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Configuring the Module

Configuration Parameters

The DIP switches allow you to configure the following items:

• Starting Logical Rack Number (Logical Rack) – is the 1747-ASB module’s

starting logical rack number in the scanner’s image.

• Starting Logical Group Number (Logical Group) – is the 1747-ASB

module’s starting logical group number within the scanner’s image.

• Baud Rate (Baud Rate) – is the 1747-ASB module’s RIO link communication

rate. The baud rate must be the same for all adapters on the RIO link.

• Primary/Complementary SLC Chassis (PRI/COMP) – determines

whether the 1747-ASB module appears to the scanner as a primary or

complementary chassis.

• Adapter Image Size (IMAGE SIZE) – indicates the I/O image size to be

reserved for the adapter. It can be any size between 2 and 32 groups in

2 logical group increments.

• Hold Last State (HLS) – determines whether the discrete output modules

are held in their last state when:

– RIO link communication with the 1747-ASB module is lost.

– The scanner inhibits the 1747-ASB module.

– The scanner sends Reset, Adapter Decide commands to the 1747-ASB module.

• Processor Restart Lockout (PRL) – determines whether the 1747-ASB

module automatically resumes RIO link communications if communication is

lost and then restored.

The 1784-PKTXD card is an Allen-Bradley network interface card.

The 1784-PKTXD network interface card is used to connect a PC to a PLC controller via a Data Highway Plus (DH+) or SLC processor and a DH485 network.

This allows the device to enable simpler and more efficient data acquisition processes, which are critical for industrial applications.

The 1784-PKTXD card has an I/O scanner function, which is also available on different cards for use with soft or embedded control engines.

The 1784-PKTXD card includes a generic PCI card as a standard feature. Therefore, the card is compatible with different operating systems.

The 1784-PKTXD card can be used in environments where general programming, configuration, and monitoring functions are required from industrial equipment or computer desktops.

The 1784-PKTXD card is ideally suited for use as a network interface card. Therefore, since it is a general purpose card for interconnecting peripheral components, it must be plugged into a PCI bus slot.

If the operator is using a general purpose card, it must be plugged into a PCI bus slot with either 3.3 volt or 5 volt signals.

The 1784-PKTXD card communicates with nodes on the Data Highway Plus network.

These include the PLC-5. PLC-5/250. and SLC 5/04 processors. This component performs data transfer, management, and local network diagnostics.

The 1784-PKTXD card and the host computer exchange data through a dual-port interface.

The dual-port interface requires up to 4 KB of memory starting at the base memory address that the PCI BIOS addresses for the card when booting the PC.

The RDIO400 is an interface module between the serial process bus and digital input or output signals.

Description

The Kongsberg Maritime Remote Input/Output System (RIO400) interfaces via the Serial Process Bus (SPBus)

connecting control computers in the process network with input and output (I/O) signals from remote devices such as valves, relays and temperature sensors.

The RDIO400 is an interface module between the SPBus and the digital inputs or outputs of eld devices.

The RIO400 system provides a cost-effective solution for connecting any number of inputs and outputs to the Kongsberg Maritime Automation system.

independent of the distance between the remote device and the controller computer.

Functionality

– Up to 32 independent go to 

– Dual serial process bus (SPBus) interfaces, allowing optional redundancy

– Each SPBus interface ensures electrical isolation from the control system.

– Easy to install and replace:

– DIN rail mounting

– Plug-in connection

– LED status indicator for normal operation or error status

– Loop checking and commissioning from the operating station and local data terminals possible

– Short-circuit proof loop current driver

– Safe start-up of outputs in case of dcs-sis.com communication breakdown

– Built-in tests for self-diagnosis and fault identification c

– SIL 1 compliant

– Line fault detection (LFD)

– Ground fault detection (EFD)

– Dual watchdog

The ModBus and Rack Interface Module is designed to provide high reliability for the plant’s most critical rotating machinery.

It reads parameters from all AMS 6500 modules and outputs them via ModBus TCP/IP and/or ModBus RTU (serial).

This 1-slot monitor can be used with other AMS 6500 monitors to form a complete API 670 machinery protection monitor.

Applications include steam, gas, compressor and hydraulic turbine machinery.

Operators have access to machinery health parameters in the control environment for seamless integration.

The module powers a local graphical display on the protection rack for reading machine and instrument information.

It can be configured with ModBus TCP/IP or ModBus RTU, or both with redundant paths.

The AMS 6500 is an integral part of PlantWeb® and AMS software.

PlantWeb combines the Ovation® and DeltaV™ process control systems to provide operators with an integrated view of machine health.

AMS software provides maintenance personnel with advanced predictive and performance diagnostic tools to accurately determine machine failures at an early stage.

3U-sized, 1-slot plug-in module reduces cabinet space requirements by half compared to traditional 6U cards

API 670-compliant hot-swappable modules

Password protected user configuration

Self-test features include monitoring of hardware, power inputs and hardware temperature

A6824 module can be used in multiple 19’ racks

A6824 is a 6TE wide module with no redundancy option for IMR6000 series 19’ racks

A6824R is a 4TE wide module with optional redundancy for IMR6500 series, 19’ racks

Data Outputs

ModBus RTU (serial): 19.2 kbaud

Data Bits 8

Parity Even

Stop Bit 1

Default address IP address 192.168.255.1

Subnet mask 255.255.255.0

ModBus Ethernet: RJ 45 socket, 10BaseT

Green LED: Power on

Handle: for easy removal of cards and boards

Module and sensor identification board

Example data types: speed, vibration (1/2x, 1x, etc.), gap value, dcs-sis.com alarm status, channel OK, phase

Environment, general

Module: IP 00. DIN 40050

Front plate: IP 21. DIN 40050

Climate: DIN 40040 class KTF

Operating temperature: 0° – 65°C (32° – 149°F)

Storage temperature: -30° – 85°C (-22° – 185°F)

Relative humidity: 5 – 95%, non-condensing

Vibration; IEC 68-2. Part 6

0.15 mm, 10 – 55 Hz

19.6 mm/s2. 55 – 150 Hz

Shock: IEC 68-2. Part 29

98 m/s2 peak, 16 ms

Electromagnetic compatibility: EN50081-1 / EN50082-2

Power consumption: 5 W max.

The CHB 1101 transmitter is an external bi-directional low frequency accelerometer for use with the PCH 1026 mk2 wind turbine and structural vibration monitor.

The external bi-directional accelerometer is used for advanced nacelle monitoring with distributed pick-up points.

Separate cables with integrated D-Sub and M12 connectors make installation and connection of the vibration monitor very simple.

Easy to install

The CHB 1101 has an internal memory chip which stores factory information: serial number, model number, sensitivity and self-test parameters.

When the CHB 1101 is connected, the monitor reads the dcs-sis.com information in the memory chip and automatically adapts to the settings of the particular sensor.

This means that the accelerometer can be freely replaced without having to manually change the parameters.

The monitor reads the chip every 30 seconds to verify that the accelerometer is still connected and recognised.

The monitor will stabilise for 20 seconds after power is applied.

The stabilisation time after disconnecting/connecting the CHB 1101 is 3 seconds. During settling, the PCH 1026 Mk2 will perform a self-test of the internal and external accelerometers.

Self-Test

The monitor will issue a system error message if the self-test fails or the accelerometer is disconnected.

Accelerometers must be specified in the PCH 1026 Vibration Monitor setup to use this feature.

The CHB 1101 accelerometer is an optional feature of the PCH 1026 Mk2 Wind Turbine and Structural Vibration Monitor.

Product Description 

IP-Quadrature provides high density, cost-effective flexible implementation of four quadrature decoder channels. Channels may also be used as general purpose counters. Four independent channels provide 24-bit resolution, programmable modes, programmable polarity, interrupt capability, differential or single-ended (RS-422 or TTL/CMOS) input, read-on-the-fly capability, and a count frequency of 0 to 10 MHz. 

Quadrature encoders are popular sensors that provide accurate, low cost incremental motion sensing. Most commonly, they are shaft encoders that provide 512 to 2048 counts per revolution. 

They are also commonly used as linear encoders with resolutions down to 0.005 inch. They are available in nearly any length desired. Most encoders are now optical, using molded assemblies consisting of a pair of LEDs, lenses, photo-sensors, and simple electronics. For rotary motion the assembly senses alternating opaque and clear lines on a rotating dcs-sis.com wheel. For linear motion the alternating lines may be on a fixed bar and the sensor assembly moves, or vice-versa. The pair of LED and photo-sensors are offset about one-half line width so that direction of motion may be sensed by observing the relative phase of the two outputs. Typical quadrature encoder outputs are a pair of digital logic signals that are nominally 90° out of phase. Some encoders also provide an 

“index” pulse output once per revolution to provide absolute position information. Most modern encoders run from +5 volts and provide CMOS/TTL logic outputs and/or RS-422 differential logic outputs. RS-422 is recommended where possible because of its inherent noise immunity and the ability to run long distances. TTL logic levels should normally be restricted to cables less than ten feet in length. Quadrature encoders are available from Hewlett-Packard, US digital, and other sources. 

The general purpose input structure permits differential input from line drivers (RS-422 levels) or single-ended logic level input (“TTL”) directly from most sensors. Programmable TTL resistive terminators provide for flexible high-quality signal termination. 

Key Features  

 • Four quadrature decoder channels, independently programmable 

 • Any channel may also act as a general purpose counter 

 • 24-bit resolution per channel 

 • DC to 10 MHz general purpose count rates 

 • DC to 1.2 MHz quadrature count rates (higher count rate in X1 and X2 modes) 

 • Counters readable “on the fly”—24-bit output register 

 • 24-bit register for capture or match interrupt on each channel 

 • Inputs may be differential or single-ended 

 • Direct connection to most sensors 

 • Programmable TTL resistor termination 

 • Each channel has a programmable control input 

 • Control input may be used to capture exact position on the fly 

 • Each channel may be used as a general purpose up/down counter 

 • Full programmable interrupt support 

 • Programmable modes; programmable prescaler: 1X, 2X, 4X. 

 • Individually programmable polarities for Count and Control inputs 

 • All CMOS 

 • Up to 16 counter channels per VME slot

Main Features

High-precision decoding of orthogonal signals

Wide operating temperature range for industrial environments

Compact industrial package form factor

Easy integration with compatible systems

Applications

Motion control systems

Position sensing and feedback

Robotics and automation

Based on state-of-the-art Intel® ATOM™ processor technology, the X20 CPUs cover a wide spectrum of demands.

They can be implemented in solutions ranging from standard applications to those requiring the highest levels of performance.

The series starts with Intel® ATOM™ processor 333 MHz compatible models – X20CP1583 and X20CP3583. 

With an optimum price/performance ratio, it has the same basic features as all of the larger CPUs.

The basic model includes USB, Ethernet, POWERLINK V1/V2 and removable CompactFlash. 

The standard Ethernet dcs-sis.com interface is capable of handling communication in the gigabit range.

 For improved real-time network performance, the onboard POWERLINK interface supports poll response chaining mode (PRC).

In addition, there are up to three multi-purpose slots for additional interface modules.

 • Intel® ATOM™ 1600/1000/600 Performance with integrated I/O processor

 • Entry-level CPU is Intel® ATOM™ 333 MHz-compatible with integrated I/O processor

 • Ethernet, POWERLINK V1/V2 with poll response chaining and onboard USB

 • 1 or 3 slots for modular interface expansion

 • CompactFlash as removable application memory

 • Up to 512 MB DDR2-SRAM according to performance requirements

 • CPU redundancy possible

 • Fanless

 • Extremely compa

Description:

.Intel Atom 1.6 GHz processor with additional I/O processor

. Onboard Ethernet, POWERLINK with polled response chain and USB.

. 1 slot for modular interface expansion .

.CompactFlash as removable application memory

.512 MB DDR2 memory

.512 MB DDR2 RAM Fanless

The X20CP1586 is a powerful controller for the X20 system. 

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