Category: Industry trends

5101 Main Processor TriPak:Main Processor Module 3101 -Main Processor Baseplate Kit 2101

5201 Communication Module TriPak: Communication Module 3201- Communication Module Baseplate Kit 2201

5351 Analog Input TriPak :Analog Input Module 3351- Analog Input Baseplate Kit 2351

5361 Analog Input/Digital Input TriPak:Analog Input/Digital Input Module 3361 -Analog Input/Digital Input Baseplate Kit 2361

5352 Analog Input Tripak (RTD/TC/4-20 mA):Analog Input Module 3351 -Analog Input Baseplate (RTD/TC/4-20 mA) 2352

5381 Analog Output TriPak : Analog Output Module3481 – AO Module Baseplate Kit 2481

5382 High-Current Analog Output Tripak: High-Current Analog Output Module 3482 – AO Module Baseplate Kit 2481

5301 Digital Input TriPak : Digital Input Module 3301 – Digital Input Baseplate Kit 2301

5302 Digital Input TriPak (high voltage) : Digital Input Module 3301 – Digital Input Baseplate Kit (high voltage) 2302

5401 Digital Output TriPak : Digital Output Module 3401 -Digital Output Baseplate Kit 2401

5401L Digital Output TriPak (low current) : Digital Output Module 3401 -Digital Output Baseplate Kit (low current) 2401L

5402 Digital Output TriPak (high voltage) : Digital Output Module 3401 – Digital Output Baseplate Kit (high voltage) 2402

5451 Solid-State Relay Output TriPak : Solid-State Relay Output Module 3451 – Solid-State Relay Output Baseplate Kit 2451

5481 Pulse Input TriPak : Pulse Input Module 3381 Pulse Input Baseplate Kit 2381

2101 Main Processor Baseplate Kit : MP Baseplate 3000671-100 MP Interconnect Assembly 2920 Trident User Documentation (hardcopy)8910-2 Accessories Kit 8401 Top End Cap – I/O 2910 Top End Cap – MP 2912 Bottom End Cap – I/O 2911 Bottom End Cap – MP 2913

2281 I/O Bus Extender Module Kit : I/O Extender Module 3000678-100 2-ft. I/O Bus Cables (Set of 3) 4000056-002 I/O Interconnect Assembly 2921 Top End Cap – I/O 2910 Bottom End Cap – I/O 2911

2291 I/O Bus Termination Kit, I/O Baseplate : I/O Extender Module 3000678-100 I/O Interconnect Assembly 2921 I/O Bus Terminator Kit 3900064-003

2292 I/O Bus Termination Kit, MP Baseplate : I/O Extender Module 3000678-100 MP Interconnect Assembly 2920 I/O Bus Terminator Kit 3900064-003

Standard Trident Products (Continued)

2301 Digital Input Baseplate Kit : I/O Baseplate 3000673-020 I/O Interconnect Assembly 2921 Slot Cover 2900 Terminal Cover 2901

2302 Digital Input Baseplate Kit (high voltage) :2 I/O External Termination Baseplate 3000721-300 External Termination Panel (Solid State Relay Input)3000762-110 I/O Interconnect Assembly 2921 Slot Cover 2900 Interface Cable, 10 ft 9105-310 SSR Input Modules for use with SSR Input ETP 100 to 240 VAC 1300447-001

2302A Digital Input Baseplate Kit, Hazardous Location : I/O External Termination Baseplate 3000721-300 External Termination Panel Kit 9573-610 I/O Interconnect Assembly 2921 Slot Cover2900 Terminal Cover 2901

2342 Analog Input/Digital Input Baseplate Kit, External Termination : I/O External Termination3000721-130 Baseplate I/O Interconnect 2921 Assembly Slot Cover 2900 Terminal Cover 2901

2342A Analog Input/Digital Input Baseplate Kit, Hazardous Location : I/O External Termination 3000721-130 Baseplate I/O Interconnect 2921 Assembly Slot Cover 2900 Terminal Cover2901 AI/DI ETP Kit, Hazardous Location 9793-610

2351 Analog Input Baseplate Kit: I/O Baseplate 3000675-010 I/O Interconnect 2921 Assembly Slot Cover 2900 Terminal Cover 2901

2352 Analog Input Baseplate Kit for TC, RTD, and 4-20mA (requires 2 of part number 9764-510) : I/O External Termination 3000721-100 Baseplate I/O 2921 Interconnect Assembly 2900 Slot Cover Terminal Cover 2901

2352A Analog Input Baseplate Kit, Hazardous Location :I/O External Termination Baseplate External Termination Panel Kit I/O Interconnect Assembly Slot Cover Terminal Cover 3000721-100 9792-310 2921 2900 2901

2354 Analog Input HART Baseplate Kit : I/O HART Baseplate MP Interconnect Assembly Slot Cover Terminal Cover 3000851-010 2920 2900 2901

2354A Analog Input HART Hazardous Location Baseplate Kit—ATEX : I/O HART Baseplate MP Interconnect Assembly Slot Cover Terminal Cover 3000851-110 2920 2900 2901

Standard Trident Products (Continued)

2361 Analog Input/Digital Input Baseplate Kit : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000675-020 2921 2900 2901

2381 Pulse Input Baseplate Kit : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000719-100 2921 2900 2901

2401 Digital Output Baseplate Kit : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000674-030 2921 2900 2901

2401L Digital Output Baseplate Kit (low current) : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000659-130 2921 2900 2901

2402 Digital Output Baseplate Kit (high voltage) : I/O Baseplate External Termination Panel (Relay Output ETP) I/O Interconnect Assembly Slot Cover Interface Cable, 10 ft 3000764-300 3000763-110 2921 2900 9106-310 Relay Output Modules for use with Relay Output ETP SSR, 2 A at 75 to 264 VAC SSR, 2 A at 4 to 60 VDC SSR, 1.5 A at 40 to 200 VDC Power (Dry Contact) Relay; 440 VAC max, 125 VDC max 1300462-001 1300471-001 1300472-001 1300463-001

2402A Digital Output Baseplate Kit, Hazardous Location : I/O External Termination Baseplate External Termination Panel Kit I/O Interconnect Assembly Slot Cover Terminal Cover 3000764-300 9671-610 2921 2900 2901

2451 Solid-State Relay Output Baseplate Kit : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000676-310 2921 2900 2901

2480A Analog Output Baseplate Kit, Hazardous Location 1 : I/O External Termination Baseplate External Termination Panel Kit I/O Interconnect Assembly Slot Cover Terminal Cover 3000764-300 9863-610 2921 2900 2901

2481 Analog Output Baseplate Kit : I/O Baseplate I/O Interconnect Assembly Slot Cover Terminal Cover 3000674-010 2921 2900 2901

Standard Trident Products (Continued)

2483 Analog Output HART Baseplate Kit ： I/O HART Baseplate MP Interconnect Assembly Slot Cover Terminal Cover 3000852-020 2920 2900 2901

2483A Analog Output HART Hazardous Location Baseplate Kit—ATEX ： I/O HART Baseplate MP Interconnect Assembly Slot Cover Terminal Cover MTL4546 Intrinsic Safety Barrier—Isolator 3000852-120 2920 2900 2901 1600107-001 8401 Trident Accessory Kit ： Set of Spare Fuses Set of Address Plugs (1 through 10) Set of Address Plugs (11 through 20) Set of Address Plugs (21 through 32) 3000698-010 3000698-020 3000698-030

9573-610 Digital Input Termination Panel Kit, Hazardous Location (for use with Model 2302A) 2 2 External Termination Panel, D1 Interface Cable, 10 ft, DI 3000771-880 4000165-310

9671-610 Digital Output Termination Panel Kit, Hazardous Location (for use with Model 2402A) ： External Termination Panel, DO Interface Cable, 10 ft, DO 3000769-390 4000166-310

9764-510 RTD/TC/AI Termination Panel Kit (for use with Model 2352) ： External Termination Panel, RTD/TC/AI Interface Cable, 10 ft 3000712-100 4000103-510 Signal Conditioning Modules for use with 9764-510 4–20 mA 32F to 392F (0C to 200C), RTD 32F to 1112F (0C to 600C), RTD 32F to 1400F (0C to 760C), Type J TC 32F to 2372F (0C to 1300 C), Type K TC 32F to 752F (0C to 400C), Type T TC 32F to 1652F (0C to 900C), Type E TC Shorting Plug 1600048-220 1600048-030 1600048-040 1600048-110 1600048-120 1600048-130 1600048-140 1600048-300

9792-310 Analog Input Termination Panel Kit, Hazardous Location (for use with Model 2352A) ： External Termination Panel, AI Interface Cable, 10 ft, AI 3000771-710 4000164-510

9793-610 Analog Input/Digital Input Termination Panels Kit, Hazardous Location (for use with Model 2342A) ： External Termination Panel, AI External Termination Panel, DI Interface Cable, 10 ft, AI Interface Cable, 10 ft, DI 3000771-710 3000771-880 4000164-510 4000165-310

9863-610 Analog Output Termination Panel Kit, Hazardous Location (for use with Model 2480A) ： External Termination Panel, AO Interface Cable, 10 ft, AO 3000770-960 4000163-510

riconex 4850

Triconex 4850 HART Multiplexer 1 Triconex 4850 HART Multiplexer 1600106-001

7254-8 TriStation 1131 Developer’s Workbench version 4.5 ： CD containing: Developer’s Workbench (software) TriStation 1131 Help Documentation (online) TriStation 1131 v 4.5 Documentation Set (hardcopy) 3000755-814

7255-8 TriStation 1131 Developer’s Workbench version 4.5 with CEMPLE ： CD containing: Developer’s Workbench (software) TriStation 1131 Help Documentation (online) TriStation 1131 v 4.5 Documentation Set (hardcopy) 3000755-815

8910-2 Trident User Documentation (hardcopy) ： Planning and Installation Guide for Trident v2 Systems Communication Guide for Trident v2 Systems 9700110-002 9700111-002

8747-8 TriStation 1131 version 4.5 User Documentation (hardcopy) ： TriStation 1131 Developer’s Guide TriStation 1131 Libraries Reference Safety Considerations Guide for Trident v2 Safety Considerations Guide for Trident v1 Safety Considerations Guide for Tricon 9700100-007 9700098-007 9700112-001 9700096-002 9700097-001

7523-2 Triconex DDE Server ：CD containing DDE Server software and documentation DDE Server, v4.1 Documentation Set (hardcopy) 3000723-301 9700108-001

7521-4 SOE Recorder version ： CD containing SOE Recorder and documentation SOE Recorder, v4.1 Documentation Set (hardcopy) 3000708-400 9700081-004

7260-4 Enhanced Diagnostic Monitor, v2.2： CD containing Enhanced Diagnostic Monitor, v2.2 (software) Enhanced Diagnostic Monitor, v2.2 Documentation Set (hardcopy) 3000796-006 9700107-004

Contact Triconex for current model number Triconex Documentation Set ： CD containing documentation in PDF format

International Approvals

The Trident controller has been certified as complying with multiple internationally recognized standards by the following internationally recognized certification agencies, these certifications have qualified the Trident for use around the world in safety critical applications. Test reports from the various certification agencies are available upon request.

Canadian Standards Association

CSA has certified that the Trident v2.x controller is in full compliance with the following internationally recognized electrical safety standards and is qualified for general use in North American and other jurisdictions requiring compliance with these standards.

European Union CE Mark

Based upon the independent TÜV evaluation and test results, Triconex has certified the Trident v2.x controller suitable to use in the European Union and all other jurisdictions requiring compliance with the European Union EMC Directive No. 89/336/EEC and Low Voltage Equipment Directive No. 72/23/EEC. See Certificate of Compliance for details.

To ensure maximum reliability and trouble-free operation, the Trident and associated wiring must be installed following the guidelines outlined in the Planning and Installation Guide

To comply with the CE Mark requirement for emissions, the Main Processor Modules and the Communication Modules must be mounted in a metal enclosure. To ensure compliance with the EU directives, the following additional guidelines must be followed:

The Main Processor Modules and the Communication Modules must be mounted in a metal enclosure.

Field power supplies must be approved for use in safety extra-lowvoltage (SELV) circuits according to the requirements of IEC 61010-1.

TÜV Rheinland

TÜV has certified that the Trident v2.x is in full compliance with the internationally recognized standards listed on page 23.

Factory Mutual

FM has certified the Trident v2.x controller is in full compliance with the international recognized standards listed on page 23 and is qualified for use in Class I, Division 2 Temperature T4, Groups A, B, C, and D hazardous indoor locations. For hazardous location applications, redundant power sources must be used for system power.

Environmental Specifications

Designed for critical applications, the Trident performs predictably in a hostile industrial environment. The specifications listed on the table to the right confirm this built-in reliability. However, due to the number of diverse items that make up a Trident system, not all of the listed specifications apply to every item. Please contact Triconex to obtain the specifications for particular items.
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Datasheet Bently Nevada Machinery Condition Monitoring

Description

The 1900/65A General Purpose Equipment Monitor is designed to continuously monitor and protect equipment that is used in a variety of applications and industries. The monitor’s low cost makes it an ideal solution for generalpurpose machines and processes that can benefit from continuous monitoring and protection.

Inputs

The 1900/65A provides four transducer inputs and four temperature inputs. Software can configure each transducer input to support 2- and 3-wire accelerometers, velocity sensors or proximity sensors. Each temperature input supports Type E, J, K, and T thermocouples, and 2- or 3-wire RTDs.

Outputs

The 1900/65A provides six relay outputs, four 4-20 mA recorder outputs, and a dedicated buffered output. The user can use the 1900 Configuration software to configure the relay contacts to open or close according to the OK, Alert and Danger statuses of any channel or combination of channels, and to provide data from any variable from any channel on any recorder output. The dedicated buffer output can provide the signal for each transducer input.

A Modbus Gateway option allows the monitor to provide static variables, statuses, event list, time and date information directly to any Modbus client, including Distributed Control Systems (DCSs), Supervisory Control and Data Acquisition (SCADA) systems, Programmable Logic Controllers (PLCs), or System 1 software. The monitor uses an internal counter and a Modbus client/master time reference to generate time and date information. Users can upgrade monitors without the Modbus Gateway by ordering the 1900/01 Communications Upgrade (see the Ordering Information section). The 1900/65A supports Modbus communications via Ethernet and a software-configurable RS232/485 serial port.
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Configurable Block Periods

0.05, 0.1, 0.2, 0.5, 0.6, 1, 2, 5, 6, 10, 30 seconds 1, 10, 60 minutes

Block Processing Cycle

0.05, 0.1, 0.2, 0.5 and 1.0 seconds, selectable at system configuration time

Time to Marry Fault-Tolerant Modules

Less than 1 second

Internal Diagnostics

Self-checking performed at power-up. Run-time checks and the watchdog timer function performed during operation.

Infrared Communications

Letterbug assignment via the Letterbug Configurator. Letterbug or Hardware ID readout via the Letterbug Configurator.

Power Requirements

INPUT VOLTAGE (REDUNDANT VOLTAGE)

24 V dc typical

CONSUMPTION (PER NON-FAULT-TOLERANT MODULE)

8.5 W, maximum

Regulatory Compliance

ELECTROMAGNETIC COMPATIBILITY (EMC)

European EMC Directive 89/336/EEC

Meets: EN 50081-2 Emission standard

EN 50082-2 Immunity standard

EN 61326 Annex A (Industrial Levels)

CISPR 11, Industrial Scientific and Medical (ISM) Radio-frequency Equipment – Electromagnetic Disturbance Characteristics – Limits and Methods of Measurement Meets Class A Limits IEC 61000-4-2 ESD Immunity Contact 4 kV, air 8 kV IEC 61000-4-3 Radiated Field Immunity 10 V/m at 80 to 1000 MHz IEC 61000-4-4 Electrical Fast Transient/Burst Immunity ±2 kV on I/O, dc power and communication lines

IEC 61000-4-5 Surge Immunity ±2 kV on ac and dc power lines; ±1 kV on I/O and communications lines IEC 61000-4-6 Immunity to Conducted Disturbances Induced by Radio-frequency Fields 10 V (rms) at 150 kHz to 80 MHz on I/O, dc power and communication lines IEC 61000-4-8 Power Frequency Magnetic Field Immunity 30 A/m at 50 and 60 Hz

PRODUCT SAFETY

Underwriters Laboratories (UL) for U.S. and Canada

UL/UL-C listed as suitable for use in UL/ULC listed Class I, Groups A-D; Division 2; temperature code T4 enclosure based systems. These modules are also UL and UL-C listed as associated apparatus for supplying non-incendive communication circuits for Class I, Groups A-D hazardous locations when connected to specified I/A Series/Foxboro Evo system Fieldbus Modules as described in the DIN Rail Mounted Subsystem User’s Guide (B0400FA). Communications circuits also meet the requirements for Class 2 as defined in Article 725 of the National Electrical Code (NFPA No.70) and Section 16 of the Canadian Electrical Code (CSA C22.1).Conditions for use are as specified in the DIN Rail Mounted Subsystem User’s Guide (B0400FA).

EUROPEAN LOW VOLTAGE DIRECTIVE 73/23/EEC AND EXPLOSIVE ATMOSPHERES (ATEX) DIRECTIVE 94/9/EC

CENELEC (DEMKO) certified as EEx nAnL IIC T4 for use in CENELEC certified Zone 2 enclosure certified as associated apparatus for supplying non-incendive field circuits for Zone 2, Group IIC, potentially explosive atmospheres when connected to specified I/A Series system Fieldbus Modules as described in the DIN Rail Mounted Subsystem User’s Guide (B0400FA).

FUNCTIONAL SPECIFICATIONS (CONTINUED)

SECURITY

Wurldtech Achilles Certification™ Level One

ENVIRONMENTAL SPECIFICATIONS(2)

Operating

TEMPERATURE:0 to +60°C (+32 to +140°F)

RELATIVE HUMIDITY :5 to 95% (Noncondensing)

ALTITUDE:-300 to +3,000 m (-1,000 to +10,000 ft)

CONTAMINATION:Class G3 (Harsh) as defined in ISA Standard, S71.04. Pollution degree 2 as defined in IEC 664-1.

VIBRATION:0.5 g (5 to 500 Hz)

Storage

TEMPERATURE:-40 to +70°C (-40 to +158°F)

RELATIVE HUMIDITY :5 to 95% (Noncondensing)

ALTITUDE:-300 to +12,000 m (-1,000 to +40,000 ft)

PHYSICAL SPECIFICATIONS

Configuration:Single processor module. The fault-tolerant version consists of two processor modules, with an interconnecting fault-tolerant connector integral to the baseplate.

Mounting:May be placed in device specific 2- or 4-position baseplates designed for horizontal or vertical mounting. For the fault-tolerant FCP270, the two modules must be mounted in dedicated slots to allow for interconnecting fault-tolerant communication.

Dimensions – Module

HEIGHT

103 mm (4.04 in)

114 mm (4.50 in) including mounting lugs

WIDTH:51.5 mm (2.03 in)

DEPTH:147 mm (5.80 in)

Mass (Maximum) :0.6 kg (1.3 lb) for a single, non-fault-tolerant module.

Fiber Optic Cabling – Ethernet Switch to FCP270

CONNECTORS

Ethernet Switch Connector

One MT-RJ Connector

FCP270 or Splitter/Combiner Connector

Two ceramic type LC connectors with clip

FIBER OPTIC CABLE

Cable Material

Multimode fiber (MMF) 62.5/125 µm plenum Cable Lengths

3 m (9.9 ft), 15 m (49.5 ft), 50 m (165 ft) greater than 50 m – user supplied

Maximum Length 2 km (6,560 ft) from the Ethernet switch to the FCP270.

Fiber Optic Cabling – Splitter/Combiner to FCP270

CONNECTORS

Two ceramic type LC connectors with clip on each end

FIBER OPTIC CABLE

Cable Material

Multimode fiber (MMF) 62.5/125 µm

Cable Lengths

0.5 m (1.6 ft), 1.0 m (3.3ft), 3.0 m (9.9 ft),

15 m (49.5 ft), 50 m (165 ft)

greater than 50 m – user supplied

Maximum Length

2 km (6,560 ft) total from the Ethernet switch to the FCP270, including the cabling to the splitter/combiner.

FCP270 Fieldbus without FCM2Fs The cable length of the Fieldbus cannot exceed 60 m (198 ft) (see Figure 4).

FCP270 Fieldbus with FCM2Fs

Each FCP/FCM drives a segment of interconnected baseplates of up to 60 m (198 ft). Up to four pairs of FCM2Fxs can be used in a Fieldbus network (see Figure 5).

FCP270 Fieldbus and Expanded Fieldbuses (1-4) without FCM2Fs The cable length of the Fieldbus cannot exceed 60 m (198 ft) (see Figure 6).

FCP270 Fieldbus and Expanded Fieldbuses (1-4) with FCM2Fs Each FCP/FCM drives a segment of interconnected baseplates of up to 60 m (198 ft). Up to four pairs of FCM2Fxs can be used in each Expanded Fieldbus network (see Figure 7).
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The self-hosting feature is recommended only for use in FCP270s which are used with 200 Series FBMs. All of the information necessary to reboot 200 Series FBMs is included in non-volatile flash memory on the FCP270. However, the flash memory on the 100 Series FBMs and related products on the 268k fieldbus does not include this information, and they require the workstation host to be present to reboot. More details on the self-hosting feature are available in DIN Rail Mounted FBM Subsystem User’s Guide (B0400FA).

DEVICES SUPPORTED

The FCP270 supports the following devices on the 2 Mbps module Fieldbus:

All 200 Series FBMs (FBM201, FBM202, and so forth) – both Compact and standard types

Field Device Systems Integrator (FDSI) modules

Intrinsically Safe I/O Subsystem (ISCM)

DCS Fieldbus Modules for Siemens APACS+™ Systems

DCS Fieldbus Modules for Westinghouse WDPF® Systems.

DCS Fieldbus Modules for Fisher’s PROVOX® Series 20 Migration with HART

DCS Fieldbus Modules for Honeywell® TDC 2000 Systems with HART.

The FCP270 supports the following devices on the 268 Kbps fieldbus:

100 Series FBMs (FBM01, FBM02, and so forth)

Fieldbus Cluster I/O via FBP10 fieldbus processor module

Foxboro® Hydrostatic Interface Unit (HIU)(1)

Foxboro Mass Flowmeter

Foxboro Panel Display Stations

SPECTRUM™ Migration Integrators

SPEC 200™ Control Integrators

SPEC 200 MICRO™ Control Integrators

SPEC 200 CCM Control Integrators

DCS Fieldbus Modules for Honeywell® TDC 2000 and TDC 3000 Systems

DCS Fieldbus Modules for Bailey® Net90 and Infi90 Systems

DCS Fieldbus Modules for Fisher’s PROVOX® Series 10, Series 20, and Controller Series Systems.

The Foxboro Gas Chromatograph is not supported.

BASEPLATE:The FCP270 is installed on a modular, DIN rail mounted baseplate in a dedicated slot that is keyed for the controller, so other modules cannot be placed in these slots. For further information on DIN rail mounted equipment, refer to PSS 21H-2W1 B3 and PSS 31H-2COV B3.

LED INDICATORS

Light-emitting diodes (LEDs) on the front of the FCP270 module provide visual indication of the:

FCP270 operational status

Communications activity of The MESH control network A and B links

 Communications activity of fieldbus A and B

 Infrared communications activity.

The MESH control network path Tx LEDs indicate which controller is primary as well as the network path it is using; these LEDs are only active on the primary module.

FUNCTIONAL SPECIFICATIONS

Processor Type

CONTROL PROCESSOR

Microprocessor-based AMD Elan 520 (running at 100 MHz) with stored programs, using highspeed communication capability. In addition, the CommControl™ ASIC with an internal 80186 controls the communication to the I/O Modules (FBMs).

Memory

SIZE

16 MB SDRAM

32 MB flash memory

ERROR DETECTION

ECC providing single-bit error detection and correction as well as multiple-bit error detection.

Process I/O Communications (with FBMs) MODULE FIELDBUS

Type

HDLC

Transmission Rate

2 Mbps for 200 Series FBMs or 268 Kbps for 100 Series FBMs

Process I/O Capacity 2 MBPS HDLC FIELDBUS

200 Series FBMs

32 maximum without FEM100 modules or with FEM100 modules, control usage supports capability for up to 128 FBMs. Refer to FCP270 Sizing Guidelines (B0700AV) for sizing constraints. Competitive Migration Modules Refer to the device specific Product Specification Sheets

268 KBPS HDLC FIELDBUS

100 Series FBMs

64 maximum depending on control processor sizing constraints (refer to FCP270 Sizing Guidelines [B0700AV]). Competitive Migration Modules Refer to the device specific Product Specification Sheets

Process I/O Capacity (Cont.)

MIX OF 2 MBPS HDLC FIELDBUS AND 268 KBPS HDLC FIELDBUS

In addition to previous sizing constraints, the total number of 100 Series and 200 Series FBMs and/or competitive migration modules supported (mixed) is 64 modules, maximum.

Memory Allocation for Blocks:5.8 MB

Maximum Number of Blocks Configured

The maximum number of blocks that can be configured for the FCP270 (or fault-tolerant FCP270 pair) is 4000.

Block Executions Per Second :10,000 blocks/second, maximum

Maximum Number of Blocks Processed

The number of blocks that can be processed per block processing cycle (BPC) time interval depends on scan periods and block type selection. These blocks include all types (control blocks, ECBs, compounds, data blocks, and so forth). For sizing guidelines, refer to FCP270 Sizing Guidelines (B0700AV).

Minimum Block Processing Cycle (BPC) :50 ms

Sequence Block Size:32 KB maximum for each block

Maximum Number of IPC Connections :131; 100 connections for source points; 30 connections for sink points; 1 connection for internal use only.

Maximum Number of OM Sink Lists:50

Maximum OM Scanner Database

12,000 points for BPC ≥ 200 ms

5,000 points for BPC ≤ 100 ms

Maximum Number of OM Sink Points :7,500
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President Donald Trump has expressed displeasure in recent days about the long wait for two Boeing 747s to serve as the new Air Force One aircraft.

The planes are years behind schedule for delivery. Trump signed a $4 billion contract for the planes during his first term, and it’s unclear if they will be ready during his current term. Cost overruns have totaled more than $2 billion so far.

Boeing CEO Kelly Ortberg reiterated Thursday that Trump adviser Elon Musk is working with Boeing to get the planes delivered faster.

“The president is clearly not happy with the delivery timeline. I think he’s made that very clear,” Ortberg said at the Barclays Industrials Conference. “Elon Musk has actually been very helpful to us in terms of meeting the requirements … helping us work through those non-value-added constraints so that we can move more quickly and get these airplanes delivered to the president.”

Ortberg praised Musk as a “smart guy” who “is able to very quickly identify the difference between a technical requirement and a hurdle that we can get around.” Musk is the CEO of SpaceX, which competes with Boeing’s defense and space division.

Trump told reporters on Wednesday aboard a 747 presidential jet he’s currently flying that he was considering other options.

“We might buy a plane, or buy a plane, or something,” Trump said, according to Reuters, who toured a 747 parked at Florida’s Palm Beach International Airport over the weekend, according to the outlet.

The White House did not immediately respond to a request for comment.

Disappointment is nothing new for Boeing’s airline customers, who faced long delays at the start of the post-pandemic travel boom. A near-catastrophic blowout of Boeing’s door plugs in January 2024 further slowed deliveries and prompted a leadership change.

Now, some customers are starting to become more optimistic. Executives told CNBC that the manufacturer appears to have turned a corner after Ortberg took over in August.

“Boeing has done a pretty good job of turning things around and becoming a more reliable supplier,” United Chief Financial Officer Mike Leskin said at the same Barclays conference on Wednesday. “In my time at United, our confidence in on-time MAX deliveries has never been stronger.”

Bob Jordan, CEO of all-Boeing 737 carrier Southwest, said on a Jan. 30 earnings call: “While they still have a lot of work to do, they appear to be on the right path and we feel more optimistic.”

Boeing’s Ortberg said at the Barclays conference on Thursday that he doesn’t see any supply chain issues that would prevent the manufacturer from increasing production of its best-selling cash cow 737 Max aircraft to 38 per month in the coming months.
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The SEC is dropping its investigation into Robinhood’s crypto unit, the company revealed on Monday.

Robinhood said it received a letter from the SEC’s enforcement division on Friday detailing that the agency had closed its investigation into the cryptocurrency business and had no intention of taking enforcement action. Three days ago, Coinbase also announced that the SEC had agreed to end its enforcement case against it.

Robinhood shares initially rose on the news, but ultimately closed down 3.2% as the stock market retreated from its highs of the day.

In May 2024, Robinhood received a notice warning that its crypto unit could be charged for securities violations after the company received subpoenas for its cryptocurrency listings, custody, and platform operations — despite “our good faith attempts to work with the SEC to obtain regulatory clarity over the years, including our well-known ‘come in and register’ attempts,” Dan Gallagher, the company’s chief legal, compliance and corporate affairs officer, said at the time.

“Robinhood Crypto has always respected federal securities laws and would never allow securities trading,” he said in a statement on Monday. “We appreciate the formal closure of this investigation, and we are pleased to see the SEC return to the rule of law and commitment to fairness.”

A spokesperson for the SEC declined to comment for this story.

The SEC’s dismissal of the Robinhood and Coinbase lawsuits is an early sign of regulatory changes to the crypto industry that President Trump promised during his campaign. Despite the surge in Bitcoin prices, many crypto businesses saw it as a low point under the previous administration due to the SEC’s notoriously aggressive enforcement approach to cryptocurrencies under then-Chairman Gary Gensler, rather than clear operating rules.

Bitcoin prices rose to $100,000 for the first time, and nearly half of Robinhood’s $672 million in fourth-quarter trading revenue came from a 700% increase in revenue related to cryptocurrency trading, as the Trump administration is expected to introduce more favorable policies.

So far in 2025, Robinhood shares have risen 34%.
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Key findings:

Customer pain points: Traditional water plant business is discrete, and real-time data synchronization cannot be achieved, which brings obstacles to the collection, analysis and processing of data and auxiliary decision-making. Intelligent management systems are needed to help water plants improve management efficiency, optimize management processes, and achieve digital and intelligent goals.

Solution: Based on customer needs, Tianjin Tengling developed a smart water management integrated management platform using the Mendix low-code development platform to help customers achieve digital transformation of water plant management and fully realize the collaboration of “people, machines, and objects”.

Implementation effect: The project development cycle was shortened by 50%, and the corresponding human resources were saved by more than 50%; after the project was launched, the water plant customers achieved a carbon reduction of 0.58 tons per month and a drug consumption saving of more than 25%.

Traditional water plant

Discrete business hinders smart management

Tianjin Tengling Electronic Technology Co., Ltd. (hereinafter referred to as Tianjin Tengling) is a supplier of digital overall solutions from end to cloud and plug-and-play. The core products are based on 5G cloud PLC and privatized open IOT data middle platform, as well as the industry’s first industrial Internet bus protocol TenNet, combined with the SAAS application developed by Siemens Mendix low-code platform, and successfully deployed in smart equipment, smart transportation, smart buildings, smart agriculture, smart docks, smart pipe corridors, smart water affairs, smart flood control and other fields of industry digital solutions.

As a partner of Siemens Mendix, Tianjin Tengling recently cooperated with Mendix to develop the smart water affairs integrated management platform project of Shangrao Water Plant.

Before the launch of the smart water affairs integrated management platform, since the business of the water plant is discrete, whether it is within the plant or between water plants, on-site management cannot solve the physical distance problem, nor can it achieve real-time synchronization of data. As the five elements of production management, how to make people, machines, things work together, how to effectively implement the “law”, how to adjust the “environment”, and how to efficiently inherit and pass on experience all need to be improved in intelligence.

Sun Jingyan, manager of Tianjin Tengling’s operations department, is responsible for providing industry customers with full life cycle management of projects from beginning to end, involving preliminary project research, pre-sales architecture design, sales business confirmation, after-sales execution, and the connection and resource allocation of project operation and maintenance.

Stand out

Mendix low-code strength assists

In the Shangrao Water Plant Smart Water Comprehensive Management Platform project, Tianjin Tengling tried many low-code platforms to help customers save development manpower. At first, the difference in basic functions did not seem so obvious, but in the process of use, the different defects of different platforms made Tianjin Tengling unable to complete the presentation of an overall project. After repeated comparisons and demonstrations, it was finally determined that Mendix was the most suitable low-code development platform. The specific development situation is compared as follows:

Although everyone thinks that the setting of login personnel permissions is a very simple function, it is difficult to achieve the extreme. Some platforms can only distinguish permissions by whether the interface can be displayed, while Mendix can be detailed to a small function in a separate page. For example, the customer wants all personnel who log in to the system to view the data on this page, but cannot perform remote control functions on the cloud for several controls. Mendix can be divided by permissions to avoid operational errors, but many other platforms need to create different pages for different personnel, so there is no reduction in development manpower.

The platform “self-defined fine decoration”, most low-code platforms have provided UI templates, but the templates are more like packages and cannot achieve real DIY. For example, in this project, Tianjin Tengling has integrated figma and creat interface design to improve the visual effect of the system, making this system not only a tool, but also a work of art, which makes managers feel refreshed when using it.

Data governance assists decision-making, and the intelligent management system built with the Mendix low-code platform provides customers with data basis, realizes data persistence within Mendix, allows customers’ experience to be accumulated, and makes the next plan based on it. Through the data model algorithm built with sufficient historical information, it can predict and guide future production links.

Mendix’s standardized templates are more powerful than other low-code platforms, including modules such as production management and project management. They can be quickly built by dragging and dropping. At the same time, they are highly compatible and can be smoothly connected to other cloud platforms that have been developed and can be well connected with the data center, providing a solid foundation for IT development of the Internet of Everything.

Tianjin Tengling used Mendix low-code to help Shangrao Water Plant develop a smart water management integrated management platform project that achieved:

Multi-plant parallel management, digital twin of physical water plants;

Real-time monitoring of inflow and outflow data;

Management of process flow, including real-time data of each production link, equipment operation status, equipment operation record, instrument data, instrument overview, dosing data, etc.;

Storage, retrieval, reuse of historical data, generation of reports, statistical analysis, and operation information recording are realized;

Real-time alarm records are realized, and remote inspection notifications are issued to realize synchronization of cloud control, cloud inspection and offline inspection information;

Intelligent control section realizes cloud control, local control, fixed frequency setting, cloud parameter revision, and comparison of predicted data and real-time data;

Integrate intelligent algorithms to build data models for effluent water quality, dosing amount, and equipment use, integrate environmental data, plant construction physical data and other information resources, and implement iterative updates of data models after deep learning, so that the algorithm is more accurate and more in line with actual production, which has good guiding significance.

If this project uses traditional development methods, it is expected to extend the delivery cycle by about twice as long as that of Mendix low-code development. The delivery cycle and manpower are both increasing year-on-year. At the same time, traditional development has very high requirements for experience and technology to ensure the smooth testing process, and the increase in manpower is expected to be more than doubled. After the project was launched, carbon emissions were reduced by 0.58 tons per month, and drug consumption was saved by more than 25%.

The future is promising

Working side by side with Mendix

Summarizing the benefits of Siemens Mendix platform in helping end users develop applications, Sun Jingyan summarized them into the following points:

The compatibility of Mendix low-code platform helps solve the difficulties of discrete management and break the island effect;

Maximize the value of data resources, trace the past, establish data models through data persistence, present prediction effects and real-time comparisons on the platform, and lay the foundation for experts to provide professional advice;

Realize data linkage, better combine with edge control, and realize cloud-edge-end collaborative control.

In addition to the smart water management platform, Tianjin Tengling has also established industrial Internet applications covering multiple industries based on the Mendix low-code development platform, including water conservancy, agriculture, gardens, building parks, intelligent manufacturing, transportation, pipe corridors, etc. to achieve IT\OT\CT, unified connection, unified cloud, unified data management, and unified innovative applications. It can realize hierarchical and hierarchical permission settings, while meeting the requirements of real-time data transmission and long-term record preservation, giving value to data resources, achieving traceability in the past and expectations in the future. At the same time, according to the threshold setting, clear alarm levels are set to prepare for a rainy day and prevent problems before they happen, and enjoy long-term peace and stability without knowing it. Avoid risks, effectively predict, and use data experience to bring a digital cornerstone for sustainable development to enterprises.

Sun Jingyan said: “Opportunities are always reserved for those who are prepared. We use low-code to realize the Internet of Everything and digital twins. We can implement our IOT integration solutions regardless of industry or field. It is not because we are lucky or outstanding, but because we stand on the shoulders of giants. Siemens Mendix is ​​a ‘giant’ for us, which enables us to see higher and farther, do faster and better.” In the future, Tianjin Tengling hopes to combine the Siemens Mendix low-code platform with its existing projects to jointly develop a standardized platform suitable for general management in all walks of life. At the same time, it can also create industry standardized platforms for several industrial Internet industries. On the basis of the standardized platform, the iteration function of the low-code platform can also be used to quickly upgrade and transform the project. Without changing the hardware facilities and equipment, the software can be quickly upgraded and iterated, which will help the development of enterprises in various industries.
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