Unsa ang mga tendensya sa pag-ukoy sa mga voltage transformer?
Gikan sa Echo, 12 Ka Tuig sa Industriya sa Elektrisidad
Kamusta tanan, ako mao si Echo, ug nagtrabaho nako sa industriya sa elektrisidad samtang 12 ka tuig na.
Gikan sa maong paglibot sa pagpatuman ug pagmatinud-an sa mga distribution room hangtod sa paglibot sa pagdisenyo sa electrical system ug pagpili sa mga equipment alang sa dako nga mga proyekto, nakakita ko kung unsaon ang pag-usbong sa mga voltage transformers — gikan sa tradisyonal nga analog devices hangtod sa intelligent, digital components.
Adunay panahon, ang usa ka bag-ong kasinabantohan gikan sa power company miangutan kanako:
“Unsa na ang kasamtangan nga estado sa pag-usbong sa voltage transformers? Asa na sila mopadulong sa hinatungan?”
Maayo nga pangutana! Mas daghan pa gihapon ang mga tawo nga isipon ang mga voltage transformers isip lang "core nga gibulag sa coils," apan sila gihapon nagpadayon sa ilang transformation.
Karon, gusto nako mohatag og:
Asa na sila gigamit karon? Unsa na ang hinatungan nga mga trend? Ug unsa na ang dapat atimanon sa mga profesional sama nato?
Walay jargon, walay komplikado nga teorya — basi real-world experience gikan sa mahigit sa dekada sa field. Tan-awon nato kung asa na nagpadayon ang pag-usbong niining matanda nga kauban nato.
1. Unsa Tuyom Ang Ginabuhat Sa Voltage Transformer?
Pagtumanon ta sa usa ka quick overview sa iyang basic function.
Ang voltage transformer (PT), o mas nailhan isip VT (voltage transformer), mao ang device nga mogamit sa high voltage ug molihok kini ngadto sa standard low voltage (kasagaran 100V o 110V) sa proportion. Kini nga signal gamiton sa measuring instruments ug relay protection systems.
Sa short, giingon kini ang “eyes” sa power grid, nga magpakilala sa aton kung asa na tinggi ang voltage sa lines.
Bagamaog simple ang iyang structure, importante gyud ang papel nianhi sa measurement, monitoring, ug protection sa tanang power system.
2. Common Types and Real-World Applications
Batasan sa akong kasinabantuhan, ang pinaka kasagaran nga ginagamit nga types sa tun-og nga mga proyekto mao ang:
Type 1: Electromagnetic Voltage Transformer (EMVT)
Simple nga structure ug cost-effective;
Widely used in distribution networks and small substations;
Disadvantages include susceptibility to saturation and ferroresonance.
Type 2: Capacitive Voltage Transformer (CVT)
Commonly used in high-voltage transmission lines (e.g., 110kV and above);
More expensive, but offers better interference resistance;
Can also serve as part of carrier communication systems.
In addition to these, I’ve seen more and more projects experimenting with Electronic Voltage Transformers (EVTs) — which is one of the key directions for future development.
3. Five Major Future Trends of Voltage Transformers
Over the years, I’ve observed that voltage transformers are evolving in the following five directions:
Trend 1: Smarter — Built-in Sensors and Remote Monitoring
In the past, voltage transformers were passive components that simply output analog signals to meters or protection devices.
But not anymore!
More and more newly built substations now require PTs with:
Built-in digital sensors;
Support for communication protocols like IEC61850;
Output of digital signals to smart monitoring systems;
Capabilities such as online monitoring, condition assessment, and even fault prediction.
For example: In one smart substation I visited, there was a new type of electronic voltage transformer that directly outputs optical fiber signals — eliminating the need for traditional secondary cables. It saved space and significantly improved data accuracy and transmission efficiency.
The future PT won’t just be a measuring device — it will become an intelligent sensing node in the power system.
Trend 2: Safer — Anti-resonance, Explosion-proof, Overheat Protection
One of the biggest issues with voltage transformers is ferroresonance.
In ungrounded systems, once resonance occurs, it can cause protection misoperations or even burn out the device.
So many manufacturers are now offering:
Anti-resonant PTs;
High-impedance open delta damping devices;
Internal fuses or overvoltage modules.
Some advanced models use epoxy resin casting or gas insulation technology to improve insulation performance and reduce explosion risks.
Trend 3: Greener — Reduced Oil Use and Environmental Impact
Many older PTs are oil-immersed, which has good heat dissipation but comes with risks like oil leakage and environmental pollution.
Nowadays, especially in new projects, there’s a growing trend toward:
Dry-type PTs;
Gas-insulated PTs;
Using recyclable materials for enclosures.
This is beneficial both for environmental protection and long-term operation and maintenance.
Trend 4: More Compact — Miniaturization and Integration
With increasing land scarcity in cities, especially in applications like data centers, metro stations, and commercial complexes, there’s higher demand for compact equipment.
Therefore, PT design is trending toward:
Smaller size;
Lighter weight;
Multi-functional integration (e.g., combined with current transformers into “composite transformers”);
Easier installation.
I once saw a modular PT in a PV step-up station — it was plug-and-play, eliminating the hassle of traditional wiring and significantly improving efficiency.
Trend 5: Better Adaptation to Harsh Environments — Moisture-resistant, Corrosion-proof, Heat-tolerant
Especially in coastal and tropical regions, voltage transformers often face challenges such as:
Salt fog corrosion;
High temperature and humidity;
UV aging.
To address these, modern PTs are increasingly designed with:
Stainless steel or fiberglass housings;
Enhanced sealing (IP54 and above);
Internal heating and dehumidification devices;
Higher insulation ratings to withstand harsh weather.
On a project in Southeast Asia, I saw a PT specially treated for moisture resistance — it could operate stably even during heavy rain.
4. Our Response Strategy
As a 12-year veteran in the electrical field, here are some suggestions for professionals in different roles:
For Technical Personnel:
Learn communication protocols and configuration methods for digital PTs;
Master new technologies like infrared thermography and partial discharge detection;
Understand the networking methods of smart substations;
Improve data analysis skills to support condition-based maintenance.
For Procurement and Project Managers:
When selecting equipment, consider reliability, compatibility, and long-term O&M costs, not just price;
Clarify protection levels and technical specifications for special environments;
Communicate clearly with suppliers to avoid blind choices;
Maintain equipment records and track operational data.
For Companies and Organizations:
Prioritize smart, eco-friendly PTs in new or upgraded projects;
Introduce digital monitoring platforms for centralized management;
Organize regular training to keep frontline staff updated with new technologies;
Develop standardized selection guidelines to improve equipment consistency.
5. Final Thoughts
Voltage transformers may sound like an "old-school" component, but they are quietly becoming smarter and more powerful.
From "just measuring voltage" to "predicting faults," their role is constantly evolving.
After 12 years in the field, I believe:
“Don’t treat them like ordinary devices anymore — they’re becoming the eyes and brains of the smart grid.”
Future voltage transformers won’t just be simple voltage conversion tools; they’ll be intelligent terminals integrating sensing, communication, analysis, and safety features.
If you're interested in the intelligent development of power systems, feel free to reach out — we can explore more hands-on experiences and cutting-edge trends together.
May every voltage transformer run stably, safeguarding the safety and efficiency of our power grid!
— Echo
