Device for measuring a chopped current

Abstract

A device for measuring a chopped current capable of flowing in a circuit having an H-bridge structure including a first branch and a second branch is disclosed. The device includes two transformers respectively connected to a branch and each comprising a primary circuit configured for the flow of a chopped current and a secondary circuit, two demagnetizing circuits, and two measuring circuits respectively connected to the terminals of the secondary circuit of an associated transformer, and respectively including at least one unit which comprises two switch connected in reverse, the two switches being respectively implemented by a transistor and being capable of being controlled. The measuring circuits include a common measuring resistor connected via a terminal to the ground, and via another terminal to the source of the first transistor of the first measuring circuit and to the source of the first transistor of the second measuring circuit.

Claims

1. A device for measuring a chopped current capable of flowing in a circuit having an H-bridge structure including a first branch and a second branch, the device comprising: two transformers respectively connected to a branch of the H-bridge, the transformers respectively comprising a primary circuit configured for the flow of a chopped current, and a secondary circuit; two circuits for demagnetizing the two transformers; and two measuring circuits respectively connected to the terminals of the secondary circuit of an associated transformer, the measuring circuits respectively including at least one unit which comprises a first switch and a second switch connected in reverse, the two switches being respectively implemented by a transistor and being capable of being controlled so as to: allow the flow of the current induced by the chopped current, in the measuring circuit when the primary circuit of an associated transformer is closed, and prevent the flow of the demagnetizing current in the measuring circuit when the primary circuit of an associated transformer is open; the measuring circuits including a common measuring resistor connected via a first terminal to the ground, and via a second terminal to the source of the first transistor of the first measuring circuit and to the source of the first transistor of the second measuring circuit.

2. The device according to claim 1, in which the first switch and the second switch are respectively implemented by a field effect transistor.

3. The device according to claim 1, wherein: the first switch of a measuring circuit comprises a terminal connected to a second terminal of the measuring resistor, the first terminal of the measuring resistor being connected to the ground; and the second switch of a measuring circuit comprises a terminal connected to the ground.

4. The device according to claim 1, wherein: the branches of the circuit respectively include a first switch and a second switch, the first transformer is connected to the first switch of the first branch and the second transformer is connected to the first switch of the second branch, and the unit of the first measuring circuit configured for allowing or preventing the flow of a current induced by the chopped current in the first measuring circuit, is configured for being controlled by the inverse of the control signal of the second switch of the first branch and the unit of the second measuring circuit configured for allowing or preventing the flow of a current induced by the chopped current in the second measuring circuit is configured for being controlled by the inverse of the control signal of the second switch of the second branch.

5. The device according to claim 1, wherein: the first measuring circuit comprises a first resistor and a second resistor, the terminal common to the two resistors being connected to the gate of the first transistor and of the second transistor of the first measuring circuit, and the second measuring circuit comprises a first resistor and a second resistor, the terminal common to the two resistors being connected to the gate of the first transistor and of the second transistor of the second measuring circuit.

6. The device according to claim 1, wherein a demagnetizing circuit is connected between the two output terminals of the secondary circuit of the associated transformer.

7. The device according to claim 6, in which a demagnetizing circuit comprises two Zener diodes mounted in series and in opposite directions.

Description

(1) Other features and advantages of the invention will appear more clearly on reading the following description, given as an illustrative and non-restrictive example, and the accompanying drawings in which:

(2) FIG. 1 represents a DC-DC converter circuit through which a chopped current flows including two transformers of a device for measuring the chopped current,

(3) FIG. 2 schematically represents two demagnetizing circuits and two measuring circuits of the device for measuring the chopped current according to a first embodiment,

(4) FIG. 3 schematically represents two demagnetizing circuits and two measuring circuits of the device for measuring the chopped current according to a second embodiment,

(5) FIG. 4 is a more detailed representation of the demagnetizing circuits and measuring circuits of the device for measuring the chopped current in FIG. 2 according to the first embodiment,

(6) FIG. 5 is a graph representing the temporal evolution of chopped currents in the primary circuits of two transformers respectively connected to a branch of the H-bridge structured converter,

(7) FIG. 6 is a first example of a timing diagram representing the temporal evolution of the chopped currents in FIG. 5, and the pulse signals of the H-bridge branch switches,

(8) FIG. 7 is a second example of a timing diagram representing the temporal evolution of chopped currents in the primary circuits of two transformers respectively connected to a branch of the H-bridge structured converter, and the pulse signals of the H-bridge branch switches, and

(9) FIG. 8 schematically represents an example of comparators used after measuring an output voltage proportional to the input chopped current.

(10) In these figures, identical elements bear the same references.

(11) The invention relates to a device 1 for measuring a chopped current, in particular flowing inside a DC-DC converter 3.

(12) Converter

(13) Referring to FIG. 1, the converter 3 represented has an H-bridge structure having a first branch B.sub.1 and a second branch B.sub.2.

(14) The first branch B.sub.1 comprises a first switch Mos.sub.1 and a second switch Mos.sub.2.

(15) The second branch B.sub.2 comprises a first switch Mos.sub.3 and a second switch Mos.sub.4.

(16) The switches Mos.sub.1 to Mos.sub.4 comprise, by way of a non-restrictive example, an N-type, field effect transistor known under the acronym MOSFET.

(17) When the first branch B.sub.1 is controlled, the first switch Mos.sub.1 is turned on when the second switch Mos.sub.1 is blocked, and conversely the second switch Mos.sub.1 is turned on when the first switch Mos.sub.1 is blocked.

(18) The same applies to controlling the second branch B.sub.2, the first switch Mos.sub.3 is turned on when the second switch Mos.sub.4 is blocked, and conversely the second switch Mos.sub.4 is turned on when the first switch Mos.sub.3 is blocked.

(19) The offset between the two branches B.sub.1 and B.sub.2 depends on the H-bridge control logic.

(20) Device for Measuring the Chopped Current

(21) Referring again to FIG. 1, the device 1 for measuring the chopped current comprises two transformers 10.sub.B1 and 10.sub.B2 with a transformation ratio of m.sub.i. The two transformers 10.sub.B1 and 10.sub.B2 are arranged respectively on a branch B.sub.1 or B.sub.2 of the converter 3.

(22) One transformer 10.sub.B1 or 10.sub.B2 includes a primary circuit 12 and a secondary circuit 14.

(23) The primary circuit 12 of a first transformer 10.sub.B1 is connected to the first switch Mos.sub.1 of the first branch B.sub.1 of the converter 3. The primary circuit 12 of the second transformer 10.sub.B2 is connected to the first switch Mos.sub.3 of the second branch B.sub.2 of the converter 3.

(24) The secondary circuit 14 of a transformer 10.sub.B1 or 10.sub.B2 comprises two output terminals 16 and 18.

(25) When a chopped current i.sub.c flows in the converter 3, it is split in the two branches B.sub.1 and B.sub.2, so that a first chopped current i.sub.Mos1 flows in the primary circuit 12 of the first transformer 10.sub.B1, and a second chopped current i.sub.Mos3 flows in the primary circuit 12 of the second transformer 10.sub.B2.

(26) When the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is closed, the chopped current i.sub.Mos1 or i.sub.Mos3 flowing in the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is non-zero, and the associated transformer 10.sub.B1 or 10.sub.B2 is magnetized.

(27) A demagnetization of a transformer 10.sub.B1 or 10.sub.B2 takes place when the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is open, the chopped current i.sub.Mos1 or i.sub.Mos3 being zero, i.e. when there is no current to be measured.

(28) And in addition, the device 1 can be used to measure the chopped current when the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is closed, the chopped current i.sub.Mos1 or i.sub.Mos3 flowing in the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 being non-zero.

(29) For this purpose, with reference to FIG. 2, the measuring device 1 further includes:

(30) two demagnetizing circuits 20.sub.B1, 20.sub.B2 respectively associated with a transformer 10.sub.B1 or 10.sub.B2, and

(31) two chopped current measuring circuits 22.sub.B1 and 22.sub.B2 respectively connected to the output terminals 16, 18 of the associated transformer 10.sub.B1 or 10.sub.B2.

(32) According to the described embodiment, the demagnetizing circuits 20.sub.B1, 20.sub.B2 are separate from the measuring circuits 22.sub.B1 and 22.sub.B2.

(33) Each demagnetizing circuit 20.sub.B1 and 20.sub.B2 is connected between the two output terminals 16 and 18 of the associated transformer 10.sub.B1 or 10.sub.B2.

(34) Each demagnetizing circuit 20.sub.B1, 20.sub.B2 enables the demagnetization of the associated transformer 10.sub.B1 or 10.sub.B2 through a flow of a current in the demagnetizing circuit 20.sub.B1 or 20.sub.B2.

(35) According to the embodiment illustrated in FIG. 2, a demagnetizing circuit 20.sub.B1 or 20.sub.B2 includes a first Zener diode 24 connected in series with a second Zener diode 26 between the output terminals 16 and 18. The Zener voltage is by way of an illustrative example of the order of 10 V.

(36) The first Zener diode 24 and the second Zener diode 26 are mounted in opposite directions. As an example, the first Zener diode 24 may be connected via its cathode to the output terminal 16 and the second Zener diode 26 may be connected via its cathode to the other output terminal 18. The two Zener diodes 24 and 26 are then connected with one another via the anodes thereof.

(37) Thus, the demagnetizing circuits 20.sub.B1, 20.sub.B2 are bidirectional, i.e. they enable demagnetization in both directions of flow of the magnetizing current, according to whether the average value of the chopped current is positive or negative.

(38) A first measuring circuit 22.sub.B1 is connected to the output terminals 16, 18 of the secondary circuit 14 of the first transformer 10.sub.B1 connected to the first branch B.sub.1 of the converter 3. The first measuring circuit 22.sub.B1 is connected in parallel with the first demagnetizing circuit 20.sub.B1.

(39) A second measuring circuit 22.sub.B2 is connected to the output terminals 16, 18 of the secondary circuit 14 of the second transformer 10.sub.B2 connected to the second branch B.sub.2 of the converter 3. The second measuring circuit 22.sub.B2 is connected in parallel with the second demagnetizing circuit 20.sub.B2. The second measuring circuit 22.sub.B2 is further connected to the first measuring circuit 22.sub.B1.

(40) The measuring circuits 22.sub.B1 and 22.sub.B2 respectively include at least one unit configured for: allowing the flow of a current i.sub.mes1; i.sub.mes2 induced by the chopped current, in the measuring circuit 22.sub.B1 or 22.sub.B2, when the primary circuit 12 of a transformer 10.sub.B1; 10.sub.B2 is closed; in this case the chopped current flowing in the primary circuit 12 is non-zero, either strictly positive or strictly negative, and preventing the flow of the demagnetizing current in the measuring circuit 22.sub.B1 or 22.sub.B2 when the primary circuit 12 of a transformer 10.sub.B1; 10.sub.B2 is open; in this case the chopped current flowing in the primary circuit 12 is zero.

(41) According to the embodiment described, the two measuring circuits 22.sub.B1 and 22.sub.B2 respectively include a unit configured for allowing or preventing the flow of a current induced by the chopped current in the associated measuring circuit 22.sub.B1 or 22.sub.B2, and comprising a first switch and a second switch. The unit of the first measuring circuit 22.sub.B1 includes a first switch K.sub.i1.sub._.sub.HS and a second switch K.sub.i1.sub.LS. The unit of the second measuring circuit 22.sub.B2 includes a first switch K.sub.i2.sub._.sub.HS and a second switch K.sub.i2.sub._.sub.LS.

(42) The first switches K.sub.i1.sub._.sub.HS and K.sub.i2.sub._.sub.HS are also called High Side switches.

(43) The second switches K.sub.i1.sub._.sub.LS and K.sub.i2.sub._.sub.LS are also called Low Side switches.

(44) The first and second switches K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 and the first and second switches K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are formed, according to the example described, of MOSFET field effect transistors.

(45) The first and second switches K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 in this example are connected in reverse. Similarly, the first and second switches K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are connected in reverse.

(46) Furthermore, with reference to FIGS. 3 and 4, the measuring circuits 22.sub.B1; 22.sub.B2 include at least one measuring resistor R.sub.mes or R.sub.mes connected via a first terminal to the ground.

(47) The first switch K.sub.i1.sub._.sub.HS; K.sub.i2.sub._.sub.HS of a measuring circuit 22.sub.B1; 22.sub.B2 comprises a terminal connected to a second terminal of the measuring resistor R.sub.mes or R.sub.mes, the first terminal of the measuring resistor R.sub.mes or R.sub.mes being connected to the ground. The second K.sub.i1.sub.LS switch; K.sub.i2.sub._.sub.LS of a measuring circuit 22.sub.B1; 22.sub.B2 in turn comprises a terminal connected to the ground.

(48) More specifically, with regard to the first measuring circuit 22.sub.B1:

(49) the drain of the first transistor K.sub.i1.sub._.sub.HS is connected to the first output terminal 16 of the first transformer 10.sub.B1 connected to the first branch B.sub.1 of the converter 3.

(50) the source of the first transistor K.sub.i1.sub._.sub.HS is connected via a terminal to the second terminal of the measuring resistor R.sub.mes (FIG. 2) or R.sub.mes (FIG. 3), the first terminal of the measuring resistor R.sub.mes (FIG. 2) or R.sub.mes (FIG. 3), being connected to the ground, and

(51) the gate of the first transistor K.sub.i1.sub._.sub.HS is connected to the gate of the second transistor K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1,

(52) the drain of the second transistor K.sub.i1.sub._.sub.LS is connected to the second output terminal 18 of the first transformer 10.sub.B1, and

(53) the source of the second transistor K.sub.i1.sub._.sub.LS is connected to the ground.

(54) With regard to the second measuring circuit 22.sub.B2:

(55) the drain of the first transistor K.sub.i2.sub._.sub.HS is connected to the first output terminal 16 of the second transformer 10.sub.B2 connected to the second branch B.sub.2 of the converter 3.

(56) the source of the first transistor K.sub.i2.sub._.sub.HS is connected via a terminal to the second terminal of the measuring resistor R.sub.mes (FIG. 2) or R.sub.mes (FIG. 3), the first terminal of the measuring resistor R.sub.mes (FIG. 2) or R.sub.mes (FIG. 3), being connected to the ground, and

(57) the gate of the first transistor K.sub.i2.sub._.sub.HS is connected to the gate of the second transistor K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2,

(58) the drain of the second transistor K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 is connected to the second output terminal 18 of the second transformer 10.sub.B2,

(59) the source of the second transistor K.sub.i2.sub._.sub.LS is connected to the ground.

(60) In addition, the first transistors K.sub.i1.sub._.sub.HS and K.sub.i2.sub._.sub.HS must be such that the voltage between the gate and the source is greater than the threshold voltage of the transistor for activating the transistor.

(61) The transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 and the transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are capable of being controlled according to the H-bridge control logic. Thus, when the primary circuit 12 of a transformer 10.sub.B1 or 10.sub.B2 is closed, the chopped current in the primary circuit 12 of the transformer 10.sub.B1 or 10.sub.B2 is non-zero, and the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS or K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the associated measuring circuit 22.sub.B1 or 22.sub.B2 are in the on state. When the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is open, the chopped current is zero, and the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS or K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the associated measuring circuit 22.sub.B1 or 22.sub.B2 are in the blocked state.

(62) Thus, when the primary circuit 12 of a transformer 10.sub.B1 or 10.sub.B2 is closed, the chopped current i.sub.Mos1 i.sub.Mos3 in the primary circuit 12 of a transformer 10.sub.B1 or 10.sub.B2 being non-zero, and there is therefore a current to be measured, the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS or K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the associated measuring circuit 22.sub.B1 or 22.sub.B2 must be controlled in the on state.

(63) And, the demagnetization of a transformer 10.sub.B1 or 10.sub.B2 may be performed when the primary circuit 12 of the transformer 10.sub.B1 or 10.sub.B2 is open, the chopped current i.sub.Mos1 or i.sub.Mos3 being zero and there is no current to be measured, by blocking the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS or K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the associated measuring circuit 22.sub.B1 or 22.sub.B2, so as to disconnect the demagnetizing circuit 20.sub.B1 or 20.sub.B2 from the measuring resistor Rmes or Rmes during the demagnetization of the corresponding transformer 10.sub.B1 or 10.sub.B2.

(64) When the primary circuit 12 of the first transformer 10.sub.B1 or of the second transformer 10.sub.B2 is closed, a chopped current i.sub.Mos1 or i.sub.Mos3 flows in the primary circuit 12 of the associated transformer 10.sub.B1 or 10.sub.B2, and a current is induced in the secondary circuit 14 of the associated transformer 10.sub.B1 or 10.sub.B2. If the transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1, respectively if the transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS, of the second measuring circuit 22.sub.B2, are turned on, a current i.sub.mes1, respectively i.sub.mes2, flows in the associated first or second measuring circuit 22.sub.B1 or 22.sub.B2.

(65) According to a first embodiment illustrated in FIG. 2, the two measuring circuits 22.sub.B1 and 22.sub.B2 further comprise a common measuring resistor R.sub.mes connected firstly via a first terminal to the ground and via a second terminal to the source of the first two transistors K.sub.i1.sub._.sub.HS and K.sub.i2.sub._.sub.HS. The source of the first transistor K.sub.i2.sub._.sub.HS of the unit capable of allowing or preventing the flow of a current induced by the chopped current in the first measuring circuit 22.sub.B1, is therefore connected to the source of the first transistor K.sub.i2.sub._.sub.HS of the unit capable of allowing or preventing the flow of a current induced by the chopped current in the second measuring circuit 22.sub.B2.

(66) Thus, the currents i.sub.mes1 and i.sub.mes2 flowing respectively in the first measuring circuit 22.sub.B1 and in the second measuring circuit 22.sub.B2 are added together, so that the common measuring resistor R.sub.mes is traversed by a current i.sub.mes, corresponding to the sum of the currents i.sub.mes1 and i.sub.mes2.

(67) According to the first embodiment, the chopped current measurement is done by measuring the voltage v.sub.mes at the terminals of the measuring resistor R.sub.mes. Indeed, this voltage v.sub.mes is an image of the chopped current i.sub.e, according to formula (1):

(68) $\begin{array}{cc}{v}_{\mathrm{mes}}=\frac{R_{\mathrm{mes}}}{m_i}{i}_e& \left(1\right)\end{array}$
where R.sub.mes=measuring resistance common to the two measuring circuits 22.sub.B1 and 22.sub.B2,
v.sub.mes=voltage measured at the terminals of the measuring resistor R.sub.mes,
m.sub.i=transformation ratio of a transformer 10.sub.B1 or 10.sub.B2.

(69) Thus a direct measurement is obtained at the terminals of the measuring resistor R.sub.mes connected to the ground.

(70) On the other hand, during the phases of demagnetization of a transformer 10.sub.B1 or 10.sub.B2, the transistors of the associated measuring circuit 22.sub.B1 or 22.sub.B2 in the blocked state enable the measuring resistor R.sub.mes to be decoupled from the demagnetizing circuit 20.sub.B1 or 20.sub.B2. Thus the measurement of the voltage V.sub.mes is not affected.

(71) As a variant, according to a second embodiment illustrated in FIG. 3, the two measuring circuits 22.sub.B1 and 22.sub.B2 each comprise a separate measuring resistor R.sub.mes. The two measuring resistors R.sub.mes are substantially equal in value according to the example described.

(72) According to the second embodiment, with regard to the first measuring circuit 22.sub.B1, the measuring resistor R.sub.mes is connected between the two sources of the first transistor K.sub.i1.sub._.sub.HS, and of the second transistor K.sub.i1.sub._.sub.LS. In addition, the source of the second transistor K.sub.i1.sub._.sub.LS is connected to the ground.

(73) With regard to the second measuring circuit 22.sub.B2, the measuring resistor R.sub.mes2 is connected between the two sources of the first transistor K.sub.i2.sub._.sub.HS, and of the second transistor K.sub.i2.sub._.sub.LS. In addition, the source of the second transistor K.sub.i2.sub._.sub.LS is connected to the ground.

(74) Thus, the two measuring circuits 22.sub.B1; 22.sub.B2 respectively include a measuring resistor R.sub.mes connected via a terminal to the ground. The measuring resistor R.sub.mes of the first measuring circuit 22.sub.B1 is connected via one of the terminals thereof to the source of the first transistor K.sub.i1.sub._.sub.HS, and via the other of the terminals thereof to the source of the second transistor K.sub.i2.sub._.sub.LS of the first measuring circuit 22.sub.B1. The measuring resistor R.sub.mes of the second measuring circuit 22.sub.B2 is connected to the source of the first transistor K.sub.i2.sub._.sub.HS via one of the terminals thereof, and via the other of the terminals thereof to the source of the second transistor K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2.

(75) Whether it is the first embodiment in FIG. 2, or the second embodiment in FIG. 3, the common measuring resistor R.sub.mes or each separate measuring resistor R.sub.mes of the two measuring circuits and 22.sub.B1 and 22.sub.B2 is connected to the ground. This arrangement provides better immunity with respect to noise.

(76) According to the second embodiment, the first measuring circuit 22.sub.B1 includes a first output resistor R connected to the source of the first transistor K.sub.i1.sub._.sub.HS and to the measuring resistor R.sub.mes.

(77) Similarly, the second measuring circuit 22.sub.B2 includes a second output resistor R connected to the source of the first transistor K.sub.i2.sub._.sub.HS and to the measuring resistor R.sub.mes. The voltage V.sub.mes can be measured at the common node between the two output resistors R.

(78) In this case, these are the voltages v.sub.mes1 and v.sub.mes2 respectively at the terminals of the measuring resistors R.sub.mes of the two measuring circuits 22.sub.B1 and 22.sub.B2 which are added together (see formula (2)):

(79) $\begin{array}{cc}{v}_{\mathrm{mes}}=\frac{v_{\mathrm{mes}1}+v_{\mathrm{mes}2}}{2}& \left(2\right)\end{array}$

(80) According to this second embodiment, the measurement of the chopped current is done by measuring the voltage v.sub.mes at the common node between the two output resistors R. Indeed, this voltage v.sub.mes is an image of the chopped current i.sub.e, according to formula (3):

(81) $\begin{array}{cc}{v}_{\mathrm{mes}}=\frac{1}{2}\frac{R_{\mathrm{mes}}^{}}{m_i}{i}_e& \left(3\right)\end{array}$
where R.sub.mes=measuring resistance of each measuring circuit 22.sub.B1 and 22.sub.B2,
v.sub.mes=voltage measured at the common node between the two output resistors R,
m.sub.i=transformation ratio of a transformer 10.sub.B1 or 10.sub.B2.

(82) In a similar way to the first embodiment, these measuring resistors R.sub.mes are decoupled from the associated demagnetizing circuit 20.sub.B1 or 20.sub.B2 during the demagnetization period of the associated transformer 10.sub.B1 or 10.sub.B2.

(83) Moreover, if the value of the measuring resistor of each measuring circuit 22.sub.B1 and 22.sub.B2 is substantially equal to the value of the measuring resistor R.sub.mes common to the two measuring circuits 22.sub.B1 and 22.sub.B2, a ratio of is found in the transfer function.

(84) In this case, if it is desired to work with the same gain for the two embodiments, the value of the resistor R.sub.mes of each circuit 22.sub.B1 and 22.sub.B2 must be chosen so that it is of the order of twice the value of the common measuring resistor R.sub.mes according to the first embodiment, (see formula (4)):
R.sub.mes=2R.sub.mes(4)

(85) The first embodiment with the measuring resistor R.sub.mes common to the two measuring circuits 22.sub.B1 and 22.sub.B2 provides measuring accuracy, since there are less resistors.

(86) Furthermore, the diagram in FIG. 4 presents details of the measuring circuit 22.sub.B1 or 22.sub.B2 according to the first embodiment illustrated in FIG. 2. Of course, these additions or details also apply to the second embodiment illustrated in FIG. 3.

(87) In the diagram in FIG. 4, it is seen that the first measuring circuit 22.sub.B1 also comprises a first resistor R.sub.11 and a second resistor R.sub.21 connected via a terminal common to the gates of the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the measuring circuit 22.sub.B1, and secondly to a third switch K.sub.i1. The third switch K.sub.i1 of the first measuring circuit 22.sub.B1 is controlled by the control signal K.sub.2 which also controls the second switch Mos.sub.2 of the first branch B.sub.1.

(88) Similarly, the second measuring circuit 22.sub.B2 also comprises a first resistor R.sub.12 and a second resistor R.sub.22, connected via a common node to the gates of the two transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the measuring circuit 22.sub.B2, and secondly to a third switch K.sub.i2. The third switch K.sub.i2 of the second measuring circuit 22.sub.B2 is controlled by the control signal K.sub.4 which also controls the second switch Mos.sub.4 of the second branch B.sub.2.

(89) The first resistor R.sub.11 or R.sub.12 is connected to a potential e.g. of 15 V and the second resistor R.sub.21 or R.sub.22 is connected to the ground.

(90) The first and second resistors R.sub.11 and R.sub.21 or R.sub.12 and R.sub.22 ensure the correct switching of the first transistor K.sub.i1.sub._.sub.HS or K.sub.i2.sub._.sub.HS to the on state. More precisely, when the third switch K.sub.i1 or K.sub.i2 is blocked, the voltage V.sub.G1, respectively V.sub.G2, at the gates of the transistors, is positive, e.g. of the order of 10 V. The value of 10 V enables obtaining the condition according to which the voltage between the source and the gate of a first transistor K.sub.i1.sub._.sub.HS or K.sub.i2.sub._.sub.HS is greater than the threshold voltage of the transistor.

(91) Otherwise, this voltage dependent on the values of the two resistors R.sub.11 and R.sub.21, respectively R.sub.12 and R.sub.22, is zero.

(92) With reference to FIGS. 5 to 7, an example of control logic is described for the device 1 for measuring the chopped current according to one or other of the previously described embodiments.

(93) Operation of the Measuring Device

(94) Temporal Evolution of the Chopped Current

(95) FIG. 5 represents an example of temporal evolution of the chopped currents i.sub.Mos1 or i.sub.Mos3 flowing in the primary circuits 12 of the transformers 10.sub.B1 et 10.sub.B2. The non-restrictive example illustrated in FIG. 5 has a high duty cycle.

(96) On the graph in FIG. 5:

(97) a first curve with round dots, represents the temporal evolution of the chopped current i.sub.Mos1 in the primary circuit 12 of the first transformer 10.sub.B1 connected to the first branch B.sub.1 of the converter 3, and

(98) a second curve with squares, represents the temporal evolution of the chopped current i.sub.Mos3 in the primary circuit 12 of the second transformer 10.sub.B2 connected to the second branch B.sub.2 of the converter 3.

(99) The chopped current i.sub.Mos1 or i.sub.Mos3 flowing in the primary circuit 12 of a transformer 10.sub.B1 or 10.sub.B2 is periodic and is capable of taking zero values and non-zero values. When the primary circuit 12 of a transformer 10.sub.B1 or 10.sub.B2 is open, the chopped current i.sub.Mos1 or i.sub.Mos3 flowing in the primary circuit 12 of the transformer 10.sub.B1 or 10.sub.B2 is zero, and the corresponding transformer 10.sub.B1 or 10.sub.B2 is demagnetized.

(100) The offset between the chopped current i.sub.Mos1 flowing in the primary circuit 12 of the first transformer 10.sub.B1 and the chopped current i.sub.Mos3 flowing in the primary circuit 12 of the second transformer 10.sub.B2 depends on the offset between the branches B.sub.1 and B.sub.2.

(101) Control of the First Measuring Circuit 22.sub.B1

(102) As mentioned previously, the first switch Mos.sub.1 of the first branch B.sub.1 is turned on when the second switch Mos.sub.1 of the first branch B.sub.1 is blocked, and conversely, the first switch Mos.sub.1 is blocked when the second switch Mos.sub.1 is turned on. In addition, according to the example of control logic illustrated in FIG. 6 or 7, a dead time t.sub.m is provided between two switchings.

(103) The first transistor K.sub.i1.sub._.sub.HS and the second transistor K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 are controlled jointly.

(104) The first transistor K.sub.i1.sub._.sub.HS and the second transistor K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 are turned on when the second switch Mos.sub.1 of the first branch B.sub.1 is blocked.

(105) In other words, the unit K.sub.i1.sub._.sub.HS, K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 configured for allowing or preventing the flow of a current induced by the chopped current i.sub.Mos1 in the first measuring circuit 22.sub.B1, is configured for being controlled by the inverse of the control signal, termed K.sub.2 of the second switch Mos.sub.1 of the first branch B.sub.1. It is therefore the inverse of the control signal of the second switch Mos.sub.2, termed K.sub.2, which controls the state of the transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first control circuit 22.sub.B1 (see FIG. 6 or 7).

(106) Thus, when the second switch Mos.sub.1 of the first branch B.sub.1 is blocked, the primary circuit 12 of the first transformer 10.sub.B1 is closed, the chopped current i.sub.Mos1 flowing in the primary circuit 12 of the first transformer 10.sub.B1 is non-zero and induces a current flowing in the secondary circuit 14 of the first transformer 10.sub.B1. Since the two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 are turned on, a current i.sub.mes1 can freely flow in the measuring circuit 22.sub.B1 associated with the first transformer 10.sub.B1. On the other hand, no current flows in the demagnetizing circuit 20.sub.B1 because the second Zener diode 26 is not turned on, given that the voltage between the terminals 18 and 16 is variable and is not equal to the Zener voltage thereof.

(107) When the second switch Mos.sub.1 of the first branch B.sub.1 is turned on and the first switch Mos.sub.1 is blocked, the primary circuit 12 of the first transformer 10.sub.B1 is open, the chopped current i.sub.Mos1 takes a zero value. The two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.8i change to the blocked state, no longer allowing the flow of a current in the measuring circuit 22.sub.B1.

(108) During this period, a demagnetizing current flows in the demagnetizing circuit 20.sub.B1, the potential difference between the terminals 18 and 16 of the secondary circuit 14 then being imposed by the Zener voltage of the second Zener diode 26 according to the example in FIGS. 2 and 3. The two transistors K.sub.i1.sub._.sub.HS and K.sub.i1.sub._.sub.LS of the first measuring circuit 22.sub.B1 in the blocked state, do not allow the flow of the demagnetizing current in the measuring circuit 22.sub.B1.

(109) As long as the chopped current i.sub.Mos1 is zero, the demagnetizing current decreases flowing in the demagnetizing circuit 20.sub.B1.

(110) Control of the Second Measuring Circuit 22.sub.B2

(111) Similarly, the first switch Mos.sub.3 of the second branch B.sub.2 is turned on when the second switch Mos.sub.4 of the second branch B.sub.2 is blocked, and conversely, the first switch Mos.sub.3 is blocked when the second switch Mos.sub.4 is turned on. According to the example of control logic illustrated in FIG. 6 or 7, a dead time t.sub.m is also provided between two switchings.

(112) The first transistor K.sub.i2.sub._.sub.HS and the second transistor K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are controlled jointly.

(113) The first transistor K.sub.i2.sub._.sub.HS and the second transistor K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are turned on when the second switch Mos.sub.4 of the second branch B.sub.2 is blocked.

(114) The unit K.sub.i2.sub._.sub.HS, K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 configured for allowing or preventing the flow of a current induced by the chopped current i.sub.Mos3 in the second measuring circuit 22.sub.B2 is configured for being controlled by the inverse of the control signal, termed K.sub.4 of the second switch Mos.sub.4 of the second branch B.sub.2.

(115) It is therefore the inverse of the control signal of the second switch Mos.sub.4, termed K.sub.4, which controls the state of the transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 (see FIG. 6 or 7).

(116) Thus, when the second switch Mos.sub.4 of the second branch B.sub.2 is blocked, the primary circuit 12 of the second transformer 10.sub.B2 is closed, the chopped current i.sub.Mos3 flowing in the primary circuit 12 of the second transformer 10.sub.B2 is non-zero and induces a current flowing in the secondary circuit 14 of the second transformer 10.sub.B2. Since the two transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 are turned on, a current i.sub.mes2 can freely flow in the measuring circuit 22.sub.B2 associated with the second transformer 10.sub.B2. On the other hand, no current flows in the demagnetizing circuit 20.sub.B2 because the second Zener diode 26 is not turned on, given that the voltage between the terminals 18 and 16 is variable and is not equal to the Zener voltage thereof.

(117) As soon as the second switch Mos.sub.4 of the second branch B.sub.2 is turned on and the first switch Mos.sub.3 is blocked, the primary circuit 12 of the second transformer 10.sub.B2 is open, the chopped current i.sub.Mos3 takes a zero value. The two transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 change to the blocked state, no longer allowing the flow of a current in the measuring circuit 22.sub.B2.

(118) However, during this period, a demagnetizing current flows in the demagnetizing circuit 20.sub.B2, according to the example illustrated in FIGS. 2 and 3, the potential difference between the terminals 18 and 16 of the secondary circuit 14 then being imposed by the Zener voltage of the second Zener diode 26. As long as the chopped current i.sub.Mos3 is zero, the demagnetizing current decreases flowing in the demagnetizing circuit 20.sub.B2. The two transistors K.sub.i2.sub._.sub.HS and K.sub.i2.sub._.sub.LS of the second measuring circuit 22.sub.B2 in the blocked state, do not allow the flow of the demagnetizing current in the measuring circuit 22.sub.B2.

(119) Thus over a period T of operation, there is always a half period when the chopped current is zero, so that the demagnetization time is constant and ensures the demagnetization of the transformers 10.sub.B1 and 10.sub.B2. Demagnetization is therefore independent of the duty cycle.

(120) Thus, whatever the direction of the demagnetizing current, when the primary circuit 12 of the transformer 10.sub.B1 or 10.sub.B2 is open, the chopped current i.sub.Mos1 or i.sub.Mos3 takes the value zero, the device 1 enables the demagnetization of the associated transformer 10.sub.B1 or 10.sub.B2. In other words, given that the direction of the magnetizing current depends on the average value of the chopped current i.sub.Mos1 or i.sub.Mos3, whatever the average value of the chopped current i.sub.Mos1 or i.sub.Mos3, the device 1 enables the demagnetization of the associated transformer 10.sub.B1 or 10.sub.B2.

(121) With regard to the measurement of the chopped current, this is accomplished by measuring the voltage v.sub.mes at the terminals of the measuring resistor R.sub.mes according to the first embodiment illustrated in FIG. 2 or 4, or by measuring the voltage v.sub.mes at the common node between the output resistors R of the two measuring circuits 22.sub.B1 and 22.sub.B2 according to the second embodiment illustrated in FIG. 3, the voltage v.sub.mes being proportional to the chopped current i.sub.e, according to formula (1) for the first embodiment or according to formula (3) for the second embodiment.

(122) Referring to FIG. 8, this measurement of the voltage v.sub.mes measured, for example, at the terminals of the measuring resistor R.sub.mes, provides information on the average value of the input current i.sub.e absorbed by the converter 3, e.g. by means of a double RC filter for obtaining the voltage V.sub.IE corresponding to the average value of the voltage V.sub.mes.

(123) In addition, it may be desired to monitor the peak value of the instantaneous current i.sub.e. Two comparators may be provided for this purpose. The first comparator being, for example, provided for limiting the current, and the second comparator for fault detection.