The document discusses an energy management solution that includes smart power meters, a power meter concentrator, and software. The power meter concentrator collects power data from smart power meters via RS-485 or Ethernet. It stores the data locally, calculates statistics, and sends the data to software. The solution allows users to remotely monitor energy usage, set demand management rules, and integrate with SCADA systems for control.
This document provides details about Anurag Kumar's summer training project on SCADA/DMS systems at PESU in Patna, Bihar, India. It includes an acknowledgments section thanking those who supported the project. The objectives are to understand the SCADA/DMS system installed at PESU, visit the IGIMS power substation, and study the master billing and customer care systems. The document then provides overview sections on SCADA, DMS, remote terminal units, networking systems, and the human-machine interface. Specific components of the SCADA/DMS package at PESU are also described.
SCADA (Supervisory Control and Data Acquisition) systems are used to monitor and control industrial processes. The document discusses the history and components of SCADA, including how it collects data from sensors using RTUs (Remote Terminal Units) and sends control signals. It also describes how SCADA is important for maintaining efficiency in power plants by remotely monitoring operations and reducing maintenance costs. SCADA plays a key role in hydroelectric power plants by integrating maintenance workstations, communicating alarm signals, and supporting future maintenance strategies through its database of equipment information.
The document discusses the current power scenario in India and the need for information technology (IT) in the power sector. It covers various IT applications used in power generation, transmission and distribution including EMS, SCADA, GIS, DMS and their benefits like loss reduction and improved monitoring. It also discusses automation of various business processes enabled by IT and its future potential to improve grid efficiency.
SCADA at the core of power systems monitoring and control
Power systems monitoring requires increasing amounts of information coming from multiples sources, manually or automatically, and at different
points in time, each with their own resolution and quality.
SCADA collects all this information in real time to:
• Process in terms of validity, usability, and accuracy and store them for future analysis.
• Combine into a flexible, simple or complex calculation.
• Provide operators and other control systems with flags and alarms, which are valuable for action and control.
• Feed advanced applications such as network security and generation dispatch.
This document provides an overview of power system automation and SCADA (Supervisory Control and Data Acquisition) systems. It defines SCADA and describes its typical components like HMIs, RTUs, PLCs and communication infrastructure. It also outlines applications of SCADA in power generation, distribution and transmission systems. Benefits of SCADA include increased efficiency, reliability and reduced manual labor through remote monitoring and control of power systems. The document concludes that SCADA provides a common framework for experiment control and ensures consistent operator experience across different parts of complex power systems.
This document provides an overview of power system automation and data acquisition systems. It discusses:
1) The role of data acquisition systems in power system automation and how they collect data from the power network using sensors and send it to programmable logic controllers and computers.
2) The key components of power system automation including electrical protection, control, measurement, monitoring, and data communication.
3) The architecture of power system automation including three levels - field equipment, protection/control equipment, and operator displays - connected by communication networks.
Power system automation refers to using instrumentation and control (I&C) devices to perform automatic decision making and control of the power system. Data is acquired from devices throughout the system and used for supervision and control by operators, engineers and automated processes. Intelligent electronic devices (IEDs) like remote terminal units, meters, and protective relays incorporate microprocessors to process and communicate data to monitor, control and protect the power system.
This document is a seminar report submitted by Dhiraj Machhindra Bhalerao to North Maharashtra University in partial fulfillment of the requirements for a Bachelor of Engineering degree in Electrical Engineering. The seminar topic is "POWER SYSTEM AUTOMATION". The report includes a certificate from the seminar guide, a declaration by the author, acknowledgements, an abstract, and multiple chapters on topics related to power system automation including literature review, components of a power system, automation, and the status of automation in India.
This document provides details about Anurag Kumar's summer training project on SCADA/DMS systems at PESU in Patna, Bihar, India. It includes an acknowledgments section thanking those who supported the project. The objectives are to understand the SCADA/DMS system installed at PESU, visit the IGIMS power substation, and study the master billing and customer care systems. The document then provides overview sections on SCADA, DMS, remote terminal units, networking systems, and the human-machine interface. Specific components of the SCADA/DMS package at PESU are also described.
SCADA (Supervisory Control and Data Acquisition) systems are used to monitor and control industrial processes. The document discusses the history and components of SCADA, including how it collects data from sensors using RTUs (Remote Terminal Units) and sends control signals. It also describes how SCADA is important for maintaining efficiency in power plants by remotely monitoring operations and reducing maintenance costs. SCADA plays a key role in hydroelectric power plants by integrating maintenance workstations, communicating alarm signals, and supporting future maintenance strategies through its database of equipment information.
The document discusses the current power scenario in India and the need for information technology (IT) in the power sector. It covers various IT applications used in power generation, transmission and distribution including EMS, SCADA, GIS, DMS and their benefits like loss reduction and improved monitoring. It also discusses automation of various business processes enabled by IT and its future potential to improve grid efficiency.
SCADA at the core of power systems monitoring and control
Power systems monitoring requires increasing amounts of information coming from multiples sources, manually or automatically, and at different
points in time, each with their own resolution and quality.
SCADA collects all this information in real time to:
• Process in terms of validity, usability, and accuracy and store them for future analysis.
• Combine into a flexible, simple or complex calculation.
• Provide operators and other control systems with flags and alarms, which are valuable for action and control.
• Feed advanced applications such as network security and generation dispatch.
This document provides an overview of power system automation and SCADA (Supervisory Control and Data Acquisition) systems. It defines SCADA and describes its typical components like HMIs, RTUs, PLCs and communication infrastructure. It also outlines applications of SCADA in power generation, distribution and transmission systems. Benefits of SCADA include increased efficiency, reliability and reduced manual labor through remote monitoring and control of power systems. The document concludes that SCADA provides a common framework for experiment control and ensures consistent operator experience across different parts of complex power systems.
This document provides an overview of power system automation and data acquisition systems. It discusses:
1) The role of data acquisition systems in power system automation and how they collect data from the power network using sensors and send it to programmable logic controllers and computers.
2) The key components of power system automation including electrical protection, control, measurement, monitoring, and data communication.
3) The architecture of power system automation including three levels - field equipment, protection/control equipment, and operator displays - connected by communication networks.
Power system automation refers to using instrumentation and control (I&C) devices to perform automatic decision making and control of the power system. Data is acquired from devices throughout the system and used for supervision and control by operators, engineers and automated processes. Intelligent electronic devices (IEDs) like remote terminal units, meters, and protective relays incorporate microprocessors to process and communicate data to monitor, control and protect the power system.
This document is a seminar report submitted by Dhiraj Machhindra Bhalerao to North Maharashtra University in partial fulfillment of the requirements for a Bachelor of Engineering degree in Electrical Engineering. The seminar topic is "POWER SYSTEM AUTOMATION". The report includes a certificate from the seminar guide, a declaration by the author, acknowledgements, an abstract, and multiple chapters on topics related to power system automation including literature review, components of a power system, automation, and the status of automation in India.
Smart energy management systems provide benefits such as energy efficiency, cost savings, load management, and power quality monitoring. They involve installing hardware like power analyzers to monitor energy usage throughout a facility. The data is visualized using software which allows users to track consumption, identify inefficiencies, set alarms, and detect power quality issues. This helps optimize energy distribution, reduce costs, and prevent production disruptions. The document discusses an implementation at a car manufacturing plant that identified power quality problems, saved on energy bills and maintenance costs, and provided a return on investment within 1.4 years.
The document discusses the Distributed Control System (DCS) at IFFCO Phulpur, located near Prayagraj, India. The IFFCO Phulpur facility produces ammonia and urea and has a production capacity of 0.824 MTPA for ammonia and 1.416 MTPA for urea, as well as other fertilizers. A DCS is a specially designed control system used to control large, complex industrial processes through distributed controllers connected by communication networks. The key components of a DCS include field devices, input/output modules, controllers located near field devices, a human-machine interface, and control engineering workstations.
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
The document describes an intelligent motor control center (MCC) system using SIMOCODE motor management and control devices. Key advantages of the intelligent MCC include sensitive motor protection, direct communication to DCS for monitoring and control, reduced commissioning time, and online monitoring of motor parameters. While the upfront cost is higher, the intelligent MCC provides benefits like reduced installation, commissioning and maintenance costs over traditional MCCs. Some initial problems during commissioning centered around communication delays and errors but were addressed through configuration and hardware changes.
Automation- Metering, Sub Station & Industrial AutomationEPC Solutions LLP
Power system automation and control is a critical means for utilities to improve reliability, efficiency, and productivity. EPC Solutions offers some of the best engineering solution in the power industry for executing the successful Substation Automation programs. With its immaculate engineering capability, backed by a team of well-qualified engineers with solid year experience, EPCS has designed wide range of protection and control panels for more than 170 Substation up to 400kV level with different bus configuration across the country. We are well versed with all make / type of Numerical functional and Auxiliary relay includes ABB, AREVA, Easun Reyrolle, GE, SIEMENS, VATECH, SEL.
>> Services:
EPC Solutions are designed to participate in our client’s business growth. By combining technology with experience we can provide successful solutions to Substation Automation.
>> System Engineering :
@ Preparing complete customer approval submittal
@ Preparing complete Manufacturing submittal
@ Preparing Switchyard Cable schedule
@ Participating in customer discussion and approval process
@ Numerical Relay Configuration
@ System functional Integration
@ Preparing system configuration diagram (SCD)
@ Micro SCADA application
@ SCD programming
@ SAS Testing
@ Application Engineering for Relay Selection
@ Relay Setting calculation
@ Factory Accept Testing
@ Site Accept Testing
@ Commissioning
-----------------------------------------------------------------
Control and Relay panels for up to 400 kV switchyard
EPCS designing a comprehensive range of control and relay panels and control desks for control, protection, alarm, indication, metering and synchronizing functions etc. for power stations, sub-stations and industrial plants of various system voltages.
@ Control and Protection panel for Feeder
@ Control and Protection panel for Line
@ Control and Protection panel for Power Transformer
@ Control and Protection panel for Generator Transformer
@ Control and Protection panel for Unit Auxiliary Transformer
@ Control and Protection panel for Station Transformer
@ Control and Protection panel for Bus coupler
@ Control and Protection panel for Bus section
@ Control and Protection panel for Transfer Bus Coupler
@ Control and Protection panel for Capacitor Bank
@ Control and Protection panel for Shunt Reactor
@ Control and Protection panel for Generator
@ Protection panel for Busbar
@ Mosaic type control panel/desk for power plant
@ Annunciation alarm panel for power plant
@ Synchronizing Panel / Trolley / Bracket
@ Tariff metering panel
@ Outdoor Marshalling kiosk
@ SCADA interfacing panel
@ RTU panel
@ Event Logger panel
@ Disturbance Recorder panel
@ Retrofit Protection Panel for feeder, transformer and generators
Power system automation involves using instrumentation and control devices to automatically control the power system. It includes substation automation which uses data from intelligent electronic devices to control power system devices from remote locations. Substations transform voltage levels and may be owned by utilities or large industrial customers. Power system automation incorporates tasks like data acquisition, supervision of system conditions, and control of devices.
SCADA - Wikipedia, the free encyclopediaRaj Bakshi
SCADA systems monitor and control industrial processes, infrastructure, and facilities. They consist of human-machine interfaces, supervisory computers, remote terminal units that connect to sensors, and communication infrastructure. While SCADA systems have evolved to incorporate standard protocols and networking, their widespread implementation and connections to other systems have introduced new security vulnerabilities that could disrupt critical infrastructure if exploited.
The aim of this project is to design and develop a system , which will help us to control the industrial processes sitting in a far of location.
Here a wireless concept of RF radio frequency (frequency Modulation technology) is used to control and monitor.
Dhiraj seminar # power system automationvision2d16
This document discusses power system automation and SCADA (Supervisory Control and Data Acquisition) systems. It describes the key components of SCADA including instrument transformers, transducers, relays, RTUs, meters, digital fault recorders, PLCs and HMIs. The advantages of power system automation are that it makes the system more efficient with less manpower and is flexible, simple and reliable. Some applications discussed are smart grids, smart meters and automatic generation control.
Mitsubishi energy measuring unit eco monitorlight_dienhathe.vnDien Ha The
Khoa Học - Kỹ Thuật & Giải Trí: http://phongvan.org
Tài Liệu Khoa Học Kỹ Thuật: http://tailieukythuat.info
Thiết bị Điện Công Nghiệp - Điện Hạ Thế: http://dienhathe.vn
The document provides information about North Delhi Power Limited (NDPL), including:
1. NDPL is a joint venture between Tata Power and the Government of Delhi that distributes power to parts of Delhi.
2. It covers an area of 510 square kilometers and supplies over 4.5 million consumers.
3. The document discusses NDPL's control centers, automation systems like SCADA, benefits of automation, and IT implementations.
The document describes the SENTRON powermanager software which provides energy management solutions that allow users to measure, analyze, store, and share energy usage and status information across their enterprise. It offers control capabilities, comprehensive reporting, and detailed energy usage data to help users reduce energy costs. The software integrates with Siemens power meters and devices to provide visibility into power flows and allow identification of opportunities to optimize energy usage and savings. It is a scalable solution that users can start with basic monitoring and later expand to an advanced enterprise-wide system.
Energy measuring unit eco monitorlight series dienhathe.vnDien Ha The
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
Điện Công Nghiệp Mitsubishi, Điện Công Nghiệp,
Điện Hạ Thế Mitsubishi, Điện Hạ Thế,
Điện Dân Dụng Mitsubishi, Điện Dân Dụng,
Mitsubishi,
Thiết Bị Đóng Cắt Mitsubishi, Thiết Bị Đóng Cắt,
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
This document discusses various components of an industrial automation and control system. It describes remote terminal units (RTUs) that collect field data and transfer it to other devices. It also explains instruments like current transformers and potential transformers that convert power signals to lower levels, as well as transducers that convert analog outputs. Additional components covered include meters, digital fault recorders, load tap changers, protective relays, and programmable logic controllers (PLCs). The document provides details on the functions of these various components that make up automation and control systems.
1. SCADA systems are used to monitor and control industrial processes through remote terminal units (RTUs) and programmable logic controllers (PLCs) that connect to sensors in the field. They allow for centralized supervision and control of geographically dispersed processes.
2. A key component is the human-machine interface (HMI) which presents data to operators and allows them to control the process. Other components include RTUs/PLCs that connect to field devices, a communication system to connect components, and a supervisory computer system for data collection and control.
3. Security is a major concern as SCADA systems often have vulnerabilities like hardcoded passwords and lack of authentication. Successful cyber attacks could disrupt
Design And Development of A Plug-In Type Wireless Data Logger for Energy Meas...IOSR Journals
This document describes the design and development of a plug-in type wireless data logger for energy measurement. The data logger is designed to accurately measure energy, voltage, current, and instantaneous power in real time for single-phase applications. It consists of hardware modules for energy measurement, data transmission, and reception. The energy measurement module uses a CS5460A chip to measure parameters. Data is transmitted wirelessly via Bluetooth and received on a computer interface. The system aims to provide low-cost real-time energy monitoring for appliances to encourage efficient energy usage.
Design and Implementing Novel Independent Real-Time Software Programmable DAQ...Editor IJCATR
The crucial features of many demanding applications like industry and aerospace are data acquisition and telemetry. It is
vital to observe and analyse the real time performance, in launch vehicle systems,so that designs can be certified and tuneablefactors
could be regulated to intensification the act and competence. At present used DAQ structures are of augmented size, weight and turn out
to be exorbitant and power hungry. This article introduce a new mission-independent real time software programmable DAQ system
using multipurpose MCU and sigma delta ADCs are planned,taking into account size, weight, costand act without compromiseon
precision, firmness and drift act. Additional digital filtering steps are also added to progress the system act. This system isproficientfor
directconnectionswithdiverse pressure and temperature sensors whichinterfaces 32 low frequency channel and two high frequency
channels. The system planned operates in two modes; one is data acquisition mode and another is program mode. Operativepower
lesseningmethods and wireless interface protocol between diverse data acquisition modules is also affected upon as avenues for future
work.
This document discusses Supervisory Control and Data Acquisition (SCADA) systems used in electric utilities. It describes:
1) SCADA systems connect master stations to remote terminal units (RTUs) via communication systems to collect data and remotely control electrical systems.
2) Control centers use SCADA for energy management and distribution management. Modern centers use open standards and protocols like ICCP for data exchange.
3) RTUs contain sensors, processors and I/O to monitor and control field devices and report to master stations. Larger RTUs are used at substations while smaller RTUs automate distribution.
Application of scada for system automation on smart grid rev2Ezechukwu Ukiwe
SCADA systems play a critical role in monitoring and controlling modern power grids and remain essential components of smart grid systems. SCADA provides real-time monitoring of power systems through continuous measurement of parameters across the network. It enables utilities to automate operations like load dispatching and frequency control. As power grids increase in complexity with smart grid technologies, SCADA takes on greater importance in integrating distributed generation, accommodating bidirectional power flows, and ensuring overall network reliability and security.
This document discusses different ways that humans can consume linked data, including through HTML browsers, linked data browsers, faceted browsers, and on-the-fly mashups. It notes that Google and Yahoo are starting to crawl RDFa to surface semantic information, and that linked data browsers allow viewing linked data returned from URIs in tabular form. It calls for creating new innovative ways to interact with linked data and partnering with the HCI community to develop novel user interfaces.
This document discusses a smart home system that uses a self-organizing sensor network. The network allows access to devices like meters, sensors, and alarms. Original network protocols consider topology, node distance, and device operation mode. The system was developed by the Center of Innovative Wireless Technologies and provides operational control of remote systems with minimum consumer cost. Test zones were deployed and investment agreements were made to install the system.
Smart energy management systems provide benefits such as energy efficiency, cost savings, load management, and power quality monitoring. They involve installing hardware like power analyzers to monitor energy usage throughout a facility. The data is visualized using software which allows users to track consumption, identify inefficiencies, set alarms, and detect power quality issues. This helps optimize energy distribution, reduce costs, and prevent production disruptions. The document discusses an implementation at a car manufacturing plant that identified power quality problems, saved on energy bills and maintenance costs, and provided a return on investment within 1.4 years.
The document discusses the Distributed Control System (DCS) at IFFCO Phulpur, located near Prayagraj, India. The IFFCO Phulpur facility produces ammonia and urea and has a production capacity of 0.824 MTPA for ammonia and 1.416 MTPA for urea, as well as other fertilizers. A DCS is a specially designed control system used to control large, complex industrial processes through distributed controllers connected by communication networks. The key components of a DCS include field devices, input/output modules, controllers located near field devices, a human-machine interface, and control engineering workstations.
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
The document describes an intelligent motor control center (MCC) system using SIMOCODE motor management and control devices. Key advantages of the intelligent MCC include sensitive motor protection, direct communication to DCS for monitoring and control, reduced commissioning time, and online monitoring of motor parameters. While the upfront cost is higher, the intelligent MCC provides benefits like reduced installation, commissioning and maintenance costs over traditional MCCs. Some initial problems during commissioning centered around communication delays and errors but were addressed through configuration and hardware changes.
Automation- Metering, Sub Station & Industrial AutomationEPC Solutions LLP
Power system automation and control is a critical means for utilities to improve reliability, efficiency, and productivity. EPC Solutions offers some of the best engineering solution in the power industry for executing the successful Substation Automation programs. With its immaculate engineering capability, backed by a team of well-qualified engineers with solid year experience, EPCS has designed wide range of protection and control panels for more than 170 Substation up to 400kV level with different bus configuration across the country. We are well versed with all make / type of Numerical functional and Auxiliary relay includes ABB, AREVA, Easun Reyrolle, GE, SIEMENS, VATECH, SEL.
>> Services:
EPC Solutions are designed to participate in our client’s business growth. By combining technology with experience we can provide successful solutions to Substation Automation.
>> System Engineering :
@ Preparing complete customer approval submittal
@ Preparing complete Manufacturing submittal
@ Preparing Switchyard Cable schedule
@ Participating in customer discussion and approval process
@ Numerical Relay Configuration
@ System functional Integration
@ Preparing system configuration diagram (SCD)
@ Micro SCADA application
@ SCD programming
@ SAS Testing
@ Application Engineering for Relay Selection
@ Relay Setting calculation
@ Factory Accept Testing
@ Site Accept Testing
@ Commissioning
-----------------------------------------------------------------
Control and Relay panels for up to 400 kV switchyard
EPCS designing a comprehensive range of control and relay panels and control desks for control, protection, alarm, indication, metering and synchronizing functions etc. for power stations, sub-stations and industrial plants of various system voltages.
@ Control and Protection panel for Feeder
@ Control and Protection panel for Line
@ Control and Protection panel for Power Transformer
@ Control and Protection panel for Generator Transformer
@ Control and Protection panel for Unit Auxiliary Transformer
@ Control and Protection panel for Station Transformer
@ Control and Protection panel for Bus coupler
@ Control and Protection panel for Bus section
@ Control and Protection panel for Transfer Bus Coupler
@ Control and Protection panel for Capacitor Bank
@ Control and Protection panel for Shunt Reactor
@ Control and Protection panel for Generator
@ Protection panel for Busbar
@ Mosaic type control panel/desk for power plant
@ Annunciation alarm panel for power plant
@ Synchronizing Panel / Trolley / Bracket
@ Tariff metering panel
@ Outdoor Marshalling kiosk
@ SCADA interfacing panel
@ RTU panel
@ Event Logger panel
@ Disturbance Recorder panel
@ Retrofit Protection Panel for feeder, transformer and generators
Power system automation involves using instrumentation and control devices to automatically control the power system. It includes substation automation which uses data from intelligent electronic devices to control power system devices from remote locations. Substations transform voltage levels and may be owned by utilities or large industrial customers. Power system automation incorporates tasks like data acquisition, supervision of system conditions, and control of devices.
SCADA - Wikipedia, the free encyclopediaRaj Bakshi
SCADA systems monitor and control industrial processes, infrastructure, and facilities. They consist of human-machine interfaces, supervisory computers, remote terminal units that connect to sensors, and communication infrastructure. While SCADA systems have evolved to incorporate standard protocols and networking, their widespread implementation and connections to other systems have introduced new security vulnerabilities that could disrupt critical infrastructure if exploited.
The aim of this project is to design and develop a system , which will help us to control the industrial processes sitting in a far of location.
Here a wireless concept of RF radio frequency (frequency Modulation technology) is used to control and monitor.
Dhiraj seminar # power system automationvision2d16
This document discusses power system automation and SCADA (Supervisory Control and Data Acquisition) systems. It describes the key components of SCADA including instrument transformers, transducers, relays, RTUs, meters, digital fault recorders, PLCs and HMIs. The advantages of power system automation are that it makes the system more efficient with less manpower and is flexible, simple and reliable. Some applications discussed are smart grids, smart meters and automatic generation control.
Mitsubishi energy measuring unit eco monitorlight_dienhathe.vnDien Ha The
Khoa Học - Kỹ Thuật & Giải Trí: http://phongvan.org
Tài Liệu Khoa Học Kỹ Thuật: http://tailieukythuat.info
Thiết bị Điện Công Nghiệp - Điện Hạ Thế: http://dienhathe.vn
The document provides information about North Delhi Power Limited (NDPL), including:
1. NDPL is a joint venture between Tata Power and the Government of Delhi that distributes power to parts of Delhi.
2. It covers an area of 510 square kilometers and supplies over 4.5 million consumers.
3. The document discusses NDPL's control centers, automation systems like SCADA, benefits of automation, and IT implementations.
The document describes the SENTRON powermanager software which provides energy management solutions that allow users to measure, analyze, store, and share energy usage and status information across their enterprise. It offers control capabilities, comprehensive reporting, and detailed energy usage data to help users reduce energy costs. The software integrates with Siemens power meters and devices to provide visibility into power flows and allow identification of opportunities to optimize energy usage and savings. It is a scalable solution that users can start with basic monitoring and later expand to an advanced enterprise-wide system.
Energy measuring unit eco monitorlight series dienhathe.vnDien Ha The
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
Điện Công Nghiệp Mitsubishi, Điện Công Nghiệp,
Điện Hạ Thế Mitsubishi, Điện Hạ Thế,
Điện Dân Dụng Mitsubishi, Điện Dân Dụng,
Mitsubishi,
Thiết Bị Đóng Cắt Mitsubishi, Thiết Bị Đóng Cắt,
Thiết Bị Điện Mitsubishi, Thiết Bị Điện,
This document discusses various components of an industrial automation and control system. It describes remote terminal units (RTUs) that collect field data and transfer it to other devices. It also explains instruments like current transformers and potential transformers that convert power signals to lower levels, as well as transducers that convert analog outputs. Additional components covered include meters, digital fault recorders, load tap changers, protective relays, and programmable logic controllers (PLCs). The document provides details on the functions of these various components that make up automation and control systems.
1. SCADA systems are used to monitor and control industrial processes through remote terminal units (RTUs) and programmable logic controllers (PLCs) that connect to sensors in the field. They allow for centralized supervision and control of geographically dispersed processes.
2. A key component is the human-machine interface (HMI) which presents data to operators and allows them to control the process. Other components include RTUs/PLCs that connect to field devices, a communication system to connect components, and a supervisory computer system for data collection and control.
3. Security is a major concern as SCADA systems often have vulnerabilities like hardcoded passwords and lack of authentication. Successful cyber attacks could disrupt
Design And Development of A Plug-In Type Wireless Data Logger for Energy Meas...IOSR Journals
This document describes the design and development of a plug-in type wireless data logger for energy measurement. The data logger is designed to accurately measure energy, voltage, current, and instantaneous power in real time for single-phase applications. It consists of hardware modules for energy measurement, data transmission, and reception. The energy measurement module uses a CS5460A chip to measure parameters. Data is transmitted wirelessly via Bluetooth and received on a computer interface. The system aims to provide low-cost real-time energy monitoring for appliances to encourage efficient energy usage.
Design and Implementing Novel Independent Real-Time Software Programmable DAQ...Editor IJCATR
The crucial features of many demanding applications like industry and aerospace are data acquisition and telemetry. It is
vital to observe and analyse the real time performance, in launch vehicle systems,so that designs can be certified and tuneablefactors
could be regulated to intensification the act and competence. At present used DAQ structures are of augmented size, weight and turn out
to be exorbitant and power hungry. This article introduce a new mission-independent real time software programmable DAQ system
using multipurpose MCU and sigma delta ADCs are planned,taking into account size, weight, costand act without compromiseon
precision, firmness and drift act. Additional digital filtering steps are also added to progress the system act. This system isproficientfor
directconnectionswithdiverse pressure and temperature sensors whichinterfaces 32 low frequency channel and two high frequency
channels. The system planned operates in two modes; one is data acquisition mode and another is program mode. Operativepower
lesseningmethods and wireless interface protocol between diverse data acquisition modules is also affected upon as avenues for future
work.
This document discusses Supervisory Control and Data Acquisition (SCADA) systems used in electric utilities. It describes:
1) SCADA systems connect master stations to remote terminal units (RTUs) via communication systems to collect data and remotely control electrical systems.
2) Control centers use SCADA for energy management and distribution management. Modern centers use open standards and protocols like ICCP for data exchange.
3) RTUs contain sensors, processors and I/O to monitor and control field devices and report to master stations. Larger RTUs are used at substations while smaller RTUs automate distribution.
Application of scada for system automation on smart grid rev2Ezechukwu Ukiwe
SCADA systems play a critical role in monitoring and controlling modern power grids and remain essential components of smart grid systems. SCADA provides real-time monitoring of power systems through continuous measurement of parameters across the network. It enables utilities to automate operations like load dispatching and frequency control. As power grids increase in complexity with smart grid technologies, SCADA takes on greater importance in integrating distributed generation, accommodating bidirectional power flows, and ensuring overall network reliability and security.
This document discusses different ways that humans can consume linked data, including through HTML browsers, linked data browsers, faceted browsers, and on-the-fly mashups. It notes that Google and Yahoo are starting to crawl RDFa to surface semantic information, and that linked data browsers allow viewing linked data returned from URIs in tabular form. It calls for creating new innovative ways to interact with linked data and partnering with the HCI community to develop novel user interfaces.
This document discusses a smart home system that uses a self-organizing sensor network. The network allows access to devices like meters, sensors, and alarms. Original network protocols consider topology, node distance, and device operation mode. The system was developed by the Center of Innovative Wireless Technologies and provides operational control of remote systems with minimum consumer cost. Test zones were deployed and investment agreements were made to install the system.
The document discusses applications of cyber-physical systems and robotics. Some key areas discussed include smart manufacturing using robotics working safely with humans, transportation systems using vehicle-to-vehicle communication and autonomous vehicles, smart energy grids, infrastructure monitoring using sensors, and medical devices. The integration of computation, networking, and physical processes allows innovative applications that can improve efficiency, safety, reliability and sustainability across many sectors.
These slides use concepts from my (Jeff Funk) course entitled analyzing hi-tech opportunities to analyze the increasing economic feasibility of smart homes. Rapid improvements in sensors, integrated circuits, transceivers, displays, mobile phones, and wireless networks are causing the cost to fall and the performance to rise for smart home-related features. It is becoming increasingly inexpensive and easy to control a wide number of appliances with mobile phones and to embed intelligence in many of these appliances. Smart homes will have higher energy efficiencies, better safety, more convenience, and better security than existing homes as the improvements in various technologies make them economically feasible.
IoT Based Control and Monitoring of Smart Grid and Power Theft Detection by L...IRJET Journal
This document discusses using IoT technology to create a smart grid system for monitoring and controlling power distribution and detecting power theft. The system uses Raspberry Pi hubs connected to smart meters via Zigbee to collect power usage data from consumers and send it to the Azure cloud. This allows identifying locations of power theft by comparing total usage recorded at transformers to reported consumer usage. The system can also detect faults, notify consumers of outages or price changes, and allow excess power from solar installations to be returned to the grid.
AUTOMATIC VOLTAGE CONTROL OF TRANSFORMER USING MICROCONTROLLER AND SCADA Ajesh Jacob
AUTOMATIC VOLTAGE CONTROL OF TRANSFORMER USING MICROCONTROLLER AND SCADA
LABVIEW PROJECT FINAL YEAR EEE
ABSTRACT: A tap changer control operates to connect appropriate tap position of winding in power transformers to maintain correct voltage level in the power transmission and distribution system. Automatic tap changing can be implemented by using µC. This improved tap-changing decision and operational flexibility of this new technique make it attractive for deployment in practical power system network. This paper deals with the implementation of µC based tap changer control practically, using special purpose digital hardware as a built-in semiconductor chip or software simulation in conventional computers. Two strategies are suggested for its implementation as a software module in the paper. One is to integrate it with the supervisory system in a substation control room operating in a LAN environment. In this configuration, the parallel transformers can be controlled locally. The other is to integrate it into the SCADA (Supervisory Control and Data Acquisition) system, which allows the transformers to be monitored and controlled remotely over a wide area of power-network. The implementation of µC based tap changer control needs interfacing between the power system and the control circuitry. µC s may need to interact with people for the purpose of configuration, alarm reporting or everyday control.
A human-machine interface (HMI) is employed for this purpose. An HMI is usually linked to the SCADA system’s databases and software programs, to provide trending, diagnostic data, and management information such as scheduled maintenance procedures, logistic information, detailed schematics for a particular sensor or machine, and expert-system troubleshooting guides.
OBJECTIVES: The original system can afford the following features:
- Complete information about the plant (circuit breakers status, source of feeding, and level of the consumed power).
- Information about the operating values of the voltage, operating values of the transformers, operating values of the medium voltage, load feeders, operating values of the generators. These values will assist in getting any action to return the plant to its normal operation by minimum costs.
- Information about the quality of the system (harmonics, current, voltages, power factors, flickers, etc.). These values will be very essential in case of future correction.
- Recorded information such case voltage spikes, reducing the voltage on the medium or current interruption.
- implementation of µC based tap changer control practically, using special purpose digital hardware as a built-in semiconductor chip or software simulation in conventional computers.
This document provides an overview of a feasibility study conducted by NISCOM Inc. on introducing energy efficient technologies and management systems to data centers in Indonesia to reduce energy consumption and greenhouse gas emissions. The study assessed technologies like high voltage direct current power supplies, energy efficient cooling systems, intelligent monitoring software. It was estimated these measures could reduce emissions by 3,400 tons of CO2 per year at a sample data center. The document also outlines plans to provide guidance to Indonesian partners on monitoring and verifying emission reductions from implementing the proposed technologies.
This document provides an overview of a feasibility study conducted by NISCOM Inc. on introducing energy efficient technologies and management systems to data centers in Indonesia to reduce greenhouse gas emissions. The study assessed technologies like high voltage direct current power supplies, energy efficient cooling systems, intelligent monitoring software. It estimated that implementing these solutions could reduce emissions by 3,400 tons of CO2 per year at a sample data center. The document also outlines plans to provide guidance to Indonesian partners on monitoring and verifying emission reductions from proposed projects.
International Journal of Engineering Research and Applications (IJERA) is a team of researchers not publication services or private publications running the journals for monetary benefits, we are association of scientists and academia who focus only on supporting authors who want to publish their work. The articles published in our journal can be accessed online, all the articles will be archived for real time access.
Our journal system primarily aims to bring out the research talent and the works done by sciaentists, academia, engineers, practitioners, scholars, post graduate students of engineering and science. This journal aims to cover the scientific research in a broader sense and not publishing a niche area of research facilitating researchers from various verticals to publish their papers. It is also aimed to provide a platform for the researchers to publish in a shorter of time, enabling them to continue further All articles published are freely available to scientific researchers in the Government agencies,educators and the general public. We are taking serious efforts to promote our journal across the globe in various ways, we are sure that our journal will act as a scientific platform for all researchers to publish their works online.
A Generalized Multistage Economic Planning Model for Distribution System Cont...IJERD Editor
This document describes a smart energy meter system that allows for wireless billing and load management. The system consists of an energy meter installed at a customer's location that measures electricity usage and transmits readings wirelessly. A billing station then receives the data, calculates customer bills, and sends bills via text message. The meter can also send warning texts and disconnect power if usage exceeds limits. The system aims to reduce energy waste, provide more convenient billing, and allow remote disconnection for non-payment. It was found to be technically, economically, and commercially feasible to automate billing and load management using wireless communication compared to traditional manual processes.
IRJET - Intelligent Energy Monitoring System using Web AccessIRJET Journal
This document describes an intelligent energy monitoring system that uses web access to optimize energy usage. The system collects energy consumption data from homes and businesses using sensors connected to a NodeMCU microcontroller. The NodeMCU transmits the data via WiFi to a central server. The server analyzes the data using ThingSpeak analytics to generate detailed reports and visualizations of energy usage. This allows users to better manage their home energy usage. The system aims to reduce energy wastage, avoid power theft, and minimize the need for manual data collection from energy meters.
POWER CONSUMPTION DETECTING AND ALERTING SYSTEMIRJET Journal
This document describes a power consumption detecting and alerting system. The system continuously monitors home appliance power consumption and calculates unit usage to alert consumers when they are close to exceeding the current electricity rate slab. When the slab rate threshold is reached, auxiliary loads will automatically be cut off and a message will be sent to the consumer. The system aims to help consumers efficiently use power from the grid and maintain a low electricity bill. It uses components like a microcontroller, relays, LCD display, step-down transformer, buzzer, and potentiometer. The system works by measuring power usage, calculating units, and sending alerts via buzzer and messages if the slab rate is approached or exceeded to encourage reduced consumption.
The document discusses Siemens' 7KT/7KM PAC measuring devices. It provides an overview of the devices' features and abilities, including precise and reliable energy measurement, integration capabilities with automation and monitoring systems through various communication options, and universal worldwide use through international approvals. Device options are presented ranging from basic energy measurement to monitoring of power quality and system status. Key highlights include intuitive menu for fast commissioning, easy connection to higher level systems, and global application in accordance with IEC/EN and UL standards.
IRJET- Implementation of Automated Urban Drinking Water Supply and Leakage Id...IRJET Journal
This document describes a proposed system to automate urban drinking water supply and identify leaks using Programmable Logic Control (PLC) and Supervisory Control and Data Acquisition (SCADA). The system would minimize human error, reduce water wastage from leaks, theft and faults in pipes. Sensors would monitor water pressure and flows. PLCs would control pumps and valves locally, while a central SCADA system would allow remote monitoring and control. Data from sensors would be transmitted to the SCADA system via RTUs to identify leaks and optimize water distribution in real-time. This could help reduce supply costs and more efficiently match demand with a scarce water supply in urban areas of India.
IRJET- Monitoring and Controlling Power using Zigbee CommunicationIRJET Journal
This document discusses using Zigbee communication for monitoring and controlling power in a smart grid system. It describes several hardware architectures that use Zigbee devices to remotely monitor home appliance power usage and control appliances on or off. Zigbee is identified as a suitable wireless communication protocol for these applications due to its low data rate, low power consumption, and ability to communicate over distances up to 200 meters.
A key part of implementing Volt-VAR control and optimization is to identify the benefits that can be attributed to VVO. The major challenge is to separate the impacts of VVO (i.e. the VVO benefits) from the impacts of factors not related to VVO, such as changing weather conditions, random customer behavior and routine operational changes (planned switching). Utilities on the panel have performed VVO measurement and verification using different methods. Each presenter will describe how the method works, data requirements, strengths and weaknesses of the approach and results. The session also will summarize work by the IEEE Volt-VAR task force to develop IEEE Guideline P1885 M&V of VVO projects for electric distribution utilities.
IRJET- Smart and Efficient Load Control System using Dynamic TariffIRJET Journal
This document summarizes a research paper on a proposed smart and efficient load control system using dynamic tariff pricing. The system would use an IoT-based approach to control home appliances and industrial loads based on changing electricity rates and time periods. Sensors would monitor electricity consumption and tariff information from a virtual web server would be sent over an IoT cloud network to a microcontroller. The microcontroller would then control connected loads like LEDs and bulbs to encourage shifting usage to off-peak low-rate times. This could help reduce electricity bills for consumers and increase efficiency for electricity suppliers by leveling peak loads. The proposed system design and components are described, along with potential advantages like remote control and energy savings, and disadvantages
This is a complete automated solution for the existing energy distribution and monitoring system in
India,which can monitor the meter readings continuously and take necessary actions to maintain the power
grid stable. A Power Line Communication (PLC) based modem is integrated with each electronic energy
meter. Through PLC the meters communicate with the coordinator. Coordinator makes use of GPRS modem
to upload/download data to/from internet. A personal computer with an internet connection at the other end,
which contains the database acts as the billing point. Live meter reading sent back to this billing point
periodically and these details are updated in a central database. An interactive, user friendly graphical
interface is present at user end. All the energy logs, notices from the Government, billing details and average
statistics will be available here. The system splits the loads into critical loads and non critical loads. This
makes the distribution system more intelligent. More over prior information about the power cuts can be
done. We can easily implement many add-ons such as energy demand prediction, real time dynamic tariff as
a function of demand and supply and so on.
This is a complete automated solution for the existing energy distribution and monitoring system in
India,which can monitor the meter readings continuously and take necessary actions to maintain the power
grid stable. A Power Line Communication (PLC) based modem is integrated with each electronic energy
meter. Through PLC the meters communicate with the coordinator. Coordinator makes use of GPRS modem
to upload/download data to/from internet. A personal computer with an internet connection at the other end,
which contains the database acts as the billing point. Live meter reading sent back to this billing point
periodically and these details are updated in a central database. An interactive, user friendly graphical
interface is present at user end. All the energy logs, notices from the Government, billing details and average
statistics will be available here. The system splits the loads into critical loads and non critical loads. This
makes the distribution system more intelligent. More over prior information about the power cuts can be
done. We can easily implement many add-ons such as energy demand prediction, real time dynamic tariff as
a function of demand and supply and so on.
This document summarizes a proposed cognitive energy distribution system for India. The system uses power line communication between electronic energy meters and coordinators. Meters communicate meter readings to coordinators via PLC, and coordinators upload data to a central database via GPRS. The system allows for remote meter reading and monitoring to reduce energy theft and inefficiencies. It also enables features like critical and non-critical load control, dynamic tariffs based on demand, and energy demand prediction to improve distribution system stability and reliability.
The document discusses Advanced Metering Infrastructure (AMI) and its benefits for utility companies and customers. It outlines the history of metering in Nigeria and introduces AMI as a system for automated two-way communication between smart meters and utilities via a communications network. AMI allows utilities to remotely collect meter data and control loads, while providing customers with consumption data to make informed energy choices. The document provides an overview of AMI components including smart meters, communication infrastructure, and meter data management systems.
Download GFS Crane DCIM case study to see how we help business via IT and Telecom Infrastructure DCIM implementation, including ROI and payback period.
Design of a Smart Meter for the Indian Energy ScenarioIJERA Editor
This document describes the design of a smart meter for the Indian energy sector. It discusses the architecture of a demand-based smart metering system that can separately monitor energy consumption during normal and peak hours. This allows for time-of-day tariff pricing to encourage reduced usage during peaks. The smart meter uses a microcontroller and wireless communication to automatically send consumption data to a utility server. The server uses a LabVIEW GUI to receive the data, generate bills, and allow remote control functions. Software and hardware designs for the smart meter and server are presented. An experiment tests how shifting load from peaks to normal hours affects costs under time-of-day pricing.
Computer Applications in Power Systems 2023 SECOND.pdfhussenbelew
The document discusses real-time applications of computers in power systems. It describes how SCADA systems are used for monitoring, control, and management of electric power grids. Key functions of SCADA include data acquisition, remote control, supervision, historical data analysis, and various control applications specific to power generation, transmission, and distribution. Real-time monitoring and control allow for faster response to disturbances, optimized system operation, and more reliable power delivery.
Similar to Fpc v2 ch7 energy management solution_20161213 (20)
Discover the latest insights on Data Driven Maintenance with our comprehensive webinar presentation. Learn about traditional maintenance challenges, the right approach to utilizing data, and the benefits of adopting a Data Driven Maintenance strategy. Explore real-world examples, industry best practices, and innovative solutions like FMECA and the D3M model. This presentation, led by expert Jules Oudmans, is essential for asset owners looking to optimize their maintenance processes and leverage digital technologies for improved efficiency and performance. Download now to stay ahead in the evolving maintenance landscape.
Null Bangalore | Pentesters Approach to AWS IAMDivyanshu
#Abstract:
- Learn more about the real-world methods for auditing AWS IAM (Identity and Access Management) as a pentester. So let us proceed with a brief discussion of IAM as well as some typical misconfigurations and their potential exploits in order to reinforce the understanding of IAM security best practices.
- Gain actionable insights into AWS IAM policies and roles, using hands on approach.
#Prerequisites:
- Basic understanding of AWS services and architecture
- Familiarity with cloud security concepts
- Experience using the AWS Management Console or AWS CLI.
- For hands on lab create account on [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
# Scenario Covered:
- Basics of IAM in AWS
- Implementing IAM Policies with Least Privilege to Manage S3 Bucket
- Objective: Create an S3 bucket with least privilege IAM policy and validate access.
- Steps:
- Create S3 bucket.
- Attach least privilege policy to IAM user.
- Validate access.
- Exploiting IAM PassRole Misconfiguration
-Allows a user to pass a specific IAM role to an AWS service (ec2), typically used for service access delegation. Then exploit PassRole Misconfiguration granting unauthorized access to sensitive resources.
- Objective: Demonstrate how a PassRole misconfiguration can grant unauthorized access.
- Steps:
- Allow user to pass IAM role to EC2.
- Exploit misconfiguration for unauthorized access.
- Access sensitive resources.
- Exploiting IAM AssumeRole Misconfiguration with Overly Permissive Role
- An overly permissive IAM role configuration can lead to privilege escalation by creating a role with administrative privileges and allow a user to assume this role.
- Objective: Show how overly permissive IAM roles can lead to privilege escalation.
- Steps:
- Create role with administrative privileges.
- Allow user to assume the role.
- Perform administrative actions.
- Differentiation between PassRole vs AssumeRole
Try at [killercoda.com](https://killercoda.com/cloudsecurity-scenario/)
Redefining brain tumor segmentation: a cutting-edge convolutional neural netw...IJECEIAES
Medical image analysis has witnessed significant advancements with deep learning techniques. In the domain of brain tumor segmentation, the ability to
precisely delineate tumor boundaries from magnetic resonance imaging (MRI)
scans holds profound implications for diagnosis. This study presents an ensemble convolutional neural network (CNN) with transfer learning, integrating
the state-of-the-art Deeplabv3+ architecture with the ResNet18 backbone. The
model is rigorously trained and evaluated, exhibiting remarkable performance
metrics, including an impressive global accuracy of 99.286%, a high-class accuracy of 82.191%, a mean intersection over union (IoU) of 79.900%, a weighted
IoU of 98.620%, and a Boundary F1 (BF) score of 83.303%. Notably, a detailed comparative analysis with existing methods showcases the superiority of
our proposed model. These findings underscore the model’s competence in precise brain tumor localization, underscoring its potential to revolutionize medical
image analysis and enhance healthcare outcomes. This research paves the way
for future exploration and optimization of advanced CNN models in medical
imaging, emphasizing addressing false positives and resource efficiency.
artificial intelligence and data science contents.pptxGauravCar
What is artificial intelligence? Artificial intelligence is the ability of a computer or computer-controlled robot to perform tasks that are commonly associated with the intellectual processes characteristic of humans, such as the ability to reason.
› ...
Artificial intelligence (AI) | Definitio
Advanced control scheme of doubly fed induction generator for wind turbine us...IJECEIAES
This paper describes a speed control device for generating electrical energy on an electricity network based on the doubly fed induction generator (DFIG) used for wind power conversion systems. At first, a double-fed induction generator model was constructed. A control law is formulated to govern the flow of energy between the stator of a DFIG and the energy network using three types of controllers: proportional integral (PI), sliding mode controller (SMC) and second order sliding mode controller (SOSMC). Their different results in terms of power reference tracking, reaction to unexpected speed fluctuations, sensitivity to perturbations, and resilience against machine parameter alterations are compared. MATLAB/Simulink was used to conduct the simulations for the preceding study. Multiple simulations have shown very satisfying results, and the investigations demonstrate the efficacy and power-enhancing capabilities of the suggested control system.
1. Energy Management
Solution
Energy Management Solution P 7-11
Software Utility P 7-64
Smart Power Meter & Devices P 7-53
● Power Meter Concentrator - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-7
● Three-phase Smart Power Meter
PM-3133-RCT/-MTCP/-CPS- - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-8
PM-3133/-MTCP/-CPS - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-10
PM-3033/-MTCP/-CPS - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-12
● Single-phase Smart Power Meter - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-14
● Multi-circuit Smart Power Meter- - - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-18
● 8-channel True RMS Input Module - - - - - - - - - - - - - - - - - - - - - - - - - - - P 7-21
● Industrial Multi-power-meter Display - - - - - - - - - - - - - - - - - - - - - - - - - P 7-23
Power Meter Concentrator P 7-22
Energy Management Solutions - EM Brochure
True RMS Input Module
TouchPAD - VPD series
Smart Power Meter
Smart Power Meter Concentrator
Power Data Management Software
Or refer to http://www.icpdas.com/root/support/catalog/pdf/Brochure/EM-Brochure-en.pdf
2. 7-1
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
1. Energy Management Solution
For the resources of the earth are getting depleted faster in recent years, countries around the world and all walks of
life all set off a wave of energy saving and carbon reduction in order to avoid the waste of resources and pursue living
a sustainable life to extend earth's resources. Under the trend of energy saving and carbon reduction, power monitoring
gradually becomes an important project for maximizing energy efficiency by power monitoring always contributing to
significant energy savings no mater on the individual, corporate or national level. In order to achieve more efficient use of
energy and reduce resources consumption, ICP DAS provides an innovative total solution in energy saving by connecting
PMC/PMD (Power Meter Concentrator) to the Power Meters via RS-485 or Ethernet interface, it can measure and monitor
the power consumption of the devices, machines, lighting, air conditioning or other electricity equipments. In addition,
PMC/PMD also provides power demand management and alarm notification functions. With the integration of ICP DAS I/O
modules and the standard Modbus I/O devices, it can perform logic control or load shedding of the devices based on the
power demand in real time. PMC/PMD also supports Modbus TCP/RTU protocol for seamless integration with SCADA. So
that the administrator can monitor the status of power consumption of each device and perform statistics and analysis of
the power information, thus improving the overall efficiency in electricity consumption to save costs on utility bills.
This innovative total solution for energy saving includes: front-end Smart Power Meter, Power Meter Concentrator, back-end
software tool for database import operation (PMC Data Server) and InduSoft SCADA software. In addition to hardware
devices, ICP DAS also provides total solution so that the user could easily view power data by their mobile phones or PC,
the administrator could set up the system quickly and the data can be recorded in real time for energy consumption inquiry
to achieve effective energy saving. During the early stage, if the scale of the application is small, the user could simply
use Smart Power Meter and PMC/PMD to set up a simple power monitoring system, once the scale of the application is
expanded, the user could get the back-end software tool involved and build an easy-to-expand power monitoring system
via blocks stacked structure. By this way, the system will be highly flexible and could be implemented in phases to meet
various requirements.
System Architecture S t A hit t
3. 7-2Website: http://www.icpdas.com E-mail: service@icpdas.com Vol. FPC 2.05.09
PACProductsPanelProducts
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2. Power Meter Concentrator
No extra software tool, using browsers to
perform system operations
Featuring web-based HMI for easy operations, the user could
connect to PMC/PMD webpage via browsers to view the power
data, set up system parameters, manage power demand and
perform logic editing function for alarm notification.
Display real-time or historical power data trend
In addition to display power data of the power meter in text form,
the power data can also be displayed in real-time and historical
trend chart for user to easily identify the variation of the electricity
usage of the devices.
Built-in Micro SD card for power data logging
The PMC/PMD features a built-in Micro SD card. After the PMC/
PMD retrieving the power data from the power meter, the system
will save the power data in CSV format in the Micro SD card and
regularly send back the data files to the backend management
center for data analysis and statistics.
FTP Server/Client for data file management and file recovery mechanism supported
The built-in FTP Client function of PMC/PMD allows regular transmission of the power data logger files saved in the
Micro SD card of PMC/PMD to the backend management center for data analysis and statistics. The PMC/PMD offers
a complete data file recovery mechanism so that when experiencing network disconnection, the data log files will be
recovered after the network is resumed to ensure the system operates properly. With the FTP Server of PMC/PMD, the
user could also use FTP Client utility to retrieve the power data files saved in PMC/PMD from the PC side easily.
PMC PMD
PMC/PMD Features:
4. 7-3
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Provide Timer Function
Timer function provides Timeout/Not Timeout status for condition evaluations. With the timer function, the users are able
to edit logic that requires timing approach. In addition, the timer function can be reset/started in real time that increases
flexibility when performing logic control.
Provide historical power data statistics
report
PMC/PMD provides historical data report inquiry and
display function, the easy-to-read daily and monthly report
of the historical power data would help to understand
current electricity usage of the devices.
Built-in IF-THEN-ELSE logic engine for thought-out power demand management and
auto alarm notification when unusual events occurs
PMC/PMD is equipped with IF-THEN-ELSE logic engine. The user could complete the control logic via web page and
download the logic rules to the PMC/PMD. The logic engine will loop execute the rules in order. By editing the IF-
THEN-ELSE logic rules, the user could include the following information in the IF condition, such as: “fail to connect
to power meter”, “FTP upload failed”, “insufficient disk space”, “power demand management”, “abnormal power data”,
etc. In addition, the Schedule setting and channel values of I/O modules that are connected to the PMC/PMD can be
also included in the IF condition. When the evaluation of the IF condition is matched, the corresponding Action will be
executed (such as: Email/SMS alarm message sending or AO/DO channel value of the I/O modules setting). By this way,
the user could quickly implement applications for power demand management, electricity control of the devices and
alarm notification sending.
Provide Schedule function
PMC/PMD provides Schedule function that allows to edit
logic for applications that requires Schedule function. The
Calendar interface allows to easily set up the schedule for
weekdays or weekends so that the user could schedule the
operations for the devices as required for power saving.
Modbus TCP/RTU for seamless integration with SCADA
The PMC/PMD supports Modbus TCP/RTU Slave protocol to connect to SCADA software or HMI devices in control
center so that it could perform real-time monitoring and control of the electricity usage for the devices. Therefore, the
regulation of the system will be more flexible.
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On-Site Power data viewing and Power Meter setting
PMD (Power Meter Concentrator with Display) series is
equipped with TFT LCD (with Touch Panel). It provides an easy
way for viewing the power data and set up the Power Meter
parameters on sites.
Support SNMP Function
In addition to Modbus protocol, PMC/PMD also supports SNMP
function that allows seamless integration with IT Management
software. The users could integrate PMC/PMD with the existing
management system and collect the power data of each device
by SNMP function easily.
Provide “Power Usage Effectiveness (PUE)” calculation operation
Power usage effectiveness (PUE) is a
measure of how efficiently a computer
data center uses energy; specifically, how
much energy is used by the computing
equipment (in contrast to cooling and other
overhead). PUE is the ratio of total amount
of energy used by a computer data center
facility to the energy delivered to computing
equipment. The PUE will be greater than 1.
The larger the PUE number the less efficient
your utilization is. PMC/PMD provides the
PUE calculation operation and also display
the PUE data in two modes (Real-Time and
History) through Web page.
Support a variety of wide-range I/O modules to achieve power control and load
shedding of the devices
According to the requirements of the
application and based on the devices
connected, the PMC/PMD is able to
connect to M-7000 I/O modules,
standard Modbus TCP/RTU Slave
modules or DO Relay channel of the
PM Series power meter for real time I/
O control operation of the devices, the
abundant selections enable maximum
flexibility for system set up and power
saving.
6. 7-5
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Provide multi-phase multi-circuit power measurement function
PM-3033: 1 Three Phase Circuit
PM-3133: 1 Three Phase Circuit
PM-3112: 2 Single Phase Circuits
PM-3114: 4 Single Phase Circuits
PM-4324: 8 Three Phase Circuits or 24 Single Phase Circuits
Support multiple communication interface
• RS-485
• Ethernet
• CANopen
Support multiple standard communication protocols:
• Modbus RTU
• Modbus TCP
• CANopen
Support 2 built-in Power Relay Output
With CT W Accuracy Better than 0.5% (PF=1)
Clip on CT for easy installation
Compact size, easy to install, suitable for a variety of industrial applications
3. Smart Power Meter & Devices
ess:
PM-3133
PM-3033
PM-3112
PM-3114
PM-4324
TCP
RTU
PMM-4324
Built-in HMI for Infermation Display of Power Meters
IP40/IP60 Ingress Protection for Front Panel
Support Modbus TCP/RTU Protocols
Support Max. of 8 Single-phase/3-phase Power Meters
(PM-3xxx series) or One PM-4324
Support Max. of 4 Modbus/TCP Connections for SCADA
Software
Support Phase Sequence Detection
Support Fine Tune of Voltage and Current Ratio
8-channel True RMS Input
±0.15% Factory Calibrated Accuracy
RMS Input Range: +150 mVrms ~ +10 Vrms
For Standard Operation with Frequencies:
45 Hz ~ 10 KHz
Individual Channel Configurable
4 kV ESD Protection
±35 VDC Overvoltage Protection
2500 VDC Intra-module Isolation
True RMS Input Module Features Industrial Multi-power-meter Display
PM Smart Power Meter Features
M-7017RMS
DCON
RTU
TCP
RTU
VPD-173-PM
7” Series
VPD-143N-PM
4.3” Series VPD 173 PM
TPD-433-PM
TPD-703-PM
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4. Software Utility
Power Meter Utility
Power Meter Utility has to be installed on PC and it enables to retrieve and display the power measurement values
that measured by power meter via COM Port or Ethernet. The users will be able to read the power measurement
values and to perform parameter settings of the meter. When connecting with ICP DAS power meters by RS-485
communication protocol interface, it requires to convert RS-232 or USB on PC to RS-485 communication interface,
converter modules (such as ICP DAS I-7561, I-7520) might be required; When connecting with ICP DAS power
meters by Ethernet interface, it must setup the correct IP address to retrieve the power measurement values easily.
Features:
By Modbus RTU or Modbus TCP protocol, it enables to connect with ICP DAS Power Meters and data retrieving.
Real time monitor power measurement values of the meter.
Real time setting up parameters of the meter.
Restore the parameters of the meter to default settings.
Support Data Log function
PMC Data Server
The PMC Data Server is a database utility designed for connecting to the PMC/PMD concentrators. When PMC/PMD
Data Server is connected to these PMC/PMDs by Ethernet, the PMC/PMDs will send the power data logger files to
the PMC Data Server at scheduled time, and these power data will be transformed to MS Access/MS SQL/MySQL
database format for easy data review or inquiry. During the whole process of system development, no programming
is required. It takes only a few settings for users to quickly retrieve and view the power data of the devices based on
database system and furthermore, enables further process of the data for statistics and analysis.
8. 7-7
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Power Meter Concentrator
PMC-5151
Power Meter Concentrator With Display
10.4” TFT LCD
PMD-4201
7” TFT LCD
PMD-2201
Features:
No extra software tool is required, using browsers to operate system
Support at most 24 ICP DAS Modbus Power Meter and 8 Modbus I/O modules
(COM2, COM3 and LAN interface can connect to Max. 16 power meters.)
Display real-time or historical power data (in data table or chart form)
Provide power data statistics report (Daily and Monthly report)
Data file auto send-back & recovery when network is resumed after disconnection
Built-in IF-THEN-ELSE logic engine for power demand management
Provide alarm message notification function via Email or SMS
(for SMS message sending, GTM-203M-3GWA is required)
Adjust device operations by its power status via Modbus I/O modules
Provide Schedule function for operations of I/O modules (devices)
Support Modbus TCP/RTU Slave protocol for seamless integration with SCADA
Support Standard SNMP Protocol
Features:
Provide 7"/10.4" Touch Panel for On-Site operations
Provide remote connection using browsers to login for operations
Support up to 24 ICP DAS Modbus Power Meter and 8 Modbus I/O
(COM2, COM3 and LAN interface can connect to Max. 16 power meters.)
Provide real-time/historical power data statistics report
Provide microSD card to store power data information
Data file auto send-back & recovery when disconnected network is resumed
Built-in IF-THEN-ELSE logic engine for power demand management
Provide alarm message notification function via Email
Adjust device operations by its power status via Modbus I/O modules
Provide Schedule function for operations of I/O modules (devices)
Support Modbus TCP/RTU Slave protocol for integration with SCADA
Support SNMP Protocol
Introduction:
The PMC-5151 is a web-based intelligent Power Meter Concentrator developed by ICP DAS. It offers webpage interface, and features
various functions such as: power data collection, logic control, power demand management, data logger and alarm notification
functions. PMC-5151 allows connections to ICP DAS Smart Power Meters via RS-485 or Ethernet interface to read the power data of the
devices measured by the power meters; and then real-time record the power values in the data logger file. It also provides data logger
file auto send-back function; together with PMC Data Server software or SCADA software, it allows collection and analysis of the power
data.
Introduction:
The PMD is a web-based intelligent Power Meter Concentrator with Display. It offers webpage interface, and features various functions
such as: power data collection, logic control, power demand management, data logger, local display/Web page data display and alarm
notification functions. PMD allows connections to ICP DAS Smart Power Meters via RS-485 or Ethernet interface to read and record the
power data of the devices measured by the power meters. PMD also provides data logger file auto send-back function; together with
PMC Data Server software or SCADA software, it allows collection and analysis of the power data.
PMD is equipped with 7"/10.4" TFT LCD (with Touch Panel). It provides an easy way for viewing the power data and setting the system
parameters on sites. In addition, it can also access built-in Web Server on the PMD via browsers for the above operations. PMD also
offers Modbus TCP/RTU Slave function that allows seamless integration with most SCADA software
9. 7-8Website: http://www.icpdas.com E-mail: service@icpdas.com Vol. FPC 2.05.09
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Three-phase Smart Power Meter
PM-3133-RCT/-MTCP/-CPS
Specifications:
Features:
True RMS Power Measurements
Energy Analysis for 3P4W, 3P3W, 1P3W, 1P2W
Current Measurements Up to 2000 A
Voltage Measurements Up to 500 V
Rogowski Coil Soft CT for Easy Installation
W Accuracy Better than 1% (PF=1; Input Current >50A)
Supports RS-485, Ethernet (PoE) or CANopen Interface
Supports Modbus RTU, Modbus TCP or CANopen Protocol
Supports 2 Power Relay Output (Form A)
Total Harmonic Distortion (THD)
Introduction:
ICP DAS brings the most powerful, cost-effective, advanced Smart Power Meters PM-3133-RCT that gives you access to real-time
electric usage for three-phase power measurement. With its high accuracy (<1%, PF=1; Input Current >50A), this series can be used
to both low voltage primary side and medium/high voltage secondary side and enables the users to obtain reliable and accurate energy
consumption readings from the monitored equipments in real time under operation. These compact size and cost-effective power
meters monitoring equipment with Rogowski Coil CT is "rope-style" Current Transformer which delivers "Easy Installation" features for
large window size (55 ~ 105mm) and mechanical fl exibility for tight space.
It operates over a wide range of input voltages 10 ~ 500 VAC which allows universal compatibility. Also, with 2 channels relay outputs,
it can be linked with sirens or lightings for alarm messages. It also supports Modbus RTU, Modbus TCP or CANopen protocols for easy
integration.
Models PM-3133-RCT PM-3133-RCT-MTCP PM-3133-RCT-CPS
AC Power Measurement
Wiring 3P4W-3CT, 3P3W-2CT, 3P3W-3CT, 1P2W-1CT, 1P3W-2CT
Measurement Voltage 10 ~ 500 V
Measurement Current CTØ55 mm (500 A), CTØ80 mm (1000 A), CTØ105 mm (2000 A)
Measurement Frequency 50/60 Hz
W Accuracy Better than 1% (PF=1; Input Current >50 A)
Power Parameter
Measurement
True RMS voltage (Vrms), True RMS current (Irms), Active Power (kW), Active Energy (kWh), Apparent
Power (kVA), Apparent Energy (kVAh), Reactive Power (kVAR), Reactive Energy (kVARh), Power Factor (PF),
Frequency, THD
Data Update Rate 1 Second
Communication
Interface RS-485 Ethernet (PoE) CANopen
Protocol Modbus-RTU Modbus TCP CANopen
Baud rate
9600,19200 (default), 38400,
115200; DIP Switch Selectable
-
125 k (default), 250 k, 500 k, 1 M;
DIP Switch Selectable
Data format
N,8,1 (default);
N,8,2; E,8,1; E,8,2; O,8,1; O,8,2
- -
Isolation 3000 VDC - 3000 VDC
Alarm Output
Power Relay Form A (Normal Open) x 2; Relay Contact Voltage Range: 5 A @ 250 VAC (47 ~ 63Hz), 5 A @ 30 VDC
Power
Power Input +12 ~ 48 VDC +12 ~ 48 VDC or PoE +12 ~ 48 VDC
Power Consumption 2 W
Environment
Temperature Operating Temperature: -20 ~ +70˚C / Storage Temperature: -25 ~ +80˚C
Ambient Relative Humidity 10% ~ 90% RH, Non-condensing
10. 7-9
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Installation
Rogowski Coil Soft CT Installation
A B C D
Models A B
PM-3133-RCT500P 55.0 68.5
PM-3133-RCT1000P 80.0 93.5
PM-3133-RCT2000P 105.0 118.5
RS-485 Interface
PM-3133-RCT500P Modbus RTU, 3-phase power meter, 500A Rogowski Coil CT
PM-3133-RCT1000P Modbus RTU, 3-phase power meter, 1000A Rogowski Coil CT
PM-3133-RCT2000P Modbus RTU, 3-phase power meter, 2000A Rogowski Coil CT
Ethernet Interface
PM-3133-RCT500P-MTCP Modbus TCP, 3-phase power meter, 500A Rogowski Coil CT
PM-3133-RCT1000P-MTCP Modbus TCP, 3-phase power meter, 1000A Rogowski Coil CT
PM-3133-RCT2000P-MTCP Modbus TCP, 3-phase power meter, 2000A Rogowski Coil CT
CANopen Interface
PM-3133-RCT500P-CPS CANopen, 3-phase power meter, 500A Rogowski Coil CT
PM-3133-RCT1000P-CPS CANopen, 3-phase power meter, 1000A Rogowski Coil CT
PM-3133-RCT2000P-CPS CANopen, 3-phase power meter, 2000A Rogowski Coil CT
Ordering Information:
Dimensions (Units: mm):
Available soonAvailable soon
Available soonAvailable soon
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Three-phase Smart Power Meter
PM-3133/-MTCP/-CPS
Models PM-3133 PM-3133-MTCP PM-3133-CPS
AC Power Measurement
Wiring 3P4W-3CT, 3P3W-2CT, 3P3W-3CT, 1P2W-1CT, 1P3W-2CT
Measurement Voltage 10 ~ 500 V
Measurement Current CTØ10 mm (60 A); CTØ16 mm (100 A); CTØ24 mm (200 A); CTØ36 mm (300 A); CTØ36 mm (400 A)
Measurement Frequency 50/60 Hz
W Accuracy Better than 0.5% (PF=1)
Power Parameter
Measurement
True RMS voltage (Vrms), True RMS current (Irms), Active Power (kW), Active Energy (kWh), Apparent Power (kVA),
Apparent Energy (kVAh), Reactive Power (kVAR), Reactive Energy (kVARh), Power Factor (PF), Frequency
Data Update Rate 1 Second
Communication
RS-485
Protocol Modbus-RTU - -
Baud rate
9600,19200 (default), 38400,
115200; DIP Switch Selectable
- -
Data format N,8,1 - -
Isolation 3000 VDC - -
Ethernet (PoE) Protocol - Modbus TCP -
CANopen
Protocol - - CANopen
Baud rate - -
125 k (default), 250 k, 500 k, 1 M;
DIP Switch Selectable
Isolation - - 3000 VDC
Alarm Output
Power Relay Form A (Normal Open) × 2; Relay Contact Voltage Range: 5 A @ 250 VAC (47 ~ 63Hz), 5 A @ 30 VDC
Power
Power Input +12 ~ 48 VDC +12 ~ 48 VDC or PoE +12 ~ 48 VDC
Power Consumption 2 W
Environment
Temperature Operating Temperature: -20 ~ +70˚C / Storage Temperature: -25 ~ +80˚C
Ambient Relative Humidity 10% ~ 90% RH, Non-condensing
Specifications:
Features:
True RMS Power Measurements
Energy Analysis for 3P4W, 3P3W, 1P3W, 1P2W
Current Measurements Up to 400 A with Different CT Ratio
Voltage Measurements Up to 500 V
Clip-on CT for Easy Installation
W Accuracy Better than 0.5% (PF=1)
Supports RS-485, Ethernet (PoE) or CANopen Interface
Supports Modbus RTU, Modbus TCP or CANopen Protocol
Supports 2 Power Relay Output (Form A)
Total Harmonic Distortion (THD)
IEC 61010-1and EN 61010-1
Introduction:
ICP DAS brings the most powerful, cost-effective, advanced Smart Power Meters PM-3133 series that gives you access to real-time
electric usage for three-phase power measurement. With its high accuracy (<0.5%, PF=1 ), the PM-3133 series can be applied to both
low voltage primary side and/or medium/high voltage secondary side and enables the users to obtain reliable and accurate energy
consumption readings from the monitored equipments in real time under operation. These compact size and cost-effective power meters
are equipped with revolutionary wired clip-on CT (various types, support input current up to 400 A). It operates over a wide input
voltages range 10 ~ 500 VAC which allows worldwide compatibility. And with 2 channels relay outputs, it can be linked with sirens or
lightings for alarm messages. It also supports Modbus RTU, Modbus TCP or CANopen protocols for easy integration. You can use CT's
that you currently own with PM-3133P (without CTs) Power Meter. The CT inputs of the PM-3133P can handle a maximum of 333mV of
AC current.
12. 7-11
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Rear ViewRight ViewFront View Top ViewLeft View Bottom View
Power
RUNLED indicators
DO1
DO0
PM-3133
RS-485 Interface
PM-3133P Modbus RTU, 3-phase power meter (Compatible with CTs from 50 to 1000 A/333 mV output)
PM-3133-100 Modbus RTU, 3-phase power meter (60 A)
PM-3133-160 Modbus RTU, 3-phase power meter (100 A)
PM-3133-240 Modbus RTU, 3-phase power meter (200 A)
PM-3133-360P Modbus RTU, 3-phase power meter (300 A)
PM-3133-400P Modbus RTU, 3-phase power meter (400 A)
Ethernet Interface
PM-3133-100-MTCP Modbus TCP, 3-phase power meter (60 A)
PM-3133-160-MTCP Modbus TCP, 3-phase power meter (100 A)
PM-3133-240-MTCP Modbus TCP, 3-phase power meter (200 A)
PM-3133-360P-MTCP Modbus TCP, 3-phase power meter (300 A)
PM-3133-400P-MTCP Modbus TCP, 3-phase power meter (400 A)
CANopen Interface
PM-3133-100-CPS CANopen, 3-phase power meter (60 A)
PM-3133-160-CPS CANopen, 3-phase power meter (100 A)
PM-3133-240-CPS CANopen, 3-phase power meter (200 A)
PM-3133-360P-CPS CANopen, 3-phase power meter (300 A)
PM-3133-400P-CPS CANopen, 3-phase power meter (400 A)
--
CT size (measurement)
100: CTΦ10 mm, 60 A Max.
160: CTΦ16 mm, 100 A Max.
240: CTΦ24 mm, 200 A Max.
360P: CTΦ36 mm, 300 A Max.
400P: CTΦ36 mm, 400 A Max.
Current Transformers
(Secondary voltage 333mV)
Communication
: RS-485
CPS: CANopen
MTCP: Modbus TCP
RS-485 Interface
CANopen Interface
Ethernet Interface
x xx P xx x
33
6.5
100
90
37.2
35.6
37.2
110127
Appearance:
Dimensions (Units: mm):
Selection Guide:
Ordering Information:
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Models PM-3033 PM-3033-MTCP PM-3033-CPS
AC Power Measurement
Wiring 3P4W-3CT, 3P3W-2CT, 3P3W-3CT, 1P2W-1CT, 1P3W-2CT
Measurement Voltage 10 ~ 500 V
Measurement Current 1A or 5A
Measurement Frequency 50/60 Hz
W Accuracy Better than 0.5% (PF=1)
Power Parameter Measurement
True RMS voltage (Vrms), True RMS current (Irms), Active Power (kW), Active Energy (kWh),
Apparent Power (kVA), Apparent Energy (kVAh), Reactive Power (kVAR), Reactive Energy (kVARh),
Power Factor (PF), Frequency
Data Update Rate 1 Second
Communication
RS-485
Protocol Modbus-RTU - -
Baud rate
9600,19200 (default), 38400,
115200; DIP Switch Selectable
- -
Data format
N,8,1 (default); N,8,2; E,8,1;
E,8,2; O,8,1; O,8,2
- -
Isolation 3000 VDC - -
Ethernet (PoE) Protocol - Modbus TCP -
CANopen
Protocol - - CANopen
Baud rate - -
125 k (default), 250 k, 500 k, 1 M;
DIP Switch Selectable
Isolation - - 3000 VDC
Power
Power Input +12 ~ 48 VDC +12 ~ 48 VDC or PoE +12 ~ 48 VDC
Power Consumption 2 W
Environment
Temperature Operating Temperature: -20 ~ +70˚C / Storage Temperature: -25 ~ +80˚C
Ambient Relative Humidity 10% ~ 90% RH, Non-condensing
Three-phase Smart Power Meter
PM-3033/-MTCP/-CPS
Specifications:
Features:
True RMS Power Measurements
Energy Analysis for 3P4W, 3P3W, 1P3W, 1P2W
Direct input of secondary side 1A/5A CT
Voltage Measurements Up to 500 V
W Accuracy Better than 0.5% (PF=1)
Supports RS-485, Ethernet (PoE) or CANopen Interface
Supports Modbus RTU/Modbus TCP or CANopen Protocol
Total Harmonic Distortion (THD)
IEC 61010-1 and EN 61010-1
Total Harmonic Distortion (THD)
IEC 61010-1and EN 61010-1
Introduction:
ICP DAS brings the most powerful, cost-effective, advanced Smart Power Meters PM-3033 series that gives you access to real-time
electric usage for three-phase power measurement. With its high accuracy (<0.5%, PF=1 ), the PM-3033 series can be applied to both
low voltage primary side and/or medium/high voltage secondary side and enables the users to obtain reliable and accurate energy
consumption readings from the monitored equipments in real time under operation.
Direct input from “secondary side 1A/5A” type CTs. Dedicated CTs are no longer needed, which lowers the cost of implementation. It
operates over a wide input voltages range 10 ~ 500 VAC which allows worldwide compatibility. It also supports Modbus RTU, Modbus
TCP or CANopen protocols for easy integration.
14. 7-13
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
33
6.5
100
90
37.2
35.6
37.2
110
116.5
127
PM-3033
RS-485 Interface
PM-3033 Modbus RTU, 3-phase power meter (1A/5A CT Input type)
Ethernet Interface
PM-3033-MTCP Modbus TCP, 3-phase power meter (1A/5A CT Input type)
CANopen Interface
PM-3033-CPS CANopen, 3-phase power meter (1A/5A CT Input type)
-
Communication
: RS-485
CPS: CANopen
MTCP: Modbus TCP
x xx
Direct input of
secondary side
1A/5A CT
AC Measurement
10 ~ 500 V
Aux. Power Input
+12 ~ 48 VDC
LED indicators
Rear ViewRight ViewFront View Top ViewLeft View Bottom View
CT Installation and Wiring:
Dimensions (Units: mm):
Selection Guide:
Ordering Information:
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PM-3112/-MTCP/-CPS
PM-3114/-MTCP/-CPS
PM-3112 PM-3114
Models PM-3112 PM-3114 PM-3112-MTCP PM-3114-MTCP PM-3112-CPS PM-3114-CPS
AC Power Measurement
Wiring 1P2W-2CT 1P4W-4CT 1P2W-2CT 1P4W-4CT 1P2W-2CT 1P4W-4CT
Input Voltage 10 ~ 300 V
Input Current CTØ10 mm (60 A); CTØ16 mm (100 A); CTØ24 mm (200 A)
Input Frequency 50/60 Hz
W Accuracy Better than 0.5% (PF=1)
Starting Current >0.03A ( 60A ), >0.05A (100A ), >0.09A( 200A )
Power Parameter
Measurement
True RMS voltage (Vrms), True RMS current (Irms), Active Power (kW), Active Energy (kWh), Apparent Power (kVA),
Apparent Energy (kVAh), Reactive Power (kVAR), Reactive Energy (kVARh), Power Factor (PF), Frequency
Data Update Rate 1 Second
Communication
RS-485
Protocol Modbus-RTU - -
Baud rate
9600,19200 (default), 38400,
115200; DIP Switch Selectable
- -
Data format N,8,1 - -
Isolation 3000 VDC - -
Ethernet (PoE) Protocol - Modbus TCP -
CANopen
Protocol - - CANopen
Baud rate - -
125 k (default), 250 k, 500 k, 1 M;
DIP Switch Selectable
Alarm Output
Power Relay Form A (Normal Open) × 2; Relay Contact Voltage Range: 5 A @ 250 VAC (47 ~ 63 Hz), 5 A @ 30 VDC
Power
Input Range +12 ~ 48 VDC +12 ~ 48 VDC +12 ~ 48 VDC
Power Consumption 2 W
Environment
Temperature Operating Temperature: -20 ~ +70˚C / Storage Temperature: -25 ~ +80˚C
Ambient Relative Humidity 10% ~ 90% RH, Non-condensing
Single-phase Smart Power Meter
Specifications:
Features:
True RMS Power Measurements
Energy Analysis for 1P2W, 1P4W
Current Measurements Up to 200 A with Different CT Ratio
Voltage Measurements Up to 300 V
Clip-on CT for Easy Installation
W Accuracy Better than 0.5% (PF=1)
Supports RS-485, Ethernet or CANopen Interface
Supports Modbus RTU, Modbus TCP or CANopen Protocol
Supports 2 Power Relay Output (Form A)
IEC 61010-1and EN 61010-1
Introduction:
ICP DAS brings the most powerful, cost-effective, advanced Smart Power Meters PM-3000 series that gives you access to real-time
electric usage for single-phase power measurement. With its high accuracy (< 0.5%, PF=1 ), the PM-3000 series can be applied to
both low voltage primary side and/or medium/high voltage secondary side and enables the users to obtain reliable and accurate energy
consumption readings from the monitored equipments in real time under operation. These compact size and cost-effective power
meters are equipped with revolutionary wired clip-on CT (various types, support input current up to 200 A). It operates over a wide
input voltages range 10 ~ 300 VAC which allows worldwide compatibility. And with 2 channels relay outputs, it can be linked with sirens
or lightings for alarm messages. It also supports Modbus RTU, Modbus TCP or CANopen protocols for easy integration.
16. 7-15
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Power
RUN
LED indicators
1P2W-2CT
1P4W-2CT
1P4W-4CT
DO1
DO0
PM-311
RS-485 Interface
PM-3112-100
Modbus RTU, 2 single-phase circuits
Power Meter with 2 CTs (60 A)
PM-3112-160
Modbus RTU, 2 single-phase circuits
Power Meter with 2 CTs (100 A)
PM-3112-240
Modbus RTU, 2 single-phase circuits
Power Meter with 2 CTs (200 A)
Ethernet Interface
PM-3112-100-MTCP
Modbus TCP, 2 single-phase circuits
Power Meter with 2 CTs (60 A)
PM-3112-160-MTCP
Modbus TCP, 2 single-phase circuits
Power Meter with 2 CTs (100 A)
PM-3112-240-MTCP
Modbus TCP, 2 single-phase circuits
Power Meter with 2 CTs (200 A)
CANopen Interface
PM-3112-100-CPS
CANOpen, 2 single-phase circuits Power
Meter with 2 CTs (60 A)
PM-3112-160-CPS
CANOpen, 2 single-phase circuits Power
Meter with 2 CTs (100 A)
PM-3112-240-CPS
CANOpen, 2 single-phase circuits Power
Meter with 2 CTs (200 A)
RS-485 Interface
PM-3114-100
Modbus RTU, 4 single-phase circuits
power meter (60 A)
PM-3114-160
Modbus RTU, 4 single-phase circuits
power meter (100 A)
PM-3114-240
Modbus RTU, 4 single-phase circuits
power meter (200 A)
Ethernet Interface
PM-3114-100-MTCP
Modbus TCP, 4 single-phase circuits
power meter (60 A)
PM-3114-160-MTCP
Modbus TCP, 4 single-phase circuits
power meter (100 A)
PM-3114-240-MTCP
Modbus TCP, 4 single-phase circuits
power meter (200 A)
CANopen Interface
PM-3114-100-CPS
CANOpen, 4 single-phase circuits
power meter (60 A)
PM-3114-160-CPS
CANOpen, 4 single-phase circuits
power meter (100 A)
PM-3114-240-CPS
CANOpen, 4 single-phase circuits
power meter (200 A)
Channel
2: 2 Circuits
4: 4 Circuits
--
CT size (measurement)
100: CTΦ10 mm (0 ~ 60 A)
160: CTΦ16 mm (0 ~ 100 A)
240: CTΦ24 mm (0 ~ 200 A)
Communication
: RS-485
CPS: CANopen
MTCP: Modbus TCP
RS-485 Interface
CANopen Interface
Ethernet Interface
x x xx xx x
110
127
3390
100
37.2
35.6
37.2
6.5
35.6
33
100
90
Rear ViewRight ViewFront View Top ViewLeft View Bottom View
Appearance:
Dimensions (Units: mm):
Selection Guide:
Ordering Information:
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PM-4324/-MTCP/-CPS
PM-4324A/-MTCP/-CPS
Multi-circuit Smart Power Meter
Features:
8 Three Phase Circuits or 24 Single Phase Circuits
True RMS Power Measurements
Energy Analysis for 3P4W, 3P3W, 1P3W, 1P2W
2 Independent main circuit inputs for PM-4324A series
Current Measurements Up to 400 A with Different CT Ratio
Voltage Measurements Up to 500 V
Easy install with split core CT
W Accuracy Better than 0.5% (PF=1)
Support RS-485, Ethernet or CAN bus Interface
Support 2 Power Relay Output (Form A)
Total Harmonic Distortion (THD)
Introduction:
The PM-4324 series multi-circuit power meter monitors up to 8 three-phase circuits or 24 single-phase circuits, or any combination
of single or three-phase circuits. The PM-4324 series can measure up to 24 currents via external Current Transformers (CTs). This
flexibility makes the PM-4324 series perfect for multi-tenant facilities such as residential projects, office buildings and shopping malls.
This compact instrument is designed to easily fit into existing panelboards or be flush mounted nearby, thus eliminating the need for
expensive retrofit projects or for allocating extra space for the device.
The PM-4324A is the same model as the PM-4324, except for the AC Measurement. The PM-4324A has 2 separate main circuit inputs
that can use in the different power system.
Specifications:
Models PM-4324/PM-4324A
PM-4324-MTCP/
PM-4324A-MTCP
PM-4324-CPS/
PM-4324A-CPS
AC Power Measurement
Wiring 3P4W-3CT, 3P3W-2CT, 3P3W-3CT, 1P2W-1CT, 1P3W-2CT
Measurement Voltage 10 ~ 500 V
Measurement Current CTØ10 mm (60 A); CTØ16 mm (100 A); CTØ24 mm (200 A); CTØ36 mm (300 A); CTØ36 mm (400 A)
Measurement Frequency 50/60 Hz
W Accuracy Better than 0.5% (PF=1)
Power Parameter
Measurement
True RMS voltage (Vrms), True RMS current (Irms), Active Power (kW), Active Energy (kWh), Apparent Power
(kVA), Apparent Energy (kVAh),Reactive Power (kVAR), Reactive Energy (kVARh), Power Factor (PF), Frequency
Data Update Rate 1 Second
Communication
Interface RS-485 Ethernet CAN Bus
Protocol Modbus-RTU Modbus TCP CANopen
Baud rate
9600,19200 (default), 38400,
115200; DIP Switch Selectable
-
125 k (default), 250 k, 500 k, 1 M;
DIP Switch Selectable
Data format
N,8,1; N,8,2; E,8,1; E,8,2; O,8,1;
O,8,2
- -
Isolation 3000 VDC - 3000 VDC
Alarm Output
Power Relay Form A (Normal Open) x 2; Relay Contact Voltage Range: 5 A @ 250 VAC (47 ~ 63 Hz), 5 A @ 30 VDC
Power
Input Range +85 ~ +264 VAC
Power Consumption 6 W
Mechanical
Dimensions / Casing 237 mm x 52 mm x 134 mm (W x L x H) / Plastic
Module Installation DIN-Rail Mounting; Wall mounting
Environment
Temperature Operating Temperature: -20 ~ +70˚C / Storage Temperature: -25 ~ +80˚C
Ambient Relative Humidity 10% ~ 90% RH, Non-condensing
18. 7-17
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Appearance:
Selection Guide:
Ordering Information:
-
CT size (measurement)
100P: CTΦ10 mm, 60 A Max.
160P: CTΦ16 mm, 100 A Max.
240P: CTΦ24 mm, 200 A Max.
360P: CTΦ36 mm, 300 A Max.
400P: CTΦ36 mm, 400 A Max.
Current Transformers
(Secondary voltage
333mV)
2 independent main circuit inputs
Communication
: RS-485
CPS: CANopen
MTCP: Modbus TCP
x x PA x x xxPM-4324 -
CANopen Interface
PM-4324-100P-CPS CANOpen, Multi-Circuit Power Meter (60 A) PM-4324A-100P-CPS CANOpen, Multi-Circuit Power Meter (60 A)
PM-4324-160P-CPS CANOpen, Multi-Circuit Power Meter (100 A) PM-4324A-160P-CPS CANOpen, Multi-Circuit Power Meter (100 A)
PM-4324-240P-CPS CANOpen, Multi-Circuit Power Meter (200 A) PM-4324A-240P-CPS CANOpen, Multi-Circuit Power Meter (200 A)
PM-4324-360P-CPS CANopen, Multi-Circuit Power Meter (300 A) PM-4324A-360P-CPS CANopen, Multi-Circuit Power Meter (300 A)
PM-4324-400P-CPS CANopen, Multi-Circuit Power Meter (400 A) PM-4324A-400P-CPS CANopen, Multi-Circuit Power Meter (400 A)
RS-485 Interface
PM-4324P Modbus RTU, Multi-Circuit Power Meter (Can be directly input from the secondary side of 333mV CT)
PM-4324-100P Modbus RTU, Multi-Circuit Power Meter (60 A) PM-4324A-100P Modbus RTU, Multi-Circuit Power Meter (60 A)
PM-4324-160P Modbus RTU, Multi-Circuit Power Meter (100 A) PM-4324A-160P Modbus RTU, Multi-Circuit Power Meter (100 A)
PM-4324-240P Modbus RTU, Multi-Circuit Power Meter (200 A) PM-4324A-240P Modbus RTU, Multi-Circuit Power Meter (200 A)
PM-4324-360P Modbus RTU, Multi-Circuit Power Meter (300 A) PM-4324A-360P Modbus RTU, Multi-Circuit Power Meter (300 A)
PM-4324-400P Modbus RTU, Multi-Circuit Power Meter (400 A) PM-4324A-400P Modbus RTU, Multi-Circuit Power Meter (400 A)
Ethernet Interface
PM-4324-100P-MTCP Modbus TCP, Multi-Circuit Power Meter (60 A) PM-4324A-100P-MTCP Modbus TCP, Multi-Circuit Power Meter (60 A)
PM-4324-160P-MTCP Modbus TCP, Multi-Circuit Power Meter (100 A) PM-4324A-160P-MTCP Modbus TCP, Multi-Circuit Power Meter (100 A)
PM-4324-240P-MTCP Modbus TCP, Multi-Circuit Power Meter (200 A) PM-4324A-240P-MTCP Modbus TCP, Multi-Circuit Power Meter (200 A)
PM-4324-360P-MTCP Modbus TCP, Multi-Circuit Power Meter (300 A) PM-4324A-360P-MTCP Modbus TCP, Multi-Circuit Power Meter (300 A)
PM-4324-400P-MTCP Modbus TCP, Multi-Circuit Power Meter (400 A) PM-4324A-400P-MTCP Modbus TCP, Multi-Circuit Power Meter (400 A)
V2 reference voltage
V1 reference voltage
V1 reference voltage
Up to 24 currents via external
Current Transformers (CTs)
2-CH Relay output
Node ID
Baud rate
AC Measurement
10 ~ 500 V (A, B, C, N)
Aux. Power Input 85 ~ 264 VAC
RS-485
PM-4324A
PM-4324
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● IntroductionCT for Smart Power Meter
38.4±0.3
38.4±0.3
57±0.3
35.7±0.3
57±0.3
35.7±0.3
9.7±0.3
9.7±0.3
19±0.319±0.3
81.5±0.381.5±0.3
15.8±0.3
15.8±0.3
4
4
22±0.3
22±0.3
FrTopViewTT
39
25
23
39
23.3
14.8
26
22 45.5
49
77
24
34.443
47.2
29
32
47
16
10
18
31.5
26
100: CTΦ10mm (60 A Max.)
160: CTΦ16mm (100 A Max.)
240: CTΦ24mm (200 A Max.)
Left View Left View
Left ViewLeft View
Left View
Front View Front View
Front ViewFront View
Front View
360P: CTΦ36mm (300 A Max.)
400P: CTΦ36mm (400 A Max.)
Clip-on CT Installation
Rogowski coil Soft CT Installation
DIN-Rail Mounting
(EX: PM-3133)
RCT1000P: CTΦ800mm (1000 A Max.)
A B C D
A B C
Dimensions (Units: mm):
Installation
20. 7-19
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
Communication
Interface RS-485
Bias Resistor
No (Usually supplied by the RS-485
Master. Or, add a tM-SG4 or SG-785.)
Baud Rate 1200 to 115200 bps
Protocol Modbus RTU, DCON
Dual Watchdog
Yes, Module (1.6 Seconds),
Communication (Programmable)
LED Indicators/Display
System LED Indicator 1 as Power/Communication Indicator
Isolation
Intra-module Isolation,
Field-to-Logic
2500 VDC
EMS Protection
ESD (IEC 61000-4-2)
±4 kV Contact for each Terminal
±8 kV Air for Random Point
EFT (IEC 61000-4-4) ±4 kV for Power Line
Surge (IEC 61000-4-5) ±0.5 kV for Power Line
Power
Reverse Polarity Protection Yes
Input +10 ~ +30 VDC
Consumption 0.9 W
Mechanical
Dimensions (L × W × H) 123 mm × 72 mm × 35 mm
Installation DIN-Rail
Environment
Operating Temperature -25 to +75°C
Storage Temperature -40 to +85°C
Humidity 10 to 95% RH, Non-condensing
Analog Input
Channels 8
Wiring Differential
Input Range
0 ~ +10 Vrms, 0 ~ +5 Vrms,
0 ~ +1 Vrms, 0 ~ +500 mVrms,
0 ~ +150 mVrms
Resolution 16-bit
Accuracy
Sinusoid
50/60 Hz ±0.15% of FSR
45 Hz to 10 kHz ±0.5% of FSR
Non-Sinusoid
Crest Factor = 1 to 2 ±0.2% of FSR
Crest Factor = 2 to 3 ±0.35% of FSR
DC
0 ~ +10 Vrms/ 0 ~ +5
Vrms/ 0 ~ +1 Vrms,
±0.3% of FSR
Other ±0.7% of FSR
Sampling Rate 10 Hz (Total)
-3dB Bandwidth 15.7 Hz
Zero Drift ±20 μV/°C
Span Drift ±25 ppm/°C
Common Mode Rejection 86 dB
Normal Mode Rejection 100 dB
Input Impedance >2 MΩ
Individual Channel Configuration Yes
Overvoltage Protection ±35 VDC
Introduction:
The M-7017RMS is an 8-channel differential AC input module
that is used to convert the AC input signals to their True RMS
DC values. The RMS input range can be from +150 mVrms to
+10 Vrms, and each channel can be configured individually.
The M-7017RMS is a complete, high-accuracy, RMS-to-DC
converter that computes the True RMS DC value of any
complex waveform. It also features 4 kV ESD protection,
2500 VDC intra-module isolation and +/-35 VDC overvoltage
protection.
Applications:
• Building Automation
• Factory Automation
• Machine Automation
• Remote Maintenance
• Remote Diagnosis
• Testing Equipment
System Specifications:
I/O Specifications:
M-7017RMS
8-channel True RMS Input Module
Features:
8-channel True RMS Input
±0.15% Factory Calibrated Accuracy
The RMS input range: +150 mVrms ~ +10 Vrms
For Standard Operation with Frequencies: 45 Hz ~ 10 KHz
Individual Channel Configurable
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● IntroductionDN-800 Series Voltage Attenuator and Current Transformer
DN-844-50A
DN-844-200A
DN-844-500A
DN-831I-100V-50A
DN-831I-100V-200A
DN-831I-100V-500A
DN-843VI-600V
DN-848VI-10V
DN-848VI-80V
DN-848VI-150V
DN-843I-CT-1
DN-843I-CT-10
DN-843I-CT-20
DN-843I-CT-50
Model Input Channel Input Type Input Range CT Type Cable Output
DN-831I-100V-50A
DN-831I-100V-200A
DN-831I-100V-500A
1 × Voltage,
1 × Current
AC/DC
±100 Vpp, ±50 A
Clip-on 1.5 m/3 m ±10 Vpp±100 Vpp, ±200 A
±100 Vpp, ±500 A
DN-843VI-600V 3 × Voltage AC/DC ±600 Vpp N/A N/A ±10 Vpp
DN-848VI-10V
DN-848VI-80V
DN-848VI-150V
8 × Voltage AC/DC
±10 Vpp,
N/A N/A ±10 Vpp±80 Vpp,
±150 Vpp
DN-843I-CT-1
DN-843I-CT-10
DN-843I-CT-20
DN-843I-CT-50
3 × Current AC/DC
±1 A,
Solid Core
(closed)
N/A
±1.6 Vpp,
±10 Vpp,
±10 Vpp,
±4 Vpp
±10 A,
±20 A,
±50 A
DN-844-50A
DN-844-200A
DN-844-500A
4 × Current AC/DC
±50 A,
Clip-on 1.5 m/3 m ±10 Vpp±200 A,
±500 A
The operating current of AC or DC motor
of the machines is converted into +/- 10
Vpp attenuated signal via DN-844, and
then the +/- 10 Vpp signal is converted
based on Modbus / RTU protocol for
seamless integration with all kinds of
PLC or SCADA.
Introduction:
DN-800 series is a Voltage Attenuator and Current Transformer designed for used in high-voltage applications. The current can be
converted into +/- 10 Vpp attenuated signal, so that a general electronic measuring device is able to read the signals. Compared to ICP
DAS power meter products (PM-3033, PM-3133, PM-4324, etc.), in addition to AC signals, the DN-800 series can convert DC signals as
well.
The users can use appropriate ICP DAS Remote I/O Modules such as: M-7017R, I-87017RW, or ET-7217 to measure the converted +/-
10 VDC signal via DN-800 series. And use M-7017RMS or I-87017W-RMS, etc. to measure the AC signals.
sBy using DN-800 series, the power data of all kinds of machines and AC/DC motors can be easily measured and retrieved, and then
the analyzed data can be used to develop a model to build a failure warning system.
Applications:
Appearance and Specifications:
22. 7-21
ICPDAS Product Catalog
ICP DAS CO., LTD. Professional Provider of High Quality Industrial Computer Products and Data Acquisition Systems Vol. FPC 2.05.09
7” Series4.3” Series
TPD-433-PM
VPD-143N-PM
TPD-703-PM
VPD-173-PM
Model No. Description
TPD-433-PM CR 4.3" Industrial Multi-meter TouchPAD, IP40 Waterproof (RoHS)
VPD-143N-PM CR 4.3" Industrial Multi-meter TouchPAD, IP65 Waterproof (RoHS)
TPD-703-PM CR 7" Industrial Multi-meter TouchPAD, IP40 Waterproof (RoHS)
VPD-173-PM CR 7" Industrial Multi-meter TouchPAD, IP65 Waterproof (RoHS)
Industrial Multi-power-meter Display
Features:
Built-in HMI for Information Display of Power Meters
4.3"/7" Colorful Display with Touch Panel
IP40/IP60 Ingress Protection for Front Panel
Built-in Real Time Clock
Support Modbus TCP/RTU Protocols
Support Max. of 8 Single-phase/3-phase Power Meters
(PM-3xxx series) or One PM-4324
Support Max. of 4 Modbus/TCP Connections for
SCADA Software
Support Phase Sequence Detection
Support Fine Tune of Voltage and Current Ratio
Introduction:
The Industrial Multi-power-meter Display features 4.3"/7" high-resolution high-color TFT touch screen and IP40/IP65 warterproof. The
built-in HMI screen pages for the information display of power meter, via the communication mechanism, can automatically display
the meter information without additional programming. The multi-power-meter & multi-circuit device information can be shown in
one display device, customers can now provide the display solution to the local end. Furthermore, the data can be integrated into the
background SCADA control system, not only to get the power information, but also to facilitate the integration and configuration.
Ordering Information:
Meter Configuration Guide: