Mitsubishi Structured Text for Packaging Automation: Complete Programming Guide

Implementing Structured Text for Packaging Automation using Mitsubishi GX Works2/GX Works3 requires translating theory into working code that performs reliably in production. This hands-on guide focuses on practical implementation steps, real code examples, and the pragmatic decisions that make the difference between successful and problematic Packaging Automation deployments. Mitsubishi's platform serves High - Popular in electronics manufacturing, packaging, and assembly, providing the proven foundation for Packaging Automation implementations. The GX Works2/GX Works3 environment supports 4 programming languages, with Structured Text being particularly effective for Packaging Automation because complex calculations, data manipulation, advanced control algorithms, and when code reusability is important. Practical implementation requires understanding not just language syntax, but how Mitsubishi's execution model handles 5 sensor inputs and 5 actuator outputs in real-time. Real Packaging Automation projects in Packaging face practical challenges including product changeover, high-speed synchronization, and integration with existing systems. Success requires balancing powerful for complex logic against steeper learning curve, while meeting 3-6 weeks project timelines typical for Packaging Automation implementations. This guide provides step-by-step implementation guidance, complete working examples tested on FX5, practical design patterns, and real-world troubleshooting scenarios. You'll learn the pragmatic approaches that experienced integrators use to deliver reliable Packaging Automation systems on schedule and within budget.

Mitsubishi GX Works2/GX Works3 for Packaging Automation

GX Works3 represents Mitsubishi's latest engineering software supporting the MELSEC iQ-R and iQ-F series controllers, while GX Works2 remains in use for legacy Q, L, and FX5 series PLCs. The programming environment features a project-based structure organizing programs into multiple POUs (Program Organization Units) including main programs, function blocks, and structured projects. Unlike Western PLC manufacturers, Mitsubishi supports both device-addressed programming (X0, Y0, M0, D0) and label-...

Platform Strengths for Packaging Automation:

Excellent price-to-performance ratio

Fast processing speeds

Compact form factors

Strong support in Asia-Pacific

Unique ${brand.software} Features:

Simple Motion module integration with motion SFC (Sequential Function Chart) programming eliminating complex positioning code

RD.DPR instruction providing direct device programming without software transfer for recipe adjustments

Melsoft Navigator project management integrating multiple controllers, HMIs, and network devices in unified environment

Multiple CPU configuration allowing up to 4 CPUs in single rack sharing memory via high-speed backplane

Key Capabilities:

The GX Works2/GX Works3 environment excels at Packaging Automation applications through its excellent price-to-performance ratio. This is particularly valuable when working with the 5 sensor types typically found in Packaging Automation systems, including Vision systems, Weight sensors, Barcode scanners.

Control Equipment for Packaging Automation:

Form-fill-seal machines (horizontal and vertical)

Case erectors and sealers

Labeling systems (pressure sensitive, shrink sleeve)

Case packers (drop, wrap-around, robotic)

Mitsubishi's controller families for Packaging Automation include:

FX5: Suitable for intermediate to advanced Packaging Automation applications

iQ-R: Suitable for intermediate to advanced Packaging Automation applications

iQ-F: Suitable for intermediate to advanced Packaging Automation applications

Q Series: Suitable for intermediate to advanced Packaging Automation applications

Hardware Selection Guidance:

Mitsubishi offers several controller families addressing different performance and application requirements. The MELSEC iQ-R series represents the flagship product line with processing speeds as fast as 0.98ns per basic instruction supporting applications from small machines to complex automated systems. R04CPU provides 40K steps program capacity and 256K words data memory suitable for compact mac...

Industry Recognition:

High - Popular in electronics manufacturing, packaging, and assembly. Packaging machinery manufacturers across Asia Pacific standardize on Mitsubishi for flexibility, compact form factors, and responsive local technical support. Form-fill-seal machines use coordinated motion controlling film advance, product dosing, sealing, and cutting with electronic line shaft (vir...

Investment Considerations:

With $$ pricing, Mitsubishi positions itself in the mid-range segment. For Packaging Automation projects requiring advanced skill levels and 3-6 weeks development time, the total investment includes hardware, software licensing, training, and ongoing support.

Understanding Structured Text for Packaging Automation

Structured Text (ST) is a high-level, text-based programming language defined in IEC 61131-3. It resembles Pascal and provides powerful constructs for complex algorithms, calculations, and data manipulation.

Execution Model:

Code executes sequentially from top to bottom within each program unit. Variables maintain state between scan cycles unless explicitly reset.

Core Advantages for Packaging Automation:

Powerful for complex logic: Critical for Packaging Automation when handling intermediate to advanced control logic

Excellent code reusability: Critical for Packaging Automation when handling intermediate to advanced control logic

Compact code representation: Critical for Packaging Automation when handling intermediate to advanced control logic

Good for algorithms and calculations: Critical for Packaging Automation when handling intermediate to advanced control logic

Familiar to software developers: Critical for Packaging Automation when handling intermediate to advanced control logic

Why Structured Text Fits Packaging Automation:

Packaging Automation systems in Packaging typically involve:

Sensors: Product detection sensors for counting and positioning, Registration sensors for label and film alignment, Barcode/2D code readers for verification

Actuators: Servo drives for precise motion control, Pneumatic cylinders for pick-and-place, Vacuum generators and cups

Complexity: Intermediate to Advanced with challenges including Maintaining registration at high speeds

Programming Fundamentals in Structured Text:

Variables:
- declaration: VAR / VAR_INPUT / VAR_OUTPUT / VAR_IN_OUT / VAR_GLOBAL sections
- initialization: Variables can be initialized at declaration: Counter : INT := 0;
- constants: VAR CONSTANT section for read-only values

Operators:
- arithmetic: + - * / MOD (modulo)
- comparison: = <> < > <= >=
- logical: AND OR XOR NOT

ControlStructures:
- if: IF condition THEN statements; ELSIF condition THEN statements; ELSE statements; END_IF;
- case: CASE selector OF value1: statements; value2: statements; ELSE statements; END_CASE;
- for: FOR index := start TO end BY step DO statements; END_FOR;

Best Practices for Structured Text:

Use meaningful variable names with consistent naming conventions

Initialize all variables at declaration to prevent undefined behavior

Use enumerated types for state machines instead of magic numbers

Break complex expressions into intermediate variables for readability

Use functions for reusable calculations and function blocks for stateful operations

Common Mistakes to Avoid:

Using = instead of := for assignment (= is comparison)

Forgetting semicolons at end of statements

Integer division truncation - use REAL for decimal results

Infinite loops from incorrect WHILE/REPEAT conditions

Typical Applications:

1. PID control: Directly applicable to Packaging Automation
2. Recipe management: Related control patterns
3. Statistical calculations: Related control patterns
4. Data logging: Related control patterns

Understanding these fundamentals prepares you to implement effective Structured Text solutions for Packaging Automation using Mitsubishi GX Works2/GX Works3.

Implementing Packaging Automation with Structured Text

Packaging automation systems use PLCs to coordinate primary, secondary, and tertiary packaging operations. These systems control filling, labeling, case packing, palletizing, and integration with production and warehouse systems.

This walkthrough demonstrates practical implementation using Mitsubishi GX Works2/GX Works3 and Structured Text programming.

System Requirements:

A typical Packaging Automation implementation includes:

Input Devices (Sensors):
1. Product detection sensors for counting and positioning: Critical for monitoring system state
2. Registration sensors for label and film alignment: Critical for monitoring system state
3. Barcode/2D code readers for verification: Critical for monitoring system state
4. Vision systems for quality inspection: Critical for monitoring system state
5. Reject confirmation sensors: Critical for monitoring system state

Output Devices (Actuators):
1. Servo drives for precise motion control: Primary control output
2. Pneumatic cylinders for pick-and-place: Supporting control function
3. Vacuum generators and cups: Supporting control function
4. Glue and tape applicators: Supporting control function
5. Film tensioners and seal bars: Supporting control function

Control Equipment:

Form-fill-seal machines (horizontal and vertical)

Case erectors and sealers

Labeling systems (pressure sensitive, shrink sleeve)

Case packers (drop, wrap-around, robotic)

Control Strategies for Packaging Automation:

1. Primary Control: Automated packaging systems using PLCs for product wrapping, boxing, labeling, and palletizing.
2. Safety Interlocks: Preventing Product changeover
3. Error Recovery: Handling High-speed synchronization

Implementation Steps:

Step 1: Define packaging specifications for all product variants

In GX Works2/GX Works3, define packaging specifications for all product variants.

Step 2: Create motion profiles for each packaging format

In GX Works2/GX Works3, create motion profiles for each packaging format.

Step 3: Implement registration control with encoder feedback

In GX Works2/GX Works3, implement registration control with encoder feedback.

Step 4: Program pattern generation for case and pallet loading

In GX Works2/GX Works3, program pattern generation for case and pallet loading.

Step 5: Add reject handling with confirmation logic

In GX Works2/GX Works3, add reject handling with confirmation logic.

Step 6: Implement barcode/vision integration for verification

In GX Works2/GX Works3, implement barcode/vision integration for verification.

Mitsubishi Function Design:

Function block (FB) programming in Mitsubishi creates reusable logic modules with defined interfaces encapsulating complexity. FB definition includes input variables (VAR_INPUT), output variables (VAR_OUTPUT), internal variables (VAR), and retained variables (VAR_RETAIN) maintaining values between calls. Creating motor control FB: inputs include Start_Cmd (BOOL), Stop_Cmd (BOOL), Speed_SP (INT), outputs include Running_Sts (BOOL), Fault_Sts (BOOL), Actual_Speed (INT), internal variables store timers, state machine stages, and diagnostic counters. FB instantiation creates instance: Motor1 (Motor_FB) with unique variable storage, allowing multiple instances Motor1, Motor2, Motor3 controlling different motors using same logic. Array of FB instances: Motors : ARRAY[1..10] OF Motor_FB accessed as Motors[3].Running_Sts checking status of motor 3. Standard function (FUN) differs from FB by lacking internal memory, suitable for calculations or conversions: Temp_Conversion_FUN(Celsius) returns Fahrenheit without retaining historical data. Structured text programming within FBs/FUNs provides clearer logic for complex algorithms compared to ladder: IF-THEN-ELSIF-ELSE structures, FOR loops, CASE statements expressing intent more directly than ladder equivalents. EN/ENO functionality enables conditional execution: EN (enable input) controls whether FB executes, ENO (enable output) indicates successful execution detecting errors within block. Library management exports FBs to library files (.glib) shared across projects and engineering teams, versioned to track modifications and ensure consistency. The intelligent function module (IFM) templates provide pre-built FBs for common applications: PID control, analog scaling, motion positioning reducing development time and providing tested reliable code. Simulation mode tests FB logic without hardware, allowing desktop development and unit testing before commissioning. Protection functionality encrypts FB contents preventing unauthorized viewing or modification, useful for proprietary algorithms or OEM machine builders distributing programs to end users.

Common Challenges and Solutions:

1. Maintaining registration at high speeds

Solution: Structured Text addresses this through Powerful for complex logic.

2. Handling product variability in automated systems

Solution: Structured Text addresses this through Excellent code reusability.

3. Quick changeover between package formats

Solution: Structured Text addresses this through Compact code representation.

4. Synchronizing multiple machines in a line

Solution: Structured Text addresses this through Good for algorithms and calculations.

Safety Considerations:

Guarding around rotating and reciprocating parts

Safety-rated position monitoring for setup access

Heat hazard protection for seal bars and shrink tunnels

Proper pinch point guarding

Robot safety zones and light curtains

Performance Metrics:

Scan Time: Optimize for 5 inputs and 5 outputs

Memory Usage: Efficient data structures for FX5 capabilities

Response Time: Meeting Packaging requirements for Packaging Automation

Mitsubishi Diagnostic Tools:

Device memory monitor: Real-time table displaying current values for X, Y, M, D devices with force capability,Entry data monitor: Shows actual rung logic states with contact ON/OFF indication during program execution,Device test: Manually control outputs and set internal relays for wiring verification without program influence,Intelligent module diagnostics: Buffer memory display showing module status, error codes, and configuration,Scan time monitor: Displays current, maximum, and minimum scan times identifying performance issues,Error code history: Chronological log of system errors, module faults, and CPU events with timestamps,CC-Link/network diagnostics: Visual network status showing connected stations, errors, and communication statistics,SD card operation log: Records all SD card read/write operations, file transfers, and access timestamps,Remote diagnosis via Ethernet: Connect GX Works over network for monitoring and troubleshooting without local access,Sampling trace: Records device value changes over time with trigger conditions for intermittent fault analysis,System monitor: Displays CPU load, memory usage, and battery status for predictive maintenance,Safety diagnosis (safety CPU): Dedicated diagnostics for safety I/O discrepancy detection and emergency stop chain status

Mitsubishi's GX Works2/GX Works3 provides tools for performance monitoring and optimization, essential for achieving the 3-6 weeks development timeline while maintaining code quality.

Mitsubishi Structured Text Example for Packaging Automation

Complete working example demonstrating Structured Text implementation for Packaging Automation using Mitsubishi GX Works2/GX Works3. Follows Mitsubishi naming conventions. Tested on FX5 hardware.

(* Mitsubishi GX Works2/GX Works3 - Packaging Automation Control *)
(* Structured Text Implementation for Packaging *)
(* Mitsubishi programming supports both traditional device addressing (M0 *)

PROGRAM PRG_PACKAGING_AUTOMATION_Control

VAR
    (* State Machine Variables *)
    eState : E_PACKAGING_AUTOMATION_States := IDLE;
    bEnable : BOOL := FALSE;
    bFaultActive : BOOL := FALSE;

    (* Timers *)
    tonDebounce : TON;
    tonProcessTimeout : TON;
    tonFeedbackCheck : TON;

    (* Counters *)
    ctuCycleCounter : CTU;

    (* Process Variables *)
    rVisionsystems : REAL := 0.0;
    rServomotors : REAL := 0.0;
    rSetpoint : REAL := 100.0;
END_VAR

VAR CONSTANT
    (* Packaging Process Parameters *)
    C_DEBOUNCE_TIME : TIME := T#500MS;
    C_PROCESS_TIMEOUT : TIME := T#30S;
    C_BATCH_SIZE : INT := 50;
END_VAR

(* Input Conditioning *)
tonDebounce(IN := bStartButton, PT := C_DEBOUNCE_TIME);
bEnable := tonDebounce.Q AND NOT bEmergencyStop AND bSafetyOK;

(* Main State Machine - Pattern: State machine implementation in Mitsubis *)
CASE eState OF
    IDLE:
        rServomotors := 0.0;
        ctuCycleCounter(RESET := TRUE);
        IF bEnable AND rVisionsystems > 0.0 THEN
            eState := STARTING;
        END_IF;

    STARTING:
        (* Ramp up output - Gradual start *)
        rServomotors := MIN(rServomotors + 5.0, rSetpoint);
        IF rServomotors >= rSetpoint THEN
            eState := RUNNING;
        END_IF;

    RUNNING:
        (* Packaging Automation active - Packaging automation systems use PLCs to coordinat *)
        tonProcessTimeout(IN := TRUE, PT := C_PROCESS_TIMEOUT);
        ctuCycleCounter(CU := bCyclePulse, PV := C_BATCH_SIZE);

        IF ctuCycleCounter.Q THEN
            eState := COMPLETE;
        ELSIF tonProcessTimeout.Q THEN
            bFaultActive := TRUE;
            eState := FAULT;
        END_IF;

    COMPLETE:
        rServomotors := 0.0;
        (* Log production data - High-speed data logging in Mitsubishi uses file registers (R devices) organized as circular buffers with automatic SD card archiving for long-term storage. Create logging structure: file registers R0-R9999 storing 10,000 samples with each sample containing timestamp (R[base]), values (R[base+1] to R[base+10]), status (R[base+11]). Write pointer (D500) increments with each log entry: [MOV current time R[(D500*12)]] [MOV process values R[(D500*12)+1]] [INC D500] with modulo operation wrapping pointer [LD> D500 K9999] [MOV K0 D500]. Triggered logging initiates capture on alarm conditions preserving pre-trigger buffer: maintain continuous logging but flag trigger index enabling post-event retrieval of 100 samples before alarm and 500 samples after providing failure context. CSV file export uses SD card write instructions formatting file register data into comma-delimited text files readable by Excel or data analysis software: SDWR instruction writes R0-R9999 to SD:\LOG\data.csv with timestamp filename generation creating unique files daily. Sampling rates configurable from 10ms (fixed cycle interrupt program) to several minutes (main program logic) depending on process dynamics and storage capacity requirements. Data compression implements deadband filtering: log sample only when value changes exceed threshold reducing storage requirements for slowly-changing process variables like tank levels or temperatures. Integration with SCADA/historian systems uses SLMP protocol transferring logged data via Ethernet to centralized databases with automatic retry logic handling network interruptions preventing data loss. Batch correlation links production data to specific product lots: each batch start creates new log file section with batch ID header enabling traceability from raw materials through finished goods. Energy logging totalizes consumption from power meters connected via CC-Link or Modbus calculating specific energy per produced unit, identifying efficiency improvements and cost allocation by product line. Safety event logging captures all safety input states, bypass activations, and emergency stop events with tamper-proof timestamps meeting regulatory documentation requirements for incident investigations and compliance audits. *)
        eState := IDLE;

    FAULT:
        rServomotors := 0.0;
        (* Alarm management in Mitsubishi uses bit devices (M or B) for alarm active flags with corresponding data registers storing timestamps, values, and alarm details. Alarm structure allocates device ranges: M1000-M1999 for alarm active flags (1000 unique alarms), D5000-D5999 storing alarm timestamps or associated values. Alarm detection logic: [LD Tank_Level > High_Limit] [AND NOT previous alarm state M1000] [OUT M1000] [MOV current time D5000] capturing alarm activation moment. Alarm acknowledgment requires operator action via HMI: GOT screen button writes to acknowledgment bit (M2000) which resets alarm flag when condition clears [LD M1000] [AND alarm cleared] [AND M2000 acknowledged] [RST M1000] [RST M2000]. Priority classification uses different device ranges or separate bits: Critical alarms M1000-M1099, Warnings M1100-M1199, Information M1200-M1299 with severity-specific visual/audible HMI indicators. Alarm logging to SD card uses CSV file write instructions (SDWR) recording alarm number, timestamp, activation/deactivation, and associated process values for historical analysis and regulatory compliance. First-out alarm detection latches initial alarm in cascade of related faults: bearing temperature alarm (M1050) latches before motor overload (M1051) before production stopped (M1052) with reset sequence clearing in reverse order after root cause addressed. Integration with GOT HMI alarm viewer displays active alarms in sortable/filterable list with acknowledgment tracking, alarm help text, and corrective action guidance displayed to operators. Alarm rate limiting prevents flooding when single fault triggers hundreds of consequential alarms: introduce 5-second delays before enabling secondary alarms allowing operators to focus on root cause. Email notification for critical alarms uses Ethernet communication function blocks sending SMTP messages to distribution lists with alarm details formatted in message body. Statistical alarm analysis counts alarm frequencies storing totals in file registers: most frequent alarm identification guides preventive maintenance priorities addressing chronic equipment issues before failures occur. *)
        IF bFaultReset AND NOT bEmergencyStop THEN
            bFaultActive := FALSE;
            eState := IDLE;
        END_IF;
END_CASE;

(* Safety Override - Always executes *)
IF bEmergencyStop OR NOT bSafetyOK THEN
    rServomotors := 0.0;
    eState := FAULT;
    bFaultActive := TRUE;
END_IF;

END_PROGRAM

Code Explanation:

1.Enumerated state machine (State machine implementation in Mitsubishi typically uses data registers (D devices) storing current state values with ladder logic evaluating state transitions. Define state constants using file registers or direct values: STATE_IDLE = 0, STATE_STARTING = 10, STATE_RUNNING = 20, STATE_STOPPING = 30, STATE_FAULT = 90 with spaced values allowing future state insertion. Current state stored in D0 with comparison instructions (LD= D0 K0) checking states and advancement logic incrementing or setting new state values (MOV K10 D0). Timer-based state transitions use timer completion contacts: [TON timer T0 reaches preset] [AND current state = STARTING] [THEN advance to RUNNING state MOV K20 D0]. Structured text programming within function blocks provides clearer state machine logic: CASE Machine_State OF 0: (IDLE state actions and transition evaluation), 10: (STARTING state actions), 20: (RUNNING state actions), END_CASE. State transition logging writes state changes to file registers creating audit trail: when D0 changes, copy timestamp and previous state to R[pointer] incrementing pointer for circular buffer. Fault handling sets state to FAULT (90) with fault code stored in separate register (D10) indicating cause: 100=Emergency_Stop, 101=Overload, 102=Communication_Loss, with reset logic evaluating fault code and returning to appropriate safe state. Parallel state machines coordinate through shared status bits: Machine1_State (D100), Machine2_State (D200) with interlock logic preventing conflicting operations. HMI integration displays state names using text switching on D0 value converting numeric states to operator-friendly descriptions: 0='Ready', 10='Starting', 20='Running'. Function block encapsulation creates reusable state machine logic instantiated multiple times for identical equipment with instance-specific state storage in FB internal variables.) for clear Packaging Automation sequence control
2.Constants define Packaging-specific parameters: cycle time 30s, batch size
3.Input conditioning with debounce timer prevents false triggers in industrial environment
4.STARTING state implements soft-start ramp - prevents mechanical shock
5.Process timeout detection identifies stuck conditions - critical for reliability
6.Safety override section executes regardless of state - Mitsubishi best practice for intermediate to advanced systems

Best Practices

✓Follow Mitsubishi naming conventions: Mitsubishi programming supports both traditional device addressing (M0, D100, X1
✓Mitsubishi function design: Function block (FB) programming in Mitsubishi creates reusable logic modules wit
✓Data organization: Mitsubishi uses file registers (R devices) and structured data in function block
✓Structured Text: Use meaningful variable names with consistent naming conventions
✓Structured Text: Initialize all variables at declaration to prevent undefined behavior
✓Structured Text: Use enumerated types for state machines instead of magic numbers
✓Packaging Automation: Use electronic gearing for mechanical simplicity
✓Packaging Automation: Implement automatic film/label splice detection
✓Packaging Automation: Add statistical monitoring of registration error
✓Debug with GX Works2/GX Works3: Use sampling trace to capture high-speed events occurring faster than
✓Safety: Guarding around rotating and reciprocating parts
✓Use GX Works2/GX Works3 simulation tools to test Packaging Automation logic before deployment

Common Pitfalls to Avoid

⚠Structured Text: Using = instead of := for assignment (= is comparison)
⚠Structured Text: Forgetting semicolons at end of statements
⚠Structured Text: Integer division truncation - use REAL for decimal results
⚠Mitsubishi common error: Error 2110: Illegal device specified - accessing device outside configured range
⚠Packaging Automation: Maintaining registration at high speeds
⚠Packaging Automation: Handling product variability in automated systems
⚠Neglecting to validate Product detection sensors for counting and positioning leads to control errors
⚠Insufficient comments make Structured Text programs unmaintainable over time

Related Certifications

🏆Mitsubishi PLC Programming Certification

🏆Advanced Mitsubishi Programming Certification

Mastering Structured Text for Packaging Automation applications using Mitsubishi GX Works2/GX Works3 requires understanding both the platform's capabilities and the specific demands of Packaging. This guide has provided comprehensive coverage of implementation strategies, working code examples, best practices, and common pitfalls to help you succeed with intermediate to advanced Packaging Automation projects. Mitsubishi's 15% market share and high - popular in electronics manufacturing, packaging, and assembly demonstrate the platform's capability for demanding applications. Packaging machinery manufacturers across Asia Pacific standardize on Mitsubishi for flexibility, compact form factors, and responsive local technical ... By following the practices outlined in this guide—from proper program structure and Structured Text best practices to Mitsubishi-specific optimizations—you can deliver reliable Packaging Automation systems that meet Packaging requirements. **Next Steps for Professional Development:** 1. **Certification**: Pursue Mitsubishi PLC Programming Certification to validate your Mitsubishi expertise 3. **Hands-on Practice**: Build Packaging Automation projects using FX5 hardware 4. **Stay Current**: Follow GX Works2/GX Works3 updates and new Structured Text features **Structured Text Foundation:** Structured Text (ST) is a high-level, text-based programming language defined in IEC 61131-3. It resembles Pascal and provides powerful constructs for... The 3-6 weeks typical timeline for Packaging Automation projects will decrease as you gain experience with these patterns and techniques. Remember: Use electronic gearing for mechanical simplicity For further learning, explore related topics including Recipe management, Pharmaceutical blister packing, and Mitsubishi platform-specific features for Packaging Automation optimization.