Mitsubishi GX Works2/GX Works3 for Temperature Control
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 Temperature Control:
- 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 Temperature Control applications through its excellent price-to-performance ratio. This is particularly valuable when working with the 4 sensor types typically found in Temperature Control systems, including Thermocouples (K-type, J-type), RTD sensors (PT100, PT1000), Infrared temperature sensors.
Control Equipment for Temperature Control:
- Electric resistance heaters (cartridge, band, strip)
- Steam injection systems
- Thermal fluid (hot oil) systems
- Refrigeration and chiller systems
Mitsubishi's controller families for Temperature Control include:
- FX5: Suitable for intermediate Temperature Control applications
- iQ-R: Suitable for intermediate Temperature Control applications
- iQ-F: Suitable for intermediate Temperature Control applications
- Q Series: Suitable for intermediate Temperature Control 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. Mitsubishi PLCs serve Japanese and Asian automotive manufacturers with MELSEC iQ-R controllers managing assembly line transfers, welding automation, and quality inspection systems. Body assembly lines use multiple CPU configurations (up to 4 CPUs in single rack) distributing control: CPU1 handles co...
Investment Considerations:
With $$ pricing, Mitsubishi positions itself in the mid-range segment. For Temperature Control projects requiring intermediate skill levels and 2-3 weeks development time, the total investment includes hardware, software licensing, training, and ongoing support.
Understanding Communications for Temperature Control
Industrial communications connect PLCs to I/O, other controllers, HMIs, and enterprise systems. Protocol selection depends on requirements for speed, determinism, and compatibility.
Execution Model:
For Temperature Control applications, Communications offers significant advantages when multi-plc systems, scada integration, remote i/o, or industry 4.0 applications.
Core Advantages for Temperature Control:
- System integration: Critical for Temperature Control when handling intermediate control logic
- Remote monitoring: Critical for Temperature Control when handling intermediate control logic
- Data sharing: Critical for Temperature Control when handling intermediate control logic
- Scalability: Critical for Temperature Control when handling intermediate control logic
- Industry 4.0 ready: Critical for Temperature Control when handling intermediate control logic
Why Communications Fits Temperature Control:
Temperature Control systems in Process Control typically involve:
- Sensors: RTDs (PT100/PT1000) for high-accuracy measurements, Thermocouples (J, K, T types) for high-temperature applications, Infrared pyrometers for non-contact measurement
- Actuators: SCR (thyristor) power controllers for electric heaters, Solid-state relays for on/off heating control, Proportional control valves for steam or thermal fluid
- Complexity: Intermediate with challenges including Long thermal time constants making tuning difficult
Control Strategies for Temperature Control:
- pid: Standard PID control with proportional, integral, and derivative terms tuned for the thermal process dynamics
- cascade: Master temperature loop outputs to slave heater/cooler control loop for tighter control
- ratio: Maintain temperature ratio between zones for gradient applications
Programming Fundamentals in Communications:
Communications in GX Works2/GX Works3 follows these key principles:
1. Structure: Communications organizes code with remote monitoring
2. Execution: Scan cycle integration ensures 4 sensor inputs are processed reliably
3. Data Handling: Proper data types for 5 actuator control signals
Best Practices for Communications:
- Use managed switches for industrial Ethernet
- Implement proper network segmentation (OT vs IT)
- Monitor communication health with heartbeat signals
- Plan for communication failure modes
- Document network architecture including IP addresses
Common Mistakes to Avoid:
- Mixing control and business traffic on same network
- No redundancy for critical communications
- Insufficient timeout handling causing program hangs
- Incorrect byte ordering (endianness) between systems
Typical Applications:
1. Factory networks: Directly applicable to Temperature Control
2. Remote monitoring: Related control patterns
3. Data collection: Related control patterns
4. Distributed control: Related control patterns
Understanding these fundamentals prepares you to implement effective Communications solutions for Temperature Control using Mitsubishi GX Works2/GX Works3.
Implementing Temperature Control with Communications
Industrial temperature control systems use PLCs to regulate process temperatures in manufacturing, food processing, chemical processing, and other applications. These systems maintain precise temperature setpoints through heating and cooling control while ensuring product quality and energy efficiency.
This walkthrough demonstrates practical implementation using Mitsubishi GX Works2/GX Works3 and Communications programming.
System Requirements:
A typical Temperature Control implementation includes:
Input Devices (Sensors):
1. RTDs (PT100/PT1000) for high-accuracy measurements: Critical for monitoring system state
2. Thermocouples (J, K, T types) for high-temperature applications: Critical for monitoring system state
3. Infrared pyrometers for non-contact measurement: Critical for monitoring system state
4. Thermistors for fast response applications: Critical for monitoring system state
5. Thermal imaging cameras for surface temperature monitoring: Critical for monitoring system state
Output Devices (Actuators):
1. SCR (thyristor) power controllers for electric heaters: Primary control output
2. Solid-state relays for on/off heating control: Supporting control function
3. Proportional control valves for steam or thermal fluid: Supporting control function
4. Solenoid valves for cooling water or refrigerant: Supporting control function
5. Variable frequency drives for cooling fan control: Supporting control function
Control Equipment:
- Electric resistance heaters (cartridge, band, strip)
- Steam injection systems
- Thermal fluid (hot oil) systems
- Refrigeration and chiller systems
Control Strategies for Temperature Control:
- pid: Standard PID control with proportional, integral, and derivative terms tuned for the thermal process dynamics
- cascade: Master temperature loop outputs to slave heater/cooler control loop for tighter control
- ratio: Maintain temperature ratio between zones for gradient applications
Implementation Steps:
Step 1: Characterize thermal system dynamics (time constants, dead time)
In GX Works2/GX Works3, characterize thermal system dynamics (time constants, dead time).
Step 2: Select appropriate sensor type and placement for representative measurement
In GX Works2/GX Works3, select appropriate sensor type and placement for representative measurement.
Step 3: Size heating and cooling capacity for worst-case load conditions
In GX Works2/GX Works3, size heating and cooling capacity for worst-case load conditions.
Step 4: Implement PID control with appropriate sample time (typically 10x faster than process time constant)
In GX Works2/GX Works3, implement pid control with appropriate sample time (typically 10x faster than process time constant).
Step 5: Add output limiting and anti-windup for safe operation
In GX Works2/GX Works3, add output limiting and anti-windup for safe operation.
Step 6: Program ramp/soak profiles if required
In GX Works2/GX Works3, program ramp/soak profiles if required.
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. Long thermal time constants making tuning difficult
- Solution: Communications addresses this through System integration.
2. Transport delay (dead time) causing instability
- Solution: Communications addresses this through Remote monitoring.
3. Non-linear response at different temperature ranges
- Solution: Communications addresses this through Data sharing.
4. Sensor placement affecting measurement accuracy
- Solution: Communications addresses this through Scalability.
Safety Considerations:
- Independent high-limit safety thermostats (redundant to PLC)
- Watchdog timers for heater control validity
- Safe-state definition on controller failure (heaters off)
- Thermal fuse backup for runaway conditions
- Proper ventilation for combustible atmospheres
Performance Metrics:
- Scan Time: Optimize for 4 inputs and 5 outputs
- Memory Usage: Efficient data structures for FX5 capabilities
- Response Time: Meeting Process Control requirements for Temperature Control
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 2-3 weeks development timeline while maintaining code quality.
Mitsubishi Communications Example for Temperature Control
Complete working example demonstrating Communications implementation for Temperature Control using Mitsubishi GX Works2/GX Works3. Follows Mitsubishi naming conventions. Tested on FX5 hardware.
// Mitsubishi GX Works2/GX Works3 - Temperature Control Control
// Communications Implementation for Process Control
// Mitsubishi programming supports both traditional device addr
// ============================================
// Variable Declarations
// ============================================
VAR
bEnable : BOOL := FALSE;
bEmergencyStop : BOOL := FALSE;
rThermocouplesKtypeJtype : REAL;
rHeatingelements : REAL;
END_VAR
// ============================================
// Input Conditioning - RTDs (PT100/PT1000) for high-accuracy measurements
// ============================================
// Standard input processing
IF rThermocouplesKtypeJtype > 0.0 THEN
bEnable := TRUE;
END_IF;
// ============================================
// Safety Interlock - Independent high-limit safety thermostats (redundant to PLC)
// ============================================
IF bEmergencyStop THEN
rHeatingelements := 0.0;
bEnable := FALSE;
END_IF;
// ============================================
// Main Temperature Control Control Logic
// ============================================
IF bEnable AND NOT bEmergencyStop THEN
// Industrial temperature control systems use PLCs to regulate
rHeatingelements := rThermocouplesKtypeJtype * 1.0;
// Process monitoring
// Add specific control logic here
ELSE
rHeatingelements := 0.0;
END_IF;Code Explanation:
- 1.Communications structure optimized for Temperature Control in Process Control applications
- 2.Input conditioning handles RTDs (PT100/PT1000) for high-accuracy measurements signals
- 3.Safety interlock ensures Independent high-limit safety thermostats (redundant to PLC) always takes priority
- 4.Main control implements Industrial temperature control systems u
- 5.Code runs every scan cycle on FX5 (typically 5-20ms)
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
- ✓Communications: Use managed switches for industrial Ethernet
- ✓Communications: Implement proper network segmentation (OT vs IT)
- ✓Communications: Monitor communication health with heartbeat signals
- ✓Temperature Control: Sample at 1/10 of the process time constant minimum
- ✓Temperature Control: Use derivative on PV, not error, for temperature control
- ✓Temperature Control: Start with conservative tuning and tighten gradually
- ✓Debug with GX Works2/GX Works3: Use sampling trace to capture high-speed events occurring faster than
- ✓Safety: Independent high-limit safety thermostats (redundant to PLC)
- ✓Use GX Works2/GX Works3 simulation tools to test Temperature Control logic before deployment
Common Pitfalls to Avoid
- ⚠Communications: Mixing control and business traffic on same network
- ⚠Communications: No redundancy for critical communications
- ⚠Communications: Insufficient timeout handling causing program hangs
- ⚠Mitsubishi common error: Error 2110: Illegal device specified - accessing device outside configured range
- ⚠Temperature Control: Long thermal time constants making tuning difficult
- ⚠Temperature Control: Transport delay (dead time) causing instability
- ⚠Neglecting to validate RTDs (PT100/PT1000) for high-accuracy measurements leads to control errors
- ⚠Insufficient comments make Communications programs unmaintainable over time