Many hybrid motor vehicles use two different batteries. One provides vehicle accessory power, and the other provides power to a drive motor. Such batteries are often isolated from each other electrically. A high-voltage battery can also be isolated from the vehicle's chassis or reference potential.
When wiring from the high voltage battery for the drive motor is routed throughout the vehicle, physical damage to the conductors that extend between the battery and the drive motor can frequently cause leakage current to flow between that battery and the vehicle's primary battery. A leakage current can also exist when connections between individual cells comprising a high-voltage battery are shorted to ground. A method and an apparatus for detecting and quantifying a leakage current flowing between two normally disconnected batteries would be an improvement over the prior art.
In accordance with embodiments of the invention, leakage current between two electrical energy sources in a vehicle, one of which is normally isolated from ground, can be detected and measured by connecting voltage dividers across the two sources. The center node voltage of the first voltage divider, connected across a first battery, is measured. Thereafter, the center nodes of both dividers are connected to each other and the center node voltage of both dividers is measured and compared to the first voltage obtained from the first divider. A difference between the two voltages indicates a leakage current from the second battery to ground.
The high-voltage battery 104 actually comprises multiple, relatively low voltage batteries connected in series with each other. Vehicle wiring and electrical connections between the multiple batteries, necessary to connect multiple batteries together, create a likelihood or possibility that a fault or leakage current can develop between one or more of the series-connected batteries and the reference potential 106 for the vehicle.
The batteries 102, 104 are supposed to be electrically and physically isolated from each other. As shown in
The terminals of the first battery 102, normally about 12 volts, are connected to each other or “shunted” by a first voltage divider 110 comprising two, series-connected resistors 112 and 114 with a center node 115 between them. The first voltage divider 110 is connected across the positive and negative terminals of the first battery 102. The negative terminal of the first battery 102 is connected to the vehicle's ground potential 106.
The second battery 104, actually several batteries in series, is shunted by a second voltage divider 116. The second voltage divider 116 comprises two resistors 118 and 120, which are connected in series and thus share a center node 119 between them.
The center node 115 of the first divider 110 and the center node 119 of the second divider 116 are connected together by a wire or cable 108. Those of ordinary skill in the art will recognize that the first divider 110 connected across the first battery 102 defines a first loop, through which a first loop current, i1 will flow. Similarly, the second divider 116 connected across the second battery 104 defines a second loop through which a second loop current i2 will flow. As the circuit shown in
A second, high-voltage battery 204, comprising multiple batteries connected in series, is shunted by a second voltage divider 218 comprising two resistors 220 and 222. The second voltage divider has its own center node 224. The “second” center node 224 of the second divider 216 is “selectably” connected to the center node 212 of the first divider 206 via closure of a computer-controlled switch 226.
As shown in the figure, a leakage resistance, Rleak 228, exists between the negative terminal of the second battery 204 and the vehicle ground potential 207, or from between one of the cells of the second battery 204, and ground potential 207. The leak resistance 228 thus represents a current leakage pathway between the first battery 202 and the second battery 204, which includes series-connected batteries comprising the second battery 204. Current flowing through a loop comprising the second battery 204, the second voltage divider 218, and the leakage resistor 226, produces a voltage drop at the center node 224 of the second voltage divider 218 due to the leakage current i3. The voltage at the center node 224 is connected to or “provided to” the center node 212 of the first voltage divider when the switch 226 is closed responsive to signals provided to a solenoid 228 comprised in the switch 226, the terminals of which are coupled to the processor 216 through two outputs 230, 232 of said processor 216.
At step 304, a first voltage divider output voltage, v1, measured at the center node of the voltage divider, is measured by a processor as an analog voltage. The analog voltage is preferably converted to a digital value by an analog-to-digital converter, comprised in the processor. Being in a digital format, the first voltage is preferably stored in a memory device at least temporarily, using a memory device such as a non-transitory memory device 217 coupled to the processor 216.
After that first voltage, v1, is measured the third step 306 of the method 300 is to connect a second voltage divider, such as the second divider 218 shown in
At step 310, it is determined whether the first measured voltage and the second measured voltage are equal. If the measured voltages are unequal, at step 312 it is assumed that a leakage current exists between the two batteries. Corrective action, if desired can then be taken. If no difference exists between the center node voltages, no leakage current exists, as shown in step 314. The method can thereafter be repeated, as desired.
The magnitude of the leakage current, i3, can be determined. If a leakage current i3 exists in the circuits shown in
Those of ordinary skill in the art will recognize that the method depicted in
Those of ordinary skill in the art will appreciate that connecting a voltage divider across a power source, such as a battery, solely to test for leakage current will inherently waste power during the time that the dividers are connected. The resistance values used for the voltage dividers will determine how much current is wasted, with larger resistance values being preferred over smaller values. In a preferred embodiment, the resistors used to form the voltage dividers are preferably the same value and preferably at least one million ohms. The voltage dividers will thus provide a voltage division factor of 2.
Current draw can be reduced further if the voltage dividers are selectably connected to the power sources/batteries, only when a leakage current measurement is wanted.
The foregoing description is for purposes of illustration only. The true scope of the invention is set forth in the following claims.