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Programmable Logic Controllers
part#
description
manufacturer
1173450
Fan module for the AXC F 3152
customer-131
Quick Quote
2702171
Safety-related digital output module, IP20 protection, for the SafetyBridge system. The module has four safe digital outputs with two-channel occupancy or 8 safe digital outputs with single-channel occupancy
customer-131
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1088134
Axioline Smart Elements, Slot cover, Diagnostic function, degree of protection: IP20
customer-131
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1182185
Axioline Smart Elements, Position detection module, Incremental encoder input: 1, Asymmetrical encoder, Digital inputs: 2, 24 V DC, degree of protection: IP20
customer-131
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2400127
Connecting cable, for connecting the controller to a PC (RS-232) for PC WORX with flow control, 3 m in length
customer-131
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2403730
Program and configuration memory for extending the internal flash memory, plug-in, 2 GB, with license key and application program for the simple web-based configuration and commissioning of a SafetyBridge solution, including communication via Modbus/TCP,
customer-131
Quick Quote
2403298
Program and configuration memory, plug-in, 2 GB, with license key and application program for easy web-based configuration and startup of a SafetyBridge solution including communication via Modbus/TCP, PROFINET, and e-mail.
customer-131
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2701872
Two of these SD cards, with two ILC 131 ETHs and the individually required input and output terminals, form a multiplexer system that requires no programming. Easy configuration via a small number of wire jumpers. Wireless, Ethernet cable or network conne
customer-131
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2701523
Axioline E, Digital I/O device, EtherCAT®, M12 fast connection technology, Digital inputs: 8, 24 V DC, connection method: 4-conductor, Digital outputs: 4, 24 V DC, 2 A, connection method: 3-conductor, Plastic housing, degree of protection: IP65/IP67
customer-131
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2701531
Axioline E-EtherCAT® device in a metal housing with 8 IO-Link ports and 4 digital inputs, 24 V DC, M12 fast connection technology
customer-131
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2701490
Axioline E, Digital I/O device, EtherNet/IP™, M12 fast connection technology, Digital inputs: 8, 24 V DC, connection method: 4-conductor, Digital outputs: 4, 24 V DC, 2 A, connection method: 3-conductor, Metal housing, degree of protection: IP65/IP67
customer-131
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2701489
Axioline E, Digital I/O device, EtherNet/IP™, M12 fast connection technology, Digital inputs: 16, 24 V DC, connection method: 4-conductor, Digital outputs: 16, 24 V DC, 500 mA, connection method: 3-conductor, Metal housing, degree of protection: IP65/IP67
customer-131
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2701493
Axioline E, Digital input device, EtherNet/IP™, M12 fast connection technology, Digital inputs: 16, 24 V DC, connection method: 4-conductor, Plastic housing, degree of protection: IP65/IP67
customer-131
Quick Quote
2861580
Inline, Bus coupler, INTERBUS, Inline shield connector, transmission speed in the local bus: 500 kbps, degree of protection: IP20, including Inline connectors and marking fields
customer-131
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2731584
Digital input device for INTERBUS; fiber optic technology with 2 Mbaud, 16 inputs (24 V DC), sensor connection via 5-pos. M12 female connectors, rugged metal housing, IP67 protection
customer-131
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2731034
Digital output device for INTERBUS; fiber optic technology with 500 kbaud, 8 outputs (24 V DC, 2 A), actuator connection via 5-pos. M12 female connectors, rugged metal housing, IP67 protection
customer-131
Quick Quote
2753504
INTERBUS-ST bus terminal module, 24 V DC, 9-pos., D-SUB with additional remote bus stub line, 9-pos. D-SUB, IP20 protection, consisting of: Terminal part with screw connection and module electronics
customer-131
Quick Quote
2701150
Inline XC, Bus coupler, INTERBUS, Inline shield connector, Extreme conditions version, transmission speed in the local bus: 500 kbps, degree of protection: IP20, including Inline connectors and marking fields
customer-131
Quick Quote
2750743
INTERBUS-ST bus terminal module, 24 V DC, 9-pos., D-SUB plug, IP20 protection, consisting of: Terminal part with spring-cage connection and module electronics
customer-131
Quick Quote
2861218
Inline, Bus coupler, INTERBUS, F-SMA connector, transmission speed in the local bus: 500 kbps, degree of protection: IP20, including Inline connector and labeling field
customer-131
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Programmable Logic Controllers
General Guide & Overview
Programmable Logic Controllers (PLCs) are digital computers used in industrial organizations to control computer systems. They monitor inputs and make decisions about related outputs, making them an essential component in predictive maintenance systems. PLCs have a rich history, with the first one being developed by Dick Morley in 1968. Over the years, PLC technology has evolved, from physical relays and timers to PC-based software.
PLCs can be classified into different types, such as PLCs, PACs, SCADA, DCS, and DDC, each serving specific automation needs. They consist of key components, including inputs, outputs, CPUs, communications, and HMIs. PLCs operate through a scan cycle, continuously monitoring inputs, executing control programs, and controlling outputs.
Different programming languages, such as ladder logic, structured text, instruction list, function block diagram, and sequential function chart, are used to program PLCs. Compact and modular PLCs offer flexibility and scalability. PLC maintenance is essential for optimal performance, with tasks such as cleaning dust, replacing modules, and checking connections.
Types and Components of PLCs
Programmable Logic Controllers (PLCs) come in various types, each designed to meet specific automation needs. Two main types of PLCs are compact PLCs and modular PLCs. Compact PLCs are integrated single-unit systems with the processor, power supply, and I/O modules all housed together. They are ideal for smaller applications due to their smaller physical footprint. On the other hand, modular PLCs offer flexibility and scalability, allowing for easier system expansion. They are often preferred by larger or growing companies that require more extensive control.
A PLC consists of several critical components that work together to perform its function. These components include inputs, outputs, CPUs, and communication capabilities. Inputs are connected to sensors and devices to gather data and information. The gathered data is then processed by the CPU, the brain of the PLC, which evaluates and makes decisions based on the input. The output devices, connected to outputs, control various components such as valves and motors to execute the desired actions.
PLCs also have communication capabilities, enabling integration with other devices and systems in the industrial environment. This ensures seamless coordination and interaction between different elements of the automation system. PLCs are an essential part of automation systems, providing reliable control and efficient operation across various industries.
PLC Maintenance Best Practices
Proper PLC maintenance is crucial for ensuring optimal performance and minimizing breakdowns. By following a comprehensive PLC maintenance checklist, you can keep your system running smoothly and prevent costly downtime.
Here are some important PLC maintenance tasks:
Cleaning dust from input and output devices to prevent signal interference and component failure.
Changing filters regularly to control dust accumulation and maintain proper ventilation within the PLC system.
Inspecting connections for secureness to avoid loose connections that can disrupt communication and reduce reliability.
Replacing worn-out modules to prevent malfunctions and ensure accurate processing of data and commands.
Increasing awareness of unusual activity by monitoring error logs and system performance to identify potential issues before they escalate.
Backing up PLC data regularly to protect against data loss in the event of a system failure or unexpected event.
Monitoring environmental conditions such as temperature and humidity to ensure they are within the specified operating range.
Calibrating devices periodically to maintain accurate measurements and prevent deviations that can impact system performance.
Conducting visual inspections of the PLC system to identify any physical damage, loose connections, or signs of wear and tear.
Checking LED lights for proper functionality, as they provide valuable diagnostic information.
Inspecting sensors to ensure they are clean, properly aligned, and functioning correctly, as they are critical for accurate data acquisition.
Addressing electromagnetic interference by keeping sensitive components and wiring away from sources of electromagnetic radiation.
Reviewing the proximity of equipment to identify potential interference and ensure proper positioning for efficient operation.
Keeping the PLC system up to date with recalls and upgrades to benefit from the latest software patches, enhancements, and security updates.
The frequency of maintenance tasks may vary depending on factors such as the surrounding environment, machine usage, and available maintenance staff capacity. It is recommended to perform daily tasks such as dusting and tidying, while more specific tasks can be scheduled at regular intervals or based on manufacturer recommendations.
FAQ
What is a programmable logic controller (PLC)?
A programmable logic controller (PLC) is a digital computer used in industrial organizations to control computer systems. It monitors inputs and makes decisions about related outputs, making it an essential component in predictive maintenance systems.
Who invented the first PLC?
The first PLC was developed by Dick Morley in 1968.
How do PLCs work?
PLCs operate through a scan cycle, continuously monitoring inputs, executing control programs, and controlling outputs.
What are the different types of PLCs?
PLCs can be classified into types such as PLCs, PACs, SCADA, DCS, and DDC, each serving specific automation needs.
What are the key components of a PLC?
The key components of a PLC include inputs, outputs, CPUs, communications, and HMIs.
What programming languages are used for PLCs?
Different programming languages, such as ladder logic, structured text, instruction list, function block diagram, and sequential function chart, are used to program PLCs.
What are the advantages of PLCs?
PLCs offer advantages such as flexibility, scalability, easy expansion, integration with other devices and systems, and improved processing speeds.
Where are PLCs used?
PLCs are used in various industries, including manufacturing, automation, oil and gas, energy, and transportation.
How important is PLC maintenance?
PLC maintenance is crucial for ensuring optimal performance and avoiding breakdowns. Regular tasks include cleaning dust, replacing modules, and checking connections.