WO2024068405A1

WO2024068405A1 - Ultrasonic sensor for a motor vehicle, motor vehicle, and method for producing an ultrasonic sensor

Info

Publication number: WO2024068405A1
Application number: PCT/EP2023/075992
Authority: WO
Inventors: Philipp Maurer; Paul Bou Saleh; Raffi KALAYCIYAN; Fabian Haag; Bastian Hafner
Original assignee: Valeo Schalter Und Sensoren Gmbh
Priority date: 2022-09-28
Filing date: 2023-09-21
Publication date: 2024-04-04
Also published as: DE102022124937A1

Abstract

An ultrasonic sensor (100) for a motor vehicle (1) comprises: a plastics housing (2); a diaphragm cup (7) that is inserted into an opening (12) in the plastics housing (2) and has an ultrasonic diaphragm (8); a sound transducer element (25) for inducing and sensing vibration of the ultrasonic diaphragm (8), which sound transducer element is mounted on the ultrasonic diaphragm (8) from the inside; a circuit board (16) which is disposed in the interior (14) of the plastics housing (2) and on which a driver circuit (19) for controlling the sound transducer element (25) is mounted; two contact pins (20, 21) for bringing the driver circuit (19) into electrical contact with the sound transducer element (25), the circuit board (16) being pressed onto the contact pins (20, 21) such that ends (35) of the contact pins (20, 21) pass through the circuit board (16); and a metal hood (40) which, together with the circuit board (16), surrounds and shields on all sides the ends (35) of the contact pins (20, 21) passing through the circuit board (16).

Description

ULTRASONIC SENSOR FOR A MOTOR VEHICLE, MOTOR VEHICLE AND

MANUFACTURING PROCESS FOR AN ULTRASONIC SENSOR

The present invention relates to an ultrasonic sensor for a motor vehicle and a motor vehicle.

Modern motor vehicles are equipped with ultrasonic sensors that allow the surroundings of the motor vehicle to be measured by sending and receiving an ultrasonic signal. The information about the vehicle surroundings obtained in this way can be evaluated by a driver assistance system in order to generate warnings for the driver, enable autonomous parking or partially or fully autonomous driving.

An ultrasonic sensor typically has a plastic housing with an opening into which a membrane pot is inserted. A sound transducer element for stimulating vibrations and detecting vibrations of the ultrasonic membrane is arranged from the inside on an ultrasonic membrane of the membrane top. A printed circuit board is also arranged in the interior of the plastic housing, on which a driver circuit for controlling the sound transducer element is mounted. Contact pins are used to contact the driver circuit with the sound transducer element. In particular, unamplified signals on the line from the sound transducer element via the contact pins to the driver circuit are particularly susceptible to electromagnetic interference.

Conventionally, to shield against electromagnetic interference, a shield plate was arranged on a top side (a side facing away from the sound transducer element) of the circuit board, which essentially covered the entire circuit board or at least the entire area of the components of the driver circuit mounted, for example, on the underside of the circuit board. The entire arrangement was then cast with a synthetic resin. However, it is desirable to avoid potting as this adds up to 20 g of additional weight, alters the stress characteristics of the ultrasonic sensor and thereby increases the risk of component breakage. Without casting, it is not possible to securely mount a large-area shielding plate that is then freely arranged inside the plastic housing. The shielding plate would vibrate under the influence of the ultrasound and come loose. For this reason, the shielding plate is dispensed with and relies on downstream signal processing and compliance with minimum distances during installation in order to deal with electromagnetic interference.

However, in certain installation situations, such as in the bumper of a motor vehicle, the EMC immunity is not yet satisfactory.

WO 2017/097496 discloses that a membrane of a sound transducer element can be connected to a mass.

The US 2019/0388936 A1 discloses a membrane pot for an ultrasonic transducer. The membrane pot is provided with a metallic coating. A piezo element attached to the membrane from the inside is electrically connected to the metallic coating. The membrane pot accordingly implements an electrical functionality, in particular an electrical ground, to improve EMC protection.

US 2006/0229785 A1 discloses a pedestrian protection system in which a plurality of ceramic sensors are applied to a carrier film. The carrier film has a continuous metallization layer or metallic protective layer for EMC shielding of the plurality of ceramic sensors.

Against this background, one object of the present invention is to improve the EMC immunity of an ultrasonic sensor. According to a first aspect, an ultrasonic sensor for a motor vehicle is proposed to solve the problem, which has: a plastic housing, a membrane pot with an ultrasonic membrane inserted into an opening in the plastic housing, a sound transducer element attached to the ultrasonic membrane from the inside for exciting and detecting vibrations of the ultrasonic membrane, a circuit board arranged in the interior of the plastic housing, on which a driver circuit for controlling the sound transducer element is mounted, two contact pins for electrically contacting the driver circuit with the sound transducer element, wherein the circuit board is pressed onto the contact pins in such a way that ends of the contact pins pass through the circuit board, and a metallic hood which, together with the circuit board, surrounds and shields the ends of the contact pins passing through the circuit board on all sides.

The inventors have recognized that the contact pins penetrating the circuit board play a crucial role as antennas for electrical interference. However, pressing the circuit board onto the ends of the contact pins in such a way that they penetrate the circuit board is desirable and advantageous, since in this case a simple manufacturing process and a more stable and higher quality connection between the contact pins and the circuit board can be achieved than in a case in which the contact pins are only soldered to the circuit board from one side. According to the proposed ultrasonic sensor, the contact pins penetrating the circuit board are now shielded by the metal hood. This advantageously allows a field input from an electric field to be diverted before it can couple into the capacitance formed by the contact pins running essentially parallel to one another. Accordingly, the interference immunity of the ultrasonic sensor against electric fields can advantageously be improved. It is therefore also harmless if the contact pins form a high capacitance. It is therefore now possible to arrange the contact pins very close to one another.

An inductance formed by the contact pins can therefore advantageously be kept low. Accordingly, the immunity of the ultrasonic sensor to magnetic fields can also be advantageously improved. Overall, the EMC interference immunity of the ultrasonic sensor can thus advantageously be improved. The membrane pot with ultrasonic membrane can be made in one piece. This means that the membrane pot can be a cup-shaped element. A bottom surface of the pot shape can be made thinner than walls of the pot shape. In this case, the floor surface in particular forms the ultrasonic membrane.

The contact pins can be pressed into the plastic housing and thereby be attached to the housing in a vibration-proof manner. The contact pins can be pressed into the plastic housing before the circuit board is pressed onto the ends of the contact pins.

The contact pins can be contacted with the driver circuit, for example, by the ends of the contact pins being pressed into a through-hole, also known as a via, with a metallized, for example tinned, inner surface when the circuit board is pressed onto the ends of the contact pins. Accordingly, a reliable electrical contact between the contact pins and the driver circuit can be provided.

The sound transducer element is, for example, a piezo element. Controlling the sound transducer element comprises in particular sending a control signal to the sound transducer element and then receiving a reception signal from the sound transducer element.

The end of each contact pin that passes through the circuit board can also be referred to as the "upper end". At a lower end opposite the upper end, the contact pins can be directly contacted with the sound transducer element, for example soldered. The contact pins can also be indirectly contacted with the sound transducer element. For example, a loose fine wire can be used to connect a lower end of each of the contact pins to the sound transducer element. An area between the sound transducer element and the lower end of the contact pin, in The area through which the loose fine wire runs can be filled with foam. This can provide additional sound insulation.

The term "enclosed on all sides together with the printed circuit board" is to be understood in particular as meaning that a space in which the upper ends of the contact pins are arranged is delimited in every spatial direction either by a surface of the metallic hood or by a surface of the printed circuit board.

The metal hood is in particular a grounded metal hood. "Grounded" is to be understood in particular as a connection to a ground that is at least not high-resistance. "Not high-resistance" is to be understood in particular as a resistance to ground of less than 1000 ohms, preferably less than 800 ohms, particularly preferably less than 600 ohms.

According to one embodiment, the driver circuit comprises one or more electronic components mounted on the circuit board on the same side of the circuit board as the metallic hood, outside the metallic hood.

The components are arranged outside the metallic hood and are therefore not shielded by it. However, the metallic hood shields the ends of the contact pins, where electrical interference fields are most likely to couple in. The metallic hood is therefore advantageously small and can be mounted on the circuit board in a vibration-proof manner. This means that it is advantageously possible to dispense with casting the interior of the plastic housing.

The side of the circuit board on which the metallic hood, the ends of the contact pins passing through the circuit board and, according to the present embodiment, also the electronic components are arranged, can also be referred to as the top side. The other side of the circuit board, on which the remaining sections of the contact pins are arranged and contact the sound transducer element, can also be referred to as the underside. The electronic components can be, for example, a capacitor, a coil, a transistor, an operational amplifier, a processor, an ASIC and the like.

According to a further embodiment, an interior space in the plastic housing is not cast at least on the same side of the circuit board as the metallic hood.

The interior space can be, in particular, a free space, i.e. a space that is not filled, on the top side of the circuit board, as long as it is not occupied by the metallic hood or the components.

Accordingly, the weight of the ultrasonic sensor can be reduced, the ultrasonic sensor can be less rigid and material breakages are advantageously less likely. At the same time, excellent damping against electric fields is still provided by the metallic cover.

According to a further embodiment, the circuit board is mounted on a projection of the plastic housing.

The seated bearing on the projection of the housing advantageously offers stability and vibration resistance.

The projection of the plastic housing is in particular an inwardly projecting projection. The projection can be ring-shaped or circumferential. The projection can be formed in particular near the diaphragm pot, where a main section of the plastic housing narrows to the opening into which the diaphragm pot is inserted. A seated mounting on such a projection can in particular only be made possible by the fact that the components are advantageously arranged on the top of the circuit board. This in turn can in particular be made possible by that the metallic cover provides shielding against electrical interference fields, which could not previously be provided with conventional solutions for components arranged on the top.

According to a further embodiment, the metallic hood has four walls that run perpendicular to the circuit board and a wall that runs parallel to the circuit board and above the ends of the contact pins.

In other words, the metal hood is in particular a cuboid or cube-shaped hood. Such a hood is particularly easy to manufacture. It can also be attached to the circuit board in a vibration-proof manner at three edges where it is perpendicular to the circuit board and can have an advantageously high level of rigidity.

According to a further embodiment, an outer wall of the metallic hood is arranged at an edge of the circuit board, and a tab formed continuously with the outer wall runs past the edge of the circuit board towards the membrane pot.

Thus, a section of the contact pins on the underside of the circuit board between the circuit board and the membrane pot can also be advantageously shielded by the tab and the shielding effect can be further improved.

“Arranged at an edge” can mean in particular that the outer wall is arranged in such a way that the tab running from the outer wall towards the membrane pot touches the edge of the circuit board.

The tab and the outer wall can in particular be formed in one piece. The metallic hood can be formed in one piece as a whole, with the tab and the outer wall being sections of the one-piece metallic hood. The outer wall can be one of the walls running perpendicular to the circuit board. The tab extends at least in one direction towards the diaphragm cup. Particularly preferably, the tab extends partially to the diaphragm cup or to a level of the diaphragm cup.

According to a further embodiment, the tab runs parallel to a plane formed by the two contact pins and is as wide as or wider than a distance between the two contact pins.

Thus, a capacitance formed by the two contact pins is advantageously shielded by the tab in a section of the contact pins that runs along the tab.

According to a further embodiment, the metallic hood is contacted with the circuit board and grounded.

Accordingly, grounding of the metal cover can advantageously be provided via a conductor track of the circuit board. In addition to the two contact pins that serve to contact the sound transducer element, the circuit board can be pressed onto further contact pins that connect the inside of the plastic housing to an outside of the plastic housing. In this way, a vehicle ground can be led into the ultrasonic sensor and to the metal cover for grounding the metal cover.

According to a further embodiment, the metallic hood is contacted with the circuit board by means of a spring pin which is formed continuously with one of the walls of the metallic hood and which is pressed into a through-plating of the circuit board.

It is therefore advantageously possible to press the metallic cover into the through-holes of the circuit board in a particularly simple manner when assembling the ultrasonic sensor, whereupon the spring pin is pushed back into the housing due to the restoring force after insertion. presses to form a stable seat. This allows the entire metal hood to be mounted on the circuit board in a simple, vibration-proof and stable manner.

Preferably, more than one wall of the metallic hood is provided with a respective spring pin; particularly preferably, at least three of the four walls running perpendicular to the circuit board and standing perpendicular to the circuit board are provided with a respective spring pin.

The spring pin can in particular be formed as a single piece with the metallic cover.

The through-hole can also be referred to as a contact hole or via. In particular, it can have a metallized, for example tin-plated, inner surface that is grounded and is in contact with the spring pin when it is pressed into the plated-through hole.

According to a further embodiment, the spring pin is designed as an eyelet enclosing an elongated hole.

Accordingly, the spring pin can be particularly easily formed in one piece with the rest of the metal hood, for example by punching from a metallic sheet.

According to a further embodiment, the metallic hood is made of copper or brass sheet with a sheet thickness between 0.2 and 0.4 mm, preferably 0.3 mm.

Accordingly, electrical eddy currents with a frequency in the working range of the ultrasonic sensor are optimally dampened and at the same time with the minimum amount of material required. For example, the penetration depth of an electrical eddy current with a frequency of 50 kHz in copper is approximately 0.3 mm. According to a further embodiment, the metallic hood is punched and folded in one piece from the copper or brass sheet.

Accordingly, a simple and cost-effective manufacturing process is possible.

According to a further embodiment, the membrane pot is a metallic membrane pot that is not connected to ground with a high resistance.

Accordingly, the diaphragm pot is grounded and can advantageously also have a shielding effect against electromagnetic interference fields. In a particularly preferred embodiment, in which the metal hood also has the tab that runs up to the diaphragm pot, an entire current path of the not yet amplified raw signals of the sound transducer element from the metal element via the contact pins to the driver circuit can be shielded against electrical interference fields by the interaction of the metal diaphragm pot, the metal hood and their walls and their tab.

The diaphragm pot can be made of aluminum, for example. Alternatively, the diaphragm pot can be made of a non-metallic material and have at least one metallic coating; such a diaphragm pot is also considered a metallic diaphragm pot in the sense of the present embodiment.

"Grounded" is understood to mean in particular a connection to a ground that is at least not high-resistance. "Not high-resistance" is understood to mean in particular a resistance to ground of less than 1000 ohms, preferably less than 800 ohms, particularly preferably less than 600 ohms.

According to a further aspect, a motor vehicle with an ultrasonic sensor according to the first aspect or one of the embodiments of the first aspect is proposed. The motor vehicle can be, for example, an automobile or a passenger car or even a truck.

According to a third aspect, a method for producing an ultrasonic sensor is specified. The method comprises: pressing two contact pins into a plastic housing; inserting a membrane pot with an ultrasonic membrane and a sound transducer element attached to the ultrasonic membrane from the inside for exciting and detecting vibrations of the ultrasonic membrane into an opening in the plastic housing; contacting the contact pins with the sound transducer element; pressing a circuit board on which a driver circuit for controlling the sound transducer element is mounted onto the ends of the contact pins in such a way that the ends pass through the circuit board; producing a metallic hood by punching out a blank from a copper or metal sheet and folding the blank; and mounting the metallic hood on the circuit board in such a way that the metallic hood, together with the circuit board, surrounds and shields the ends of the contact pins passing through the circuit board on all sides.

The embodiments and features described for the proposed ultrasonic sensor apply accordingly to the proposed motor vehicle and the proposed manufacturing method.

Further possible implementations of the invention also include combinations of features or embodiments described above or below with respect to the exemplary embodiments that are not explicitly mentioned. The person skilled in the art will also add individual aspects as improvements or additions to the respective basic form of the invention.

Further advantageous refinements and aspects of the invention are the subject of the subclaims and the exemplary embodiments of the invention described below. The invention is further explained in more detail using preferred embodiments with reference to the accompanying figures. Fig. 1 shows an ultrasonic sensor according to exemplary embodiments;

Fig. 2 shows a motor vehicle according to embodiments;

Fig. 3A-D show possible electrical interference fields;

4 shows a section AA in FIG. 1 of an ultrasonic sensor according to a first exemplary embodiment;

Fig. 5 shows a section B-B in Fig. 4;

Fig. 6 shows a section A-A in Fig. 1 of an ultrasonic sensor according to a second

embodiment;

Fig. 7 shows a section B-B in Figs. 6, 8;

Fig. 8 shows a section CC in Figs. 6, 7;

Fig. 9 shows a blank according to the second exemplary embodiment; and

Fig. 10 shows a manufacturing method according to a third embodiment.

In the figures, identical or functionally identical elements have been given the same reference numbers unless otherwise stated.

Fig. 1 shows an ultrasonic sensor 100 according to exemplary embodiments. The ultrasonic sensor has a housing 2 made of plastic and a metallic membrane pot 7 with an ultrasonic membrane 8 inserted into an opening (not shown in FIG. 1) of the housing 2. The housing has a body 3, a union ring 4, a cover 5 and an extension section 6. The union ring 4 holds the membrane pot 7 on the body 3 of the housing 2. The cover 5 is placed on the body 3 in an interior of the housing 2 after the components described in more detail have been assembled. The union ring 4, the lid 2 and the extension section 6 can be joined to the body 3, for example by ultrasonic welding.

The ultrasonic sensor 100 is set up to emit ultrasonic signals by controlling the ultrasonic membrane 8, with a central direction of an emitted ultrasonic signal lobe coinciding with an axial direction 13 of the membrane pot 7. Here the ultrasonic membrane 8 serves as a “loudspeaker”. The ultrasonic sensor 100 is also set up to receive reflected ultrasonic signals, for example from the surroundings of a motor vehicle 1 (FIG. 2). The ultrasonic membrane 8 serves as a “microphone”. Signals for controlling the ultrasonic membrane 8 as well as received signals supplied by the ultrasonic membrane 8 are led out of the housing 2 of the ultrasonic sensor 100 through signal lines (not shown) through the extension section 6.

Fig. 2 shows a motor vehicle 1 according to embodiments. The motor vehicle 1 has several of the ultrasonic sensors 100. A first ultrasonic sensor 101 is arranged in a front bumper 52 of the motor vehicle 1. Three ultrasonic sensors 102, 103, 104 are arranged in a side sill 9 of the motor vehicle 1. An ultrasonic sensor 105 is arranged in a rear bumper 10 of the motor vehicle 1.

In the front bumper 52 of the motor vehicle 1, for example, a line 11 of a local instrumentation network, LIN, is also arranged in the immediate vicinity of the ultrasonic sensor 101. LIN is a simple standard for data-based vehicle on-board networks and is used, for example, for rain sensors, wiper motors, spray devices and the like. The signals of a LIN are rectangular with a stroke of 12 V and have a rise rate of 2 V / ps. A LIN operates at a frequency of 19 kHz. A harmonic overtone of this is three times that, i.e. 57 kHz, and thus in a range in which the ultrasonic sensor 101 also sends out and receives acoustic ultrasonic signals. Within the ultrasonic sensor 101, as explained later with reference to Fig. 4 and Fig. 5, electrical signals that correspond to the acoustic ultrasonic signals are generated by a sound transducer element 25 (Fig. 5). Thus, electrical fields generated by line 11 of the LIN represent potential interference fields for the ultrasonic sensor 101. For example, the ultrasonic sensor 101 could falsely signal the reception of an ultrasonic echo, although in fact only an interference field from a signal on line 11 has disturbed the ultrasonic sensor 101. This is referred to as "ghost echoes". This problem is particularly pronounced in the front bumper 52 of the motor vehicle 1, since a required minimum distance between the ultrasonic sensor 101 and the line 11 may not be maintained due to limited space.

Possible relative spatial arrangements of ultrasonic sensor 101 and line 11 are shown in FIGS. 3A-D. The course of field lines of an electrical interference field is indicated by arrows. As can be seen in FIGS. 3A-D, the electrical interference field acts on the ultrasonic sensor 101 primarily from the left and from above.

Fig. 4 shows a section A-A in Fig. 1 of the ultrasonic sensor 100 in a design according to a first embodiment, and Fig. 5 shows a section B-B in Fig. 4. In the following, reference is made to Fig. 4 and Fig. 5. A direction indication "downward" and a location indication "down" refer hereinafter to a direction along the axial direction 13 downwards in Fig. 5 or into the plane of the page in Fig. 4. A direction indication "upward" and a location indication "up" refer hereinafter to a direction opposite the axial direction 13 upwards in Fig. 5 or out of the plane of the page in Fig. 4.

As can be seen in Fig. 5, the diaphragm cup 7 is placed on an edge 11 of the downwardly open body 3. The collar ring 4 is placed on the diaphragm cup 7 and the body 3. Accordingly, the diaphragm cup 7 is inserted into an opening 12 of the housing 2 formed by the body 3 and the collar ring 4.

A circuit board 16 is arranged in an interior space 14 of the housing 2. Electronic components 17, 18 of a driver circuit 19 are arranged on the circuit board 16. The driver circuit 19 can also comprise conductor tracks (not shown) that run on or in the circuit board 16.

Several first contact pins 20, 21 are pressed into the body 3 of the housing 2. Furthermore, several second contact pins 22, 23, 24 are pressed into the body 3 and the extension section 5 of the housing 6. The first contact pins 20, 21 are used to contact the driver circuit 19 with a piezo element 25 arranged on an inside of the ultrasonic membrane 8. Lower ends of the first contact pins 19, 20 are indirectly contacted with the piezo element 25 via respective loose, non-tensioned fine wires 26 . A lower area 28 of the interior 14 in the area of the loose wires 26 can be filled with foam. In this way, an advantageous vibration decoupling is achieved between the ultrasonic membrane 8 with the piezo element 25 on the one hand and the housing 3 and the circuit board 16 on the other hand.

The second contact pins 22, 23, 24 are used to contact the driver circuit 19 with lines (not shown) which lead out of the ultrasonic sensor 100 through the extension section 6 and can be connected, for example, to a control unit (not shown) of the motor vehicle 1 (FIG. 2). .

The circuit board 16 has several through-holes 29-33. The circuit board is pressed onto the upper ends 35, 36 of the contact pins 20-24 so that the upper ends 35, 36 of the contact pins 20-24 pass through the through-holes 29-33 of the circuit board 16. In this way, the contact pins 20-24 are contacted with the driver circuit 19. At the same time, this results in a firm fit of the circuit board 16 on the contact pins 20-24.

In addition, the circuit board 16 is particularly preferably supported on a circumferential and inwardly projecting projection 15 of the housing 2. Supporting the projection 15 arranged far below is made possible by the fact that the components 17, 18 of the driver circuit 19 are arranged on the top side of the circuit board 16, i.e. on the same side as the upper ends 35, 36 of the contact pins 20-24 passing through the circuit board 16. The circuit board 16 is thus advantageously pressed and supported in the housing 2 in a stable and firm manner, in particular vibration-proof.

During operation, the driver circuit 19 is connected via the contact pins 22, 23, 24 and the lines (not shown) from the control unit (not shown) of the motor vehicle 1 (FIG. 2). controls. The driver circuit generates a suitable electrical control signal for the piezo element 25 and transmits this to the piezo element 25 via the contact pins 20, 21 and the loose fine wires 26. In response to the control signal, the piezo element 25 excites the ultrasonic membrane 8 of the membrane pot 7 to oscillate, whereby an acoustic ultrasonic signal is emitted in the axial direction 13. When this ultrasonic signal is reflected back to the ultrasonic membrane 8 in the surroundings of the motor vehicle 1 (FIG. 2), it is excited to oscillate. The piezo element 25 detects the vibrations of the ultrasonic membrane 8 and sends an electrical reception signal, which is indicative of the received ultrasonic signal, to the driver circuit 19 via the loose fine wires 26 and the contact pins 20, 21. The driver circuit 19 amplifies the reception signal and sends it via the Contact pins 22, 23, 24 and the lines, not shown, to the control unit, not shown, of the motor vehicle 1 (Fig. 2). The control device, not shown, can, for example, determine a distance to an obstacle in the surroundings of the motor vehicle 1 (FIG. 2) based on a transit time difference between emitting the ultrasonic signal and receiving the reflected ultrasonic signal.

It should be noted that an un-amplified and therefore very weak electrical reception signal is transmitted from the piezo element 25 to the driver circuit 19 via the contact pins 20, 21 and the fine wires 26, 27. This reception signal is particularly susceptible to electrical and magnetic interference fields.

The distance between the contact pins 20 and 21 is therefore chosen to be narrow, as shown in Fig. 4. The distance between the two contact pins 20, 21 is, for example, no more than 5 mm, preferably no more than 3 mm, particularly preferably no more than 1 mm. In this way, an inductance of a coil formed by the contact pins 20, 21, the circuit board 16 and the piezo element 25, via which a magnetic interference field could couple in, is low.

Furthermore, the membrane pot 7 is made of a metal or is provided with a metallic coating and therefore shields the loose fine wires 26 against electrical shield against interference fields. Particularly preferably, the membrane pot 7 is also connected directly to ground or at least not with high resistance, for example with a resistance of 600 ohms to 800 ohms, in any case with a resistance of less than 1000 ohms, in order to be able to develop this shielding effect as best as possible. For this purpose, for example, a line (not shown) running in the body 3 can be used, which connects the membrane pot 2 to one of the second contact pins 22-24.

The first contact pins 20, 21 are also comparatively well shielded along their course by the membrane pot 7 on the one hand and by the circuit board 16 on the other hand.

However, the inventors have recognized that electrical interference fields couple into the signal path from the piezo element 25 to the driver circuit 19, in particular at the upper ends 35 of the first contact pins 20, 21 which pass through the circuit board 16 and protrude upwards.

Therefore, according to the first embodiment, a metallic hood 40 is arranged on the circuit board 16 in such a way that, together with the circuit board 16, it surrounds and shields the upper ends 35 of the first contact pins 20, 21 on all sides.

Experiments have shown that the interference of the electric fields shown in Fig. 3A-3D is significantly reduced. This effect is particularly pronounced in the configurations shown in Fig. 3B and Fig. 3D, in which the electric interference field acts on the ultrasonic sensor 100, 101 from above.

However, the metallic hood 40 surrounds and shields neither the upper ends 36 of the second contact pins 22-24 nor the components 17, 18 of the driver circuit 19. The majority of the conductor tracks (not shown) on the circuit board 16 are also not covered by the metallic hood 40. Accordingly, the metallic hood 40 can advantageously be designed with a small size and a low weight. The metallic hood 40 can thus be manufactured using simple means, comparable to other components 17, 18, vibration-resistant on the circuit board 16 and hardly contributes to an increase in the weight of the ultrasonic sensor 100. In particular, with such a small metallic hood 40, it is particularly advantageous that no encapsulation of the interior 14 of the ultrasonic sensor 100 is required in order to achieve vibration resistance.

The metallic hood 40 can in particular be made from a copper or brass sheet. The sheet thickness is preferably set up in such a way that a penetration depth of an expected electrical interference field is essentially completely absorbed in the sheet, but the sheet does not become unnecessarily thick. In the case of the LIN discussed with reference to FIG. 2 as a source of interference, a sheet thickness of 0.3 mm is sufficient. The sheet thickness is preferably at least 0.2 and at most 0.4 mm.

Fig. 6 shows a section A-A in Fig. 1 of an ultrasonic sensor 100 according to a second embodiment, Fig. 7 shows a section B-B in Figs. 6, 8, and Fig. 8 shows a section C-C in Figs. 6, 7. Reference is made below to Figs. 6 to 8. Features of the second embodiment that are similar to the features of the first embodiment will not be described in detail again. The second embodiment differs from the first embodiment as follows:

The circuit board 16 does not lie flush along its entire circumference against an inner surface 37 of the body 3. In a section on the left in Fig. 6, 7, which is arranged opposite the extension section 6 of the housing 2, a recess 38 is formed in the circuit board 16. The metallic hood 40 is arranged on an edge 39 of the circuit board 16, which borders on the recess 38, and projects slightly into the recess 38.

The annular projecting projection 15 of the body 3 of the housing 2, on which the circuit board 16 is mounted, also has a recess 47 in an area of the recess 38 of the circuit board 16. According to the second exemplary embodiment, the metallic hood 40 has a cube or cuboid shape in a section arranged above the circuit board 16 with four vertical walls 41, 42, 43, 44 running perpendicular to the circuit board and one parallel to the circuit board 16 above the ends 35 the first contact pins 20, 21 extending horizontal wall 45. Here, an outer vertical wall 41 is arranged close to the edge 39 of the circuit board 16 above the recess 38. 7, a tab 46 formed continuously with the outer vertical wall 41 runs from a lower end of the vertical wall 41 through the recess 38 of the circuit board 16, past the edge 39 of the circuit board 16 and through the recess 47 in the inwardly projecting projection 15 of the housing 2 downwards towards the membrane pot 7. As can be seen in FIGS. 7, 8, the tab 46 runs parallel to a plane formed by the first contact pins 20, 21. As can be seen in FIG. 8, the tab 46 is only slightly wider than a distance between the first contact pins 20, 21, which in turn run parallel to one another on the membrane pot 7. The tab 46 is in particular not wider than and preferably narrower than the outer wall 41, of which it represents an extension.

With the tab 46 extending onto the diaphragm cup 7 according to the second embodiment, a vertical section of the first contact pins 20, 21 between the circuit board 16 and the diaphragm cup 7 can also advantageously be shielded against electrical interference field inputs, in particular from the left in Fig. 7 (cf. Fig. 3A and Fig. 3C).

As shown in Fig. 7, an inner vertical wall 42, which is arranged opposite the outer vertical wall 41, also has a spring pin 48. The spring pin 48 is pressed into another via 34 of the circuit board 16 and is held stably in the via 34 by a spring force (restoring force) of the spring pin 48. The via 34 can have a tinned inner surface that is connected to ground. Accordingly, the metallic hood 40 is contacted and grounded with the circuit board 16 via the spring pin 48 of the inner vertical wall 42. Fig. 9 shows a blank 50 according to the second embodiment. The blank 50 is a shape punched out of a copper or brass sheet with a thickness of between 0.2 and 0.4 mm, preferably 0.3 mm. If the blank 49 is folded along the dashed-dotted fold lines, for example backwards in the plane of the sheet, the result is the metallic hood 40 (Fig. 6-8) with the four vertical walls 41-44, the horizontal wall 45, the tab 46, which is continuously connected to the outer vertical wall 41, and the spring pin 48.

The spring pin 48 is in particular designed, for example, as an eyelet 51 enclosing an elongated hole 49. The eyelet has, for example, a wall thickness of 0.3 mm, and the elongated hole 49 is, for example, a 1 mm hole. When the spring pin 48 is pressed into the via 34 (FIG. 7), the elongated hole 49 is compressed and exerts a restoring force which is in the via 34 (FIG. 7) perpendicular to an inner surface of the via 34 (FIG. 7). acts on the outside and the metallic hood 40 (Fig. 7) is fixed to the circuit board 16 (Fig. 7).

Fig. 10 illustrates a manufacturing method of the ultrasonic sensor 100 according to a third embodiment. Reference is also made to Figs. 4 to 10.

In step S1, the first contact pins 20, 21 and the second contact pins 22-24 are pressed into the body 3 made of plastic (into the housing 2).

In step S2, the membrane pot 7, to whose ultrasonic membrane 8 the sound transducer element 25 is attached from the inside, is inserted into an opening 12 of the housing 2. For example, the membrane pot 7 can be placed on an edge 11 of the body 3, as shown in Fig. 7, 8, and the collar ring 4 can be thrown over the membrane pot 7 and the body 3. The collar ring can then be joined to the membrane pot 7 and the body 3, for example by means of ultrasonic welding. In step S3, the first contact pins 20, 21 are contacted with the sound transducer element 25. For this purpose, for example, the first contact pins 20, 21 are soldered to the loose fine wires 26, 27 and the loose fine wires 26, 27 are soldered to the sound transducer element 25.

In step S4, the circuit board 16 on which the driver circuit 19 is mounted is pressed onto the upper ends 35, 36 of the contact pins 20-24 in such a way that the ends 35, 36 pass through the circuit board 16.

In step S5, the blank 50 shown in Fig. 9 is punched out of a copper or metal sheet and folded along the dash-dot fold lines, thus obtaining the metallic hood 40.

In step S6, the metallic hood 40 is mounted on the circuit board 16 in such a way that the metallic hood 40 surrounds and shields the upper ends 35 of the first contact pins 20, 21 that pass through the circuit board 16 on all sides. For mounting, for example, the spring pin 48 in particular is pressed into the through-hole 34 of the circuit board 16, whereby the metallic hood 40 is fixed to the circuit board 16, contacted with it and grounded.

The lid 5 can then be placed on the body 3 and joined to it by ultrasonic welding.

Thus, an ultrasonic sensor 100 according to the third embodiment is obtained.

An ultrasonic sensor 100 according to exemplary embodiments can therefore be particularly easy to manufacture, have a vibration-stable construction with vibration-proof mounting of the circuit board 16 and vibration-proof attachment of the metallic hood 40, do not require casting of an interior 14 of the plastic housing 2, be light and unbreakable, and thanks to the parallel first contact pins 20, 21 and at least the The ends 35 of the first contact pins 20, 21 that pass through the circuit board 16 have excellent EMC interference immunity.

Although the present invention has been described using embodiments, it is capable of being modified in many ways. Features disclosed for different embodiments can be combined with one another in any suitable manner, provided that this does not result in contradictions.

The union ring 4 is not a necessary feature of the invention, and the membrane pot 7 can also be inserted directly into an opening in the body 3 of the housing 2.

The loose fine wires 26, 27 are not necessary. The contact pins 20, 21 can also be contacted with the piezo element 25 in another way, for example directly.

In the figures, three second contact pins 22-24 are shown, but only two or more than three second contact pins 22-24 can be used for external connection.

The metallic hood 40 does not necessarily need to have a cube or cuboid shape with five walls, particularly in the first but also in the second exemplary embodiment. For example, it can also be hemispherical.

In the second exemplary embodiment, the tab 46 does not need to extend close to the membrane pot 7, as shown in FIG. In order to achieve the desired additional shielding effect of the tab 46, it is sufficient if the tab extends from the underside of the circuit board 16 at least a certain distance in the direction of the membrane pot 7. On the other hand, according to an advantageous development, the tab 46 can also extend all the way to the membrane pot 7 and contact it. In this way, the membrane pot 7 can advantageously be easily grounded via the tab 46 of the metallic hood 40. Only a spring pin 48 attached to the inner wall 42 has been described. However, it is understood that a respective spring pin 48 can be formed on one or more of the inner wall 42, the side walls 43, 44 and the outer wall 41 and can be pressed into respective vias 34 of the circuit board 16. If several spring pins 48 are present, the metallic hood 40 can be mounted and fixed on the circuit board 16 even more reliably.

LIST OF REFERENCE SYMBOLS

1 motor vehicle

2 housings

3 body

4 union ring

5 lids

6 Extension section

7 Diaphragm pot

8 Ultrasonic membrane

9 Side skirts

10 Rear bumper

11 edge

12 Opening in the housing

13 Axial direction

14 interior

15 Housing projection

16 Circuit board

17, 18 Component

19 Driver circuit

20, 21 contact pin, first contact pin

22-24 Contact pin, second contact pin

25 piezo element, sound transducer element

26, 27 loose fine wire

28 lower area

29-34 Through-hole plating

35, 36 top ends

37 body inner surface

38 Circuit board recess

39 Edge of the circuit board 40 metallic hood

41 outer vertical wall

42 inner vertical wall

43, 44 lateral vertical wall 45 horizontal wall

46 tab

47 Recess of the cantilevered projection

48 Spring pin

49 slotted hole 50 punched metal sheet, blank

51 eyelet

52 Front bumper

100-105 ultrasonic sensor

S1 -S6 process steps

Claims

PATENT CLAIMS

1 . Ultrasonic sensor (100) for a motor vehicle (1), comprising: a plastic housing (2), a membrane pot (7) inserted into an opening (12) of the plastic housing (2) with an ultrasonic membrane (8), an ultrasonic membrane (8) sound transducer element (25) attached from the inside for vibration excitation and vibration detection of the ultrasonic membrane (8), a circuit board (16) arranged in the interior (14) of the plastic housing (2), on which a driver circuit (19) for controlling the sound transducer element (25) is mounted , two contact pins (20, 21) for electrically contacting the driver circuit (19) with the sound transducer element (25), the circuit board (16) being pressed onto the contact pins (20, 21) in such a way that ends (35) of the contact pins (20 , 21) pass through the circuit board (16), and a metallic hood (40), which, together with the circuit board (16), surrounds on all sides the ends (35) of the contact pins (20, 21) passing through the circuit board (16). and shields.

2. Ultrasonic sensor according to claim 1, characterized in that the driver circuit (19) comprises one or more electronic components (17, 18) which are mounted on the same side of the circuit board (16) as the metallic hood (40) outside the metallic hood (40) on the circuit board (16).

3. Ultrasonic sensor according to claim 2, characterized in that an interior space (14) in the plastic housing (2) is not encapsulated at least on the same side of the circuit board (16) as the metallic cover (40).

4. Ultrasonic sensor according to claim 2 or 3, characterized in that the circuit board (16) is mounted on a projection (15) of the plastic housing (2).

5. Ultrasonic sensor according to one of the preceding claims, characterized in that the metallic hood (40) has four walls (41-44) running perpendicular to the circuit board (16) and one parallel to the circuit board (16) and above the ends (35). the contact pins (20, 21) has a wall (45).

6. Ultrasonic sensor according to one of the preceding claims, characterized in that an outer wall (41) of the metallic hood (40) is arranged at an edge (39) of the circuit board (16) and a tab (46) formed continuously with the outer wall (41) runs past the edge (39) of the circuit board (16) towards the diaphragm pot (7).

7. Ultrasonic sensor according to claim 6, characterized in that the tab (46) runs parallel to a plane formed by the two contact pins (20, 21) and is as wide as or wider than a distance between the two contact pins (20, 21). .

8. Ultrasonic sensor according to one of the preceding claims, characterized in that the metallic hood (40) is contacted with the circuit board (16) and is grounded.

9. Ultrasonic sensor according to claim 8, characterized in that the metallic hood (40) is contacted with the circuit board by means of a spring pin (48) which is formed continuously with one of the walls (42) of the metallic hood (40) and which is inserted into a through-hole (34 ) is pressed into the circuit board (16).

10. Ultrasonic sensor according to claim 9, characterized in that the spring pin (48) is designed as an eyelet (51) enclosing an elongated hole (49).

11. Ultrasonic sensor according to one of the preceding claims, characterized in that the metallic cover (40) is made of copper or brass sheet with a sheet thickness between 0.2 and 0.4 mm, preferably 0.3 mm.

12. Ultrasonic sensor according to claim 11, characterized in that the metallic

Hood (40) is punched and folded in one piece from the copper or brass sheet.

13. Ultrasonic sensor according to one of the preceding claims, characterized in that the diaphragm pot (7) is a metallic diaphragm pot (7) which is not connected to ground with high resistance.

14. Motor vehicle (1) with an ultrasonic sensor (100, 101 -105) according to one of the preceding claims.

15. Method for producing an ultrasonic sensor (100), comprising:

Pressing (S1) two contact pins (20, 21) into a plastic housing (2);

Inserting (S2) a membrane pot (7) with an ultrasonic membrane (8) and a sound transducer element (25) attached to the ultrasonic membrane (8) from the inside for exciting and detecting vibrations of the ultrasonic membrane (8) into an opening (12) of the plastic housing (2);

Contacting (S3) the contact pins (20, 21) with the sound transducer element (25);

Pressing (S4) a circuit board (16), on which a driver circuit (19) for controlling the sound transducer element (25) is mounted, onto ends (35) of the contact pins (20, 21) in such a way that the ends (35) pass through the circuit board (16) pass through;

Producing (S5) a metallic hood (40) by punching out a blank (50) from a copper or metal sheet and folding the blank (50);

Mounting (S6) the metallic hood (40) on the circuit board (16) in such a way that the metallic hood (40), together with the circuit board (16), surrounds and shields the ends (35) of the contact pins (20, 21) passing through the circuit board (16) on all sides.