Secure, reliable and mission-critical control capability providing “bumpless” automatic failover between redundant controllers.
Fast processor for increased productivity
One-step data acquisition functionality through the definition of the I/O database
Small footprint with low power requirements and fanless operation
Interfaces to Ovation and WDPF I/O, both local and remote
Integral interface to digital busses through Ovation I/O modules
Integrated virtual I/O capability for third-party OEM systems over Ethernet protocols.
Non-volatile storage of application software, point database, configuration information, and operating tuning constants
Integrated sequence of events capability with 1 millisecond resolution
Meets IEC 61131-3 standards
Achilles Level 1 certified
Introduction
Emerson’s Ovation™ distributed control system is renowned for delivering precision control with outstanding performance. That precision begins with the Ovation controller secure, mission-critical operations such as those of power generation, water and wastewater plants.
The OCR1100 model of the Ovation controller series executes simple or complex modulating and sequential control strategies, performs data acquisition functions and interfaces to the Ovation network and various I/O sub-systems. It has the capability to originate up to 32,000 points.
DeltaV SIS process safety system: the innovation benchmark of intelligent safety instrument system
introduction Emerson’s DeltaV SIS™ process safety system is the representative of the new generation of safety instrumented system (SIS), which improves the availability of safety instrumented functions through predictive field intelligence technology. As the world’s first intelligent SIS logic solver, its design gives consideration to flexibility, compliance and network security, and it is suitable for SIL 1 to SIL 3 security applications.
Core advantage
Intelligent diagnosis and high availability 85% of SIS failures come from field instruments and actuators. DeltaV SIS can diagnose faults in real time through HART protocol, which can reduce false trip, prolong process running time and reduce life cycle cost. Flexible deployment mode Support deep integration with traditional DCS interface or DeltaV DCS, and realize seamless operation of workstations while maintaining functional independence (hardware, software and network isolation). Compliance guarantee Automatically meet the strict requirements of IEC 61511, such as data verification of HMI parameter modification, to ensure the accuracy of data writing of logic solver. Extensible architecture SLS 1508 logic solver has built-in dual CPU and 16-channel I/O, which can be extended without additional processor. The scanning rate and memory occupation have nothing to do with the system scale. Key technical characteristics
Redundancy design: SLS 1508 runs in redundant pairs, with no division between master and slave, no disturbance in failover, and supports online replacement. Network security: The world’s first security system certified by ISA SSA Level 1 (based on IEC 62443) has a defensive architecture. Event sequence record: Time stamp record with 1ms resolution, which supports quick location of the first fault. hardware configuration
Logic solver: 16-channel flexible I/O (supporting HART and discrete quantity), optical isolation (1500V DC) and IP20 protection. Communication network: local peer-to-peer bus (SISNet) and optical fiber remote ring network to ensure data synchronization and redundancy.
EMERSON KJ3221X1-BA1 is an 8-channel analog output module (AO) supporting 4-20 mA and HART protocols, which is a part of Emerson DeltaV system. This module has the following features:
Number of channels and signal types: The module provides 8 independent analog output channels, each of which supports 4-20 mA current signal, and is compatible with HART protocol for communication and parameter configuration with HART equipment.
Application scenario: This module is suitable for industrial automation field, and can control multiple HART devices at the same time, supporting process control, data acquisition and diagnosis functions.
Compatibility: It is compatible with the DeltaV system, supports the built-in safety I/O function of DeltaV, and is suitable for industrial environments requiring high reliability and safety.EMERSON KJ3221X1-BA2 VE4035S2B1 ATEX Instruction Sheet
Technical specification: The module is designed as a modular structure with high reliability, which is suitable for harsh industrial environment. In addition, its power consumption is low, 2.7W
Other information: The specific model of KJ3221X1-BA1 indicates that it is an analog output card in Emerson DeltaV series, and together with other similar models (such as KJ3221x1-BK1AI module), it forms a part of Emerson industrial automation solution
1:1 redundancy for M-series FOUNDATION™ Fieldbus I/O
Autosense of redundant I/O
Automatic switchover
Provides synchronized control
Introduction
Are you looking for an efficient, yet robust, I/O subsystem? M-series FOUNDATION Fieldbus I/O is a modular subsystem that communicates digitally with field devices, increases your input/ output capacity, and gives you access to more information about your process than conventional I/O subsystems. If you want an efficient, economical, and secure process control system, use DeltaV™ M-series FOUNDATION Fieldbus redundant I/O. It greatly enhances device diagnostics that affect your control strategy and alerts operators to device malfunctions. The modular design of M-series FOUNDATION Fieldbus I/O offers flexibility during installation. It’s designed to be installed in the field, close to your devices. M-series FOUNDATION Fieldbus I/O is equipped with function and field-wiring protection keys to ensure that the correct I/O card is always plugged into the corresponding terminal block. Modularity, protection keys, and increased input/output capacity make M-series FOUNDATION Fieldbus I/O a smart choice for your process control system.
Benefits
Increases input/output. Use M-series FOUNDATION Fieldbus I/O instead of Classic I/O to increase information flow. Take advantage of FOUNDATION Fieldbus digital communications to access additional information from your smart devices. Get more information over one wire than over multiple wires, as with Classic I/O. Takes advantage of all smart device capabilities. Increase your ability to communicate with your devices using DeltaV M-series FOUNDATION Fieldbus I/O; field device status is updated continuously. For multi-variable devices, all process variables are available on the single fieldbus connection. Facilitates multi-drop 16 devices on one port. Save on wiring expenditures by installing M-series FOUNDATION Fieldbus I/O in the field, close to the actual field devices. Mounting the controller with the I/O further reduces your wiring costs by eliminating the need for long runs of multi-cores. Multi-dropping up to 16 devices on one port reduces your wiring expenses substantially. The integrated design of the M-series FOUNDATION Fieldbus I/O can eliminate the need for marshalling panels. This saves you even more time and money. Features secure uninterrupted control. A DeltaV system offers back-up link active schedule (LAS) to ensure secure control when upgrading a card or in the case of card failure. LAS control is automatically transferred to the backup device when upgrading or experiencing card failure. Control is automatically transferred back to the H1 Interface Card when the system detects a new card. This process requires no user interaction.
Product Description
The I/O card is enclosed in a DeltaV-designed common form factor that plugs into the I/O interface carrier. The housing is clearly labeled with the enclosed I/O card type. Clearly visible LEDs on the top of the I/O card display the power, error, and status to the two channels included in the I/O card. The Fieldbus I/O Card meets ISA G3 corrosion specifications by using superior electronic components and conformal coating. Redundancy Made Easy. The active and standby I/O cards are connected to the field at the redundant terminal block. When a fault is detected, the system automatically switches to the backup I/O card. The reliability rating of the terminal block is greater than the high reliability of the I/O cards. The controller scans each card of a redundant pair. Incremental controller loading is a function of the number of redundant cards. In addition, the redundant cards have dedicated communication between the pair and the backup card monitors the health of the active card. Configuration of redundancy is not required as the DeltaV system automatically recognizes the redundant pair of cards and assigns a device signal tag (DST) to the channels on the primary card. Signals referenced for each connected FOUNDATION Fieldbus device will count at most 1 DST. The DST type counted will be the most valuable type used to reference a signal for each device. For example, a device with 1 AI signal reference and 1 AO signal reference will count as 1 AO DST. Switchover time for redundant I/O is minimal, and the process will be undisturbed. An alarm on the integrity error for the primary notifies the operator of a switchover. The backup card is also monitored for integrity alarms. Events that can cause a switchover include.
y Hardware failure within the active card.
y Communications failure between the active card and the controller.
y Removal of the active card from the carrier.
y Detection of a fault in the field wiring. A switchover may also be initiated from the diagnostics explorer, and the health and status of both cards and their channels are available in the diagnostics explorer. The system automatically commissions a new standby card. In safe areas, failed cards can be replaced under power. In hazardous areas, appropriate installation procedures must be followed. The M-series FOUNDATION Fieldbus I/O subsystem includes: y H1 interface card and simplex terminal block, or y 2 H1 interface cards and redundant terminal block.EMERSON VE4017P0
The 16-Channel Output Relay Module is designed for high reliability for the plant’s most critical rotating machinery. This 2-slot monitor is used together with the AMS 6500 to build a complete API 670 machinery protection monitor. Applications include steam, gas, compressors and hydro turbo machinery. Easy-to-use software provides graphical logic displays that guide the user pictorially through configuration.
Specifications
A6740-EMERSONInputs60 inputs of type: channel clear, alert and dangerOutputsRelay 1-16Time Delay0-30 secondsHandleEasily remove card and provide plate for module and sensor identificationDimensions (W x H x L)60 mm x 128.4 mm x 160 mmGross Weightapp 450 g (0.992 lbs)Operating Temperature0 to 65°C (32 to 149°F)Storage Temperature-40 to 70°C (-40 to 156°F)Relative Humidity5-95%, non condensingShock98 m/s² (9.98 g’s peak), 16 msecVibration0.15 mm (10-55HZ), 19.6 mm/s² (55-150 Hz)
EMERSON A6125 is a dual-channel piezoelectric vibration monitor for housing, which is specially designed for rotating machinery in factories to monitor housing vibration. Its main features include:
Dual-channel design: supports two independent measurement channels, and is suitable for monitoring two vibration signals at the same time. Modular design: 3U-sized and 1-slot modular plug-in is adopted, which can be hot-swapped, thus reducing the equipment space requirement. High reliability: conforming to API 670 standard, suitable for steam, compressor and hydraulic turbine machinery. Remote configuration function: Support remote limit multiplication and trip bypass setting. Output and interface: front and rear buffering, proportional output (0-4 mA/0-20 mA) and digital output (0-10 V) are provided, and self-checking function is provided to monitor the hardware status. Cooperate with piezoelectric accelerometer: it can be used together with piezoelectric accelerometer and speedometer sensor to improve monitoring accuracy. This product is suitable for industrial environments that need high-precision vibration monitoring, such as the health monitoring system of rotating machinery.
The A6000 series can be configured: A6110、A6120、A6125、A6140、A6150、A6151、A6210、A6220、 A6310、A6312、A6312-8、A6410、A6620、A6630、A6740、 A6740-10,A6824,A6824R
A6370 Overspeed Protection Monitor The A6370 Monitor is part of the AMS 6300 SIS Overspeed protection system and is mounted in a 19” rack (84HP width and 3RU height) in combination with the A6371 system backplane. One AMS 6300 SIS consists of three Protection monitors (A6370) and one backplane (A6371). The system is designed for use with Eddy-Current sensors, Hall- Element sensors and Magnetic (VR) Sensors.
EMERSON A6370 is an overspeed protection monitor, which is a part of AMS 6300 SIS overspeed protection system. It is mainly used to monitor the rotating speed of rotating mechanical equipment (such as turbines, compressors, pumps, etc.). When the rotating speed exceeds the set value, it will trigger an alarm or emergency stop to prevent equipment damage or accidents.
The equipment supports various sensor types, including Hall sensor, magnetic (VR) sensor and eddy current sensor. It has high accuracy and reliability and is suitable for harsh industrial environment.
A6370 monitor has various communication interfaces, such as USB, RS485 and Profibus DP, which supports remote monitoring and data transmission.
About this document This manual provides information on planning, mounting, wiring, and initial setup of the Micro Motion 5700 transmitter. For information on full configuration, maintenance, troubleshooting, or service of the transmitter, see the . The information in this document assumes that users understand basic transmitter and sensor installation, configuration, and maintenance concepts and procedures. Hazard messages This document uses the following criteria for hazard messages based on ANSI standards Z535.6-2011 (R2017).
DANGER Serious injury or death will occur if a hazardous situation is not avoided. WARNING Serious injury or death could occur if a hazardous situation is not avoided. CAUTION Minor or moderate injury will or could occur if a hazardous situation is not avoided. NOTICE Data loss, property damage, hardware damage, or software damage can occur if a situation is not avoided. There is no credible risk of physical injury. Physical access WARNING Unauthorized personnel can potentially cause significant damage and/or misconfiguration of end users’ equipment. Protect against all intentional or unintentional unauthorized use. Physical security is an important part of any security program and fundamental to protecting your system. Restrict physical access to protect users’ assets. This is true for all systems used within the facility.
Installation checklist
□ If possible, install the transmitter in a location that will prevent direct exposure to sunlight. The environmental limits for the transmitter may be further restricted by hazardous area approvals.
□ If you plan to mount the transmitter in a hazardous area:
WARNING
— Verify that the transmitter has the appropriate hazardous area approval. Each transmitter has a hazardous area approval tag attached to the transmitter housing.
— Ensure that any cable used between the transmitter and the sensor meets the hazardous area requirements.
— For ATEX/IECEx installations, strictly adhere to the safety instructions documented in the ATEX/IECEx approvals documentation available on the product documentation DVD shipped with the product or at .
□ Verify that you have the appropriate cable and required cable installation parts for your installation. For wiring between the transmitter and sensor, verify the maximum cable length does not exceed 1,000 ft (305 m).
□ Ensure that you use a twisted-pair instrument cable for all output connections.
□ You can mount the transmitter in any orientation as long as the conduit openings do not point upward. Installing the transmitter with the conduit openings facing upward risks condensation moisture entering the transmitter housing, which could damage the transmitter. Following are examples of possible orientations for the transmitter. Preferred orientation Alternate orientations
□ Any fittings, adapters, or blanking elements used on either conduit entries or threaded joints that are a part of flame proof joints must comply with the requirements of EN/IEC 60079-1 & 60079-14 or CSA C22.2 No 30 & UL 1203 for Europe/International and North America respectively. Only qualified personnel can select and install these elements in accordance with EN/IEC 60079-14 for ATEX/IECEx or to NEC/CEC for North America.
□ To maintain the Ingress protection thread sealant, a sealing washer, or O-ring must be applied:
— For Zone 1 applications thread sealant must also comply with the requirements of EN/IEC 60079-14 and thus must be non-setting, non-metallic, non-combustible, and maintain earthing between the equipment and conduit.
— For Class I, Groups A, B, C, and D applications thread sealant must also comply with the requirements of UL 1203/CSA C22.2 No. 30. □ Mount the meter in a location and orientation that satisfies the following conditions:
— Allows sufficient clearance to open the transmitter housing cover. Install with 8 in (203 mm) to 10 in (254 mm) clearance at the wiring access points.
— Provides clear access for installing cabling to the transmitter.
— Provides clear access to all wiring terminals for troubleshooting.
