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GE Fanuc IC693ALG391 Series 90-30 Analog Current Output Module

GE Fanuc IC693ALG391 Series 90-30 Analog Current Output Module

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  • Manufacturer: General Electric

  • Product No.: IC693ALG391

  • Country of origin:Egyesült Államok

  • Product Type: Analog Current Output Module

  • Barcode: 8537101190

  • Payment: T/T, Western Union

  • Weight: 450g

  • Dimensions: 200 mm × 150 mm × 60 mm

  • Shipping port: Xiamen

  • Warranty: 12 months

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Description

The IC693ALG391 is a high-performance 2-channel analog current output module developed for the GE Fanuc Series 90-30 Programmable Logic Controller platform. This space-saving single-slot interface board converts 12-bit digital binary values received from the central processing host into stable, isolated industrial-grade analog output currents for precision control applications. Operating over standard output ranges of 4 to 20 mA or 0 to 20 mA, the module ensures synchronized loop updates by executing full internal digital-to-analog conversions on both channels simultaneously during every programmable controller CPU I/O scan loop. High-speed internal galvanic optical isolation buffers block high-voltage spikes and eliminate industrial electromagnetic noise interference between active field loop cabling and the low-voltage logic side backplane.

Features

  • Dual high-speed, individually isolated analog output channels driven by a dedicated internal 12-bit digital-to-analog converter framework.
  • Dual software-independent configuration profiles accommodating standard industrial 4 to 20 mA or extended 0 to 20 mA operational loops.
  • Integrated high-speed updating logic driving simultaneous data transformations across both channels within an approximate 5-millisecond execution interval.
  • Advanced active safety response mechanism allowing individual channels to instantly hold their last active output state or default directly to 0/4 mA during system stop or reset conditions.
  • Multifunctional circuit path routing allowing standard low-impedance current sourcing or configuration as a voltage source via simple external jumper links.
  • Heavy-duty optical isolation barriers engineered to continuously block electrical noise and common-mode transients up to 1500 volts between the field wiring terminal and controller logic.
  • Dual-input power architecture utilizing either standard isolated PLC backplane 24 VDC power lines or external auxiliary 24 VDC loop standby power supplies.

Applications

  • Variable speed drive frequency reference control and modulated speed sequencing loops.
  • Proportional flow-control valve positioners and pneumatic actuator balancing instrumentation.
  • Remote analog instrumentation recorders, loop controllers, and distributed processing interface units.
  • Paper mill, water treatment, and petrochemical processing cell parameter profiling.

Technical Specifications

Electrical

Parameter Specification
Nominal Supply Voltage +24 VDC from isolated backplane rail or external loop supply 
Logic Supply Voltage +5 VDC supplied directly via the backplane 
External Supply Voltage Range 20 to 30 VDC 
External Supply Voltage Ripple 10% maximum 
Maximum Compliance Voltage 25 V 
Internal Power Consumption (+5V) 30 mA from +5 VDC logic supply rail 
Internal Power Consumption (+24V) 215 mA from isolated +24 VDC backplane or external supply 
Galvanic Isolation Barrier 1500 Volts continuous between field-side connections and backplane logic 

Performance

Parameter Specification
Digital-to-Analog Resolution 12 bits binary (1 part in 4096) 
Channel Update Rate Approximately 5 milliseconds simultaneously for both output channels 
Output Current Ranges 4 to 20 mA (Default) and 0 to 20 mA (Jumpered) 
Output Voltage Ranges 1 to 5 V and 0 to 5 V (Up to 2 to 10 V and 0 to 10 V with external resistor) 
Resolution (4 to 20 mA) 4 uA per least significant bit (1 LSB = 4 uA) 
Resolution (0 to 20 mA) 5 uA per least significant bit (1 LSB = 5 uA) 
Resolution (1 to 5 V) 1 mV per least significant bit (1 LSB = 1 mV) 
Resolution (0 to 5 V) 1.25 mV per least significant bit (1 LSB = 1.25 mV) 
Absolute Accuracy (4 to 20 mA) +/-8 uA at 25 degC (77°F) ambient 
Absolute Accuracy (0 to 20 mA) +/-10 uA at 25 degC (77°F) ambient 
Absolute Accuracy (1 to 5 V) +/-50 mV at 25 degC (77°F) ambient 
Absolute Accuracy (0 to 5 V) +/-50 mV at 25 degC (77°F) ambient 
Factory Calibration Factor Calibrated to 4 uA per digital count increment 

Output Loading Parameters

Parameter / Operational Mode Specification / Loading Limit
User Load Resistance (Current Mode) 0 to 850 ohms maximum 
Output Load Capacitance (Current Mode) 2000 pF maximum 
Output Load Inductance (Current Mode) 1 H maximum 
Maximum Loading (Voltage Mode) 5 mA maximum drive current (2K ohms minimum load resistance) 
Output Load Capacitance (Voltage Mode) 2000 pF maximum 

Mechanical & Physical Attributes

Attribute Description
Manufacturer GE Fanuc Automation (Industrial Systems)
Country of Origin USA
Form Factor / Slot Width Single-slot module, high-density compact layout 
Baseplate Placement Constraints Any available I/O slot of a 5-slot or 10-slot Series 90-30 rack 
Module Status Diagnostics Single green faceplate LED indicating active internal power supply state 

Connections and Interfaces

Detachable I/O Terminal Block Layout & Pin Assignment

The front-facing connection assembly utilizes a standard 20-pin removable terminal strip to organize field loop routing, configuration jumpers, and auxiliary supply ties.

Terminal Pin Terminal Label Engineering Function / Circuit Mapping
1 VOUT1 Voltage Mode Output Terminal for Channel 1 
2 VOUT2 Voltage Mode Output Terminal for Channel 2 
3 IOUT1 Current Mode Sourcing Output for Channel 1 
4 IOUT2 Current Mode Sourcing Output for Channel 2 
5 RTN1 Current Loop Return Path Node for Channel 1 
6 RTN2 Current Loop Return Path Node for Channel 2 
7 GND Shield Ground Connection Point / Frame Ground Bus Link 
8 GND Shield Ground Connection Point / Frame Ground Bus Link 
9 JMPV1 Voltage Mode Selection Jumper Node for Channel 1 
10 JMPV2 Voltage Mode Selection Jumper Node for Channel 2 
11 NC No Internal Connection Point
12 DEF 0 Fail-Safe State Jumper Node (Default to 0/4 mA configuration) 
13 NC No Internal Connection Point
14 RANGE 1 0 to 20 mA Scale Range Jumper Node for Channel 1 
15 NC No Internal Connection Point
16 NC No Internal Connection Point
17 NC No Internal Connection Point
18 24V Auxiliary External +24 VDC Positive Supply Input Terminal 
19 NC No Internal Connection Point
20 RANGE 2 0 to 20 mA Scale Range Jumper Node for Channel 2 

Installation Guidelines

To ensure maximum equipment reliability, safety, and compliance with industrial standards, follow these structured engineering protocols during deployment.

1. System Power Safety & Slot Restrictions
CRITICAL NOTICE: MANDATORY DE-ENERGIZATION
Always confirm that the main controller baseplate power source is completely disconnected before inserting, adjusting, or extracting the module. Do not hot-swap under any circumstances.
  • The module can be placed into any standard I/O slot across any expansion or CPU baseplate.
  • To prevent power supply degradation and overheating, restrict population to a maximum of 6 master modules per CPU baseplate simultaneously.
  • Ensure that each installed module is routed to a physically isolated, independent network loop to avoid signal contention.
+-------------------------------------------------------------+ | [CPU] | [Slot 2] | [Slot 3] | [Slot 4] | [Slot 5] | [Slot 6] | | Slot1 | I/O LINK| I/O LINK| I/O LINK| I/O LINK| I/O LINK| | | Master | Master | Master | Master | Master | +-------------------------------------------------------------+ |__________ Max 6 Modules per CPU Baseplate __________|
2. Communication Cabling & Shielding Techniques
  • Signal Interference Mitigation: All field connections terminating at the 20-pin Honda-type front port must be routed through industrial-grade shielded twisted-pair (STP) cabling. This is critical to maintain RS-422/RS-485 balanced line signal integrity.
  • Drain Wire Grounding: Terminate the cable outer shield directly to the system frame ground or dedicated chassis ground bus bar to eliminate high-frequency electromagnetic noise.
3. Execution Sequence & Initial Power-Up
1
Verify Hardware Mounting
Confirm the module is firmly seated into the backplane slots and the top/bottom plastic clips are locked in place.
2
Connect Field Wiring
Secure the 20-pin Honda-type connector to the serial line leading to the first distributed slave device.
3
Apply Primary Power
Turn on the main chassis power supply and closely monitor the startup sequence diagnostics via the LED indicators.
4. Post-Installation Fault Recovery Operations
  • Link Instability Resolution: If a transient communication error, timeout, or packet loss occurs on the serial bus, utilize the integrated front-panel interface to restore normal system operations.
  • Manual Reset Execution: Firmly press the dedicated LINK RESTART manual pushbutton on the front faceplate. This overrides frozen error registers, clears network faults, and forces an immediate cold initialization of the serial communication link without rebooting the main PLC CPU.

Product Documentation

Technical Datasheet (PDF) Complete specifications and technical drawings.

Technical Datasheet

GE Fanuc IC693ALG391 Series 90-30 Analog Current Output Module

What happens to the analog current loop outputs if the host CPU enters STOP mode?

The response is determined by the DEF 0 jumper on terminal pin 12. If unjumpered, channels hold their last active value, provided backup power is connected. If jumpered, they default immediately to 0 mA or 4 mA based on the selected range.

How can the module be modified to output a 0 to 10 V signal instead of a current loop?

To configure a 0 to 10 V range, the channel must be set to the 0 to 20 mA range with a jumper, and a high-precision 250-ohm resistor must be installed between the JMPVx and IOUTx terminals instead of a standard wire link.

What is the maximum number of these modules that can be installed on a single baseplate?

A maximum of three modules can be installed per baseplate if they are drawing power exclusively from the PLC backplane. To overcome this limit and avoid overloading the backplane supply, an external 24 VDC power supply must be wired to the terminal block.

How does the module process out-of-range register values written by user code?

The module uses a 16-bit 2's complement format scaled up to a decimal count of 32000 for full-scale current outputs. If an invalid data value greater than 32767 is entered, the programming software rejects the entry and does not accept the value.

Globális expressz szállítás

  • Normál szállítás: 4-6 munkanap a DHL, FedEx és UPS szolgáltatásával.
  • Gyors kiszállítás: A raktáron lévő, 14:00 (GMT+8) előtt leadott megrendeléseket aznap feladjuk.
  • Világszintű lefedettség: Több mint 150 országban szolgálunk ki, beleértve a gyors szállítást Szaúd-Arábiába és az Egyesült Arab Emírségekbe.

Visszaküldés és garancia

  • 30 napos garancia: Csak a raktáron lévő termékek eredeti, gyári zárt csomagolásban történő visszaküldését fogadjuk el.
  • 12 hónapos garancia: Minden ipari alkatrészünket szakmai műszaki garancia védi.

A megrendeléseket hétfőtől péntekig dolgozzuk fel és szállítjuk (állami ünnepnapok kivételével).


A teljes jogosultság, a készletfeltöltési díjak és a nemzetközi visszaküldési részletek megtekintéséhez kérjük, tekintse meg hivatalos oldalunkat Visszatérítési és Visszaküldési Szabályzat .

TECHNICAL SPECIFICATIONS

Color pattern
Szürkésfehér Fekete
Country of origin
Egyesült Államok
Power source
DC áram

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