Accurate High Voltage Power Measurement

Roy Hali · 16.12.2024

Power Electronics · 4 min. reading duration

HIOKI’s all new High Voltage Divider VT1005 is an important addition to the HIOKI power measurement solutions. In combination with one of the HIOKI power analyzers, the VT1005 enables to accurately measure power up to 5kV. Especially for high voltage and high frequency applications with SiC and GaN semiconductors, the VT1005 realizes a huge improvement in accuracy over currently available solutions. Additionally, the for loss measurement of HV coils and transformers the new VT1005 is the perfect choice because of its 4MHz bandwidth.

Roy Hali

Senior Application Engineer, HIOKI Europe

With ongoing electrification of our society there is a rapidly growing need for more electrical power. One way to meet this need is to increase the system voltage. Obvious applications are the ultra-high-speed chargers for EV’s and all kind of power converters and solid-state transformers to increase the flexibility and reduce the losses of the power grid. Power measurement instruments like for instance the HIOKI PW8001 Power Analyzer can measure power up to a voltage of 1500 Vdc. The VT1005 High Voltage Divider now offers the solution for accurate voltage and power measurements up to 5000 Vrms.

High noise resistivity is essential

The VT1005 is highly resistant to both common-mode and high-frequency noise, allowing it to measure voltage accurately even in noisy environments. Since conversion devices like inverters are sources of noise, noise resistivity is an important factor in power efficiency evaluation. The design of the VT1005 with the floating differential input eliminates common mode noise because the same noise signal will be picked up in both input connection cables and cancelled out in the differential amplifier as it only amplifies the differences at the input.

Figure 1: Common-Mode Noise is cancelled thanks to the floating differential input.

SiC and even more GaN power devices are characterized by fast voltage rising and falling response, and their output waveforms contain numerous high-frequency components. When we compare the output voltage of the VT1005 with a similar voltage divider on the market, we find that the competitor product shows a “ringing effect” whereas the VT1005 does not. (see fig. 2) Such a ringing effect occurs because the HV input pulses cause parasitic capacitances and inductances in the circuit to resonate at their characteristic frequency. Parasitic capacitances and inductances are not part of the design but just by-products of the components within the circuit layout.

Such a ringing effect though has a negative impact on the accuracy of the voltage and power measurement and therefore must be avoided.

Figure 2: Output voltage waveform from an inverter using SiC semiconductors at 50 kHz carrier frequency.

Frequency flatness: manage the increase of your power efficiency

To further increase the efficiency of power systems, SiC and GaN semiconductors are becoming popular switching devices. The switching frequency of SiC semiconductors is 50 kHz or higher, and GaN can even go up to 1 MHz. This makes it hard to accurately measure power efficiency because accuracy must be guaranteed over a broad frequency spectrum from DC up to 1 MHz or even more. To realize such accurate power measurement, HIOKI power measurement systems have excellent frequency flatness, i.e. measurement stability, which enables a constant measurement accuracy over a wide frequency range, which in turn is essential to make targeted increases in efficiency measurable and assessable.

For example, to measure an efficiency improvement of 0.01 %, it is necessary to have a gain accuracy of 0.1 % and the phase error must be within 0.1°.

Figure 3: Gain and phase characteristics of the VT1005 HVD (solid lines) in comparison to a competitor (dotted lines)

The above two graphs show the gain and phase error for three individual VT1005 and another 3-phase high voltage divider available on the market. What is striking is that you can hardly differentiate the 3 solid lines of the VT1005 as they are almost identical and therefore overlapping whereas the 3 dotted lines of the other voltage divider are much more divergent, indicating that the accuracy is lower. Furthermore, the gain and phase error at higher frequencies are greater with this voltage divider, which makes it unsuitable for applications using SiC or GaN semiconductors.

Because both the VT1005 High Voltage Divider and the Current Sensors are designed and produced by HIOKI, they are optimized to be used in combination with the HIOKI Power Analyzers. This allows you to realize outstanding performance both in gain and phase accuracy over the entire frequency range when the phase shift correction function of the power analyzer is activated (see fig.4).

Figure 4: Stable phase characteristics of the VT1005 after phase correction with a HIOKI Power Analyzer (yellow) compared to before (red). Gain flatness up to 1 MHz (blue).

Efficiency measurement for Wireless Power Transfer systems (WPT)

The voltage output of WPT applications tends to be usually up to 3 kV because transmitting power at a higher voltage can reduce power losses during transmission. Therefore, WPT efficiency assessments require an accurate high voltage measurement. Since WPT transfers power through coils, the transmit/receive part has a very low power factor. When the power factor is low, the phase error greatly affects the measured value, so power measurement with a low phase error is essential.

Figure 5: For WPT coils are used for power transmission resulting in low power factor.

The VT1005’s measurement band ranging from DC to 4 MHz allows to measure voltage from DC to high frequencies. In addition, the excellent flatness of the amplitude and phase characteristics in the measurement band enable highly accurate power measurements and thus accurate evaluation of power efficiency.

Loss Measurement of HF reactors and Transformers

The VT1005 High Voltage Divider in combination with the PW8001 Power Analyzer and the CT6904A Current Sensor represents the optimum solution to measure loss of high voltage, high frequency inductors and transformers. With this set up accurate loss measurements can be guaranteed even at a frequency of 300 kHz due to the strong noise resistivity and phase accuracy at high frequencies.

Figure 6: High frequency and voltage transformer in a SiC based power converter.

In the light of the increased use of SiC and GaN semiconductors, high frequency and high voltage applications are on the rise. These require highly accurate measurement solutions like the VT1005 with HIOKI power analyzers to prove even small efficiency gains.

PW8001

PW8001 - High Precision Power Analyzer

High precision power analyzer for power converter and inverter efficiency analysis, ±0.03% basic accuracy, 15 MHz sampling rate, 18-bit conversion, automatic phase shift correction for HIOKI current sensors, 1 ms data update rate and excellent noise resistivity of 110 dB @ 100 kHz.Technical details:Basic power accuracy ±0.03%8 power channels combined with motor analysisExcellent noise resistivity of 110 dB @ 100 kHz5 MHz frequency measurement band for powerStable and accurate measurement at 1 ms data update rateFunctions:8 power channels in combination with motor analysis for dual drivetrain analysisUnique power range with 2 A to 2 kA high accuracy HIOKI current sensorsPlug & Play connectivity with HIOKI current sensorsAutomatic Phase Shift Correction secures accurate high-frequency power measurementVisualize high-frequency loss with Power Spectrum Analysis measurementApplications:R&D and production line testing of high efficiency power converters and invertersLoss measurement of transformers and other inductive components under loadMotor efficiency measurementDetailed Description:The HIOKI PW8001 Power Analyzer is a state-of-the-art measurement instrument designed for the most demanding power analysis tasks, providing precise measurement results when evaluating efficiency of latest high accuracy electrical devices and systems. The PW8001 has 8 slots for power input units, which all can be used in combination with the motor analysis function.For the configuration of the PW8001, two types of input units are available that can freely be combined in one instrument according to the application requirements.The U7005 High Bandwidth input unit offers ultimate precision with ±0.03% basic accuracy, a sampling frequency of 15 MHz, 18-bit A/D conversion and a maximum input voltage of 1000 VAC. It is suitable for applications such as efficiency measurements of SiC and GaN based inverters motor drives, and accurate inductor loss measurement of inductors under load. Excellent resistivity for external noise of 110 dB at 100 kHz, ensure accurate and stable results even in the proximity to high frequency power switching semiconductors. For high-voltage applications, the U7001 input unit provides ±0.07% basic accuracy, a maximum input voltage of 1500 VDC, a sampling frequency of 2.5 MHz, 16-bit A/D conversion and a maximum voltage to ground of 1500 VDC CAT II. It is a suitable unit for applications which need less bandwidth, such as testing of the efficiency of industrial motor drives using IGBTs, or wind turbines and PV power converters. Combined with HIOKI’s extensive lineup of high-accuracy and high-bandwidth current sensors, probes and direct connection current boxes, the PW8001 offers a unique and comprehensive solution for reliably measuring applications from small electronic devices to large-scale power systems. The PW8001 power analyzer and the current sensors are developed and produced by HIOKI, making the advanced automatic phase shift correction function possible. This ensures accurate phase angle measurement between the voltage and current, even at high frequencies and low power factors. The PW8001 offers the unique Power Spectrum Analysis function. While the traditional FFT function determines the harmonics based on the fundamental frequency, limiting the frequency range, this new function covers the entire frequency spectrum of the analyzer. The Power Spectrum Analysis function delivers quick visibility into the high frequency power, providing developers with valuable data for further system efficiency improvements. Other advanced functions like wideband harmonic analysis, and motor analysis, ensure precise and reliable power analysis results for a wide range of applications in the power electronics industry, such as the development of high efficiency power converters, electrical drivetrains and electrical motors. The 1 ms update rate enables high-speed data refresh, allowing precise detection and analysis of rapid power fluctuations, such as those occurring during battery charging or discharging in EVs. This feature ensures unprecedented updates without compromising on measurement accuracy. The optical link function allows the connection of two PW8001 power analyzers to increase the maximum number of measurement channels to 16. It enables synchronized power measurements and efficiency calculation from multiple inputs, optimizing measurement setup and eliminating timing differences in data collection because the sampling of all inputs is synchronized.

CT7822

CT7822 - AC/DC Current Probe

Ultra-small, zero-flux clamp-on AC/DC Current Probe using flux gate detection, high accuracy ±0.3%, max. resolution 1 mA, wide temperature range -40 to 85 oC, measurable current up to 20 A, designed exclusively for LR8450 Series Data Logger

€1,268.00*

CT6904A

CT6904A - High-precision AC/DC current sensor, 500 A / 4 MHz

High-accuracy pass-through AC/DC current sensor, zero-flux detection with flux gate technology, currents up to 500 A, bandwidth from DC to 4 MHz, CMRR of 120 dB at 100 kHz, linearity ±5 ppm, 3 m cable length with ME15W connector