Applications of 10kV Feeder Voltage Regulators

Echo

06/18/2025

Rural power grids are characterized by numerous nodes, wide coverage, and long transmission lines. Meanwhile, the electrical load in rural areas shows strong seasonality. These features lead to high line losses on 10 kV rural feeders, and during peak load periods, the voltage at the end of the line drops too low, causing user equipment to malfunction.

Currently, there are three common voltage regulation methods for rural power grids:

Upgrading the power grid ：Requires substantial investment.
Adjusting the on - load tap - changer of the main transformer ：Takes the substation bus voltage as the reference. However, frequent adjustments affect the safe operation of the main transformer and cannot ensure stable line voltage.
Switching shunt capacitors ：Reduces voltage drop caused by reactive power when the grid has large inductive loads, but the voltage regulation range is narrow.

After final discussion, it was decided to adopt a new - type voltage regulation device — the 10 kV feeder voltage regulator (SVR), which effectively improved the voltage quality of the rural power grid.And through the comparison of measures to improve voltage quality in the following table, it can be seen that using feeder voltage regulators is currently the most effective way to enhance the voltage quality of rural 10 kV lines.

Application Example

Taking the 10 kV Tuanjie Line of a certain substation as an example, the installation process of the SVR is as follows:

Identify the critical point where voltage drops exceed acceptable limits.
Select SVR capacity based on the maximum load at the critical point.
Determine voltage regulation range according to the measured voltage drop.
Choose installation location prioritizing accessibility for maintenance.

Calculation Method

Line Parameters:

Length: 20 km
Conductor: LGJ - 50
Resistivity: R₀ = 0.65 Ω/km
Reactance: X₀ = 0.4 Ω/km
Transformer Capacity: S = 2000 kVA
Power Factor: cosφ = 0.8
Rated Voltage: Ue = 10 kV

Step 1: Calculate Line Impedance

Resistance: R = R₀ × L = 0.65 × 20 = 13 Ω
Reactance: X = X₀ × L = 0.4 × 20 = 8 Ω
Active Power: P = S × cosφ = 2000 × 0.8 = 1600 kW
Reactive Power: Q = S × sinφ = 2000 × 0.6 = 1200 kvar

Step 2: Voltage Drop Calculation
ΔU = (PR + QX)/U = (1600×13 + 1200×8)/10 = 3.04 kV

Step 3: SVR Sizing

Installation Location: 10 km from the source (critical point with measured voltage 9.019 kV).
Load at Critical Point: P = 1200 kW, cosφ = 0.8 → S = 1200/0.8 = 1500 kVA.
Selected SVR Capacity: 2000 kVA.

Step 4: Voltage Regulation Range

Input Voltage: U₁ = 9 kV (measured)
Target Output Voltage: U₂ = 10.5 kV
Required Regulation Range: 0～+20%.

Step 5: Loss Reduction Calculation
Post - installation:

Remaining Line Length: L₁ = 20 km - 10 km = 10 km
Power Loss Reduction:
ΔP = R₀ × L₁ × (S²/U₁² - S²/U₂²)
= 0.65 × 10 × (1500²/9² - 1500²/10.5²)
= 63.9 kW
Net Reduction (after SVR loss): 63.9 kW - 4.4 kW = 59.5 kW

Economic Benefits:

Annual Energy Savings: 59.5 kW × 24 h × 30 days × 4 months ≈ 450,000 kWh
Cost Savings: 450,000 kWh × ¥0.33/kWh ≈ ¥60,000
Revenue Increase: ¥80,000 annually
Payback Period: <1 year

This demonstrates that SVRs are the most effective and economical solution for improving rural voltage quality.