1. Field of the Invention
The invention relates generally to supplying electric power from a variety of sources, such as electric generators, solar cells, fuel cells and batteries, to various loads, such as electric appliances, motor drives and down-stream power converters.
2. Description of the Prior Art
Power electronics is an enabling technology which provides a means to regulate electric power supplied from a variety of sources to various loads. The power sources may include, but are not limited to, electric generators, solar cells, fuel cells and batteries. On the other hand, the loads may include, but are not limited to, electric appliances, motor drives and down-stream power converters. With foreseeable near-term and long-term global energy shortage, precise electric energy regulation using power electronics becomes indispensable. Examples include wind turbines, solar cells power-tracked by electronic converters, appliances operated by variable-speed electronic motor drives, hybrid electric vehicles, fuel-cell vehicles with high-power electronic converters and/or motor drives to maximize efficiencies.
To work under desired conditions, these power electronic converters and motor drives include a variety of sensors to monitor their operations. Accuracy and integrity of these sensors are therefore critical for proper operation and fault detection. The signals from these sensors are also useful for estimating the parameters of the systems, the power sources and the loads, which can be used to detect catastrophic failures or to monitor system aging.
There is a need in the industry for systems and methods to cross check the outputs of sensors and to estimate system parameters related to various systems including, but not limited to, power converters, home appliances, and vehicle electronic systems.
To address this need, this invention disclosure proposes methodologies to cross check the outputs of sensors and to estimate system parameters. These approaches can be used in many areas, including, but not limited to, power converters, home appliances, and on-vehicle electronic systems.
In a multi-phase motor drive that includes a bus capacitor, a multi-phase motor, a multi-phase inverter, multiple switches each having an on-state and an off-state, and multiple current sensors each monitoring the current on respective phase winding, a method for checking the accuracy and integrity of circuit parameters of the motor drive, including using the switches to produce a first loop that includes the capacitor bank, a first phase winding, a first current sensor, a second phase winding, and a second current sensor, using the current sensors to determine a magnitude of current in the first and second phase windings, comparing a magnitude of current indicated by the first current sensor and the second current sensor, and determining a magnitude of a difference between the current in the first and second phase windings.
The scope of applicability of the preferred embodiment will become apparent from the following detailed description, claims and drawings. It should be understood, that the description and specific examples, although indicating preferred embodiments of the invention, are given by way of illustration only. Various changes and modifications to the described embodiments and examples will become apparent to those skilled in the art.
These and other advantages will become readily apparent to those skilled in the art from the following detailed description of a preferred embodiment when considered in the light of the accompanying drawings in which:
Referring to
iloop=ic=−ia (1)
Meanwhile, the B phase current is zero:
ib=0 (2)
Equation (1) can be used to cross-check the two current sensors 34 and 36, and Equation (2) can be used to monitor the offset of the third current sensor 35. Different switch combinations can be chosen to cross-check other current sensor pairs as well as offsets of a third current sensor.
Also, while switches 17 and 18 are ON, the loop current iloop is governed by the following equation:
wherein L is the inductance of the motor winding between Phase A and C, and the other parameters are as shown in
Equation (3) can also be expressed in an integration form:
Equations (3)-(6) can be used to estimate the motor winding inductance, assuming the sensor signals iloop and vbus are accurate.
When the current is increased to a desired amplitude, either switch 17 Sc1 or switch 18 Sa2 may be off, but not both.
Based on the estimated motor winding inductance L from Equations (3)-(6), the forward-voltage drop (vc2-va2) can be estimated by Equation (7). Similarly, the inductance of other motor winding pairs and the forward voltage drops of other semiconductor pairs can be estimated.
Equations (1)-(7) can be applied to determine the magnitude of the variables during system start-up, idling, or shut-down processes.
When the dc bus voltage collapses to zero, the motor currents circulate through the windings of motors 28, 70, diodes 21, 26, 58, 63 and switches 17, 18, 66, 69, as shown in
With slightly positive dc bus voltage, the current in motor 70 will be reduced, while that of motor 28 will be increased. This forces these currents to become equal eventually. When these two currents are equal in amplitude momentarily, the net dc bus current is zero, as is the slope of the dc bus voltage. In other words, the dc bus voltage (a small positive value) and its slope become excellent indicators to determine when these two currents are exactly equal. When the conditions are met, the four current sensors 34, 36, 54, 56 associated in the process should provide the same signal amplitude.
A similar procedure can also be applied to cross-checking current sensors of a system 78 that includes a boost converter 80 and the inverter 14, as illustrated in
Then, two inverter switches 17 Sc1 and 18 Sa2 (in the illustrated example) are turned on in order to drain the energy in capacitors 92 C1 and 12 Cbus through the windings of motor 28. After the DC bus voltage is substantially or completely discharged, all switches, including those of converters 80 and inverters 14, are turned off. Then, as shown in
Then, when the voltage on bus capacitor 12 Cbus is high enough, switch 82 S1 is turned on, which initiates a free resonance between converter inductor 94 L1 and capacitor 92 C1. By properly choosing the time to turn on switch 82 S1, the resonant current drawn from bus capacitor 12 Cbus can be higher than the motor current charging capacitor 12. In other words, there are instances when the net current to bus capacitor 12 Cbus is zero as is the slope of the voltage on capacitor 12 Cbus. Similarly, this can be used as an indicator that the current to converter inductor 94 L1 at those instances equals the motor current ics or −ias.
Parameter identification is closely related to sensor accuracy. After cross-checking current sensors and voltage sensors as described above, it is safe and reliable to implement passive device parameter identification. Passive device parameter identification can be used to predict component life, evaluate possible failure, and initiate a limited operation strategy.
There are three levels of parameter identification:
Offline parameter identification can be performed as a standard check procedure performed at a particular location, such as an automobile dealership, or as a programmed auto self-check routine performed periodically.
Step 1. Passive Discharge
For a hybrid electric vehicle system without a boost converter, as shown in
t=−R2·Cbus ln(1−Vbus2/Vbus1) (8)
If the measured discharge time is close to the calculated value, then it can be safely concluded that both bus capacitor 12 and bleeding resistor 98 have the correct values.
If the discharge time is shorter than expected, either the bleeding resistor 98 is partially shorted or decreased in resistance, or the bus capacitor 12 is deteriorated. In either case, the step two, capacitance and inductance check, shall be performed.
For a hybrid electric vehicle system with a boost converter 80 and inverter 14, as shown in
To identify each capacitor or resistor, boost is needed to ensure that the bus voltage Vbus is greater than V1 in order to block conduction through diode 86 D1.
Step 2. Capacitance and Inductance Check
Capacitance is checked by an active discharge approach, as described with reference to
The relationship between the voltage across bus capacitor 12 and the current through the A and B windings of motor 28 is
Thus, the capacitance of bus capacitor 13 can be calculated from
Since step two is an offline operation, the switching frequency and duty ratio can be adjusted to an optimized value for sample accuracy. One easy way is to close switch 15 Sa1 and switch 19 Sb2 until Vbus drops close to zero, and then open switches 15, 17. The current will then be conducted through diode 24, motor windings A and B, and diode 22 to charge bus capacitor 12 Cbus. In this way, switching noise can be eliminated from the test.
For the system shown in
First, charge capacitors 92, 12 (C1 and Cbus) to the same voltage using an external pre-charge circuit, as shown in
Second, boost the voltage in bus capacitor 12 Cbus to a predetermined voltage in continuous current mode by operating switches 84 S2, 15 Sa1, and 19 Sb2, as shown in
wherein Ton is length of the period during which switch 84 S2 is on, and ΔIL1 is the inductor current change during that period.
Third, discharge capacitor 92 C1 and bus capacitor 12 Cbus by changing the states of switches S1, Sa1 and Sb2 on and off, as shown in
2. Semi-online Parameter Identification
While the vehicle is shutdown, sub-steps 2 and 3, discussed above, can be performed to check the inductance and capacitance.
3. Online Parameter Identification
When the vehicle is running, inductance of L1 can always be checked using equation (11).
In accordance with the provisions of the patent statutes, the preferred embodiment has been described. However, it should be noted that the alternate embodiments can be practiced otherwise than as specifically illustrated and described.
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