DE102021133906A1 - Ultrasonic transducer with housing - Google Patents

Abstract

The present invention relates to an ultrasonic transducer (1) with a housing which has a plastic material, the housing comprising a base (2) and a housing wall, the housing wall having a first section (3) which adjoins the base (2), and a second section (4), the first and second sections (4) having different dimensions, a transition section (5) being provided between the first and second sections (4) and a surface normal being perpendicular to the outside of the housing wall in the transition section (5), is oblique to a surface normal that is perpendicular to the floor (2), and is oblique to a surface normal that is perpendicular to the outside of the housing wall in the first section and to the outside of the housing wall in the second section (4 ) stands. A transducer element (6) is arranged on the base (2) and is designed to excite the base (2) to vibrate with a frequency in the ultrasonic range. The present invention also relates to a method for producing a corresponding housing by injection molding.

Description

The present invention relates to an ultrasonic transducer with a housing and a method for its manufacture.

Known ultrasonic transducers for the frequency range from 40 to 80 kHz usually have aluminum housings. A portion of the housing typically forms the diaphragm, which can vibrate at an ultrasonic frequency. Furthermore, the housing serves as a carrier for the transducer element and as a resonance body. The vibration of the diaphragm can be transmitted to the rest of the housing in an undesirable manner. Mechanical damping is also usually necessary through direct contact of the membrane with a damping element, since small distances can no longer be measured using ultrasound if the membrane is not sufficiently damped. Excessive damping, on the other hand, leads to a lack of sensitivity of the sensor, so that large distances in particular can no longer be measured.

A corresponding ultrasonic transducer with an aluminum housing is, for example, from WO 2020245064 A2 known.

An object of the present invention is to provide an improved ultrasonic transducer and a method for its manufacture.

An ultrasonic transducer is provided with a housing that includes a plastic material.

The housing includes a floor and a housing wall. An outer side of the housing wall comprises a first section which adjoins the floor and a second section which preferably does not adjoin the floor. The second section connects to a housing opening.

The first and second sections have different dimensions. In particular, the first and the second section can have different dimensions in a direction perpendicular to a surface normal of the floor or parallel to the floor.

A transition section is also provided between the first and second sections. The housing thus comprises in this order the bottom, the adjoining first section of the housing wall, the transition section of the housing wall adjoining the first section and the second section of the housing wall adjoining the transition section, as well as the housing opening adjoining the second section. In a direction parallel to the floor, the first section, the transition section and the second section preferably have different dimensions. The sections can also have different dimensions in a direction perpendicular to the ground.

The transition section preferably follows directly on the first section and the second section preferably follows directly on the transition section. This means that the housing wall preferably has no further sections apart from the three sections mentioned.

A surface normal that is perpendicular to the outside of the housing wall in the transition section is also inclined to a surface normal that is perpendicular to the floor. Furthermore, the surface normal, which is perpendicular to the outside of the housing wall in the transition section, is oblique to a surface normal, which is perpendicular to the outside of the housing wall in the first section. Furthermore, the surface normal, which is perpendicular to the outside of the housing wall in the transition section, is oblique to a surface normal, which is perpendicular to the outside of the housing wall in the second section.

A transducer element is disposed on the floor and is configured to excite the floor to vibrate at a frequency in the ultrasonic range.

The surface normal that is perpendicular to the outside of the housing wall in the transition section is oblique to a surface normal that is perpendicular to the floor, oblique to a surface normal that is perpendicular to the outside of the housing wall in the first section, and oblique to a surface normal that is perpendicular to the outside of the housing wall in the second section.

In particular, in relation to a sectional plane of the housing, the surface normal that is perpendicular to the outside of the housing wall in the transition section is oblique to a surface normal that is perpendicular to the floor, oblique to a surface normal that is perpendicular to the outside of the housing wall in the first section, and oblique to a surface normal that is perpendicular to the outside of the housing wall in the second section. All surface normals mentioned here are therefore in one plane, namely in the same sectional plane of the housing.

In one embodiment, each surface normal that is normal to the outside of the transition section is oblique to each surface normal that is normal to the ground.

In a preferred embodiment, each surface normal that is perpendicular to the outside of the transition section is also oblique to each surface normal that is perpendicular to the outside of the first section.

In a further preferred embodiment, each surface normal that is perpendicular to the outside of the transition section is also oblique to each surface normal that is perpendicular to the outside of the second section.

Preferably, each surface normal that is perpendicular to the outside of the transition section is oblique to each surface normal that is perpendicular to the bottom or the outside of the first section or the outside of the second section.

Here and in the following, the term oblique is understood to mean a position that is neither vertical nor parallel.

The bottom of the housing can preferably be designed as a membrane which vibrates at an ultrasonic frequency when excited by a transducer element or by external vibrations. For this purpose, the base is very thin, in particular thinner than the housing wall.

The described housing with a transition section has the advantage that vibrations of the floor are hardly transmitted or are only transmitted in a damped manner to the rest of the housing, in particular to the second section of the housing wall. This effect is supported by the geometric shape of the housing, the shape of the transition section and a suitable material for the housing.

In particular, the appropriate selection of a plastic with appropriate elasticity and damping properties enables the setting of a desired sensitivity or damping of vibrations of the floor, which determines the minimum and maximum measurable distance. If the damping of floor vibrations is too high, the maximum measurable distance decreases, if the damping is too low, the minimum measurable distance increases.

Furthermore, the housing described has a high level of stability, in particular with respect to mechanical pressure on the outside of the housing wall. The housing described is therefore particularly suitable for being installed in automated assembly processes, during which pressure is exerted on the outside of the housing wall, for example by gripping arms.

In particular, the use of a suitable plastic material enables a versatile, variable shape of the housing that is adapted to the assembly and application conditions and can then be produced, for example, in an injection molding process.

According to one embodiment, a surface normal that is perpendicular to the outside of the housing wall in the transition section and a surface normal that is perpendicular to the floor form an angle of between 1° and 89°, preferably between 5° and 85° and even more preferably between 10° and 80° in. The same preferably applies to an angle between a surface normal that is perpendicular to the outside of the housing wall in the transition section and a surface normal that is perpendicular to the outside of the housing wall in the first section, and also for an angle between a surface normal that is perpendicular to the outside of the housing wall in the transition section, and a surface normal that is perpendicular to the outside of the housing wall in the second section.

A vibration in the housing between the first and the second section of the housing wall is dampened by such an inclined position of the outside of the housing wall in the transition section. Furthermore, this increases the stability of the housing against pressure on the outside of the housing wall.

If the housing wall forms a flat inclined surface in the transition section, any surface normal of this surface is preferably inclined to a surface normal of the base, preferably at an angle between 1° and 89°, more preferably at an angle between 5° and 85° and even more preferably at an angle Angles between 10° and 80°.

According to one embodiment, the outside of the housing wall is curved in the transition section. The housing wall can have both a concave and a convex outward curvature or both. The housing wall in the transition section can also include one or more curved and planar sections.

In particular, a curved section can be provided adjacent to the first section and a flat section can be provided adjacent to the second section. As an alternative or in addition, oblique and arched sections can also be arranged next to one another, each adjoining the first and the second section or only one of the two sections.

With an outside of the housing wall designed in this way in the transition section, the Vib ration behavior of the housing can be adjusted in a targeted manner and in particular the vibration behavior of individual housing sections can be adapted to the requirements desired for this. In particular, a damping of vibrations in the housing between the first and the second section of the housing wall can be achieved, so that only little or no vibration occurs at least in desired sections of the second section of the housing wall. In other sections of the housing wall, including the second section, the vibrations can be more pronounced. Furthermore, this increases the stability of the housing against pressure on the outside of the housing wall, in particular during assembly of the housing.

According to one embodiment, the plastic material has a quality factor Q as a measure of the damping between 10 and 100, preferably between 10 and 65. More preferably, the quality factor Q is between 25 and 50. The quality factor is a measure of the damping or energy loss of a system capable of oscillation. A high quality of a system means that the system is weakly damped. The desired figure of merit can be obtained by an appropriate choice of plastic material for the housing. A base made of a plastic material with the selected quality factor Q can be sufficiently excited and dampened to vibrate when used as an ultrasonic transducer.

In particular, the housing can consist of the plastic material. The entire housing, including the bottom and the housing wall, can be made of the plastic material. The plastic material can have homogeneous properties over the entire housing. Differences in the damping or the mechanical stability, in particular the stability against external pressure, between individual sections of the housing are preferably not achieved in the present housing by different compositions of the housing material but by the suitably designed housing shape.

According to one embodiment, the plastic material has a modulus of elasticity of at least 1 GPa. The plastic material preferably has a modulus of elasticity of at least 10 GPa. A base made of the plastic material with the selected modulus of elasticity can be sufficiently excited and dampened to vibrate when used as an ultrasonic transducer.

According to one embodiment, the transition section is shaped such that vibration of the first section is dampened in the second section.

According to one embodiment, the bottom has a round shape and the first section has a cylindrical or conical shape. The base preferably has a circular shape and the first section has a circular-cylindrical shape or a conical shape with a circular base area. The floor forms the base of the cylinder or the cone, with cone being a synonym for a truncated cone.

In the case of a conical shape, this preferably deviates only slightly from a cylindrical shape. The outer surface of the cone therefore has only a slight incline of, for example, a maximum of 10°, preferably a maximum of 5°, relative to the surface normal of the base.

In particular, a conical shape of the section is advantageous, for example, to increase the stability of the housing against external pressure.

According to one embodiment, the second section has larger dimensions parallel to the ground than the first section. In the transition section, the housing then widens from the dimension of the first section to the dimension of the second section.

The transition in the dimensions of the sections makes it possible to adjust the vibration behavior of the housing wall and in particular dampen vibrations in the housing wall or in desired sections of the housing wall.

A wider dimension of the second section also makes it possible to embed a printed circuit board with evaluation electronics of the ultrasonic transducer directly in the second section.

According to an embodiment, an inner space of the housing has a conical shape in a lower portion adjacent to the bottom. The shape of the interior of the housing and an outside of the housing wall, which delimits the housing on the outside, do not have to be the same. In particular, an inside of the housing wall, which delimits the interior of the housing, and the outside of the housing wall can have different slopes.

In particular, the lower section can be formed in the section of the housing in which the first section is formed on an outside of the housing wall. However, the lower section of the interior can also be pronounced in a section of the housing, in which the over on the outside of the housing wall passage section or the second section are pronounced.

An inner side of the housing is preferably beveled at an angle of between 0.5° and 45°, preferably between 0.5° and 5°, particularly preferably 2° relative to a cylinder jacket surface perpendicular to the base.

Such a pronounced conical shape of the interior of the housing increases its mechanical stability and enables the insertion of a preformed absorption element without it slipping through to the floor.

According to one embodiment, the outline of the second portion widens in the direction towards the ground. This increases the mechanical stability of the housing and leads to the adjustment of different vibrations and in particular to the damping of vibrations in sections of the housing wall. In particular, a larger difference in the dimensions between the first and the second section must then be bridged via the transition section, for example by the transition section being formed further outwards or curved, which further increases the damping in the housing wall due to its shape.

According to one embodiment, the second section of the housing wall and the first section of the housing wall have different geometric shapes.

This enables precise adjustment of the vibration behavior in the housing wall and, in particular, better damping of vibrations in individual sections of the housing wall. In particular, a difference in the geometric shape between the first and the second section must then be bridged over the transition section, which increases a damping effect in the housing wall due to its shape. The different geometric shapes ensure that the transition section is irregularly shaped. As a result, vibrations are transmitted across the transition section differently at different sections, so that the vibrations are dampened in individual sections of the second section and amplified in other sections.

According to one embodiment, an outer side of the second section has a rectangular outline shape.

According to a preferred embodiment, an inner space of the housing also has a rectangular outline shape in an upper portion which adjoins the housing opening. The outline shapes are preferably square.

In particular, the upper section can be formed in the section of the housing in which the second section is formed on an outside of the housing wall. However, the upper section of the interior space can also be formed in a section of the housing in which the transition section or the first section is formed on the outside of the housing wall.

The transition section can then comprise a curved section which is directly adjacent to the first section and extends to the corners of the rectangular shape of the second section. Further, the transition portion may include planar sloping portions that abut the side edges of the rectangular outline of the second portion. Such a shape is advantageous in terms of stability of the housing and damping in the transition section.

A rectangular shape also means, in particular, a rectangular shape with rounded corners. Rounding the corners improves the handling of the case.

In addition to the advantages of the shape of the second section that have already been explained, this makes it possible to insert a rectangular printed circuit board with evaluation electronics directly into the second section. A rectangular PCB is easier to manufacture than a round PCB. In addition, the production of a round printed circuit board involves a considerable loss of material. In the case of round printed circuit boards, a lot of material has to be discarded, especially when cutting out from a wafer. A material-saving process is more cost-effective and sustainable.

According to a further embodiment, the second section has a round outline shape, in particular a cylindrical or conical shape. According to one embodiment, an interior space of the housing also has a cylindrical or conical shape in the upper section. Such a shape also allows round printed circuit boards to be installed directly in the housing. A round housing shape is still easy to manufacture. The outer outline of the second section of the housing wall and the inner outline of the upper section in the interior of the housing can also be shaped differently.

According to one embodiment, the transducer element may be a piezoelectric element, for example in the form of a disc. The piezoelectric element includes a piezo electrical material such as a piezoelectric ceramic. Furthermore, the converter element preferably comprises two electrodes which, for example, rest on different sides of the piezoelectric ceramic in order to pick up an electrical signal or to build up an electrical voltage in the ceramic. The piezoelectric element is preferably glued to the inside of the floor.

According to one embodiment, a printed circuit board is arranged in the upper portion of the interior of the housing, the printed circuit board being designed as a lid covering the housing opening which is opposite to the bottom.

The housing can therefore have the shape of a pot, which has a bottom and a housing wall and a housing opening opposite the bottom. The housing opening is preferably closed by a cover. The cover can be the printed circuit board mentioned, on which the evaluation electronics and control electronics of the ultrasonic transducer can be partially or completely arranged. The electronics are preferably attached to the inside of the printed circuit board in the interior of the housing and are thus protected from external influences.

According to one embodiment, the circuit board is bonded to corresponding contact surfaces in the interior of the housing by means of an elastic adhesive on a plurality of separate contact surfaces of the circuit board. The use of an elastic adhesive reduces or completely avoids the possible transmission of vibrations in the housing to the cover, which in particular can also disrupt the electronics.

According to one embodiment, at least part or the entire upper section of the interior of the housing below the circuit board or between an optional absorption element and the circuit board is filled with a filler. The filler is preferably introduced in pasty form through the housing opening and then hardened. The filler preferably comprises a plastic material or synthetic resin. The filler is preferably elastic. The filler may also include any other suitable material.

In one embodiment, the circuit board as a cover does not end flush with the surrounding housing wall, but is arranged sunken in the interior of the housing. The remaining space in the housing, outside of the interior space enclosed by the base and circuit board, is preferably partially filled with the filler. The filler then preferably covers almost the entire printed circuit board, except for a section of the printed circuit board on which electrical contact is provided to the outside. The printed circuit board is also fixed in the housing and protected from external influences.

In a preferred embodiment, the circuit board rests in particular on contact surfaces in the interior of the housing where the vibrations in the housing are minimal (so-called vibration nodes) in order to prevent the vibrations from being transmitted to the circuit board.

According to one embodiment, a step is formed in the upper section of the interior of the housing, on which the printed circuit board rests and on which the contact surfaces of the housing are provided. For example, the step may have a rectangular outline or a round outline. Preferably, the outline shape of the step is the same as that of the interior space in the upper portion.

According to an exemplary embodiment, the contact surfaces of the housing are pronounced at corners or in the middle between two corners of the step. The vibrations in the housing are then preferably minimal at these points.

Electrical contact is made between the converter element and the printed circuit board or, in particular, the evaluation electronics of the printed circuit board. In particular, at least two contacts are preferably provided in order to contact two differently polarized electrodes of the converter element.

According to one embodiment, the printed circuit board and the converter element are electrically contacted via conductive traces on the inside of the housing.

In particular, they can be printed or sputtered tracks made of an electrically conductive material such as a metal, preferably copper, or an electrically conductive plastic. An electrically conductive plastic contains electrically conductive particles, for example metal particles that include copper.

Alternatively, the tracks can also be formed within the housing wall in one embodiment, so that only contact points of the tracks for contacting the evaluation electronics and the converter element on the inside of the housing, i.e. in particular on the inside of the housing wall and the floor, are exposed.

Such a design eliminates the need for contacting by wires in the interior of the housing, the assembly of which is complex and cumbersome.

In one embodiment, the conductive traces are bonded to electrical contacts on the circuit board by a conductive adhesive. In particular, this concerns the contacts of the evaluation electronics on the printed circuit board. The conductive adhesive is preferably also elastic, so that transmission of vibrations from the housing to the printed circuit board is avoided.

Such a configuration of the contact via the tracks and the electrically conductive adhesive allows the ultrasonic transducer to be assembled simply by placing the printed circuit board on as a cover, without having to take any further steps to make contact between the printed circuit board and the transducer element.

According to one embodiment, the plastic material is electrically insulating. The traces can thus be applied directly to the plastic material or embossed in it. A suitable method for forming the tracks in the case of a housing consisting of an electrically insulating base material would be laser direct structuring (LDS).

In one embodiment, the tracks terminate in multiple pads on the ground. The transducer element is preferably glued to the floor at a section provided for this purpose by means of a non-conductive adhesive.

In one embodiment, the electrodes of the transducer element contact the electrically conductive traces. Preferably, in this embodiment, the tracks extend to the floor and the transducer element rests on the tracks.

In particular, the transducer element can be glued to the floor in such a way that the transducer element and in particular its electrodes lie directly on the tracks and are preferably electrically contacted with them.

In a preferred embodiment, contact between the electrodes of the transducer element and the traces is made via a conductive adhesive. Alternatively, the contact can also be made using a non-conductive adhesive if the surface roughness of the tracks or the electrodes of the transducer element is sufficiently large that electrical contact can be made through the adhesive layer, in particular contact by direct contact, between the tracks and adjusts the electrodes of the transducer element.

In one embodiment, the tracks can also end next to the transducer element and the transducer element cannot fly onto the tracks. In this embodiment, electrical contact between the electrodes of the transducer element and the traces is preferably made via the conductive adhesive.

According to one embodiment, an electrically conductive coating for electromagnetic shielding is applied to the outside of the housing, ie in particular to the outside of the housing wall and the base.

In a further embodiment, the housing comprises a material that is not electrically insulating or the plastic material is electrically conductive. In this embodiment, an electrically insulating layer is arranged between the housing wall and the tracks on an inner side of the housing wall or the base on which the electrically conductive tracks are applied. For example, an insulating layer of Parylene C can be provided.

A housing wall made of an electrically conductive material has the advantage that the housing wall shields the electronics arranged in the housing against interfering electromagnetic influences from the outside (EMC/EMI protection).

In a further embodiment, in particular if the housing is not electrically conductive, an electrically conductive coating is applied to the outside of the housing, which preferably completely covers the outside of the housing.

Such a coating shields the electronics and electrically conductive traces arranged in the housing from disruptive electromagnetic influences and in particular from external electrical induction (EMC/EMI protection).

In particular, the electrically conductive coating can contain a metallic material such as copper. The coating can be applied evenly and thinly. The coating can be applied, for example, by sputtering, but also, for example, in the form of a paint that includes electrically conductive particles.

In one embodiment, for ground contacting of the coating, an electrically conductive via, that is to say through-contacting, can be provided between the coating on the outside of the housing and one of the tracks on the inside of the housing.

In particular, in one embodiment, the via can be formed in a through-hole in the housing wall.

The through hole can be a specially made hole in the housing wall. The electrically conductive coating can then also be arranged on a surface in the bore and can extend to the electrically conductive track on the inside of the housing wall. In particular, the track and the coating can have the same material and form a continuously connected coated area.

In a further embodiment, the via can be stamped out in a groove in an outer edge of the housing wall surrounding the housing opening instead of in a through hole. Analogous to the through-hole, the groove can be a bore, but not in the center of the housing wall, but rather on an outer edge of the housing wall.

The channel ensures that the electrically conductive coating or the track or its electrical connection is exposed on an outer edge of the housing wall, so that, for example, an unintentional short circuit with an electrical contact in the area surrounding the housing is avoided.

In a further embodiment, the electrically conductive coating and one of the tracks are electrically contacted via the printed circuit board. In this embodiment, the conductive coating and the track are electrically contacted only when the cover is closed, ie the printed circuit board is placed on the housing. A coated groove or a coated through-hole can in particular be provided again for contacting between the electronics on the printed circuit board and the outer coating.

In one embodiment, a cylindrical or conical preformed absorption element is arranged at a distance from the bottom in the interior of the housing. The preformed absorption element can be easily inserted into the housing when the ultrasonic transducer is connected.

The absorption element absorbs sound and ultrasonic waves and preferably prevents, in particular, sound or ultrasonic propagation in the interior of the housing, but preferably does not dampen the mechanical oscillations or vibrations in the housing wall. The absorption element thus also enables the measurement of distances at short distances using the ultrasonic transducer.

According to one embodiment, a cavity is provided between the preformed absorption element and the floor. In particular, the cavity is a gap comprising only air. The cavity prevents vibrations of the floor from being dampened by undesired direct contact of the absorption element with the floor. Rather, the cavity should be so wide that the floor does not come into contact with the absorption element even if the floor vibrates at its maximum during operation of the ultrasonic transducer. Additionally or alternatively, the distance between the floor and the absorption element is preferably measured in such a way that destructive interference of the acoustic waves occurs between the two opposite surfaces of the floor and the absorption element.

A direct mechanical damping of the floor is, however, not necessary due to the advantageously selected plastic material as described and the described shape of the housing.

In particular, in one embodiment, the absorption element is a foamed plastic element. The plastic element comprises, for example, a urethane derivative such as polyurethane or a silicone. With a suitable choice, such a foamed plastic has the necessary material properties in order to dampen the vibrations, in particular sound vibrations, as completely as possible.

Such an absorption element is also easy to prefabricate and can be brought into the desired required shape easily and without post-processing.

According to one embodiment, a radial dimension of the absorption element is greater than a radial extension of the interior of the housing in the area of the bottom. In particular, this prevents the absorption element from slipping through to the bottom of the housing.

In particular, the absorption element and/or the lower section of the interior of the housing can be conical in shape, so that a radial dimension of the absorption element is greater than that of the interior only in the region of the bottom.

Furthermore, a method for producing a housing of an ultrasonic transducer from a plastic is disclosed. The method can be used in particular for the production of the previously described Housing and ultrasonic transducer are applied.

In one step, the method includes the production of the housing by injection molding. The housing may include all of the features and components previously described.

In particular, the housing comprises a base and a housing wall, the housing wall comprising a first section, which adjoins the base, and a second section. The first and second sections have different dimensions, with a transition section being provided between the first and second sections. A surface normal that is perpendicular to the outside of the housing wall in the transition section is oblique to a surface normal that is perpendicular to the floor and oblique to a surface normal that is perpendicular to the outside of the housing wall in the first section and to the outside of the housing wall in the second section.

According to one embodiment of the method, the conductive traces are formed in an interior space of the housing by means of direct laser structuring, the conductive traces being designed to electrically connect a transducer element on the bottom to a circuit board forming a cover of the housing.

In addition to the LDS process, other methods for generating the conductive traces are also possible, such as sputtering, metal printing, in particular using metal inserts, or another method using metal inserts or a laser-induced graphene process (LIG process).

In the LDS process, an electrically conductive track is defined by a laser beam that writes a layout of the track directly onto the plastic material of the package. A special LDS additive is added to the plastic material for this purpose. Areas on which tracks are provided are then exposed to the laser beam and the added LDS additive activated. In a subsequent metallization in a copper bath, copper layers are formed on the activated areas in an adherent manner and with sharp contours. Different layers can be built up one after the other, for example made of nickel, gold, silver or solder, which then form the tracks.

Exemplary embodiments are described below with reference to figures. The present invention is not limited to the exemplary embodiments shown.

• 1: Perspektivische Ansicht von schräg oben eines ersten Ausführungsbeispiels eines Gehäuses eines Ultraschallwandlers.
• 2: Perspektivische Ansicht von schräg unten des ersten Ausführungsbeispiels des Gehäuses des Ultraschallwandlers mit eingezeichneten Flächennormalen.
• 3: Seitenansicht im Querschnitt des Gehäuses des ersten Ausführungsbeispiels des Ultraschallwandlers.
• 4: Seitenansicht im Querschnitt des ersten Ausführungsbeispiels des Ultraschallwandlers.
• 5: Ansicht des ersten Ausführungsbeispiels des Ultraschallwandlers von schräg oben. Gezeigt sind das Gehäuse und zwei leitende Spuren.
• 6: Simulation der Vibration des Gehäuses.
• 7: Perspektivische Ansicht eines weiteren Ausführungsbeispiels des Gehäuses mit metallischer Schicht zur Abschirmung und Bohrung.
• 8: Querschnitt durch das Gehäuse mit metallischer Schicht zur Abschirmung und Bohrung.
• 9: Querschnitt durch ein weiteres Gehäuse mit metallischer Schicht zur Abschirmung und Rinne.

The figures show:

• 1 : Perspective view obliquely from above of a first embodiment of a housing of an ultrasonic transducer.
• 2 1: Perspective view obliquely from below of the first exemplary embodiment of the housing of the ultrasonic transducer with surface normals drawn in.
• 3 : Side view in cross section of the housing of the first embodiment of the ultrasonic transducer.
• 4 : Side view in cross section of the first embodiment of the ultrasonic transducer.
• 5 : View of the first exemplary embodiment of the ultrasonic transducer obliquely from above. Shown are the case and two conductive traces.
• 6 : Simulation of the vibration of the case.
• 7 : Perspective view of another embodiment of the housing with metallic layer for shielding and drilling.
• 8th : Cross section through the housing with metallic layer for shielding and drilling.
• 9 : Cross section through another housing with metallic layer for shielding and trough.

Similar or apparently the same elements in the figures are provided with the same reference numbers. The figures and the proportions in the figures are not true to scale.

The 1 , 2 and 3 show different views of a housing of a first embodiment of an ultrasonic transducer 1. The 1 and 2 show perspective views from diagonally above and diagonally below, the 3 a cross-sectional side view. 4 shows a side view of the ultrasonic transducer including the housing and other described components of the ultrasonic transducer.

The ultrasonic transducer 1 comprises a housing which is closed off by a base 2 on its underside. In the exemplary embodiment, the bottom 2 has a circular shape. The housing further includes a housing wall and a housing opening opposite the bottom. A first section 3 of a housing wall connects to the bottom 2 at the top.

The direction away from the floor and towards the housing opening is defined as "top".

The outside of the first section 3 can have a cylindrical or conical shape. im before lying embodiment, the outside of the first portion is conically shaped. The angle of inclination of the cone shape in relation to the lateral surface of a flat cylinder is 0.5° to 5°, preferably 2°. However, the angle can also be selected to be smaller or larger. The diameter of the cone shape is smallest adjacent to the bottom 2 and then increases towards the top.

A lower section 31 also encloses a cone-shaped cavity in the interior of the housing. The slope of the inside of the housing wall in the lower section 3I can differ from the slope of the outside in the first section 3. The slope is preferably 0.5° to 45°, more preferably 0.5° to 5°, more preferably 2° relative to a surface normal of the inside of the base 2.

The housing wall further comprises a second section 4 which is arranged above the first section 3 and away from the bottom 2 . The second section 4 can have different outline shapes. In the present exemplary embodiment, the outer contour of the second section 4 is rectangular and preferably square. This also means, in particular, a rectangular or square shape with rounded corners, as is also shown in the figures. The dimensions of the second section 4 parallel to the bottom 2 are greater than the dimensions of the first section 3.

A transitional section 5 of the housing wall is provided between the first section 3 and the second section 4 . The transition section preferably follows directly on the first section and the second section preferably follows directly on the transition section. This means that the housing wall preferably has no further sections apart from the three sections mentioned.

The outside of the transition section 5 can be curved or flat. The outer side of the transition section is in particular not parallel or perpendicular to the floor and not parallel or perpendicular to one of the outer sides of the first or second section, but rather inclined to the floor and to said outer sides, as for example in 2 illustrated.

“Oblique” in turn means that a surface normal FN5 that is perpendicular to the outside of the transition section 5 is not parallel and not perpendicular to a surface normal FN2 that is perpendicular to the floor 2 . Likewise, a surface normal FN 5, which is perpendicular to the outside of the transition section 5, is not parallel and not perpendicular to a surface normal FN3, which is perpendicular to the outside of the first section 3, and not perpendicular to a surface normal FN 4, which is perpendicular to the outside of the second section 4 is.

Rather, the outside of the transition section forms a transition between the outside of the first section 3 and the outside of the second section 4. A surface normal FN5, which is perpendicular to the outside of the housing wall in the transition area 5, preferably has an angle of between 10 and 80 degrees with respect to one Surface normal FN2 of the bottom 2 of the housing. Likewise, a surface normal FN5, which is perpendicular to the outside of the housing wall in the transition region 5, preferably has an angle of between 10 and 80 degrees to a surface normal FN3, which is perpendicular to the outside of the first section 3, and to a surface normal FN4, which is perpendicular to the Outside of the second section 4 is on.

In the illustrated embodiment, the outside of the housing wall has a transition section 5 with the following configuration. The transition section 5 extends from the outside of the first section 3 to the outside of the second section 4. Here, the transition section 5 is noticeably curved towards the corners of the rectangular shaped outline of the second section 4. The curvature decreases between the corners. In a crest line between the corners, the transition section 5 is not curved at all, but runs flat from an outer edge of the first section 3 to an outer edge of the second section 4. The differences in the curvature of the transition section 5 are caused by a different height of the second section 4 conditional. The outer edges of the second section 4 are bent towards the first section or the base 2 between its corners.

The different height of the second section 4 leads to an irregular shape of the transition section 5, as a result of which vibration in the housing between the first and second sections 3 and 4 is only transmitted to a small extent, ie the vibration in the transition section 5 is damped.

The interior of the case also has a rectangular outline in an upper portion 4I adjacent to the case opening. A stage 4A is also provided within the housing. In the interior of the housing, the lower section 3I with a circular inner outline directly adjoins the upper section 4I with a rectangular inner outline.

In particular, the upper section 4I is formed in the section of the housing in which the second section 4 is formed on an outside of the housing wall. In particular, the lower section 3I is also formed in the section of the housing in which the first section 3 is formed on an outside of the housing wall. However, the upper section 4I and the lower section 3I of the interior space are also formed in a section of the housing in which the transition section 5 is formed on the outside of the housing wall.

The bottom 2 of the housing is designed as a membrane which vibrates at an ultrasonic frequency when excited by a transducer element 6 or by external vibrations. For this purpose, the base 2 is very thin, in particular thinner than the housing wall.

The entire housing including base 2 and housing wall is made in one piece and from the same material. The housing is an injection molded part made of plastic.

The plastic has vibration and sound-damping properties. A plastic with a high modulus of elasticity of more than 1 GPa, preferably more than 10 GPa, is selected for this. The ratio of density ρ to modulus of elasticity E of the plastic and in particular the factor (ρ) ³ /E should be as small as possible. Preferably the factor (ρ) ³ /E is less than 0.35, more preferably less than 0.1, even more preferably less than 0.01. Furthermore, the plastic has a quality factor Q as a measure of the damping between 10 and 100, preferably between 10 and 65.

Another preferred selection criterion for the plastic is that its mechanical properties remain constant in an application temperature range of -40 °C and +85 °C. Even more preferably, the mechanical properties remain constant in an application temperature range of -55°C and +150°C.

The transducer element 6 is preferably a piezoelectric element. The piezoelectric element preferably comprises a piezoelectric ceramic material. The piezoelectric element can be disc-shaped. Two electrodes are preferably arranged on two opposite surfaces of the disc-shaped piezoelectric element, one electrode each on one of the surfaces. The piezoelectric element can be controlled electrically via the electrodes and an electrical voltage can be applied in particular, or an electrical signal, in particular an electrical voltage, can be tapped from the piezoelectric element.

In the exemplary embodiment, the piezoelectric element is disc-shaped and is glued to the inside of the base 2 . The piezoelectric element can also be applied to the floor 2 in a materially bonded manner in another way.

Furthermore, the ultrasonic transducer 1 includes a preformed absorption element 7, which is arranged in the interior of the housing. The preformed absorption element consists of a foamed plastic.

The absorption element 7 has a cylindrical or conical shape. In particular, the absorption element has a larger dimension in a radial direction than the lower portion 3I of the inner space close to the floor 2 , so that the absorption element is clamped in the lower portion 3I of the inner space of the housing and does not slip down to the floor 2 . Thus, a cavity 7A is formed between the bottom 2 and the absorption element 7. FIG. The cavity 7A prevents feedback between the floor 2 and the absorption element 7. In particular, the absorption element 7 does not dampen the oscillations or vibrations of the floor 2 since the floor 2 is not in contact with the absorption element 7. Rather, the absorption element 7 serves to dampen ultrasonic waves in the interior of the housing, in particular so that the ultrasonic waves do not interfere with downstream evaluation electronics.

The evaluation electronics are mounted on a printed circuit board 8, which also forms the cover of the housing. For this purpose, the printed circuit board 8 is placed on the step 4A in the second section, so that it covers the housing opening in the second section. In order to dampen vibrations from the housing and, if possible, not to transfer them to the printed circuit board, the printed circuit board 8 is only glued to selected contact surfaces on corresponding contact surfaces of the housing or the stage 4A. The corresponding contact surfaces of the housing are in particular points in the housing at which vibration is maximally damped due to the housing structure described. Such places are in particular the corners 4B or the midpoints between the corners 4B of the rectangular outline of the second housing section 4.

In 6 a simulation of vibrations in the housing of the ultrasonic transducer 1 is shown. For this purpose, the floor 2 is excited to a defined vibration. The oscillations are transmitted in the form of vibrations throughout the housing.

A strong vibration occurs in particular on the floor 2 . The simulation shown clearly shows that hardly any vibrations occur at the corners 4B of the rectangular second section 4 of the housing wall, while stronger vibrations occur in sections 4C between the corners 4B. However, in differently shaped housings, smaller vibrations can also occur in the sections 4C between the corners 4B.

Vibrations of the floor 2 in particular, which propagate from there through the housing, are strongly damped at these points.

The cavity between the preformed absorption element 7 and the printed circuit board 8 or the remaining cavity above the printed circuit board 8 in the housing is filled in the exemplary embodiment with a filler 12, preferably with an elastic plastic or a synthetic resin. The filler 12 preferably only hardens after it has been introduced into the cavity, so that the cavity is filled as completely as possible.

In one exemplary embodiment, the circuit board 8 as a cover does not end flush with the surrounding housing wall, but is arranged lowered in the upper section 4I of the interior of the housing. The remaining, unused space in the housing outside of the interior space enclosed by base 2 and circuit board 8 is preferably also filled with filler 12 . The filler 12 then preferably covers almost the entire printed circuit board, except for a section of the printed circuit board on which an electrical contact 13 is provided to the outside. The circuit board 8 is additionally fixed in the housing and protected from external influences.

Both in the first and in the second section, the outside of the housing wall, as well as in 3 shown, a slight slope. In this case, an incline means, in particular, an incline relative to a surface normal FN 2 on the surface of the floor 2 . The bevel and the transition section 5 described contribute to the mechanical stability of the housing in relation to a force applied to this outside from the outside.

In particular, the housing shaped as described is stable against a uniform force applied from two sides on the outside, for example of a gripping arm during assembly or a clamp for fastening the housing.

For contacting between the converter element 6 and the printed circuit board 8, as in 5 shown electrically conductive traces 9 applied to the inside of the housing wall. At least two tracks 9 are provided for contacting two differently polarized electrodes of the transducer element 6 . The tracks 9 extend in particular up to the step 4A on which the printed circuit board 8 is mounted. The tracks 9 extend at most to a surface of an upper side of the case formed parallel to the bottom 2 around the case opening. In particular, the tracks 9 do not extend to the outside of the housing wall.

The traces 9 can be both a metal coating that is applied to the inside of the housing wall and electrically conductive traces 9 inside the housing wall itself, i.e. not on the surface, i.e. the inside or outside, of the housing wall.

With the exception of any traces 9 formed in the housing wall, the housing wall is not electrically conductive in the exemplary embodiment, but can also be electrically conductive in other exemplary embodiments. In the latter case, an electrically insulating layer is applied to the inside of the housing wall or at least between the electrically conductive traces 9 and the housing wall. The insulating layer can, for example, comprise a plastic such as Parylene C in particular.

The electrically conductive traces 9 end in a plurality of contact surfaces on the floor 2. The transducer element 6 is glued to the floor 2 in the exemplary embodiment. The transducer element 6 is preferably glued to the floor 2 at a section provided for this purpose using a non-conductive adhesive, while the electrodes of the transducer element 6 contact the electrically conductive traces 9 on its sides. In this exemplary embodiment, the tracks 9 preferably reach down to the floor 2 so that the converter element 6 can be glued to the floor in such a way that the electrodes of the converter element 6 rest directly on the tracks 9 .

In another embodiment, the contact between the transducer element 6, in particular its electrodes, and the electrically conductive traces 9 is established via a conductive adhesive. Alternatively, the contact can also be made using a non-conductive adhesive if the surface roughness of the tracks 9 is so great that direct contact between the tracks 9 and the electrodes of the transducer element 6 occurs through the adhesive layer.

The tracks 9 can also already end next to the transducer element 6, so that the transducer element 6 does not land on the tracks 9. In this embodiment, the electrical contact between the electrodes of the transducer element 6 and the traces 9 is made via the conductive adhesive.

The electrically conductive traces 9 can be applied in particular by sputtering or by imprinting a metallic layer or by laser direct structuring (LDS). The traces contain a metallic, electrically conductive material such as copper. So that the tracks 9 can be structured using the LDS method, the housing preferably does not contain any carbon fibers.

In the LDS process, the electrically conductive track 9 is defined by a laser beam, which writes a layout of the track 9 directly onto the injection-molded plastic of the housing.

A special LDS additive is added to the plastic for this purpose. Areas on which tracks 9 are provided are then exposed to the laser beam, thereby activating the added LDS additive. In a subsequent metallization in a copper bath, copper layers are formed on the activated areas in an adherent manner and with sharp contours. In this way, different layers, for example made of nickel, gold, silver or solder, can be built up one after the other, which then form the tracks 9 .

In the further 7 until 9 various further embodiments of the housing of the ultrasonic transducer are shown with a metallic layer for electromagnetic shielding (EMI/EMC shielding) of the housing.

If the housing is not electrically conductive, an electrically conductive layer 10 must be applied to the outside of the housing, ie in particular the housing wall and the base 2, for electromagnetic shielding. The layer 10 can be applied, for example, by painting, physical or chemical vapor deposition (CVD) or sputtering. The layer can, for example, comprise a metal or a conductive plastic, ie usually a plastic with a conductive additive. The layer 10 preferably covers the entire outside of the housing.

The required ground contact of the layer 10 is provided, for example, by a through hole such as a bore 11A ( 8th ), or through a gutter 11B ( 9 ) made in the housing wall. The electrically conductive layer 10 is also applied in the bore 11A or the channel 11B, so that the electrically conductive layer 10 is in contact with one of the electrically conductive traces 9 on the inside of the housing.

Alternatively, the electrically conductive layer 10 can be in contact with the printed circuit board 8 and can be contacted with the electrically conductive tracks 9 via this. In this case, the necessary ground contact of the layer 10 is produced via the printed circuit board 8 . In this last example, however, the printed circuit board is not electrically contacted in a case where the cover with the printed circuit board is removed from the housing.

reference list

1

ultrasonic transducer

2

Floor

3

first section

3I

lower section

4

second part

4I

upper section

4A

Step

4B

Corner

4C

Section between two corners

5

transition section

6

transducer element

7

absorption element

7A

cavity

8th

circuit board

9

Sense

10

electrically conductive layer

11A

drilling

11B

gutter

12

filler

13

electrical contacting

FN2

surface normal to the ground

FN3

Surface normal to first section

FN4

Surface normal to the second section

FN5

Surface normal to the transition section

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• WO 2020245064 A2 [0003]

Claims (38)

Ultrasonic transducer (1) with a housing which has a plastic material, the housing comprising a base (2) and a housing wall, an outer side of the housing wall having a first section (3) which adjoins the base (2) and a second Section (4) which adjoins a housing opening, the first and the second section (4) having different dimensions, a transition section (5) being provided between the first and the second section (4) and a surface normal ( FN5) that is perpendicular to an outside of the housing wall in the transition section (5), oblique to a surface normal (FN2) that is perpendicular to the floor (2), and the surface normal (FN5) that is perpendicular to the outside of the housing wall in the transition section (5) is inclined to a surface normal (FN3) which is perpendicular to an outside of the housing wall in the first section (3), and wherein the surface normal (FN5) which is perpendicular to the outside of the housing wall in the transition section (5) is inclined to a surface normal (FN4) which is perpendicular to an outside of the housing wall in the second section (4), and wherein a transducer element (6) is arranged on the base (2) and is designed to cover the base ( 2) to excite a vibration with a frequency in the ultrasonic range. Ultrasonic transducer (1) according to claim 1 , wherein the surface normal (FN5), which is perpendicular to the outside of the housing wall in the transition section (5), and the surface normal (FN2), which is perpendicular to the bottom (2), enclose an angle between 1° and 89°. Ultrasonic transducer (1) according to claim 1 or 2 , wherein the outside of the housing wall is curved in the transition section (5). Ultrasonic transducer (1) according to one of Claims 1 until 3 , wherein the plastic material has a quality factor Q between 10 and 100. Ultrasonic transducer (1) according to one of Claims 1 until 4 , wherein the plastic material has a modulus of elasticity of at least 1 GPa or preferably at least 10 GPa. Ultrasonic transducer (1) according to one of Claims 1 until 5 wherein the transition section (5) is shaped such that vibration of the first section (3) is dampened in the second section (4). Ultrasonic transducer (1) according to one of Claims 1 until 6 , wherein the bottom (2) has a round shape and the first portion (3) has a cylindrical or conical shape. Ultrasonic transducer (1) according to one of Claims 1 until 7 , wherein the second section (4) parallel to the bottom (2) has larger dimensions than the first section (3). Ultrasonic transducer (1) according to one of Claims 1 until 8th wherein an inner space of the housing in a lower portion (31) adjacent to the bottom (2) has a conical shape. Ultrasonic transducer (1) according to one of Claims 1 until 9 , wherein the outline of the second section (4) widens towards the bottom (2). Ultrasonic transducer (1) according to one of Claims 1 until 10 , wherein the second section (4) and the first section (3) have different geometric shapes. Ultrasonic transducer (1) according to one of Claims 1 until 11 , wherein an outer side of the second section (4) has a rectangular or round outline shape. Ultrasonic transducer (1) according to one of Claims 1 until 12 , wherein the transducer element (6) is a piezoelectric element. Ultrasonic transducer (1) according to one of Claims 1 until 13 wherein a printed circuit board (8) is arranged in an upper portion (41) of the interior of the housing, the printed circuit board (8) being designed as a cover which covers the housing opening which faces the bottom (2). Ultrasonic transducer (1) according to Claim 14 , wherein the printed circuit board (8) is bonded to corresponding contact surfaces in the interior of the housing by means of an elastic adhesive on a plurality of separate contact surfaces of the printed circuit board (8). Ultrasonic transducer (1) according to claim 15 wherein in the upper portion (41) of the interior of the housing a step (4A) is pronounced, on which the printed circuit board (8) rests, and wherein the contact surfaces of the housing are provided on the step (4A). Ultrasonic transducer (1) according to Claim 16 , the contact surfaces of the housing being pronounced at the corners (4B) or in the middle between two corners (4B) of the step (4A). Ultrasonic transducer (1) according to one of Claims 14 until 17 , wherein the circuit board (8) and the transducer element (6) via conductive traces (9) are electrically contacted on an inside of the housing. Ultrasonic transducer (1) according to Claim 18 , wherein the conductive tracks (9) are contacted by means of a conductive adhesive with electrical contacts on the printed circuit board (8). Ultrasonic transducer (1) according to Claim 18 , wherein the conductive traces (9) are connected to electrical contacts on the circuit board (8) by means of a non-electrically conductive adhesive and the surface roughness of the traces (9) or of electrodes of the transducer element (6) is sufficiently large that the adhesive through an electrical contact between the tracks (9) and the transducer element (6) sets. Ultrasonic transducer (1) according to one of claims 18 until 20 , wherein the conductive traces (9) extend to the floor (2) and the transducer element (6) rests on the traces (9). Ultrasonic transducer (1) according to one of claims 18 until 20 , wherein the transducer element (6) does not fly up on the tracks (9). Ultrasonic transducer (1) according to one of Claims 14 until 22 , wherein a part of the upper portion (41) of the inner space is filled with a filler (12). Ultrasonic transducer (1) according to Claim 23 , wherein the printed circuit board (8) does not end flush with the surrounding housing wall, but is arranged lowered in the interior (41) of the housing and part of the remaining space in the housing outside of the interior enclosed by the base (2) and printed circuit board (8), is filled with the filler (12). Ultrasonic transducer (1) according to one of Claims 1 until 24 , wherein the plastic material is electrically insulating. Ultrasonic transducer (1) according to one of Claims 1 until 25 , wherein an electrically conductive coating (10) for electromagnetic shielding is applied to an outside of the housing. Ultrasonic transducer (1) according to Claim 26 , wherein the electrically conductive coating (10) completely covers the outside. Ultrasonic transducer (1) according to Claim 18 and Claim 26 wherein an electrically conductive via is provided between the coating (10) on the outside and one of the traces (9) on the inside. Ultrasonic transducer (1) according to claim 28 , wherein the via is stamped in a through hole (11A) in a wall of the housing. Ultrasonic transducer (1) according to claim 28 , the via being pronounced in a groove (11B) in an outer edge of the housing wall surrounding the housing opening. Ultrasonic transducer (1) according to Claim 18 and Claim 26 , wherein the electrically conductive coating (10) and one of the tracks (9) on the printed circuit board (8) are electrically contacted. Ultrasonic transducer (1) according to one of Claims 1 until 31 wherein a cylindrical or conical preformed absorption element (7) is arranged at a distance from the bottom (2) in the interior of the housing. Ultrasonic transducer (1) according to Claim 32 wherein a cavity (7A) is provided between the preformed absorption element (7) and the bottom (2). Ultrasonic transducer (1) according to Claim 32 or 33 , wherein the absorption element (7) is a foamed plastic element comprising, for example, urethane or silicone. Ultrasonic transducer (1) according to one of Claims 32 until 34 , wherein a radial dimension of the absorption element (7) is greater than a radial extent of the interior of the housing in the region of the bottom (2). Method for producing a housing of an ultrasonic transducer (1), comprising the steps: - manufacturing a housing in an injection molding process, the housing comprising a base (2) and a housing wall, an outside of the housing wall having a first section (3) which is attached to the Bottom (2) adjoins, and a second section (4), which adjoins a housing opening, wherein the first and the second section (4) have different dimensions, wherein a transition section (5) between the first and the second section ( 4) is provided and wherein a surface normal (FN5), which is perpendicular to an outside of the housing wall in the transition section (5), is inclined to a surface normal (FN2) which is perpendicular to the floor (2), and wherein the surface normal ( FN5), which is perpendicular to the outside of the housing wall in the transition section (5), is oblique to a surface normal (FN3) which is perpendicular to an outside of the housing wall in the first section (3), and the surface normal (FN5) being perpendicular to the outside of the housing wall in the transition section (5) is inclined to a surface normal (FN4) which is perpendicular to an outside of the housing wall in the second section (4), and - attaching a transducer element which is designed to the bottom (2) to a to excite vibration with a frequency in the ultrasonic range, on an inner side of the floor. procedure according to Claim 36 , wherein conductive traces (9) are formed in an interior of the housing, wherein the conductive traces (9) are designed to connect the transducer element (6) on the bottom (2) with a circuit board (8) forming a cover of the housing, to connect electrically. procedure according to Claim 37 , wherein the conductive traces (9) are formed by means of laser direct structuring, sputtering, metal printing or a laser-induced graphene process.

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