Author Archives: Nguyen Son

OPC_UA SERVER for PC WORX-based Controllers

From |
Leave a reply

Dynamic market changes make it necessary to solve automation tasks in line with Industry 4.0. The objective is always to produce more efficiently and intelligently. Uniform protocols, rules, and standards for communication are required to intelligently link machines and system components.

In the past, it was a very challenging task for any engineer to setup, access or share OPC classic remotely in a network but that has changed now, with Phoenix Contact’s OPC_UA Server.

The PC WORX UA SERVER from Phoenix Contact enables you to access all variables of PC WORX programmable controllers via the OPC_UA (Unified Architecture) standardized communication protocol.

Fig 1: System architecture with OPC_UA

Fig 1: System architecture with OPC_UA

Why you should switch to OPC_UA

The OPC Unified Architecture Standard, OPC_UA, is being adopted more widely across the market as the new market standard and provides the basis for open and standardized communication in the digital future.

OPC_UA Server capability:

  • Handle up to 200 controllers in a visualization or production control system
  • Variables are mapped via the standardized PLCopen profile
  • The OPC_UA server uses the binary protocol for communication, resulting in high data transmission speeds
  • A security concept based on certificates protects against unauthorized access
  • Status & Quality of connection for each individual items
Fig 2: OPC_UA VS OPC Classic

Fig 2: OPC_UA VS OPC Classic

In the end, the key feature that makes OPC_UA server the backbone for any IIOT system that uses PLCopen profile would be the fact that it allows customers to build extremely fast web/cloud base visualization even without a need to pay additional costs for licensing.

Fig 3 & Fig 4: Web/Cloud Visualization of data from monitoring a mini solar cell via OPC_UA

Choosing the Right Signal Conditioner

From |
Leave a reply

Basic 4-20mA current loopSensors and other devices with 4-20mA current loop output are very popular in industrial fields. We can find them from Process Control to data logging systems. A basic current loop has parts as stated below:

  • Sensor: a device which draws current from its power source in direct proportion to the value it measures (level, pressure, etc.).
  • Power source: supplies DC power to sensors or any device in the loop.
  • Reading devices: a PLC, a controller or data logger which reads the current value provided from the sensor and uses it for the next step of controlling or data logging.

In order to isolate, convert, filter and amplify or duplicate control signals we use signal conditioners. Signal conditioner makes a simple 4-20mA current loop into a field loop and control loop like below:

The devices in both the field loop and the control loop need to be powered. They can be powered by a DC Auxiliary power supply or by another active device in the loop. That being said, we have many types of Signal Conditioners (According to how it is powered or can it supply power for other device) that can be used in this scenario.

Types of sensors

The most common 4-20mA sensors in industrial fields are 4-wires sensors and 2-wire sensors. The difference lies in how they powered.

A 4-wire sensor is an active device which has a separate power supply for itself (from DC or AC power supply).

4-wire sensor

4-wire sensor

On the other hand, a 2-wire sensor is a passive device which draws power from a DC auxiliary power supply in the loop or from other active devices in the loop (like a repeater power supply signal conditioner)

2-wire sensor

2-wire sensor

Types of 4-20mA Signal Conditioners:

  • Passive Signal Conditioner: A passive signal conditioner doesn’t need a separate power supply for itself. It draws power from the field loop or control loop. This means there are 2 types: one powered by a field loop and one powered by a control loop. As passive signal conditioners can cause a drop in voltage in the loop, if there are too many passive devices in loop it could lead to inaccuracies in the measured values. In the picture below is a field loop powered signal conditioner with 2-wire sensor, where the devices in the field loop are powered by an auxiliary power supply.

  • Active Signal Conditioner: This type of signal conditioner is powered by a separate power supply so it doesn’t cause voltage drops in the loop. It can also provide power for the control loop. For example, an active mini MCR Pro signal conditioner can drive up to a 600 Ohm load in a control loop. The field loop still needs an auxiliary power supply when using a 2-wire sensor. Pictured below is an active signal conditioner and 4-wire sensor. In the control loop is a passive analog input controller.

  • Repeater Power Supply Isolator: This type of signal conditioner is powered by a separate power supply and it can supply power for the sensor’s loop and also for the control loop (with a maximum load of 600 Ohms). It can be used for 2, 3 or 4-wire sensor without the need of a power supply for the field loop.

So depending on the type of application, we can choose the right 4-20mA signal conditioner. Based on information about the type of sensor, whether the field loop has an auxiliary power supply as well as if the control loop has a passive or active controller, we can choose the suitable 4-20mA signal conditioner.

If you have any questions, feel free to contact us!

ReSy 104 : Upgrading Control Systems in Power Industry

From |
Leave a reply

Nowadays, in the age of Smart Grids, power systems are getting more complicated in order monitor and avoid system down time. End users /operators require the ability to control everything from big substations to small hangover substations; even to each MV cabinet or recloser located in remote areas such as at a consumer site or along power lines.
So do you meet these requirement within a  reasonable cost especially in existing substations, MV cabinets where installation space is very limited.

Solution with ReSy 104 + PLC

The ReSy 104 remote control communication library is based on the IEC 60870-5-104 protocol.

The remote control system enables communication between the control center and substation via a standard TCP/IP network. You can also use transmission via DSL, SHDSL, GPRS, EDGE, and 3G.

With PLC for Fieldbuses and Ethernet, Phoenix Contact offers a flexible system structure that covers a wide range of application options in a centralized or distributed format. Thanks to a compact design and numerous supported protocols, Phoenix Contact PLC is ideal for applications where compact size and high-quality is required at a competitive price.

How Phoneix Contact's ReSy 104 RTU works.

Fig 1 : How Phoneix Contact’s 104 RTU works.

By combining ReSy 60870-5-104 + PLC Phoenix contact can offer possible applications for

  • IEC 60870-5-104 enables data transmission via a standard network, which can communicate with multiple devices and services simultaneously.
  • Full function PLC with able to communicate with field device via numerous built in protocol such as Modbus , Profibus, Profinet, etc…
  • High standard of security and encryption for reliable data transmission with the FL MGUARD series of security devices from Phoenix Contact
  • Smooth communication between devices from various manufacturers. The supplied interoperability list states which functions are supported.
  • The remote control station can be connected redundantly to two or more higher-level control systems or remote control heads via the ReSy+ library
  • Acquisition of basic data types, such as messages, commands, plus counter values with and without time stamp.
  • Event-oriented communication ensures the active transmission of current events.
  • Historical data backup ensures that data is logged with a time stamp.
ReSy Solution

Fig 2 : Possible solution with ReSy 104 + PLC

To find out more about our ReSy 104 solutions, just leave us your contact and we will get in touch with you shortly.