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Configured for eddy-current displacement and vibration sensing in 3300 XL Proximity Transducer System platforms, the Bently Nevada 330103-00-10-05-01-00 (330103 Proximity Probe) provides direct physical/electrical execution.

Hardware Specifications

Parameter Specification
Model 330103-00-10-05-01-00
Brand Bently Nevada
Origin United States
Probe Tip Diameter 8 mm
Measurement Type Eddy-current, non-contact
Target Function Vibration, shaft position, Keyphasor speed
Output Signal Voltage proportional to gap distance
Measurement Range Typical 2 mm to 4 mm linear range
Accuracy +-0.25 mm typical
Frequency Response Suitable for dynamic vibration analysis
Housing Material Stainless steel
Connector Type Standard Bently Nevada connector
Operating Temp -51 to +177 deg C
Power Consumption Passive sensor driven by external Proximitor interface
Dimensions 8 mm tip diameter
Weight 0.323 kg

Eddy-Current Probe Scaling and Rotor Dynamics

The 3300 XL 8 mm proximity probe utilizes eddy-current probe scaling to convert physical gap distances into proportional electrical voltage. When paired with a compatible 3300 XL Proximitor Sensor, the system allows precise gap voltage validation with a nominal target of -10 VDC at the center of the linear range. This electrical configuration minimizes cross-talk suppression issues when multiple probes are installed in close physical proximity along the machine casing. The resulting high-frequency signal output enables accurate profiling of rotor dynamics, including dynamic shaft vibration, position, and axial thermal growth.

Frequently Asked Questions

Q: How is the gap voltage validation target verified during initial installation?

A: Connect a digital voltmeter to the corresponding Proximitor Sensor output terminals. Adjust the mechanical positioning of the probe body relative to the target shaft until the signal stabilizes at the standard -10 VDC target, indicating the center of the linear range.

Q: What are the electrical consequences of field-modifying the integrated cable length?

A: Trimming or splicing the integrated coaxial cable alters the factory-calibrated impedance of the RF loop. This directly de-calibrates the eddy-current probe scaling, inducing measurement errors during the analysis of machinery rotor dynamics.

Field Installation Guidelines

  • Mechanical Torque Constraints: Secure the threaded probe body into the indicator bracket using a calibrated torque tool. Do not exceed standard industrial limits for 8 mm tips to prevent mechanical failure of the internal copper coils.
  • Coaxial Connector Ingress Protection: Ensure the coaxial connector interface remains dry and free of lubricants or water. Apply specified sealing boots or self-fusing electrical insulation tape over the terminal junction.
  • Cable Bend Curvature Limits: Route the integral cable along the machine structures while respecting minimum bend radius regulations. Avoid sharp kinks or compression points that could degrade the internal RF shielding.
  • Target Surface Flatness: The shaft target track area must be flat and match the calibrated target alloy specification to maintain linear eddy-current loop execution.

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