TSI Monitoring Systems
-
Bently Nevada 3300/25 | Bently Nevada | Accelerometer Monitor
Bently Nevada 3300/25 Dual Accelerometer Monitor Configured for casing vibration measurement from dual accelerometer inputs in the 3300 Monitoring System, the Bently Nevada 3300/25 Dual Accelerometer Monitor (3300/25) provides direct physical/electrical execution of two-channel vibration signal conditioning, alarm comparison, and proportional output generation. SuffixBreakdown&ModelMatrix The 3300/25 is a fixed functional module designation within the Bently Nevada 3300 series. No further functional subdivision or suffix-based performance matrix is defined in the provided technical dataset. Electrical configuration, scaling, and approvals are determined by system-level implementation and hardware revision. HardwareSpecifications Parameter Specification ModelBrand Bently Nevada 3300/25 Origin USA (manufacturer reference: Bently Nevada / Baker Hughes) OperatingTemp 0 degC to +65 degC Input Channels 2 independent accelerometer/velocity inputs Signal Processing Dual-channel vibration conditioning and scaling Output Type 4-20 mA DC, buffered raw vibration output Alarm Functions Alert and Danger setpoints per channel Relay Output SPDT or DPDT, epoxy sealed contacts Eddy-current probe scaling and gap voltage validation (-10 VDC targets) The 3300/25 signal processing chain is aligned with Bently Nevada transducer scaling architecture, including compatibility with eddy-current proximity probe systems where applicable in the 3300 platform. Internal scaling logic supports gap voltage validation referenced to standard -10 VDC proportional signal ranges used in proximity measurement chains. Cross-channel comparison logic is implemented to reduce measurement deviation between paired vibration inputs under steady-state rotational conditions. FrequentlyAskedQuestions Q: Can the 3300/25 process two independent accelerometer signals simultaneously?A: Yes. The module contains two isolated processing channels with independent scaling and alarm evaluation paths. Q: Does the module output raw vibration signals for external diagnostics?A: Yes. Buffered outputs provide unfiltered dynamic signals via coaxial front-panel connectors and rear terminals. Q: Is channel-to-channel signal interaction present under normal operation?A: No intentional coupling exists; internal architecture is designed for cross-channel isolation within hardware limits. FieldInstallationGuidelines Install module in a compatible Bently Nevada 3300 rack system with correct backplane seating. Maintain separation between signal wiring and power conductors to reduce induced noise. Use shielded cable for accelerometer inputs; terminate shield at single-point ground only. Ensure relay output wiring conforms to specified contact rating limits (5 A at 120 Vac / 24 Vdc). Verify proper calibration scaling before connecting to PLC or DCS analog input channels. Avoid mechanical stress on front-panel connectors to preserve buffered output integrity.
$200.00 $100.00
-
Bently Nevada 3300/20-12-01 Dual Driver Monitor | Bently Nevada
Bently Nevada 3300/20-12-01 Dual Driver Monitor TheBently Nevada 3300/20-12-01serves astheprimary3300/20Dual Driver Monitor utilized toexecutecontinuous dual-channel vibration and displacement signal conditioning across3300 proximity transducer monitoring systems. The module converts eddy-current probe inputs into calibrated vibration and axial position signals with relay-based alarm execution. Cross-channel measurement processing is implemented using parallel analog conditioning paths for two independent proximity probe channels. Signal scaling is factory-defined via full-scale configuration (-12 option), mapping raw probe voltage into defined vibration amplitude ranges without field recalibration. Suffix Breakdown & Model Matrix 3300/20: Dual Driver Monitor base platform -12: Full-scale vibration range configuration (0 to 5 mils pp or calibrated metric equivalent) -01: Agency approval option (CSA / NRTL / Class I Division 2) Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/20-12-01 Origin USA Weight 1.0 kg OperatingTemp 0 degC to 65 degC Input Type Dual proximity transducer (3300 / 7200 systems) Input Impedance 10 kOhm nominal Output Signals 4-20 mA or 1-5 VDC configurable Alarm Outputs SPDT / DPDT relay (Alert / Danger) Frequency Response 10 Hz to 1 kHz (-3 dB) Eddy-Current Probe Scaling and Signal Conditioning Behavior The 3300/20 platform applies fixed eddy-current probe scaling to convert shaft displacement into proportional electrical signals derived from proximity probe bias voltage variation. Cross-channel signal conditioning maintains independent processing of dual measurement paths, minimizing phase distortion during transient rotor dynamics. Gap-related DC offset tracking is maintained through continuous bias reference monitoring, ensuring stable axial displacement representation under steady-state and transient conditions. Frequently Asked Questions Q: Does the module support hot-swap replacement in an energized rack?A: The module is not intended for energized insertion or removal. Backplane signal stability may be disrupted during live replacement. Q: Are scaling parameters field adjustable?A: No. Full-scale configuration is hardware-defined by the -12 option and not software reconfigurable. Q: Can both channels share a single alarm relay output?A: Alarm logic routing depends on internal jumper configuration, but channels remain electrically independent at input stage. Field Installation Guidelines Install only into compatible 3300 rack slot with secure backplane engagement Maintain shield continuity for proximity probe coaxial cables Use single-point grounding to prevent loop current interference Route sensor cables away from high voltage conductors Verify relay contact wiring before system energization
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/16-15-01-03-00-00-02 Vibration Monitor Module
Bently Nevada 3300/16 Vibration Monitor Module Configured for dual-channel radial vibration and shaft gap electrical conversion in 3300 rack based proximity transducer networks, the Bently Nevada 3300/16-15-01-03-00-00-00 (3300/16 XY/GAP Dual Vibration Monitor) provides direct physical/electrical execution of eddy-current probe signal conditioning and alarm logic processing across Bently Nevada 3300 monitoring platforms. The module processes two independent proximity probe inputs with fixed sensitivity scaling (200 mV/mil) and converts shaft displacement into conditioned peak-to-peak vibration and DC gap voltage signals. Internal alarm logic supports relay output configuration (quad relay epoxy sealed type) for threshold-based trip and warning states. Suffix Breakdown & Model Matrix 3300/16: XY/GAP dual-channel vibration monitor base module -15: Full-scale range option, 0 to 500 um peak-to-peak equivalent -01: Proximitor input compatibility (3300 / 3300 XL / 7200 systems, 200 mV/mil) -03: Quad relay alarm output configuration (epoxy sealed) -00: Agency approval not required configuration -00: No intrinsic safety barriers installed -00: No trip multiply function enabled Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/16-15-01-03-00-00-00 Origin USA Weight 1kg (shipping weight) Input Type 3300 / 7200 Proximitor, 200 mV/mil Channels Dual (X-Y radial vibration + gap) Full Scale Range 0 to 500 um peak-to-peak Alarm Output Quad relay (epoxy sealed) Eddy-Current Probe Scaling and Gap Voltage Validation Behavior The 3300/16 platform applies fixed eddy-current probe scaling using calibrated 200 mV/mil sensitivity conversion to translate probe air-gap variation into electrical displacement signals. Gap voltage validation is referenced against stable DC operating points derived from proximity probe bias conditions, enabling continuous monitoring of shaft centerline position drift. Cross-channel interaction suppression is implemented at analog conditioning stage to reduce coupling between X and Y measurement paths during high amplitude rotor orbit conditions. Frequently Asked Questions Q: Can the quad relay output be used for independent alarm zoning?A: Yes, the quad relay configuration supports discrete alarm assignment per channel or combined logic outputs depending on backplane configuration. Q: Does the module require software configuration for scaling?A: Scaling is hardware-defined via factory option (-15), no field programmable scaling is applied to the measurement chain. Q: Is channel synchronization required for X-Y vibration measurement?A: Channels operate in parallel analog paths; phase relationship is preserved inherently without digital synchronization logic. Field Installation Guidelines Install module only into compatible 3300 rack slot with secure backplane engagement Verify proximity probe wiring polarity and shielding continuity before energization Use single-point grounding for coaxial and probe cable shields to avoid ground loop currents Maintain separation between signal cabling and high voltage conductors to reduce induced noise Ensure relay output wiring matches intended alarm logic configuration prior to system start-up
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/16-15-01-01-00-00-01 XY/Gap Dual Vibration Monitor
Bently Nevada 3300/16-15-01-01-00-00-01 XY/Gap Dual Vibration Monitor TheBently Nevada 3300/16-15-01-01-00-00-01serves astheprimary3300/16XY/Gap Dual Vibration Monitor utilized toexecutecontinuous dual-channel radial vibration and shaft gap measurement across3300 rackbasedTSI monitoring systems. The module processes dual proximity probe inputs for real-time electrical conversion of shaft displacement into conditioned vibration and DC gap voltage signals. Suffix Breakdown & Model Matrix 3300/16: XY/Gap dual-channel vibration monitor platform -15: Full-scale configuration (0 to 10 mils peak-to-peak) -01: Proximitor input compatibility (3300 / 7200 system, 200 mV/mil) -01: Standard agency configuration -00-00: Non-isolated auxiliary and display configuration options -01: Factory-defined functional option set (trip logic configuration variant) Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/16-15-01-01-00-00-01 Origin USA Weight 1.0 kg Dimensions 5.1 cm x 20.3 cm x 30.5 cm OperatingTemp -40 degC to +85 degC PowerConsumption 2 W typical Input Type 3300 / 7200 Proximitor, 200 mV/mil Measurement Range 0 to 10 mils peak-to-peak Channels Dual (X-Y radial vibration + gap) Output Interface 4-20 mA, buffered transducer outputs Eddy-Current Probe Scaling and Gap Voltage Validation Behavior Within the Bently Nevada 3300 architecture, eddy-current probe scaling is performed through fixed sensitivity conversion (200 mV/mil), enabling direct translation of shaft displacement into conditioned analog signals. Gap voltage validation maintains DC reference stability typically aligned with negative supply bias ranges, ensuring probe-to-target spacing integrity under transient rotor conditions. Cross-channel interaction is managed through internal isolation design to reduce signal cross-talk during high vibration amplitude transitions. Frequently Asked Questions Q: Does the module support hot-swapping in the rack backplane?A: The module is designed for insertion into the 3300 rack; removal or insertion should be performed under controlled system shutdown conditions to avoid transient signal corruption on shared backplane rails. Q: What is the effect of dual-channel operation on signal timing?A: Both channels are processed in parallel analog conditioning paths, with no intentional digital delay alignment, preserving real-time phase relationship for orbit analysis. Q: Can buffered outputs be used for external diagnostic oscilloscopes?A: Yes, buffered transducer outputs are provided via front panel coaxial interface with 100 ohm output impedance suitable for diagnostic monitoring equipment. Field Installation Guidelines Install module only in valid 3300 rack slots (avoid slot 1 and 2 constraints if applicable to rack configuration rules) Ensure proper seating on backplane connectors to maintain stable 4-20 mA loop integrity Maintain shielded cable routing for proximity probe inputs to reduce electromagnetic coupling noise Verify probe polarity and scaling configuration prior to system energization Ground cable shields at single-point reference to prevent ground loop induced measurement drift
$200.00 $100.00
-
Bently Nevada 3300/16 Dual Vibration Monitor | Bently Nevada
Bently Nevada 3300/16 Dual Vibration Monitor The Bently Nevada 3300/16, also cataloged as the 3300/16 Dual Vibration Monitor, operates as a dedicated hardware component for continuous rotor vibration monitoring within machinery protection systems. It accepts dual independent proximitor transducer inputs and provides analog outputs, alarm relays, and front-panel display for real-time condition assessment. Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/16 Origin USA Weight 1.1 kg (2.4 lbs) Dimensions Standard 19-inch rack-mount width, 3U height (approximate) OperatingTemp 0 degC to +65 degC StorageTemp -40 degC to +85 degC RelativeHumidity Up to 95%, non-condensing PowerConsumption Typical <10 W TransducerInputs 2 channels, 5mm/8mm/11mm Proximitor systems InputImpedance 10 kOhm nominal BufferedOutputs Coaxial front panel, terminal block rear panel, 100 Ohm impedance, short-circuit protected RecorderOutputs 4-20 mA or 1-5 Vdc per channel FrequencyResponse Standard: 4 Hz to 4 kHz; Optional Low-Freq: 1 Hz to 4 kHz (-3 dB) Accuracy ±0.5% of full scale at 25 degC AlarmSetpoints Alert/Danger, 0-100% full scale, programmable time delay 0.1–6 s RelayOutputs SPDT, 5 A @ 120 Vac / 24 Vdc resistive, epoxy/hermetic/pneumatic options FrontPanelDisplay Digital LED, bar graph, gap voltage monitoring Rotordynamics & GapVoltage Validation The 3300/16 monitor includes eddy-current probe scaling for precise rotor vibration measurement. Gap voltage validation supports direct measurement against -10 Vdc reference targets to confirm probe-to-shaft clearance. Cross-talk suppression circuits isolate each channel to reduce interference between dual proximitor inputs, maintaining integrity of rotordynamic analysis. Frequently Asked Questions Q: Does the 3300/16 support hot-swap of transducer modules?A: No, the module requires system power-down before input transducer replacement to avoid signal damage. Q: What is the maximum load on recorder outputs?A: Buffered 4-20 mA outputs are rated for standard 500 Ohm maximum load; voltage outputs maintain 1-5 Vdc over typical 1 kOhm load. Q: Can firmware updates be applied in the field?A: The 3300/16 is a legacy analog monitor; firmware is fixed and not field-upgradable. Field Installation Guidelines Mount the monitor on a stable, vibration-free panel or 19-inch rack. Ensure all proximitor cabling is shielded and grounded at one end to minimize electrical noise. Maintain separation between analog signal wiring and high-voltage or digital communication lines. Verify proper orientation of the front panel to facilitate gap voltage measurement access. Install relays according to current ratings; use external suppression diodes if driving inductive loads. Confirm environmental limits: avoid condensation and direct exposure to high heat sources.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/16 Dual Vibration Monitor
Bently Nevada 3300/16 Dual Vibration Monitor The Bently Nevada 3300/16, also cataloged as the 3300/16 Dual Vibration Monitor, operates as a dedicated hardware component for continuous rotor vibration monitoring within machinery protection systems. It accepts dual independent proximitor transducer inputs and provides analog outputs, alarm relays, and front-panel display for real-time condition assessment. Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/16 Origin USA Weight 1.1 kg (2.4 lbs) Dimensions Standard 19-inch rack-mount width, 3U height (approximate) OperatingTemp 0 degC to +65 degC StorageTemp -40 degC to +85 degC RelativeHumidity Up to 95%, non-condensing PowerConsumption Typical <10 W TransducerInputs 2 channels, 5mm/8mm/11mm Proximitor systems InputImpedance 10 kOhm nominal BufferedOutputs Coaxial front panel, terminal block rear panel, 100 Ohm impedance, short-circuit protected RecorderOutputs 4-20 mA or 1-5 Vdc per channel FrequencyResponse Standard: 4 Hz to 4 kHz; Optional Low-Freq: 1 Hz to 4 kHz (-3 dB) Accuracy ±0.5% of full scale at 25 degC AlarmSetpoints Alert/Danger, 0-100% full scale, programmable time delay 0.1–6 s RelayOutputs SPDT, 5 A @ 120 Vac / 24 Vdc resistive, epoxy/hermetic/pneumatic options FrontPanelDisplay Digital LED, bar graph, gap voltage monitoring Rotordynamics & GapVoltage Validation The 3300/16 monitor includes eddy-current probe scaling for precise rotor vibration measurement. Gap voltage validation supports direct measurement against -10 Vdc reference targets to confirm probe-to-shaft clearance. Cross-talk suppression circuits isolate each channel to reduce interference between dual proximitor inputs, maintaining integrity of rotordynamic analysis. Frequently Asked Questions Q: Does the 3300/16 support hot-swap of transducer modules?A: No, the module requires system power-down before input transducer replacement to avoid signal damage. Q: What is the maximum load on recorder outputs?A: Buffered 4-20 mA outputs are rated for standard 500 Ohm maximum load; voltage outputs maintain 1-5 Vdc over typical 1 kOhm load. Q: Can firmware updates be applied in the field?A: The 3300/16 is a legacy analog monitor; firmware is fixed and not field-upgradable. Field Installation Guidelines Mount the monitor on a stable, vibration-free panel or 19-inch rack. Ensure all proximitor cabling is shielded and grounded at one end to minimize electrical noise. Maintain separation between analog signal wiring and high-voltage or digital communication lines. Verify proper orientation of the front panel to facilitate gap voltage measurement access. Install relays according to current ratings; use external suppression diodes if driving inductive loads. Confirm environmental limits: avoid condensation and direct exposure to high heat sources.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/15-03-01-01-00-00-00 Dual Vibration Monitor
Bently Nevada 3300/15-03-01-01-00-00-00 Dual Vibration Monitor The Bently Nevada 3300/15-03-01-01-00-00-00, also cataloged as the 3300/15 Dual Vibration Monitor, operates as a dedicated hardware component for continuous radial vibration measurement across dual Proximitor channels within the 3300 Machinery Monitoring System. It provides real-time signal acquisition, relay actuation, and 4-20 mA recorder output for industrial machinery monitoring loops. Hardware Specifications Parameter Specification ModelBrand Bently Nevada Origin United States Weight 1.0 kg (2.2 lbs) Dimensions 221 mm x 24.4 mm x 295 mm OperatingTemp 0 degC to 65 degC StorageTemp -40 degC to 85 degC RelativeHumidity Up to 95% non-condensing PowerConsumption 6 W typical SignalInput 2 independent proximity probe channels InputImpedance >10 kOhm FrequencyResponse 4 Hz to 5 kHz (-3 dB) FullScaleRange 0-5 mils pp AlarmOutputs Alert and Danger SPDT relays, 5 A @ 120 VAC / 28 VDC RecorderOutput 4-20 mA DC proportional to full scale Display 4-digit LCD with backlight LEDIndicators OK (green), ALERT (yellow), DANGER (red), BYPASS (red) Rotordynamics & Eddy-Current Probe Scaling The monitor supports eddy-current probe scaling with configurable millivolt-per-unit displacement calibration. Gap voltage validation is maintained at -10 VDC targets to ensure rotor displacement linearity. Cross-talk suppression circuitry reduces signal interference between adjacent channels, supporting precise vibration measurement for high-speed rotating machinery and dynamic imbalance detection. Frequently Asked Questions Q: What is the maximum loop current for recorder output?A: The recorder output supports standard 4-20 mA DC current proportional to the configured full-scale vibration range. No additional amplification is required. Q: Can the 3300/15 be hot-swapped in a live 3300 rack?A: The monitor requires powering down the rack slot before replacement. It is not designed for hot-swap operation. Q: How does the monitor respond to sensor failure or gap loss?A: The OK LED will turn off, and both Alert and Danger relays will default according to preprogrammed safe-state configuration. Field Installation Guidelines Mount the unit in a standard 3300 single-slot rack with proper mechanical fastening. Ensure proximity probe cabling is shielded and grounded at one end only to avoid ground loops. Maintain separation from high-current power cables to minimize EMI pickup. Connect relay outputs to dry-contact circuits rated for 5 A maximum; avoid exceeding voltage or current ratings. Verify that the 4-20 mA loop is configured for the correct full-scale range and polarity. Avoid inserting the unit while the rack is energized; use static protection measures when handling connectors. Periodically inspect BNC transducer outputs and internal connections for corrosion or loose terminations.
$200.00 $100.00
-
Bently Nevada DC Power Supply Module | Bently Nevada 3300/14
Bently Nevada 3300/14 DC Power Supply Module Configured for power distribution within Bently Nevada 3300 rack system, the Bently Nevada 3300/14 (3300/14 DC Power Supply Module) provides direct electrical execution. The unit converts external DC input into regulated rack supply rails used by 3300 series monitor modules and proximity measurement channels, supporting backplane power distribution within a single-slot rack position. The module occupies Slot 1 of the 3300 rack and operates as the sole power source for a fully populated configuration of monitoring modules and associated transducer interfaces. Protection functions include input polarity protection, regulated output control, and internal filtering against conducted line disturbances. Suffix Breakdown & Model Matrix The 3300/14 is a single fixed-order module designation. No extended suffix segmentation or functional sub-variant matrix is defined within the provided specification. All electrical and mechanical characteristics apply uniformly to the base model. Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/14 Weight approx 2.04 kg Dimensions approx 5.2 cm x 33 cm x 20.5 cm OperatingTemp 0 degC to 65 degC PowerConsumption Derived from input: 20 to 34 VDC @ 5.5 A max or 90 to 140 VDC @ 1.5 A max Output Voltage -24 VDC or -18 VDC selectable via internal jumpers Rack Capacity Up to 12 monitors with associated transducers Relay Output SPDT OK relay, 5 A @ 28 VDC / 120 VAC / 220 VAC Bently Nevada Mechanical Signal Integrity Interface Behavior Within Bently Nevada 3300 architecture, power stability directly affects eddy-current probe signal conditioning and gap voltage validation referenced at approximately -10 VDC operating targets in proximity measurement chains. Supply rail noise attenuation contributes to reduced cross-talk between adjacent vibration monitor channels, particularly in high-density rack configurations where multiple proximity transducer scaling circuits operate concurrently. The regulated DC rail supports consistent rotor dynamics measurement integrity by maintaining stable excitation conditions for downstream monitor electronics. Frequently Asked Questions Q: Can the 3300/14 support hot-swap operation during rack energization?A: The module is intended for fixed Slot 1 installation. Removal under energized conditions can interrupt backplane power distribution to all installed monitor modules. Q: Does the power supply isolate individual monitor channels on the backplane?A: Channel-to-channel isolation is implemented at the monitor module level. The 3300/14 provides centralized regulated DC distribution only. Q: What is the expected behavior under input undervoltage conditions?A: The module disables regulated output and de-energizes the OK relay when input voltage falls outside specified operating thresholds. Field Installation Guidelines Install the module exclusively in Slot 1 of the 3300 rack. Ensure DC input polarity is verified before energization. Maintain shield continuity for rack grounding to minimize conducted interference across monitor backplane lines. Route input power conductors away from proximity probe cabling to reduce coupled noise into measurement circuits. Verify OK relay state transitions during initial power-up before connecting field transducer loads.
$200.00 $100.00
-
Bently Nevada AC Power Supply | Bently Nevada 3300/12
Bently Nevada 3300/12 AC Power Supply The Bently Nevada 3300/12, also cataloged as the 3300/12 AC Power Supply, operates as a dedicated hardware component for regulated DC power distribution within 3300 series machinery monitoring racks. It provides direct electrical execution for up to 12 3300 series monitors and their connected transducers. Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/12 Origin Manufactured for Bently Nevada 3300 series systems Weight Approximately 1.0 kg (2.2 lbs) Dimensions 83 mm (3.25 in) vertical height OperatingTemp 0 degC to +65 degC StorageTemp -40 degC to +85 degC RelativeHumidity 95% non-condensing InputVoltage 95-125 Vac, 50/60 Hz or 190-250 Vac, 50/60 Hz PowerConsumption Nominal 1.5 W (varies with rack load) OutputVoltage Regulated DC for 3300 series monitors and transducers Eddy-Current ProbeScaling & Signal Integrity The 3300/12 module includes integrated filtering for line noise suppression, supporting eddy-current probe scaling and gap voltage validation down to -10 VDC targets. Its architecture minimizes cross-talk between channels, preserving rotordynamics monitoring fidelity across multiple transducers in a single rack configuration. Frequently Asked Questions Q: VnA: Can the 3300/12 be hot-swapped while the rack is powered?A: No. The power supply must be installed with the rack de-energized to avoid transient voltage spikes affecting connected monitors. Q: VnA: What is the maximum number of monitors supported?A: The 3300/12 provides regulated DC power for up to 12 monitors with associated transducers. Q: VnA: Does the module support backplane current sharing for redundant racks?A: Only one 3300/12 supply is intended per rack. Parallel operation of multiple units is not supported. Field Installation Guidelines Mount the 3300/12 in Position 1 (leftmost slot) of the 3300 rack. Ensure proper grounding to the rack chassis to reduce electrical noise coupling. Route input AC power with separation from signal cables to prevent EMI. Verify ambient temperature within 0 degC to +65 degC and humidity below 95% non-condensing. Tighten connectors to manufacturer torque specifications; avoid stress on DC output terminals.
$200.00 $100.00
-
Bently Nevada 3300/05-24-00-00 Rack Module | Bently Nevada
Bently Nevada 3300/05-24-00-00 Rack Module Configured for physical housing and backplane distribution in the 3300 Machinery Monitoring System, the Bently Nevada 3300/05-24-00-00 (3300/05 Rack) provides direct physical/electrical execution within Bently Nevada 3300 rack-based monitoring architecture. The unit implements an 8-slot instrument chassis with integrated power supply and system monitor placement for backplane signal routing and module interconnection. Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/05-24-00-00 Origin USA Dimensions 19-inch rack form factor, 8-slot chassis OperatingTemp 0 degC to +65 degC PowerConsumption Not specified Slot Capacity 8 monitor module slots (excluding PSU/system monitor position) Mounting Type Panel mount Cable Termination Top and bottom entry Eddy Current Probe Scaling and Backplane Signal Integrity Control The Bently Nevada 3300/05 rack structure supports stable routing of eddy-current probe inputs through its backplane interconnect system. Signal channels derived from proximity probe drivers are routed via controlled impedance paths to minimize cross-channel interference during vibration and position measurement acquisition. Backplane layout is designed to maintain consistent scaling reference alignment between probe gap voltage conversion stages and monitoring modules. Cross-talk suppression is achieved through physical separation of channel traces and defined grounding topology across the rack frame, ensuring stable -10 VDC nominal gap voltage validation reference behavior at the module interface level. Frequently Asked Questions Q: Can 3300/05 rack support hot-swap of monitoring modules?A: Module insertion and removal are not designed for energized backplane operation. Power removal is required to maintain stable bus voltage conditions. Q: What is the backplane current distribution limit behavior?A: Current distribution is handled through the integrated rack power rail. Load is shared across installed modules; total consumption is limited by the system power supply rating rather than individual slots. Q: Does the rack introduce signal delay on vibration channels?A: The rack backplane operates as a passive interconnect system; propagation delay is negligible and primarily dependent on external module processing. Field Installation Guidelines Ensure the rack is mounted in a mechanically rigid 19-inch panel cutout with sufficient rear clearance for top and bottom cable routing. Maintain separation between signal wiring and power conductors to reduce induced noise coupling. All shielded cable terminations should be grounded at a single-point chassis reference to avoid ground loop formation. Verify that the system power supply is de-energized prior to module insertion. Torque all rack mounting fasteners to standard industrial enclosure practice to prevent vibration-induced loosening.
$200.00 $100.00
-
Bently Nevada 3300/05-22-00-00 3300 System Monitor Rack | Bently Nevada
Bently Nevada 3300/05-22-00-00 3300 System Monitor Rack Configured for modular machinery condition monitoring in 3300 System architectures, the Bently Nevada 3300/05-22-00-00 (3300/05 System Monitor Rack) provides direct backplane-based execution of multi-channel vibration and process signal acquisition across insertable monitor modules. Suffix Breakdown & Model Matrix 3300/05: Rack chassis series designation 22: 12-inch, 8-slot panel mount configuration 00: Left-position system monitor and power supply placement 00: No agency certification option pre-assigned Hardware Specifications Parameter Specification ModelBrand Bently Nevada 3300/05-22-00-00 Origin USA Weight 2.7 kg Dimensions 27.9 cm x 45.7 cm x 58.4 cm OperatingTemp 0 degC to 65 degC PowerConsumption Not specified (depends on installed modules and PSU type) Rack Architecture 8-slot modular backplane system Slot Type Insertable monitoring modules Mounting Style Panel mount Communication Internal backplane signal routing Eddy Current Probe Scaling and Cross-Talk Suppression (Bently Nevada TS Interface Domain) Within the Bently Nevada Bently Nevada 3300 architecture, input conditioning stages support eddy-current proximity probe scaling via standardized gap voltage conversion, typically referenced against calibrated -10 VDC full-scale displacement targets. Signal integrity is maintained through backplane isolation design, limiting inter-channel cross-talk during high-density vibration monitoring. The system architecture enforces deterministic separation between adjacent monitor modules, reducing phase distortion in multi-channel rotor dynamic measurements and stabilizing synchronous amplitude tracking under variable shaft speed conditions. Frequently Asked Questions Q: Can 3300/05 rack modules be hot-swapped during operation?A: Hot-swap is not supported for signal processing modules under energized backplane conditions. Power isolation is required prior to insertion or removal to avoid transient bus disturbances. Q: What is the backplane current limitation for full 8-slot configuration?A: Backplane loading is defined by the installed power supply module. Total current draw scales with monitor density and transducer interface types. Q: Does the rack support mixed vibration and position modules simultaneously?A: Yes. The backplane architecture supports heterogeneous module population, including vibration, thrust, and radial position monitoring cards. Field Installation Guidelines Ensure the rack is mounted on a rigid panel structure with controlled mechanical vibration isolation. Maintain minimum clearance around the chassis for airflow across installed modules. Shielded cabling must be routed with single-point grounding at the cabinet entry to minimize ground loop formation across proximity probe return paths. Backplane connectors must remain free of contamination during installation, and module seating force must be applied evenly to avoid pin misalignment or partial engagement. Power supply wiring should follow industrial control cabinet segregation rules, separating low-level sensor wiring from power conductors to preserve signal integrity.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/03 System Monitor Module
Bently Nevada 3300/03 System Monitor Configured for rack-level signal conditioning and multi-channel monitor interconnection in the 3300 monitoring system, the Bently Nevada 3300/03 System Monitor (3300/03 System Monitor) provides direct physical/electrical execution within 3300 monitor rack architectures. Suffix Breakdown & Model Matrix No validated suffix segmentation is defined beyond the base ordering designation 3300/03 System Monitor. No internal subcode decomposition is assumed. Hardware Specifications Parameter Specification Model 3300/03 System Monitor Brand Bently Nevada Origin United States (Bently Nevada product line) OperatingTemp Not specified (system dependent rack environment) PowerConsumption 2 W (4.6 W with interface options) Keyphasor Inputs Up to 4 proximity probe signals Input Impedance 10 k ohm (Keyphasor inputs) RS422 Baud Rate Up to 19.2 k baud (SDI), 38.4 k baud (DDI) RS232 Baud Rate Up to 19.2 k baud Signal Conditioning Range Up to 10 kHz (software selectable) Dynamic Accuracy ±0.3% full-scale typical at 25 degC Phase Accuracy ±0.2 deg typical at 25 degC Output Type Buffered Keyphasor outputs (4 coaxial) Bently Nevada Eddy-Current Signal Conditioning & Gap Validation Logic The Bently Nevada 3300/03 System Monitor integrates eddy-current probe scaling logic for Keyphasor processing, maintaining proportional conversion between mechanical shaft displacement and conditioned voltage output. Gap voltage validation routines support negative bias operating windows (0 to -24 VDC / 0 to -18 VDC), ensuring stable probe linearization across rotor dynamic operating ranges. Cross-channel signal interaction is minimized through isolated impedance domains and buffered coaxial output stages, reducing crosstalk propagation in multi-rack installations. Frequently Asked Questions Q: Can the 3300/03 System Monitor interface directly with external control systems?A: Yes. It supports RS422 and RS232 communication channels for SDI/DDI data transmission to external processors or compatible monitoring systems. Q: What is the maximum Keyphasor input capacity?A: The module accepts up to four proximity probe Keyphasor inputs with 10 k ohm input impedance and conditioned signal routing. Q: Does the module perform internal signal conditioning?A: Yes. It provides software-selectable frequency conditioning up to 10 kHz with dynamic and phase accuracy specified at 25 degC reference conditions. Field Installation Guidelines The 3300/03 System Monitor shall be installed within a compatible 3300 monitor rack backplane assembly with verified connector seating integrity. RS422/RS232 communication wiring must maintain controlled impedance routing and separation from high-noise power conductors. Keyphasor coaxial outputs require shield termination at a single-point ground to prevent ground loop formation. Probe input cabling should follow standard eddy-current extension practices, ensuring continuous shield integrity from probe head to termination module. Backplane insertion force must be applied evenly to avoid connector pin deformation.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3300/01 System Monitor Module
Bently Nevada 3300/01 System Monitor Module Configured for system diagnostics, Keyphasor signal distribution, and rack-level control functions in the Bently Nevada 3300 Machinery Protection System, the Bently Nevada 3300/01 (3300/01 System Monitor Module) provides direct physical and electrical execution. The module occupies the second rack slot from the left, interfaces with rack power and backplane circuits, processes up to two Keyphasor inputs, and supports optional serial communication functions for supervisory systems and data acquisition platforms. Hardware Specifications Parameter Specification Model 3300/01 Brand Bently Nevada Origin Not specified Product Type System Monitor Module Rack Position Second slot from left, adjacent to power supply module Power Consumption Nominal 3.6 W (with serial interface option) Power Source Regulated DC power from 3300 rack backplane Keyphasor Inputs Up to 2 proximity transducer inputs Keyphasor Frequency Range 60 to 30,000 cpm (1 Hz to 500 Hz) Minimum Input Amplitude 0.5 Vp-p DC Signal Range 0 to -24 VDC or 0 to -18 VDC Buffered Outputs 4 front-panel Keyphasor outputs Output Impedance 50 Ohm Dynamic Signal Accuracy +/-0.3% of full scale typical Phase Accuracy +/-0.2 degrees typical at 25 degC RPM Accuracy +/-1 rpm typical Communication Interfaces RS-232 or RS-422 (optional) Supported Protocols Modbus RTU, SDI, DDI Maximum Baud Rate 19.2 kbaud (RS-232), 38.4 kbaud (RS-422) Operating Temp -20 degC to +70 degC Storage Temp -40 degC to +85 degC Relative Humidity Up to 95% non-condensing Weight Approximately 0.6 kg to 0.7 kg Dimensions Approximately 5.1 cm x 20.3 cm x 33.0 cm Front Panel Functions RESET, UP/DOWN setpoint adjustment Rear Terminal Functions Rack Inhibit, Trip Multiply, Remote Alarm Reset Eddy-Current Probe Interface and Rotor Dynamic Signal Distribution The 3300/01 module accepts Keyphasor signals generated by proximity probe systems and distributes phase-reference information through the rack backplane. Signal conditioning supports rotational speed measurements from 1 Hz to 500 Hz while maintaining phase accuracy for vibration, position, and rotor dynamic monitoring functions. For installations using eddy-current proximity transducers, probe system validation commonly includes verification of probe gap voltage against the target surface. During commissioning, signal integrity should be confirmed before Keyphasor references are utilized by rack-mounted monitoring modules. The front-panel buffered outputs provide direct access to conditioned Keyphasor signals for diagnostic instrumentation and waveform verification. Frequently Asked Questions Q: Does the 3300/01 support hot replacement while the rack is energized?A: The supplied documentation does not specify hot-swap capability. Module replacement procedures should follow the applicable 3300 system maintenance instructions and site isolation requirements. Q: How many Keyphasor reference signals can the module process?A: The module accepts up to two Keyphasor inputs and distributes the reference information through the rack backplane for use by compatible monitoring modules. Q: What communication options are available on the 3300/01?A: Optional communication boards provide RS-232 or RS-422 interfaces supporting Modbus RTU and Bently Nevada SDI/DDI communication protocols for host-system integration. Field Installation Guidelines Install the module only in the designated System Monitor position immediately to the right of the rack power supply. Verify all rack supply voltages through the front-panel and internal status indicators before commissioning connected monitor modules. Route Keyphasor signal cables separately from high-energy power conductors to minimize induced electrical noise. Maintain proper shield termination practices according to plant grounding standards and proximity transducer installation requirements. Confirm correct operation of Rack Inhibit, Trip Multiply, and Remote Alarm Reset wiring before placing the machinery protection system into service. Use the front-panel buffered Keyphasor outputs when validating phase-reference quality, rotational speed signals, or diagnostic measurements. Inspect communication interface settings and protocol configuration before connecting supervisory computers, PLCs, or monitoring software.
$200.00 $100.00
-
Yokogawa Yokogawa Temperature Monitoring Module | F3CX04-0N
Yokogawa F3CX04-0N Temperature Monitoring Module The Yokogawa F3CX04-0N, also cataloged as the F3CX04 Temperature Monitoring Module, operates as a dedicated hardware component for multi-channel temperature input processing within FA-M3 automation platforms. HardwareSpecifications Parameter Specification Model Brand Yokogawa F3CX04-0N Origin Japan Weight 200 g Dimensions 28.9 W × 100 H × 106.1 D mm OperatingTemp Max allowable ambient temperature change rate: 10 degC/h PowerConsumption 440 mA at 5 VDC NumberOfChannels 4 InputIsolation Isolated via photocouplers and transformers TerminalVoltageWithstand 150 VAC tested AlarmTypes Input upper limit alarm, input lower limit alarm (with or without delay) NumberOfAlarmOutputs 4 points per channel (only alarms 1 and 2 have relays) AlarmDelayTimer Yes WarmUpTime 30 minutes min MountingPosition Horizontal only; inverted orientation not allowed ExternalConnection 18-point terminal block with M3.5 screws InputProcessingModes Single-input (default), Two-input changeover Industrial Control Features Omron modules integrate deterministic backplane bus communication for FA-M3 systems. Firmware flash compatibility allows in-field updates without disrupting ongoing input monitoring. Channel-to-channel isolation is maintained to prevent cross-interference, supporting precise analog signal acquisition across all four inputs. Single- and two-input changeover modes allow paired or independent channel monitoring, with configurable alarm delay timers to align with system response requirements. Frequently Asked Questions Q: Can the F3CX04-0N be hot-swapped while the FA-M3 base module is powered?A: No. The module requires system power-down before insertion or removal to prevent signal disruption and relay misoperation. Q: What is the maximum rate of ambient temperature change the module can tolerate?A: The module supports up to 10 degC per hour. Faster changes may affect input accuracy and alarm triggering. Q: Are firmware updates compatible with all installed channel configurations?A: Yes, firmware flash operations preserve current input processing settings, but it is recommended to verify alarm and relay settings post-update. Field Installation Guidelines Mount the module horizontally on the FA-M3 base; inverted or vertical mounting is not permitted. Ensure 18-point terminal block connections are tightened with M3.5 screws to maintain proper electrical isolation. Route analog input wiring separately from high-current or switching circuits to minimize cross-talk. Verify ambient temperature stability; avoid locations with rapid thermal fluctuations exceeding 10 degC per hour. Ground module shielding appropriately to reduce electromagnetic interference and maintain signal integrity.
$200.00 $100.00
-
Bently Nevada Bently Nevada 144181-51 3300 XL 5/8 mm Proximity Sensor
Bently Nevada 144181-51 3300 XL 5/8 mm Proximity Sensor Configured for non-contact shaft displacement and vibration measurement in 3300 XL machinery monitoring networks, the Bently Nevada 144181-51 (144181-51 Proximity Sensor) provides direct electrical execution. The sensor assembly operates with analog voltage output scaling for rotor position and dynamic vibration acquisition across rotating equipment monitoring channels. Suffix Breakdown & Model Matrix Parameter Specification Full Model 144181-51 Base Model 144181 Brand Bently Nevada Series 3300 XL Product Type 5/8 mm Proximity Sensor Measurement Method Eddy-current non-contact sensing Output Type Analog voltage Mounting Method Threaded or bracket-mounted installation Hardware Specifications Parameter Specification Model 144181-51 Brand Bently Nevada Origin United States Series 3300 XL Sensor Type Eddy-current proximity sensor Operating Frequency 10 kHz to 1 MHz Input Impedance 50 Ohm Output Signal Analog voltage Sensitivity 200 mV/mil (7.87 V/mm) Accuracy +/-0.5% Resolution 100 mV Operating Voltage 24 VDC typical Operating Temp -40 deg C to +120 deg C Storage Temp -40 deg C to +125 deg C Humidity 0-95% non-condensing Protection Rating IP65 Housing Material Stainless steel Shaft Diameter Range 10 mm to 300 mm Probe Length 50 mm to 1000 mm Dimensions Approximately 81 x 35 x 64 mm Weight Approximately 0.25 kg to 2 kg depending on configuration Compliance CE, UL, API 670 Application Shaft displacement and vibration monitoring Eddy-Current Probe Scaling and Gap Voltage Validation The 3300 XL sensing architecture applies eddy-current transducer scaling to generate linear shaft displacement output relative to conductive target movement. Probe response is influenced by shaft metallurgy, surface finish, and radial clearance stability. During commissioning, gap voltage verification is commonly performed against nominal negative bias targets near -10 VDC to confirm proper probe-to-shaft positioning within the calibrated linear operating region. Incorrect gap positioning may introduce amplitude compression, non-linear response, or elevated cross-talk between adjacent probe channels. Rotor dynamic monitoring applications typically use the sensor for: Radial vibration measurement Axial thrust displacement detection Differential expansion observation Eccentricity and shaft position tracking The analog response bandwidth supports both slow-roll shaft behavior and higher-frequency vibration signatures generated by imbalance, rub, or misalignment conditions. Frequently Asked Questions Q: Does the 144181-51 support direct hot-swap replacement while the monitoring rack remains energized?A: Hot-swap capability depends on the associated monitoring rack and proximitor interface design. Standard practice requires verification of channel inhibit conditions before probe replacement to avoid transient vibration alarms or invalid gap readings. Q: What installation factors affect proximity sensor linearity?A: Probe tip clearance, shaft material composition, concentricity, cable routing separation, and grounding continuity directly affect linear analog response and signal stability. Q: Can multiple proximity probes be installed in close mechanical spacing?A: Yes, but probe spacing and cable shielding practices must minimize electromagnetic coupling. Cross-talk suppression becomes increasingly important in multi-channel radial vibration monitoring arrangements. Field Installation Guidelines Maintain shield grounding at a single designated instrumentation grounding point to reduce circulating noise currents. Route proximity probe extension cables separately from high-voltage motor leads and VFD output conductors. Verify probe target surface condition before calibration. Excessive shaft runout or surface scoring may distort vibration readings. Avoid excessive cable bending radius near connector transitions and probe heads. Confirm threaded engagement depth and mechanical locking torque according to the associated mounting hardware specification. Validate gap voltage after installation and again after thermal stabilization of the rotating assembly.
$200.00 $100.00
-
Bently Nevada Bently Nevada 135305-01 Dual Vibration XY/Gap Monitor
Bently Nevada 135305-01 Dual Vibration XY/Gap Monitor The Bently Nevada 135305-01, also cataloged as the 135305-01 Dual Vibration XY/Gap Monitor, operates as a dedicated hardware component for continuous radial vibration and shaft gap measurement within 3300/16 series monitoring systems. Hardware Specifications Parameter Specification Model 135305-01 Brand Bently Nevada Origin USA Weight 2.2 lbs Dimensions Standard 3300/16 module size Operating Temp –40 to +85 deg C Relative Humidity 0–95% non-condensing Power Consumption Industry-standard for 3300/16 modules Measurement Channels 2 independent channels (X and Y axes) Functions Radial vibration + shaft gap (displacement) Inputs 2 proximity probes / Proximitor sensors Frequency Response 1 Hz–4 kHz (option-dependent) Bandwidth Up to 24 kHz Sampling Rate Up to 50 kHz per channel Resolution 16-bit Outputs Programmable: 4–20 mA, 0 to –10 Vdc, +1 to +5 Vdc Recorder Outputs Dedicated, short-circuit protected Hot-Swap Compatible within 3300 series racks Compliance API 670, CSA, ATEX, CE Eddy-Current Probe Scaling & Rotor Dynamics The 135305-01 module implements precise eddy-current probe scaling to ensure accurate radial vibration and shaft gap measurements. Gap voltage validation is maintained at –10 VDC targets for all Proximitor channels. Rotor dynamics signals are captured with 16-bit resolution, and cross-talk suppression is applied to prevent interference between X and Y channels. Programmable low-frequency filtering allows monitoring of slow-speed machinery without loss of diagnostic fidelity. Frequently Asked Questions (FAQ) Q: Can this module be hot-swapped without shutting down the 3300/16 rack?A: Yes, the 135305-01 supports controlled hot-swap within 3300 series racks, maintaining all channel calibration and alarm settings. Q: What is the maximum sampling rate per channel?A: Each channel can sample up to 50 kHz, supporting high-speed vibration monitoring. Q: Does the module support independent gap alarm thresholds?A: Yes, separate ALERT and DANGER setpoints can be configured for both vibration and displacement channels. Field Installation Guidelines Install module in a 3300/16 rack with correct slot orientation; ensure proper mechanical retention. Connect Proximitor probes with shielded cabling; terminate shields to system ground. Maintain separation between sensor cabling and high-current or high-voltage lines to reduce EMI. Verify probe excitation voltage and cable continuity before system power-up. Use manufacturer-recommended torque for all terminal connections. Ensure ambient conditions comply with –40 to +85 deg C operating range and 0–95% relative humidity.
$200.00 $100.00
-
Bently Nevada Bently Nevada 133811-02 3500/61 Temperature Monitor Module
Bently Nevada 133811-02 3500/61 Temperature Monitor Module The Bently Nevada 133811-02 serves as the primary 133811-02 3500/61 Temperature Monitor Module utilized to execute high-accuracy temperature signal monitoring across Bently Nevada 3500 Machinery Protection System platforms. Suffix Breakdown & Model Matrix The 133811-02 is supplied as a single fixed-configuration module. No additional suffixes or alternative model matrices are specified in the provided documentation. The module supports six independent temperature input channels and integrates with 3500 Series rack systems for signal processing and alarm output. Hardware Specifications Parameter Specification Model 133811-02 Brand Bently Nevada Origin USA Weight 0.91 kg Dimensions 241.3 × 24.4 × 241.8 mm Operating Temp −30 deg C to +65 deg C Storage Temp −40 deg C to +85 deg C Power Consumption ~5.8 W Input Channels 6 temperature channels Supported Sensors RTDs (2/3/4-wire), Thermocouples (Type J, K, T, E), Thermistors Measurement Range Sensor-dependent (e.g., −200 deg C to +850 deg C for thermocouples) Accuracy ±3 deg C at 25 deg C typical, ±0.1% FS Resolution 16-bit A/D Analog Outputs 2 outputs, 4–20 mA Alarm Functions Independent Alert and Danger thresholds per channel Relay Output Via 3500 rack relay modules Certifications CE, CSA, ATEX, IECEx Rotor Thermal & Signal Integrity Features The module incorporates cross-channel signal isolation to prevent interference between analog temperature inputs. Thermocouple inputs include cold junction compensation (CJC) to maintain accuracy over the operating range. Input scaling is performed internally to ensure consistent readings across 2/3/4-wire RTDs and multiple thermocouple types. The module design mitigates electromagnetic interference from adjacent machinery and rack components, maintaining integrity of real-time monitoring data critical to predictive maintenance. Frequently Asked Questions (FAQ) Q: Can the 133811-02 module be hot-swapped without disrupting the rack?A: Yes. The module supports hot-swap replacement, allowing maintenance without powering down the 3500 Series rack. Q: How are temperature inputs isolated from each other?A: Each input channel is galvanically isolated, reducing cross-talk and preventing interference between sensors. Q: What is the recommended ambient environment for accurate operation?A: Operate within −30 deg C to +65 deg C, with humidity up to 95% non-condensing. Avoid direct exposure to water ingress or strong EMI sources beyond standard industrial control environments. Field Installation Guidelines Install modules in 3500 Series racks according to rack orientation and slot numbering. Ensure proper backplane engagement; listen for tactile click confirming seating. Route sensor cables to minimize exposure to high-voltage lines or switching noise. Maintain grounding and shield continuity on thermocouple or RTD cabling for optimal signal fidelity. Avoid mechanical shock or bending stress on input cables; secure wiring with cable ties or trays.
$200.00 $100.00
-
Bently Nevada Bently Nevada 129974-01 Industrial Monitoring I/O Module
Bently Nevada 129974-01 Industrial Monitoring I/O Module The Bently Nevada 129974-01 serves as the primary 129974-01 Industrial Monitoring I/O Module utilized to execute transducer signal acquisition and vibration diagnostic communication across machinery protection system platforms. Hardware Specifications Parameter Specification Model 129974-01 Brand Bently Nevada Origin United States Weight Not specified Dimensions 150 x 100 x 50 mm Operating Temp -40 to +85 deg C Storage Temp -55 to +105 deg C Power Consumption Not specified Power Supply 24 VDC Input Channels 8 channels Output Channels 4 channels Communication Interfaces Ethernet, RS-485 Signal Range +/-10 Vpp or 4-20 mA Transducer Power -24 VDC regulated, up to 40 mA Frequency Response 4 Hz to 4 kHz vibration; 0.017 Hz to 20 kHz speed Enclosure Rating IP65 Certifications CE, RoHS Supported Sensors Proximity probes, accelerometers, Velomitor transducers Eddy-Current Probe Scaling and Rotor Dynamics The module supports eddy-current probe scaling for shaft vibration and position measurements associated with rotor dynamics analysis. Integrated signal conditioning filters high-frequency interference before transmission to supervisory systems through Ethernet or RS-485 links. Gap voltage validation aligned with -10 VDC probe targets assists in maintaining stable transducer bias conditions during continuous monitoring. Cross-talk suppression between adjacent channels reduces interference during simultaneous multi-sensor acquisition. Frequently Asked Questions (FAQ) Q: Does the 129974-01 support both voltage and current input signals?A: Yes. The module accepts signal ranges of +/-10 Vpp and 4-20 mA depending on sensor configuration. Q: Can the module supply power directly to connected transducers?A: Yes. It provides regulated -24 VDC transducer power with output current up to 40 mA. Q: Are redundant monitoring configurations supported?A: Yes. The module documentation specifies support for redundant configurations intended for machinery protection architectures. Field Installation Guidelines Install the module inside grounded industrial control enclosures with adequate airflow clearance. Route proximity probe and accelerometer cabling separately from motor power conductors. Terminate cable shields at the designated ground reference point to reduce induced electrical noise. Verify transducer polarity and communication addressing before energizing the module. Maintain dry enclosure conditions consistent with the specified IP65 environmental protection level.
$200.00 $100.00
-
Bently Nevada Bently Nevada 124534-01 Proximitor Transducer Module
Bently Nevada 124534-01 Proximitor Transducer Module Configured for shaft vibration and gap position monitoring in Bently Nevada TSI systems, the Bently Nevada 124534-01 (124534 Proximitor Transducer Module) provides direct electrical conversion of eddy-current probe impedance variation into a proportional negative DC output signal for rotor dynamic measurement circuits. Hardware Specifications Parameter Specification Model 124534-01 Brand Bently Nevada Origin United States Product Type Proximitor Transducer Module Supply Voltage -24 VDC Linear Sensitivity 200 mV/mil Sensitivity Equivalent Approximately 7.87 V/mm Measurement Range 10-90 mils (0.25-2.30 mm) Output Signal Negative DC voltage proportional to probe gap Connector Type 3-pin Housing Material Aluminum Mounting Method DIN rail mounting Weight 0.75 lbs Compatibility Bently Nevada 3300 and 3500 monitoring systems Calibration Reference -10 VDC at 50 mil gap target Signal Interface Eddy-current proximity probe input Eddy-Current Probe Scaling and Gap Voltage Validation The module operates as a calibrated Proximitor interface for eddy-current probe assemblies. Linear scaling is maintained at 200 mV/mil throughout the specified operating span between 10 mils and 90 mils. Gap voltage verification is typically referenced at approximately -10 VDC during probe alignment at the 50 mil mechanical center position. Incorrect target gap adjustment may introduce amplitude deviation in radial vibration channels and axial position measurements. Internal circuit construction incorporates shielding methods intended to reduce EMI and probe cable cross-talk effects in turbine supervisory instrumentation installations where parallel routing of transducer cables exists. Frequently Asked Questions Q: Does the 124534-01 support hot replacement during system operation?A: The supplied documentation does not specify online hot-swap capability. Standard industrial practice is to isolate monitor channel power before transducer replacement to prevent incorrect gap reference readings. Q: What type of output does the module generate?A: The module provides a negative DC voltage output proportional to probe-to-target distance variation derived from eddy-current signal conditioning circuitry. Q: What installation factor most directly affects measurement accuracy?A: Probe gapping accuracy and shield grounding continuity directly influence linear response stability and vibration signal integrity. Improper shield termination may increase electrical noise coupling. Field Installation Guidelines Install the module on grounded DIN rail structures with low impedance bonding continuity. Maintain physical separation between transducer cabling and high-voltage motor conductors. Use shielded extension cable assemblies approved for matching eddy-current probe systems. Avoid sharp cable bending near probe connectors to minimize impedance variation. Confirm target material compatibility before calibration procedures. Validate gap voltage prior to machine startup and after rotor maintenance activity. Terminate cable shielding at the designated instrumentation ground point only to reduce ground-loop current circulation.
$200.00 $100.00
-
Bently Nevada Bently Nevada 102550-01 Monitor Main Module
Bently Nevada 102550-01 Monitor Main Module The Bently Nevada 102550-01, also cataloged as the 102550 Monitor Main Module, operates as a dedicated hardware component for PLC I/O signal handling and machinery monitoring interface execution within Bently Nevada monitoring and automation systems. The module links field transducers and controller logic through continuous online signal acquisition and process communication functions. Hardware Specifications Parameter Specification Model 102550-01 Brand Bently Nevada Origin United States Product Type PLC I/O Modules Module Type Monitor Main Module Compatibility Bently Nevada systems and compatible PLC platforms Monitoring Capability Continuous online machinery monitoring Construction Industrial-grade module assembly Integration Method PLC and monitoring system interface connection Dimensions 190 x 16.2 x 10.8 cm Weight 1.2 kg Supported Functions Signal acquisition, monitoring interface, machinery protection support Cross-Talk Suppression and Signal Conditioning The module architecture supports conditioned signal transfer between machinery transducers and PLC interface circuitry. Internal signal routing is arranged to reduce electrical cross-talk between adjacent monitoring channels and control-related signal paths. When integrated with eddy-current proximity probe systems, signal stability depends on matched transducer scaling and controlled grounding continuity. Probe circuits operating near standard -10 VDC gap reference targets require shield integrity throughout the cable path to maintain stable shaft position measurements. Channel isolation practices within the monitoring assembly assist in minimizing transient interference generated by relay switching devices, variable-frequency drives, and adjacent power conductors. Frequently Asked Questions Q: Does the 102550-01 support online module replacement during operation?A: Replacement procedures depend on the host monitoring platform and PLC architecture. Power isolation and communication verification should be completed before module removal. Q: Can the module interface directly with standard PLC input structures?A: The module is designed for integration with compatible PLC systems and Bently Nevada monitoring platforms using supported signal interface methods. Q: What installation condition most affects signal integrity?A: Improper shield grounding, parallel routing with power conductors, and loose connector termination can introduce electrical noise into low-level monitoring signals. Field Installation Guidelines Install the module within a grounded industrial enclosure with adequate spacing for cable routing and heat dissipation. Secure all field wiring to prevent connector stress caused by vibration or cabinet movement. Separate low-level transducer wiring from motor power cables, relay outputs, and switching power supplies. Maintain continuous shield grounding according to the site instrumentation standard. Inspect terminal connections periodically for oxidation, loosened hardware, or insulation degradation. Avoid excessive cable bending near module connector interfaces during maintenance procedures.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3500/05-02-04-01-00-01 System Rack
Bently Nevada 3500/05-02-04-01-00-01 System Rack The Bently Nevada 3500/05-02-04-01-00-01 serves as the primary 3500/05 System Rack utilized to execute module power distribution and backplane signal routing across 3500 Machinery Protection System platforms. The rack frame supports monitor module installation, redundant power supply integration, and internal communication paths between vibration, relay, and interface modules. Suffix Breakdown & Model Matrix The supplied documentation identifies the model as a fixed rack assembly configuration. No official suffix allocation matrix or option decoding structure was provided within the source material. Hardware Specifications Parameter Specification Model 3500/05-02-04-01-00-01 Brand Bently Nevada Origin United States Product Type Machinery Protection System Racks Rack Size Full-size 19-inch EIA rack Slot Capacity 14 slots Dimensions 19-inch rack format Weight Not specified Mounting Options Panel mount, rack mount, bulkhead mount Operating Temp -20 deg C to +65 deg C Storage Temp -40 deg C to +85 deg C Power Consumption Dependent on installed module count and power supply configuration Power Supply Support Dual redundant power supplies Hazardous Area Rating ATEX/IECEx Zone 2, CSA Class I Division 2 Compliance FCC Part 15, EMC Directive 2014/30/EU, RoHS Directive 2011/65/EU Certifications ABS, DNV GL, CE, CSA, IECEx Rotor Dynamics Signal Path Integrity The rack backplane architecture maintains dedicated communication paths between machinery monitoring modules used for rotor vibration and axial position analysis. Internal signal routing is arranged to reduce electrical interference between adjacent monitor channels and relay outputs. When used with eddy-current probe monitoring systems, the rack supports stable module communication required for probe scaling and gap voltage verification. Typical proximity transducer systems operating near -10 VDC gap targets depend on shield continuity and controlled grounding practices across rack wiring assemblies. Frequently Asked Questions Q: Does the rack permit online replacement of monitoring modules?A: Replacement procedures depend on the installed module type and site maintenance policy. Backplane communication status and redundant power condition should be verified before module extraction. Q: Can the rack operate with a single installed power supply?A: Yes. The rack can operate with one power supply installed. Redundant operation requires installation of dual compatible power supply modules. Q: Are all rack mounting formats interchangeable between full-size and mini-rack versions?A: No. Mini-rack versions are not available with bulkhead mounting configurations. Mechanical mounting compatibility depends on rack frame size.
$200.00 $100.00
-
Bently Nevada Bently Nevada 3500/05-02-04-01-00-00 System Rack
Bently Nevada 3500/05-02-04-01-00-00 System Rack Configured for module power distribution and backplane communication in the 3500 Machinery Protection System, the Bently Nevada 3500/05-02-04-01-00-00 (3500/05 System Rack) provides direct physical and electrical execution. The rack assembly supports monitoring module installation, redundant power input routing, and internal signal transfer between vibration, relay, and communication modules within the 3500 platform. Hardware Specifications Parameter Specification Model 3500/05-02-04-01-00-00 Brand Bently Nevada Origin United States Product Type Machinery Protection System Rack Rack Format Full-size 19-inch EIA rack Slot Capacity 14 slots Mounting Options Panel mount, rack mount Weight 4.5 kg Operating Temp -20 deg C to +65 deg C Storage Temp -40 deg C to +85 deg C Power Consumption Dependent on installed module population and power supply configuration Power Supply Support Dual redundant power supplies Backplane Function Internal module communication and power distribution Compliance FCC Part 15, EMC Directive 2014/30/EU, LV Directive 2014/35/EU, RoHS Directive 2011/65/EU Hazardous Area Approvals ATEX/IECEx Zone 2, CSA Class I Division 2 Certifications ABS, DNV GL, CE, CSA, IECEx, GOST Eddy-Current Probe Signal Distribution and Cross-Talk Isolation The 3500/05 rack backplane architecture is designed to maintain signal separation between adjacent machinery monitoring modules operating with eddy-current probe inputs. Shield continuity and low-noise grounding paths are used to minimize cross-talk between high-sensitivity vibration channels and relay output circuits. Within 3500 monitoring systems, probe extension cable scaling and gap voltage validation are processed by installed monitor modules while the rack distributes regulated power and communication pathways. Typical proximity probe systems targeting -10 VDC gap reference values depend on stable rack grounding continuity and controlled shield termination practices. Frequently Asked Questions Q: Does the 3500/05 rack support hot-swapping of monitoring modules?A: Module insertion and removal capability depends on the installed monitor type and plant maintenance procedures. Power isolation verification and rack communication status checks should be completed before module replacement. Q: Can redundant power supplies operate simultaneously in the rack?A: Yes. The rack supports dual redundant power supplies configured for automatic transfer during loss of the primary supply input. Q: Are mini-rack and full-size rack mounting methods interchangeable?A: No. Bulkhead mounting is not available for mini-rack versions. Mounting compatibility depends on the selected rack format and frame dimensions.
$200.00 $100.00
-
Bently Nevada 3500/05-01-01-00-00 Bently Nevada System Rack Chassis
Bently Nevada 3500/05-01-01-00-00 System Rack The Bently Nevada 3500/05-01-01-00-00, also cataloged as the 3500/05 system rack, operates as a dedicated hardware chassis for mechanical protection module hosting within the 3500 Machinery Protection System. Configured for structured module accommodation and backplane distribution in the 3500 rack architecture, the Bently Nevada 3500/05-01-01-00-00 (3500/05 rack) provides direct electrical interconnection and physical mounting for monitoring, relay, and communication modules. Suffix Breakdown & Model Matrix 01 → Full-size 19-inch rack configuration 01 → Rear-access wiring architecture 00-00-00 → Standard mechanical and enclosure configuration Hardware Specifications ParameterSpecification Model 3500/05-01-01-00-00 Brand Bently Nevada Origin Not specified Weight 4.5 kg Dimensions Height ~266 mm; Width 483 mm; Depth 267–349 mm Operating Temp -20 deg C to +65 deg C Power Consumption Not specified (backplane distributed, module-dependent) Rack Type 19-inch EIA full-size chassis Slot Capacity 14 slots Mounting Panel mount / rack mount Wiring Access Rear-access Protection Class IP20 Eddy-Current Probe Scaling and Backplane Signal Integrity (TSI Architecture) The 3500/05 rack backplane maintains controlled distribution paths for vibration and position measurement chains used in eddy-current probe systems. Probe scaling alignment is preserved through module-to-backplane impedance consistency, ensuring stable conversion of gap voltage signals typically referenced against -10 VDC linear range targets. Signal routing is structured to reduce cross-talk between adjacent monitoring channels, maintaining separation between vibration, Keyphasor, and relay bus lines. Rotor dynamics data acquisition integrity depends on stable backplane reference grounding and deterministic slot addressing across installed 3500 modules. Frequently Asked Questions (FAQ) Q: Does the 3500/05-01-01-00-00 support hot-swapping of installed modules? A: Yes. The backplane architecture supports module hot-swap while maintaining rack-level power and communication continuity. Individual module replacement does not require full rack power removal. Q: How is backplane power distributed across the 14-slot architecture? A: Power is distributed through a centralized backplane rail system. Load is determined by installed modules, including monitor, relay, and communication cards. Redundant power supply configurations are supported via dedicated supply slots. Q: Can rear-access wiring be combined with panel mounting in the same configuration? A: No mixed configuration is defined within a single rack option code. The 01 wiring option specifies rear-access only, while mounting style is selected independently at cabinet integration level. Field Installation Guidelines Maintain minimum rear clearance for wiring harness routing under rear-access configuration Ensure chassis grounding to cabinet earth using low-impedance bonding strap Install power supply modules before inserting monitoring or communication cards Avoid routing high-voltage cabinet wiring parallel to backplane signal harness paths Verify slot alignment before inserting modules to prevent backplane connector damage Maintain ventilation spacing in accordance with cabinet thermal design limits
$200.00 $100.00
-
Bently Nevada Bently Nevada 3500/05-01-03-00-00-00 19-Inch System Rack Chassis
Product Description The Bently Nevada 3500/05-01-03-00-00-00 is a full-width 19-inch industrial rack chassis developed for the 3500 Machinery Protection System. It functions as the mechanical and electrical backbone for all system modules, providing structured housing, integrated power distribution, and internal communication routing across the platform. This chassis is designed to accommodate monitoring modules, relay cards, communication interfaces, Keyphasor modules, and power supply units within a unified rack architecture. It supports continuous-duty operation in industrial environments where system stability and modular scalability are required. The configuration code “01-03-00-00-00” defines a standard full-size rack design with factory default mechanical and backplane layout. Core System Functions Mechanical housing for complete 3500 module architecture Integrated backplane for power and signal distribution Centralized communication routing between modules Support for monitoring, relay, and communication cards Hot-swappable module insertion capability Compatible with redundant power supply configurations Flexible installation in industrial cabinet systems Designed for continuous machinery protection operation Technical Specifications ParameterSpecification Model 3500/05-01-03-00-00-00 Product Type 19-Inch System Rack Chassis System Series Bently Nevada 3500 Rack Standard 19-inch EIA industrial format Total Module Capacity 14 slots Backplane Function Power distribution + system communication bus Power Supply Support 3500/15 AC or DC modules Redundancy Support Available Hot-Swap Capability Supported Supported Modules Monitoring, relay, communication, Keyphasor Slot Architecture Dedicated slot for power supply module Dedicated slot for Rack Interface Module (RIM) 14 configurable module positions for system expansion Mixed module compatibility across all 3500 series components Mechanical Specifications ItemSpecification Width 483 mm (19-inch EIA standard) Height Approx. 266 mm Depth 267–349 mm (varies by mounting configuration) Weight 4.5 kg Material Industrial-grade aluminum alloy Mounting Types Panel mount / Rack mount / Bulkhead mount Electrical Architecture Internal backplane distributes regulated power to all installed modules Supports AC and DC power input via 3500/15 power supplies Dual redundant power supply compatibility Integrated system communication bus for inter-module data exchange Designed for continuous operational stability in protection systems Environmental Ratings ParameterValue Operating Temperature -20°C to +65°C Storage Temperature -52°C to +105°C Humidity 10–90% RH non-condensing Vibration Resistance 5–150 Hz, 2G Shock Resistance 15G, 11 ms Protection Class IP20 Compliance & Certifications EMC: EN 61000-6-2 / EN 61000-6-4 Safety: EN 61010-1 RoHS: 2011/65/EU Hazardous Area Approvals: ATEX / IECEx / CSA / NRTL (Zone 2 rated configurations) Marine Certifications: ABS / DNV-GL compliant designs Key Features Full-size 14-slot chassis architecture for system expansion Compatible with complete 3500 module portfolio Hot-swappable design for maintenance without shutdown Rugged industrial-grade construction Suitable for harsh environmental conditions Supports flexible wiring access (front or rear depending on mounting style) Designed for mission-critical machinery protection infrastructure Application Areas Gas and steam turbine protection systems Compressor station monitoring platforms Oil and gas production facilities Power generation control systems Pipeline pumping infrastructure Offshore and marine machinery protection systems Industrial rotating equipment monitoring networks FAQ How many modules can be installed in this rack? The chassis provides 14 standard module slots, in addition to dedicated positions for power and interface modules. Does it support redundant power configuration? Yes. The rack is designed to support single or dual redundant power supply arrangements. Can modules be replaced while the system is running? Yes. The system supports hot-swappable module replacement for maintenance without full shutdown.
$200.00 $100.00
You have seen 192 out of 788 products