The device is engineered for versatility. It can conduct transformer turns ratio measurements, winding resistance tests, short-circuit impedance tests, and CT/VT commissioning. By utilizing various plug-and-play modules, the CPC 100 adapts to the specific test object, reducing the need for multiple disparate testing units. This consolidation of hardware not only simplifies logistics for field engineers but also minimizes the downtime of the substation during maintenance windows.
| Part Number | Description | |-------------|-------------| | CPC-100-PTM-1310 | 100π PTM, 1310 nm optimized | | CPC-100-PTM-1550 | 100π PTM, 1550 nm optimized (standard) | | CPC-100-PTM-CBL | Control cable (10-pin to DB15) | | CPC-100-MNT-KIT | Mounting bracket & thermal pad | omicron cpc 100 ptm
The CPC 100 PTM utilizes a thermo-optic effect in a proprietary low-stress waveguide core. A control voltage applied to the TEC changes the waveguide temperature, altering its refractive index and physical length. An integrated resistive temperature detector (RTD) provides feedback to an onboard PID controller, enabling stable phase positioning even under ambient thermal drift. The device is engineered for versatility
Partial discharge (PD) is a phenomenon that occurs in high-voltage insulation systems, where a small portion of the insulation breaks down, causing a localized discharge. PD can lead to insulation failure, resulting in costly repairs, downtime, and even safety hazards. Regular PD testing and monitoring can help identify potential issues before they become major problems. This consolidation of hardware not only simplifies logistics
The CPC 100 is a versatile unit capable of performing a wide range of electrical tests on assets such as power transformers, current and voltage transformers (CTs/VTs), circuit breakers, and grounding systems. Up to 800 A or 2,000 V AC (up to 5 kVA). DC Capabilities: Provides up to 400 A DC for testing.
Revolutionizing Substation Testing: An Analysis of the Omicron CPC 100 and Primary Test Management (PTM)
[ \Delta \phi = 2\pi \cdot \frac\Delta n \cdot L\lambda + 2\pi \cdot \fracn \cdot \Delta L\lambda ]
