The present invention concerns the field of systems for powering electrical and/or electronic equipment, in particular such systems intended to be installed in a motor vehicle, in particular an electric or hybrid motor vehicle. The present invention concerns more specifically the field of DC-DC converters, i.e. electrical systems enabling a direct-current input voltage to be converted into a direct-current output voltage which is lower or higher than the input voltage.
In a known manner, an electric or hybrid motor vehicle includes an electric motor system, powered by a high-voltage power battery via a high-voltage on-board electrical network, and various auxiliary electrical devices, powered by a low-voltage power battery, via a low-voltage on-board electrical network.
Recharging the HV high-voltage power battery with electrical energy is accomplished in a known manner by connecting it, via an electrical charger of the vehicle, to an external electrical power network, for example the G1 domestic AC electrical network. Finally, again with reference to
The electrical charger typically includes an insulated DC-DC converter. A resonant LLC converter is known, illustrated in
In a known manner, with reference to
This solution has disadvantages: in particular the high cost of these “ultrafast” diodes, bearing in mind that two such diodes are required for each circuit. In addition, the two “ultrafast” diodes cannot short-circuit at the same time. Finally, the diode's short-circuit threshold voltage is not adjustable since it is intrinsic to the diode.
To mitigate these disadvantages the present invention proposes an electrical system configured to use a method to detect the overloading of the resonance capacitor, based on a current measurement.
More specifically, the invention refers to an electrical system enabling a DC voltage to be converted into another DC voltage, including:
Advantageously, the electrical system's resonant DC-DC converter includes a rectifier, connected to the output of the transformer, and in particular to the transformer's secondary winding.
The said rectifier enables the square wave AC voltage, at the output of the transformer, to be converted into a pulsed rectified voltage, i.e. a variable voltage, but with a constant sign.
The evaluation period is preferably equal to one or more switching periods of the transistors of the resonant DC-DC converter.
In a preferred manner the first determination module is configured to determine the average value of the output current, from a measuring point located at an output terminal of the rectifier, in particular a low-output terminal of the rectifier.
The second module for determining the electrical system is preferably configured to determine the maximum voltage value and the minimum voltage value from the input voltage of the resonant DC-DC converter, the rms value of the resonance current, the switching frequency of the resonant DC-DC converter, and the value of the resonance capacitor.
The maximum voltage value and minimum voltage value are thus determined precisely.
Advantageously, the electrical system includes an electrical filter connected to the output of the rectifier of the resonant DC-DC converter.
The filter enables the quality of the signal being output from the DC-DC converter to be improved.
Advantageously, the electrical system's comparison module is configured such that:
The maximum voltage threshold and the minimum voltage threshold can be modified, and thus be modified to suit the context of the system.
Advantageously, the electrical system's fault element includes a disconnection element configured to stop operation of the resonant DC-DC converter in the event of a fault.
The invention also concerns an method for detecting an overload of a resonant DC-DC converter used in an electrical system including a resonant DC-DC converter including a resonant LLC converter circuit which includes a resonance inductor, two resonance capacitors and a transformer, where the said method is characterised by the fact that it includes steps of:
In a preferred manner, the method's fault-detection step is the detection of an overload of a resonance capacitor.
Advantageously, the method includes, after the fault-detection step, a step of disconnection of the resonant DC-DC converter, in which operation of the resonant DC-DC converter is stopped.
The method enables the electrical system, and in particular the DC-DC converter, to be protected, in order to prevent possible damage to certain components of the system, in particular the resonance capacitors, and therefore to prevent erroneous operation of the system.
In a preferred manner, the maximum value of the voltage at the terminals of each resonance capacitor is determined using the following formula:
and the minimum value (Vr_min) of the voltage at the terminals of each resonance capacitor (Cr/2) is determined using the following formula:
where Vin is the input voltage of the resonant DC-DC converter, Cr is the value of the resonance capacitors, Fs is the switching frequency of the resonant DC-DC converter, N refers to the transformer's transformation ratio, Is_avrg is the average value of the output current, Vout is the output voltage and Lm refers to the transformer's primary magnetizing inductance.
The invention will be better understood on reading the following description, given only as an example, which makes reference to the appended drawings, given as non-restrictive examples, in which identical references are given to similar objects, and in which:
It should be noted that the figures explain the invention in detail in order to implement the invention, and that the said figures can of course be used to improve the definition of the invention, if applicable.
It should be noted that the present invention is described below using different non-restrictive implementations, and may be implemented using variants within the understanding of a person skilled in the art, to which the present invention also refers.
With reference to
The HBS circuit includes two transistors T1 and T2, in particular field-effect transistors, and performs as a switch mode power supply, with transistors T1, T2 operating in switching mode. Losses may occur on activation and deactivation of each transistor T1, T2. Capacitors C1, C2 can be connected respectively in parallel with transistors T1, T2 to enable zero-voltage switching (ZVS), and to minimize losses due to switching, and thus to obtain a higher switching frequency for transistors T1 and T2. Again with reference to
Rectifier 20 can be a four-diode bridge to allow voltage rectification. Indeed, a square wave AC voltage, changing from positive to negative, is rectified as a periodic voltage of constant sign, either positive or negative.
In addition, again with reference to
When the input voltage of filter 30, corresponding to the output voltage of rectifier 20, increases, capacitor C3 is charged. Then, when the input voltage of filter 30 is reduced, capacitor C3 discharges. But, in a known manner, a capacitor is charged and is discharged “slowly”, and therefore the amplitude of the voltage delivered at the output of filter 30 is much lower than that of the input voltage of filter 30, or almost zero. The voltage at the output of filter 30 is thus almost a direct-current voltage.
Detection of a potential overload of one of resonance capacitors Cr/2 is accomplished by measuring output current Is at a measurement point B1 taken at the output of rectifier 20.
In addition, to detect a potential overload of a resonance capacitor Cr/2, the electrical system includes a control unit TN. Control unit TN is in particular a digital processing device. Said control unit TN includes a first determination module TN1, a second determination module TN2, including a comparison module TNC, and a fault detection element UP. Control unit TN is connected, in particular, by its first determination module TN1 to measurement point B1. Fault detection element UP can be a transistor control unit, commonly called a “driver” by a person skilled in the art.
With reference to
Step 1: Determination of the Rms Resonance Current Value
Ir_RMS
First determination module TN1 determines average value Is_avg of output current Is, measured at a measuring point B1 at a low output terminal of rectifier 20 of resonant DC-DC converter 1, over a period T known as the “evaluation period”. This evaluation period T can extend over one or more switching periods of transistors T1, T2 and can include a portion of a switching period.
Average value Is_avg of output current Is is also related to rms resonance current value Ir_RMS.
Indeed, by applying Kirchhoff s current law to the node located at the low terminal of the primary magnetizing inductor of transformer Tr, rms value of the resonance current Ir_RMS is defined by the following formula:
Ir_RMS≈√{square root over (Is2+Im2)} (1)
It should be noted that Is refers to the measurement of the output current and Im refers to the current in the primary magnetizing inductor of transformer Tr.
Then, when the values of output current Is and of the current in the primary magnetising inductor Im are replaced by their respective expressions, in expression (1), the following expression is obtained:
It should be noted that N refers to the transformation ratio of transformer Tr defined mathematically by the ratio of the number of coils of the secondary inductor to the number of coils of the primary inductor of transformer Tr. In addition, Lm refers to the primary magnetizing inductor of transformer Tr, Vout refers to the output voltage of rectifier 20, Fs refers to the switching frequency of resonant DC-DC converter 1, and therefore in the present case the switching frequency of transistors T1, T2 and I
It is also known that rms output current value Is_rms is defined using the following formula:
Thus, if in (1 bis) rms output current value Is_rms is replaced by its expression, one obtains:
Thus, equation (1 ter) demonstrates that average value Is_avg of output current Is, determined by first determination module TN1, is mathematically related to rms resonance current value Ir_RMS.
Step 2: Determination of Vr_Max and Vr_Min
Second determination module TN2 determines maximum value Vr_max of the voltage at the terminals of each resonance capacitor Cr/2 and minimum value Vr_min of the voltage at the terminals of each resonance capacitor Cr/2 from average value Is_avg of output current Is, determined above, and input voltage (2) Vin. To this end, second determination module TN2 uses the expression of a voltage in a resonance capacitor. Sinusoidal voltage Vr at the terminals of each resonance capacitor Cr/2 is defined by the following formula:
Vr(t)=½Vin+U0 cos(2πFst).
In this equation Vin refers to the measurement of the input voltage of resonant DC-DC converter 1, U0 is a constant, in particular a constant representative of the amplitude of periodic voltage Vr, Fs refers, as above, to the switching frequency of transistors T1, T2 and finally t represents time. There are two identical resonance capacitors Cr/2, a first capacitor of which connected to an upper terminal of first circuit 10-1 and a second capacitor of which connected to a lower terminal of first circuit 10-1, with both capacitors being connected to their other terminal in a middle point. Resonant LLC converter circuit is, in particular, connected firstly to the middle point of resonance capacitors Cr/2, and secondly to the middle points of transistors T1, T2. According to a small-signal model analysis it is considered that these capacitors are mounted in parallel.
Secondly, the expression of the current in a capacitor is known, and therefore in this case resonance capacitors Cr/2, and the expression of resonance current Ir:
where Ir peak is the maximum value of resonance current Ir. In (3), by replacing Ir(t) by its expression given in (4), the following is obtained:
In equation (3 bis) voltage Vr is replaced by its expression in (2). The following is thereby obtained:
The following is therefore obtained:
Replacing Uo in (1) by its expression in (4) the following is obtained:
It should be noted that Ir peak=V2 Ir RMS. Thus, in (2 bis), by replacing Ir peak by its expression, the following is found:
It is known that Vin and
are constant values. The only variable member of expression (2 ter) of voltage Vr is cos(2πFst). Since the maximum of cos(2πFst) is equal to 1, and the minimum of a cos(2πFst) is equal to −1, maximum value Vr_max of voltage Vr and minimum value Vr_min of voltage Vr can be deduced therefrom:
From this the expressions of maximum value Vr_max and of minimum value Vr_min are obtained, according to rms resonance current value Ir_RMS.
In addition, the expression of rms resonance current value Ir_RMS as a function of average value Is_avg of output current Is was previously determined in equation (1 ter). Thus, in the expressions of maximum value Vr_max and of minimum value Vr_min rms resonance current value Ir_RMS can be replaced by its expression given in equation (1 ter). The following is obtained:
Step 3: Comparison Between Thresholds and Vr_Min and Vr_Max
Again with reference to
Thus, a fault in resonant DC-DC voltage converter 1 is detected when maximum voltage value Vr_max is greater than or equal to maximum voltage threshold Vr_define_max, and/or when minimum voltage value Vr_min is less than or equal to minimum voltage threshold Vr_define_min. In this case the fault detection step is the detection of an overload of a resonance capacitor Cr/2.
Again with reference to
A possible alternative to the step of disconnection of resonant DC-DC converter 1 consists of a step in which fault detection element UP would require resonant DC-DC converter 1 to operate in degraded mode but would not order a complete stop of resonant DC-DC converter 1.
Number | Date | Country | Kind |
---|---|---|---|
18 60223 | Nov 2018 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
8391026 | Santoro | Mar 2013 | B2 |
9356523 | Yoshida | May 2016 | B2 |
20130099787 | Lu | Apr 2013 | A1 |
20140009968 | Matsuura | Jan 2014 | A1 |
20140160800 | Zimmanck | Jun 2014 | A1 |
20140268907 | Cinagrossi et al. | Sep 2014 | A1 |
20150229225 | Jang et al. | Aug 2015 | A1 |
20170163144 | Boncato | Jun 2017 | A1 |
Number | Date | Country |
---|---|---|
101997421 | Aug 2014 | CN |
Entry |
---|
Search Report from French Intellectual Property Office on corresponding FR application (FR1860223) dated Jun. 24, 2019. |
Number | Date | Country | |
---|---|---|---|
20200144810 A1 | May 2020 | US |