FR3144450A1 - Inverter for electric machine - Google Patents

Abstract

The present invention relates to an inverter (1), comprising: a capacitive module (2); a first power module (3a) connected to the capacitive module (2) by a direct current connection (4a) and comprising an alternating current connection (5a) arranged on an opposite side of the first power module (3a); at least a first electronic power card (8) electrically connected to the first power module (3a) and extending parallel to the first power module ( 3a);an electronic control card (7) electrically connected to the electronic power card (8) and extending parallel to the electronic power card (8); the inverter (1) being characterized in that the alternating current connection (5a) of the first power module (3a) extends parallel between the electronic power card (8) and the electronic control card (7). Abstract Figure: Figure 4

Description

Inverter for electric machine

The present invention relates to electrical equipment such as inverters, equipped with power modules and associated with an electrical machine, for example an electric or hybrid vehicle engine.

STATE OF THE ART

As is known, an electric or hybrid motor vehicle comprises an electric motor system powered by a high voltage power battery, generally greater than 100V, via a high voltage onboard electrical network and a plurality of auxiliary electrical equipment powered by a low-voltage power battery via a low-voltage on-board electrical network. The high-voltage power battery provides an energy supply function for the electric motor system allowing the propulsion of the vehicle. More precisely, in order to control the electrical machine driving the wheels of the vehicle, it is known to use an inverter making it possible to convert the direct voltage supplied by the high voltage supply battery into one or more alternative control voltages, for example sinusoidal. .

It is also known to integrate within the inverter a capacitive filtering device called link capacitor or "DC-link capacitor" for those skilled in the art, having in particular the function of stabilizing the voltage supplied to the component of active power electronics of the inverter, in particular a power module supplying electrical energy to the electrical machine.

In the context of electronic or hybrid vehicles requiring high levels of power, for example a utility vehicle, it is known to power an electric machine via several power modules, generally two power modules each delivering an electric current three-phase. This architecture can then use two link capacities, each being connected to a power module.

In known inverters comprising at least one power module, the electrical connector intended to power phases of the electrical machine extends mainly in a vertical direction relative to the capacitive module or relative to the power module towards an output of the inverter. This connector is generally located on another side of the power module than an electrical connector connecting the capacitive module to the power module. The electrical connector is then connected to the phases of the electrical machine according to a specific architecture occupying a large longitudinal space in the inverter, and the arrangements in which the electrical connector connecting the capacitive module to the power module is located on the same side of the power module. power module and outputs from the inverter to the electrical machine are not feasible. In addition, the cooling of such an electrical connector is not optimal, which can lead to significant energy losses.

The invention aims to resolve the drawbacks of the state of the art by proposing a simplified inverter architecture, with reduced cost and improved performance.

PRESENTATION OF THE INVENTION

• un module capacitif ;
• au moins un premier module de puissance relié au module capacitif par une connexion à courant continu et comprenant une connexion à courant alternatif configurée pour permettre la circulation d’un courant électrique entre le module capacitif et une machine électrique à courant alternatif, la connexion à courant alternatif étant disposée d’un côté opposé du premier module de puissance par rapport à la première connexion à courant continu ;
• au moins une première carte électronique de puissance reliée électriquement au premier module de puissance et s’étendant parallèlement au premier module de puissance ;
• une carte électronique de contrôle reliée électriquement à la carte électronique de puissance et s’étendant parallèlement à la carte électronique de puissance;

l’onduleur étant caractérisé en ce que la connexion à courant alternatif du premier module de puissance s’étend parallèlement entre la carte électronique de puissance et la carte électronique de contrôle.More precisely, the subject of the invention is an inverter, in particular configured to be embedded in a motor vehicle, comprising:

• a capacitive module;
• at least a first power module connected to the capacitive module by a direct current connection and comprising an alternating current connection configured to allow the circulation of an electric current between the capacitive module and an alternating current electric machine, the current connection alternating current being arranged on an opposite side of the first power module with respect to the first direct current connection;
• at least a first electronic power card electrically connected to the first power module and extending parallel to the first power module;
• an electronic control card electrically connected to the electronic power card and extending parallel to the electronic power card;

the inverter being characterized in that the alternating current connection of the first power module extends parallel between the electronic power card and the electronic control card.

Thanks to such a combination of characteristics, such an inverter makes it possible to increase the number of possible configurations for an inverter architecture, depending on the location of the inverter output towards the electrical machine. For example, the alternating current connection can thus be arranged on a side opposite the output of the inverter in relation to the power module. Such an arrangement also makes it possible to increase the number of possible configurations for locating the direct current connection connecting the capacitive module to the power module, which can for example be located on the same side as the output of the inverter with respect to to the power module.

Advantageously, the alternating current electrical connection of the first power module comprises a plurality of electrical connectors. In this configuration, the AC connection is a three-phase AC connection.

Advantageously, the electronic control card electrically connected to the electronic power card extending parallel to the electronic power card on the same side of the first power module as the electronic power card.

Advantageously, the inverter comprises a second power module extending substantially in the same plane as the first power module. In such a configuration, the power delivered by the inverter to the electrical machine is improved.

Advantageously, the inverter comprises a second electronic power card electrically connected to the second power module and extends substantially in the same plane as the first electronic power card. The alternating current connection then extends between the electronic control card and the plane comprising the first and the second electronic power card.

Advantageously, the alternating current connection of the first power module and an alternating current connection of the second power module are shared in a connection interface configured to power an alternating current motor, said connection interface extending parallel between the card power and control card.

Advantageously, the alternating current electrical connection of the first power module and the alternating current connection of the second power module comprise a plurality of electrical connectors whose electrical currents have equal phase shift angles are associated two by two in the interface of connection, said connection interface comprising at least three outputs configured to power the respective phases of a three-phase alternating current motor. In such a configuration, the phases of a three-phase electric motor are supplied as close as possible to the power modules, and the two-to-two association of connectors presenting electric currents of the same phase shift under these conditions guarantees similar characteristics delivered by the two power modules.

Advantageously, the inverter comprises a plate extending parallel between the alternating current connection and the control card. Such a plate can for example help protect the electronic control card from electromagnetic radiation coming from other components of the inverter. In addition, such a plate can also serve as a heat exchange surface to cool the AC connection.

Advantageously, the first power module and the second power module are identical.

According to another aspect of the invention, it relates to a mobility device such as an electric or hybrid vehicle.

PRESENTATION OF FIGURES

The invention will be better understood on reading the description which follows, given solely by way of example, and referring to the appended drawings given by way of non-limiting examples, in which identical references are given to similar objects. and on which:

There is a schematic perspective representation of an inverter according to one embodiment of the invention;

There is a schematic representation in front view of the inverter of the in the removed position from an inverter chassis and cover;

There is a schematic representation in front view of the inverter in the removed position from the chassis and the cover according to another embodiment of the invention;

There is a schematic representation in front view of an inverter according to another embodiment of the invention in the removed position of the chassis and the cover of the inverter;

There is a schematic representation in front view of an inverter according to another embodiment of the invention.

It should be noted that the figures set out the invention in detail to enable the invention to be implemented; although not limiting, said figures serve in particular to better define the invention where applicable.

DETAILED DESCRIPTION OF THE INVENTION

There illustrates an inverter 1, for example for an electric or hybrid vehicle engine. The inverter 1 comprises a chassis 100 and a removable cover 200 between a removed position in which an interior space of the chassis 100 is accessible and a closed position which corresponds to an operating position of the inverter 1.

There illustrates the inverter 1 in the removed position from the chassis 100 and the cover 200. The inverter 1 comprises a capacitive module 2, here a connection capacitor. The connection capacitor 2 has a general shape which is substantially prismatic parallelepiped, a length of the connection capacitor 2 extending in a horizontal direction the connection capacity 2 extending in a vertical direction Z.

The inverter 1 further comprises a first power module 3a connected to the link capacity 2 by a first direct current connection 4a. By “power module”, we mean an assembly comprising components through which energy supplying the electrical machine passes. These components may include electronic switches, such as for example semiconductor transistors, arranged in an electrical circuit to allow a controlled passage of electrical energy between the power battery and the electrical machine. In particular, the components are bare semiconductor chips for which encapsulation is carried out. In other words, a power module is an assembly comprising a plurality of semiconductor chips forming an electrical circuit encapsulated in the same package. The first power module 3a extends parallel to a plane X, Y, vertically above the link capacity 2.

The first direct current connection 4a allows the link capacitor 2 to supply the first power module 3a with filtered and stabilized direct current. The first direct current connection 4a extends vertically in the Z direction. The first power module 3a further comprises an alternating current connection 5a. In the embodiment described, the first alternating current connection 5a comprises a plurality of electrical connectors, each of the electrical connectors being powered by an alternating electrical current having a different phase shift. The alternating current connection 5a and the electrical connectors of the alternating current connection 5a are arranged on an opposite side of the first power module 3a with respect to the first direct current connection 4a.

The inverter 1 further comprises a first electronic power card 8 electrically connected to the first power module 3a and extending parallel to the first power module 3a. Preferably, the electronic power card 8 is mechanically secured to the power module 3a. The inverter 1 also includes an electronic control card 7 electrically connected to the electronic power card 8 and extending parallel to the electronic power card 8, on the same side of the first power module 3a. The electronic control card 7 makes it possible to control the inverter 1.

The alternating current connection 5a of the power module 3a extends in parallel between the electronic power card 8 and the electronic control card 7. In the embodiment described, the plurality of connectors of the alternating current connection 5a is shared in a connection interface 6 which extends parallel between the electronic power card 8 and the electronic control card 7. In such a configuration, outputs 60a, 60b and 60c of the connection interface 6 can be located the same side relative to the first power module 3a as the direct current connection 4a, which increases the possible configurations of location of the direct current connection 4a.

There illustrates the inverter 1 according to another embodiment. Inverter 1 of the differs from inverter 1 of the in that the power module 3a is located on one side of the capacitive module 2 opposite longitudinally to the outputs 60a, 60b, 60c of the connection interface 6.

As illustrated on the and on the , the inverter 1 further comprises a second power module 3b connected to the link capacity 2 by a second direct current connection 4b. The second power module 3b extends in the same plane as the first power module 3a. The first power module 3a and the second power module 3b may be identical. In such a configuration, the power delivered by the inverter 1 to the electrical machine is improved.

In the embodiment of the and some , an alternating current connection 5b of the second power module 3b comprises a plurality of electrical connectors, each of the electrical connectors being powered by an alternating electric current having a different phase shift. The alternating current connection 5b and the connectors of the alternating current connection 5b are arranged on an opposite side of the second power module 3b with respect to the second direct current connection 4b.

The connectors of the first power module 3a and the connectors of the second power module 3b whose electric currents have equal phase shift angles are associated two by two in the connection interface 6. The three outputs 60a, 60b, 60c of the The connection interface 6 are then configured to power the respective phases of a three-phase alternating current motor. The connection interface 6 is in particular an electrical connection bar, or “busbar” for those skilled in the art. The outputs of the connection interface 60a, 60b, 60c can also extend through a passage orifice of the electronic control card 7.

Inverter 1 of the differs from inverter 1 of the in that the inverter 1 of the comprises in particular a plate 9 extending parallel to the connection interface 6 and to the electronic control card 7, between the connection interface 6 and the electronic control card 7. The plate 9, preferably metallic, allows in particular to protect the electronic control card 7 from electromagnetic radiation induced by the alternating electric currents circulating in the connection interface 6. In addition, the plate can also serve as a heat exchange surface to cool the connection interface 6, this which makes it possible to reduce energy losses within the connection interface 6 and to improve the performance of the inverter 1. The connection interface 6 can be directly in contact with the plate 9. Alternatively, there may be a thermal interface material between the plate 9 and the connection interface 6 which makes it possible to evacuate the heat generated by the connection interface 5. The thermal interface material is for example a paste or a thermal grease.

It should also be noted that the invention is not limited to the embodiments described above. It will indeed appear to those skilled in the art that various modifications can be made to the embodiment described above, in light of the teaching which has just been disclosed to them.

For example, the inverter 1 may comprise a second electronic power card, electrically connected to the second power module 3b and extending substantially in the same plane as the first electronic power card 8. The connection interface 6 is then extends between the electronic control card 7 and the plane comprising the first electronic power card 8 and the second electronic power card. The first electronic card 8 and the second electronic card can be two separate pieces or formed in a single piece.

In the detailed presentation of the invention which is made previously, the terms used should not be interpreted as limiting the invention to the embodiment set out in the present description, but must be interpreted to include all the equivalents for which the prediction is within the reach of those skilled in the art by applying their general knowledge to the implementation of the teaching which has just been disclosed to them.

Claims (10)

Inverter (1), in particular configured to be embedded in a motor vehicle, comprising:

• a capacitive module (2);
• at least a first power module (3a) connected to the capacitive module (2) by a direct current connection (4a) and comprising an alternating current connection (5a) configured to allow the circulation of an electric current between the capacitive module (2) and an alternating current electric machine, the alternating current connection (5a) being provided on an opposite side of the first power module (3a) to the first direct current connection (4a);
• at least one first electronic power card (8) electrically connected to the first power module (3a) and extending parallel to the first power module (3a);
• an electronic control card (7) electrically connected to the electronic power card (8) and extending parallel to the electronic power card (8);

the inverter (1) being characterized in that the alternating current connection (5a) of the first power module (3a) extends parallel between the electronic power card (8) and the electronic control card (7). Inverter (1) according to claim 1, characterized in that the alternating current electrical connection (5a) of the first power module (3a) comprises a plurality of electrical connectors. Inverter (1) according to any one of the preceding claims, characterized in that it comprises a second power module (3b) extending substantially in the same plane as the first power module (3a). Inverter (1) according to claim 3, characterized in that it comprises a second electronic power card electrically connected to the second power module (3b) and extending substantially in the same plane as the first electronic power card (8 ). Inverter (1) according to any one of the preceding claims, characterized in that the alternating current connection (5a) of the first power module (3a) and an alternating current connection (5b) of the second power module (3b) are shared in a connection interface (6) configured to power an alternating current motor, said connection interface (6) extending parallel between the electronic power card (8) and the electronic control card (7). Inverter (1) according to claim 5, characterized in that the alternating current electrical connection of the first power module (3a) and the alternating current connection (5b) of the second power module (3b) comprise a plurality of electrical connectors whose electric currents have equal phase shift angles are associated two by two in the connection interface (5), said connection interface (6) comprising at least three outputs configured to power the respective phases of an alternating current motor three-phase. Inverter (1) according to any one of claims 3 to 6, characterized in that the first power module (3a) and the second power module (3b) are identical. Inverter (1) according to any one of the preceding claims, characterized in that it comprises a plate (9) extending parallel between the alternating current connection (5a) and the electronic control card (7). Inverter (1) according to any one of the preceding claims, characterized in that the capacitive module (2) is a link capacitor. Mobility device characterized in that it comprises an inverter (1) according to any one of the preceding claims.