Patent Description:
Ultrasonic liquid sensing transducers (ULSTs) are widely used for measuring the level of a liquid, a flow rate of a fluid and/or the concentration of components of the liquid. Such devices are based on measuring a lapsed time between the generation of an ultrasonic signal and the received echo of said generated ultrasonic signal. Based on the measured time of flight and a predetermined velocity of ultrasonic signals in the liquid or fluid to be sensed, a distance may be determined, which may correspond to a level of the liquid. The ultrasonic transducer may be operated by an integrated circuit (IC), such as an IC of the type ELMOS <NUM>/<NUM>, which includes functions of a time-to-digital converter and suitable functions for measurements based on the time-of-flight principle with picosecond accuracy. <CIT> describes a conventional ultrasonic liquid sensing transducer.

The ultrasonic signal may be generated by a piezoelectric element provided in the ultrasonic liquid sensing transducer, which is often mounted on a supporting structure and adapted to emit ultrasonic waves into a direction facing away from the supporting structure. However, a part of the ultrasonic waves generated by the piezoelectric element usually propagate along the opposite direction and are reflected and/or scattered by the supporting structure, which often leads to an undesired echo signal from the back side of the piezoelectric element and, hence, to a disturbing artefact. In some cases the artefact resulting from the signal reflected from the back direction may even be stronger than the actual signal to be measured from a reflection in forward direction.

It is, thus, desirable to provide an ULST having less measurement artefacts and an improved signal quality.

This problem is solved by an ultrasonic liquid sensing transducer, an ultrasonic liquid level sensing system and a method for producing an ultrasonic liquid sensing transducer having the features of the respective independent claim. Optional embodiments and features are subject-matter of the dependent claims and the description.

An ultrasonic liquid sensing transducer is provided, comprising a rigid supporting frame and a piezoelectric element mounted on the supporting frame. The supporting frame is adapted to support a peripheral section of the piezoelectric element and to provide a void overlapping with a central section of the piezoelectric element.

Further, an ultrasonic liquid level sensing system is provided comprising at least one ultrasonic liquid sensing transducer according to any one of the preceding claims.

Yet further, a method for producing an ultrasonic liquid sensing transducer is provided. The method comprises a step of providing a rigid supporting frame having a first surface and a second surface. The supporting frame further has a recess and a frame structure at least partly surrounding the recess. The method further comprises a step of attaching a first part of a housing to the second surface of the supporting frame such that the first part of the housing forms a boundary surface overlapping with the recess of the supporting frame. Moreover, the method comprises a step of arranging a piezoelectric element with its back surface at the first surface of the supporting frame such that the frame structure of the supporting frame supports a peripheral section of the piezoelectric element and the recess of the supporting frame overlaps with a central section of the piezoelectric element, wherein the boundary surface of the first part of the housing, the back surface of the piezoelectric element and the supporting frame enclose a void extending from the back surface of the piezoelectric element to the boundary surface of the first part of the housing. In addition, the method comprises a step of providing a second part of the housing enclosing the piezoelectric element, the first part of the housing and at least a part of the supporting frame.

An ultrasonic liquid sensing transducer is an ultrasonic transducer for liquid sensing applications, such as measuring a level of a liquid and/or a fluid flow and/or a concentration of a constituent or component of a liquid, such as a salt concentration of water. The ultrasonic liquid sensing transducer is, thus, to be adapted to be operated in a wet environment and has to exhibit suitable properties regarding ingress protection and chemical resistance. The ULST may operate at a central frequency of <NUM>, i.e. the frequency of the ultrasonic waves emitted by the ULST may be centered at or around a frequency of <NUM>. However, the ULST may also operate at other frequencies conventionally used for ultrasonic liquid sensing.

If not indicated otherwise, the acoustic impedances specified throughout the disclosure are specified for the central frequency of the ultrasonic waves to be emitted by the piezoelectric element. The central frequency may be <NUM>.

The supporting frame being rigid means that the supporting frame may have suitable mechanical properties, such as a stiffness, to provide suitable support of the piezoelectric element when the piezoelectric element is excited to generate ultrasonic waves. The supporting frame may have electrically conductive properties to provide electrical signals and/or an electrical field to the piezoelectric element for excitation and/or sensing.

The piezoelectric element may comprise a single piezoelectric unit or an array of multiple piezoelectric units. The piezoelectric element may be made of or comprise a piezoelectric material, such as lead zirconate titanate (PZT) and/or other piezoelectric ceramic materials. The central section of the piezoelectric element may be a section around a center point of the piezoelectric element in a plane perpendicular to a preferred emission axis, along which the ultrasonic waves are to be emitted. The peripheral section may be one or more sections at the edge of the piezoelectric element surrounding the central section. The supporting frame being adapted to support the peripheral section of the piezoelectric element and to provide the void overlapping with a central section of the piezoelectric element means that the supporting frame supports the piezoelectric element only along the edges but not in the middle. For instance, the peripheral section may extend from each edge of the piezoelectric element over not more than <NUM>%, optionally not more than <NUM>%, optionally not more than <NUM>% of the total width of the piezoelectric element in the respective direction. On the other hand, the peripheral section may extend over at least <NUM>%, optionally at least <NUM>% and optionally at least <NUM>% of the total width of the piezoelectric element in the respective direction on each side. The section of the piezoelectric element being enclosed by the peripheral section may be defines as the central section. The supporting frame may support the peripheral section of the piezoelectric element on each side of the back surface of the piezoelectric element, although according to some optional embodiments the supporting frame may support the piezoelectric element only on two or three sides.

The void is a cavity between the piezoelectric element and the housing, which has a significantly different acoustic impedance than the piezoelectric element and the housing. The void may be empty, i.e. evacuated, or filled with air. According to some embodiments, the void may be at least partly filled with a material having a significantly higher or lower acoustic impedance than the piezoelectric element and the housing. Thus, the void provides an acoustic barrier for ultrasonic waves emitted through the back surface of the piezoelectric element. The void overlapping with the central section of the piezoelectric element means that a projection of the void in a plane perpendicular to the intended emission direction of ultrasonic waves generated by the piezoelectric element overlaps with the central portion of the projection of the piezoelectric element in said plain. In other words, the void is arranged right under the central section of the piezoelectric element.

It is understood that the order of the steps comprised by the method for producing an ultrasonic liquid sensing transducer (ULST) may be changed, as long as an ULST having the features described herein can be obtained. In particular, the order of attaching the first part of the housing and arranging the piezoelectric element may be varied.

The disclosure provides the advantage that a transmission of ultrasonic waves to the back side of the ULST, i.e. via the back surface of the piezoelectric element, may be reduced or even eliminated. Due to the void at the back surface of the piezoelectric element, an emission and transmission of ultrasonic waves off the back surface of the piezoelectric element may be reduced or entirely eliminated, as the void has an acoustic impedance being significantly different from the acoustic impedance of the supporting frame and the housing and, thus, offers suitable properties for blocking or attenuating a transmission of ultrasonic waves.

Reducing or eliminating such undesired transmissions to the opposite direction of an intended emission direction allows reducing undesired measuring artefacts and, hence, improving the signal-to-noise ratio of the ULST. Moreover, avoiding or reducing undesired reflected signals of ultrasonic waves transmitted through the back surface of the piezoelectric elements may allow reducing the technical effort for electronic signal processing and/or signal evaluation and, thus, may reduce the requirements regarding the electronic hardware used for signal processing and signal evaluation.

In addition, the disclosure provides the advantage that the above-mentioned improvements may be achieved with a low manufacturing effort and, hence, at a low cost. In particular, the disclosure may allow providing said improvements with limited structural modifications of the parts of the ULST. Moreover, the disclosure may allow using an ULST according to the disclosure in combination with conventional devices and systems for flow, level, concentration and/or temperature measurement. In addition, the disclosure may allow operating an ULST according to the disclosure with a conventional microprocessor for flow, level, concentration and/or temperature measurements, such as the commercially availble microprocessor E703. <NUM> provided by ELMOS SEMICONDUCTORS SE. The disclosure further provides the advantage that the signal strength of the ultrasonic waves emitted as intended into the front direction is increased, as less or no energy is lost due to undesired emissions to the back direction. Hence, the energy provided as ultrasonic waves by the piezoelectric signals is used in a more efficient manner, as an undesired waste of ultrasonic energy emitted towards the back direction is eliminated or significantly reduced.

The supporting frame may at least partly be made of a rigid metal material. This may ensure suitable mechanical and/or thermal properties for supporting the piezoelectric element, in particular in an agitated state. Moreover, having the supporting frame made of a rigid metal material may allow using the supporting frame for electrically contacting the piezoelectric element and/or for applying an electric field to the piezoelectric element. The rigid metal material may comprise or consist of copper, which offers a high electrical conductivity, a high thermal conductivity and a high mechanical rigidity.

The ULST comprises a housing enclosing the piezoelectric element and at least a part of the supporting frame. The housing may be formed of a single part or comprise two or more parts. The housing may be adapted to offer an ingress protection for the ULST to prevent in particular liquids and fluids from entering the ULST. This may be particularly beneficial as it may allow using the ULST in direct contact with the liquid or fluid, whose level, flow and/or concentration is to be measured. In addition to the ingress protection, the housing may offer a suitable chemical resistance to sustain a direct contact with a liquid and/or fluid chemicals to be measured, such as solvents, gasoline and/or corrosive chemicals.

The housing may in particular cover also the front surface of the piezoelectric element, i.e. the surface intended for emitting ultrasonic waves to be used for the measurement purposes. The section of the housing covering the front surface of the piezoelectric element or a part of it may be adapted to act as a matching layer between the piezoelectric element and the fluid or liquid to be measured. Optionally an additional matching structure may be provided between the front surface of the piezoelectric element and the housing material covering the front surface piezoelectric element to further improve the matching and/or mechanical properties of the ULST. The matching layer with our without the optional matching structure may have a total thickness in forward direction corresponding to a quarter wavelength of the ultrasonic waves generated by the piezoelectric element in the housing material or an odd integer multiple of the quarter wavelength. For instance, a thickness of three quarters of the central wavelength may offer a suitable compromise between compactness and sufficient mechanical stability. The additional matching structure may have an identical or similar acoustic impedance as the housing material. The additional matching structure may be selected to exhibit a high adhesion to the piezoelectric element, which may facilitate attaching the housing material and in particular the matching layer to the front surface of the piezoelectric element. Moreover, the matching structure may serve the purpose of shielding heat generated in the molding step for applying the second part of the housing from the front surface of the piezoelectric element and, thus, reduce stress from the piezoelectric element during the manufacturing process. For instance, the additional matching structure may comprise or consist of a layer of the epoxy adhesive LOCTITE EA E-<NUM>-HP, as it is commercially available from HENKEL ADHESIVES TECHNOLOGIES. LOCTITE has an acoustic impedance of about <NUM>,<NUM> Mrayl which is almost identical to the acoustic impedance of PEI, which may be used as a housing material.

In some optional embodiments, the section of the housing covering the front surface of the piezoelectric element may have a thickness being adapted to the central wavelength of the ultrasonic waves emitted by the piezoelectric element. In particular, the section of the housing covering the piezoelectric element may have a total thickness corresponding to a quarter of the wavelength of the ultrasonic waves in the material of the housing or an odd integer multiple thereof. This may facilitate the out-coupling of the ultrasonic waves emitted by the piezoelectric element into the liquid or fluid being in direct contact with the ULST, and in particular with the outer side of the housing. The material of the housing may be selected such as to provide suitable properties regarding ingress protection, chemical resistivity and acoustic properties for transmitting ultrasonic waves. In particular, the housing may at least partly made of a plastic material and may particularly be made of polyetherimide, which offers suitable properties regarding ingress protection, chemical resistivity and suitable acoustic properties.

The void extends from a back surface of the piezoelectric element to a boundary surface of the housing opposing the back surface of the piezoelectric element. In other words, the void may be confined at at least two sides by the back surface of the piezoelectric element and the boundary surface of the housing. This provides the advantage that no further parts are needed for creating the void, as the void is defined by the piezoelectric element and the housing, which are anyways to be provided. Therefore, the production costs can be kept low and no significant modifications are required for providing an ULST having said void.

The housing may comprise a first part comprising the boundary surface. The housing may further comprise a second part enclosing the piezoelectric element, at least a part of the supporting frame and at least a part of the first part of the housing. This provides the advantage that two independent parts of the housing may be optimized and provided in a separate manner. For instance, the first part of the housing may be optimized for confining the void and may be applied in a first manufacturing step, wherein the second part of the housing may be optimized for providing a suitable ingress protection and/or mechanical stability for the ULST and may be applied in a second manufacturing step. Hence, providing a housing comprising several parts may facilitate the manufacturing process and may allow one or more degrees of freedom for adapting the properties of the ULST.

An average acoustic impedance of the void is at least <NUM> times smaller or at least <NUM> times higher than an acoustic impedance of the housing. The average acoustic impedance of the void may optionally be at least <NUM> times smaller or optionally at least <NUM> times higher than an acoustic impedance of the housing. For instance, the housing may be made of polyetherimide (PEI) having an acoustic impedance of about <NUM>,<NUM> Mrayl (= Mega Rayl; the unit Rayl or Mega Rayl used throughout the disclosure relates to the SI unit based MKS Rayl). When providing the void filled with air, which has an acoustic impedance of about <NUM>,<NUM> Mrayl, the acoustic impedance of the void is about <NUM> times smaller than the acoustic impedance of the housing offering a high attenuation of ultrasonic waves emitted by the piezoelectric element off the back surface of the piezoelectric element. Moreover, the use of PEI as a material for the housing offers suitable properties as a matching layer covering the front surface of the piezoelectric element, as its acoustic impedance having a value of about <NUM>,<NUM> Mrayl is well bridging between the acoustic impedance of the piezoelectric element (PZT ceramics have an acoustic impedance of about <NUM> Mrayl) to the liquid (water for instance has an acoustic impedance of about <NUM>,<NUM> Mrayl). This allows an efficient outcoupling of ultrasonic waves from the front surface of the piezoelectric element and an efficient suppression of an emission of ultrasonic waves off the back surface of the piezoelectric element.

The void may be evacuated or essentially filled with air. This ensures a very low acoustic impedance of the void being at least <NUM> times lower than the acoustic impedance of the housing. Moreover, this facilitates the production of the void, as no additional material and optionally no additional manufacturing steps are required for providing the void, which would otherwise be necessary for filling the void with a material different than the ambient air.

Alternatively, the void may at least partly be filled with one or more of the following materials: a gas, a vapor, a porous material, a foam material. The gas may be different than the ambient air during the production of the ULST. Using such materials may allow precisely adjusting the acoustic impedance of the void to a desired value and in particular establishing a precise ratio between the acoustic impedance of the housing and the acoustic impedance of the void. The materials may be chosen such that the acoustic impedance is at least <NUM> times or at least <NUM> times smaller than the acoustic impedance of the housing. For instance, annealed Tungsten may be used as a filling material for the void. Annealed Tungsten having an acoustic impedance of about <NUM> Mrayl, which is, thus, about <NUM> times higher than the acoustic impedance of PEI (about <NUM>,<NUM> Mrayl), which may be used as a housing material.

A thickness of the void corresponds to a thickness of a part of the supporting frame supporting the peripheral section of the piezoelectric element. For instance, the supporting frame surrounding the void and the void may flush, i.e. the supporting frame surrounding the void and the void may be adapted such as to have the same thickness. This provides the advantage that the void can be confined by the supporting frame in a plane perpendicular to the intended emission direction of the ultrasonic waves. This may facilitate the production of the ULST as no further parts are required for providing the void.

The void may have for instance a thickness of <NUM> or less, optionally <NUM>,<NUM> or less, optionally <NUM> or less and optionally <NUM>,<NUM> or less, and/or wherein the void has a thickness of <NUM>,<NUM> or more, optionally <NUM>,<NUM> or more and optionally <NUM>,<NUM> or more. Thus, according to an optional embodiment the void may have a thickness between <NUM>,<NUM> and <NUM>,<NUM>. Such a thickness may be a suitable compromise between an effective attenuation or elimination of ultrasonic waves emitted off the back surface of the piezoelectric element and a limited spatial extension allowing the production of a compact device.

In the method for producing an ULST, the first part of the housing and the second part of the housing may be made of a plastic material. The first part of the housing is applied in a first injection molding step and the second part of the housing is applied in a second injection molding step. This may provide a low-effort production of the housing and, hence, keep the production costs low.

The method may further comprise a step of filling the recess of the supporting frame prior to arranging the piezoelectric element at the first surface of the supporting frame at least partly with one or more of the following materials: a gas, a vapor, a porous material, a foam material. Alternatively, the method may comprise a step of evacuating the void. These steps may be obsolete when providing the void filled with ambient air present at the manufacturing process.

It is understood by a person skilled in the art that the above-described features and the features in the following description and figures are not only disclosed in the explicitly disclosed embodiments and combinations, but that also other technically feasible combinations as well as the isolated features are comprised by the disclosure. In the following, several optional embodiments and specific examples are described with reference to the figures for illustrating the disclosure without limiting the disclosure to the described embodiments.

Further optional embodiments will be illustrated in the following with reference to the drawings.

In the drawings the same reference signs are used for corresponding or similar features in different drawings.

<FIG> depict an ultrasonic liquid sensing transducer <NUM> (ULST) according to an optional embodiment, wherein <FIG> shows the ULST <NUM> in a perspective view and <FIG> shows the ULST in a cross-sectional view. The arrows <NUM> and <NUM> indicate the front direction or forward direction <NUM>, in which the emission of ultrasonic waves is intended, and the back direction <NUM>, in which no emission of ultrasonic waves is intended.

The ULST comprises several components, such as a rigid supporting frame <NUM>, which is adapted to mechanically support a piezoelectric element <NUM> arranged thereon. In order to sufficiently support the piezoelectric element <NUM> during an excitation of the piezoelectric element <NUM> for emitting ultrasonic waves, the supporting frame <NUM> has a high mechanical rigidity. Moreover, the supporting frame <NUM> may be made of a metal material, such as copper, offering a high electrical conductivity for electrically contacting the piezoelectric element <NUM> and/or for applying an electrical field to the piezoelectric element <NUM>. Moreover, providing the supporting frame <NUM> from a metal material having a high thermal conductivity, such as copper, may allow an efficient heat dissipation from the piezoelectric element <NUM> via the supporting frame <NUM>.

As can be seen in <FIG>, the piezoelectric element <NUM> is supported by the supporting frame <NUM> only in a peripheral section 14a, while the supporting frame <NUM> leaves a void <NUM> overlapping with a central section 14b of the piezoelectric element <NUM>. The supporting frame exhibits a respective recess overlapping with the central section 14b of the piezoelectric element <NUM> to ensure such a support only in the peripheral section 14a.

Moreover, the ULST <NUM> according to the presented embodiment comprises a housing <NUM> having a first part 18a and a second part 18b. The first part 18a of the housing <NUM> is mainly arranged underneath the supporting frame, i.e. on the back side of the supporting frame <NUM>, and provides a boundary surface <NUM>, which confines the void <NUM> towards the back direction <NUM>. Hence, the void <NUM> is confined by the back surface of the piezoelectric element <NUM> towards the front direction <NUM>, by the boundary surface <NUM> of the first part 18a of the housing <NUM> towards the back direction <NUM> and by the supporting frame <NUM> towards the side directions.

The second part 18b of the housing <NUM> encloses at least partly the other components, i.e. the piezoelectric element <NUM>, the supporting frame <NUM> and the first part 18a of the housing <NUM> to ensure a high level of ingress protection and optionally a high level of chemical resistance. The first part 18a of the housing <NUM> may be entirely enclosed by the second part 18b or may partly protrude to the outer surface of the housing <NUM>. Moreover, the first part 18a and the second part 18b of the housing may be made of the same material, for instance a plastic material such as polyetherimide, or may be made of different materials. However, the material may be chosen such as to ensure proper ingress protection and optionally chemical resistivity to be usable when immersed in the intended liquid to be measured. The supporting frame <NUM> may partly protrude from the housing <NUM> to provide metal pins for electrically contacting the supporting frame <NUM> from the outer side.

The void <NUM> provided at the back surface of the piezoelectric element <NUM> may be filled with air or may be evacuated. Alternatively, the void <NUM> may be filled with a different kind of gas, a vapor, a porous material and/or a foam material. In any case the void <NUM> has an acoustic impedance, which strongly differs from the acoustic impedance of the housing material at the central frequency of the ultrasonic waves emitted by the piezoelectric element <NUM>. In particular, the acoustic impedance of the void <NUM> is at least <NUM> times higher or smaller and optionally at least <NUM> times higher or smaller than the acoustic impedance of the housing material. The large difference between the acoustic impedances results in a pronounced step of acoustic behavior at the back surface of the piezoelectric element <NUM> which efficiently eliminates or attenuates the transmission of ultrasonic waves from the back surface of the piezoelectric element <NUM> into the void <NUM>. Consequently, the void <NUM> effectively blocks an emission of ultrasonic waves into the back direction <NUM> via the back surface of the piezoelectric element <NUM> and, thus, reduces undesired artefacts which might otherwise originate from back reflections of ultrasonic waves emitted to the back direction <NUM>.

With reference to <FIG> the different components of the ULST <NUM> according to the optional embodiment and the assembly of the ULST <NUM> is explained.

<FIG> depicts the supporting frame <NUM> in a top view. As can be seen, the supporting frame <NUM> may be made of a single piece of metal offering a frame structure to support the peripheral section 14a of the piezoelectric element <NUM> and offering a recess <NUM> for creating the void <NUM> overlapping with the central section 14b of the piezoelectric element <NUM> to be supported by the supporting frame <NUM>.

<FIG> show the first part 18a of the housing <NUM> arranged at the supporting frame <NUM> in a top view and a perspective view, respectively. In some sections the first part 18a of the housing <NUM> interdigitates with the supporting frame <NUM> to ensure a defined relative positioning of both components. As can be seen, the first part of the housing 18a covers the recess <NUM> of the supporting frame <NUM> and by this provides the boundary surface <NUM> for confining the void <NUM> towards the back direction <NUM>. The first part 18a of the housing <NUM> may evenly cover the recess <NUM> such that the void <NUM> is confined flush with the surrounding supporting frame <NUM>.

<FIG> presents the components shown in <FIG> having the piezoelectric element <NUM> attached to the supporting frame <NUM>. As can be seen, the piezoelectric element <NUM> is arranged on the supporting frame <NUM> such as to entirely cover the recess <NUM> and to be supported by the supporting frame <NUM> only in the peripheral section 14a, i.e. along the edges of the piezoelectric element <NUM>. Consequently, the recess <NUM> located underneath the back surface of the piezoelectric element <NUM> forms the void <NUM> being directly adjacent to the back surface of the piezoelectric element <NUM> and being confined by the piezoelectric element <NUM>, the boundary surface <NUM> of the first part of the housing 18a and the supporting frame <NUM>.

<FIG> depicts the final ULST <NUM>, wherein the components shown in <FIG> are enclosed by the second part 18b of the housing <NUM>. According to the presented embodiment, the first part 18a of the housing <NUM> protrudes to the outer surface of the ULST <NUM> in some sections, which however is optional. In any case, the housing <NUM> offers an ingress protection and a chemical resistivity being suitable for operating the ULST <NUM> in the liquid to be measured by the ULST <NUM>. A section of the second part 18b of the housing <NUM> covers the piezoelectric element <NUM> in the front direction <NUM> and, thus, has the additional function of transmitting the ultrasonic waves emitted by the piezoelectric element <NUM> into the front direction <NUM>. This section of the housing <NUM> may serve as a matching layer facilitating the transmission and outcoupling of the emitted ultrasonic waves as well as facilitating the incoupling of received echo signals to be detected by the ULST <NUM>. For this purpose, the housing <NUM> may be made of a material having an acoustic impedance in a range between the acoustic impedance of the piezoelectric element <NUM> and the acoustic impedance of the surrounding liquid. Moreover, a thickness of the covering section of the housing <NUM> may be adapted to facilitate the transmission and coupling of the emitted and received ultrasonic waves. According to an optional embodiment, the ULST <NUM> may have an additional matching structure (shown in <FIG> with reference sign <NUM>) between the front surface of the piezoelectric element <NUM> and the second part 18b of the housing <NUM>, which may further improve the coupling and transmission of ultrasonic waves. The additional matching structure may have the same or a similar acoustic impedance in a range between the acoustic impedance of the piezoelectric element <NUM> and the acoustic impedance of the material of the housing <NUM> and thus contribute to the effect of the matching layer. Moreover, the additional matching structure <NUM> may provide beneficial mechanical properties for protecting the piezoelectric element. The matching layer including an optional matching structure <NUM> may have a specific thickness with regard to the central wavelength or frequency of the ultrasonic waves to be emitted. For instance, the thickness of the matching layer may be equal to a quarter of the wavelength of the ultrasonic waves in the material of the additional matching layer or an odd integer multiple thereof.

In the following an exemplary method for producing an ULST according to the above-presented optional embodiment is explained with reference to the flow diagram <NUM> presented in <FIG>.

In a first step <NUM>, a rigid supporting frame <NUM> is provided, which may be made of copper. The rigid supporting frame <NUM> has a first surface and a second surface, as well as a recess <NUM> and a frame structure at least partly surrounding said recess to support a piezoelectric element <NUM>.

In step <NUM>, a first part 18a of a housing <NUM> is attached to the supporting frame <NUM>. The first part 18a of the housing <NUM> may be provide by injection molding. The first part 18a of the housing <NUM> is attached to the second surface of the supporting frame <NUM>, which is the back surface, such that the first part 18a of the housing <NUM> forms a boundary surface <NUM> overlapping with and covering the recess <NUM> of the supporting frame <NUM>.

In step <NUM>, a piezoelectric element <NUM> is arranged with its back surface at the first surface, i.e. the front surface, of the supporting frame <NUM> such that the frame structure of the supporting frame <NUM> supports a peripheral section 14a of the piezoelectric element <NUM> and the recess <NUM> of the supporting frame <NUM> overlaps with a central section 14b of the piezoelectric element <NUM>, wherein the boundary surface <NUM> of the first part 18a of the housing <NUM>, the back surface of the piezoelectric element <NUM> and the supporting frame <NUM> enclose a void <NUM> extending from the back surface of the piezoelectric element <NUM> to the boundary surface <NUM> of the first part of the housing 18a.

In step <NUM>, the piezoelectric element and/or the supporting frame <NUM> may be electrically contacted. This may be achieved by welding wires to the supporting frame <NUM>, i.e. to contact pins of the supporting frame protruding from the housing <NUM>.

In step <NUM>, the function of the piezoelectric element <NUM> and/or the ULST <NUM> may be tested and/or characterized by carrying out respective measurements.

In step <NUM>, a second part 18b of the housing <NUM> is provided such as to enclose at least partly the piezoelectric element <NUM>, the first part 18a of the housing <NUM> and at least a part of the supporting frame12. The second part 1b of the housing <NUM> may be provided in a further injection molding step. The second part 18b of the housing <NUM> may be made of the same material as the first part 18a of the housing <NUM>.

In step <NUM>, an end-of-line test may be carried out to test the correction function of the ULST <NUM>.

In step <NUM>, if the ULST <NUM> passed the test in step <NUM>, the ULST <NUM> may be packaged.

With reference to <FIG> a comparison of different ULSTs is provided, wherein <FIG> shows a conventional ULST having no void provide at the back surface of the piezoelectric element, <FIG> shows an ULST <NUM> according to the embodiment detailed with reference to <FIG> having the void <NUM> filled with air, and <FIG> depicts an ULST <NUM> according to a further embodiment having an additional matching structure <NUM> arranged at the front surface of the piezoelectric element <NUM> but being otherwise identical to the ULST <NUM> shown in <FIG>. For the sake of the comparison and to demonstrate the beneficial effect of the void <NUM>, the conventional ULST shown in <FIG> has been provided by preparing the ULST in the same manner as the ULST <NUM> shown in <FIG> with the only difference that the void <NUM> is filled up with housing material of the first part 18a of the housing <NUM>.

The characteristics of various samples of each type of ULST, as presented in <FIG> have been measured, wherein the ULSTs were operated using an E703. <NUM> microprocessor of ELMOS SEMICONDUCTOR SE. For the measurement, the voltage signal of a reflection in a distance of <NUM> in front direction <NUM> from the ULST has been measured and compared to a possible artefact voltage signal generated by a reflection from the back direction <NUM>.

The conventional ULST shown in <FIG> measured a voltage signal from the reflection of the front direction in the range from <NUM>,<NUM> V to <NUM>,<NUM> V wherein the artefact voltage signal caused by the reflection from the back direction were measured to be in the range from <NUM>,<NUM> V to <NUM>,<NUM> V. It is to be noted that the artefact voltage signal from the back reflection is very pronounced and even stronger than the actual signal obtained from the reflection in front direction <NUM>.

In contrast, the ULST <NUM> according to an embodiment of the disclosure, as presented in <FIG>, did not exhibit any artefact voltage signal caused by an undesired reflection from the back direction. Consequently, the related artefact voltage signal is <NUM> V. The measured signal obtained from the desired reflection in front direction was measured to be in a range from <NUM>,<NUM> V to <NUM>,<NUM> V. Hence, the void <NUM> and the ULST <NUM> according to the disclosure not only effectively block undesired reflections from the back direction and, thus, eliminate artefact voltage signals, but also increase the signal strength for measurements in front direction, which further improves the signal-to-noise ratio.

Claim 1:
Ultrasonic liquid sensing transducer (<NUM>) comprising:
- a rigid supporting frame (<NUM>);
- a piezoelectric element (<NUM>) mounted on the supporting frame (<NUM>); and
- a housing (<NUM>) enclosing at least partly the piezoelectric element (<NUM>) and the supporting frame (<NUM>);
wherein the supporting frame (<NUM>) is adapted to support a peripheral section (14a) of the piezoelectric element (<NUM>) and to provide a void (<NUM>) overlapping with a central section (14b) of the piezoelectric element (<NUM>),
characterized in that
- the void (<NUM>) extends from a back surface of the piezoelectric element (<NUM>) to a boundary surface (<NUM>) of the housing (<NUM>) opposing the back surface of the piezoelectric element (<NUM>);
- a thickness of the void (<NUM>) corresponds to a thickness of a part of the supporting frame (<NUM>) supporting the peripheral section (14a) of the piezoelectric element (<NUM>), and
- an average acoustic impedance of the void (<NUM>) is at least <NUM> times smaller or at least <NUM> times higher than an acoustic impedance of the housing (<NUM>).