FR3053467A1 - SENSOR FOR INTAKE AIR DISTRIBUTOR WITH THERMOCOUPLE - Google Patents

Abstract

The present invention relates to a sensor (1) for an intake air distributor (2) of a motor vehicle comprising a thermocouple (4) comprising two metal wires (3) of different nature welded together at two first ends (4a) forming a hot weld to measure a temperature T1 of a gas flowing inside the intake air distributor (2). The two metal wires (3) each have a second end (4b) electrically connected to a substrate (5). The sensor (1) comprises a pressure sensor (6) for measuring the pressure of the gas flowing inside the intake air distributor (2). The substrate (5) comprises an electronic component (7) making it possible to calculate the temperature T1 at the first two ends (4a) of the thermocouple (4) from a voltage measured at the second ends (4b) of the thermocouple (4) and a reference temperature T0. According to the invention, the pressure sensor (6) is integrated in the electronic component (7).

Description

Holder (s): SC2N.

Agent (s): VALEO ENGINE CONTROL SYSTEMS Simplified joint-stock company.

(34) SENSOR FOR INTAKE AIR DISTRIBUTOR WITH THERMOCOUPLE.

FR 3 053 467 - A1 (3T) The present invention relates to a sensor (1) intended for an intake air distributor (2) of a motor vehicle comprising a thermocouple (4) comprising two metal wires (3 ) of a different nature welded together at two first ends (4a) forming a hot weld to measure a temperature T1 of a gas circulating inside the intake air distributor (2). The two metal wires (3) each have a second end (4b) electrically connected to a substrate (5). The sensor (1) comprises a pressure probe (6) intended to measure the pressure of the gas circulating inside the intake air distributor (2). The substrate (5) comprises an electronic component (7) making it possible to calculate the temperature T1 at the first two ends (4a) of the thermocouple (4) from a voltage measured at the second ends (4b) of the thermocouple (4) and d 'a reference temperature T0.

According to the invention, the pressure probe (6) is integrated in the electronic component (7).

Sensor for intake air distributor with thermocouple

The present invention relates to a sensor intended to be mounted on an intake air distributor of a motor vehicle.

This type of sensor includes a temperature probe to measure the temperature of a gas mixture circulating in the intake manifold of a heat engine of a vehicle. The gas mixture consists essentially of air but may also include exhaust gases which recirculate in the intake, oil vapors from the recycling of crankcase gases, and fuel vapors which can come from the tank.

This sensor also includes a pressure probe for measuring the pressure of the gas mixture. This pressure probe is distant from the temperature probe.

The pressure and temperature measurement allows the control system driving the heat engine to determine, among other things, the density of the intake air. This information makes it possible to optimize engine control in order to reduce polluting emissions and increase performance.

Known temperature probes include a substrate which may be a printed circuit or a ceramic and a temperature probe electrically connected to the substrate. The temperature probe includes a temperature sensitive element. In order to obtain a temperature representative of the actual temperature of the flow of the gaseous fluid, the temperature-sensitive element is generally placed substantially in the center of the vein of the fluid.

To prevent the substrate from being damaged by the temperature of the gas mixture, it is separated from the sensitive element and electrically connected to the latter by metal tabs having a length conventionally between 10 and 50 mm.

According to the known prior art, the temperature probe can be a NTC thermistor (with Negative Temperature Coefficient) or a thermocouple.

The advantage of the thermocouple over the NTC thermistor is that it achieves lower response times with better accuracy.

The use of a thermocouple makes it possible to obtain a temperature accuracy of less than 0.8 ° C, or even 0.3 ° C and a response time of less than 7 seconds, or even less than 5 seconds. In addition, the thermocouple makes it possible to carry out measurements over a greater temperature range, between -200 ° C. and 350 ° C. approximately.

The measuring principle of thermocouples is based on the Seebeck effect which results in a potential difference between two wires of different metals when they are subjected to a temperature difference.

The two metal wires are welded together at a first end forming a hot weld (or hot spot) intended to measure the temperature T1 of the medium to be measured, for example the temperature of a gaseous mixture circulating in the intake manifold of a vehicle heat engine.

The two metal wires of the thermocouple also each have a second end each connected to a voltmeter by a weld commonly known as a cold weld (or cold spot) which is at a reference temperature TO.

This type of temperature sensor is known to include a printed circuit (PCB) comprising an integrated circuit integrating the voltmeter. The integrated circuit is an application-specific integrated circuit ASIC (Application Specifies for Integrated Circuit) capable of processing voltage signals to convert them into temperature. It is capable of providing an analog or digital output signal and using a protocol ("SENT").

The voltage signal measured by the voltmeter at the second ends of the metal wires is transmitted to the printed circuit via electrical conductors and then to the integrated circuit.

The voltage variation between these two second ends of the metal wires of the thermocouple is proportional to the temperature variation between the hot solder which is at temperature T1 and the second ends of the metal wires which are at a reference temperature T0.

By knowing the reference temperature TO of the cold point and the voltage between the second ends of the metal wires, it is possible to deduce the temperature T1 of the hot point.

However, these sensors are complex and expensive.

The invention therefore aims to overcome these drawbacks of the prior art by providing a sensor for an intake air distributor comprising a thermocouple simpler and less expensive than those of the prior art.

The invention relates to a sensor intended for an intake air distributor of a motor vehicle, said sensor comprising:

a thermocouple comprising two metallic wires of different nature welded together at two first ends forming a hot weld to measure a temperature T1 of a gas circulating inside the intake air distributor, said two metallic wires each comprising a second end electrically connected to a substrate, and

- a pressure probe intended to measure the pressure of the gas circulating inside the intake air distributor.

The substrate includes an electronic component making it possible to calculate the temperature T1 at the first two ends of the thermocouple from a voltage measured at the second ends of the thermocouple and from a reference temperature TO.

According to the invention, the pressure probe is integrated into the electronic component.

The sensor can also include one or more of the following characteristics, taken separately or in combination:

- the electronic component includes a temperature probe for measuring the reference temperature TO,

the electronic component comprises two separate electronic subcomponents, a first electronic subcomponent dedicated to calculating the temperature T1 and a second electronic subcomponent integrating the pressure probe and / or the temperature probe measuring the reference temperature TO,

- the temperature probe for measuring the reference temperature TO is positioned outside the electronic component and near the second ends of the thermocouple,

- the substrate comprises a heat dissipation layer,

the electronic component comprises a heat dissipation layer,

the heat dissipation layer is positioned on a first face of the substrate which is opposite to a second face supporting the electronic component,

- The second face supporting the electronic component is oriented towards the side of the first two ends of the thermocouple.

The invention thus provides a sensor for an intake air distributor comprising a thermocouple which is simpler and less expensive than those of the prior art.

The number of electronic components is reduced since the processing of the temperature data and the pressure measurement are carried out in the same electronic component.

The same integrated circuit with specific ASIC application makes it possible to process temperature and pressure and to supply digital signals.

When the electronic component comprises the temperature probe measuring the reference temperature TO, the heat dissipation layer allows better transfer of the reference temperature TO located at the location of the second ends of the thermocouple to the temperature probe. Calories are better dissipated through the substrate.

The characteristics of the invention will be described in more detail with reference to the accompanying drawings in which:

Figure 1 is a schematic representation of a sensor of the prior art; Figure 2 is a schematic representation of this sensor mounted on a vehicle air intake manifold;

Figure 3 is a schematic representation of a sensor according to an embodiment of the invention;

Figure 4 is a schematic representation of a sensor according to another embodiment of the invention.

Figure 1 shows a sensor 1 of the prior art. FIG. 2 represents this sensor 1 mounted on an intake air distributor 2 of a vehicle.

The temperature sensor 1 comprises a thermocouple 4 comprising two different metal wires 3 welded together at a first end 4a forming a hot weld (or hot spot) for measuring a temperature T1 in the engine (not shown).

The temperature T1 corresponds to the temperature of the medium to be measured. The metal wires 3 consist of two different metals, for example a pair of Nisil / Nicrosil metals. Thermocouple 4 is of type J, K, T, R, S, N, for example.

The two metal wires 3 each have a second end 4b electrically connected to a voltmeter measuring the voltage between the two second ends 4a.

The sensor 1 comprises a substrate 5 comprising an electronic component 7 formed of a semiconductor on which an integrated circuit is assembled. The substrate 5 can be a printed circuit or a ceramic.

The electronic component 7 includes the voltmeter.

Electronic component 7 is an application-specific integrated circuit ASIC (Application Specifies for Integrated Circuit) capable of processing voltage signals to convert them into temperature. It is capable of providing an analog or digital output signal and using a protocol ("SENT").

By knowing the reference temperature TO and the voltage at the second ends 4b of the metal wires 3 of the thermocouple 4, we deduce the temperature T1 of the hot solder (or hot spot) which corresponds to the temperature of the medium to be measured in the engine of the vehicle.

The sensor 1 comprises a protective casing 13 made of polymer in which the second ends 4b of the metal wires 3 of the thermocouple 4 and the substrate 5 are housed.

The substrate 5 is housed in a cavity 17 formed in the protective housing 13.

The second ends 4b of the metal wires 3 of the thermocouple 4 are electrically connected to two electrical studs 14 by welding or crimping, for example. The two electrical pads 14 are connected to the substrate 5.

The sensor 1 comprises two guide elements 15 each comprising a V-shaped or U-shaped recess arranged to receive a portion of the metal wires 3 of the thermocouple 4.

The sensor 1 comprises a connector 16 for electrically connecting it to an electronic device (not shown).

As shown in FIG. 2, representing a sensor 1 mounted on a part of an intake air distributor 2 of a motor vehicle, the first two ends 4a of the thermocouple 4 are protected by an arch 18. This arch 18 protects the first two ends 4a of the thermocouple 4 from shocks that may occur during transport of the sensor 1 before it is assembled on an intake air distributor 2.

Arch 18 is largely openwork and does not prevent the flow of air from accessing the temperature-sensitive element 5.

The sensor 1 can thus be screwed onto the portion of the intake air distributor 2, by one or more screws passing through one or more fixing lugs arranged in the sensor 1.

The sensor 1 comprises a pressure probe 6 intended to measure the pressure of the gas circulating inside the intake air distributor 2, as shown in FIG. 3.

According to the invention, the pressure probe 6 is integrated in the electronic component 7. A single electronic component 7 or integrated circuit is necessary to process the temperature and pressure data, simplifying the electronics of the sensor 1 and reducing its cost.

The electronic component 7 thus delivers digital pressure and temperature signals. The transmission of the measurement signals from the sensors 4, 6 to the electronic device using this information is done by a digital communication protocol. This allows the same electronic device to be used for the pressure probe 6 and the thermocouple 4, reducing the number of elements.

Such a sensor 1 makes it possible to combine two functions, which limits the number of mechanical interfaces to be provided for housing these sensors in their environment, and simplifies the electrical wiring, by limiting the number of connections and ramifications.

The electronic component 7 can also include the temperature probe 8 measuring the reference temperature TO, as shown in FIG. 3.

Alternatively, the temperature probe 8 measuring a reference temperature TO is placed in the vicinity, that is to say in the vicinity, or in contact with the second ends 4b of the thermocouple 4 forming the cold junction in order to avoid a shift between the measured temperature and the actual temperature, improving accuracy.

As a variant, the electronic component 7 comprises two separate electronic sub-components 9a, 9b including a first electronic sub-component 9a dedicated to calculating the temperature T1 and a second electronic sub-component 9b integrating the pressure probe 6 and the temperature probe 8 measuring the reference temperature TO, as shown in Figure 4.

Alternatively, the second electronic sub-component 9b can comprise only the pressure probe 6.

Each electronic subcomponent 9a, 9b is formed of a semiconductor or "die" in English on which an integrated circuit is assembled.

According to another embodiment illustrated in FIG. 3, the substrate 5 comprises a heat dissipation layer 10.

The heat dissipation layer 10 is positioned on a first face of the substrate 5 which is opposite to a second face 12 supporting the electronic component 7.

The second face 12 supporting the electronic component 7 is oriented towards the side of the first two ends 4a of the thermocouple 4.

When the electronic component 7 comprises the temperature probe 8 measuring the reference temperature TO, this heat dissipation layer 10 allows better transfer of the reference temperature TO from the second ends 4b of the thermocouple 4 to the temperature probe 8.

The calories are better dissipated through the substrate 5. This makes it possible to reduce the difference between the actual reference temperature TO and the temperature read by the temperature probe 8, improving the accuracy.

Claims (8)

1. A sensor (1) intended for an intake air distributor (2) of a motor vehicle, said sensor (1) comprising: - a thermocouple (4) comprising two metallic wires (3) of different nature welded together at two first ends (4a) forming a hot weld to measure a temperature T1 of a gas circulating inside the air distributor d 'inlet (2), said two metal wires (3) each comprising a second end (4b) electrically connected to a substrate (5), - a pressure probe (6) intended to measure the pressure of the gas circulating inside the intake air distributor (2), the substrate (5) comprising an electronic component (7) making it possible to calculate the temperature T1 at the first two ends (4a) of the thermocouple (4) from a voltage measured at the second ends (4b) of the thermocouple (4) and a reference temperature TO, characterized in that: - the pressure probe (6) is integrated in the electronic component (7). 2. Sensor (1) according to claim 1, characterized in that the electronic component (7) comprises a temperature probe (8) for measuring the reference temperature TO. 3. Sensor (1) according to claim 2, characterized in that the electronic component (7) comprises two separate electronic components (9a, 9b) including a first electronic component (9a) dedicated to calculating the temperature T1 and a second electronic sub-component (9b) integrating the pressure probe (6) and / or the temperature probe (8) measuring the reference temperature TO. 4. Sensor (1) according to claim 1, characterized in that the temperature probe (8) for measuring the reference temperature TO is positioned outside the electronic component (7) and near the second ends (4b) thermocouple (4). 5. Sensor (1) according to any one of claims 1 to 4, characterized in 5 that the substrate (5) comprises a heat dissipation layer (10). 6. Sensor (1) according to claim 5, characterized in that the heat dissipation layer (10) is positioned on a first face (11) of the substrate (5) which is opposite to a second face (12) supporting the component electronic (7). 7. Sensor (1) according to claim 6, characterized in that the second face (12) supporting the electronic component (7) is oriented on the side of the two first ends (4a) of the thermocouple (4). 15 8. Sensor (1) according to any one of claims 1 to 7, characterized in that the electronic component (7) comprises a heat dissipation layer (10). 1/3