE

The output indicates that the delayed alarms now enabled. Can be used to control external logic circuitry.

23 DIGITAL INPUT-1 ALARM

This output indicates that digital input 1 alarm has occurred.

24 DIGITAL INPUT-2 ALARM

This output indicates that digital input 2 alarm has occurred.

25 DIGITAL INPUT-3 ALARM

This output indicates that digital input 3 alarm has occurred.

26 DIGITAL INPUT-4 ALARM

This output indicates that digital input 4 alarm has occurred.

27 DIGITAL INPUT-5 ALARM

This output indicates that digital input 5 alarm has occurred.

28 DIGITAL INPUT-6 ALARM

This output indicates that digital input 6 alarm has occurred.

29 DIGITAL INPUT-7 ALARM

This output indicates that digital input 7 alarm has occurred.

30 DIGITAL INPUT-8 ALARM

This output indicates that digital input 8 alarm has occurred.

31 DIGITAL INPUT-9 ALARM

This output indicates that digital input 9 alarm has occurred.

32 DIGITAL INPUT-10 ALARM

This output indicates that digital input 10 alarm has occurred.

33 DIGITAL INPUT-11 ALARM

This output indicates that digital input 11 alarm has occurred.

34 DIGITAL INPUT-12 ALARM

This output indicates that digital input 12 alarm has occurred.

35 DIGITAL INPUT-13 ALARM

This output indicates that digital input 13 alarm has occurred.

36 EXPANSION CONFIGURABLE INPUT-1 ALARM

This output indicates that expansion configurable input 1 alarm has occurred.

37 EXPANSION CONFIGURABLE INPUT-2 ALARM

This output indicates that expansion configurable input 2 alarm has occurred.

38 EXPANSION CONFIGURABLE INPUT-3 ALARM

This output indicates that expansion configurable input 3 alarm has occurred.

39 EXPANSION CONFIGURABLE INPUT-4 ALARM

This output indicates that expansion configurable input 4 alarm has occurred.

40 EXPANSION CONFIGURABLE INPUT-5 ALARM

This output indicates that expansion configurable input 5 alarm has occurred.

41 EXPANSION CONFIGURABLE INPUT-6 ALARM

This output indicates that expansion configurable input 6 alarm has occurred.

42 EXPANSION CONFIGURABLE INPUT-7 ALARM

This output indicates that expansion configurable input 7 alarm has occurred.

43 EXPANSION CONFIGURABLE INPUT-8 ALARM

This output indicates that expansion configurable input 8 alarm has occurred.

44 RESERVED

45 EMERGENCY STOP

This output indicates that an emergency stop alarm has occurred.

46 RESERVED

47 RESERVED

48 RESERVED

49 RESERVED

50 RESERVED

51 GENERATOR AT REST

The output indicates that the generator is not running.

52 GENERATOR AVAILABLE

This output indicates when the generator is ready to accept load, i.e. after safety on and warm up timers have timed out.

53 BUS CLOSED AUXILIARY

This output indicates that a digital input that has been configured as 'bus closed auxiliary' is active.

54 BUS FAILED TO CLOSE

This output source has intended to be used to indicate a failure of the generator bus circuit breaker (GBCB) can only be used if the unit is configured to use 'bus closed auxiliary' feedback.

55 BUS FAILED TO OPEN

This output source has intended to be used to indicate a failure of the generator bus circuit breaker (GBCB) can only be used if the unit is configured to use 'bus closed auxiliary' feedback.

56 RESERVED

57 RESERVED

58 RESERVED

59 RESERVED

60 BUS LOAD INHIBIT

This output indicates that a digital input has been configured as 'bus load inhibit' is active.

61 RESERVED

62 RESERVED

63 RESERVED

64 RESERVED

65 GENERATOR STOPPING

This output indicates that the engine has been instructed to stop but has not come to rest.

66 BUS OPEN BREAKER

This output used to control the generator bus cFouDetailkere(GBR)AKERS Page" section.

67 HORN OUTPUT LATCHED

This output indicates that the latched horn alarm has occurred.

68 HORN OUTPUT PULSED

This output indicates that the pulsed horn alarm has occurred.

69 LAMP TEST

This output indicates that the module is performing a lamp test. Once the lamp test completed, the output will become inactive again. The output can be used to feed a lamp test on external modules or panel lamps.

70 RESERVED

71 RESERVED

72 RESERVED

73 RESERVED

74 MAINS CLOSED AUXILIARY

This output indicates that a digital input that has been configured as 'mains closed auxiliary' is active.

75 MAINS FAILED TO CLOSE

This output source has intended to be used to indicate a failure of the mains contactor or breaker. It can only be used if the unit is configured to use 'mains closed auxiliary' feedback.

76 MAINS FAILED TO OPEN

This output source has intended to be used to indicate a failure of the mains contactor or breaker. It can only be used if the unit is configured to use 'mains closed auxiliary' feedback.

77 MAINS FAILURE

This output indicates that the unit has sensed that a failure of the incoming AC mains supply. This output will become active whenever the mains voltage or frequency goes out of limits, or if the auxiliary mains failure input active (if used) and the mains transient timer has expired.

78 MAINS HIGH FREQUENCY

This output indicates that the unit has sensed that the incoming AC mains supply frequency has exceeded the frequency limit setting.

79 MAINS HIGH VOLTAGE

This output indicates that the unit has sensed that the incoming AC mains supply voltage has exceeded the voltage limit setting.

80 MAINS LOAD INHIBIT

This output indicates that a digital input has been configured as 'mains load inhibit' is active.

81 MAINS LOW FREQUENCY

This output indicates that the unit has sensed that the incoming AC mains supply frequency has fallen below the frequency setting.

82 MAINS LOW VOLTAGE

This output indicates that the unit has sensed that the incoming AC mains supply voltage has fallen below the voltage limit setting.

83 MAINS OPEN BREAKER

This output used to control the load switching device. For Details see: "BREAKERS Page" section.

84 NO LOADING COMMAND

This output indicates that the unit is not calling of the generator contactor or breaker to be closed. Should the unit close the generator contactor this output will become inactive.

85 RESERVED
86 RESERVED
87 RESERVED
88 RESERVED
89 RESERVED
90 RESERVED
91 RESERVED
92 RESERVED
93 RESERVED
94 RESERVED

95 PANEL LOCK

This output indicates that the unit 'panel lock' is active. If the panel lock input is active, the unit will not respond to operation of the Mode select or start buttons. This allows the unit to be placed into a specific mode (such as auto) and then secured.

96 RESERVED
97 RESERVED
98 RESERVED
99 RESERVED

100 REMOTE START PRESENT

This output indicates that a digital input that has been configured as 'remote start' is active. This output could be used to pass the remote start signal on to else where in the control system.

101 RESERVED
102 RESERVED
103 RESERVED
104 RESERVED

105 STARTING ALARMS ARMED

The output indicates that the starting alarms are now enabled. It can be used to control external logic circuitry. Starting alarms are armed as soon as the unit commences starting of the engine and remain armed until the engine at rest.

106 RESERVED

107 SYSTEM IN AUTO MODE

The output indicates that the unit is in the Auto mode.

108 SYSTEM IN MANUAL MODE

The output indicates that the unit is in the Manual mode.

109 SYSTEM IN STOP MODE

The output indicates that the unit is in the Stop mode.

110 SYSTEM IN TEST MODE

The output indicates that the unit is in the Test mode.

111 RESERVED

112 RESERVED

113 RESERVED

114 RESERVED

115 RESERVED

116 RESERVED

117 WAITING FOR GENERATOR

This output indicates that the engine has been instructed to start but has not yet become available. Once the generator becomes available this output will be in-active.

118 RESERVED

119 LOAD SUPPLY FROM BUS

This output indicates that the load is supplying from generator bus.

120 LOAD SUPPLY FROM MAINS

This output indicates that the load is supplying from mains.

121 RESERVED

122 RESERVED

123 RESERVED

124 RESERVED

125 RESERVED

126 RESERVED

127 RESERVED

128 REMOTE CONTROL ACTIVE

This output indicates that the engine is being controlled remotely.

129 RESERVED

130 RESERVED

131 RESERVED

132 RESERVED

133 RESERVED

134 RESERVED

135 REMOTE OUTPUT

This output indicates that the output can be energised or de-energised remotely.

136 RESERVED

137 RESERVED

138 BUS NOT ALIVE

Active when the busbar ready signal is received from the Trans-Syncro units and the bus is not seen to go live.

139 SYNCHRONIZATION FAIL

Becomes active if the module fails to synchronise after the “Maximum synchronization time”.

140 RESERVED

141 RESERVED

142 RESERVED

143 RESERVED

144 RESERVED

145 RESERVED

146 RESERVED

147 MAINS ROCOF ALARM

This output indicates that the R.O.C.O.F. (Rate Of Change Of Frequency) protection has triggered during parallel operation with the mains.

148 MAINS VECTOR SHIFT ALARM

This output indicates that the Vector Shift protection has triggered during parallel operation with the mains.

149 MAINS UNDER VOLTAGE COIL

This output is used to control the load switching device. This output will be active whenever the mains is required to be on load. When want to the mains to be off load, this output will be passive.

150 BUS UNDER VOLTAGE COIL

This output is used to control the load switching device. This output will be active whenever the generator bus is required to be on load. When want to the generator bus to be off load, this output will be passive.

5.2.7 Timers

Mains Transient Delay (001.Mains transient delay)

The unit uses this parameter to decide the mains failure.

Mains Fail Start Delay (002.Mains fail start delay)

This timer dictates how long the unit will wait after it has received a mains failure signal before it will attempt to genset start. This prevent un-necessary starting on a fluctuating mains supply etc.

Remote Start Delay (003.Remote start delay)

This timer dictates how long the willwait after it has received a remote start signal before it will attempt to gate this prevent un-necessary starting on a fluctuating mains supply etc.

Horn Duration (008.Horn duration)

This timer dictates how long the external field the last internal sounder detected. Once after this timer ended will do the external horn and the internal sounder reset.

Mains Return Delay (001.Mains return delay)

This timer dictates how long the unit will wait before it will un-load the generator bus (back to the mains supply) and initialise it's stop cycle. This is ensure that the mains supply has stabilised before transferring the load back to mains.

Remote Stop Delay (002.Remote stop delay)

This timer dictates how long the unit will wait after it has received a remote stop signal before it will attempt to genset stop. This prevent un-necessary stopping on a fluctuating mains supply etc.

Note: dis = disable

5.2.8 Expansion Modules

IO Module Selection (001.Disable/enable select)

DISABLE: If IO module will not be used, this parameter should be set as "DISABLE".

ENABLE: If IO module is to be used, this parameter should be set as "ACTIVE". In this case, the parameters related to the inputs and outputs of the IO module are added to the input/output parameters of the device.

When a compatible Dial-up communication module is installed on the back of the device, the device automatically recognizes this module and lists the following parameters in the "Expansion modules->Dial-up" section:

Dial-Up Module Selection (001.Disable/enable select)

DISABLE: The device does not respond to inquiries via the Dial-up communication module.

ENABLE: The device responds to inquiries via the Dial-up communication module.

Call Back Selection (002.Call back selection)

DISABLE: When a malfunction occurs in the device, the device does not call back.

ENABLE: When a malfunction occurs in the device, the device informs the computer on which the PC software runs through the Dial-up communication module by making a callback.

When a compatible GPRS communication module is installed on the back of the device, the device automatically recognizes this module and lists the following parameters in the "Expansion modules->GPRS" section:

GPRS Module Selection (001.Disable/enable select)

0-DISABLE: The device does not respond to inquiries via the GPRS communication module.

1-GPRS SERVER: The device connects to the internet by using a static IP SIM card inserted on the module and waits for a connection request from the PC or Cloud software.

2-GPRS CLIENT: The device connects to the internet using a static or dynamic IP-enabled SIM card installed on the module and sends a connection request to the PC or Cloud software. Note: This mode can be used for reverse connection to the Cloud.

3-SMS: The device can send the fault conditions as an SMS to the mobile phone stored in its memory via the SIM card in the module. In addition, the user can read and write all parameters with special SMS commands, monitor the current status of the generator and control the generator when necessary.

Note: dis = disable

Call Back Selection (002.Call back selection)

DISABLE: When a malfunction occurs in the device, the device does not call back.

ENABLE: When a malfunction occurs in the device, the device informs the computer on which the PC software runs through the GPRS communication module by making a callback.

Cell Info Refresh Rate (003.Cell info refresh rate)

GSM cell informations (operator name, signal level, IP number, base station location, etc.) is updated with the period defined in this parameter.

Location Data (004.Location data)

DISABLE: The device does not look at the location (latitude-longitude) information.

ENABLE: The device displays the location (latitude-longitude) of the nearest base station on the screen.

Location Warning (005.Location warning)

When the location of the device changes as much as the value in this parameter, the device adds this situation to the event logs with the message "Location changed" and can send an SMS to the mobile phone stored in its memory.

Note: dis = disable

5.2.9 Synchronization

Power Factor Control Set Value (Q06.PF control set

The power factor is controlled using a PID controller on the Trans-Syncro units in the system. In mains parallel operation, the reactive load sharing is not performed. So the reactive power of the genset is regulated by the "006.Power factor control set" parameter.

Device Number (001.Device number)

This parameter defines identification number of a controller on the “CAN OPEN” link (Multilink). This device number must be unique and only be used once on the “CAN OPEN” link.

Baud rate (002.Baudrate)

This parameter defines the used baud rate. All controllers on the “CAN OPEN” link (Multilink) must use the same baud rate.

Message Transmission Rate (003.Message transmission rate)

The value of this parameter defines the time delay between two fast CAN messages. If the value of configured here is short given, the bus load will be reduced.

Note: Changing above mentioned parameters becomes only effective after restarting the unit.

Data Delay Time (004.Data delay time)

This parameter is used to decide the "CANOPENInfall(Meltilink)

Can Open Fault Actions (005.Can Open fault actions)

DISABLE: The "GAMOREAN"ohinlai(MeltWilk)ot be checked.

ENABLE: The "OANOnREAnInNai(MeltWilk)e checked.

Check Can Open Version (006.Check Can Open version)

DISABLE: The Software Version (Multiple) checked.

ENABLE: The Software Version (Mobile) checked.

In order for the system to work safely, all units (“Trans-Syncro” or “Trans-Mains” units) in the system must to have the same version of Can Open.

If the unit detects the "Trans-Syncro" unit which has a different the Can Open version in the system, the unit will display a "Can Open version error-1" message and stop the genset.

If the unit detects the "Trans-Mains" unit which has a different the Can Open version in the system, the unit will display a "Can Open version error-2" message and stop the genset.

The above parameters are used for the mains and/or generator bus synchronization.

Dead Busbar Voltage Level (001.DeadBus voltage set)

The bus is measured when the mains is to be loaded. If the measured value of the bus is to be below the parameter's value, the mains breaker can be closed immediately and the bus is assumed to be "dead". If the measured value of the bus is to be above the parameter's value, the mains must be completed its synchronization before the breaker can be closed.

Maximum Voltage Difference (002.Maximum voltage difference

If the difference between mains and busbar voltage is less than this parameter's value, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Positive Frequency Difference (Q03. Positive frequency difference

If the difference between mains and busbar frequency is less than this parameter's value, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Negative Frequency Difference (Q04.Negative frequency difference

If the difference between mains and busbar frequency is greater than this parameter's value, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Maximum Positive Phase Angle (Q05.Maximum positive phase angle

If the leading phase angle between mains and busbar is less than this parameter's value, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Maximum Negative Phase Angle (Q06.Maximum negative phase angle

If the lagging phase angle between mains and busbar is less than this parameter's value, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Contactor Closing Time (Q07.Relay closing time

The specific time of the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB) defines to the lead time of the close command.

Maximum Synchronization Time (Q08.Maximum synchronization time

If the synchronization is not successful within a time period adjusted by this parameter, the synchronization alarm will be issued and the gensets will be stopped.

Synchronization dwell time (009.Synchron dwell time)

If the synchronization conditions occurs and persists until this time, the close command will be issued for the mains circuit breaker (MCB) or generator bus circuit breaker (GBCB).

Slip Frequency Set Value Offset (Q10.Frequency set value offset

This parameter is used for while the generator bus synchronize to the mains. With this offset, the unit synchronizes with a positive slip.

Number Of Gensets On System (002.Number of gensets on system)

The number of gensets on the system should be defined by this parameter.

Minimum Genset Fault Actions (003.Minimum genset fault actions)

This protection is considered if the number of gensets on the system is less than the value defined in the "002.Number of gensets on the system" parameter.

Number Of Mains On System (004.Number of mains on system)

The number of mains on the system should be defined by this parameter.

Mains Priority (005.Mains priority)

This parameter is used for to define the priority of the mains multiple mains system.

The lower number represents higher priority.

If more than one mains supply has failed, the gensets are started and the related loads are transferred to the gensets in sequence according the priority order.

If more than one mains supply returns at the same time, the unit with the highest priority will take control of the gensets and perform a no-break transition to the mains supply.

Breaker Transition Mode Selection (Breaker transition mode)

0-BREAK: This mode is used to enable break transfer. When this mode is activated, the load is transferred after a short interruption according to the content of "01p2a01e transfer time

1-NO BREAK: This mode is used to enable no-break transfer. When this mode is activated, the load is transferred uninterruptedly. The load is supplied from both the mains and the gensets until the time in "09p10a02tArcexpal transition time
2-SOFT: This mode is used to enable soft transfer. When this mode is activated, the load is transferred with ramp.
3-PARALLEL: This mode is used to enable parallel operation. When this mode is activated, the load is shared between the mains and the gensets according to the content of "09.10.003.Load control mode parameter.

No Break Transition Time (008.break transition time)

If the "001 Breaker transition mode" parameter is configured as "1-NO BREAK", t he load is supplied from both the mains and the gensets until the time in this parameter expires.

Load Control Mode Selection (load control mode)

If the "0001 Breaker transition mode" parameter is configured as "3-PARALLEL", the Load control mode must be selected from this parameter. Options are as follows;

0-IMPORT POWER: Peak lopping or peak shaving. The mains shall always supply for the limit value set by parameter "0910.004. Lootbontersand load exceeds the limit value set by parameter "0910.004. abavectrionset" value is supplied by the gensets. It is especially used at times when the power requirement increases, that is, when the mains tariff will endure.

1-EXPORT POWER: Power export to mains. The gensets power export to the mains as much as the value in parameter "With constant power allocation." The gensets operate as part of the mains line in this mode.
2-CONSTANT POWER: Base load. The gensets shall always supply for the limit value set by parameter "09th0604Load control set and load exceeds the limit value set by parameter "09th0604Load control set value is supplied by the mains. If the load falls below the limit value set by parameter "09th0604Load control set" power of the genset is export to the mains.

Load Control Set (0.04ad control set)

This value is the reference for the load controller mode (import, export, constant) or the soft transition mode when performing parallel operation.

Load Control Hysteresis (0.05ad control hysteresis)

In parallel operation with the mains (0-Import power mode), this hysteresis value is used to issue stop command to the gensets.

Import Power Start Delay (00port power start delay)

In parallel operation with the mains (0-Import power mode), when the customer demand load exceeds the limit value set by parameter "09.10.004.Load control set" the start command will be issued to the gensets after the delay time of this parameter has expired.

Import Power Stop Delay (0.07port power stop delay)

In parallel operation with the mains (0-Import power mode), when the customer demand load falls below 0.04 "Order control" set's 0.05 "Load control hysteresis" parameter, the stop command will be issued to the gensets after the delay time of this parameter has expired.

Soft Transition High Limit (0.1ft transition high limit)

If the mains active power this exists while soft transferring from the gensets to the mains, the soft transition will be terminated and the well-beater-energized breaker (GBCB)

Soft Transition Low Limit (088ft transition low limit)

If the mains active power falls below this limit while soft transferring from the mains to the gensets, the soft transition will be terminated and the mains will be cheaper (138)

Soft Transition Timeout (Shift transition timeout)

If this timer was expired while soft transferring from the gensets to the mains, the soft transition will be terminated and the generator bus circuit breaker (GBCB) will be de-energized.

If this timer was expired while soft transferring from the mains to the gensets, the soft transition will be terminated and the mains will be de-kergized.

Vector Shift Set Value (001.Vector shift set)

Vector shift protection is enabled when the gensets are in parallel with the mains supply.

This parameter specifies the level of vector shift protection.

The unit measures the last 4 periods for any phase of the mains. At the end of each period, the average duration of the last 2 periods and the average duration of the 3th and 4th periods are compared. If the difference is greater than the value defined in this parameter, the unit will detect mains failure and display the “Mains vector shift alarm!” message on the screen.

Rocof (df/dt) Set Value (Q@cof (df/dt) set)

Rocof means "rate of change of frequency".

Rocof protection is enabled when the gensets are in parallel with the mains supply.

This parameter specifies the level of Rocof protection.

The unit measures the frequency of the mains every period. If the change in the mains frequency value exceeds the value defined in this parameter in the last 4 periods measured and this condition continues for the time specified in the "09.11.003.Rocof (df/dt) delay" parameter, the unit will detect mains failure and display the "Mains rocof alarm!" message on the screen.

Rocof (df/dt) Delay (R8cof (df/dt) delay)

If the measured Excel (df/dt) value in the "09.11.002.Rocof (df/dt) set" parameter for delay time configured here, the unit will detect mains failure and display the "Mains rocof alarm!" message on the screen.

Mains Decoupling Actions (Mains decoupling actions)

The mains decoupling protections are "Rocof" and "Vector shift".

When any of these protections (“Rocof” and “Vector shift”) is active, the unit decides how to behave according to the selection on this parameter;

0-Warning: The related alarm message is displayed to warn the user. But the generator bus load switch (GBCB), the mains load switch (MCB) or the gensets are not affected by this situation.

1-Electrical Trip: The generator bus load switch (GBCB) is opened and the gensets are stopped after running for as long as the cooling period.

2-Auxiliary Mains Failure: The mains load switch (MCB) is opened and the gensets are allowed to continue providing power to the load.

Mains Decoupling Control Delay (0.5ins decoupling control delay)

In parallel operation with the mains, when the mains contactor is switched on, the mains decoupling protections (Rocof and Vector shift) are activated after this time.

5.2.10 Logic Controller

Factory setting of the above LC parameters:

graph LR
    A["003.LC:Aux.flag-1"] --> B["&"]
    C["003.LC:Aux.flag-1"] --> B
    D["003.LC:Aux.flag-1"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph TD
    A["004.LC:Aux.flag-2"] --> B["&"]
    C["004.LC:Aux.flag-2"] --> B
    D["004.LC:Aux.flag-2"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph TD
    A["017.LC:Aux.flag-15"] --> B["&"]
    C["017.LC:Aux.flag-15"] --> B
    D["017.LC:Aux.flag-15"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

graph TD
    A["110.Timer-1 set"] --> B["&"]
    C["111.Timer-2 set"] --> B
    D["112.Active weekday"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 S 0.0"]
    H --> I["X"]

Factory setting of the above LC parameters:

10.02.CONFIGURE OUTPUTS
001.Configurable output-1:

graph LR
    A["074.Cnf.out-1 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

10.02.CONFIGURE OUTPUTS

002.Configurable output-2:

graph LR
    A["075.Cnf.out-2 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 S 0.0"]
    H --> I["X"]

10.02.CONFIGURE OUTPUTS

003.Configurable output-3:

graph LR
    A["076.Cnf.out-3 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

10.02.CONFIGURE OUTPUTS

004.Configurable output-4:

graph LR
    A["077.Cnf.out-4 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 S 0.0"]
    H --> I["X"]

10.02.CONFIGURE OUTPUTS

005.Configurable output-5:

graph LR
    A["078.Cnf.out-5 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["079.Cnf.out-6 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["080.Cnf.out-7 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

graph LR
    A["081.Cnf.out-8 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["082.Cnf.out-9 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["x"]

Factory setting of the above LC parameters:

graph LR
    A["084.Exp.out-1 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["085.Exp.out-2 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 s 0.0"]
    H --> I["X"]

graph LR
    A["086.Exp.out-3 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["087.Exp.out-4 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["088.Exp.out-5 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 / s / 0.0"] --> I["X"]

graph LR
    A["089.Exp.out-6 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

graph LR
    A["090.Exp.out-7 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

graph LR
    A["091.Exp.out-8 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

Factory setting of the above LC parameters:

graph LR
    A["003.LC:Aux.flag-1"] --> B["&"]
    C["001.Always false"] --> B
    D["001.Always false"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph LR
    A["003.LC:Aux.flag-1"] --> B["&"]
    C["001.Always false"] --> B
    D["001.Always false"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

graph LR
    A["003.LC:Aux.flag-1"] --> B["&"]
    C["001.Always false"] --> B
    D["001.Always false"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 S 0.0"]
    H --> I["X"]

graph LR
    A["003.LC:Aux.flag-1"] --> B["&"]
    C["001.Always false"] --> B
    D["001.Always false"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\nS\n0.0"]
    H --> I["X"]

graph TD
    A["110.Timer-1 set"] --> B["&"]
    C["111.Timer-2 set"] --> B
    D["002.Always true"] --> E["&"]
    F["001.Always false"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

The LC parameters in this page are used for establish specific times within various Logic Controller functions.

The LC parameters in this page are used for control specific register value within various Logic Controller functions.

5.2.11 User Adjustment

Battery Voltage Offset (001.Battery volt offset)

If the battery voltage value that the device calculates and displays on the screen is different from its actual value, this situation can be eliminated by entering the difference value in this parameter.

6. The Feature Of Exporting Of The Internal Data & Event Logs

The unit provides the feature of exporting to USB host memory of Internal Data & Event logs.

Export mode activate steps:

1-) Insert a USB flash memory into the USB host port of the unit.
2-) Activate the Stop mode by pressing the "Stop" button.
3-) In theStop mode when the horn silence button held pressed for 10 seconds, the unit will ask confirm as follows; EXPORT INTERNAL DATA & EVENT LOGS

4-) Select "YES" option using the Decrement button and press the Enter button to start the Export process. Then the below screen will be showed;

5-) The Export process will be completed after approximately 25 seconds and the below screen will be showed;

6-) Press the "ESC" button to finalize the Export process.

Exported Internal Datalogs:

The log directory structure is in an external USB host;

Unit serial number Year Day of year

ExportedDataLogs→SN_12045678230609.csv→

The below registers are exported;

Datalog time,

Bus V1, Bus and Bus frequency,

Mains, Mains 2, Mains 3 and Mains frequency,

Mains I1, Mains I2, Mains I3,

Mains kWh,

Battery voltage

Exported Event Logs:

The log directory structure is in an external USB host;

Unit serial number Year Day of year

Exported LogsEvent→SN 12345678_2023 20230609.csv

The below registers are exported;

Event log time,

Event log text code (Used to reference event text),

Mains V1, Main and Main frequency Mains

Mains I1, Mains I2, Mains I3,

Mains Mains kWh

Event log text codes descriptions:

Text Code: Description:

Event log text codes descriptions:

Text Code: Description:

17 => Reserved
18 => Battery low warning
19 => Battery high warning
20 => Reserved
21 => Reserved
22 => Reserved
23 => Reserved
24 => Reserved
25 => Reserved
26 => Emergency stop
27 => Spare-1 error
28 => Spare-2 error
29 => Spare-3 error
30 => Spare-4 error
31 => Spare-5 error
32 => Spare-6 error
33 => Spare-7 error
34 => Spare-8 error
35 => Spare-9 error
36 => Spare-10 error
37 => Spare-11 error
38 => Spare-12 error
39 => Spare-13 error
40 => Expansion spare-1 error
41 => Expansion spare-2 error
42 => Expansion spare-3 error
43 => Expansion spare-4 error
44 => Expansion spare-5 error
45 => Expansion spare-6 error
46 => Expansion spare-7 error
47 => Expansion spare-8 error
48 => Can Open communication failure
49 => Mains breaker not opened
50 => Bus breaker not closed
51 => Bus breaker not opened
52 => Reserved
53 => Reserved
54 => Reserved
55 => Reserved
56 => Reserved
57 => Can bus warning
58 => Reserved
59 => Reserved
60 => Reserved
61 => Reserved
62 => Mains phase sequence wrong
63 => Reserved
64 => Reserved
65 => Reserved
66 => Reserved
67 => Reserved
68 => Reserved
69 => Reserved
70 => Changed mode to stop
71 => Changed mode to manual
72 => Changed mode to test
73 => Changed mode to auto

Event log text codes descriptions:

Text Code: Description:

74 => SMS was sent
75 => SMS was not sent
76 => GPRS reset fail
77 => GPRS IP not found
78 => No response from modem
79 => Modem response: error
80 => Busbar phase sequence wrong
81 => Reserved
82 => Reserved
83 => Reserved
84 => Reserved
85 => Reserved
86 => Reserved
87 => Reserved
88 => Reserved
89 => Reserved
90 => Reserved
91 => Reserved
92 => Reserved
93 => Reserved
94 => Reserved
95 => Reserved
96 => Reserved
97 => Busbar not alive error
98 => Synchronization error
99 => Reserved
100 => Reserved
101 => Parameter differ error
102 => Reserved
103 => Reserved
104 => Location changed
105 => Mains breaker not closed
106 => Mains rocof alarm
107 => Mains vector shift alarm
108 => Minimum genset alarm
109 => Slave controller communicat.error
110 => Mains failure
111 => Mains okay
112 => Can Open version error-1
113 => Can Open version error-2

7. Logic Controller

The Logic Controller is used for configure the unit outputs or the gensets start/stop or the unit operation mode. For instance, the engine start can be programmed depending on whether the configurable input is active or a specific time of related day.

Structure of the Logic Controller:

graph LR
    A["Command (C1)"] --> B["Sign (S1)"]
    C["Command (C2)"] --> D["Sign (S2)"]
    E["Command (C3)"] --> F["Sign (S3)"]
    G["Command (C4)"] --> H["Sign (S4)"]
    B --> I["Operator (O1)"]
    D --> J["Operator (O2)"]
    F --> K["Operator (O3)"]
    H --> K
    I --> K
    J --> K
    K --> L["On/Off Delay"]
    L --> M["Output"]

Command (Cx):

Up to 330 functions is provided for the command inputs. These command variables are used for control the output function or relay.

Complete list of all command variables as follows;

1. Always false: The command and sign value are ignored and this logic path is always "false"

2. Always true: The command and sign value are ignored and this logic path is always "true"

003.LC:Aux.flag-1: Auxiliary flag-1

004.LC:Aux.flag-2: Auxiliary flag-2

005.LC:Aux.flag-3: Auxiliary flag-3

006.LC:Aux.flag-4: Auxiliary flag-4

007.LC:Aux.flag-5: Auxiliary flag-5

008.LC:Aux.flag-6: Auxiliary flag-6

009.LC:Aux.flag-7: Auxiliary flag-7

010.LC:Aux.flag-8: Auxiliary flag-8

011.LC:Aux.flag-9: Auxiliary flag-9

012.LC:Aux.flag-10: Auxiliary flag-10

013.LC:Aux.flag-11: Auxiliary flag-11

014.LC:Aux.flag-12: Auxiliary flag-12

015.LC:Aux.flag-13: Auxiliary flag-13

016.LC:Aux.flag-14: Auxiliary flag-14

017.LC:Aux.flag-15: Auxiliary flag-15

018.LC:Aux.flag-16: Auxiliary flag-16

019.LC:Conf.out-1: Configurable output-1

020.LC:Conf.out-2: Configurable output-2

021.LC:Conf.out-3: Configurable output-3

022.LC:Conf.out-4: Configurable output-4

023.LC:Conf.out-5: Configurable output-5

024.LC:Conf.out-6: Configurable output-6

025.LC:Conf.out-7: Configurable output-7

026.LC:Conf.out-8: Configurable output-8

027.LC:Conf.out-9: Configurable output-9

028.LC:Reserved

029.LC:Cnf.exp.out-1: Configurable expansion output-1

030.LC:Cnf.exp.out-2: Configurable expansion output-2

031.LC:Cnf.exp.out-3: Configurable expansion output-3

032.LC:Cnf.exp.out-4: Configurable expansion output-4

033.LC:Cnf.exp.out-5: Configurable expansion output-5

034.LC:Cnf.exp.out-6: Configurable expansion output-6

035.LC:Cnf.exp.out-7: Configurable expansion output-7

036.LC:Cnf.exp.out-8: Configurable expansion output-8

037.LC:Reserved

038.LC:Reserved

039.LC:Reserved

040.LC:Oper.mod.auto: Changed operation mode to auto

041.LC:Oper.mod.test: Changed operation mode to test

042.LC:Oper.mod.man.: Changed operation mode to manual

043.LC:Oper.mod.stop: Changed operation mode to stop

044.LC:Inf.mains.int: Informed mains interruption

045.LC:Reserved

046.LC:Reserved

047.LC:Reserved

048.LC:Reserved

049.LC:Reserved

050.LC:Reserved

051.LC:Reserved

052.LC:Reserved

053.Cnf.in-1 active: Configurable input-1 active

054.Cnf.in-2 active: Configurable input-2 active

055.Cnf.in-3 active: Configurable input-3 active

056.Cnf.in-4 active: Configurable input-4 active

057.Cnf.in-5 active: Configurable input-5 active

058.Cnf.in-6 active: Configurable input-6 active

059.Cnf.in-7 active: Configurable input-7 active

060.Cnf.in-8 active: Configurable input-8 active

061.Cnf.in-9 active: Configurable input-9 active

062.Cnf.in-10 active: Configurable input-10 active

063.Cnf.in-11 active: Configurable input-11 active

064.Cnf.in-12 active: Configurable input-12 active

065.Cnf.in-13 active: Configurable input-13 active

066.Exp.in-1 active: Configurable expansion input-1 active

067.Exp.in-2 active: Configurable expansion input-2 active

068.Exp.in-3 active: Configurable expansion input-3 active

069.Exp.in-4 active: Configurable expansion input-4 active

070.Exp.in-5 active: Configurable expansion input-5 active

071.Exp.in-6 active: Configurable expansion input-6 active

072.Exp.in-7 active: Configurable expansion input-7 active

073.Exp.in-8 active: Configurable expansion input-8 active

074.Cnf.out-1 funct.: Configurable output-1 function

075.Cnf.out-2 funct.: Configurable output-2 function

076.Cnf.out-3 funct.: Configurable output-3 function

077.Cnf.out-4 funct.: Configurable output-4 function

078.Cnf.out-5 funct.: Configurable output-5 function

079.Cnf.out-6 funct.: Configurable output-6 function

080.Cnf.out-7 funct.: Configurable output-7 function

081.Cnf.out-8 funct.: Configurable output-8 function

082.Cnf.out-9 funct.: Configurable output-9 function

083.Reserved

084.Exp.out-1 funct.: Configurable expansion output-1 function

085.Exp.out-2 funct.: Configurable expansion output-2 function

086.Exp.out-3 funct.: Configurable expansion output-3 function

087.Exp.out-4 funct.: Configurable expansion output-4 function

088.Exp.out-5 funct.: Configurable expansion output-5 function

089.Exp.out-6 funct.: Configurable expansion output-6 function

090.Exp.out-7 funct.: Configurable expansion output-7 function

091.Exp.out-8 funct.: Configurable expansion output-8 function

092.GBCB close activ: Generator bus circuit breaker (GBCB) close output active

093.MCB close active: Mains circuit breaker (MCB) close output active

1. Auto mode active: Auto mode active

2. Test mode active: Test mode active

096.Man. mode active: Manual mode active

1. Stop mode active: Stop mode active

098.Reserved

099.Reserved

1. Busbar ready: Busbar ready

101.Load supply bus: Load supply from bus

102.Load suppl.Mains: Load supply from mains

103.Mains okay: Mains okay

104.Reserved

105.Reserved

106.Reserved

107.Reserved

108.Reserved

1. Dead bus: Dead bus detected

110.Timer-1 set: Timer-1 set point exceeded

111.Timer-2 set: Timer-2 set point exceeded

112.Active weekday: Active weekday equal to setting

113.Active day: Active day equal to setting

114.Active hour: Active hour equal to setting

115.Active minute: Active minute equal to setting

116.Active second: Active second equal to setting

117.Reserved

118.Reserved

119.Reserved

120.Red alarm led-1: Red alarm led-1 active

121.Red alarm led-2: Red alarm led-2 active

122.Red alarm led-3: Red alarm led-3 active

123.Red alarm led-4: Red alarm led-4 active

124.Red alarm led-5: Red alarm led-5 active

125.Red alarm led-6: Red alarm led-6 active

126.Yellow alr led-1: Yellow alarm led-1 active

127.Yellow alr led-2: Yellow alarm led-2 active

128.Yellow alr led-3: Yellow alarm led-3 active

129.Servic.alr led-1: Service alarm led-1 active

130.Servic.alr led-2: Service alarm led-2 active

131.Servic.alr led-3: Service alarm led-3 active

132.Servic.alr led-4: Service alarm led-4 active

133.Servic.alr led-5: Service alarm led-5 active

134.Servic.alr led-6: Service alarm led-6 active

135.Input-1 alarm!: Spare 1 error

136.Input-2 alarm!: Spare 2 error

137.Input-3 alarm!: Spare 3 error

138.Input-4 alarm!: Spare 4 error

139.Input-5 alarm!: Spare 5 error

140.Input-6 alarm!: Spare 6 error

141.Input-7 alarm!: Spare 7 error

142.Input-8 alarm!: Spare 8 error

143.Input-9 alarm!: Spare 9 error

144.Input-10 alarm!: Spare 10 error

145.Input-11 alarm!: Spare 11 error

146.Input-12 alarm!: Spare 12 error

147.Input-13 alarm!: Spare 13 error

148.Exp.input-1 alr!: Expansion I/O module spare 1 error

149.Exp.input-2 alr!: Expansion I/O module spare 2 error

150.Exp.input-3 alr!: Expansion I/O module spare 3 error

151.Exp.input-4 alr!: Expansion I/O module spare 4 error

152.Exp.input-5 alr!: Expansion I/O module spare 5 error

153.Exp.input-6 alr!: Expansion I/O module spare 6 error

154.Exp.input-7 alr!: Expansion I/O module spare 7 error

155.Exp.input-8 alr!: Expansion I/O module spare 8 error

1. Emergency stop!: Emergency stop error

157.Reserved

158.Reserved

159.Reserved

160.Reserved

161.Bus ph.seq.wrng!: Busbar phase sequence wrong

162.Reserved

163.Reserved

164.Reserved

165.Batt. low warn!: Battery low error

166.Batt. high warn!: Battery high error

167.Reserved

168.Reserved

169.Reserved

170.Reserved

171.Reserved

172.Reserved

173.Reserved

174.Reserved

1. Bus br. not clos!: Generator bus breaker not closed alarm

2. Bus br. not open!: Generator bus breaker not opened alarm

177.Mains br.not cl!: Mains breaker not closed alarm

178.Mains br.not op!: Mains breaker not opened alarm

179.Reserved

180.Reserved

181.Reserved

182.Reserved

183.Reserved

184.Reserved

185.Reserved

186.Reserved

187.Reserved

188.Reserved

189.Reserved

190.Reserved

191.Reserved

192.Reserved

193.Can bus warning!: Can Bus error

194.Reserved

195.Reserved

196.Reserved

197.Reserved

198.Reserved

199.Reserved

200.Reserved

201.Reserved

202.Mains ph.seq.wr!: Mains phase sequence wrong

203.Reserved

204.Reserved

205.Reserved

206.Reserved

207.Reserved

208.Reserved

209.Reserved

210.Reserved

211.Reserved

212.Reserved

213.Reserved

214.Reserved

215.Reserved

216.Reserved
217.Reserved
218.Reserved
219.Reserved
220.Reserved
221.Reserved
222.Reserved
223.Reserved
224.Reserved
225.Reserved
226.Reserved
227.Reserved
228.Reserved
229.Reserved
230.Reserved
231.Reserved
232. Bus no aliv.err!: Busbar Not alive error
233.Synchroniz. err!: Synchronization error
234.Reserved
235.Reserved
236.Reserved
237.Reserved
238.Reserved
239.Reserved
240.Reserved
241.Reserved
242.Reserved
243.Reserved
244.Reserved
245.Reserved
246.Reserved
247.CanOpen com.err!: Can Open communication failure
248.Mains rocof alr!: Mains rocof alarm
249.Mains vec.shift!: Mains vector shift alarm
250.Min.genset alarm!: Minimum genset alarm
251.Reserved!
252.Reserved!
253.Reserved!
254.Reserved!
255.Reserved!
256.Reserved!
257.Reserved!
258.Reserved!
259.Reserved!
260.Reserved!
261.Reserved!
262.Reserved!
263.Reserved!
264.Reserved!
265.Reserved!
266.Reserved!
267.Reserved!
268.Reserved!
269.Reserved!
270.Reserved!
271.CanOpen ver.er1!: Can Open version error-1
272.CanOpen ver.er2!: Can Open version error-2
273.SI.Contr.com.er!: Slave controller communication error

274.RC:Register set1: Register set1 parameter value
275.RC:Register set2: Register set2 parameter value
276.RC:Register set3: Register set3 parameter value
277.RC:Register set4: Register set4 parameter value
278.RC:Register set5: Register set5 parameter value
279.RC:Register set6: Register set6 parameter value
280.RC:Register set7: Register set7 parameter value
281.RC:Register set8: Register set8 parameter value
282.RC:Bus V1: Bus V1 active value
283.RC:Bus V2: Bus V2 active value
284.RC:Bus V3: Bus V3 active value
285.RC:Bus V12: Bus V12 active value
286.RC:Bus V23: Bus V23 active value
287.RC:Bus V31: Bus V31 active value
288.RC:Bus frequency: Bus frequency active value
289.RC:Mains V1: Mains V1 active value
290.RC:Mains V2: Mains V2 active value
291.RC:Mains V3: Mains V3 active value
292.RC:Mains V12: Mains V12 active value
293.RC:Mains V23: Mains V23 active value
294.RC:Mains V31: Mains V31 active value
295.RC:Mains freque.: Mains frequency active value
296.RC:Mains l1: Mains l1 active value
297.RC:Mains I2: Mains I2 active value
298.RC:Mains I3: Mains I3 active value
299.RC:Load L1 Curr.: Load L1 current active value
300.RC:Reserved
301.RC:Reserved
302.RC:Reserved
303.RC:Mains P1: Mains P1 active value
304.RC:Mains P2: Mains P2 active value
305.RC:Mains P3: Mains P3 active value
306.RC:Mains P total: Mains P total active value
307.RC:Mains Q1: Mains Q1 active value
308.RC:Mains Q2: Mains Q2 active value
309.RC:Mains Q3: Mains Q3 active value
310.RC:Mains Q total: Mains Q total active value
311.RC:Mains S1: Mains S1 active value
312.RC:Mains S2: Mains S2 active value
313.RC:Mains S3: Mains S3 active value
314.RC:Mains S total: Mainsn S total active value
315.RC:Mains kWh: Mains kWh active value
316.RC:Mains kVArh: Mains kVArh active value
317.RC:Reserved
318.RC:Reserved
319.RC:Reserved
320.RC:Reserved
321.RC:Reserved
322.RC:Reserved
323.RC:Battery volt: Battery voltage active value
324.RC:Reserved
325.RC:Reserved
326.RC:Reserved
327.RC:Reserved
328.RC:Reserved
329.RC:Reserved
330.RC:Reserved

Sign (Sx):

The sign field can be used for invert the status of the input command. If the sign field is configured to the "Not" state value, the output of the input command variable switches to false or vice versa. Complete list of all sign values as follows;

Direct command value:

— The input command value is passed directly to the operator.

Not command value:

- The input command value is inverted passed to the operator.

Operator (Ox):

The operator field can be used for logic symbols such as AND, NAND, OR, NOR, XOR, NXOR. Additionally the operator field can be used for comparison symbols such as >, <. Complete list of all operator field symbols as follows;

Logic and comparison symbols:

AND NAND OR NOR XOR NXOR

> <

Symbols

→xx

-

Truth table

a a a a a ab b b b b bx x x x x x

if a>b, x=1

if a

0 0 0 0 0 0 0 0 0 10 0 0 0 0 0 1 0 1 01 1 0 0 0 0 0 0 1 01 1 1 1 1 1 0 1 0 0 1

On/Off Delay:

The On Delay is the amount of time that the logical output status is delayed before changing to true. The Off Delay is the amount of time that the logical output status is delayed before changing to false.

Output:

The Logic Controller outputs can be grouped into three types as “Configurable auxiliary flags”, “Unit configurable outputs” and “Configurable logic functions”.

1-) Configurable auxiliary flags:

These 16 auxiliary logical flags can be programmed to activate or deactivate logical functions. These flags can be used whenever for input commands are not enough or time delayed signals are required.

The "10.01.016.Auxiliary flag-16" logical output can be used like "Timer function" as follows;

graph LR
    A["110.Timer-1 set"] --> B["&"]
    C["111.Timer-2 set"] --> B
    D["112.Active weekday"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0 / s / 0.0"] --> I["X"]

2-) Unit configurable outputs:

There are 10 internal configurable outputs and 8 expansion I/O module configurable outputs.

If the "10.02.001.Configurable output-1" logical output becomes true, the unit configurable output-1 will be activated.

If the "10.02.002.Configurable output-2" logical output becomes true, the unit configurable output-2 will be activated.

If the “10.02.003.Configurable output-3” logical output becomes true, the unit configurable output-3 will be activated.

If the "10.02.004.Configurable output-4" logical output becomes true, the unit configurable output-4 will be activated.

If the “10.02.005.Configurable output-5” logical output becomes true, the unit configurable output-5 will be activated.

If the “10.02.006.Configurable output-6” logical output becomes true, the unit configurable output-6 will be activated.

If the "10.02.007.Configurable output-7" logical output becomes true, the unit configurable output-7 will be activated.

If the "10.02.008.Configurable output-8" logical output becomes true, the unit configurable output-8 will be activated.

If the "10.02.009.Configurable output-9" logical output becomes true, the unit configurable output-9 will be activated.

If the "10.03.001.Config. expansion output-1" logical output becomes true, the unit configurable expansion output-1 will be activated.

If the "10.03.002.Config. expansion output-2" logical output becomes true, the unit configurable expansion output-2 will be activated.

If the "10.03.003.Config. expansion output-3" logical output becomes true, the unit configurable expansion output-3 will be activated.

If the “10.03.004.Config. expansion output-4” logical output becomes true, the unit configurable expansion output-4 will be activated.

If the "10.03.005.Config. expansion output-5" logical output becomes true, the unit configurable expansion output-5 will be activated.

If the "10.03.006.Config. expansion output-6" logical output becomes true, the unit configurable expansion output-6 will be activated.

If the "10.03.007.Config. expansion output-7" logical output becomes true, the unit configurable expansion output-7 will be activated.

If the "10.03.008.Config. expansion output-8" logical output becomes true, the unit configurable expansion output-8 will be activated.

As factory default, the "10.02.001.Configurable output-1" logical output is programmed as configurable output-1 function (Fuel relay energised) as follows;

graph LR
    A["074.Cnf.out-1 funct."] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

3-) Configurable logic functions:

Internal conditions such as “Changed mode to auto”, “Changed mode to test”, “Changed mode to manual”, “Changed mode to stop” and “Informed mains interruption”.

If the “10.04.004.Changed mode to auto” logical function becomes true, the unit operation mode will be changed to auto mode.

If the "10.04.005.Changed mode to test" logical function becomes true, the unit operation mode will be changed to test mode.

If the “10.04.006.Changed mode to manual” logical function becomes true, the unit operation mode will be changed to manual mode.

If the “10.04.007.Changed mode to stop” logical function becomes true, the unit operation mode will be changed to stop mode.

If the "10.04.008.Informed mains interruption" logical function becomes true, the gensets are started, synchronised with the mains supply and the load is transferred with both mains to the gensets transferring.

Programming examples:

Example-1: If the configurable input-1 is active and if this situation continues for 5 seconds, the unit configurable output-6 will be active.

For this, the "10.02.006.Configurable output-6" logical output must be programmed as follows;

graph LR
    A["053.Cnf.in-1 active"] --> B["&"]
    C["002.Always true"] --> B
    D["002.Always true"] --> E["&"]
    F["002.Always true"] --> E
    B --> G["&"]
    E --> G
    G --> H["5.0\ns\n0.0"]
    H --> I["X"]

Example-2: In auto mode, if the bus frequency active value rises above 52.0Hz or if the mains frequency active value falls below 48.0Hz, the operation mode of the unit will change to stop mode.

For this;

• Set the "Program->Technician setting->10.Logic controller->06.General->001.Register set-1" parameter as "520"
• Set the "Program->Technician setting->10.Logic controller->06.General->002.Register set-2" parameter as "480"
• The "10.04.007.Changed mode to stop" logical function must be programmed as follows;

graph TD
    A["288.RC:Bus frequency"] --> B[">"]
    C["274.RC:Register set-1"] --> B
    D["295.RC:Mains freque."] --> E["<"]
    F["275.RC:Register set-2"] --> E
    B --> G[">=1"]
    E --> G
    G --> H["0.0\ns\n0.0"]
    H --> I["X"]

1. Specifications

9. Other Informations

Manufacturer Information:

Emko Elektronik Sanayi ve Ticaret A.Ş.

Repair and maintenance service information:

Emko Elektronik Sanayi ve Ticaret A.Ş.