The document provides a quick reference guide for parameter settings of the P7 Drive. It lists the parameter numbers, factory settings, and space for user settings. There are warnings and cautions provided about safely installing and operating the drive. The introduction describes the drive's applicability for HVAC applications and its communication capabilities.
Tanel Poder - Troubleshooting Complex Oracle Performance Issues - Part 1Tanel Poder
The document describes troubleshooting a complex performance issue in an Oracle database. Key details:
- The problem was sporadic extreme slowness of the Oracle database and server lasting 1-20 minutes.
- Initial AWR reports and OS metrics showed a spike at 18:10 with CPU usage at 66.89%, confirming a problem occurred then.
- Further investigation using additional metrics was needed to fully understand the root cause, as initial diagnostics did not provide enough context about this brief problem period.
The document provides details about a training course on various types of power plants and power management in Bangladesh. It discusses the following:
- An 8-day training course held at Rajshahi Training Center from March 4-10, 2022.
- An overview of the power system including generation, transmission, and distribution.
- Types of power plants in Bangladesh including their fuel sources and total installed capacities. Gas based power plants have the highest share.
- Specific power plants are listed with their locations and fuel sources. These include coal, gas, oil and gas turbine, gas engine, and hydroelectric plants.
- A site visit description of the Katakhali Peaking Power Plant in
Oracle Cloud is Best for Oracle Database - High AvailabilityMarkus Michalewicz
This presentation looks behind the covers and evaluates the offerings provided by various cloud vendors and compares them to the Oracle Database offerings available in the Oracle Cloud. The comparison includes Oracle Database in general, focusing on High Availability (HA) and Disaster Recovery (DR), as those areas have historically distinguished the Oracle Database from other databases and will likely continue to be some of the most distinguishing features when it comes to operating the Oracle Database in the cloud.
Novkabel AD is a cable factory located in Novi Sad, Serbia that was established in 1921. It produces a wide range of energy cables, telecommunication cables, and cables for electronic equipment. The factory occupies 40 hectares and has a production capacity of up to 35,000 tons per year. It focuses on quality and adheres to quality standards and environmental requirements. The goal is to remain a leading company in cable production and distribution by improving sales, expanding markets, and strengthening partnerships. It has developed around 16,000 registered product types through research and development.
Many customers have discovered AWS to be a great environment for running their Windows workloads – making Microsoft licensing compliance critically important. In this session we will look at some of the Microsoft products customers are running on AWS and how they are integrated into their operations. We will also walk through the multitude of licensing options you have and explain how AWS tools can help you achieve Microsoft licensing compliance. Speaker: Allan Knudsen, Business Development Manager, Amazon Web Services
Using 8051 microcontroller based washing machine control pptSangeeth Sb
This document describes the control system of a microcontroller-based washing machine. It includes:
- Descriptions of the control knobs for load selection, water inlet selection, mode selection, and program selection.
- Details of the washing cycles for heavy, normal, light, and delicate settings including fill, agitate, drain, and spin times.
- A circuit diagram showing the 8051 microcontroller and connections to control motors, sensors, and indicators.
- Pseudocode commands for the washing machine controller to check the program selected and run the corresponding cycle before indicating completion.
1) The document is a technical specification sheet for the Goodrive100 inverter model GD100 011G 4, which has an output power of 11kW, AC 3PH 400V input, and AC 3PH 0-400Hz output.
2) It provides details on the inverter components, wiring diagrams, installation instructions, parameters and functions.
3) The specification sheet includes information for installers and technicians on the safe and proper installation and use of the Goodrive100 inverter.
The document provides safety precautions and instructions for operating an inverter. It describes potential hazards such as electric shock, fire, and injury that could occur from improper operation or maintenance. Specific warnings are given for instructions on use, installation, wiring, operation, maintenance, inspection, replacement, and disposal. Operators and maintenance personnel are instructed to read the manual carefully before handling the device to ensure safe use.
The document describes manuals for ACS850 drives and their control program. It lists the ACS850 drive hardware manuals and firmware manual, as well as manuals for optional modules. The firmware manual document provided contains information about the ACS850 control panel layout and functions, operating modes, program features, and safety instructions. Tables of contents and sections within the firmware manual are previewed.
The document provides instructions for the CT-2000F Series AC motor driver from Cutes Corporation. It includes:
1) An introduction and table of contents describing the contents of the manual.
2) Details on inspecting and installing the device, wiring diagrams, terminal specifications, and operation tests.
3) Information on function setup and specifications, alarm displays, troubleshooting, maintenance, and technical specifications.
[1] Install the inverter on a non-flammable surface in an environment that meets specified conditions. [2] Properly ground the inverter and follow recommended wiring practices. [3] Do not operate the inverter if any components are damaged or missing.
This document is the user's manual for ACS310 drives. It begins with a table of contents and list of related manuals. The introduction provides an overview of the manual's purpose and contents. It then covers the drive's operation principle, hardware description, type designation label and installation. Subsequent sections provide planning guidance for the electrical installation, including selecting cables and their routing. It also provides recommendations for protecting the drive and related components.
This document provides instruction manuals for Mitsubishi Electric inverters FR-F740 and FR-F746. It contains safety warnings and instructions, information on transportation and installation, wiring instructions, and operation instructions. The document outlines potential hazards, required environmental conditions, and technical specifications for the inverters. It also describes version changes made to the instruction manuals.
This document provides instructions for setting up and running Unidrive M700 and M701 drives. It covers basic mechanical and electrical installation, getting started procedures like understanding the display and menu structure, and descriptions of basic parameters. Instructions include mounting the drive, making power and control connections, checking firmware versions, navigating the menu to change operating mode and view/save parameters, and taking initial steps to run the motor.
The document provides instructions for the Varispeed G7 general purpose inverter, including safety precautions, component names, installation procedures, wiring diagrams, and descriptions of user constants and functions. It contains information on installing, operating, and maintaining the inverter, with warnings and cautions to ensure proper and safe application.
The document provides contact information for Delta Electronics' headquarters and various regional offices around the world. It also contains safety warnings and instructions for installing Delta's CH2000 series AC motor drives. Key details include danger, caution and note labels regarding working with high voltages, electrostatic sensitivity, proper grounding, and not touching internal circuitry. Dimensional drawings are provided for different frame sizes of the drives.
This document provides operating instructions for a VLT AQUA Drive frequency converter. It describes safety procedures that must be followed when installing and servicing the frequency converter due to the high voltages present. Proper grounding and ensuring capacitors are discharged is critical. The document reviews mechanical installation, electrical installation procedures, start up testing, programming and configuration, application examples, troubleshooting, and specifications. Safety is emphasized throughout as frequency converters require qualified personnel to install and maintain.
This document provides instructions for installing and operating a DELTA VFD-VL Series AC motor drive. It contains safety guidelines that must be followed to prevent injury and damage. The drive uses high-quality components and microprocessor technology. The manual covers installation, wiring, parameter settings, troubleshooting and maintenance. It is important to only allow qualified personnel to work with the drive and always follow the safety warnings.
This document provides instructions for installing and operating a universal variable speed AC drive for elevator systems. It contains safety warnings and describes how to connect the drive to motors, encoders, and other system components. The document also summarizes the lift software functions such as creep-to-floor positioning and direct-to-floor positioning. Installation, I/O configuration, basic operation, and optimizing parameters are covered to help commission the elevator solution.
This document provides warnings, cautions, and instructions for the F7 Drive user manual. It warns that the drive should only be installed and operated by qualified personnel according to the manual and codes. It also cautions against modifying the product. The intended use section explains the drive is for industrial applications and must meet certain EU directives if used in Europe.
This document provides programming instructions for the P7 Drive. It describes the initialization, sequence, and speed reference parameters. The initialization parameters allow selecting the language, access level, and initializing the drive settings. The sequence parameters determine the run command source and speed reference source, which can be set to the digital operator, analog input, serial communication, or option board. The speed reference source sets where the drive receives the speed command signal when in remote mode.
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The document provides installation instructions for DELTA's VFD-C200 Series AC motor drives. It recommends installing drives in a metal cabinet with minimum clearances between drives to prevent overheating. Drives should be installed in pollution degree 2 environments and proper airflow direction must be maintained. When installing multiple drives, a metal separation is required between drives to prevent mutual heating.
- The drive provides motor thermal protection by calculating the I2t. This protects the motor against overloads by tripping the drive if the
calculated motor temperature exceeds a preset threshold.
- However, this protection only considers the motor's thermal time constant and does not account for external cooling such as a fan.
- For motors that rely on external cooling (e.g. fan-cooled motors), additional external protection against overloads is still required.
- The drive's internal I2t protection alone may not be sufficient, as it does not factor in the external cooling and actual motor temperature.
- An external motor protection device that monitors the motor temperature directly is recommended to fully protect fan-cooled motors from
This document provides instructions for safely installing and operating Delta's Hybrid servo drive for plastic injection molding machines. It outlines product specifications, selection guidelines, installation procedures, wiring details, parameter settings, fault diagnosis, maintenance recommendations, and optional accessories. Safety warnings are included to prevent personal injury and equipment damage from improper use.
Here are the typical steps for setting up the Altivar 312 drive:
1. Install and connect the drive mechanically and electrically according to the installation manual. This includes connecting the power supply, motor, control terminals and optional communication cards.
2. Apply power and check that the drive runs correctly with its factory configuration:
- The motor starts correctly
- The direction of rotation and speed are as expected
- No faults or alarms occur
3. Configure the drive for your specific application by adjusting parameters in the necessary menus, such as:
- Motor parameters in the [MOTOR CONTROL] (drC-) menu
- Application functions in the [INPUTS/OUTPUTS CFG] (I
This document provides safety and installation instructions for DELTA's VFD-E Series AC motor drive. It contains guidelines for receiving, inspecting, preparing, and installing the drive. The user must read all safety instructions carefully before installation, as improper use could result in injury or equipment damage. Only qualified personnel should perform installation, start-up and maintenance of the drive. The document outlines the drive components and features, including input/output terminals, indicators, switches and ports.
This document provides safety guidelines and instructions for installing and operating an AC motor drive. It explains that the drive should only be installed by qualified personnel who have read the manual. Several dangers are listed, including lethal voltages that can remain after power is turned off. Correct grounding, wiring and motor selection are emphasized. Troubleshooting tips and maintenance guidelines are also included to ensure safe and proper operation of the equipment.
The document provides safety instructions for installing an AC motor drive. It states that power must be disconnected before wiring, capacitors can hold hazardous voltages even after power is turned off, and sensitive components can be damaged by static electricity. It instructs the user to ground the drive properly, not install it in hot or hazardous areas, and only allow qualified persons to perform installation and maintenance.
This document provides installation and operation instructions for the SSM23Q/IP integrated step-servo motor. It includes:
1. An overview of the motor's features such as torque capabilities, control modes, inputs/outputs, and Ethernet communication.
2. Instructions for installing the necessary software, mounting the motor, and choosing an appropriate power supply.
3. Details on connecting the power supply, connecting the motor to a PC over Ethernet, and descriptions of the input and output connections.
4. Contact information for support.
This document provides technical data for Control Techniques Commander SE variable speed drives. It includes power ratings, current and voltage specifications, efficiency and cooling information for Size 1 and Size 2 drive models. Recommendations are provided for supply fuses, cable sizes and braking resistors. Safety is emphasized, including warnings about high voltages and currents, stored electrical energy, and ensuring personnel safety in system design.
The document provides an introduction and programming guide for the VLT HVAC Basic Drive FC 101 frequency converter. It contains information on safety, programming methods using the local control panel or MCT 10 Setup Software, menus and parameters. The guide describes how to program operation, load and motor settings, digital and analog I/O, communications options and application functions. It also contains troubleshooting information and lists all adjustable parameters and their default settings.
The document provides an overview of the VLT AutomationDrive FC 302, including:
1) Product specifications such as power ratings, dimensions, and enclosure views for different sizes.
2) Safety information and instructions for qualified personnel regarding installation, commissioning and maintenance.
3) Descriptions of the interior components including the control shelf, local control panel, terminals, and optional items.
This document provides safety guidelines and instructions for installing and operating DELTA's VFD-VE Series AC motor drive. It describes receiving and inspecting the drive, preparing for installation including ambient conditions and dimensions, wiring considerations, digital keypad operation, parameter settings, troubleshooting, and maintenance. Safety warnings are provided regarding electrical hazards and qualified personnel.
This document provides a quick start guide for installing, starting up, and programming a PowerFlex 400 Adjustable Frequency AC Drive. It summarizes the basic steps and safety precautions required. For full installation instructions and technical specifications, users should refer to the detailed PowerFlex 400 User Manual. The guide covers mounting considerations, wiring requirements, input/output specifications, and agency certifications for the drive.
This document is an installation and operation manual for Conext CL 18000NA and Conext CL 25000NA three phase grid tie inverters. It provides safety information and guidelines for installing, operating, and maintaining the inverters. The manual is intended for use by qualified personnel and contains specifications, procedures, and troubleshooting information to safely install and set up the inverter systems.
This document provides a user guide for an IP66/Nema 4X rated variable speed drive for controlling AC motors. It discusses safety information and warnings, describes the drive's environmental and electrical characteristics, and lists its optional components. The guide contains information to help ensure the drive is properly installed and commissioned according to regulations.
This document is an instruction manual for the CT-2000V inverter produced by Cutes Corporation. It provides details on:
- Inspecting the inverter upon receiving
- Proper storage and installation procedures
- Wiring diagrams and specifications for connecting the main circuit and motor
- Recommendations for fitting an ACL to the power input side under certain conditions
The manual contains 9 chapters that cover topics such as keypad operation, parameter settings, control modes, protective functions, and serial communication protocols.
The document provides instructions for the CT-2000PLUS Series AC Motor Driver. It includes an introduction, table of contents, and sections on inspection upon receiving, installation and storage, application notes, block diagram and wiring, operation test, function setup and specification, alarm display indications, troubleshooting, maintenance and inspection, standard specifications, function code table, Modbus address of display data, and series communication user manual. The document provides detailed guidance on setup, wiring, operation, maintenance and specifications for the CT-2000PLUS AC motor driver unit.
This document provides instructions for installing and operating an inverter. It includes wiring diagrams, terminal specifications, installation guidelines, and descriptions of operation modes and functions. Chapters cover installation, operation and autotuning, settings, control modes, protective functions, specifications, and more. The document aims to ensure proper use of the inverter.
This document provides instructions for the CT-2000ES inverter unit. It includes:
1) An overview of inspection, installation, storage, dimensions and application notes for the inverter unit.
2) Details on wiring the main and control circuits, connecting the power supply and motor, and using a power source reactor and brake resistor.
3) Instructions for operation testing and adjusting functions via the keypad, including display specifications and function codes.
4) Descriptions of alarm displays, troubleshooting, maintenance, specifications and communication protocols.
This document provides manuals and documentation for ABB industrial drives firmware. It includes a list of related English language manuals for ACS880 drives hardware, firmware, options, and accessories. The table of contents shows that the manual covers topics like control locations and operating modes, programmable features, motor control, application control, safety functions, diagnostics, and more. Contact ABB for any manuals not available online.
This document is a manual for the ACS800 Standard Control Program firmware. It provides instructions on starting up and controlling the drive through input/output, using the control panel, and descriptions of key program features such as the start-up assistant, local vs external control, reference types and processing, reference trimming, and programmable analogue inputs. The manual contains chapters covering these topics and provides technical details, parameters, and examples to explain the drive's operation and programming.
This document provides the user's manual for ABB component drives ACS150 drives ranging from 0.37 to 4 kW (0.5 to 5 hp). It includes a list of related manuals, a table of contents, and sections covering safety, an introduction to the manual, the operation principle and hardware description, mechanical installation, planning the electrical installation, and electrical installation. The manual provides instructions and specifications for installing, commissioning, and operating the ACS150 drives.
This manual provides instructions for installing, starting up, and operating the ACH550-01 drive. It includes details on:
1. Preparing for installation, including drive identification, frame sizes, motor compatibility, and wiring considerations.
2. Installing the drive, including mounting, power and control wiring based on enclosure type.
3. Starting up and using the control panel to access operating modes, parameters, assistants and more.
4. Configuring application macros for common HVAC applications.
5. Using the real-time clock and timer for timed functions.
6. Configuring serial communications via embedded or external fieldbus options.
7. Lists and descriptions for all drive parameters.
This document provides information about ABB industrial drives firmware manual for the ACQ810 standard pump control program. It includes the following:
- A table of contents listing the chapters and sections within the manual.
- Descriptions of the ACQ810 control panel features, layout, and basic operations.
- An explanation of local control vs external control of the drive.
- Details about the pump control program features like PID control, sleep function, soft pipefill, autochange, flow calculation, and protective functions.
- Information on programming the control interfaces, motor control functions, and configurable parameters.
The manual provides installation and configuration instructions for using the ACQ810 drive firmware to implement standard
This document provides information about safety instructions and programming for an ACS 600 frequency converter, including:
- Safety warnings for working with high voltages when installing or servicing the converter. Proper precautions such as allowing capacitors to discharge must be followed.
- An overview of how the converter is programmed using parameters, macros, and a control panel. The control panel allows viewing signals, modifying parameters, and running macros.
- Descriptions of the standard application macros that are included for common control configurations like factory automation or hand/auto control. Wiring diagrams and the function of inputs/outputs are explained for each macro.
This document is the user manual for ABB's ACS550 low voltage AC drive. It provides information on installing, starting up, using embedded fieldbus communication, diagnostics, maintenance and technical specifications for the ACS550 drive. The manual contains sections on safety, installation, start-up, embedded fieldbus communication, fieldbus adapter communication, diagnostics, maintenance and technical data. It provides installation instructions, parameter listings and descriptions, commissioning guidance, troubleshooting help and specifications.
This document provides manuals for ACS550 adjustable speed AC drives including safety, installation, start-up, diagnostics, and maintenance information. It contains details on preparing for installation such as checking motor compatibility, protecting the motor winding and bearings, routing cables, installing the drive, and checking the installation. Technical specifications and drawings are also included to aid in the selection and installation of the appropriate drive model.
This document provides manuals and instructions for ABB general machinery drives. It includes:
1. A list of related manuals delivered with ABB drives in printed or PDF format, including the ACS355 user's manual.
2. An overview of the ACS355 user's manual, which covers safety, mechanical installation, electrical installation, start-up and control.
3. Details about additional option manuals and maintenance manuals available from ABB.
The document describes manuals for ACS850 drives and their control program. It lists the ACS850 drive hardware manuals and firmware manual, as well as manuals for optional modules. The firmware manual document provided contains information about the ACS850 control panel layout and functions, operating modes, program features, and parameter settings. Safety instructions and a table of contents are also included.
The document provides installation and safety instructions for an AC drive (ACS55) for controlling the speed of 3-phase AC induction motors from 0.18 to 2.2 kW. Key steps include checking the delivery, ensuring a suitable installation environment, mounting the unit, setting DIP switches to match the motor and application, connecting power and motor cables, and setting the speed reference. Safety warnings advise only allowing a competent electrician to install the drive and never working on the drive or motor with power applied due to dangerous voltages present even when stopped.
This document provides safety instructions for LS Variable Frequency Drives. It begins by defining different safety symbols used in the manual and on the equipment. It then provides warnings and cautions for safe installation, operation and maintenance. The document covers proper handling, wiring, environmental conditions, trial runs, operation precautions and maintenance procedures. It aims to prevent injury, electric shock and equipment damage.
The document provides an overview and instructions for an LS Variable Frequency Drive inverter model SV-iP5A. It discusses safety instructions, component specifications, installation procedures, operation instructions, parameter settings, troubleshooting tips, and communication protocols. Safety symbols and precautions are defined at the beginning. Installation, wiring and operational guidelines are provided to safely set up and use the inverter. Technical specifications are given for various power ratings. Parameter details allow for customizing the inverter's functions and applications.
1) This document provides safety instructions and operating precautions for using an LS Variable Frequency Drive. It outlines potential hazards and proper safety procedures to prevent accidents.
2) Warnings and cautions are provided throughout regarding electric shock, improper wiring, operating errors, environmental conditions, and maintenance procedures.
3) Quick reference guides are included at the beginning and end to help users understand specifications, installation, operation, parameters, troubleshooting and more for maximizing performance of the inverter.
This document provides instructions for the proper use and maintenance of an SV-iV5 series inverter. It describes the inverter's specifications, installation procedures, operation instructions, and maintenance guidelines. Safety instructions are provided throughout and cover proper handling, transportation, wiring, operation and storage of the inverter. The document instructs users to read it fully before operating the inverter to understand its functions and parameters.
The document provides safety instructions and operational guidelines for the LS Variable Frequency Drive. It begins with danger, warning, and caution symbols to indicate the seriousness of safety hazards. It then lists various safety precautions regarding removing covers, exposed high voltage terminals, wiring, grounding, environmental conditions, and more. The document also provides operating instructions, maintenance procedures, and general guidelines for proper use.
AI and Best Use Cases for Your Personal Life.pptxBrian Frerichs
THIS SLIDE PROVIDES A BRIEF OVERVIEW OF THE TOPIC AND THE KEY AREAS THAT WILL BE COVERED IN THE PRESENTATION ON HOW AI CAN BE LEVERAGED FOR PERSONAL LIFE APPLICATIONS.
This case study underscores upGrad's role in reshaping education through internet-driven innovation, illustrating its commitment to empowering learners and fostering career growth in the digital age.
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As the world spins on its axis, the constant ebb and flow of current events, technological advancements, and social trends shape our daily lives. Here are the top five predictions for today that are set to influence various facets of our global society:
1. AI Integration in Daily Life
Artificial Intelligence (AI) continues to embed itself deeper into our everyday routines. Today, expect to see more AI-driven solutions in sectors like healthcare, finance, and education. Personalized learning experiences powered by AI algorithms are becoming mainstream, while in healthcare, AI is aiding in early diagnosis and personalized treatment plans. Financial institutions are increasingly relying on AI for fraud detection and customer service automation.
2. Stock Market Fluctuations Amid Economic Uncertainty
The stock market remains a rollercoaster, reflecting global economic uncertainties. Inflation concerns, geopolitical tensions, and shifting monetary policies are likely to cause significant fluctuations. Investors should brace for a volatile day as markets react to new economic data and policy announcements. Keep an eye on tech stocks, which are particularly sensitive to changes in interest rates and investor sentiment.
3. Climate Action and Environmental Policies
With climate change becoming an ever-pressing issue, today's headlines will likely feature significant climate action. Governments and organizations are set to announce new policies and initiatives aimed at reducing carbon footprints and promoting sustainable practices. From renewable energy investments to stricter emission regulations, these efforts are critical in the global fight against climate change.
4. Breakthroughs in Medical Research
The field of medical research is on the cusp of several groundbreaking discoveries. Today, we anticipate announcements of advancements in treatments for chronic diseases such as cancer, diabetes, and neurodegenerative disorders. Innovative therapies, including gene editing and personalized medicine, are set to offer new hope for patients worldwide. These breakthroughs not only promise to improve health outcomes but also to revolutionize medical practices.
5. Social Media Trends and Digital Influences
Social media platforms continue to shape public opinion and cultural trends. Today, expect new viral challenges, influencer endorsements, and social justice movements gaining traction online. With platforms like TikTok and Instagram driving much of the digital conversation, brands and public figures will leverage these channels to connect with audiences and promote their messages. Be prepared for a flood of new content that could spark debates and inspire collective action.
As these predictions unfold, they will undoubtedly impact various aspects of our lives. Staying informed and adaptable is key to navigating the rapid changes in today's dynamic world.
1. **Team Strength**:
- Seasoned discoverers with mineral finds of >$1Bn (silver), >42Mozs (gold), >12Blbs (copper)
- $8.75M recently raised for aggressive exploration
- 30% management ownership aligns interests
2. **High-Grade Discovery**:
- 2021 re-discovery: 75Moz at 980g/t AgEq (silver-zinc-lead)
- Objective: Prove continuity between high-grade discovery and existing gold-silver mine
- Potential for a gigantic, continuous deposit
3. **Proven Production Area**:
- Site of one of Alaska's first open-pit gold mines
- Existing 43-101 resource: ~500,000 oz AuEq, mostly indicated
4. **Carbonate Replacement Deposit (CRD) Advantages**:
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- Metallurgically simple, minimal environmental impact
- Strategic metals (Zn, Ga) could expedite permitting
5. **Massive Potential**:
- Two polymetallic deposits potentially linked
- Extensive mineralization corridor to be confirmed by drilling
Key Takeaway: High-grade discovery with potential for a giant, continuous CRD deposit, backed by a proven team and existing resources in a mining-friendly jurisdiction.
2024's Top Chief Revenue Officers to Follow.pdfTHECIOWORLD
He exemplifies this approach by his unshakable commitment to generating results and his relentless drive, as evidenced by his over 15 years of experience in the industry. As an accomplished professional in the diversified industry of telecommunications, his story illustrates the power of enthusiasm and tenacity to propel success.
IRDAI's Regulatory Sandbox - Transforming Insurance Sector in IndiaEnterslice
The IRDAI Regulatory Sandbox is a groundbreaking initiative that allows insurers and innovators to test new ideas in a safe environment before rolling them out widely. This blog explores how the IRDAI Regulatory Sandbox is encouraging innovation while ensuring consumer protection in India's insurance sector.
The report provides detailed insights into project economics, including capital investments, project funding, operating expenses, income and expenditure projections, fixed costs vs. variable costs, direct and indirect costs, expected ROI and net present value (NPV), profit and loss account, financial analysis, etc.
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3. Warnings i
Warnings and Cautions
This Section provides warnings and cautions pertinent to this product, that if not
heeded, may result in personal injury, fatality, or equipment damage. Yaskawa is
not responsible for consequences of ignoring these instructions.
YASKAWA manufactures component parts that can be used in a wide variety of industrial applications. The selection and
application of YASKAWA products remain the responsibility of the equipment designer or end user. YASKAWA accepts no
responsibility for the way its products are incorporated into the final system design. Under no circumstances should any
YASKAWA product be incorporated into any product or design as the exclusive or sole safety control. Without exception, all
controls should be designed to detect faults dynamically and fail safely under all circumstances. All products designed to
incorporate a component part manufactured by YASKAWA must be supplied to the end user with appropriate warnings and
instructions as to that part’s safe use and operation. Any warnings provided by YASKAWA must be promptly provided to the
end user. YASKAWA offers an express warranty only as to the quality of its products in conforming to standards and
specifications published in the YASKAWA manual. NO OTHER WARRANTY, EXPRESS OR IMPLIED, IS OFFERED.
YASKAWA assumes no liability for any personal injury, property damage, losses, or claims arising from misapplication of its
products.
• Read and understand this manual before installing, operating, or servicing this Drive. All warnings, cautions, and
instructions must be followed. All activity must be performed by qualified personnel. The Drive must be installed according
to this manual and local codes.
• Do not connect or disconnect wiring while the power is on. Do not remove covers or touch circuit boards while the power is
on. Do not remove or insert the digital operator while power is on.
• Before servicing, disconnect all power to the equipment. The internal capacitor remains charged even after the power supply
is turned off. Status indicator LEDs and Digital Operator display will be extinguished when the DC bus voltage is below
50 VDC. To prevent electric shock, wait at least five minutes after all indicators are OFF and measure DC bus voltage level
to confirm safe level.
• Do not perform a withstand voltage test on any part of the unit. This equipment uses sensitive devices and may be damaged
by high voltage.
• The Drive is not suitable for circuits capable of delivering more than the specified RMS symmetrical amperes. Install
adequate branch short circuit protection per applicable codes. Refer to the specification. Failure to do so may result in
equipment damage and/or personal injury.
• Do not connect unapproved LC or RC interference suppression filters, capacitors, or overvoltage protection devices to the
output of the Drive. These devices may generate peak currents that exceed Drive specifications.
• To avoid unnecessary fault displays caused by contactors or output switches placed between Drive and motor, auxiliary
contacts must be properly integrated into the control logic circuit.
• YASKAWA is not responsible for any modification of the product made by the user; doing so will void the warranty. This
product must not be modified.
• Verify that the rated voltage of the Drive matches the voltage of the incoming power supply before applying power.
• To meet CE directives, proper line filters and proper installation are required.
WARNING
WARNING
4. Warnings ii
• Some drawings in this manual may be shown with protective covers or shields removed, to describe details. These must be
replaced before operation.
• Observe electrostatic discharge procedures when handling circuit cards to prevent ESD damage.
• The equipment may start unexpectedly upon application of power. Clear all personnel from the drive, motor, and machine
area before applying power. Secure covers, couplings, shaft keys, and machine loads before energizing the Drive.
• Please do not connect or operate any equipment with visible damage or missing parts. The operating company is responsible
for any injuries or equipment damage resulting from failure to heed the warnings in this manual.
Intended Use
Drives are intended for installation in electrical systems or machinery.
For use in the European Union, the installation in machinery and systems must conform to the following product standards of
the Low Voltage Directive:
EN 50178, 1997-10, Equipping of Power Systems with Electronic Devices
EN 60201-1, 1997-12 Machine Safety and Equipping with Electrical Devices
Part 1: General Requirements (IEC 60204-1:1997)/
EN 61010, 1997-11Safety Requirements for Information Technology Equipment
(IEC 950:1991 + A1:1992 + A2:1993 + A3:1995 + A4:1996, modified)
CE certification per EN 50178 can be achieved using the line filters specified in this manual and following the appropriate
installation instructions.
Other
The Drive is suitable for use on a circuit capable of delivering not more than 100,000 RMS symmetrical amperes, 240Vac max-
imum (240V Class) and 480Vac maximum (480V Class).
WARNING
5. Introduction iii
Introduction
This Section describes the applicability of the Manual
The P7 Drive is a Pulse Width Modulated Drive for 3-Phase AC induction motors. This type of Drive is also known as an
Adjustable Frequency Drive, Variable Frequency Drive, AC Drive, AFD, ASD, VFD, and Inverter. In this manual, the P7
Drive will be referred to as the “Drive”.
The Drive is a variable torque AC drive, designed specifically for HVAC applications in building automation, including fans,
blowers and pumps. A new benchmark for size, cost, performance, benefits, and quality, the Drive includes numerous
built-in features such as network communications, PI, parameter storage and copy functions.
The Drive has embedded communications for Modbus®
protocol. An optional LONWORKS
®
interface card is also available.
The LCD keypad/operator is equipped with local/remote functions, copy feature, 7 language choices, and 5 lines of display
with 16 characters per line. User parameter settings can be recovered at any time via “user initialization”. Optional software
allows upload/download, as well as graphing and monitoring of drive parameters from a PC for ease of drive management.
Built-in PI control eliminates the need for closed loop output signals from a building automation system. It includes feedback
display, inverse, square root and differential control functions, and maintains setpoint for closed loop control of fans and
pumps for pressure, flow, or temperature regulation.
This manual is applicable to Drives defined by model numbers CIMR-P7U_ _ _ _ . This manual reflects the Software
Version 1020.
This manual is subject to change as product improvements occur. The latest version of the manual can be obtained from the
Yaskawa website www.drives.com . The date shown on the rear cover is changed when revisions are made.
6. Introduction iv
This manual may describe trademarked equipment, which is the property of other companies. These trademarks are the
property of the registered owner companies and may include the following:
Modbus®
, trademark of Schneider Automation, Inc.
LONWORKS
®
, trademark of Echelon Corporation
Other Documents and Manuals are available to support special use or installation of this product. These documents may be
provided with the product or upon request. Contact Yaskawa Electric America, Inc. as required. Documents may include the
following:
TM.P7.02.Programming… Manual included on CD ROM with product
TM.AFD.11.Modbus… Manual included on CD ROM with product
TM.AFD.20.LONWORKS… Manual included on CD ROM with product
TM.P7B.01. Bypass… This manual should be used when the Drive is packaged with Bypass Control
DriveWizard ... Software and Manual…Included on CD ROM with product
Option Instructions… Included on CD ROM with product
7. Table of Contents v
Table of Contents
Quick Reference Parameter List....................................................... Inside front cover
Warnings and Cautions................................................................................................ i
Introduction .................................................................................................................iii
Chapter 1- Physical Installation ................................................................................1-1
Model Number and Enclosure Style.........................................................................1-2
Confirmations Upon Delivery ...................................................................................1-3
Component Names ..................................................................................................1-5
Exterior and Mounting Dimensions ..........................................................................1-7
Heat Loss Data ......................................................................................................1-11
Checking and Controlling the Installation Site........................................................1-13
Installation Orientation and Clearances .................................................................1-14
Removing and Attaching the Terminal Cover.........................................................1-15
Removing/Attaching the Digital Operator and Front Cover....................................1-16
Chapter 2- Electrical Installation...............................................................................2-1
Terminal Block Configuration ...................................................................................2-2
Wiring Main Circuit Terminals...................................................................................2-3
Control Wiring ........................................................................................................2-21
Chapter 3- Digital Operator........................................................................................3-1
Digital Operator Display ...........................................................................................3-2
Digital Operator Keys...............................................................................................3-3
Drive Mode Indicators ..............................................................................................3-4
Drive Main Menu......................................................................................................3-6
Quick Setting Menu (-QUICK-)...............................................................................3-11
Programming Menu (-ADV-)...................................................................................3-12
Example of Changing a Parameter........................................................................3-14
8. Table of Contents vi
Chapter 4- Start Up.....................................................................................................4-1
Drive Start Up Preparation .......................................................................................4-2
Drive Start Up Procedures .......................................................................................4-5
Chapter 5- Basic Programming.................................................................................5-1
A1 Initialization......................................................................................................... 5-2
b1 Sequence............................................................................................................ 5-4
b2 DC Braking.......................................................................................................... 5-9
b3 Speed Search ................................................................................................... 5-11
b5 PI Function........................................................................................................5-15
b8 Energy Savings.................................................................................................5-24
C1 Accel/Decel.......................................................................................................5-25
d2 Reference (Speed Command) Limits................................................................5-26
d3 Jump Frequencies.............................................................................................5-27
E1 V/f pattern .........................................................................................................5-28
E2 Motor Setup ......................................................................................................5-31
F6 Com OPT Selection ..........................................................................................5-32
H3 Analog Inputs....................................................................................................5-33
L2 Momentary Power Loss Ride-thru Function......................................................5-39
L3 Stall Prevention .................................................................................................5-40
L4 Speed Command Loss Detection......................................................................5-43
L5 Fault Restart......................................................................................................5-44
L6 Torque Detection...............................................................................................5-46
L8 Hardware Protection .........................................................................................5-48
o1 Monitor Configuration........................................................................................5-50
o2 Key Selections ..................................................................................................5-54
o3 Digital Operator Copy Function.........................................................................5-56
T1 Auto-Tuning ......................................................................................................5-59
9. Table of Contents vii
Chapter 6- Diagnostic & Troubleshooting .............................................................. 6-1
Fault Detection......................................................................................................... 6-2
Alarm Detection........................................................................................................ 6-8
Operator Programming Errors (OPE)..................................................................... 6-11
Auto-Tuning Faults.................................................................................................6-12
Digital Operator COPY Function Faults .................................................................6-13
Troubleshooting .....................................................................................................6-14
Main Circuit Test Procedure...................................................................................6-20
Drive Date Stamp Information................................................................................6-24
Chapter 7- Maintenance.............................................................................................7-1
Periodic Inspection................................................................................................... 7-2
Preventative Maintenance........................................................................................ 7-3
Heatsink Cooling Fan Replacement......................................................................... 7-4
Removing and Mounting the Terminal Card............................................................. 7-6
Appendix A - Parameters.......................................................................................... A-1
Parameter List..........................................................................................................A-2
Monitor List.............................................................................................................A-25
Fault Trace List ......................................................................................................A-27
Fault Trace History.................................................................................................A-28
Appendix B - Capacity Related Parameters............................................................ B-1
Drive Capacity Selection..........................................................................................B-2
Parameters Affected by o-04 ...................................................................................B-3
Appendix C - Specifications..................................................................................... C-1
Standard Drive Specification ................................................................................... C-2
10. Table of Contents viii
Appendix D - Communications ................................................................................ D-1
Using Modbus Communication ............................................................................... D-2
Modbus Function Code Details............................................................................... D-7
Modbus Data Tables ............................................................................................... D-9
Modbus Self- Diagnosis ........................................................................................ D-14
Appendix E - Peripheral Devices ............................................................................. E-1
Branch Circuit Short Circuit Protection.....................................................................E-2
Branch Circuit Overload Protection..........................................................................E-5
Peripheral Devices...................................................................................................E-6
Appendix F - EMC Compatibility ...............................................................................F-1
EMC Compatibility....................................................................................................F-2
Electromagnetic Compatibility (EMC) ......................................................................F-3
Index .................................................................................................................... Index-1
Support Services................................................................................ Inside rear cover
11. Physical Installation 1 - 1
Chapter 1
Physical Installation
This chapter describes the requirements for receiving and installing the Drive.
Model Number and Enclosure Style ....................................1-2
Confirmations upon Delivery ...............................................1-3
Component Names..............................................................1-5
Exterior and Mounting Dimensions......................................1-7
Heat Loss Data..................................................................1-11
Checking and Controlling the Installation Site ...................1-13
Installation Orientation and Clearances.............................1-14
Removing and Attaching the Terminal Cover ....................1-15
Removing/Attaching the Digital Operator
and Front Cover.................................................................1-16
12. Physical Installation 1 - 2
Model Number and Enclosure Style
Table 1.1 Model Numbers and Enclosure Style
Input
Voltage
3-Phase
Model-Number EnclosureStyle
Rated
Output
Current
Nominal
Hp
208-240Vac
CIMR-P7U20P4 NEMA Type 1 (IP20) 3.6 0.5/0.75
CIMR-P7U20P7 NEMA Type 1 (IP20) 4.6 1
CIMR-P7U21P5 NEMA Type 1 (IP20) 7.8 1.5/2
CIMR-P7U22P2 NEMA Type 1 (IP20) 10.8 3
CIMR-P7U23P7 NEMA Type 1 (IP20) 16.8 5
CIMR-P7U25P5 NEMA Type 1 (IP20) 23.0 7.5
CIMR-P7U27P5 NEMA Type 1 (IP20) 31.0 7.5/10
CIMR-P7U2011 NEMA Type 1 (IP20) 46.2 15
CIMR-P7U2015 NEMA Type 1 (IP20) 59.4 20
CIMR-P7U2018 NEMA Type 1 (IP20) 74.8 25
CIMR-P7U2022 NEMA Type 1 (IP20) 88.0 30
CIMR-P7U2030 NEMA Type 1 (IP20) 115.0 40
208-230Vac
CIMR-P7U2037 Open Chassis (IP00) 162.0 50/60
CIMR-P7U2045 Open Chassis (IP00) 192.0 60/75
CIMR-P7U2055 Open Chassis (IP00) 215.0 75
CIMR-P7U2075 Open Chassis (IP00) 312.0 100/125
CIMR-P7U2090 Open Chassis (IP00) 360.0 125/150
CIMR-P7U2110 Open Chassis (IP00) 415.0 150
480Vac
CIMR-P7U40P4 NEMA Type 1 (IP20) 1.8 0.5/0.75
CIMR-P7U40P7 NEMA Type 1 (IP20) 2.1 1
CIMR-P7U41P5 NEMA Type 1 (IP20) 3.7 1.5/2
CIMR-P7U42P2 NEMA Type 1 (IP20) 5.3 3
CIMR-P7U43P7 NEMA Type 1 (IP20) 7.6 5
CIMR-P7U45P5 NEMA Type 1 (IP20) 12.5 7.5
CIMR-P7U47P5 NEMA Type 1 (IP20) 17.0 10
CIMR-P7U49P0 NEMA Type 1 (IP20) 21.0 15
CIMR-P7U4011 NEMA Type 1 (IP20) 27.0 20
CIMR-P7U4015 NEMA Type 1 (IP20) 34.0 25
CIMR-P7U4018 NEMA Type 1 (IP20) 40.0 30
CIMR-P7U4024 NEMA Type 1 (IP20) 52.0 40
CIMR-P7U4030 NEMA Type 1 (IP20) 67.2 50
CIMR-P7U4037 NEMA Type 1 (IP20) 77.0 60
CIMR-P7U4045 NEMA Type 1 (IP20) 96.0 75
CIMR-P7U4055 NEMA Type 1 (IP20) 125.0 100
CIMR-P7U4075 Open Chassis (IP00) 156.0 125
CIMR-P7U4090 Open Chassis (IP00) 180.0 150
CIMR-P7U4110 Open Chassis (IP00) 240.0 200
CIMR-P7U4160 Open Chassis (IP00) 304.0 250
CIMR-P7U4185 Open Chassis (IP00) 414.0 300/350
CIMR-P7U4220 Open Chassis (IP00) 515.0 400/450
CIMR-P7U4300 Open Chassis (IP00) 675.0 500+
13. Physical Installation 1 - 3
Confirmations upon Delivery
Receiving Checks
Check the following items as soon as the Drive is received.
If there are any irregularities in the above items, contact the shipping company, the distributor or representative who sold the
Drive, or a Yaskawa office immediately.
The P7 is thoroughly tested at the factory. Any damages or shortages evident when the equipment is received must be reported
immediately to the commercial carrier that transported the material. Shipping damage is not covered by the Yaskawa warranty.
After unpacking and inspecting for damage, verify that internal wire connections have not come loose during shipment by spot
checking wire terminations with a screwdriver or the appropriate tool.
P7 Drive storage must be in a clean and dry location. Maintain the factory packaging and provide covering as needed to
protect the P7 from construction site dirt, water, debris and traffic prior to and during construction.
Nameplate Information
A nameplate is attached to the right side of each Drive. The following nameplate is an example for a standard Drive.
Fig 1.1 Drive Nameplate
Table 1.2 Receiving Checks
Item Method
Has the correct model of Drive been
delivered?
Check the model number on the nameplate on the right side of the Drive.
Reconcile with packing slip and/or order information.
Is the Drive damaged in any way?
Inspect the entire exterior of the Drive to see if there are any dents, scratches or
other damage resulting from shipping.
Are any screws or other components
loose?
Use a screwdriver or other tool to check for tightness.
Note: The Drive Model Number and Drive Spec Number are required to completely identify a Drive.
14. Physical Installation 1 - 4
Drive Model Numbers
The model number on the nameplate indicates the design specification, voltage, and rating of the Drive in alphanumeric codes.
Fig 1.2 Drive Model Number Structure
Drive Enclosure and Revision Code
The Drive SPEC number on the nameplate indicates the voltage, Drive rating, enclosure type, and the revision code of the
Drive in alphanumeric codes.
Fig 1.3 SPEC Number Structure
TERMS
Open Chassis Type (IEC IP00)
Protected so that parts of the human body cannot reach electrically charged parts from the front when the
Drive is mounted in a control panel, also called (protected chassis).
NEMA Type 1 (IEC IP20)
The Drive is shielded from the exterior, and can thus be mounted to the interior wall of a building
(not necessarily enclosed in a control panel). The protective structure conforms to the standards of NEMA
Type 1 in the USA. All protective covers (Fig 1.4) must be installed to conform with IEC IP20 and NEMA Type
1 requirements.
No. Spec
UL Specification
CIMR – P7 U 2 0 11
AC Drive
U
No. Voltage
2
4
3-phase, 208-240Vac
3-phase, 480Vac
Rating
P7 Family
2 011 1 A
No.
2
4
Voltage
3-phase, 208 - 240Vac
3-phase, 480Vac
No. Enclosure Type
0 Open chassis (IEC IP00)
1 NEMA Type 1 (IEC IP20)
Hardware Revision
Rating
15. Physical Installation 1 - 5
Component Names
Models CIMR-P7U20P4 thru 2018 (25HP @ 208V/240V) and 40P4 thru 4018
(30HP @ 480V)
The external appearance, component names, and terminal arrangement of the Drive are shown in Fig 1.4. and 1.5.
Fig 1.4 Drive Appearance
Fig 1.5 Terminal Arrangement (Terminal Cover Removed)
Top protective cover
Front cover
Digital Operator
NameplateTerminal cover
Diecast Heat Sink
Mounting hole
Bottom protective cover
16. Physical Installation 1 - 6
Models CIMR-P7U2022 thru 2110 (30HP and above @ 208V/240V) and 4030 thru
4300 (40HP and above @ 480V)
The external appearance, component names, and terminal arrangement of the Drive are shown in Fig 1.6 and 1.7.
Fig 1.6 Drive Appearance
Fig 1.7 Terminal Arrangement (Terminal Cover Removed)
Mounting holes
Cooling fan
Nameplate
Drive cover
Front cover
Digital Operator
Terminal cover
Mounting holes
Cooling fan
Nameplate
Drive cover
Front cover
Digital Operator
Terminal cover
Charge indicator
Control circuit
terminals
Main circuit
terminals
Ground terminal Ground terminal
19. Physical Installation 1 - 9
14.17
13.78
13.78
14.96
11.81
12.99192
215
162
312
360
162
192
415
20750
20370
20450
20900
21100
20370
20450
20550
2.4617.72 .4912.8027.56 28.54100
33.46
34.84
32.28
33.66
125
50-60
75
150
14.57
17.52
19.69
22.64 .59
.59 2.56
2.56
28.54
23.62
23.62
27.56
22.64
22.6460
75
50
12.80
9.84
9.84
17.72
14.76
14.76
.49
.49
.49
2.46
2.46
2.46
5.12 3/8
5.12
5.51
3/8
3/8
3.94
5.12
5.12
3/8
3/8
3/8
191
238
330
125
189
139
33.66
27.56
27.56
32.28
304
360
15640750
41100
41600
40900
20900
20750
150
250
200
125
150
240
180
100-125312
28.54
36.06
33.46
28.54
12.80
17.52
14.57
12.80
22.64
19.69
17.72
17.72
.59
.59
.49
.49 196
352
224
194
5.12
5.12
5.51
5.12
13.78
14.96
14.17
13.78
2.56
2.56
2.46
2.46 3/8
3/8
3/8
3/8
22.64 23.629.84 14.76 .49 1253.9411.812.46 3/8
22.64 23.629.84 14.76 .49 1395.1212.992.46 3/8
27.56 28.5412.80 17.72 .49 1915.1213.782.46 3/8
32.28 33.4614.57 19.69 .59 2385.1214.172.56 3/8
W1
H1 H
H2
W
W2
AIR
AIR
D1
D
DIMENSIONS: P7 (PROTECTED CHASSIS)
FOR REFERENCE ONLY UNLESS PROPERLY ENDORSED.
APPVL.
DR BY
MOUNTING HOLES
FOR "A" SIZE SCREW
FRONT VIEW
RIP 9.29.04
TA 9.29.04
DIMENSIONS IN INCHES
OUTPUT
CURRENT
RATED
(AMPS)
480V
INPUT
RATED
208V
230V
MODEL
MOUNTINGHP
NOM.
H1 W1
H W H2 W2 D
CIMR-P7U
D1 A
APPROX.
WEIGHT
(LBS.)
5 INCHES TOP AND BOTTOM
OF FREE AIR SPACE OF 1.2 INCHES ON SIDES AND
THE DRIVE MUST BE POSITIONED TO ALLOW A MINIMUM
IN ORDER TO ACHIEVE ADEQUATE COOLING
480V (156-304 AMPS)
208-230V (162-415 AMPS)
20. Physical Installation 1 - 10
16.34
16.34
16.34515
675
41441850
42200
43000 58.07
51.38
51.38
56.70
50.00
50.00400-450
500
300-350
14.37
10.63
10.63
36.06
27.95
27.95
.79
.79
.79
3.66
3.35
3.35
4.94
4.94
4.94
3/8
3/8
3/8
572
891
616
W
W1 W1W2
HH1
H2
AIR
D1
D
AIR
RIP 8-02
TBS 9.5.02
IN ORDER TO ACHIEVE ADEQUATE COOLING
THE DRIVE MUST BE POSITIONED TO ALLOW A MINIMUM
OF FREE AIR OF 1.2 INCHES ON SIDES AND
5 INCHES TOP AND BOTTOM
DIMENSIONS IN INCHES
OUTPUT
CURRENT
RATED
(AMPS)
INPUT
RATED
480V
MODEL
MOUNTING
HP
NOM.
H1 W1
H W H2 W2 D
CIMR-P7U
D1 A
APPROX.
WEIGHT
(LBS.)
MOUNTING HOLES
FOR "A" SIZE SCREWS
DIMENSIONS: P7 (PROTECTED CHASSIS)
FOR REFERENCE ONLY UNLESS PROPERLY ENDORSED.
APPVL.
DR BY
21. Physical Installation 1 - 11
Heat Loss Data
Table 1.3 200V Class Heat Loss Data
TYPE
CIMR-P7U
Drive
(Inverter)
Capacity
(kVA)
Rated
Output
Current
(A)
Cooling
Fin Side
(W)
Internal
UnitSide
(W)
Total
Watt
Loss
(W)
Cooling
Method
20P4 1.4 3.6 19 39 58 Self
20P7 1.8 4.6 26 42 68 Self
21P5 3.0 7.8 48 50 98 Self
22P2 4.1 10.8 68 59 127 Self
23P7 6.4 16.8 110 74 184 Fan
25P5 8.8 23 164 84 248 Fan
27P5 12 31 219 113 332 Fan
2011 18 46.2 357 168 524 Fan
2015 23 59.4 416 182 597 Fan
2018 29 74.8 472 208 680 Fan
2022 34 88 583 252 835 Fan
2030 44 115 883 333 1217 Fan
2037 62 162 1010 421 1430 Fan
2045 73 192 1228 499 1727 Fan
2055 82 215 1588 619 2206 Fan
2075 120 312 1956 844 2800 Fan
2090 140 360 2194 964 3157 Fan
2110 160 415 2733 1234 3967 Fan
22. Physical Installation 1 - 12
Table 1.4 400V Class Heat Loss Data
TYPE
CIMR-P7U
Drive
(Inverter)
Capacity
(kVA)
Rated
Output
Current
(A)
Cooling
Fin Side
(W)
Internal
UnitSide
(W)
Total
Watt
Loss
(W)
Cooling
Method
40P4 1.4 1.8 14 39 53 Self
40P7 1.6 2.1 17 41 58 Self
41P5 2.8 3.7 36 48 84 Self
42P2 4.0 5.3 59 56 115 Fan
43P7 5.8 7.6 80 68 140 Fan
44P0 6.6 8.7 90 70 160 Fan
45P5 9.5 12.5 127 81 209 Fan
47P5 13 17 193 114 307 Fan
49P0 16 21 232 158 390 Fan
4011 21 27 232 158 390 Fan
4015 26 34 296 169 465 Fan
4018 30 40 389 201 590 Fan
4022 38 50.4 420 233 653 Fan
4024 40 52 691 297 989 Fan
4030 51 67.2 691 297 989 Fan
4037 59 77 801 332 1133 Fan
4045 73 96 901 386 1287 Fan
4055 95 125 1204 478 1682 Fan
4075 120 156 1285 562 1847 Fan
4090 140 180 1614 673 2287 Fan
4110 180 240 1889 847 2736 Fan
4132 200 260 2388 1005 3393 Fan
4160 230 304 2636 1144 3936 Fan
4185 315 414 2791 1328 3964 Fan
4220 390 515 3797 1712 5509 Fan
4300 510 675 5838 2482 8319 Fan
23. Physical Installation 1 - 13
Checking and Controlling the Installation Site
Install the Drive as described below and maintain optimum conditions.
Installation Site
Locate the P7 Drive as close as possible to the motor.
Install the Drive under the following conditions in UL Pollution Degree 1 & 2 environments. This excludes wet locations
where surfaces may become conductive due to moisture and contaminant loading.
Protective covers are attached to the top and bottom of the Drive. It is recommended to remove the protective covers before
operating a CIMR-P7U2030/4055 Drive and smaller in a panel to obtain the 113°F (45°C) ambient operating temperature.
Observe the following precautions when installing the Drive:
• in a clean location which is free from oil mist and dust.
• in an environment where metal shavings, oil, water, or other foreign materials will not get into the Drive enclosure.
• in a location free from radioactive materials.
• in a location free from harmful gasses and liquids.
• in a location free from excessive vibration.
• in a location free from chlorides.
• in a location away from direct sunlight.
• on a non-combustible surface.
Controlling the Ambient Temperature
To enhance the reliability of operation, the Drive should be installed in an environment free from extreme temperature
variations. If the Drive is installed in an enclosure, use a cooling fan or air conditioner to maintain the internal air temperature
below 113°F (45°C).
Protecting the Drive from Foreign Matter
During Drive installation and project construction it is possible to have foreign matter, such as metal shavings or wire
clippings, fall inside the Drive. To prevent foreign matter from falling into the Drive, place a temporary cover over the Drive.
Always remove the temporary cover from the Drive before Start-Up. Otherwise, ventilation will be reduced, causing the Drive
to overheat.
WARNING
The Drive heatsink temperature may exceed 158°F (70°C). Therefore, mount the Drive to a surface suitable
for high temperature.
Table 1.5 Installation Site Specifications
Type Ambient Operating Temperature Humidity Plenum Rated
NEMA Type 1 14°F-to-104°F (-10-to-+40°C) 95%-RH-or-less-(no-condensation) Yes
Open Chassis 14°F-to-113°F (-10-to-+45°C) 95%-RH-or-less-(no-condensation) No
24. Physical Installation 1 - 14
Installation Orientation and Clearances
Install the Drive vertically so as not to reduce the cooling efficiency. When installing the Drive, always provide the following
installation clearances to allow normal heat dissipation. Ensure that the heatsink is against a closed surface to avoid diverting
cooling air around the heatsink.
Fig 1.8 Drive Installation Orientation and Clearance
IMPORTANT
1. The same clearance is required horizontally and vertically for both Open Chassis (IP00) and NEMA
Type 1 Drives.
2. Always remove the top and bottom protection covers before installing a CIMR-P7U2018/4018 and
smaller Drive in a panel.
Always provide enough clearance for lifting eye bolts and the main circuit wiring when installing a
CIMR-P7U2022/4030 and larger Drive in a panel.
4.75 in (120 mm. minimum)
4.75 in (120 mm. minimum)
Air
Air
Vertical ClearanceHorizontal Clearance
1.2 in
(30.5 MM.) min.
1.2 in
(30.5 mm. minimum)
1.2 in
(30.5 mm. minimum)
4.75 in (50 mm. minimum)
4.75 in (120 mm. minimum)
25. Physical Installation 1 - 15
Removing and Attaching the Terminal Cover
Remove the terminal cover to connect cables to the control circuit and main circuit terminals.
Removing the Terminal Cover
Models CIMR-P7U20P4 thru 2018 (0.5HP to 25HP @ 208V/240V) and 40P4 thru 4018
(0.5HP to 30HP @ 480V)
Loosen the screw at the bottom of the terminal cover, press in on the sides of the terminal cover in the directions of arrow 1,
and then lift up on the terminal in the direction of arrow 2. Refer to Figure 1.9
Models CIMR-P7U2022 thru 2110 (30HP to 150HP @ 208V/240V) and 4030 thru 4300
(40HP to 500HP @ 480V)
Loosen the screws on the left and right at the top of the terminal cover, pull down the terminal cover in the direction of arrow
1 and then lift up on the terminal cover in the direction of arrow 2. Refer to Figure 1.10
Fig 1.9 Removing the Terminal Cover
Fig 1.10 Removing the Terminal Cover
Attaching the Terminal Cover
After wiring the terminal block, attach the terminal cover by reversing the removal procedure.
For Models CIMR-P7U2018/4018 and smaller, insert the tab on the top of the terminal cover into the groove on the Drive and
press in on the bottom of the terminal cover until it snaps into place.
For Drives CIMR-P7U2022/4030 and larger, insert the tab on the top of the terminal cover into the groove on the Drive, and
secure the terminal cover by lifting it up toward the top of the Drive.
WARNING
Prior to removing any protective cover or wiring any part of the Drive, remove all power sources, including
main input power and control circuit power. Wait a minimum of 5 minutes after power removal, before
removing any cover. The charge lamp located within the Drive should be off prior to working inside. Even if
the charge lamp is off, one must measure the AC input, output, and DC Bus potential to insure safe levels
prior to resuming work. Failure to adhere to this warning may result in personal injury or death.
1
2
26. Physical Installation 1 - 16
Removing/Attaching the Digital Operator and Front Cover
Models CIMR-P7U20P4 thru 2018 (0.5HP to 25HP @ 208V/240V) and 40P4 thru
4018 (0.5HP to 30HP @ 480V)
For Models CIMR-P7U2018/4018 and smaller, remove the terminal cover and then use the following procedures to remove
the Digital Operator and front cover.
Removing the Digital Operator
Press on the side of the Digital Operator in the direction of arrow 1 to unlock, then lift the Digital Operator in the direction of
arrow 2 to remove it as shown in Fig 1.11.
Fig 1.11 Removing the Digital Operator
Removing the Front Cover
Press the left and right sides of the front cover in the direction of arrows 1 and lift the bottom of cover in the direction of arrow
2 to remove it as shown in Fig 1.12.
Fig 1.12 Removing the Front Cover
Attaching the Front Cover
Mount the front cover to the Drive by performing the steps to remove the front cover in reverse order.
1.Do not mount the front cover with the Digital Operator attached to the front cover; this may cause the Digital Operator to
malfunction due to imperfect contact.
2.Insert the tab of the upper part of the front cover into the groove of the Drive and press the lower part of the front cover onto
the Drive until the front cover snaps into place.
2
1
1
2
27. Physical Installation 1 - 17
Models CIMR-P7U2022 thru 2110 (30HP to 150HP @ 208V/240V) and 4030 thru
4300 (40HP to 500HP @ 480V)
For Models CIMR-P7U2022/4030 and larger, remove the terminal cover and then use the following procedures to remove the
Digital Operator and front cover.
Removing the Digital Operator
Use the same procedure for Models CIMR-P7U2018/4018 and smaller.
Removing the Front Cover
Loosen all screws on the front cover. Lift up at the location labeled 1 at the top of the control circuit terminal card and move in
the direction of arrow 2.
Fig 1.13 Removing the Front Cover
Attaching the Front Cover
Attach the front cover by reversing the procedure to remove it.
1.Confirm that the Digital Operator is not mounted on the front cover. Contact faults can occur if the cover is attached while
the Digital Operator is mounted to it.
2.Insert the tab on the top of the front cover into the slot on the Drive and press in on the cover until it snaps into place on the
Drive.
1
2
28. Physical Installation 1 - 18
Attaching the Digital Operator
After attaching the front cover, mount the Digital Operator onto the Drive using the following procedure.
1.Hook the Digital Operator at A (two locations) on the front cover by moving in the direction of arrow 1 as shown in the
following illustration.
2.Press the Digital Operator in the direction of arrow 2 until it snaps in place at B (two locations).
Fig 1.14 Mounting the Digital Operator
IMPORTANT
1. Do not remove or attach the Digital Operator or mount or remove the front cover using methods other
than those described above, damage to the Digital Operator or Drive may occur.
2. Never attach the front cover to the Drive with the Digital Operator attached to the front cover. Damage to
the Digital Operator may occur. Always attach the front cover to the Drive first, and then attach the Digital
Operator to the front cover.
A
B
1
2
29. Electrical Installation 2 - 1
Chapter 2
Electrical Installation
This chapter describes wiring terminals, main circuit terminal connections, main
circuit terminal wiring specifications, control circuit terminals, and control circuit
wiring specifications.
Terminal Block Configuration .............................................2-2
Wiring Main Circuit Terminals............................................ 2-3
Control Wiring ................................................................. 2-21
30. Electrical Installation 2 - 2
Terminal Block Configuration
The wiring terminals are shown in Fig 2.1.
Fig 2.1 Control Circuit Terminal Layout
Models CIMR-_ _ _2018 (25 HP, 208V)/
4018 (30 HP, 480V) and smaller
Models CIMR-_ _ _2022 (30 HP, 208V)/
4030 (40 HP, 480V) and larger
AC MP
AMS6
-V
IG
R- M5
FM
R+RP
S1 S4
SP
S7 M4
+V
S3
SC
S+
A2
M2
SN M6
AC
A1
E(G) E(G)
MCMB
S5 M1
AC MA
M3S2 S-
AC MP
AMS6
-V
IG
R- M5
FM
R+RP
S1 S4
SP
S7 M4
+V
S3
SC
S+
A2
M2
SN M6
AC
A1
E(G) E(G)
MCMB
S5 M1
AC MA
M3S2 S-
Ground terminal
Ground terminal
Ground terminal
Ground terminal
Charge indicator
Charge indicator
Main circuit terminals
Main circuit terminals
Control circuit terminals
Control circuit terminals
35. Electrical Installation 2 - 7
4185 300/350
R/L1, S/L2, T/L3, , 1 M8
88.5
(10.0)
300 X 2P
(152 X 2P)
600Vac
UL Approved
vinyl-sheathed
or equivalent
U/T1, V/T2, W/T3, R1/L11, S1/L21, T1/L33 M8
88.5
(10.0)
300 X 2P
(152 X 2P)
3 M8
88.5
(10.0)
2/0
(67.4)
M16
867.4
(98.0)
3/0 X 2P
(85 X 2P)
r/l1, s200/l2200, s400/l2400 M4
12.4
(1.4)
14
(2.1)
4220 400/450
R/L1, S/L2, T/L3, , 1 M8
88.5
(10.0)
500 X 2P
(253 X 2P)
U/T1, V/T2, W/T3, R1/L11, S1/L21, T1/L33 M8
88.5
(10.0)
400 X 2P
(203 X 2P)
3 M8
88.5
(10.0)
2/0
(67.4)
M16
867.4
(98.0)
250 X 2P
(127 X 2P)
r/l1, s200/l2200, s400/l2400 M4
12.4
(1.4)
14
(2.1)
4300 500+
R/L1, S/L2, T/L3, , 1 M8
88.5
(10.0)
700 X 2P
(355 X 2P)
U/T1, V/T2, W/T3, R1/L11, S1/L21, T1/L33 M8
88.5
(10.0)
600 X 2P
(304 X 2P)
3 M8
88.5
(10.0)
2/0
(67.4)
M8
867.4
(98.0)
400 X 2P
(203 X 2P)
r/l1, s200/l2200, s400/l2400 M16
12.4
(1.4)
14
(2.1)
* Use 75°C copper wire or equivalent.
IMPORTANT
Determine the wire size for the main circuit so that line voltage drop is within 2% of the rated voltage. Line
voltage drop is calculated as follows:
Line voltage drop (V) = x wire resistance (Ω/km) x wire length (m) x current (A) x 10-3
Table 2.2 480Vac Wire Sizes and Connector Specifications
Drive Model
CIMR-P7U
Nominal
Hp
Terminal Symbol
Terminal
Screws
Clamping
Torque
lb. in.
(N•m)
Recommended
Wire Size AWG
(mm2)
Wire Type
3
WARNING
Prior to removing any protective cover or wiring any part of the Drive, remove all power sources, including
main input power and control circuit power. Wait a minimum of 5 minutes after power removal, before
removing any cover. The charge lamp located within the Drive should be off prior to working inside. Even if
the charge lamp is off, one must measure the AC input, output, and DC Bus potential to insure safe levels
prior to resuming work. Failure to adhere to this warning may result in personal injury or death.
36. Electrical Installation 2 - 8
Main Circuit Terminal Functions
Main circuit terminal functions are summarized according to terminal symbols in Table 2.3. Wire the terminals correctly for
the desired purpose.
Table 2.3 Main Circuit Terminal Functions (208-240Vac and 480Vac)
Purpose Terminal Designation
Model: CIMR-P7U_ _ _ _
208-240Vac 480Vac
Main circuit power input
R/L1, S/L2, T/L3 20P4 to 2110 40P4 to 4300
R1/L11, S1/L21, T1/L31 2022 to 2110 4030 to 4300
Drive outputs U/T1, V/T2, W/T3 20P4 to 2110 40P4 to 4300
DC power input 1, 20P4 to 2110 40P4 to 4300
Braking Transistor
Unit Connection 3, 2022 to 2110 4030 to 4300
Braking Resistor
Unit Connection
B1, B2 20P4 to 2018 40P4 to 4018
DC reactor connection 1, 2 20P4 to 2018 40P4 to 4018
Ground 20P4 to 2110 40P4 to 4300
37. Electrical Installation 2 - 9
Main Circuit Configurations 208-240Vac
The 208-240Vac main circuit configurations of the Drive are shown in Table 2.4.
Table 2.4 Drive Main Circuit Configurations
208-240Vac
---
Note1. Input fuses or molded case circuit breakers are required for proper branch circuit protection for all Drives. Failure
to use recommended fuses/circuit breakers (See Appendix E) may result in damage to the wiring, Drive and/or
personal injury.
2. Control power is supplied internally from the main circuit DC power supply for all Drives.
3. Consult your Yaskawa representative before using 12-pulse rectification.
Power
supply
Control
circuits
{
CIMR-_ _ _ 20P4 to 2018
(1/2 Hp to 25 Hp)
1
Note
Power
supply
Control
circuits
{Notes
1 & 3
CIMR-_ _ _ 2037 to 2110
(50 Hp to 150 Hp)
Power
supply
Control
circuits
{Notes
1 & 3
CIMR-_ _ _ 2022 and 2030
(30 Hp to 40 Hp)
38. Electrical Installation 2 - 10
Main Circuit Configurations 480Vac
The 480Vac main circuit configurations of the Drive are shown in Table 2.5.
Table 2.5 Drive Main Circuit Configurations
480Vac
---
Note1. Input fuses or molded case circuit breakers are required for proper branch circuit protection for all Drives. Failure
to use recommended fuses/circuit breakers (See Appendix E) may result in damage to the wiring, Drive and/or
personal injury.
2. Control power is supplied internally from the main circuit DC power supply for all Drives.
3. Consult your Yaskawa representative before using 12-pulse rectification.
Power
supply
Control
circuits
{
CIMR-_ _ _ 40P4 to 4018
(1/2 Hp to 30 Hp)
Note
1
CIMR-_ _ _ 4024 to 4055
(40 Hp to 100 Hp)
Power
supply
Control
circuits
{Notes
1 & 3
Power
supply
Control
circuits
{Notes
1 & 3
3
CIMR-_ _ _ 4075 to 4160 and CIMR-_ _ _ 4185 to 4300
(125 Hp to 500 Hp)
39. Electrical Installation 2 - 11
Cable Length between Drive and Motor
The P7 should be installed as close as possible to the motor to minimize the length of load side power cable. If the cable
between the Drive and the motor is long, the high-frequency leakage current will increase, causing the Drive output current to
increase as well. This may affect peripheral devices. To prevent this, reduce the cable length whenever possible, or if
necessary, adjust the carrier frequency (set in C6-02) as shown in Table 2.6.
Ground Wiring
Observe the following precautions when connecting the ground wire:
1. 208-240Vac Drives should have a ground connection with resistance of less than 100Ω.
2. 480Vac Drives should have a ground connection with resistance of less than 10Ω.
3. Do not share the ground wire with other devices, such as motors or large-current electrical equipment.
4. Always use a ground wire that complies with technical standards on electrical equipment and minimize the length of the
ground wire. Leakage current flows through the Drive. Therefore, if the distance between the ground rod and the ground
terminal is too long, potential on the ground terminal of the Drive will become unstable.
5. When using more than one Drive, be careful not to loop the ground wire. See Fig 2.2.
Fig 2.2 Ground Wiring Examples
Control Circuit Ground Terminals
The removable Drive control terminal card provides two ground terminals (marked TB3 and TB4) to accept the control wire
shield connection. The control wire shield should be connected on this end only, the opposite end should be isolated with
electrical tape.
Table 2.6 Motor Cable Length vs. Carrier Frequency (C6-02)
Motor Cable Length 164 ft. (50m) maximum 328 ft. (100m) maximum More than 328 ft.(100m)
Carrier Frequency 15kHz maximum 10kHz maximum 5kHz maximum
IMPORTANT Grounding of the P7 enclosure and motor is required for proper system operation.
NO
OK NOT OK
40. Electrical Installation 2 - 12
Dynamic Braking Connections
General
Dynamic braking (DB) enables the motor to be brought to a smooth and rapid stop. This is achieved by dissipating the
regenerative energy of the AC motor across the resistive components of the Dynamic Braking option. For further details on
dynamic braking operation, see the instruction sheet shipped with dynamic braking components.
Drives P7U20P4 thru P7U2018 and P7U40P4 thru P7U4018 have an integral braking transistor and require the addition of a
Remote Mounted Resistor Unit or a Heat Sink Mount Resistor (ERF). All higher rated Drives require the use of a Braking
Transistor Unit (CDBR) and a Remote Mount Resistor Unit.
Remote Mount Resistor Units typically mount outside of the electrical enclosure. Braking Transistor Units mount inside of the
electrical enclosure. Heat Sink Mount Resistors mount to the back of the Drive, attaching directly to the heat sink.
Installation
This option should only be installed by a technically qualified individual who is familiar with this type of equipment and the
hazards involved.
Hazardous voltages can cause severe injury or death. Lock all power sources feeding the Drive in the “OFF” position.
Failure to follow these installation steps may cause equipment damage or personal injury.
Preliminary Procedures
1. Disconnect all electrical power to the Drive.
2. Remove Drive front cover.
3. Use a voltmeter to verify that voltage is disconnected from incoming power terminals and that the DC bus has dissipated.
Table 2.7 Heat Sink Mount Dynamic Braking Resistor - 3% Duty Cycle
Drive Heat Sink Mount Resistor
Rated
Input
Vac
Drive
Model No.
P7U
Part No.
Qty.
Reqd.
Resistance
(Ohms)
Power
(Watts)
Approx.
Braking
Torque
(%)
Dimensions (Inches)
Height Width Depth
208-240
20P4 R7505 1 200 150 220 7.16 1.73 0.51
20P7 R7505 1 200 150 125 7.16 1.73 0.51
21P5 R7504 1 100 150 125 7.16 1.73 0.51
22P2 R7503 1 70 150 120 7.16 1.73 0.51
23P7 R7510 1 62 150 100 7.16 1.73 0.51
480
40P4 R7508 1 750 150 230 7.16 1.73 0.51
40P7 R7508 1 750 150 130 7.16 1.73 0.51
41P5 R7507 1 400 150 125 7.16 1.73 0.51
42P2 R7506 1 115 150 115 7.16 1.73 0.51
43P7 R7505 1 200 150 110 7.16 1.73 0.51
WARNING
41. Electrical Installation 2 - 13
Fig 2.3 230V Rated Braking Transistor and Resistor Units
Duty and HP Required Dynamic Braking Units and Resistors Typical Performance
Braking
Duty
Motor Voltage and
Power Rating
Required Dynamic
Braking Units:
Resistance and
rms Current Rating
Additional Required
Dynamic Braking Units:
Resistance and rms
Current Rating
Peak Braking
Power
Average
Braking Power
Standard
Duty:
150%
Peak
Braking
Power
12%
Average
Braking
Power
230VAC
15HP 1 of CDBR-2022B 9.00 ohm 12.0A 154% of 15HP 12.5% of 15HP
20HP 1 of CDBR-2022B 6.80 ohm 16.0A 152% of 20HP 12.5% of 20HP
25HP 2 of CDBR-2022B 9.00 ohm 12.0A 183% of 25HP 14.8% of 25HP
30HP 2 of CDBR-2022B 9.00 ohm 12.0A 152% of 30HP 12.3% of 30HP
40HP 2 of CDBR-2022B 6.80 ohm 16.0A 151% of 40HP 12.4% of 40HP
50HP 1 of CDBR-2110B 2.10 ohm 50.0A 194% of 50HP 14.8% of 50HP
60HP 1 of CDBR-2110B 2.10 ohm 50.0A 162% of 60HP 12.3% of 60HP
75HP 1 of CDBR-2110B 1.60 ohm 64.0A 169% of 75HP 12.3% of 75HP
100HP 1 of CDBR-2110B 1.60 ohm 64.0A and 1 of CDBR-2022B 6.80 ohm 16.0A 156% of 100HP 11.6% of 100HP
125HP 1 of CDBR-2110B 1.60 ohm 64.0A and 2 of CDBR-2022B 6.80 ohm 16.0A 148% of 125HP 11.2% of 125HP
150HP 2 of CDBR-2110B 1.60 ohm 64.0A 167% of 150HP 12.1% of 150HP
Heavy
Duty:
150%
Peak
Braking
Power
50%
Average
Braking
Power
230VAC
15HP 2 of CDBR-2022B 18.0 ohm 12.0A 154% of 15HP 49.8% of 15HP
20HP 2 of CDBR-2022B 13.6 ohm 16.0A 152% of 20HP 49.9% of 20HP
25HP 1 of CDBR-2110B 4.20 ohm 50.0A 197% of 25HP 60.0% of 25HP
30HP 1 of CDBR-2110B 4.20 ohm 50.0A 163% of 30HP 49.9% of 30HP
40HP 1 of CDBR-2110B 3.20 ohm 64.0A 160% of 40HP 46.5% of 40HP
50HP 2 of CDBR-2110B 4.20 ohm 50.0A 194% of 50HP 59.4% of 50HP
60HP 2 of CDBR-2110B 4.20 ohm 50.0A 162% of 60HP 49.4% of 60HP
75HP 2 of CDBR-2110B 3.20 ohm 64.0A 169% of 75HP 49.1% of 75HP
100HP 3 of CDBR-2110B 3.20 ohm 64.0A 189% of 100HP 55.0% of 100HP
125HP 4 of CDBR-2110B 4.20 ohm 50.0A 153% of 125HP 46.8% of 125HP
150HP 4 of CDBR-2110B 3.20 ohm 64.0A 167% of 150HP 48.6% of 150HP
‘Decel’
Duty:
150%
Peak
Braking
Power
6%
Average
Braking
Power
230VAC
15HP 1 of CDBR-2022B 9.00 ohm 09.2A 154% of 15HP 7.3% of 15HP
20HP 1 of CDBR-2022B 6.80 ohm 11.6A 152% of 20HP 6.6% of 20HP
25HP 2 of CDBR-2022B 9.00 ohm 09.2A 183% of 25HP 8.7% of 25HP
30HP 2 of CDBR-2022B 9.00 ohm 09.2A 152% of 30HP 7.2% of 30HP
40HP 2 of CDBR-2022B 6.80 ohm 11.6A 151% of 40HP 6.5% of 40HP
50HP 1 of CDBR-2110B 2.10 ohm 36.0A 194% of 50HP 7.7% of 50HP
60HP 1 of CDBR-2110B 2.10 ohm 36.0A 162% of 60HP 6.4% of 60HP
75HP 1 of CDBR-2110B 1.60 ohm 46.0A 169% of 75HP 6.3% of 75HP
100HP 1 of CDBR-2110B 1.60 ohm 46.0A and 1 of CDBR-2022B 6.80 ohm 11.6A 156% of 100HP 6.0% of 100HP
125HP 1 of CDBR-2110B 1.60 ohm 46.0A and 2 of CDBR-2022B 6.80 ohm 11.6A 148% of 125HP 5.8% of 125HP
150HP 2 of CDBR-2110B 1.60 ohm 46.0A 167% of 150HP 6.3% of 150HP
42. Electrical Installation 2 - 14
Fig 2.4 480V Rated Braking Transistor and Resistor Units
Duty and HP Required Dynamic Braking Units and Resistors Typical Performance
Braking
Duty
Motor Voltage
and Power Rating
Required Dynamic
Braking Units:
Resistance and
rms Current Rating
Additional Required
Dynamic Braking Units:
Resistance and rms
Current Rating
Peak Braking
Power
Average
Braking Power
Standard
Duty:
150%
Peak
Braking
Power
12%
Average
Braking
Power
480VAC
30HP 1 of CDBR-4045B 18.0 ohm 12.1A 152% of 30HP 12.5% of 30HP
40HP 1 of CDBR-4045B 13.6 ohm 16.0A 151% of 40HP 12.4% of 40HP
50HP 2 of CDBR-4045B 18.0 ohm 12.1A 182% of 50HP 14.9% of 50HP
60HP 2 of CDBR-4045B 18.0 ohm 12.1A 151% of 60HP 12.4% of 60HP
75HP 2 of CDBR-4045B 13.6 ohm 16.0A 159% of 75HP 13.0% of 75HP
100HP 1 of CDBR-4220B 4.20 ohm 50.0A 192% of 100HP 14.7% of 100HP
125HP 1 of CDBR-4220B 4.20 ohm 50.0A 153% of 125HP 11.7% of 125HP
150HP 1 of CDBR-4220B 3.20 ohm 64.0A 167% of 150HP 12.1% of 150HP
200HP 1 of CDBR-4220B 3.20 ohm 64.0A and 1 of CDBR-4045B 13.6 ohm 16.0A 154% of 200HP 11.5% of 200HP
250HP 1 of CDBR-4220B 3.20 ohm 64.0A and 2 of CDBR-4045B 13.6 ohm 16.0A 146% of 250HP 11.1% of 250HP
300HP 2 of CDBR-4220B 3.20 ohm 64.0A 166% of 300HP 12.0% of 300HP
400HP 2 of CDBR-4220B 4.20 ohm 50.0A and 1 of CDBR-4220B 3.20 ohm 64.0A 156% of 400HP 11.7% of 400HP
500HP 3 of CDBR-4220B 3.20 ohm 64.0A 148% of 500HP 10.7% of 500HP
Heavy
Duty:
150%
Peak
Braking
Power
50%
Average
Braking
Power
480VAC
30HP 2 of CDBR-4045B 36.0 ohm 12.1A 152% of 30HP 50.1% of 30HP
40HP 2 of CDBR-4045B 27.2 ohm 16.0A 151% of 40HP 49.4% of 40HP
50HP 1 of CDBR-4220B 8.40 ohm 50.0A 194% of 50HP 59.4% of 50HP
60HP 1 of CDBR-4220B 8.40 ohm 50.0A 162% of 60HP 49.4% of 60HP
75HP 1 of CDBR-4220B 6.40 ohm 64.0A 169% of 75HP 49.1% of 75HP
100HP 2 of CDBR-4220B 8.40 ohm 50.0A 192% of 100HP 58.8% of 100HP
125HP 2 of CDBR-4220B 8.40 ohm 50.0A 153% of 125HP 46.8% of 125HP
150HP 2 of CDBR-4220B 6.40 ohm 64.0A 167% of 150HP 48.6% of 150HP
200HP 3 of CDBR-4220B 6.40 ohm 64.0A 187% of 200HP 54.4% of 200HP
250HP 4 of CDBR-4220B 8.40 ohm 50.0A 152% of 250HP 46.3% of 250HP
300HP 4 of CDBR-4220B 8.40 ohm 50.0A 126% of 300HP 38.5% of 300HP
400HP 5 of CDBR-4220B 8.40 ohm 50.0A 118% of 400HP 36.0% of 400HP
500HP 6 of CDBR-4220B 6.40 ohm 64.0A 148% of 500HP 42.9% of 500HP
‘Decel’
Duty:
150%
Peak
Braking
Power
6%
Average
Braking
Power
480VAC
30HP 1 of CDBR-4045B 18.0 ohm 08.5A 152% of 30HP 6.2% of 30HP
40HP 1 of CDBR-4045B 13.6 ohm 11.6A 151% of 40HP 6.5% of 40HP
50HP 2 of CDBR-4045B 18.0 ohm 08.5A 182% of 50HP 7.4% of 50HP
60HP 2 of CDBR-4045B 18.0 ohm 08.5A 151% of 60HP 6.1% of 60HP
75HP 2 of CDBR-4045B 13.6 ohm 11.0A 159% of 75HP 6.2% of 75HP
100HP 1 of CDBR-4220B 4.20 ohm 36.0A 192% of 100HP 7.6% of 100HP
125HP 1 of CDBR-4220B 4.20 ohm 36.0A 153% of 125HP 6.1% of 125HP
150HP 1 of CDBR-4220B 3.20 ohm 46.0A 167% of 150HP 6.3% of 150HP
200HP 1 of CDBR-4220B 3.20 ohm 46.0A and 1 of CDBR-4045B 13.6 ohm 11.6A 154% of 200HP 6.0% of 200HP
250HP 1 of CDBR-4220B 3.20 ohm 46.0A and 2 of CDBR-4045B 13.6 ohm 11.0A 146% of 250HP 5.6% of 250HP
300HP 2 of CDBR-4220B 3.20 ohm 46.0A 166% of 300HP 6.2% of 300HP
400HP 2 of CDBR-4220B 4.20 ohm 50.0A and 1 of CDBR-4220B 3.20 ohm 46.0A 156% of 400HP 9.5% of 400HP
500HP 3 of CDBR-4220B 3.20 ohm 46.0A 148% of 500HP 5.5% of 500HP
43. Electrical Installation 2 - 15
Heat Sink Mount Resistor Installation
1. Remove the Drive from its mounting for access to the rear of the heat sink.
2. Attach the Heat Sink Mount Resistor on the back of the Drive’s heat sink with screws M4 x 10mm (0.7mm pitch), as shown
in figure below.
3. Remove the rubber plug and run the braking resistor wires into the hole that leads to the terminal block.
4. Reinstall the Drive in its mounting position.
5. Connect the leads from the Heat Sink Mount Resistor to the Drive terminals B1 and B2.
6. Proceed to “Adjustments” section on page 2-20.
Fig 2.5 Attaching Heat Sink Mount Resistor on Heat Sink
44. Electrical Installation 2 - 16
Remote Mount Resistor Unit Installation Using Internal Braking Transistor
(for P7U20P4 thru P7U2018 and P7U40P4 thru P7U4018)
Since the Remote Mount Resistor Unit generates heat during dynamic braking operation, install it in a location away from
other equipment.
1. Install the Remote Mount Resistor Unit to a non-combustible surface, maintaining a minimum 1.97 inches (50mm)
clearance on each side and a minimum 7.87 inches (200mm) clearance on top.
2. Remove the Remote Mount Resistor Unit cover to access its terminal block. Connect the Remote Mount Resistor Unit to the
Drive and to external control circuitry according to Fig 2.6 below.
Fig 2.6 Wiring Remote Mount Resistor Unit (for P7U20P4 thru P7U2018 and P7U40P4 thru P7U4018)
3. Reinstall and secure Remote Mount Resistor Unit cover and Drive front cover.
4. Proceed to “Adjustments” section on page 2-20.
Table 2.8 Wire Size for Remote Mount Resistor Unit
Terminals B, P, R1, R2 1, 2*
Wire Size (AWG) 12-10 18-14*
Wire Type 600V Ethylene propylene rubber insulated, or equivalent
Terminal Screw M4
* Power Leads for the Remote Mount Resistor Unit generate high levels of electrical noise - these signal leads must be grouped separately.
IM
S3 SN
(R2)*
(R1)*
3% DUTY CYCLE
RESISTOR ASSEMBLY
* Terminal markings in parentheses
are for resistors manufactured by
Powerohm Resistors Inc.
120 VAC
45. Electrical Installation 2 - 17
Braking Transistor Unit(s) and Remote Mount Resistor Unit(s) Installation (for P7U2022 thru P7U2110 and
P7U4022 thru P7U4300)
Since the Remote Mount Resistor Unit generates heat during dynamic braking operation, install it in a location away from
other equipment.
Select Mounting locations for Braking Transistor Unit(s) and Remote Mount Resistor Unit(s) so that wiring between the Drive
and the (Master) Braking Transistor Unit, and between each Braking Transistor Unit and its associated Remote Mount
Resistor Unit, is less than 33 feet (10m).
1. Mount the Braking Transistor Unit(s) on a vertical surface. The Braking Transistor Unit requires a minimum of 1.18 inches
(30mm) clearance on each side and a minimum 3.94 inches (100mm) clearance top and bottom. Attach the Remote Mount
Resistor Unit maintaining a minimum 1.97 inches (50mm) clearance on each side and a minimum 7.87 inches (200mm)
clearance on top.
2. In each Braking Transistor Unit, set the nominal line voltage jumper plug to the correct setting for the installation; this is
factory set at the 230V/460V position. To access jumper plugs, remove the Plexiglas cover.
3. If multiple Braking Transistor Units are being installed, the unit closest to the Drive should have the Slave/Master jumper
plug set to the “Master” position (factory setting); all others must have this jumper plug set to the “Slave” position.
4. If a single Braking Transistor Unit and Remote Mount Resistor Unit are being installed, connect them to the Drive and
external control circuitry according to the chart and figure below.
5. Power leads for the Remote Mount Resistor Unit generate high levels of electrical noise - these power leads must be
grouped separately.
Table 2.9 Wire Size for Remote Mount Resistor Unit and Braking Transistor Unit
Name Circuit Terminals Wire Size AWG (mm2) Wire Type Terminal Screw
Braking Transistor Unit
(Models CDBR-2015B,
-2022B, -4030B, -4045B)
Main
0
0
12-10 (3.5-5.5)
600V vinyl sheathed wire
or equivalent
M4
Control
1 2 3
4 5 6
18-14 (0.75-2)
Braking Transistor Unit
(Model CDBR-2045, -4090)
Main P, Po, N, B 12-10 (3.5-5.5)
600V vinyl sheathed wire
or equivalent
M5
Control
1 2 3
4 5 6
18-14 (0.75-2) M4
Braking Transistor Unit
(Model CDBR-2110)
Main
P, Po, N, B
4 (22)
8-6 (8-14) *1
600V vinyl sheathed wire
or equivalent
M6
r s 12-10 (3.5-5.5)
M4
Control
1 2 3
4 5 6
18-14 (0.75-2)
Braking Transistor Unit
(Model CDBR-4220)
Main
P, Po, N, B
4 (22)
8-6 (8-14) *1
600V vinyl sheathed wire
or equivalent
M6
r s 12-10 (3.5-5.5)
M4
Control
1 2 3
4 5 6
18-14 (0.75-2)
Braking Resistor Unit
(Model LKEB- )
Main B P 12-10 (3.5-5.5) 600V vinyl sheathed wire
or equivalent
M4
(M5) *2
Control 1 2 18-14 (0.75-2) M4
*1 For wire size of 8-6 (8-14), use UL1283 heat-resistant vinyl-insulated wire or equivalent.
*2 M4 for Models LKEB-20P7 to -27P5 or -40P7 to -4015.
M5 for Models LKEB-2011 to -2022 or -4018 to -4045.
46. Electrical Installation 2 - 18
Fig 2.7 Wiring Single Braking Transistor Unit and Remote Mount Resistor Unit to Drive
(P7U2022 thru P7U2110 and P7U4022 thru P7U4300)
IM
S3 SN
0 0
REMOTE
MOUNT
RESISTOR
UNIT
R2R1
47. Electrical Installation 2 - 19
6. If two or more Braking Transistor Units and Remote Mount Resistor Units are being installed, connect them to the Drive
and to external circuitry according to Fig 2.8.
Fig 2.8 Wiring Multiple Braking Transistor Units and Remote Mount Resistor Units to Drive
(P7U2022 thru P7U2110 and P7U4022 thru P7U4300)
IM
S3 SN
0
0
0
0
0
0
0
0
R1 R2
R1 R2
R1 R2
R1 R2
0 0 0 0
R2 R1
Note: Connect only the number of braking transistor units and remote mount resistor units required for the application.
48. Electrical Installation 2 - 20
Adjustments
7. All Drives: Program Parameter L3-04 to “0” or “3” to disable stall prevention during deceleration.
8. Heat Sink Mount Resistor Only: Program L8-01 to “1” to enable overheat protection for heat sink mount braking
resistor.
Operation Check
9. During dynamic braking, verify that the “BRAKE” lamp inside the Braking Unit is lit. This lamp illuminates only when
dynamic braking is activating (during quick deceleration).
10. During dynamic braking, ensure that the required deceleration characteristic is obtained. If not, contact Yaskawa for
assistance.
11. Reinstall and secure covers on the Braking Transistor Units, Remote Mount Resistor Units, and the Drive.
49. Electrical Installation 2 - 21
Control Wiring
Control Circuit Wire Sizes
The auto mode speed reference (speed command) field wiring connection is made to P7 Drive terminals A1 or A2 (signal
positive), AC (signal common) and G (shield). Keep this lead length as short as possible to maintain signal quality. Insulated
twisted shielded pair wire (2 conductor # 18 ga, Belden 8760 or equivalent) is required. Do not run these wires in the same
conduits as other AC power or control wires. The shield must be connected on this end only, stub and isolate the other end.
The A2 signal employed is 4 to 20 mA with parameter H3-08 set for “2: 4 - 20 mA”. For 0 to 10 VDC, parameter H3-08 is set
for “0: 0 - 10 VDC” and the P7 control board DIP switch S1-2 must be in the OFF position. (See Figure 2.9)
For remote operation, keep the length of the control wiring to 50m or less. Separate the control wiring from high-power lines
(input power, motor leads or relay sequence circuits) to reduce noise induction from peripheral devices.
When setting speed commands (frequency references) from an external speed potentiometer (and not from the Digital Opera-
tor), use shielded twisted-pair wires and ground the shield to terminal E(G), as shown in Fig 2.9. Terminal numbers and wire
sizes are shown in Table 2.10.
Fig 2.9 Analog Input Terminal Configuration
Table 2.10 Terminal Numbers and Wire Sizes (Same for all Drives)
Terminals
Terminal
Screws
Tightening
Torque
lb-in
(N•m)
Possible
Wire Sizes
AWG (mm2)
Recommended
Wire Size AWG
(mm2)
Wire Type
S1, S2, S3, S4, S5, S6, S7
SN, SC, SP, +V, A1, A2,
AC, MI, M2, M3, M4,
MA, MB, MC, FM, AC,
AM, R+, R-, S+, S-, IG
Phoenix
type *3
4.2 to 5.3
(0.5 to 0.6)
Stranded
wire:
26 to 16
(0.14 to 1.5)
18
(0.75)
• Shielded, twisted-pair wire*1
• Shielded, polyethylene-covered,
vinyl sheath cable
E(G) M3.5
7.0 to 8.8
(0.8 to 1.0)
20 to 14
(0.5 to 2*2
)
12
(1.25)
*1.Use shielded twisted-pair cables to input an external speed command.
*2.Yaskawa recommends using straight solderless terminals on digital inputs to simplify wiring and improve reliability.
*3. Yaskawa recommends using a thin-slot screwdriver with a 3.5 mm blade width.
Signal Terminal Connections
0-10Vdc A1 to AC
4-20mA
or
0-10Vdc
A2 to AC(P=Pair)
E(G )
+V +15V DC ,20m A
A1 0-10V DC (20K )
A2 H 3-08
4-20m A (250K )
[0 to +10V (20K )]
AC
E7
Ω
Ω
Ω
4 to 20m A
P P
External
Frequency
Reference
2kΩ
2k
External
Frequency
Reference
E (G)
2kΩ
2k
P P
4 to 20m A
+V +15VDC, 20mA
A1 0-10VDC (20k Ω)
A2 H3-08
4-20m A (250K Ω)
[0 to +10V (20K Ω)]
AC
P7
50. Electrical Installation 2 - 22
Wiring Checks
After all wiring is completed, perform the following checks:
1. Is all wiring correct?
2. Have all wire clippings, screws or other foreign material been removed from the Drive enclosure?
3. Are all terminal screws tight?
51. Electrical Installation 2 - 23
Control Circuit Terminal Functions
The factory default functions of the control circuit terminals for 2-wire control are shown in Table below.
Table 2.11 Control Circuit Terminals
Type No. Signal Name Description Signal Level
Digital
input
signals
S1 Forward run/stop command Forward run when CLOSED; stopped when OPEN.
24 Vdc, 8 mA
Photocoupler isolation
S2 Reverse run/stop command Reverse run when CLOSED; stopped when OPEN.
S3 External fault input Fault when CLOSED.
Multi-function
digital inputs
Functions set by
H1-01 to H1-05.
S4 Fault reset Reset when CLOSED
S5 Multi-step speed reference 1
(Master/auxiliary switch)
Auxiliary frequency reference
when CLOSED.
S6 Multi-step speed reference 2
Multi-step setting 2 when
CLOSED.
S7 Jog frequency reference Jog frequency when CLOSED.
SN Digital input supply common
Refer to Table 2.14 for connection details.SC Digital input photocoupler
SP Digital input supply +24Vdc
Analog
input
signals
+V +15Vdc power output +15Vdc power supply for analog inputs or transmitters +15Vdc
(Max. current: 20 mA)
A1
Analog input or
Speed Command 0 to +10Vdc/100% 0 to +10 V(20 kΩ)
A2 Multi-function analog input 4 to 20 mA/100%
0 to +10Vdc/100% (H3-0
Function set by
H3-09.
4 to 20 mA(250Ω)
0 to +10 V(20kΩ)
AC Analog common – –
E(G) Shield wire, optional ground
line connection point
– –
Digital
output
signals
M1
During Run
(N.O. contact)
CLOSED during operation
Multi-function
digital output
Function set by
H2-01.
Dry contacts
Contact capacity:
1 A max. at 250Vac
1 A max. at 30Vdc
M2
M3
Remote/Auto Operation
(N.O. contact)
CLOSED when local control
Multi-function
digital output
Function set by
H2-02.M4
MA
Fault output signal
(SPDT)
MA/MC: CLOSED during fault condition
MB/MC: OPEN during fault condition
Dry contacts
Contact capacity:
1 A max. at 250Vac
1 A max. at 30Vdc
MB
MC
Analog
output
signals
FM Multi-function analog output (output frequency)
0 to +10Vdc/100% frequency
Multi-function
analog monitor 1
Function set by
H4-01
0 to +10Vdc max. ±5%
2 mA max.
AC Analog common –
AM Multi-function analog output
(output current)
0 to +10Vdc/100% Drive's rated
output current
Multi-function
analog monitor 2
Function set by
H4-04
RS-485/
422
R+ Modbus
communication input For 2-wire RS-485, jumper R+ and S+ and
jumper R- and S-.
Differential input,
PHC isolationR-
S+ Modbus
communication output
Differential input,
PHC isolationS-
IG Signal common - -
52. Electrical Installation 2 - 24
DIP Switch S1
DIP Switch S1 is described in this section. The functions of DIP switch S1 are shown in Table 2.12.
Fig 2.10 DIP Switch S1 Location
Table 2.12 DIP Switch S1
Name Function Setting
S1-1 RS-485 and RS-422 terminating resistance
OFF: No terminating resistance
ON: Terminating resistance of 110Ω
Factory Default = OFF
S1-2 Input method for analog input A2
OFF: 0-10 Vdc (internal resistance: 20KΩ)
ON: 4-20mA (internal resistance: 250Ω)
Factory Default = ON
S1
O 1
Terminating
resistance
DIP Switch S1 located on
terminal board.
2
1
53. Electrical Installation 2 - 25
Shunt Connector CN15
The shunt connector CN15 is described in this section. Shunt connector along with parameters H4-07 and H4-08 select the sig-
nal range of the analog output terminals FM and AM.
Shunt connector CN15 is only available when the optional Terminal Card with the 4-20mA Analog Output Monitor is installed
(Model No. ETC61812_). See Chapter 7, Maintenance, for installation of the optional Terminal Card.
The function of various shunt connector CN15 configurations is shown in Table 2.13.
Fig 2.11 Shunt Connector CN15 Location
The software configuration for the analog output monitor signal type is listed below:
Table 2.13 Shunt Connector CN15 Configuration Options
CN15 Analog Output Monitor Configurations
Voltage Output (0-10Vdc) for terminals FM-AC (CH1) and AM-AC (CH2)
Current Output (4-20mA) for terminals FM-AC (CH1) and AM-AC (CH2)
Voltage Output (0-10Vdc) for terminals FM-AC (CH1)
Current Output (4-20mA) for terminals AM-AC (CH2)
Current Output (4-20mA) for terminals FM-AC (CH1)
Voltage Output (0-10Vdc) for terminals AM-AC (CH2)
Parameter
No.
Parameter Name
Digital Operator Display
Description
Setting
Range
Factory
Setting
Menu
Location
H4-07
Terminal FM Signal Level
Selection
AO Level Select1
0: 0 - 10 V
2: 4-20 mA
0 or 2 0 Programming
H4-08
Terminal AM Signal Level
Selection
AO Level Select2
0: 0 - 10 V
2: 4-20 mA
0 or 2 0 Programming
54. Electrical Installation 2 - 26
Sinking/Sourcing Mode
The input terminal logic can be switched between sinking mode (0V common) and sourcing mode (+24V common) by using
the terminals SN, SC, and SP. An external power supply can also be connected, providing more freedom in signal input
methods.
Table 2.14 Sinking/Sourcing Mode and Input Signals
Internal Power Supply – Sinking Mode
(Factory Default)
External Power Supply – Sinking Mode
External +24V
Internal Power Supply – Sourcing Mode External Power Supply – Sourcing Mode
External +24V
55. Electrical Installation 2 - 27
Terminal Connections
Connections to Drive terminals are shown.
Fig 2.12 Terminal Connections
B1
Braking terminals only on
CIMR-P7U 20P4 to 2018
CIMR-P7U 4024 to 4300
B2
56. Electrical Installation 2 - 28
Control Circuit Wiring Precautions
Observe the following precautions when wiring control circuits:
1. Separate control wiring from power/motor wiring (terminals R/L1, S/L2, T/L3, U/T1, V/T2, W/T3, , 1, 2, and
3) and other high-power lines.
2. Separate wiring for control circuit terminals MA, MB, MC, M1, M2, M3, and M4 (digital outputs) from wiring to other
control circuit terminals.
3. If using an optional external power supply, ensure it is a UL Listed Class 2 power supply source.
4. Use twisted-pair or shielded twisted-pair cables for control circuits to prevent operating faults. Prepare cable ends as
shown in Figure below.
5. Connect the shield wire to terminal E(G).
6. Insulate the shield with tape to prevent contact with other signal lines and equipment.
Fig 2.13 Preparing the Termination of Shielded Twisted-pair Cables
Shield sheath Insulation
Connect to shield sheath
terminal E(G) at Drive Insulate with tape
Do not connect here.
57. Electrical Installation 2 - 29
Field Wiring Diagram
Use this diagram to document field wiring. It may be helpful to copy this page.
Fig 2.14 Field Wiring Diagram
T/L3
S/L2
R/L1
S3 (H1-01)
S2
S1
SC
E(G)
SP
S4 (H1-02)
S5 (H1-03)
S6 (H1-04)
S7 (H1-05)
SN
+V +15VDC, 20mA
A1 0-10VDC, 20 K
A2 (H3-08)
4-20mA, 250 K
[0 to +10VDC, 20K ]
AC
S+
R-
R+
S-
IG
1+ 2+ 3+ -
P7
W/T3
V/T2
U/T1
MC
MB
MA
M2
M1
M4
M3
E(G)
(H4-01) FM
(H4-04) AM
AC
(H2-01)
(H2-02)
Ω
Ω
Ω
S1-1
110
Terminating
Resistance
B1 B2
59. Digital Operator 3 - 1
Chapter 3
Digital Operator
This chapter describes the displays and functions of the Digital Operator.
Digital Operator Display.......................................................3-2
Digital Operator Keys ..........................................................3-3
Drive Mode Indicators..........................................................3-4
Drive Main Menu .................................................................3-6
Quick Setting Menu (-QUICK-) ..........................................3-11
Programming Menu (-ADV-)..............................................3-12
Example of Changing a Parameter ...................................3-14
60. Digital Operator 3 - 2
Digital Operator Display
The Digital Operator is used for programming, operating, monitoring, and copying the Drive’s parameters. To copy parameters,
both Drives must have the same software version, model, and control method. The various items included on the Digital
Operator are described below.
Fig 3.1 Digital Operator Component Names and Functions
-DRIVE- Rdy
Frequency Ref
U1-01= 60.00Hz
- - - - - - - - - - - - - - - - - - - - - - - - - - - - -
U1-02= 60.00Hz
U1-03= 10.05A
Drive Mode Indicators
See Table 3.2
Data Display
Displays monitor data, parameter data and settings
RUN & STOP Indicators
See Tables 3.5 and 3.6
Ready Display
Drive can operate when a Drive command is input
1 line x 13 characters
3 lines x 16 characters
Menu Display
Key Descriptions
See Table 3.1
-QUICK-
Control Method
---------------------------------
A1-02= 3 *3*
Flux Vector
“2”
Currently Programmed Value
Present Selection (User adjusts)
Example of Data Display
Factory Default
Setting
61. Digital Operator 3 - 3
Digital Operator Keys
The names and functions of the Digital Operator Keys are described in Table 3.1.
Table 3.1 Digital Operator Keys
Key Name Function
LOCAL / REMOTE
• Switches between operation via the Digital Operator (LOCAL) and the settings in
parameter b1-01 (Frequency Reference Selection) and b1-02 (Run Command
Selection) (REMOTE).
• This key can be enabled or disabled by the setting in parameter o2-01.
• The Drive must be in a stopped condition before it can be transferred to “LOCAL”
or “REMOTE” mode.
MENU
• Scrolls through the five main menus:
• Operation (-DRIVE-), Quick Setting (-QUICK-), Programming (-ADV-),
Modified Constants (-VERIFY-), and Auto-Tuning (-A.TUNE-).
ESCAPE
• Returns to the previous display, before the DATA/ENTER key was
pressed.
JOG
• Enables jog operation when the Drive is being operated from the Digital
Operator (LOCAL).
FWD / REV
• Selects the rotation direction of the motor when the Drive is being operated
from the Digital Operator (LOCAL).
INCREASE
• Increases parameter numbers and set values.
• Used to move to the next item or data value.
DECREASE
• Decreases parameter numbers and set values.
• Used to move to the previous item or data value.
SHIFT/RESET
• Selects the digit to be changed. The selected digit will blink.
• Also resets the Drive when a fault has occurred. The run command must be
removed before the reset command will be accepted.
DATA/ENTER • Enter menus and parameters as well as to set values.
RUN
• Starts Drive operation when the Drive is being controlled by the Digital Operator
(LOCAL).
STOP Key
• Stops Drive operation.
• This key can be enabled or disabled when operating from the external
terminal or communications by setting user parameter o2-02.
62. Digital Operator 3 - 4
Drive Mode Indicators
The definition of the Drive mode indicators are shown in Table 3.2.
REMOTE Sequence (SEQ) Indicator
The status of the “REMOTE” Sequence (SEQ) indicator is shown in Table 3.3. This indicator is always “Off” when the Drive
is in the “LOCAL” mode. When the Drive is in the “REMOTE” mode, the SEQ indicator status is dependent on the setting of
parameter b1-02 (Run Command Selection). See Table 3.3.
Table 3.2 Drive Mode Indicators
Indicator Definition
FWD Lit when a forward run command is input.
REV Lit when a reverse run command is input.
REMOTE SEQ See Table 3.3.
REMOTE REF See Table 3.4.
ALARM Lit when a fault has occurred. Flashes when an Alarm has occurred.
Table 3.3 REMOTE Sequence (SEQ) Indicator
Indicator Status Condition
On
Parameter b1-02 (Run Command Selection) is set to terminal strip, communications, or an option
board as indicated below:
b1-02 =1 (Terminals)
=2 (Communications)
=3 (Option PCB)
Off
Parameter b1-02 (Run Command Selection) is set to Digital Operator as indicated below:
b1-02=0 (Operator)
63. Digital Operator 3 - 5
REMOTE Reference (REF) Indicator
The status of the “REMOTE” Reference (REF) indicator is shown in Table 3.4. This indicator is always “Off” when the Drive
is in the “LOCAL” mode. When the Drive is in the “REMOTE” mode, the REF indicator status is dependent on the setting of
parameter b1-01 (Frequency Reference Selection). See Table 3.4.
Run Indicator
The status of the “RUN” indicator is shown in Table 3.5 when the Drive is in either the “LOCAL” or “REMOTE” mode.
Stop Indicator
The status of the “STOP” indicator is shown in Table 3.6 when the Drive is in either the “LOCAL” or “REMOTE” mode.
Table 3.4 REMOTE Reference (REF) Indicator
Indicator Status Condition
On
Parameter b1-01 (Frequency Reference Selection) is set to terminal strip, communications, option
board, or pulse train as indicated below:
b1-01 =1 (Terminals)
=2 (Communications)
=3 (Option PCB)
=4 (Pulse Train)
Off
Parameter b1-01 (Frequency Reference Selection) is set to digital
operator as indicated below:
b1-01=0 (Operator)
Table 3.5 RUN Indicator
Indicator Status Condition
On Drive is running.
Blinking Drive is decelerating to a stop.
Off Drive is stopped.
Table 3.6 STOP Indicator
Indicator Status Condition
On Drive is decelerating to a stop or stopped.
Blinking
Drive is in a run condition but the frequency reference is less than the
minimum output frequency E1-09, or the Drive is running in “REMOTE” mode and the “STOP”
key on has been pressed.
Off Drive is running.
64. Digital Operator 3 - 6
Drive Main Menu
The Drive’s parameters and monitoring functions are organized into menu groups that make it easier to read and set
parameters. The Drive is equipped with five menu selections. The five selections and their primary functions are shown in
Table 3.7 and are directly available by pressing the menu key.
Table 3.7 Drive Main Menu
Main Menu Primary Function(s)
Operation
- DRIVE -
The Drive can be run in this menu.
Use this menu for monitoring values such as frequency reference or output current, displaying fault his-
tory or displaying the fault traces.
Quick Setting
- QUICK -
The Drive can be programmed in this menu.
Use this menu to set/read the most commonly used parameters.
Programming
- ADV -
The Drive can be programmed in this menu.
Use this menu to set/read every parameter.
Modified Constants
- VERIFY -
The Drive can be programmed in this menu.
Use this menu to set/read the parameters that have been modified from their factory default settings.
Auto-Tuning
- A.TUNE -
The Drive can be programmed in this menu.
Use this menu to auto-tune the Drive in order to optimize motor control as well as utilize the bi-directional
speed search feature.
65. Digital Operator 3 - 7
Main Menu Structure
The menu selection display will appear when the MENU key is pressed from a monitor or setting display. While viewing the
menu selection display, press the MENU key repeatedly to scroll between the menu selections. Press the DATA/ENTER key to
enter the desired menu selection.
1
Modified Consts = Modified Parameters
Fig 3.2 Main Menu Structure
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Operation
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Quick Setting
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Programming
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Modified Consts
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Auto-Tuning
1
MENU
MENU
MENU
MENU
MENU
MENU
66. Digital Operator 3 - 8
Operation Menu (-DRIVE-)
This menu is used for setting a speed command or monitoring values such as output frequency and output current. It is also
used for displaying the fault history and the fault traces. The Drive must be in this menu in order to run, see parameter
b1-08.
U1 Monitor List
Follow the key operations below (Fig.3.3) to access the Operation Menu:
Fig 3.3 U1 Monitor List Access Procedure
Use and keys to scroll through the U1 “Monitor” parameter list. See Appendix A for functional description.
IMPORTANT
Leaving the Drive in a menu other than the Operation Menu, will prohibit the Drive from running. While
running, if the Drive is in a menu other than “Operation” and the run command is removed and re-applied,
the Drive will stop and will not start until the Operation Menu is selected.
Table 3.8 U1 Monitor List
Monitor Monitor
U1-01 Frequency Ref U1-20 SFS Output (Soft Starter Signal)
U1-02 Output Freq U1-24 PI Feedback
U1-03 Output Current U1-28 CPU ID
U1-06 Output Voltage U1-29 kWh
U1-07 DC Bus Voltage U1-30 MWh
U1-08 Output kWatts U1-34 OPE Detected
U1-10 Input Term Sts U1-36 PI Input
U1-11 Output Term Sts U1-37 PI Output
U1-12 Int Ctl Sts 1 U1-38 PI Setpoint
U1-13 Elapsed Time U1-39 Transmit Err
U1-14 FLASH ID U1-40 FAN Elapsed Time
U1-15 Term A1 Level U1-51 Auto Mode Fref
U1-16 Term A2 Level U1-52 Hand Mode Fref
U1-18 Mot SEC Current (Secondary Current) U1-53 PI Feedback 2
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Operation
-DRIVE- Rdy
Frequency Ref
U1-01= 0.00Hz
- - - - - - - - - - - - - - - - - - - -
U1-02= 0.00Hz
U1-03= 0.00Ax1
67. Digital Operator 3 - 9
U2 Fault Trace List
After viewing the “Monitor” parameter list, in order to view the “Fault Trace” parameter list, follow the key operations below
(Fig.3.4).
Fig 3.4 U2 Fault Trace List Access Procedure
Use and keys to scroll through the U2 “Fault Trace” parameter list.
Table 3.9 U2 Fault Trace List
Fault Trace Parameters
U2-01 Current Fault
U2-02 Last Fault
U2-03 Frequency Ref
U2-04 Output Freq
U2-05 Output Current
U2-07 Output Voltage
U2-08 DC Bus Voltage
U2-09 Output kWatts
U2-11 Input Term Sts
U2-12 Output Term Sts
U2-13 AC Drive Status
U2-14 Elapsed Time
-DRIVE- Rdy
Monitor
U1-01= 0.00Hz
- - - - - - - - - - - - - - - - - - - -
U1-02= 0.00Hz
U1-03= 0.00A
-DRIVE- Rdy
Fault Trace
U2-01= None
- - - - - - - - - - - - - - - - - - - -
U2-02= None
U2-03= 0.00Hz
-DRIVE- Rdy
Current Fault
U2-01= None
- - - - - - - - - - - - - - - - - - - -
U2-02= None
U2-03= 0.00Hz
68. Digital Operator 3 - 10
U3 Fault History List
After viewing the “Fault Trace” parameter list, in order to view the “Fault History” parameter list, follow the key operations
below Fig. 3.5).
Fig 3.5 U3 Fault History Access Procedure
Use and keys to scroll through the U3 “Fault History” parameter list.
Table 3.10 Fault History List
Fault History Parameters
U3-01 Last Fault
U3-02 Fault Message 2
U3-03 Fault Message 3
U3-04 Fault Message 4
U3-05 Elapsed Time 1
U3-06 Elapsed Time 2
U3-07 Elapsed Time 3
U3-08 Elapsed Time 4
U3-09 Fault Message 5
U3-10 Fault Message 6
U3-11 Fault Message 7
U3-12 Fault Message 8
U3-13 Fault Message 9
U3-14 Fault Message 10
U3-15 Elapsed Time 5
U3-16 Elapsed Time 6
U3-17 Elapsed Time 7
U3-18 Elapsed Time 8
U3-19 Elapsed Time 9
U3-20 Elapsed Time 10
-DRIVE- Rdy
Fault Trace
U2-01= None
- - - - - - - - - - - - - - - - - - - -
U2-02= None
U2-03= 0.00A
-DRIVE- Rdy
Fault History
U3-01= None
- - - - - - - - - - - - - - - - - - - -
U3-02= None
U3-03= None
-DRIVE- Rdy
Last Fault
U3-01= None
- - - - - - - - - - - - - - - - - - - -
U3-02= None
U3-03= None
69. Digital Operator 3 - 11
Quick Setting Menu (-QUICK-)
This menu is used to set/read the most commonly used parameters in the Drive. Follow the key operations below (Fig. 3.6) to
access the Quick Setting Menu:
Fig 3.6 Quick Setting Parameter Access Procedure
Use and keys to scroll through the “Quick Setting” parameter list.
Table 3.11 Quick Setting Parameter List
Parameter
Number
Parameter Name Parameter
Number
Parameter Name
A1-00 Language Selection b5-29 PI Square Root Gain
b1-01 Frequency Reference Selection b5-30 Output Square Root Monitor Selection
b1-02 Run command Selection b8-01 Energy Savings Control Selection
b1-03 Stopping Method Selection C1-01 Acceleration Time 1
b1-04 Reverse Operation Selection C1-02 Deceleration Time 1
b4-01 Delay-On Timer
b5-01 PI Mode Selection d2-01 Frequency Reference Upper Limit
b5-02 Proportional Gain Setting d2-02 Frequency Reference Lower Limit
b5-03 Integral Time Setting E1-01 Input Voltage Setting
b5-04 Integral Limit Setting E2-01 Motor Rated Current
b5-06 PI Output Limit F6-01 Operation Selection After Communication Error
b5-07 PI Offset Adjustment H3-02 Terminal A1 Gain Setting
b5-08 PI Primary Delay Time H3-03 Terminal A1 Bias Setting
b5-09 PI Output Level Selection H3-10 Terminal A2 Gain Setting
b5-10 PI Output Gain Setting H3-11 Terminal A2 Bias Setting
b5-11 PI Output Reverse Selection L2-01 Momentary Power Loss Detection Selection
b5-12 PI Feedback Reference Missing Detection Selection L2-02 Momentary Power Loss Ride-thru Time
b5-13 PI Feedback Loss Detection Level L4-05 Frequency Reference Loss Detection Selection
b5-14 PI Feedback Loss Detection Time L4-06 Frequency Reference Level at Loss Frequency
b5-15 PI Sleep Function Start Level L5-01 Number of Auto Restarts Attempts
b5-16 PI Sleep Delay Time L5-03 Maximum Restart Time After Fault
b5-17 PI Accel/Decel Time L6-01 Torque Detection Selection 1
b5-18 PI Setpoint Selection L6-02 Torque Detection Level 1
b5-19 PI Setpoint Value L6-03 Torque Detection Time 1
b5-20 PI Setpoint Display Setting L8-11 Heatsink Cooling Fan Operation Delay Time
b5-21 PI Sleep Input Source o1-01 User Monitor Selection
b5-22 PI Snooze Level o1-05 LCD Brightness Adjustment
b5-23 PI Snooze Delay Time o1-07 Second Line User Monitor Selection
b5-24 PI Snooze Deactivation Level o1-08 Third Line User Monitor Selection
b5-25 PI Setpoint Boost Setting o2-03 User Parameter Default Value
b5-26 PI Maximum Boost Time o2-05 Frequency Operation Time Selection
b5-27 PI Snooze Feedback Level o2-08 Cumulative Operation Time Selection
b5-28 PI Feedback Square Root Ac Function Selection o3-02 Read Allowed Selection
-QUICK-
** Main Menu **
- - - - - - - - - - - - - -
Quick Setting
-QUICK-
Reference Source
- - - - - - - - - - - - - - - - - - - -
B1-01= 1 *1*
Terminals
“1”x2
70. Digital Operator 3 - 12
Programming Menu (-ADV-)
This menu is used to set/read every parameter in the Drive. Follow the key operations below (Fig. 3.7) to access the Program-
ming Menu.
Fig 3.7 Programming Menu Access Procedure
Use , , and keys to scroll through the “Programming” parameter group list. For complete parameter listing
see appendix A.
Table 3.12 Programming
Parameter Group List
Parameter Group Functions
A1 Initialization
A2 User Parameters
b1 Sequence
b2 DC Braking
b3 Speed Search
b4 Delay Timers
b5 PI Control
b8 Energy Saving
C1 Accel/Decel
C2 S-Curve Acc/Dec
C4 Torque Comp
C6 Carrier Freq
d1 Preset Reference
d2 Reference Limits
d3 Jump Frequencies
d4 Sequence
E1 V/F Pattern
E2 Motor Setup
F6 Com OPT Setup
H1 Digital Inputs
H2 Digital Outputs
H3 Analog Inputs
H4 Analog Outputs
H5 Serial Com Setup
L1 Motor Overload
L2 PwrLoss Ridethru
L3 Stall Prevention
L4 Ref Detection
L5 Fault Restart
L6 Torque Detection
L8 Hdwe Protection
n1 Hunting Prev
n3 High Slip
o1 Monitor Select
o2 Key Selections
o3 COPY Function
-ADV-
** Main Menu **
- - - - - - - - - - - - - -
Programming
-ADV-
Initialization
- - - - - - - - - - - - - - - - - - - -
A1-00= 0
Select Language
x3
71. Digital Operator 3 - 13
Modified Constants Menu (-VERIFY-)
This menu is used to set/read the parameters that have been modified from their original factory default settings. Follow the
key operations below (Fig. 3.8) to access the Modified Constants Parameter Menu.
Fig 3.8 Modified Constants Menu Access Procedure
Note 1: If there are not any parameters that have been modified from their original factory default settings, then the display
will state “None Modified”. Otherwise, use the “increase” and “decrease” keys to scroll through the “Modified
Constants” list.
Auto-Tuning Menu (-A.TUNE-)
This menu is used to auto-tune the Drive in order to optimize motor control as well as utilize the bi-directional speed search
feature. Follow the key operations below (Fig. 3.9) to access the Auto-Tuning Menu.
Fig 3.9 Auto-Tuning Menu Access Procedure
Use and keys to scroll through the “Auto-Tuning” parameter list.
Table 3.13 Auto-Tuning
Parameter List
Auto-Tuning Parameters
T1-02 Mtr Rated Power
T1-04 Rated Current
-VERIFY-
** Main Menu **
- - - - - - - - - - - - - -
Modified Consts
See Note 1
x4
See Note 1
-A.TUNE-
** Main Menu **
- - - - - - - - - - - - - -
Auto-Tuning
-A.TUNE-
Mtr Rated Power
- - - - - - - - - - - - - - - - - - - -
T1-02= 0.40kW
(0.00~650.00)
“0.40kW”x5
72. Digital Operator 3 - 14
Example of Changing a Parameter
Table 3.14 provides an example of how to change parameter “C1-02” (Deceleration Time 1) from 30 seconds to 40 seconds.
Table 3.14 Changing a Parameter in the Programming Menu
Step
Number
Digital Operator Display Description
1 The Drive is first powered up.
2 Press the MENU key to scroll to “Operation” menu.
3 Press the MENU key to scroll to “Quick Setting” menu.
4 Press the MENU key to scroll to “Programming” menu.
5 Press the DATA/ENTER key to enter “Programming” menu.
6 Press the INCREASE key until C1-01 (Accel/Decel) is displayed.
7 Press the SHIFT/RESET key to move flashing digit to the right.
-DRIVE- Rdy
Frequency Ref
U1-01= 0.00Hz
- - - - - - - - - - - - - - - - - - - -
U1-02= 0.00Hz
U1-03= 0.00A
-DRIVE-
** Main Menu **
- - - - - - - - - - - - - -
Operation
-QUICK-
** Main Menu **
- - - - - - - - - - - - - -
Quick Setting
-ADV-
** Main Menu **
- - - - - - - - - - - - - -
Programming
-ADV-
Initialization
- - - - - - - - - - - - - - - - - - - -
A1-01= 0
Select Language
-ADV-
Accel/Decel
- - - - - - - - - - - - - - - - - - - -
C1-01= 1.0sec
Accel Time 1
-ADV-
Accel Time 1
- - - - - - - - - - - - - - - - - - - -
C1-01= 30.0sec
(0.0~6000.0)
“30.0sec”