Prinsip Paggana ug mga Key Points sa Pagpangalag sa 10kV High-Voltage Reactive Power Compensation Device
Ang 10kV high-voltage reactive power compensation device usa ka importante ug indispensable nga komponente sa modernong sistema sa kuryente. Sa paghatag o pag-absorb sa reactive power, mahimo nini nga ma-address ang mga problema sama sa low power factor, mataas nga line losses, ug voltage fluctuations gikan sa reactive power demand, nagpahayag og key role sa pag-improve sa ekonomiya, seguridad, ug kalidad sa grid operation. Ang high-voltage 10kV reactive power compensation usa ka critical nga device alang sa pag-ensure sa safe ug economical nga grid operation.
Ang pagkaunawa sa iyang working principle mao ang pundokan alang sa maintenance, habang ang pagpatuman sa regular nga maintenance plan nga nagsentro sa preventive testing ug condition monitoring—ug laging gi-priority ang seguridad—mga fundamental nga guarantee alang sa pag-ensure sa long-term reliable operation. Ang maintenance work kinahanglan nga isulod pinaagi sa qualified ug experienced nga personnel sumala sa established procedures. Sumala ang sunod nga detalyado nga explanation sa working principle ug maintenance essentials sa 10kV high-voltage reactive power compensation systems.
1. Working Principle sa 10kV High-Voltage Reactive Power Compensation
Core Objective: Pag-improve sa grid power factor, pag-reduce sa line losses, pag-stabilize sa system voltage, ug pag-enhance sa power supply quality.
1.1 Compensation Principle
Source of Reactive Power: Inductive loads sa power grid (e.g., motors, transformers) nanginahanglan sa establishment sa magnetic field sa panahon sa operasyon, consuming lagging reactive power (Q).
Compensation Method: Capacitor banks gigamit sa parallel, generating leading capacitive reactive power (Qc) aron moganti sa inductive reactive power (Ql).
Result: Ang total reactive power (Q) nga nanginahanglan sa system mahimong mapalito, ang power factor (Cosφ = P / S) mahimong mapadako, ug ang apparent power (S) mahimong mapababa.
1.2 Components sa Compensation Device
High-Voltage Shunt Capacitor Bank: Ang core component nga naghatag og capacitive reactive power. Kasagaran gibubo niini og multiple capacitor units nga gigamit sa series ug parallel aron mopasabot sa 10kV voltage ug required capacity requirements.
Series Reactor:
Current-Limiting Reactor: Limits inrush current sa moment sa capacitor switching (kasagaran 5–20 times ang rated current), protektahan ang capacitors ug switching equipment.
Filter Reactor: Forma og LC tuned circuit uban sa capacitor (kasagaran tuned below the 5th, 7th, o specific harmonic frequency), suppressing harmonic currents sa pag-enter sa capacitor, preventing harmonic amplification ug resonance, thus protecting the capacitor.
High-Voltage Switching Equipment:
Vacuum Contactor or Vacuum Circuit Breaker: Gigamit sa pag-switch sa capacitor banks in or out. Ang vacuum contactors kasagaran gamiton ug suitable sa frequent operations.
Isolating Switch / Grounding Switch: Gigamit sa panahon sa maintenance aron mag-isolate sa power source ug ensure reliable grounding para sa seguridad.
Discharge Device:
Discharge Coil or Discharge Resistor: Pagkatapos ma-disconnect ang capacitor bank, quick discharge sa stored charge sa capacitor terminals (kasagaran required to reduce residual voltage to below 50V within 5 seconds), ensuring safety during maintenance. Ang discharge coils kasagaran gamiton.
Protection Devices:
Fuse: Protektahan ang individual capacitors labi na sa internal faults (expulsion-type fuse).
Relay Protection: Inklusibo sa overcurrent protection (phase-to-phase short circuit), unbalance protection (internal capacitor element breakdown or fuse blowout), overvoltage protection, undervoltage protection, harmonic overlimit protection, open-delta voltage protection, etc.
Measurement and Control Devices:
Controller: Continuous monitoring sa system voltage, current, power factor, harmonic current, harmonic voltage distortion rate, ug uban pang parameters. Automatic control sa switching sa capacitor banks sumala sa preset strategies (e.g., target power factor, target voltage, harmonic over-limit protection, time-based programs).
Current Transformer (CT), Voltage Transformer (PT): Provide signals for measurement and protection.
1.3 Operational Process
Monitoring: Ang controller continuous monitoring sa parameters sama sa power factor, voltage, ug reactive power demand sa grid.
Decision: Kung ang power factor mobaba sa set lower limit (e.g., 0.9 lagging), o kung ang system nanginahanglan og additional reactive power, ang controller issues an energizing command.
Energizing: Ang control circuit drives ang vacuum contactor to close, connecting the capacitor bank (usually through a series reactor) in parallel to the 10kV busbar.
Compensation: Ang capacitor bank supplies capacitive reactive power to the system, offsetting part of the inductive reactive power, improving the power factor, and supporting the voltage.
De-energizing: Kung ang power factor mobata sa set upper limit (e.g., 0.98 leading, which may cause overcompensation), o kung ang system voltage is too high, o kung load reduction leads to decreased reactive power demand, ang controller issues a de-energizing command, ang vacuum contactor opens, and the capacitor bank is taken out of service.
Discharge: Pagkatapos ma-disconnect ang capacitor bank, ang discharge device (discharge coil) automatic operates, quick discharge sa stored energy.
2. Maintenance sa 10kV High-Voltage Reactive Power Compensation Devices
Core Objective: Ensure safe, reliable, and efficient operation, and extend equipment service life.
2.1 Daily Inspection
Visual Inspection: Check capacitor casing for bulging, oil leakage, rust, or paint peeling; check bushings for cracks, contamination, or flashover traces; check connection points for looseness, overheating (infrared thermography), or discoloration.
Operating Sound: Listen for abnormal vibration or noise from reactors, discharge coils, or capacitors (e.g., an abnormally increased "humming" sound may indicate internal looseness).
Instrument Indication: Check if the indications of voltmeters, ammeters, power factor meters, and reactive power meters are normal, and compare with the controller display values.
Environmental Check: Check indoor ventilation, ambient temperature, and humidity to ensure they are within allowable limits; check for dust accumulation or signs of small animal intrusion; check if fences and labels are intact.
Protection Signals: Check if there are any alarm or trip signals from the protection devices.
2.2 Periodic Maintenance (Typically Every Six Months to One Year)
Power-Down Cleaning: Thoroughly remove dust and dirt from the surfaces of capacitor casings, bushings, insulators, busbars, frames, reactors, and switchgear (using dry, lint-free cloths or special tools, avoiding insulation damage). (Important! Cleaning of high-voltage equipment must be done after power-off, voltage testing, and grounding!)
Tightening Connections: Check and tighten all electrical connection bolts (busbar connections, capacitor terminal connections, grounding wires, etc.) to ensure good contact and prevent overheating. Operate according to specified torque.
Capacitor Testing:
Capacitance Measurement: Use a dedicated capacitance bridge to measure the total capacitance of each phase or each branch (if applicable), and compare with nameplate values or historical data. If deviation exceeds ±5% or shows significant change (especially decrease), it requires close attention, possibly indicating internal component damage. The capacitance value of a single capacitor should not deviate from the rated value by more than -5% to +10%.
Insulation Resistance Test: Measure the insulation resistance between poles and between pole and case (using a 2500V megohmmeter), which should meet regulatory requirements (typically, inter-pole insulation resistance should be very high, pole-to-case insulation resistance > 1000MΩ). Must be fully discharged before and after testing!
Dissipation Factor (tanδ) Measurement: Can be performed if conditions allow, which is more sensitive in reflecting internal capacitor insulation moisture or deterioration. Should not show significant increase compared to factory or previous measurement values.
Reactor Inspection:
Check coil appearance for overheating, discoloration, insulation aging, or damage.
Check if core (if present) fasteners are loose.
Measure winding DC resistance, which should not show significant difference compared to factory or previous values (considering temperature influence).
Measure insulation resistance.
Discharge Device Check:
Check discharge coil appearance and wiring.
Verify discharge performance (under safety regulation permission, simulate operation to verify residual voltage drop speed).
Switching Equipment Maintenance:
Check vacuum interrupter appearance.
Check if operating mechanism operates flexibly and reliably; apply appropriate lubricant to lubrication points.
Measure main circuit contact resistance.
Perform mechanical characteristic tests (opening/closing time, synchronism, bounce, stroke, etc.).
Protection Device Calibration: Calibrate settings and perform transmission tests for overcurrent, unbalance, overvoltage, undervoltage, etc., according to regulations to ensure accurate and reliable operation. Check fuse appearance and indicator status.
Controller Check: Check if display, buttons, and communication are normal; verify sampling accuracy (compare voltage, current, power factor, etc., with standard meter); check if switching logic is correct.
2.3 Special Maintenance
Harmonic Environment: If the system has serious harmonics, strengthen monitoring of temperature rise of capacitors and reactors (infrared thermography), conduct regular harmonic tests, ensure tuning point settings are reasonable to avoid resonance. Add filtering devices if necessary.
Frequent Switching: Strengthen inspection of contact wear of vacuum contactors/circuit breakers, shorten their maintenance cycle.
After Faults: After protection operation (especially fuse blowout or unbalance protection operation), the cause must be thoroughly identified, damaged components replaced, and comprehensive inspection and testing completed before re-energization.
2.4 Safety Precautions (Most Important!)
Strictly enforce the "Two Tickets and Three Systems": Work Ticket, Operation Ticket; Shift Handover System, Patrol Inspection System, Equipment Periodic Testing and Rotation System.
Power-Off, Voltage Test, Grounding: Before any maintenance work, the power source must be reliably disconnected (including possible back-feeding from PT secondary side), use a qualified voltage tester to confirm absence of voltage, and install grounding wires at both ends of the work location. The capacitor bank must be fully discharged using a dedicated grounding rod and grounded before contact!
Dedicated Supervisor: Operation and maintenance of high-voltage equipment must have a dedicated supervisor.
Use Qualified Tools and Protection: Use tools with qualified insulation rating, wear insulating gloves, insulating boots, and other safety protective equipment.
Residual Voltage Awareness: Even after discharge, use a grounding rod to short-circuit capacitor terminals again before contact.
2.5 Record Keeping and Analysis
Record data from each inspection, maintenance, and test in detail (capacitance value, insulation resistance, temperature, protection action information, etc.).
Establish equipment files, perform trend analysis, and promptly identify potential defects.
Record abnormal conditions and handling processes.
3. Reference for Key Maintenance Intervals
Daily Inspection: Daily or weekly (depending on importance and operating environment).
Periodic Cleaning and Inspection (without power-off): Monthly or quarterly.
Periodic Maintenance (with power-off): Once to twice a year (combined with preventive testing).
Capacitor Capacitance/Insulation Resistance Measurement: Conducted during power-off maintenance; once within one year of commissioning, then once every 1–2 years.
Protection Device Calibration: Once a year.
Switching Equipment Characteristic Test: Combined with power-off maintenance, once every 1–2 years or when operation count reaches a certain value.
4. Notes
Ambient Temperature: The operating ambient temperature of capacitors must not exceed the specified upper limit (typically -40°C ~ +45°C), avoid direct sunlight.
Overvoltage: Capacitors can operate long-term at 1.1 times the rated voltage; avoid prolonged overvoltage operation.
Overcurrent: Capacitors can operate long-term at 1.3 times the rated current (considering harmonic and overvoltage effects).
Harmonics: Harmonics are one of the main causes of capacitor damage. The system harmonic background must be considered during design, and the reactor ratio configured reasonably. Strengthen harmonic monitoring during operation.
