PLC Programmable Variable Frequency Speed ​​Regulation and Electrical Control Training Equipment 5568SA67 Industrial PLC Training Equipment

I. Features of the PLC Programmable Variable Frequency Speed ​​Regulation and Electrical Control Training Device:

1. The device adopts a modular structure, making it easy to replace experimental modules. If expansion of functions or development of new experiments is needed, simply add experimental module boxes; it will never become obsolete.

2. Dual-port wiring method: The connection between the PLC host and the experimental module box can be achieved through self-locking plug-in single-wire point-by-point connection, improving the experimenter’s hands-on and problem-solving abilities and deepening their understanding of the PLC’s structure and functions. Alternatively, it can be connected in one go via ribbon cable, increasing the speed of experimental wiring. This method is absolutely superior to the single-wire connection methods used by other manufacturers.

3. The experimental objects are realistic, closely resembling actual industrial applications. Through training with this device, students can quickly adapt to on-site work.

4. It uses a Mitsubishi FX1N-40mR programmable controller, which is powerful, high-performance, and features a modular design for flexible combination. Users can assemble different control systems according to different needs. 5. Configuration bar diagram teaching: MCGS industrial control configuration software is used. All experiments have been edited to create visually appealing, dynamic, and effective configuration bar diagrams for dynamic tracking and teaching.

6. Comprehensive experimental projects: Includes digital and analog signals, variable frequency speed control, touch screens, network communication, and electrical control.

7. Network teaching experiments with PLC mainframes: Equipped with RS485 network communication (CC-Link communication is also optional, price to be discussed separately). The teacher’s computer (master station) can conduct direct communication experiments with 16 PLC mainframes (slave stations) (i.e., 1:N communication), and any one PLC mainframe (master station) can conduct direct communication experiments with 7 PLC mainframes (slave stations) (i.e., N:N communication).

II. Technical Specifications of the PLC Programmable Variable Frequency Speed ​​Regulation and Electrical Control Training Device:

1. Input Power: Three-phase four-wire (~380V±10% 50Hz)

2. Operating Environment: Temperature -10℃～+40℃, Relative Humidity <85% (25℃)

3. Device Capacity: 300VA

4. Weight: 160Kg

5. Dimensions: 160×75×150 cm3
III. Composition of the PLC Programmable Variable Frequency Speed ​​Regulation and Electrical Control Training Device:

(I) AC Power Control Function Board

1. Input Power: Three-phase four-wire power supply; indicator light illuminates upon input.

2. Power Output: Equipped with leakage current protector, overload protection, and short-circuit protection.

A. Three-phase four-wire 380V output, indicated by three voltmeters.

B. ~220V output via safety socket.

C. +24V/2A DC regulated power supply output (digital display).

D. +5V/1A DC regulated power supply output (digital display)

E. ±12V/1A DC regulated power supply output (depending on device requirements)

(II) Control Panel: The front panel features a large recessed area with vertical guide rails, allowing for interchangeable positions of experimental modules.

(III) Experiment Table: Steel-wood structure

(IV) ZL-01 PLC Main Unit Experiment Components:

1. Mitsubishi FX1N-40mR-001 AC/DC/Relay, with built-in digital I/O (24-channel switch input, 16-channel relay output).

2. FX0N-3A Analog Module (2-channel analog input, 1-channel analog output).

3. FX2N-485-BD Communication Module, SC-09 Communication Programming Power Supply, using RS485 network communication.

(V) ZL-02 Relay Contactor Control Experiment Box (I): Provides 2 AC contactors, 2 thermal relays, 1 analog light bulb, and 3 control buttons. (VI) ZL-03 Relay Contactor Control Experiment Box (II): Provides 2 AC contactors, 1 time relay, energy-consuming braking transformer, rectifier diodes, high-power resistors, etc.

(VII) ZL-04 Touch Screen Experiment Box: Equipped with a 5.7-inch eview500 256-color LCD touch screen with an RS485 communication interface. (VIII) ZL-05 Inverter Experiment Box (Mitsubishi FR-S520)

(IX) Temperature Closed-Loop Control Box

(X) A/D and D/A Conversion Box

(XI) PLC01 Traffic Signal Light PLC Automatic Control Experiment Box

(XII) PLC02 Agitator PLC Automatic Control Experiment Box

(XIII) PLC03 LED Digital Tube Display PLC Automatic Control Experiment Box (Actual)

(XIV) PLC04 Four-Story Elevator PLC Automatic Control Experiment Box (Actual)

(XV) PLC05 Machining Center Tool Magazine Selection Control Experiment Box (Actual)

(XVI) PLC06 Artistic Decorative Light PLC Control Experiment Box

(XVII) PLC07 Motor Automatic Control Experiment Box (Actual)

(XVIII) PLC08 Stepper Motor PLC Control Experiment Box (Actual)

(XIX) PLC09 Analog TV Transmission Tower Experiment Box

(XX) PLC10 Experimental Boxes for Automatic Feeding and Loading Systems

(XXI) Experimental Boxes for Automatic Vending Machines (PLC11) Experimental Boxes for Automatic Molding Systems (PLC12) Experimental Boxes for Automatic Molding Systems (PLC12) Experimental Boxes for Automatic Water Supply Systems for Water Towers (PLC13) Experimental Boxes for Automatic Mail Sorting Systems (PLC14) Experimental Boxes for Automatic Mail Sorting Systems (PLC14) Experimental Boxes for Automatic Washing Machine Systems (PLC15) Experimental Boxes for Automatic Washing Machine Systems (PLC15) Experimental Boxes for Automatic Water Supply Systems (PLC16) Experimental Boxes for Electroplating Systems (PLC16) Experimental Boxes for Electroplating Systems (PLC16) 2 Units of Three-Phase Squirrel Cage and Motor 380V Y/Δ Connection

(XXVIII) Basic Experimental Boxes

IV. Experimental Contents of PLC Programmable Variable Frequency Speed ​​Regulation and Electrical Control Training Devices:

1. AND, OR, NOT Logic Function Experiments

2. Timer and Counter Function Experiments

3. Jump and Branch Function Experiments

4. Shift Register Experiments

5. Data Processing Function Experiments

6. Differentiation and Bit Operation Experiments

7. A/D and D/A Conversion

8. 9. Traffic Signal Light PLC Automatic Control Experiment
10. Mixer PLC Automatic Control Experiment
11. LED Digital Display PLC Automatic Control Experiment
12. Four-Story Elevator PLC Automatic Control Experiment
13. Machining Center Tool Magazine Selection Control Experiment
14. Artistic Lighting Design PLC Control Experiment
15. Motor Automatic Control Experiment
16. Stepper Motor PLC Control
17. Simulated TV Transmission Tower Experiment
18. Automatic Feeding and Loading System Control Experiment
19. Vending Machine Experiment
20. Automatic Molding Experiment
21. Water Tower Automatic Water Supply Control System Experiment
22. Automatic Mail Sorting Experiment
23. Automatic Washing Machine Control System Simulation Experiment
24. Electroplating Process Control Experiment
25. Touchscreen Basic Instruction Demonstration
26. Touchscreen LED Digital Display Control
27. Touchscreen Controlled Three-Phase Squirrel-Cage Asynchronous Motor Variable Frequency Speed ​​Regulation Experiment
28. Inverter Function Parameter Setting and Operation Experiment
29. Touchscreen Temperature PID Control
20. Experiments on Open-Loop Speed ​​Control of Three-Phase Asynchronous Motors

30. Open-Loop Speed ​​Control of Frequency Converters Based on PLC Communication

31. Closed-Loop Speed ​​Control of Frequency Converters Based on PLC Communication

32. Closed-Loop Speed ​​Control of Frequency Converters Based on PLC Analog Signals

33. Jogging Control of Three-Phase Squirrel-Cage Asynchronous Motors

34. Forward Rotation Control Circuit of Three-Phase Squirrel-Cage Asynchronous Motors with Self-Locking

35. Forward and Reverse Rotation Control of Three-Phase Squirrel-Cage Asynchronous Motors with Interlocking

36. Forward and Reverse Rotation Control of Three-Phase Squirrel-Cage Asynchronous Motors with Delay

37. Y/Δ Conversion Starting Control of Three-Phase Squirrel-Cage Asynchronous Motors

38. Contactor Control Series Resistor Starting Control Circuit

39. Delay Control Series Resistor Reduced Voltage Starting Circuit

40. Electrical Control Circuit of C620 Lathe

41. MCGS Configuration Bar Diagram Experiment Teaching

42. Dynamic Tracking Teaching Experiment Using Pre-programmed Configuration Bar Diagrams

43. Students Conduct Experiments Independently Based on Specific Requirements of Experiment Projects