Home / Industrial Drive & Control / High-Performance Sensorless & Closed-Loop Vector AC Drive (0.75kW – 450kW)

High-Performance Sensorless & Closed-Loop Vector AC Drive (0.75kW – 450kW)

The VDN700 Series is a new generation of high-performance, universal current vector frequency converters, meticulously engineered for controlling and regulating the speed of three-phase AC asynchronous motors. Unlike conventional V/F drives, the VDN700 adopts a powerful vector control architecture (SVC & FVC), delivering exceptional low-speed, high-torque output, remarkable dynamic response, and super-strong overload capability. Its plug-and-play design supports multi-type PG cards, integrated fieldbus communication, and user-friendly programming through powerful PC software. This all-in-one solution provides a versatile, highly efficient, and cost-effective drive solution for a wide range of industrial automation applications, from textile and wire drawing to CNC machinery and pump control.

Installation Type:
Cabinet Mounting
Tags:
* AC Drive
* Current Vector Drive
* High-Performance VFD
* Low-Voltage AC Drive
Documentos:
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Key technical parameter

ItemParameter
Power Range:
3-Phase 380-480V: 45kW – 450kW
Input Voltage:
3-Phase 380V: -15% ~ +15%, 50/60Hz
Protection Level:
IP20 (Standard)
Control Model:
Sensorless Vector Control (SVC)
Flux Vector Control (FVC)
V/F Control (Premium V/F Separation)
Overload Capacity:
G-Type: 150% rated current for 60s (Heavy-duty, e.g., hoisting, extruders)
P-Type: 110% rated current for 60s (Fan/Pump duty)
Starting Torque:
SVC: 150% at 0.5Hz
FVC: 180% at 0Hz
(Zero-speed full torque, enabling precise positioning)
Braking Unit:
Built-in for lower power models, external for higher power (≥45kW)
Communication:
RS485 (Modbus-RTU), Profibus-DP, CANlink, CANopen (Optional)
Protection:
Comprehensive: Over-current, Over-voltage, Under-voltage,
Overload, Stall prevention, Phase Loss, Short-circuit, Overheat, etc.

Our advantage

High-Performance Vector Control (SVC/FVC)
Delivers 0Hz/180% starting torque and 1:1000 speed regulation range with closed-loop vector control. Ideal for cranes, elevators, and precision machinery.
Advanced V/F Separation & Dual Motor Switching
Supports independent voltage and frequency control for induction heating or torque motor applications. Seamlessly switch between two motors with separate parameter groups – saves panel space and cost.
All-in-One Intelligence: PID, PLC, Swing Frequency
Built-in PID, 16-step simple PLC, and swing frequency for textile winding and constant pressure control. Reduces need for external controllers.
Reliable & Energy-Saving
Fast current limit prevents nuisance trips. Auto energy-saving operation and random PWM reduce noise and power consumption. Full protection (overload, overvoltage, phase loss).
WP Data Tables

HUAKIA VFD Series: Frequently Asked Questions (FAQ)

This FAQ provides answers to common questions about HUAKIA's VDN series Variable Frequency Drives (VFDs), covering models VDN100, VDN200, VDN300, VDN500, VDN700, and VDN900. This guide is optimized for users seeking reliable motor control solutions.

A Variable Frequency Drive (VFD) controls the speed and torque of an AC induction motor by varying the frequency and voltage of its power supply. HUAKIA’s VDN series VFDs are designed for high performance and reliability across various industries, including textile, paper making, wire drawing, machine tools, packaging, food processing, fans, and pumps. Our drives feature advanced vector control technology, providing excellent low-speed torque, fast dynamic response, and robust overload protection for demanding automation applications.

To select the right VFD, you must match the drive’s output current and power rating (kW) to your motor’s full load current and power. First, check your motor’s nameplate for its rated voltage (e.g., 380V), current (Amps), and power (kW). Then, refer to the “Rated Output Current” table in our manuals (e.g., for VDN500/700/900). Choose a VFD model (G-type for constant torque loads like conveyors, or P-type for variable torque loads like fans and pumps) whose rated output current is equal to or greater than your motor’s rated current. For high-starting torque loads (e.g., hoists, extruders), select a G-type model and consider oversizing the VFD by one power level.

The HUAKIA VDN series offers versatile control modes to suit different performance needs:

  • V/F Control (Voltage/Frequency): Suitable for basic speed control, multi-motor applications, or when motor parameters are unknown (e.g., VDN100, VDN200).

  • Sensorless Vector Control (SVC): Provides high starting torque (up to 150% at 0.5Hz) and good speed accuracy without an encoder. Ideal for most general-purpose high-performance applications (e.g., VDN700, VDN900).

  • Closed-Loop Vector Control (FVC): Requires an encoder (PG card) on the motor. Offers zero-speed full torque, the highest speed accuracy (±0.02%), and precise torque control for demanding applications like hoisting and elevators (e.g., VDN500, VDN900).

Auto-tuning is critical for optimal vector control performance. The process is:

  1. Correctly set the motor’s nameplate parameters (rated power, voltage, current, frequency, speed) in the P1 group (or similar) of the VFD parameters.

  2. For Static Tuning (motor shaft cannot be uncoupled), set the tuning parameter (e.g., P1-37=1 for VDN500/700, H-62=2 for VDN300) to measure stator and rotor resistance.

  3. For Dynamic Tuning (best performance, uncouple motor from load), set the tuning parameter (e.g., P1-37=2) to measure all motor parameters.

  4. After setting the parameter, press the RUN key on the VFD’s keyboard. The drive will perform the measurement and stop automatically. The motor will run briefly during dynamic tuning.

Overcurrent (OC) and overvoltage (OV) are common faults often caused by incorrect parameter settings.

  • Overcurrent (OC) fault: Usually occurs during acceleration or heavy load. Solution: Increase the acceleration time (e.g., P0-17), decrease the torque boost value (e.g., E04.01 for VDN900), or check for mechanical blockages.

  • Overvoltage (OV) fault: Often happens during deceleration due to load inertia generating energy back to the VFD. Solution: Increase the deceleration time (e.g., P0-18), enable the overvoltage stall protection (e.g., P3-23=1 for VDN500), or add a braking resistor/unit. For a comprehensive guide, refer to the ‘Fault Diagnosis’ chapter in your specific model’s manual.

No, you cannot. The VDN series (e.g., VDN100-300, VDN500-900) three-phase models are designed specifically for three-phase power input. Connecting them to a single-phase supply will cause a fault and potentially damage the drive. If you only have single-phase power, you must purchase a model specifically designed for single-phase input, typically available for smaller power ratings (e.g., VDN100-S2 series for 220V single-phase).

To ensure long life and reliable operation, regular maintenance is key.

  • Daily: Check the ambient temperature, unusual motor noise/vibration, and cooling fan operation.

  • Every 3-6 months: Inspect for loose terminals, dust buildup on the heatsink, and corrosion. Clean the VFD with compressed air. Tighten all power terminals to the specified torque.

  • Every 2-3 years: The cooling fans may need replacement as they are mechanical wear parts.

  • Every 4-5 years: The main circuit DC bus capacitors should be checked, and their usable life is typically 4-5 years depending on ambient temperature and load.

The VDN series drives are designed for easy integration into industrial automation systems. They support multiple communication protocols via optional plug-in cards:

  • Standard: Modbus RTU (RS485) is available on most models like VDN100, VDN200, VDN300, and VDN500.

  • Optional: Via dedicated expansion cards, the VDN series can support Profibus-DP, CANlink, and CANopen for more advanced fieldbus requirements.

Standard VFD operation is specified for altitudes up to 1000m (about 3280 feet). If you install a VDN series VFD at a higher altitude, the air is thinner, which reduces the drive’s cooling capacity.

  • Derating: You must “derate” the VFD, meaning you must reduce the output current to prevent overheating. A common rule (for VDN100, VDN700) is to reduce the rated output current by 1% for every 100m above 1000m. The maximum recommended altitude for standard models is typically 3000m. Please consult the specific manual or HUAKIA support for precise derating factors.

HUAKIA provides a standard 18-month warranty from the date of manufacture (as indicated by the product serial number) for all VDN series VFDs. This warranty covers repair or replacement of the product if the failure is due to confirmed manufacturing defects or component failure under normal operating conditions. The warranty does not cover damage caused by improper installation, misuse, overloading, or external factors like fire, flood, or lightning.