WO2014006313A1 - Electrical circuit for the excitation of at least one electromagnet - Google Patents

Abstract

Electrical circuit (1) for the excitation of at least one electromagnet (4), comprising: - an inductor (4) forming the electro magnet, said inductor (4) extending between a first terminal (6) and a second terminal (7), - a first electrical energy storage unit (2), - a second electrical energy storage unit (3), and - a switching system (5) interposed between the inductor (4) and the electrical energy storage units (2, 3), the switching system (5) being configured so as to: - allow positive electrical current (i₁) issuing from the first electrical energy storage unit (2) to flow from the second (7) to the first (6) terminal of the inductor (4), in such a way as to perform a first charging of the inductor (4), - allow positive electrical current (i₁) flowing from the second (7) to the first (6) terminal of the inductor (4) to flow in the second electrical energy storage unit (3) and - allow positive electrical current (i₂) issuing from the second electrical energy storage unit (3) to flow from the first (6) to the second (7) terminal of the inductor (4), in such a way as to perform a second charging of the inductor (4).

Description

 Electrical circuit for energizing at least one electromagnet

 The present invention relates to an electric circuit for energizing at least one electromagnet. The excitation of the electromagnet makes it possible to create a magnetic field that can be used to move an element made of a ferromagnetic material. When the circuit is integrated into a fuel injector of a motor vehicle, the element made of a ferro-magnetic material is for example a needle moving in a body of the injector between a position in which it allows the passage of the fuel to a combustion chamber of the engine of the vehicle and a position in which it prevents the passage of fuel, the displacement of this element being effected under the effect of the magnetic field created by the electromagnet.

 Other applications are possible. In the context of use in a vehicle comprising a heat engine, the invention may for example be applied to:

 the control of a solenoid valve, for example a canister bleed solenoid valve,

the control of a DC motor of an electric actuator of the intake or exhaust circuit of the heat engine, for example the control of a motor actuating an EGR valve or of any other valve of the intake circuit or exhaust, or

 the control of an electric supercharging motor of the engine of the vehicle.

 It is known, in this application for fuel injection, to generate a large voltage across the inductance forming the electromagnet by means of an overvoltage generating stage by raising the available voltage, this overvoltage being also called "boost voltage". This generator stage comprises in known manner an inductor, a capacitor and a diode, the inductor being charged by the available voltage and transferring the energy from this charge to the capacitor whose discharge provides the overvoltage.

To reduce the size and cost associated with the use of the surge generator stage, it is known from US Pat. Nos. 5,717,562 and 5,936,827 to use the inductance forming an electromagnet during generation of the surge. For this purpose, the inductance is charged from the available voltage with a sufficiently low current not to generate a magnetic field that can move the needle and thus open the injector. The energy accumulated in the inductance is then transferred to the capacitor whose subsequent discharge leads to the application of an overvoltage across the inductance which is then traversed by a current sufficient to generate a magnetic field moving the needle and opening the injector.

 Such a solution is restrictive because it requires to ensure that the current flowing in the inductor to subsequently charge the capacitor remains low to avoid an undesired fuel injection.

 Also known from FR 2 772 972 a control device of an electromagnet for circulating in the electromagnet a current of the same direction from two different sources of electrical energy.

 There is a need to provide an electrical circuit for exciting an electromagnet that is relatively simple to use, efficient, inexpensive and compact.

 The invention aims to meet this need and it succeeds, according to one of its aspects, with the aid of an electrical circuit for the excitation of at least one electromagnet, comprising: an inductor forming Γ electromagnet, said inductor extending between a first terminal and a second terminal,

 a first electrical energy storage unit,

 a second electrical energy storage unit, and

 a switching system interposed between the inductor and the electric energy storage units, the switching system being configured to:

 allow positive electric current from the first electrical energy storage unit to flow from the second to the first inductance terminal, so as to perform a first charge of the inductor,

 allowing positive electric current flowing from the second to the first inductance terminal to flow into the second electrical energy storage unit, and

 - Allow positive electric current from the second power storage unit to flow from the first to the second terminal of the inductor, so as to perform a second load of the inductor.

 According to the invention, during the first charging of the inductance forming Γ electromagnet, the inductor is charged in the opposite way to the way it is charged during the second charge.

Thus, the first charge of the inductor generates a magnetic field different from that generated during the second charging of the inductor. In this way, we make sure that the effect sought during the second charge of the inductor will not be reached during the first charge of the inductor.

 When applying to move a needle from a fuel injector, the movement of the needle may occur only during the second charge. The needle is for example by default in a position in abutment against a bearing surface and the magnetic field induced in the inductor during the first load exerts a force on the needle in the direction of the bearing surface. The first charge does not change the

configuration of the injector that remains closed. During the second charge, the magnetic field induced in the inductor can instead exert on the needle a force away from the bearing surface and thus allowing a fuel passage, which causes the opening of the injector.

 The inductance forming P electromagnet is for example a solenoid, having in particular an inductance value of between 1 mH and 10 mH.

 The switching system may comprise an H-bridge. This H-bridge may make it possible to reverse the direction of the positive current in the inductance forming the electromagnet.

 The H bridge may comprise two arms each extending between the same input terminal and the same output terminal, each arm comprising two switches between which a midpoint is connected to a respective terminal of the inductor.

 Each arm may comprise two controllable bidirectional switches or two controllable unidirectional switches. Each switch comprises for example a field effect transistor, bipolar, or IGBT type.

 Each terminal of the inductor can be directly connected to a midpoint of an arm. Alternatively, at least one intermediate component, for example a resistor, may be interposed between a terminal of the inductor and a midpoint of an arm.

 The switching system may comprise at least a first switch disposed between the first electrical energy storage unit and the input terminal of the H bridge. This first switch is for example unidirectional and may be controllable or not.

 The switching system may comprise at least one second switch disposed between the second electrical energy storage unit and the input terminal of the H-bridge.

 This second switch is for example bidirectional and can be controllable or not.

In particular for an application for a vehicle fuel injector, the first electrical energy storage unit may be a battery. In this case, the second unit Electrical energy storage can be a capacitor. The capacitor has for example a capacity of the order of one μΡ. The second charge of the inductor can then be obtained by discharging the capacitor forming the second electrical energy storage unit.

 The first electrical energy storage unit can apply across the inductor during the first charge thereof a voltage of the order of 12 V or 14 V, the first storage unit of electrical energy being in particular the battery supplying the on-board network in the case of an application to a motor vehicle.

 The second electrical energy storage unit can apply across the inductor during the second load thereof a voltage between 50 V and 100 V, being in particular of the order of 80 V.

 Another object of the invention is, according to another of its aspects, a method of exciting at least one electromagnet using an electric circuit comprising, besides said electromagnet formed by an inductance extending between a first and a second terminal, a first electrical energy storage unit, a second electrical energy storage unit, and a switching system interposed between the electrical energy storage units and the inductor,

process in which

 the switching system is controlled so that a positive electric current supplied by the first electric energy storage unit flows from the second terminal to the first terminal of the inductor, so as to make a first load of said inductor,

 the switching system is controlled so that a positive electric current flowing from the second terminal to the first terminal of the inductor feeds the second electric energy storage unit, so as to transfer to it the energy accumulated in inductance, and

 the switching system is controlled so that a positive electric current supplied by the second electric energy storage unit flows from the first terminal to the second terminal of the inductor so as to effect a second charge of the inductance.

As mentioned above, the first charge of the inductor can allow the subsequent charging of the second electric power storage unit, so that the energy subsequently accumulated in the second electric power storage unit is transferred to the inductance during the second charging thereof. The above method makes it possible not to induce the same magnetic field when the inductor is powered by the first electric energy storage unit for the subsequent charging of the second electric storage unit and when using the The inductor is powered by the second electrical energy storage unit. Thus, in the case where the magnetic field induced when the inductor is powered by the second electrical energy storage unit serves to move an element such as a needle, the supply of the inductor by the first storage unit electrical energy can subsequently charge the second power storage unit without moving this element.

 The voltage applied to the inductor by the first electrical energy storage unit during the first charging of the inductor may be lower than the voltage applied to the inductance by the second electrical energy storage unit during the second charge of the inductor, being in particular of the order of 12 or 14 V respectively and of the order of 80 V.

 All or some of the above characteristics of the application to the excitation method, in particular with a first electrical energy storage unit being a battery and a second electrical energy storage unit being a capacitor, in which case the second Inductance load is obtained by discharging the capacitor.

 The invention will be better understood on reading the following description of a nonlimiting example of implementation thereof and on examining the appended drawing in which:

 FIG. 1 schematically represents an example of an electrical circuit according to an exemplary implementation of the invention, and

 Figures 2 to 4 show the electric circuit of Figure 1 at different stages for the excitation of Γ electromagnet.

 The example described relates to an electric circuit 1 for energizing an electromagnet for fuel injection in a motor vehicle. This example is not, however, limiting, as explained below.

The circuit 1 is embedded on the vehicle and the excitation of the electromagnet can create a magnetic field moving a needle to control the injection of fuel into a combustion chamber of the engine of the vehicle. The invention is however not limited to this application. As shown in FIG. 1, the circuit 1 comprises a first electrical energy storage unit 2, a second electrical energy storage unit 3, an inductance 4 forming an electromagnet, and a switching system 5. The first electrical energy storage unit 2 is in the example considered a battery supplying the on-board network of the vehicle while the second storage unit of electrical energy is a

power capacitor.

 In this example, the inductor 4 is a solenoid having a first terminal 6 and a second terminal 7.

 As can be seen in FIG. 1, the switching system 5 may comprise an H-bridge formed by two arms 8 which extend in the example described between an input terminal 9 of the H-bridge and a terminal of exit 10 which is here the mass.

 Each arm 8 comprises in the example described two electronic switches 11 and a current measuring member 12. Each electronic switch is for example a transistor such as a field effect transistor or an IGBT type transistor.

 Between the two electronic switches 10 is a midpoint 13. The midpoint 13 of an arm 8, called "first arm" thereafter, is connected to the first terminal 6 of the solenoid 4 while the midpoint 13 of the Another arm 8, called "second arm" thereafter, is connected to the second terminal 7 of the solenoid 4.

 For the sake of clarity of the description, the electronic switches 11 of the example of Figure 1 are designated respectively by SI, S2, S3 and S4, SI corresponding to the electronic switch 10 at the top of the first arm 8, S2 corresponding at the electronic switch 10 at the bottom of the first arm 8, S3 corresponding to the electronic switch 10 at the top of the second arm 8 and S4 corresponding to the electronic switch 10 at the bottom of the second arm 8.

 As shown in FIG. 1, the switching system 5 also comprises in the example considered a first switch 15 interposed between the input terminal 9 of the H-bridge and the positive terminal of the first electrical energy storage unit 2 and a second switch 16 interposed between the input terminal 9 of the H-bridge and the positive terminal of the second electrical energy storage unit 3.

In the example considered, the first switch 15 is non-controllable. It is also in this example unidirectional, being a diode. Still in this example, the second switch 16 is controllable. It can be bidirectional, being in particular a transistor. A control example of the switching system 5 is now described with reference to FIGS. 2 to 4 when it is desired to move the needle of the injector to inject fuel into a combustion chamber of the heat engine.

 The switching system 5 is first of all controlled so as to charge the solenoid 4 from the first electrical energy storage unit 2, as shown in FIG. 2. The switches S 2 and S 3 are thus controlled so that that the latter are passing so that the positive current ii provided by the first electrical energy storage unit 2 flows from the second terminal 7 to the first terminal 6 of the solenoid 4. The switch 16 is at this stage controlled to be open , so that only the first electrical energy storage unit 2 can feed the solenoid 4.

This circulation of the positive current ii in the solenoid 4 induces a magnetic field B _l .

This magnetic field exerts for example a force on the needle of the injector which does not allow the displacement of this needle, for example because said force tends to move the needle beyond a position in which it is already in abutment. The current ii flowing in the solenoid can be measured in the measuring member 12 of the first arm 8. The solenoid 4 is thus magnetized.

 The switching system 5 is then controlled, as shown in FIG. 3, so that the energy previously accumulated in the solenoid is transferred to the capacitor 3. The switches S2 and S3 are then open while the switches S1 and S4 are open. are controlled to be in the on state, just like the switch 16. Due to this configuration of the switching system 5 and the choice of a diode to make the first switch 15, the positive current ii which circulated from the second terminal 7 to the first terminal 6 of the solenoid circulates in the capacitor 3, so as to load the latter. The current ii flowing in the solenoid can be measured in the measuring member 12 of the second arm 8. No current flows at this stage to the first electrical energy storage unit 2. The energy of the solenoid 4 is thus transferred. to the capacitor 3.

Next, as shown in FIG. 4, the switching system 5 is controlled so that a positive current i ₂ supplied by the second previously loaded electrical energy storage unit 3 flows from the first terminal 6 to the second terminal 7 of the solenoid. For this purpose, the switches S1, S4 and the switch 16 are on while the switches S2 and S3 are open. The current i ₂ flowing in the solenoid can be measured in the measuring member 12 of the second arm 8 The voltage applied by the second electric energy storage unit 3 to the terminals of the solenoid 4 is for example then of the order of 80 V. This power supply of the solenoid 4 by the second electrical energy storage unit 3 induces a magnetic field B ₂ opposite to that of the field B ₁ above. A force can then be exerted on the needle of the injector and move it into a position in which fuel is injected into the combustion chamber of the engine of the vehicle.

 The invention is not limited to the example of application to the fuel injection which has just been described.

 In the context of use in a vehicle comprising a heat engine, the invention may for example be applied to:

 the control of a solenoid valve, for example a canister bleed solenoid valve,

the control of a DC motor of an electric actuator of the intake or exhaust circuit of the heat engine, for example the control of a motor actuating an EGR valve or of any other valve of the intake circuit or exhaust, or

 the control of an electric supercharging motor of the engine of the vehicle.

 The expression "comprising a" shall be understood as synonymous with the expression "including at least one" unless the contrary is specified.

Claims

claims

 An electric circuit (1) for energizing at least one electromagnet (4), comprising: an inductor (4) forming the electromagnet, said inductor (4) extending between a first terminal ( 6) and a second terminal (7),

 a first electrical energy storage unit (2),

 a second electrical energy storage unit (3), and

 a switching system (5) interposed between the inductor (4) and the electrical energy storage units (2, 3), the switching system (5) being configured to:

 allow positive electric current from the first electrical energy storage unit (2) to flow from the second (7) to the first (6) terminal of the inductor (4) to perform a first load inductance

(4)

 allowing positive electric current flowing from the second (7) to the first (6) terminal of the inductor (4) to flow into the second electric power storage unit (3), and

allow positive electric current (i ₂ ) from the second electrical energy storage unit (3) to flow from the first (6) to the second (7) terminals of the inductor (4), so as to perform a second charge of the inductor (4).

 2. The electrical circuit according to claim 1, the switching system (5) comprising an H-bridge.

 3. Electrical circuit according to claim 2, the H-bridge comprising two arms (8) each extending between the same input terminal (9) and the same output terminal (10), each arm (8) comprising two switches (11) between which a midpoint (13) is connected to a respective terminal (6, 7) of the inductor (4).

 4. The electrical circuit according to claim 3, the switching system (5) comprising at least a first switch (15) arranged between the first electrical energy storage unit (2) and the input terminal (9) of the bridge. in H.

Electrical circuit according to Claim 3 or 4, the switching system (5) comprising at least one second switch (16) arranged between the second electrical energy storage unit (3) and the input terminal (9). of the H bridge.

6. Circuit according to any one of the preceding claims, the first electrical energy storage unit (2) being a battery.

 7. Circuit according to any one of the preceding claims, the second electrical energy storage unit (3) being a capacitor.

8. A method of exciting at least one electromagnet (4) using an electric circuit (1) comprising, in addition to said electromagnet formed by an inductance (4) extending between a first ( 6) and a second (7) terminal, a first power storage unit (2), a second power storage unit (3) and a switching system (5) interposed between the storage units electric energy (2, 3) and inductance (4), wherein:

 the switching system (5) is controlled so that a positive current (ii) supplied by the first electric energy storage unit (2) flows from the second terminal (7) to the first terminal (6) inductance (4), so as to perform a first load of said inductor (4),

 the switching system (5) is controlled so that a positive current

(ii) flowing from the second terminal (7) to the first terminal (6) of the inductor (4) feeds the second electric energy storage unit (3), so as to transfer to it the energy accumulated in the inductor (4), and

the switching system (5) is controlled so that a positive current (i ₂ ) supplied by the second electric energy storage unit (3) flows from the first terminal (6) to the second terminal (7). ) of the inductor (4), so as to perform a second charge of the inductor (4).

 The method according to claim 8, wherein the voltage applied to the inductor (4) by the first power storage unit (2) during the first charging of the inductor (4) is less than the voltage applied to the inductor by the second electric power storage unit (3) during the second charging of the inductor (4).

 The method of claim 9, wherein the first power storage unit (2) is a battery and wherein the second power storage unit (3) is a capacitor.