ELECTRICAL DEVICE, INVERTER, ELECTRIC DRIVE, VEHICLE AND MANUFACTURING METHODS

Abstract

Electrical device including a printed circuit board, a sensor mounted on the printed circuit board and projecting from the PCB, and a sensor protection component including a housing in which is housed the sensor.

Claims

1. Electrical device comprising: a printed circuit board, a sensor mounted on said printed circuit board and projecting from the printed circuit board, and a sensor protection component comprising a housing in which is housed the sensor.

2. Electrical device according to claim 1, wherein the sensor is a Hall sensor, and/or the protection component is mounted and fixed on the printed circuit board.

3. Electrical device according to claim 1, wherein the sensor comprises a body and at least one connection pin projecting from the body and connected to the PCB so that the body extends at a distance from the printed circuit board.

4. Electrical device according to claim 1, wherein the sensor is mounted on the printed circuit board by through-hole technology.

5. Electrical device according to claim 1, wherein the sensor protection component comprises at least one pin extending through the printed circuit board and allowing the positioning of said sensor protection component on the printed circuit board.

6. Electrical device according to claim 1, wherein the sensor protection component comprises at least one snap fits extending through the printed circuit board and fixing said sensor protection component on the printed circuit board.

7. Electrical device according to claim 1, wherein the housing of the sensor protection component comprises an opening facing the printed circuit board, said opening having a frustoconical shape allowing for centering the Hall sensor when entering said housing.

8. Inverter comprising: input terminals, output terminals, controllable switches connected to the input terminals and to the output terminals, and an electrical device according to claim 1, configured to control the controllable switches so as to convert a DC voltage at the input terminals into an AC voltage at the output terminals.

9. Inverter according to claim 8, further comprising a magnetic core around one of the output terminals, OTA said magnetic core being provided with an air gap, and wherein the Hall sensor extends in the air gap.

10. Electric drive comprising an inverter according to claim 8, and an electric motor driven by the inverter.

11. Vehicle comprising wheels and an electric drive according to claim 10 for driving, at least indirectly, at least one of the wheels.

12. Method for manufacturing an electrical device, particularly according to claim 1, comprising: mounting a sensor, in particular Hall sensor on a printed circuit board, and mounting a sensor protection component on the printed circuit board for positioning the sensor inside a housing of the sensor protection component.

13. Method for manufacturing an inverter, comprising: manufacturing a power module comprising input terminals, output terminals, and controllable switches connected to the input terminals and to the output terminals, manufacturing, according to claim 12, an electrical device being a control device of the power module, mounting a magnetic core provided with an air gap around at least one of the output terminals, mounting the electrical device on the power module, so that the sensor extends in the air gap of the magnetic core, and connecting the control device to the power module to control the controllable switches so as to convert a DC voltage at the input terminals into an AC voltage at the output terminals.

14. Electrical device according to claim 2, wherein the sensor comprises a body and at least one connection pin projecting from the body and connected to the PCB so that the body extends at a distance from the printed circuit board.

15. Electrical device according to claim 2, wherein the sensor is mounted on the printed circuit board by through-hole technology.

16. Electrical device according to claim 2, wherein the sensor protection component comprises at least one pin extending through the printed circuit board and allowing the positioning of said sensor protection component on the printed circuit board.

17. Electrical device according to claim 2, wherein the sensor protection component comprises at least one snap fits extending through the printed circuit board and fixing said sensor protection component on the printed circuit board.

18. Electrical device according to claim 2, wherein the housing of the sensor protection component comprises an opening facing the printed circuit board, said opening having a frustoconical shape allowing for centering the Hall sensor when entering said housing.

19. Inverter comprising: input terminals, output terminals, controllable switches connected to the input terminals and to the output terminals, and an electrical device according to claim 2, configured to control the controllable switches so as to convert a DC voltage at the input terminals into an AC voltage at the output terminals.

20. Electric drive comprising an inverter according to claim 9, and an electric motor driven by the inverter.

Description

[0033] The present invention will be described more specifically with reference to the following drawings, in which:

[0034] FIG. 1 is a schematic view showing an embodiment of a vehicle comprising an inverter with an electric control device according to the invention,

[0035] FIG. 2 is a sectional view of the inverter of FIG. 1,

[0036] FIG. 3 is a front/section view of the inverter of FIGS. 1 and 2,

[0037] FIG. 4 is a 3D section/view of the inverter of FIGS. 1 to 3,

[0038] FIG. 5 is a zoom in on a Hall effect sensor of the control device projection view of FIGS. 1 to 4, and

[0039] FIG. 6 is a block diagram illustrating a method for manufacturing the inverter of FIGS. 1 to 5.

[0040] Referring to FIG. 1, a vehicle 100 according to the invention will now be described. In the described example, the vehicle 100 is an automotive vehicle.

[0041] The vehicle 100 comprises wheels 102 and an electric drive 104 configured to drive at least one of the wheels 102 at least indirectly. The vehicle 100 further comprises a DC voltage source 106, such as a battery, for electrically powering the electric drive 104. The DC voltage source 106 is configured to provide a DC voltage E.

[0042] The electric drive 104 comprises a motor, for instance, an electric asynchronous motor 108 and an inverter 110 configured to drive the motor 108, for instance by supplying electric power. For example, the motor 108 is a rotary electric motor comprising a stator and a rotor configured to rotate around a rotation axis with respect to the stator.

[0043] The stator is provided with stator phases. In the described example, the motor 108 is a three-phase electric motor comprising three stator phases.

[0044] The inverter 110 is intended to drive the motor 108 so that phase currents I.sub.1-3 flows respectively in the stator phases, so as to produce a rotating magnetic field rotating around the rotation axis.

[0045] The inverter 110 comprises input terminals IT+, IT? connected to the DC voltage source 106 so that the DC voltage E is present at the input terminals IT+, IT?. More precisely, the input terminals IT+, IT? include a positive input terminal IT+ connected to a positive terminal of the DC voltage source 106 and a negative input terminal IT? connected to a negative terminal of the DC voltage source 106 and to an electrical ground GND.

[0046] The inverter 110 further comprises output terminals OT.sub.1-3 connected to the motor 108. An AC voltage is intended to be present at the output terminals OT.sub.1-3 for powering the electric motor 108. More precisely, the output terminals OT.sub.1-3 are connected to respective stator phase of the motor 108 and the respective phase currents I.sub.1-3 are intended to flow through them. The AC voltage may be a single or a multiphase AC voltage. In the described example where the motor 108 is a three-phase electric motor, the AC voltage is a three-phase AC voltage.

[0047] The inverter 110 further comprises a power module 111 including controllable switches Q, Q, called main switches, connected to the input terminals IT+, IT? and to the output terminals OT. The main switches Q, Q may be semi-conductor switches comprising for example transistors. Each main switch Q, Q comprises for example one amongst: a Metal Oxide Semiconductor Field Effect Transistor (MOSFET), an Insulated Gate Bipolar Transistor (IGBT) and a Silicon Carbide MOSFET (SiC MOSFET).

[0048] In the described example, the power module 111 comprises switch legs 114.sub.1-3 respectively associated to the stator phases of the motor 108. Each switch leg 114.sub.1-3 comprises a high side (HS) main switch Q connected to the positive input terminal IT+ and a low side (LS) main switch Q connected to the negative input terminal IT?. The HS main switch Q and the LS main switch Q are connected to each other at a middle point connected to the output terminal OT connected to the associated stator phase of the motor 108.

[0049] Each switch leg 114.sub.1-3 is intended to be controlled to commute between two configurations. In the first one, called high side (HS) configuration, the HS main switch Q is closed (on) and the LS main switch Q is open (off) so that the DC voltage E is essentially applied to the associated stator phase. In the second one, called low side (LS) configuration, the HS main switch Q is open (off) and the LS main switch Q is closed (on) so that a zero voltage is essentially applied to the associated stator phase.

[0050] The inverter 110 further comprises a control device 116 configured to control the power module 111, and, more precisely, the main switches Q, Q such that the main switches Q, Q convert the DC voltage E into the AC voltage. In the described example, the control device 116 is configured to commute each switch leg 114 between the two configurations mentioned above.

[0051] For controlling the power module 111, the control device 116 uses at least one measured phase current I.sub.1-3.

[0052] Referring to FIGS. 2 to 5, an example of a system for measuring the phase current I.sub.1-3 will now be described.

[0053] The electric drive 104 comprises, for at least one of the output terminals OT.sub.1-3, a magnetic core 202.sub.1-3 mounted around this output terminal OT.sub.1-3. In the described example, all three output terminals OT.sub.1-3 are associated with a respective magnetic core 202.sub.1-3. Each magnetic core 202.sub.1-3 comprises an air gap 204.sub.1-3. When the phase currents I.sub.1-3 flow through the output terminals OT.sub.1-3, they create respective magnetic fields in the magnetic cores 202.sub.1-3 which pass through the air gaps 204.sub.1-3. These magnetic fields are therefore representative of the phase currents I.sub.1-3.

[0054] To measure the magnetic fields and determine from them the phase currents I.sub.1-3, the control device 116 comprises a printed circuit board 206, herein called PCB, on which sensors, in particular Hall sensors 208.sub.1-3 are mounted, one for each measured phase currents I.sub.1-3.

[0055] More precisely, in the described example, each Hall sensor 208.sub.1-3 comprises a body 210 and at least one connection pin 212 (three in the described example) projecting from the body 210. The connection pins 212 are connected to the PCB 206 so that the body 210 extends at a distance from the PCB 206, in the air gap 204.sub.1-3 of the respective magnetic core 202.sub.1-3.

[0056] Each Hall sensor 208.sub.1-3 is for example mounted on the PCB 206 using Through Hole Technology (THT). Advantageously, the connection pins 212 of the Hall sensor 208.sub.1-3 are soldered to the PCB 206.

[0057] In order to accurately measure the magnetic field, the body 210 of each Hall sensor 208.sub.1-3 needs to be precisely positioned in the respective air gap 204.sub.1-3, for example precisely in the middle of the air gap 204.sub.1-3.

[0058] However, the PCB 206 is located at a distance from the air gap 204.sub.1-3, so that the connection pins 212 need to be long. Because of this length, the connection pins 212 are prone to bending so that the positioning of the body 210 may become incorrect, which in turn could have a negative functional impact.

[0059] To overcome this problem, the control device 116 also comprises a sensor protection component 214 intended to protect the sensors 208.sub.1-3 from mechanical stress and bending in particular during handling and assembly operations. The sensor protection component 214 comprises, for each sensor 208.sub.1-3, a housing 216.sub.1-3 in which this sensor 208.sub.1-3 is housed. Advantageously, the sensor protection component 214 comprises a plurality of housings 216.sub.1-3, for example three housings in the described example, for respectively receiving the plurality of sensors 208.sub.1-3. In particular, the body 210 of the sensor 208.sub.1-3 is held in place by the housing 216.sub.1-3. To this end, the body 210 is preferably in contact with at least to walls of the housing 216.sub.1-3 facing each other.

[0060] The sensor protection component 214 is preferentially made in one single piece, for example in plastic.

[0061] Once mounted on the PCB 206, the sensor protection component 214 is in abutment against a lower face of the PCB 206. Advantageously, the sensor protection component 214 comprises at least on positioning pin 218 for positioning the sensor protection component 201 relative to the PCB 206 during mounting, and at least one snap fit 220 for fixing the sensor protection component 214 to the PCB 206. When the sensor protection component 214 is mounted on the PCB 206, the positioning pin 218 as well as the snap fit 220 extend through the PCB 206. The mounting of the sensor protection component 214 is better represented on FIG. 4.

[0062] When the Hall sensor 208.sub.1-3 is housed in the housing 216.sub.1-3 of the sensor protection component 214, the risks of bending and damaging the Hall sensor 208.sub.1-3 are considerably reduced. Furthermore, the positioning of the Hall sensor 208.sub.1-3 may be controlled relative to the magnetic core 202.sub.1-3, allowing a good current measure.

[0063] Referring more particularly to FIG. 5, in the described embodiment, each housing 216.sub.1-3 of the sensor protection component 214 comprises a first opening 502 facing the PCB 206. The first opening 502 has a frustoconical shape. This shape allows to center the respective Hall sensor 208.sub.1-3 when entering said housing 216.sub.1-3. Each housings 216.sub.1-3 of the sensor protection component 214 may also comprises a lower opening 504, opposite to the first opening 502. An extremity of the Hall sensor 210 preferably passes through said lower opening 504. In is also possible that the entire Hall sensor is covered by the protection component 214 preferably made from plastics.

[0064] Referring to FIG. 6, an example of a method 600 for manufacturing the inverter 110 will now be described. In other embodiments, the order of the steps could differ.

[0065] At a step 602, the power module 111 is manufactured. As explained above, the power module 111 comprises the input terminals IT+, IT?, the output terminals OT.sub.1, OT.sub.2, OT.sub.3, and the controllable switches Q, Q connected to the input terminals IT+, IT? and to the output terminals OT.sub.1, OT.sub.2, OT.sub.3.

[0066] At a step 604, the control device 116 is manufactured. This step comprises in particular the following steps.

[0067] At a step 604-1, each Hall sensor 208.sub.1-3 is mounted on the PCB 206. For example, the connection pins 212 of each Hall sensor 208.sub.1-3 are passed into corresponding holes of the PCB 206 and soldered to the PCB 206.

[0068] At a step 604-2, the sensor protection component 214 is mounted on the PCB 206, for positioning the Hall sensors 208.sub.1-3 inside their respective housings 216.sub.1-3 of the sensor protection component 214. For example, the step 604-2 comprises positioning said sensor protection component 214 in abutment with the PCB 206) by inserting the positioning pins 218 of the sensor protection component 214 through the PCB 206, and fixing the sensor protection component 214 to the PCB 206 by inserting the snap fits 220 of the sensor protection component 214 through the PCB 206.

[0069] At a step 606 or preferably at step 602, the magnetic cores 202.sub.1-3 are respectively mounted around the output terminals OT.sub.1-3.

[0070] At a step 608, the control device 116 is mounted on the power module 111, so that the Hall sensors 208.sub.1-3, extends in the air gap 204.sub.1-3 of the respective magnetic core 202.sub.1-3.

[0071] At a step 610, the control device 116 is connected to the power module 111 to control the controllable switches Q, Q so as to convert a DC voltage at the input terminals IT+, IT? into an AC voltage at the output terminals OT.sub.1-3.

[0072] It will 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 embodiments described above, in the light of the teaching which has just been disclosed.

[0073] In the previous detailed description of the invention, the terms used should not be interpreted as limiting the invention to the embodiments presented in the present description, but should be interpreted to include all the equivalents 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.