Gaskiya na THD: Daga Grid zuwa Aikinƙasa
Har daɗiyan THD na harmonics a cikin kungiyar zabe mafi yawan tattalin aiki ya kamata a duba da biyu: "THD na gida yadda aka fi sani (yawan harmonics mai girma)" da "Tattalin aiki na wadannan THD (wadannan ba ta shahara ba)" — babu wanda ke taka rawa muhimmin aikinsa da hanyar jirgin ruwa da kuma nasarorin aikin, amma babu wanda ke taka rayukansu da hanyar "wadannan ko wadannan ba su shahara ba." Idan suka dace, wannan abubuwa biyu ke taka rayukansu a cikin kungiyar zabe. Tabbacin yana haɓaka daga tsarin zabe → tasiri → tafkirchi → ci gaba, wanda ke taka alaƙa a kan cin bayanai, nasarorin da kuma takardun aiki.
Tsari Mai Yawa 1: Tabbacin Yawan THD Na Gida (Yawan Harmonics Mai Girma)
Idan THDv (total harmonic distortion na voltage) na gida yadda aka fi sani (≤5% don gidajen masu ƙananan) ko THDi (total harmonic distortion na current) yadda aka fi sani (e.g., transformers ≤10%), zai iya tabbatar da lalacewar aikin na kayayyakin, nasarorin aikin da kuma kayayyakin masu ƙananan.
Kungiyoyin Tasiri: Yawan Lalauci da Karamin Lalauci
Yawan Lalauci na Copper: Harmonics currents suna taka "skin effect" a cikin lines na tasiri (e.g., 110kV cables), wanda ke taka high-frequency currents a tsakiyar conductor, yana daɗe resistance da kuma copper losses da rike harmonics.
Misali: Idan THDi yana ɗauki daga 5% zuwa 10%, line copper losses yana ɗauki daga 20%-30% (calculated via I²R). A lokacin da ake yi aiki a lokacin, temperature na conductor (e.g., dari 70°C zuwa 90°C), yana daɗe insulation aging da kuma karamin life na line (dari 30 zuwa 20 years).Worsened Voltage Sag: Harmonic voltages suna taka superimpose a fundamental voltage, wanda ke taka waveforms a cikin load ends. Masu ƙananan (e.g., semiconductor plants) zai iya samu shutdowns equipment saboda voltage irregular, idan akwai wanda ke faru za'a iya faru hundred of thousands.
Equipment na Tafkirchi: Karamin Lalauci, Lalacewa, da Karamin Life
Transformer Failure Risks:
Harmonic currents suna daɗe "additional iron losses" (eddy current losses yana ɗauki daga square of harmonic frequency). Idan THDv=8%, transformer iron losses yana ɗauki daga 15%-20% compared to rated conditions, yana daɗe core temperature (e.g., dari 100°C zuwa 120°C), yana daɗe insulation oil degradation, zai iya taka partial discharge ko burnout (e.g., a substation lost a 10kV transformer due to excessive 5th harmonic, with direct losses over one million).
Unbalanced three-phase harmonics also increase neutral wire current (up to 1.5× phase current), risking neutral overheating and breakage, leading to three-phase voltage imbalance.Capacitor Bank Resonance Damage:
Capacitors have low impedance to harmonics, easily forming "harmonic resonance" with grid inductance (e.g., 5th harmonic resonance can cause capacitor current to reach 3–5× rated value), resulting in insulation breakdown or explosion. One industrial workshop damaged three 10kV capacitor banks within a month due to 7th harmonic resonance, with repair costs exceeding 500,000.
Generation Equipment: Output Fluctuations and Efficiency Drop
Synchronous Generator Output Limitation:
Grid harmonics back-feed into generator stator windings, creating "harmonic torque," increasing vibration (speed fluctuation ±0.5%), reducing output (e.g., a 300MW unit drops to 280MW at THDv=6%), and raising stator temperature, affecting generator lifespan.Renewable Inverter Grid-Connection Failure:
PV/wind inverters are sensitive to grid THD. If point-of-connection THDv > 5%, inverters trigger "harmonic protection" and disconnect (per GB/T 19964-2012), causing renewable curtailment (e.g., a wind farm lost over 100,000 kWh in one day due to excessive 3rd harmonic).
Control Systems: Maloperation Leading to System Faults
Relay Protection Misoperation:
Harmonic currents cause transient saturation in current transformers (CTs), leading to inaccurate sampling in overcurrent or differential protection. For example, superimposed 5th harmonic current distorts secondary CT current, causing overcurrent protection to falsely detect "line short circuit" and trip, resulting in widespread outages (e.g., a distribution network experienced 10 feeder trips due to THDi=12%, affecting 20,000 households).Automation System Communication Interference:
Harmonics couple electromagnetically into control communication lines (e.g., RS485, fiber), increasing data error rates (from 10⁻⁶ to 10⁻³), delaying or corrupting dispatch commands (e.g., a "trip fault line" command fails to deliver, expanding the fault).
End-User Equipment: Performance Degradation and Frequent Failures
Industrial Motor Overheating and Burnout:
Asynchronous motors under harmonic voltage generate "negative sequence torque," causing speed fluctuations, increased vibration, and higher stator copper losses. At THDv=7%, motor efficiency drops by 5%-8%, temperature rises by 20–30°C, and lifespan is halved (e.g., a steel plant burned two rolling mill motors within six months due to 7th harmonic, with repair costs over 2 million).Precision Equipment Accuracy Loss:
Sensitive equipment like semiconductor lithography machines and medical MRI systems require extremely clean voltage (THDv≤2%). Excessive THDv increases measurement errors — e.g., a lithography machine’s etching precision drops from 0.1μm to 0.3μm due to voltage harmonics, reducing product yield from 95% to 80%.
Tsari Mai Yawa 2: Indirect Risks of THD Measurement Errors (Inaccurate Monitoring)
THD measurement errors (e.g., actual THDv=6%, measured as 4%, error = -2%) lead to "false compliance" or "over-treatment," exacerbating risks or causing economic waste — essentially, "data distortion leading to poor decisions."
Missed Detection of Excess: Delayed Mitigation, Escalated Harm
If measured THD is lower than actual (e.g., actual THDv=6%, measurement error -1%, displayed as 5%), it falsely indicates "harmonic compliance," delaying filter installation (e.g., APF). This allows long-term harmonic accumulation:
Short-term: Accelerated aging and higher failure rates of transformers, capacitors, etc.
Long-term: Risk of system resonance, potentially causing regional grid collapse (e.g., a regional grid experienced resonance after two years due to missed 3rd harmonic detection, resulting in 5 substations offline).
False Alarm of Excess: Over-Investment, Wasted Costs
If measured THD is higher than actual (e.g., actual THDv=4%, measurement error +1%, displayed as 5%), it falsely indicates "harmonic excess," leading to unnecessary filter installation:
Economic waste: A 10kV/100A APF costs ~500,000; if no mitigation is needed, the equipment sits idle (with annual maintenance of 20,000).
System disturbance: Excess filters may create new resonance points (e.g., installing a 5th harmonic filter triggers 7th harmonic resonance), introducing new risks.
Data Distortion: Affects Grid Planning and Dispatch
THD measurement errors distort harmonic distribution data, impacting long-term planning:
Example: A region’s monitoring shows average THDi=8% (actual 6%), leading to over-provisioning of harmonic mitigation capacity (building 2 extra filter stations, investment over 10 million).
In dispatch, inaccurate THD data prevents precise harmonic source identification (e.g., wrongly blaming a PV plant, limiting its output), affecting renewable energy integration.
Tsari Mai Yawa 3: Economic Loss — From Direct Costs to Indirect Losses
Harmonic THD errors (including excess and measurement inaccuracies) cause significant economic losses through equipment damage, increased energy consumption, and production downtime, quantifiable in three cost categories:
| Loss Type | Specific Performance | Quantification Example (Taking a 10kV Industrial User as an Example) |
| Direct Equipment Cost | Burnout/replacement of equipment such as transformers, capacitors, motors | When THDv=8%, the annual equipment replacement cost increases by 5-20 million yuan (calculated based on 2 transformers + 3 sets of capacitors) |
| Additional Energy Consumption Cost | Increase in copper loss/iron loss of lines and transformers | When THDi=10%, the annual additional electricity consumption increases by 100,000 - 500,000 kWh (calculated based on an annual electricity consumption of 10 million kWh and an electricity price of 0.6 yuan/kWh, the annual additional electricity fee is 60,000 - 300,000 yuan) |
| Production Stop Loss | Shutdown of sensitive equipment and interruption of production lines | A semiconductor factory’s lithography machine shuts down for 1 hour due to harmonics, resulting in a loss of wafer output value exceeding 500,000 yuan |
Summary: The Core Impact Chain of THD Errors on Power Systems
The fundamental impact of harmonic THD errors follows a cascading chain: "waveform distortion → equipment damage → system instability → economic loss." Measurement errors act to amplify or misjudge this chain:
Excessive actual THD is the "primary hazard", directly damaging power system hardware and compromising stability;
THD measurement error is the "decision interference", leading to improper mitigation—either worsening risks or wasting resources;
Ultimately, both lead to safety risks (equipment burnout, system collapse) and economic losses (repair costs, energy waste, production downtime).
Therefore, power systems must adopt a dual approach: "precise monitoring (controlling THD measurement error ≤ ±0.5%) + effective mitigation (keeping actual THDv below 5%)" to comprehensively avoid these risks.
