Description
2351 Safety Instrumented System (SIS)
2351 Safety Instrumented System (SIS)
Module Clips Drive controller servo motor
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Application of IO Link in Industrial Automation
This article mainly introduces the overall solution of ST IO Link communication master station used in industrial systems, including the following 5 aspects:
Firstly, the application of IO Link in industrial automation; The second is the introduction of ST IO Link main station transceiver; The third is the introduction of our ST”s IO Link main site evaluation board; The fourth is an introduction to the reference design scheme of the IO Link main station; The fifth is a demonstration of the IO Link master station reference design.
The industrial automation system can be said to be composed of many levels. The top level is usually industrial Ethernet to transmit data to the upper control center or monitoring center of the factory, while the middle layer is usually some PLC system for specialized process processing, such as controlling a specialized assembly line or production line. At the bottom, there are usually many industrial sensors, such as temperature sensors, pressure sensors, flow sensors, or proximity sensors, as well as some actuators, such as valves, moving lights, relays, or contactors, which are used for collecting and controlling physical quantities.
Between these levels, there will also be some modules or gateways for conversion and processing work. Therefore, in traditional industrial systems, there are many different level standards and communication protocols on site, resulting in poor modularity and versatility. Because there are both analog signals on site, such as a 4 to 20 mA current loop and analog voltage signals, as well as digital signals. In such an environment, analog signals are particularly susceptible to interference from harsh on-site environments. At the same time, sensors or actuators for analog transmission cannot perform on-site remote configuration or calibration 2351 Safety Instrumented System (SIS) diagnosis work. In order to solve the transmission of the last segment of data to sensors and actuators in industrial field environments, as described earlier, we have introduced a specialized digital interface IO Link to achieve fully digital transmission between the interface modules of sensors and industrial field buses. The bidirectional data transmission makes it possible to parameterize the interaction of on-site data, diagnose and transmit information. By using this technology, remote condition monitoring and predictable maintenance of terminal equipment can be achieved, thereby effectively alleviating the problem of production line downtime.
Its advantages include:2351 Safety Instrumented System (SIS)
Firstly, whether it is a pure digital sensor, an analog sensor after digital quantization, or different types of actuators, unified access can be achieved, thus achieving a simplified and standardized system architecture. Secondly, the transmission of digital signals will have stronger anti-interference ability than the transmission of analog signals, so the reliability of the system will also be stronger. Thirdly, through the bidirectional transmission of digital signals, more intelligent and advanced actuators or sensors can be used, making it easier to achieve status monitoring and system diagnostic protection functions. In this way, any issues and status of the production line can be monitored and maintained in real-time, ensuring the reliability, maintainability, and upgradability of the entire production line, thereby ensuring the minimum downtime.
The following is the specific content about IO Link technology
Firstly, the definition of the IO LINK standard enables data transmission, processing, configuration, and diagnostic information exchange between sensors or actuators and control systems. Secondly, this is a simple peer-to-peer communication architecture, where a master port is connected to a device port. Then, it can achieve compatibility with existing communication architectures, such as reusing cables and interfaces. At the same time, the IO Link system also has backward compatibility upgrade capability, as the master end of the system uses digital binary serial communication to interact with devices, and vice versa.
It can be said that IO link makes the system simpler:
Firstly, this is a universal standard communication method that complies with IEC61131-9. Secondly, IO Link is an intelligent communication system that solves the digital information exchange and transmission of the last distance from the control host to the terminal device. Thirdly, IO Link is simple to use and can be said to be plug and play, compatible with some existing system devices.
Some related products and solutions provided by ST in IO Link communication solutions
Firstly, in this communication system, the IO Link Master, which connects to the upper computer controller, is one of the main key solutions that will be mentioned later. Secondly, ST can provide some communication chips on the IO Link Master project, such as L6360. On the other side of the sensor or actuator end, namely the IO Link Slave end, ST can provide communication chips L6362A and L6364 on this IO Link Slave slave project. According to standards, this three-wire point-to-point communication method is easily compatible with some existing sensor actuators” standard ports, such as M12 standard industrial connectors and M12 standard connector wires. In addition, its advantages include the ability to achieve point-to-point bidirectional signal transmission within a single cable, as well as the general power supply requirements of the master end to the sensor actuator. According to the general requirements of the current industry, the maximum length of this cable is 20 meters, and the three wires inside are 24V, 0V, and data cables. The L+of this chip can support up to 500 milliamperes. If greater current is needed, there are also other L+drivers, including Load Switch IPS and other products, which can provide greater current or can be applied externally. The IO Link communication speed can generally reach a baud rate of 230.4K per COM3, and it also has functions such as status indication and detection.
For some specific application characteristics of IO Link, the communication transceiver system composed of L6360 and L6362A can support three standard data types of IO Link, namely COM1 (4.8k), COM2 (38.4K), and COM3 (230.4K) modes. This communication system can meet the requirements of all modern standards, industrial sensors, and actuators: firstly, it can quickly and very easily configure or reconfigure sensors or actuators. Secondly, it can be widely applied to various standardized sensors or systems that execute information. Thirdly, as a digital communication system, compared to traditional analog signal transmission systems, it can reduce power consumption and improve system efficiency. Fourthly, it has complete diagnostic and protection functions, which can improve the reliability of related systems. Therefore, it can be widely used to drive various digital sensors and actuators, as well as input and output modules of PLC, in order to achieve and meet various requirements of Industry 4.0.
How to Determine the Interference Problem of PROFINET IO Communication
Preliminary Diagnosis of PROFINET Interference Problems
1. Overview
When debugging PROFINET IO communication, it is common to encounter communication failures. One of the reasons for communication failures is interference. PROFINET IO communication equipment often operates in complex industrial electromagnetic environments, and incorrect shielding grounding or non-standard installation may lead to communication interference problems. Since optical signals are not affected by electromagnetic interference, this article only introduces interference problems with electrical signals.
2. How to determine interference issues
If PROFINET IO communication is affected by electromagnetic interference, a simple judgment can generally be made through the following aspects:
2.1. Judging the communication status through PROFINET IO
If the following communication phenomena are found during PROFINET IO communication debugging or operation, it may be affected by electromagnetic interference:
① Occasionally, communication is interrupted and restored.
② When certain on-site devices or specific operations are turned on, communication is interrupted, and on the contrary, communication returns to normal.
2.2. By using STEP7 online diagnostic information to determine and view the diagnostic buffer information of the IO controller, how to detect the presence of frequent communication failures and recovery information between the IO controller and IO devices in the diagnostic buffer, as shown in the following figure, may be affected by electromagnetic interference:
14 STEP7 Device Diagnostic Buffer Information
3. How to troubleshoot and solve interference problems
If a suspected electromagnetic interference causing PROFINET IO communication failure is found, how should we troubleshoot and solve it? The following will be introduced from the following aspects:
3.1 Increase PROFINET IO communication watchdog time
Due to PROFINET IO communication failure occurring during watchdog time, the IO controller did not provide input or output data (IO data) to the IO device, and watchdog time=the number of update cycles allowed for IO data loss × The refresh time is usually automatically calculated and allocated by the IO controller. This time value is generally small. If electromagnetic interference is encountered, the probability of communication failure occurring within the automatically calculated watchdog time will increase. At this time, we can appropriately increase the PROFINET IO communication refresh time or the number of update cycles allowed for IO data loss to increase the watchdog time. However, this method may not solve serious electromagnetic interference problems, and it is recommended to eliminate and solve them through subsequent methods.
TRICONEX 3805E Invensys can accommodate the backplane of previous modules
TRICONEX 3805E Invensys can accommodate the backplane of previous modules
Fault tolerance in the TRICONEX 3805E is achieved through the the third mock examination redundancy (TMR) architecture. Tricon can provide error free and uninterrupted control in the event of hard faults or internal or external transient faults in components. Tricon adopts a completely triple architecture design, from the input module to the main processor and then to the output module. Each I/O module contains three independent branch circuits. Each pin on the input module reads process data and passes this information to their respective main processors. The three main processors communicate with each other using a proprietary high-speed bus system called TriBus. Every scan, the three main processors synchronize and communicate with their two neighbors through TriBus. Tricon votes on digital input data, compares output data, and sends copies of analog input data to each main processor. The main processor executes user written applications and sends the output generated by the application to the output module. In addition to voting on input data, TriBus also votes on output data. This is done on the output module as close to the field as possible to detect and compensate for any errors between the Tricon voting and the final output driven to the field.
The TRICONEX 3805E system typically consists of the following typical modules: [2]
Main processor modules (three).2351 Safety Instrumented System (SIS)
Communication module.
Input and output modules: can be analog and/or digital, can work independently, or can be hot backup (backup).
Power module (redundant).2351 Safety Instrumented System (SIS)
A backplane (chassis) that can accommodate previous modules.
System cabinet: One or more chassis can be compressed into one cabinet.
Organize cabinets to adapt and standardize interface connections between on-site instruments and Triconex system cabinets.
Human Machine Interface (HMI) for monitoring events.
Engineering Workstation (EWS) for programming. Monitoring, troubleshooting, and updating.
The remote IO module is designed according to the demanding industrial application environment requirements, embedded with a 32-bit high-performance microprocessor MCU, to meet various combinations of digital, analog, and thermal resistance IO modules. The communication protocol of the remote IO module adopts the standard Modbus TCP protocol, Modbus RTU over TCP protocol, and MQTT protocol. The remote IO module supports a wide working voltage of DC9-36V and has anti reverse protection function. It is equipped with a built-in watchdog and comprehensive lightning protection and anti-interference measures to ensure reliability.
The remote IO module supports 1 isolated 10/100M adaptive Ethernet interface with 15KV ESD protection, optocoupler isolated digital input, and supports dry wet contact input. The first channel can be used as pulse counting, supporting high-speed pulse and low-speed pulse modes. The default is high-speed pulse frequency with a maximum of 700KHz, and the optional low-speed pulse frequency with a maximum of 10KHz; DO output supports transistor Sink output, with the first channel available for high-speed pulse output, supporting pulse frequencies of 10Hz~300KHz; The remote IO module supports isolated 12 bit resolution analog input: 0-5V, 0-10V, 0-20mA, 4-20mA differential input; 1 channel RS485 communication interface, supporting standard Modbus RTU protocol for expansion; The thermal resistance RTD input supports two types: PT100 and PT1000;
What are the common types of IO extension modules? How much does an IO expansion module usually cost?
2. Analog Input Output Module: A module used to process and monitor analog signal input and output. Common analog input and output modules include modules based on resistors, transistors, and optocouplers.
3. Communication Interface Module: A module used to achieve communication between devices. Common communication interface modules include modules based on interfaces such as RS232, RS485, Ethernet, and CAN.
4. Special Function Module: A module used to implement specific functions. For example, the PWM (Pulse Width Modulation) module is used to control the speed and direction of the motor, and the counting module is used to achieve counting functions.
The price of IO expansion modules may vary depending on different brands, models, and functions.
Generally speaking, the price of more basic IO expansion modules ranges from tens to hundreds of yuan, while the price of IO expansion modules with more complex functions and stronger performance may be higher.
For example, the Io extension module ET1010 recently released by Zongheng Intelligent Control Company costs only 169 yuan per unit, and supports functions such as front-end and back-end cascading, sensorless expansion, and plug and play. It can be purchased in bulk or applied for a free trial address; The specific prices of these IO modules need to be queried and compared based on the specific modules you need.
What is the function of an IO chip
Io generally refers to input and output devices, where I is the input and O is the output. The input to the IO port of the chip is the external signal transmission to the chip, while the output is the internal signal transmission to other devices. The input and output are relative. In short, in a broad sense, the control of input and output interfaces is called an IO chip, and network cards are also considered IO or array cards.
The CPU must read and write data to external registers or ROMs on RAM or other hardware through IO commands (such as input/output commands). For example, reading a keyboard involves accessing external registers on the keyboard through the 60H port, and the chip on the keyboard scans the keyboard. Pressing or holding down a key for a long time will cause the chip to generate corresponding scan or break codes, which will be written to the external register of the 60H port, so that the CPU can achieve the purpose of controlling the keyboard. Therefore, I think IO chips should refer to a large category. The CPU already has powerful IO instructions and corresponding control buses.
51 microcontroller IO port input and output mode_ Four usage methods for IO ports
The traditional 51 microcontroller IO interface can only be used as a standard bidirectional IO interface. If it is used to drive LED, it can only be driven by injecting current or using a transistor external expansion drive circuit.
Current injection method: LED positive pole connected to VCC, negative pole connected to IO port. If the IO is at a high level, the two poles of the LED are at the same level, and there is no current, the LED will turn off; IO is at low power level, current flows from VCC to IO, and LED lights up. But when you connect the positive pole of the LED to the IO interface and the negative pole to GND, placing the IO interface at a high level will cause the LED to light up. However, due to the insufficient pull-up capability of the IO interface, the brightness is not ideal. The following method can be used to solve this problem.
Push-pull working mode: The positive and negative poles of the LED are connected to two IO ports, and then the positive IO interface is set as the push-pull output, while the negative IO interface is set as the standard bidirectional current input. The push pull method has strong pull-up ability and can achieve high-level LED driving.
Four usage methods for IO ports2351 Safety Instrumented System (SIS)
From the perspective of the characteristics of the I/O port, the P0 port of Standard 51 is an open drain structure when used as an I/O port, and in practical applications, a pull-up resistor is usually added; P1, P2, and P3 are all quasi bidirectional I/Os with internal pull-up resistors, which can be used as both input and output. The I/O port characteristics of the LPC900 series microcontroller have certain differences, and they can be configured into four different working modes: quasi bidirectional I/O, push pull output, high resistance input, and open drain.
Compared with Standard 51, the quasi bidirectional I/O mode differs in internal structure but is similar in usage. For example, when used as an input, it must first write “1” to set it to high level before reading the level state of the pin.!!!!! Why is it like this? Please refer to the diagram below for analysis.
The characteristic of push-2351 Safety Instrumented System (SIS)pull output is that it can drive a large current regardless of whether it outputs high or low levels. For example, when outputting high levels, it can directly light up the LED (by connecting several hundred ohm current limiting resistors in series), which is difficult to achieve in quasi bidirectional I/O mode.
The characteristic of high impedance input mode is that it can only be used as an input, but it can obtain relatively high input impedance, which is necessary in analog comparator and ADC applications.
The open drain mode is similar to the quasi bidirectional mode, but there is no internal pull-up resistance. The advantage of open drain mode is good electrical compatibility. If the external pull-up resistor is connected to a 3V power supply, it can interface with a 3V logic device. If the pull-up resistor is connected to a 5V power supply, it can also interface with a 5V logic device. In addition, the open drain mode can also conveniently implement the “line and” logic function.
For the explanation of the above question, there is this information:
High resistance state is a common term in digital circuits, referring to an output state of a circuit that is neither high nor low. If the high resistance state is input into the next level circuit, it has no impact on the lower level circuit, just like not connected. If measured with a multimeter, it may be high or low, depending on what is connected afterwards.
High resistance states can be understood as open circuits during circuit analysis. You can think of it as having a very high output (input) resistance. His limit can be considered suspended.
Typical applications of high resistance states:
1. On the bus connected structure. There are multiple devices hanging on the bus, and the devices are connected to the bus in a high impedance form. This automatically releases the bus when the device does not occupy it, making it easier for other devices to gain access to the bus.
2. Most microcontroller I/O can be set to high impedance input when used, such as Lingyang, AVR, and so on. High resistance input can be considered as having infinite input resistance, indicating that I/O has minimal impact on the preceding stage and does not generate current (without attenuation), and to some extent, it also increases the chip”s resistance to voltage surges.
Ethernet IO module assists industrial robots
Industrial robots are multi joint robotic arms or multi degree of freedom machine devices aimed at the industrial field, which can achieve many material distribution, retrieval, pallets, and so on in industrial sites. However, due to the fact that many industrial six axes are equipped with 32 IO ports as standard, the IO ports are not sufficient in practical applications. Therefore, some DIN and DO extensions can be met through IO modules.
MQTT Ethernet IO Remote Module2351 Safety Instrumented System (SIS)
The Modbus TCP Ethernet IO module has multiple channels, such as 4-way, 8-way, and 16-way switch input and output options. The communication protocol of the Ethernet IO module adopts the standard Modbus TCP protocol, Modbus RTU over TCP protocol, and MQTT protocol. Can support LAN configuration, with 1 DC power output to other devices on site, reducing the difficulty and cost of on-site wiring.
Most of the MQTT Ethernet IO modules should collect some IO port information and transmit data through the network port. In fact, the Ethernet IO module can not only serve as a TCP server, but also as a TCP client. In addition, it can not only count high-speed pulses but also output high-2351 Safety Instrumented System (SIS)speed pulses. This is very convenient for doing some control processing on industrial sites, such as controlling servo motors and other scenarios! The most important thing is the data caching function. Even if the network is disconnected, it is not afraid. The data will be automatically cached, and after the network is restored, it will be automatically retransmitted.
The MxxxT industrial remote Ethernet I/O data acquisition module is embedded with a 32-bit high-performance microprocessor MCU, and integrates an industrial grade 10/100M adaptive Ethernet interface to support the standard Modbus protocol. It can easily integrate with third-party SCADA software, PLC, and HMI devices for application. Equipped with an RS485 interface, it has good scalability and can be cascaded with standard Modbus RTU I/O devices through the RS485 bus to achieve the combination of various digital, analog, and thermal resistance IO modules, saving costs. At the same time, this device has the function of cluster register mapping, and the data of the cluster is automatically collected into the mapping storage area of the local computer. The upper computer can respond quickly without waiting when querying, meeting the strict and timely functional requirements of industrial sites.
What is a remote IO module and what are its purposes
Technology is constantly evolving, and we can come into contact with various electronic devices both in daily life and in the workplace. And a large number of electronic devices work together to generate some signal sources. In order to better transmit and collect signals, industrial control products such as remote IO modules, signal transmitters, and signal acquisition modules have been developed.
In the past, people had to connect existing lines and boxes one at a time, which greatly increased the cost and construction time of cables. Moreover, if the distance was too long, they also had to face issues such as voltage attenuation. And through the remote IO module, this problem can be effectively solved.
If your cabinet is 200 meters away from the site and remote IO is not used, then you can extend each signal line by 200 meters and install the remote IO module on site, which can save you a lot of cable costs and reduce the complexity of construction.
In short, sometimes some IOs are set far away from the central control room and then connected back to the central control room through fiber optics to save on cable procurement and construction. Sometimes, the logical “remote” is because the allowed quantity of “local IO” cannot meet the actual needs, so it is necessary to connect to the “remote IO template”, which depends on the situation.
In addition, the general cabinet is placed on the equipment site. However, some control signals, such as emergency stop and bypass, are implemented in the control room, so remote IO modules need to be used to transmit these signals to the control system in the computer room.
What is an Ethernet IO module and what are its functions
The Ethernet IO module is a hardware gateway that adds IO to the network port.
The Ethernet IO module has hardware interfaces such as switches, analog signals, relays, RS485, RJ45, etc. Can be used for IO data collection network port transmission in industrial automation. Simply put, it refers to sensors with standard signals on site, or serial devices with 485 signals such as PLCs, which can be converted into real values through such gateways and then transmitted to the host for display through network ports.
1. Collect and control data for internal processing and transmit it to the external network through Ethernet
2. Support 4-way photoelectric isolation switch input
3. Supports 4 independent relay control outputs
4. Supports 8 analog inputs, 4-20mA or 0-5V/0-10V/0-30V (optional)
5. Support RS485 serial port data collection, with serial port server function
6. Supports Modbus RTU communication protocol and virtual serial port
7. Supports docking with various configuration software and TCP/UDP servers
1.Has been engaged in industrial control industry for a long time, with a large number of inventories.
2.Industry leading, price advantage, quality assurance
3.Diversified models and products, and all kinds of rare and discontinued products
4.15 days free replacement for quality problems
ABB — AC 800M controller, Bailey, PM866 controller, IGCT silicon controlled 5SHY 3BHB01 3BHE00 3HNA00 DSQC series
BENTLY — 3500 system/proximitor, front and rear card, sensor, probe, cable 3500/20 3500/61 3500/05-01-02-00-001 3500/40M 176449-01 3500/22M 138607-01
Emerson — modbus card, power panel, controller, power supply, base, power module, switch 1C31,5X00, CE400, A6500-UM, SE3008,1B300,1X00,
EPRO — PR6423 PR6424 PR6425 PR6426 PR9376 PR9268 Data acquisition module, probe, speed sensor, vibration sensor
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NI — SCXI-1100 PCI – PXIE – PCIE – SBRIO – CFP-AO-210 USB-6525 Information Acquisition Card, PXI Module, Card
Westinghouse — RTD thermal resistance input module, AI/AO/DI/DO module, power module, control module, base module
Woodward — 9907-164 5466-258 8200-1300 9907-149 9907-838 EASYGEN-3500-5/P2 8440-2145 Regulator, module, controller, governor
YOKOGAWA – Servo module, control cabinet node unit
Main products:
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