WO2015067730A2

WO2015067730A2 - Secure control of an electric heater

Info

Publication number: WO2015067730A2
Application number: PCT/EP2014/074000
Authority: WO
Inventors: Bertrand Puzenat
Original assignee: Valeo Systemes Thermiques
Priority date: 2013-11-08
Filing date: 2014-11-07
Publication date: 2015-05-14
Also published as: DE112014005110T5; FR3013004A1; FR3013003A1; FR3013003B1; FR3013004B1; WO2015067730A3

Abstract

The invention relates to a device (1) for securely controlling a heater module (3) comprising at least one heating resistor (31, 33) suitable for being connected in series between a high-voltage conductor (5) and a ground conductor (7) of a high-voltage electrical network (9). The device (1) includes: a first electronic switch (11) connected in series to said at least one heating resistor (31, 33); a second electronic switch (15) connected in series to said at least one heating resistor (31, 33) and to the first electronic switch (11); first and second control modules (13, 17) suitable for controlling the first and second electronic switches (11), respectively, the second control module (17) floating with respect to the first control module (13); and chopping conversion means (19) connected to a low-voltage electrical network (21) and suitable for independently supplying the first control module (13) and the second control module (17) with power, the conversion means (19) including galvanic insulation between the low-voltage electrical network (21) and the high-voltage electrical network (9).

Description

Secure control of an electric heater

The present invention generally relates to an electric heater, and more particularly to a secure control of such a heater.

The invention particularly relates to the field of electric or hybrid vehicles where the electric heaters are designed to operate with two supply voltages of different values, typically a low voltage of the order of 12 volts and a high voltage of the order of 350 Volts. The high voltage is used to operate the heater, while the low voltage is used to control this operation (on, off, power, etc.). In general, the low voltage network of the vehicle is constituted by the low voltage battery at the nominal value of 12 V. This low voltage circuit is connected to the vehicle body by one of the terminals of the low voltage battery. The high voltage network of the vehicle is constituted by the high voltage battery (~ 350 V), called traction battery. The high voltage circuit is kept inaccessible to the passengers of the vehicle.

Heaters for electric or hybrid vehicles are used to heat the vehicle interior by warming the water in the cooling system. The heaters comprise one or more heating resistive elements and are powered by a power current coming from the high voltage battery of the vehicle (~ 350 V), called traction battery. The resistive heating element may, for example, be controlled by a control circuit including a power transistor placed in series with the heating element on the power supply, where the gate of the transistor is driven by a control device. grid control whose energy comes from the low voltage circuit of the vehicle.

When the supply circuit of a heater is faulty, resulting for example from a short-circuit of the power transistor, the heater can operate permanently, which creates a risk of fire when the water boils and evaporates, thus confronting parts of the vehicle at very high temperatures. Heaters in vehicles must meet the ISO 26262 standard, the risk coming from a faulty heater being classified ASIL (English initials for automotive safety integrity level), which corresponds to the most critical level of requirement in terms of safety.

To protect against abnormally high temperatures, heaters generally use, as heating resistive elements, either heating resistors associated with a fuse, for example a bimetallic strip, or elements with a positive temperature coefficient (called PTC elements). The CTP elements, whose resistance increases with temperature, make it possible not to exceed a given temperature (for example, about 200 ° C.). However, the CTP elements are rather expensive (compared to a fixed resistance) and their performance decreases very rapidly depending on the temperature of the water. The bimetallic strips, in turn, have the disadvantage of the appearance of an arc during the breaking of a continuous current of power. In addition, bimetallic strips are very compact.

It is therefore necessary to have a heater control capable of mitigating any failure of one of the elements of the electronic circuit to avoid the unwanted operation of the heater and thus the risk of fire, while overcoming the disadvantages of conventional orders mentioned above.

The present invention satisfies this objective by proposing a device for the secure control of a heating module comprising at least one heating resistor capable of being connected in series between a high-voltage conductor and a ground conductor of a high-voltage electrical network. device comprising:

a first electronic switch adapted to be connected in series with said at least one heating resistor;

a first control module able to control the first electronic switch;

a second electronic switch adapted to be connected in series with said at least one heating resistor and the first electronic switch; a second control module capable of controlling the second electronic switch, the second control module being floating relative to the first control module; and

switching conversion means adapted to be connected to a low-voltage electrical network and capable of independently supplying the first control module and the second control module, the conversion means comprising a galvanic isolation between the low-voltage electrical network and the high voltage electrical network.

The secure control of a heater module according to the invention thus provides redundancy in the function of the duplicated components (control modules, switches). This makes it possible to overcome any possible failure of one of these components and, consequently, to ensure the required functional safety with respect to the risk of fire while overcoming the disadvantages mentioned above.

According to one embodiment of the invention, the conversion means comprise two switching converters each comprising:

a primary winding adapted to be connected to the low-voltage electrical network for supplying electrical energy;

- a galvanically isolated secondary winding of the primary winding;

wherein the secondary winding is adapted to provide a useful voltage value by restoring the supplied electrical energy.

In a particularly preferred manner, the conversion means comprise a single switching converter capable of supplying the first and second control modules.

In addition to the advantages mentioned above, a single switching converter is a perfectly adapted, economical and clever power supply for the two control modules, which also saves space with respect to two separate power supplies. In addition, a single switching converter saves space

According to one variant, the single switching converter is a flyback type converter, comprising: a primary winding adapted to be connected to the low-voltage electrical network for supplying electrical energy;

- two galvanically isolated secondary windings of the primary winding;

wherein the secondary windings are adapted to provide the same value of useful voltage by restoring the electrical energy supplied.

Preferably, the single switching converter further comprises:

a regulation winding capable of supplying a useful voltage value by restoring the electrical energy supplied; and

a regulation module;

wherein the control module is adapted to measure the value of the useful voltage supplied by the regulation winding and to regulate the duty cycle of the converter to obtain a predetermined value of the useful voltage. This allows the converter to be regulated so that the first and second secondary windings provide a predetermined voltage value for powering the first and second control modules.

Advantageously, the device further comprises a first temperature detector and a second temperature detector, the detectors being able to detect a water temperature value in the vicinity of the at least one first heating resistor of the heating module and to provide the value detected at one of the control modules.

According to a preferred variant, the first control module is a master control module, and the second control module is a slave control module.

Advantageously, the master control module comprises a current measuring module capable of measuring a power current flowing in the first electronic switch and the second electronic switch.

According to a variant, the first and the second control modules are able to communicate with one another via a data link.

Preferably, the master control module is able to:

detecting a failure of one of the first and second electronic switches by means of the measurement module of current and to detect a failure of the slave control module by means of the data link,

- to control the opening of the first electronic switch when one of these failures is detected.

Preferably, the slave control module is able to detect a failure of the master control module by means of the data link and to control the opening of the second electronic switch when a fault is detected.

Advantageously, the device according to one embodiment further comprises:

a LIN communication module able to be connected to the low-voltage electrical network; and

a non-galvanic coupler;

wherein the LIN communication module is adapted to transmit control commands from the heater module to the master control module by means of the non-galvanic coupler.

Preferably, each of the first and second electronic switches comprises a transistor comprising a gate connected to an output of the associated control module. According to variants, the transistor is an IGBT or a MOSFET. Each of said first and second control modules comprises a microcontroller and a gate controller.

Advantageously, the first and the second electronic switches are capable of being connected to the same side of the at least one heating resistor.

Alternatively and advantageously, the first and second electronic switches are able to be connected on either side of said at least one heating resistor.

Preferably, the useful voltage value is about 15 V.

The invention and the advantages it provides will be better understood from the following description of a nonlimiting example of implementation of the invention, with reference to the appended figures, in which: FIG. 1 represents a simplified diagram of a secure control device according to a first embodiment of the invention; and

- Figure 2 schematically illustrates a secure control device according to a second embodiment of the invention.

FIG. 1 represents an embodiment of a secure control device 1 of a heating module 3, the heating module 3 comprising two heating resistors 31, 33 adapted to be connected in series between a high-voltage conductor 5 and a power supply conductor. mass 7 of a high voltage electrical network. The secure control device 1 comprises:

a first electronic switch 11 adapted to be connected in series with the heating resistors 31, 33,

a first control module 13 able to control the first electronic switch 11,

a second electronic switch 15 adapted to be connected in series with the heating resistors 31, 33 and the first electronic switch 11, and

a second control module 17 able to control the second electronic switch 15.

The control device 1 according to the illustrated embodiment further comprises switching conversion means 19 connected to a low voltage electrical network. The low voltage electrical network provides, for example, a voltage of about 12 V, which can vary approximately between 9 V and 16 V. The low voltage network can be constituted, for example, by the low voltage battery of the vehicle. The high voltage network is, for example, constituted by the traction battery of the vehicle. It provides a voltage of approximately 350 V, which can vary between 250 V and 450 V approximately.

The conversion means 19 serve to supply the first control module 13 and the second control module 17 with a useful value of low voltage. Typically, this output voltage value is of the order of 15 V, and it is essentially the same for both power supplies. control module. The conversion means 19 comprise a galvanic isolation between the low-voltage electrical network and the high-voltage electrical network, in order to guarantee the secure isolation between these two networks. This safe insulation is required by electric and hybrid automakers.

The power supply of the second control module 17 is floating relative to the power supply of the first control module 13. This means that there is no fixed relationship between the ground potential of the first switch 11 and the first control module. 13 and the ground potential of the second switch 15 and the second control module 17. For example, the ground potentials may be of the same value in the case where the second switch 15 is closed, and they may be different. one of the other in other cases.

Preferably, and as shown in FIG. 1, the conversion means 19 comprise a single switching converter capable of independently supplying the first control module 13 and the second control module 17. The converter is, for example, a flyback type converter having inductances (windings) coupled to the same magnetic core. The low voltage network provides the primary of the converter 19 with electrical energy which is stored as magnetic energy. The magnetic energy is restored by secondary energy. In the embodiment shown, the switching converter comprises a primary winding 119 connected to the low voltage electrical network and two secondary windings 219, 319 galvanically isolated from the primary winding 119. The switching converter also comprises a regulation winding 419, in the form of a third secondary winding, for regulating the converter 19 so that the first and second secondary windings 219, 319 provide an output voltage of a predetermined value, for example, about 15 V. For this, the converter 19 also comprises a regulation module 420 connected to the regulation winding 419 and which regulates the duty ratio of the converter 19 as a function of the voltage value of output of the three secondary windings 219, 319, 419, in order to obtain a predetermined value of useful voltage for the respective supply of the two control modules 13, 17. For example, if the output voltage is too high, the duty cycle is decreased to obtain the predetermined output voltage. This is possible if we consider that the three secondary are similar. Thus, the correct regulation of a secondary winding automatically leads to good regulation of the other two secondary windings.

A single switching converter type flyback conversion means 19 is thus perfectly suited for the power of the two control modules 13, 17. The single converter is indeed an economical supply, simple and clever two redundant control modules .

According to a not shown variant of the secure control device 1, the conversion means 19 comprise two switching converters. In this variant, each of the two converters comprises a primary winding connected to the low-voltage electrical network and a galvanically isolated secondary winding of the primary winding. Each secondary winding restores electrical energy to power its associated control module.

Each of the first and second electronic switches 11, 15 comprises a transistor. The gate G of the transistor is connected to an output of its associated control module. The transistor may be, for example, an IGBT (Insulated Gate Bipolar Transistor) or a MOSFET (Metal-oxide-Semiconductor Field Effect Transistor). for Metal Oxide Semiconductor Field Effect Transistor).

According to the embodiment shown, the first control module

13 includes a first microcontroller 113 and a first gate controller 213, and the second control module 17 includes a second microcontroller 117 and a second microcontroller 117. gate 217. The two power supplies provided by the secondary of the converter 19 are respectively intended to power a microcontroller / gate control device assembly. The first and second gate drivers 213, 217 control their associated transistor to switch between the off state (open position) and the on state (closed position). For example, the gate drivers 213, 217 apply to the gate of the transistor 0 V to open the transistor and 12V (in the case of MOSFET) or 15 V (in the case of IGBT) to close it. Each microcontroller 113, 117 controls that its associated transistor is controlled at a value of about 12 V or 15 V, do not vary more than about 2 V to protect the transistor.

According to a variant, the device 1 further comprises regulators (not shown) for each microcontroller 113, 117 in order to regulate the supply voltage of the latter. For example, the voltage of 15 V supplied by the secondary of the converter can be lowered to 5 V by the regulators.

Advantageously, the device 1 comprises a first and a second temperature detector 35, 37 each located near one of the two heating resistors 31, 33 of the heating module 3 in order to measure the temperature of the heated water of the cooling circuit . The first temperature detector 35 provides its detected temperature value to the first control module 13, and the second temperature detector 37 supplies its detected temperature value to the second control module 17. If the temperature of the water is close to its boiling point, for example, about 90 ° C, the electronic switch 11, 15 associated with the control module 13, 17 having received the measured value is put in the open position by the control module 13, 17 to stop the passage of the current in the heater module 3. As the water temperature value is approximately the same for the two detectors, the two switches are put in the open position. The detection of the temperature is thus part of the diagnosis of the good functioning of the control device 1.

According to one variant, the heating module 3 comprises a single heating resistor, and the two temperature detectors 35, 37 can be near a single heating resistor. The first control module 13 receives the two measured temperature values either close to two heating resistors, respectively, or close to a single heating resistor.

Duplication of some components of the controller

(Control modules, electronic switches, temperature detectors) here makes it possible to have a redundancy in the function of these components which makes it possible to overcome any possible failure of one of these components. For example, the failures of a control module may include a blockage due to a latch (lock-up latch-up) of the circuit and a malfunction of the electronics of the control module. Also, in most cases, the failure of a transistor produces a short circuit.

In the illustration of the embodiment, in exemplary fashion, the first electronic switch 11 and the second electronic switch 15 are connected in series with each other and in series with the two heating resistors 31, 33 which are arranged in parallel in the heater module 3 The two switches 11, 15 are connected in series on the ground potential side of the heating resistors 31, 33.

According to other variants, the switches can also be connected in series on the high voltage potential side of the heating resistors, or in series on either side of the heating resistors.

Advantageously, the first control module 13 is a master control module comprising a main microcontroller 113 and a main gate control device 213, and the second control module 17 is a slave control module comprising an auxiliary microcontroller 117 and an auxiliary gate control device 217. The main and auxiliary microcontrollers 13, 17 communicate with each other via a data link 23. For example, this link 23 may be an SPI link (Serial Peripheral Interface). wherein the slave module responds to requests from the master module to communicate according to a clock generated by the master module. For example, the master module 13 can ask the slave module 17 to communicate the temperature measured by the second temperature detector 37. This data link 23 is made non-galvanically to allow the two control modules 13, 17 to remain floating l one with respect to the other. For this purpose, the device 1 according to the second embodiment comprises a connection module 27. The connection module 27 comprises, for example, a photocoupler or a capacitive coupler (digital coupler). SPI communication is bidirectional. The communication allows the control modules 13, 17 to carry out diagnostic sequences which will be seen in more detail later.

The master control module 13 comprises a current measurement module 313 making it possible to measure the power current flowing in the first transistor 11 (main transistor) and the second transistor 15 (auxiliary transistor). When both transistors 11, 15 are closed, a power current must be detected. In all other cases, no current should be measured. This allows the master module 13 to verify the proper operation of the two transistors 11, 15. This verification can also be performed by measuring the high voltage at the output of the heating elements 31, 33.

According to the embodiment of FIG. 2, the secure control device 1 further comprises a LIN communication module (English initials set for Local Interconnect Network) 25 connected to the low-voltage electrical network, and a coupling means 250 that is not connected. galvanic between the LIN 25 communication module and the main microcontroller 113. The LIN communication is bidirectional. LIN communication makes it possible to communicate with the control system (microcontroller, control device, switch) of the heater 3 even if the high voltage supply malfunctions. This allows the LIN communication module 25 to transmit control commands from the heater module 3 to the main microcontroller 113 so that the gate control device 213 can drive its transistor 11 accordingly. In the embodiment shown, the auxiliary microcontroller 117 has no means of communication with the low voltage network, the communication being ensured. by the main microcontroller 113 via the LIN and SPI links. The coupling means 250 comprise, for example, a photocoupler or a capacitive coupler (digital coupler).

Advantageously, the master control module 13 performs a number of functions, the main ones of which are:

- The diagnosis of the proper operation of the first and second switches 11, 15, verifying, for example, that neither of the two is short-circuited. This diagnosis can be made according to the following diagram:

o first open switch and second closed switch, and

o second open switch and first closed switch. In both cases, no current should be detected.

the verification of the smooth operation of the slave control module 17 by means of the data link 23,

the command to open the first switch 11 when one of these failures is detected.

The main functions of the slave control module 17 are:

the detection of a failure of the master control module 13 by means of the data link 23,

the command to open the second switch 15 when a fault is detected.

Advantageously, the master control module 13 further comprises a high voltage measurement module 29 for measuring the voltage between the high-voltage conductor 5 and the ground conductor 7 of the high-voltage electrical network. Depending on the measured high voltage value, the duty cycle of the main switch 11 can be adapted to obtain the required power of the heating resistors 31, 33 of the heating module 3.

Thus, the embodiment provides, in addition to the aforementioned redundancy in the function of the components of the device, increased security against the unwanted operation of the heating resistors through the communication between the control modules and the diagnoses that are thus made possible.

Preferably, the device 1 comprises an EMC filtering module 41 (English initials set for Electro Magnetic Compatibility) between the low voltage potential of the low voltage circuit and the primary 119 of the converter 19 (shown in FIG. 2). The EMC filtering module is adapted to suppress possible voltage variations, for example due to the electromagnetic pollution resulting from the operation of the converter 19.

Advantageously, the secure control device 1 also comprises temperature detectors 38, 39 near the transistors in order to measure the temperature of the latter. The temperature of the transistors may vary depending on the environment, e.g. ex. due to heating by the engine. When the temperature exceeds a certain value, for example, about 120 ° C, the transistor concerned is open to protect it.

Claims

Secure control device (1) for a heating module (3) comprising at least one heating resistor (31, 33) adapted to be connected in series between a high-voltage conductor (5) and a ground conductor (7). a high voltage electrical network (9), the device (1) comprising:

- a first electronic switch (11) adapted to be connected in series with said at least one heating resistor (31, 33);

a first control module (13) able to control the first electronic switch (11);

- a second electronic switch (15) adapted to be connected in series with said at least one heating resistor (31, 33) and the first electronic switch (11);

- A second control module (17) adapted to control the second electronic switch (15), the second control module (17) being floating relative to the first control module (13); and

switching conversion means (19) adapted to be connected to a low-voltage electrical network (21) and capable of independently supplying the first control module (13) and the second control module (17), the conversion means (19) comprising a galvanic isolation between the low voltage electrical network (21) and the high voltage electrical network (9).

Device (1) according to claim 1, wherein the conversion means (19) comprise two switching converters each comprising:

a primary winding adapted to be connected to the low-voltage electrical network (21) for supplying electrical energy;

- a galvanically isolated secondary winding of the primary winding; wherein the secondary winding is adapted to provide a useful voltage value by restoring the supplied electrical energy.

Device (1) according to claim 1, wherein the conversion means (19) comprises a single switching converter adapted to supply the first and second control modules (13, 17).

Device (1) according to claim 3, wherein the single switching converter (19) is a flyback converter, comprising:

a primary winding (119) able to be connected to the low-voltage electrical network (21) for supplying electrical energy;

- two secondary windings (219, 319) galvanically isolated from the primary winding (119);

Device (1) according to claim 4, wherein the single switching converter (19) further comprises:

a regulating winding (419) capable of supplying a useful voltage value by restoring the electrical energy supplied; and

a regulation module (420);

wherein the control module is adapted to measure the value of the useful voltage supplied by the regulation winding and to regulate the duty cycle of the converter to obtain a predetermined value of the useful voltage.

Device (1) according to one of the preceding claims, further comprising a first temperature detector (35) and a second temperature detector (37), the detectors being able to detect a water temperature value in the vicinity of said at least a first heating resistor (31, 33) of the heating module (3) and supplying the detected value to one of the control modules (13, 17).

7. Device (1) according to one of the preceding claims, wherein the first control module (13) is a master control module, and the second control module (17) is a slave control module.

8. Device (1) according to claim 7, wherein the master control module (13) comprises a current measuring module (313) capable of measuring a power current flowing in the first electronic switch (11) and the second electronic switch (15).

9. Device (1) according to one of claims 7 and 8, wherein the first and the second control modules (13, 17) are able to communicate with each other by a data link (23).

10. Device (1) according to one of claims 7 to 9, wherein the master control module (13) is adapted to:

- detecting a failure of one of the first and second electronic switches (11, 15) by means of the current measurement module (313) and detecting a failure of the slave control module (17) by means of the data link (23)

- control the opening of the first electronic switch (11) when one of these failures is detected.

11. Device (1) according to one of claims 7 to 10, wherein the slave control module (17) is adapted to detect a failure of the master control module (13) by means of the data link (23) and controlling the opening of the second electronic switch (15) when a failure is detected.

12. Device (1) according to one of claims 7 to 11, further comprising:

a LIN communication module (25) adapted to be connected to the low-voltage electrical network (21); and

a non-galvanic coupler (250);

wherein the LIN communication module (25) is adapted to transmit control commands of the heater module (3) to master control module (13) by means of the non-galvanic coupler (250).

13. Device (1) according to one of the preceding claims, wherein each of the first and second electronic switches (11, 15) comprises a transistor comprising a gate (G) connected to an output of the control module (13, 17). associated.

14. Device (1) according to claim 13, wherein the transistor is an IGBT or a MOSFET.

15. Device (1) according to one of claims 13 and 14, wherein each of said first and second control modules (13, 17) comprises a microcontroller (113, 117) and a gate control device (213, 217). ).

16. Device (1) according to one of the preceding claims, wherein the first and the second electronic switches (11, 15) are adapted to be connected to the same side of said at least one heating resistor (31, 33).

17. Device according to one of claims 1 to 14, wherein the first and the second electronic switches (11, 15) are adapted to be connected on either side of said at least one heating resistor (31, 33). .