As vehicle electrification gains popularity for its environmental benefits, precise measurement of various parameters is becoming essential. Among these include measurement of voltage, current, power, power factor, and frequency of traction motors for each rotation cycle. These measurements are equivalent to conventional engine characterizations including combustion efficiency, TDC and spark timing. When evaluating the rotor performance as it gradually increases its speed from a standstill, statistical measurements of each rotation cycle is important.
Many power analyzers calculate measurement values at regular intervals or according to the cycle of a specific input signal. As a result, they may not always align with the rotation cycles of the motors. Motors typically have poles due to their structure, creating a relationship with the driving signal frequency that corresponds to the rotation cycles. This means that normal measurement methods cannot accurately capture data for each rotation cycle.
To address this issue, power analyzers need to obtain the rotor’s cycle signals using sensors. Rotation speed is commonly measured and calculated using the Z-phase signal from an incremental (ABZ) encoder. Additionally, devices such as Hall sensors, resolvers, and compressors, which cannot have sensors attached directly to their axes, require alternative methods for measurement.
Figure 1. Input of Z-phase signal to the EXT Clock terminal
To measure the rotation cycle using the WT5000 and an encoder’s Z-phase signal, follow these steps:
However, note the following restrictions:
The data measured with the WT5000 is stored and graphed using spreadsheet software (Figure 2). It shows that other parameters are plotted against rotational position. However, since measurement parameters (rotational speed, torque, mechanical power, etc.) in the motor evaluation function generate time differences with the frequency set at a rotation speed, it is set at the voltage waveform of the inverter output. Therefore, it is updated at twice the speed of the motor rotation cycle.
Following the notes above, the data measured by the WT5000 is stored and graphed using spreadsheet software to confirm its operation. Please refer to Figure 2. It shows that some parameters are updated each mechanical rotation. However, as mechanical measurement parameters (rotational speed, torque, mechanical power etc.) generate time differences with the electrical measurement (voltage, current, electrical power). Because a four pole motor was used (one electrical cycle per pole pair), the electrical measurement parameters appear to update at twice the speed of the mechanical parameters.
Figure 2. Measurement data for each rotation cycle using the WT5000
As data updating rate is at a maximum speed of 50 ms with the WT1800E, data will be updated at a cycle five times longer than the WT5000’s even under the same setting as the WT5000’s, resulting in a slight decrease in the time resolution. In addition, when the data updating rate is fixed, the minimum measurable frequency is 45 Hz. Additionally, under Auto setting with high input frequency, the result will be the mean value of multiple cycles. The measurement results are shown in Figure 3.
Figure 3. Measurement data for each rotation cycle with the WT1800E
Der Präzisions-Leistungsanalysator WT5000 definiert die neue Referenz in der Leistungsmesstechnik mit einer aktuell weltweit höchsten Grundgenauigkeit von ± (0,01 % des Messwerts + 0,02 % des Effektivwert-Messbereichs). Jedes erdenkliche Anwenderszenario wird durch die modulare Bauweise (Self-Service) sowie durch die mögliche Kaskadierung realisiert: bis zu 28 Leistungsmesskanäle plus 16 Motoreingänge gewährleisten vollumfängliche Messungen. Die neue „Digital Parallelpfad-Technologie“, wie auch die Harmonischen-Analyse (bis zur 500. Ordnung) runden den Leistungsumfang ab.