EV Component Testing Challenges - From 12 to 800VDC

As the global interest for clean energy alternatives increases within the automotive industry, so does the requirement of efficiently storing electricity. The latest trends in electric vehicle technology have led to the development of high-voltage storage solutions, all backed by the need for increased efficiency and quicker charge times.

Starting with the traditional 12VDC lead-acid battery, one advancement was the 48-volt electrical system in mild hybrid electric vehicles (MHEV), which consists of an 48V lithium-ion battery in addition to a downsized 12VDC lead-acid battery. This advancement was driven to a large extent by the need to replace components that were traditionally mechanically-driven with more efficient electrical alternatives. It includes components such as electric power steering racks, electric transmission oil pumps, electric water pumps, electric brake vacuum pumps, etc.

Further development in plug-in hybrid vehicles (PHEV) and battery electric vehicles (BEV) has increased battery voltage levels to 300-400VDC. The very latest designs in the BEV sector are pushing that envelope even further to 800VDC, driven by the requirement of faster charging times and reduced wiring size and weight. There are however specific aspects opposing the further increase in battery voltage, such as semiconductor component breakdown voltage ratings, safety regulations (60–1500VDC is considered “high voltage”), cost challenges with connecting battery cells in series, etc.

Even in this current state, the need to test a portfolio of electrically-driven products with supply voltages ranging from 12-800VDC presents certain challenges. Let us analyze the example of electric coolant pumps. A typical design verification / product validation (DV/PV) test for this product type is the traditional 5-Point Functional/Parametric Check test (GMW3172 General Specification). This test verifies component performance through a combination of various supply voltage and temperature setpoints. For a 12VDC powered pump, this would require running a test using the Minimum Supply Voltage (Umin) of 9VDC, Nominal Supply Voltage (Unom) of 12VDC, and Maximum Supply Voltage (Umax) of 16VDC. In addition, it would require pairing these with the Minimum Operating Ambient Temperature (Tmin) of -40°C and Maximum Operating Ambient Temperature (Tmax) of +125°C. The combination of parameters would look something like the table below.

The same logic would apply for high-voltage systems, except the voltage spread (Umin-Umax) would be much higher. It is quite common for high-voltage battery systems to use DC-DC converters to step down the voltage to more traditional levels, allowing selection from a larger pool of more readily available hardware.

Let us consider the pump power rating next. Low power variants such as auxiliary electric coolant pumps usually operate in the 20-60W range. As such, they do not require a high current capacity since even with 12V architectures they will draw less than 5A. However main cooling pumps, which are used to displace traditionally mechanically-driven pumps, can be in the 300-1,000W power range for passenger cars. Continued use of the 12V architecture in these cases does not lend itself well due to high current draw requirement in order to satisfy the rated power.