The present disclosure relates generally to improving acoustic transmission efficiency by incorporating acoustic matching structures into acoustic transducers.
Acoustic transducers convert one form of energy, typically electrical, into acoustic (pressure) waves. The proportion of energy that is emitted from the transducer into the surrounding acoustic medium depends on the acoustic impedance of the medium relative to the transducer. For effective transmission, the impedances should be close to equal. In many applications the acoustic medium will be air or another gaseous medium, which, typically, has an acoustic impedance several orders of magnitude lower than that of the transducing element. This large impedance mismatch leads to poor transmission of energy into the acoustic medium, limiting the amount of acoustic energy emitted by the transducer. Techniques to improve the transmission efficiency involve adding a matching layer, or matching structure, between the transducer and acoustic medium.
Many conventional impedance matching layer approaches require dimensions parallel to the transmission direction be a significant fraction of an acoustic wavelength. This limits their usability for applications that require a very thin or compact solution. A further disadvantage of conventional impedance matching layers is that the low acoustic impedance materials used may require complex manufacturing processes.
This application describes an acoustic matching structure used to increase the transmission efficiency of an acoustic transducer when emitting into a medium that has an acoustic impedance significantly lower than that of the transducer.
The following terminology identifies parts of the transducer: the transducer consists of an acoustic matching structure and a transducing element. The acoustic matching structure is passive and is designed to improve the efficiency of acoustic transmission from the transducing element to a surrounding acoustic medium. The transducing element generates acoustic output when driven with an electrical input. The transduction mechanism may be by oscillating motion, for example using an electromechanical actuator, or by oscillating temperature, for example, using an electrothermal transducer.
Specifically, an acoustic matching structure is used to increase the power radiated from a transducing element with a higher impedance into a surrounding acoustic medium with a lower acoustic impedance.
The acoustic matching structure consists of a resonant acoustic cavity bounded by an acoustic transducing element and a blocking plate. The resonant acoustic cavity amplifies pressure oscillations generated by the transducing element and the blocking plate contains one or more apertures, which allow pressure oscillations to propagate from the resonant acoustic cavity into the surrounding acoustic medium.
A preferred embodiment of the acoustic matching structure consists of a thin, substantially planar cavity bounded by a two end walls and a side wall. The end walls of the cavity are formed by a blocking plate wall and a transducing element wall separated by a short distance, less than one quarter of the wavelength of acoustic waves in the surrounding acoustic medium at the operating frequency of the transducer. The end walls and side wall bound a cavity with diameter approximately equal to half of the wavelength of acoustic waves in the surrounding acoustic medium. In operation, a transducing element generates acoustic oscillations in the fluid in the cavity. The transducing element may be an actuator which generates motion of an end wall in a direction perpendicular to the plane of the cavity to excite acoustic oscillations in the fluid in the cavity, and the cavity causes resonant amplification of the resulting pressure oscillation. The cavity side wall or end walls contain at least one aperture positioned away from the center of the cavity to allow pressure waves to propagate into the surrounding acoustic medium.
The accompanying figures, where like reference numerals refer to identical or functionally similar elements throughout the separate views, together with the detailed description below, are incorporated in and form part of the specification, serve to further illustrate embodiments of concepts that include the claimed invention and explain various principles and advantages of those embodiments.
Those skilled in the art will appreciate that elements in the figures are illustrated for simplicity and clarity and have not necessarily been drawn to scale. For example, the dimensions of some of the elements in the figures may be exaggerated relative to other elements to help to improve understanding of embodiments of the present invention.
The apparatus and method components have been represented where appropriate by conventional symbols in the drawings, showing only those specific details that are pertinent to understanding the embodiments of the present invention so as not to obscure the disclosure with details that will be readily apparent to those of ordinary skill in the art having the benefit of the description herein.
In this description, a transducing element directly refers to the portion of the structure that converts energy to acoustic energy. An actuator refers to the portion of the solid structure that contains the kinetic energy before transferring it to the medium.
The specific acoustic impedance of a gas or material is defined as the ratio of the acoustic pressure and the particle speed associated with that pressure, or
This holds for arbitrary acoustic fields. To simplify this discussion, it is most useful to consider the plane wave solution to the above. This reduces the equation to scalar quantities,
z=ρc,
for a wave propagating in the same direction as the particle velocity, and where ρ is the density and c is the speed of sound of the medium. The importance of this quantity is highlighted when considering the reflection and transmission from an interface between two acoustic media with differing acoustic impedance. When a plane wave is incident on a medium boundary traveling from material with specific acoustic impedance z1 to z2, the normalized intensity of reflection (R) and transmission (T) is,
This shows that when the impedance of the two media have substantially different values, the reflected intensity is much larger than the transmitted intensity. This is the case for most gas coupled acoustic actuators where the actuator is composed of bulk, solid material with acoustic impedance on the order of Z1≈107 kg·m−2·s−1 and for example, air at sea level and 20° C. at Z3≈400 kg·m−2·s−1. This results in decreased efficiency and output.
The acoustic impedance of a resonant piezoelectric bending actuator has been analyzed for a 40 kHz actuator (Toda, IEEE Transactions on Ultrasonics, Ferroelectrics, and Frequency Control, Vol. 49, No. 7, July 2002) giving Z1≈2×104 kg·m−2·s−1. Although this resonant bending actuator has a much lower acoustic impedance than the bulk materials from which it is constructed (PZT and aluminum), there remains a substantial difference between the actuator impedance and air impedance, decreasing efficiency and acoustic output.
A solution to this problem is to add an acoustic matching layer with an impedance Z2 which serves as an intermediary between the higher-impedance actuator and the lower-impedance bulk gaseous phase medium.
An acoustic matching layer or other acoustic matching structure is required to be inserted into the path of acoustic energy transfer from the actuator into the medium and is designed to have an acoustic impedance that is as close as possible to the optimal matching structure impedance, that is the geometric mean of the acoustic impedances of the source and the destination, which in some embodiments may be a higher-impedance actuator and the lower-impedance bulk air or other acoustic medium. The effect of the intermediate impedance matching layer is that the energy transfer from the higher impedance region to the matching layer and then from the matching layer to the lower impedance region is more efficient than the more direct energy transfer from the higher to the lower impedance regions.
There may also be a plurality of matching layers that form a chain which is at its most efficient when the logarithms of the acoustic impedances of the endpoints and each matching layer form a chain whose values are progressive and substantially equally spaced.
In the case of a single-material matching layer added to the surface of a transducing element, there are two key properties that must be selected and balanced:
1. The acoustic impedance of the layer, Z2, must be approximately equal to the geometric mean of the impedance of the acoustic source region, which in some embodiments may consist of a piezoelectric source element (Z1) and the impedance of the medium (Z3).
2. The thickness of the layer of bulk material must be approximately equal to a quarter wavelength of the longitudinal pressure waves in the matching layer material at the operating frequency (frequency of pressure oscillations).
These two properties must be tuned and matched, as the thickness of the layer of any given material also impacts the acoustic impedance. It can be seen that there will only be a limited selection of suitable materials, and for some ranges of frequencies this limited selection may be small.
As an example, the acoustic impedance of a matching layer for a thickness-mode, piezoelectric actuator operating in air may be computed. The acoustic impedance required in this situation is approximately 100,000 kg·m−2·s−1. The computation proceeds by taking logarithms of each of the impedances of the adjoining elements, which is found to be approximately 7.5 for the piezoelectric transducing element (Z1) and approximately 2.5 for the bulk air (Z3) at the expected temperature and pressure. Then, for each matching layer required the average of the logarithms of the impedances of the adjoining regions may be used to determine the logarithm of the impedance required for the matching layer. Table 1 shows the acoustic impedance of air and PZT-5A (a piezoelectric material), and the ideal acoustic impedance of a matching layer for a thickness mode piezoelectric actuator operating in air which is
alongside the logarithms of each of the impedances.
The acoustic impedances required for an ideal matching layer to bridge this large gap in acoustic impedances must be therefore composed of a solid material with a very low speed of sound and low density. The low speed of sound is preferable in order to reduce the size or volume of material required to make a matching layer that fits the quarter wavelength criterion. The low density is required for the material to have an acoustic impedance that is appropriate to a matching layer. But in general, suitable materials do not occur naturally. They must be often constructed with special manufacturing processes that tend to be complex and difficult to control, leading to variable acoustic properties and variable performance as a matching layer. For examples of such constructed suitable materials, matching layers using glass and resin microspheres are described in U.S. Pat. No. 4,523,122 and a matching layer using a dry gel material is described in U.S. Pat. No. 6,989,625. An ideal matching layer for a typical resonant piezoelectric bending actuator would have even lower acoustic impedance and would be more challenging to construct.
A further problematic issue with low-density, low-speed-of-sound matching layers of suitable materials is the constraint on thickness imposed by the quarter wavelength requirement. The lower the primary operating frequency of the transducing element, the longer the wavelength and the thicker the matching layer must be. For example, the wavelength at 40 kHz in air at ambient pressure and temperature is 8.58 mm. Therefore, assuming the material has a similar speed of sound to that of air—which would itself be difficult to achieve as it would require a high-density but low-stiffness material which would again likely require a specialist process to create—an ideal matching layer would have a thickness close to 2.14 mm. In thickness-constrained applications, this may be too great to be viable, either commercially or for the particular application of interest. Matching layers made of a material with a speed of sound greater than air would need to be thicker than this 2.14 mm.
This invention proposes the use of a vented resonant acoustic cavity formed by placing a blocking plate in the path of the acoustic energy transfer from a transducing element to an acoustic medium to achieve an intermediate acoustic impedance, that is lower acoustic impedance than that of the transducing element and higher acoustic impedance than the surrounding acoustic medium. The intermediate acoustic impedance increases the efficiency of acoustic energy transfer from the transducing element to the acoustic medium, and is provided through the production of a controlled resonant acoustic mode in an acoustic cavity in the path of the transfer of acoustic energy from the transducing element to the acoustic medium. The acoustic cavity that constrains the acoustic medium in a way that gives rise to a resonant acoustic mode in the acoustic medium that can be excited by the transducing element. The blocking plate which forms one face of the acoustic cavity contains apertures that allow acoustic energy to be transmitted from the acoustic cavity into the acoustic medium.
The effective acoustic impedance of the acoustic matching structure can be determined from the definition of acoustic impedance, Z=p/u, that is the ratio of acoustic pressure to particle velocity. In operation, the actuator creates a boundary velocity field in the acoustic medium and is situated on one side of the blocking plate which is placed intentionally in the path of the energy transfer. The actuator and blocking plate form an acoustic cavity substantially bounded by the actuator and the blocking plate. The actuator drives an acoustic wave from the surface of the actuator into the acoustic cavity. As the actuator continues to oscillate with substantially constant displacement amplitude and frequency, resonant acoustic oscillations in the cavity are excited and build in amplitude. The resonant increase in acoustic pressure resulting from substantially constant actuator oscillation velocity amplitude indicates an increase in the effective acoustic impedance of the acoustic cavity relative to the bulk acoustic medium by a factor of Qcavity, where Qcavity is the quality factor of the cavity acoustic resonance.
In the structure designed to produce such a resonant acoustic mode, the dimensions can also be arranged and resized so that the close spacing of the blocking plate and actuator increases the effective acoustic impedance of the acoustic medium by confining the fluid to a thin layer and constraining the fluid motion to be substantially parallel to the face of the actuator. In the case of a flat cylindrical cavity, the fluid velocity and pressure are increased by a factor: fgeom=rcavity/(2 hcavity), where rcavity is the radius of the cavity and hcavity is the height of the cavity, that is the separation of the actuator and blocking plate, and the effective acoustic impedance of the medium is increased by the same factor fgeom. Preferably, rcavity>5 heavily so that fgeom>2.5, and more preferably, rcavity>10 hcavity so that fgeom>5. The acoustic impedance of the fluid in the cavity is increased relative to the bulk acoustic medium by a factor: Qcavity×fgeom, the product of the resonant cavity quality factor and the geometric amplification factor. In this way the acoustic cavity acts as an acoustic matching layer with acoustic impedance higher than the bulk acoustic medium and lower than the actuator.
It is useful to consider the minimum cavity height that can support an acoustic resonance. In order to establish an acoustic resonance in the cavity without excessive viscous losses we require hcavity>δ, where δ is the viscous boundary layer thickness. For a cylindrical cavity with radius rcavity containing a fluid with speed of sound c, with a pressure node at its perimeter, the first radial acoustic mode has a pressure distribution following a Bessel function of the form:
and the frequency of the first radial acoustic resonance, f0, is given by:
From this we can derive the condition
For or operation in air at 20° C., this gives
For gases with lower kinematic viscosity and higher speed of sound, this value may be smaller, as low as 1×10−8 m.
However a small cavity height is beneficial as the narrow separation of actuator and blocking plate constrains the acoustic medium and results in an increase in the radial velocity of the acoustic medium in the cavity for a given actuator drive velocity, with a geometric amplification factor fgeom=rcavity/(2 hcavity) as described above. The optimal cavity height results from a tradeoff between maximizing the geometric amplification factor, and maximizing the cavity quality factor by minimizing the viscous losses in the boundary layers.
However, as the goal is to transfer the energy into the medium, an aperture is needed to allow acoustic waves to escape from the structure. It is helpful to balance the constraints of the maintenance and conservation of the appropriate acoustic perturbation, wherein a smaller area aperture in the novel matching structure is beneficial, which the requirement that the increased perturbation be transmitted onwards into the acoustic medium, wherein a larger area aperture in the novel matching structure is beneficial. At least some aperture, which may comprise one or many discrete sections, must be added so that a portion of the acoustic output generated by the transducer can escape on every cycle into the bulk medium.
In these embodiments, the term “acoustic medium” refers to the medium inside the cavity through which acoustic waves travel. The “bulk medium” refers to the acoustic medium which exists outside the cavity. The medium can be liquid, such as water, or gas, such as air or any other medium which is distinct from the construction material of the invention. Any medium supporting acoustic waves can be referred to as a “fluid” for the purposes of this discussion.
The process of designing the structure that is to create a suitable resonant mode in the acoustic medium can be illustrated with a simplified boundary value problem. A simple structure can embody the properties described above in the form of an acoustic cavity consisting of a volume of the acoustic medium which has in this example been restricted by a surrounding structure of side walls. The resonant frequency mode structure can be determined by finding solutions to the Helmholtz equation,
∇2p+k2p=0
with p=P(x)exp(jωt) and p=c02ρ1, with appropriate boundary conditions. In these equations P(x) is the peak pressure deviation from ambient pressure (a spatially varying function of the displacement vector x=[x, y, z] in Cartesian coordinates or function of the displacement vector r=[r, θ, z] in cylindrical coordinates from the cavity origin), p is the complex-valued acoustic pressure, c0 is the speed of sound in the ambient medium, ρ1 is the first-order density deviation from ambient density (where the density is this deviation ρ1 added to the ambient density ρ0, so ρ=ρ0+ρ1), ω is the acoustic angular frequency, t is time, j is √{square root over (−1)}, and k is the wavenumber. It can be immediately appreciated that the acoustic pressure, p, can be related to the density, ρ, and thus the acoustic impedance as previously discussed.
As an example using cylindrical coordinates, suitable for a cylindrical cavity, we can consider a cavity with radius acavity and height hcavity. The domain of interest is described by 0≤r≤acavity, 0≤θ≤2π, 0≤z≤hcavity. Separation of variables allows for an analytic solution of the form,
P
lmn
=A
lmn
J
0(krlr)cos(kθmθ)cos(kznz)ejω
Where J0 is the zeroth order Bessel function of the first kind, with the radial wavenumber krl having values given by Bessel function zeros divided by the cavity radius, kθm having integer values (kθm=m) and kzn having values given by kzn=2πn/hcavity. The first three values of krl are given by: kr0=2.404/acavity, kr0=5.201/acavity, kr0=8.6537/acavity. Note that Plmn=0 at r=acavity in this analytical description, corresponding to a zero pressure boundary condition. In practice, this analytical description is not fully accurate, and the boundary condition will be mixed (neither zero pressure nor zero displacement) due to the presence of apertures near r=acavity. However Plmn will be small at r=acavity compared with its value at r=0, as shown by the results of a numerical simulation shown in
As an example using Cartesian coordinates, we can work through the determination of the mode structure for the medium volume contained within a rectangular cavity with rigid walls, the origin placed at one corner of the box, with the axes oriented such that the domain of interest is described by x≥0, y≥0 and z≥0. Separation of variables then allows for an analytic solution of the form,
p
lmn
=A
lmn cos(kxlx)cos(kymy)cos(kznz)ejω
with the wavenumbers kxl, kym and kzn given by the physical dimensions of the cavity Lx, Ly, and Lz respectively as:
wherein l, m and n can be substituted for any unique combination of integers to describe each resonant mode of the cavity.
The angular frequency that generates the mode is then given by,
ωlmn=c0√{square root over (kxkl2+kym2+kzn2)}
The amplitude of the wave (Almn) scales with input but in this analysis has no effect on the frequency of the mode.
Let us examine the specific case of the mode l=2, m=2 and n=0 wherein Lx=Ly=L. Here the angular frequency is given by
The acoustic pressure within the cavity is given by
with no dependence on z. The bottom center of the cavity
is an acoustic pressure antinode and experiences the same peak pressure as the walls which can be much higher than the ambient pressure. An actuator placed at this location receives the benefit of working against a higher pressure for a given displacement. The lack of z-dependence in this example means that this cavity achieves this mode even if Lz is very small.
The presence of apertures causes a mixed boundary condition, and this complicates the solution. Furthermore, losses and energy propagation from the transducing element to the external acoustic medium lead to a travelling wave component in the acoustic wave. The result is that there are no perfectly nodal locations, but there are locations of minimum pressure oscillation amplitude.
Aperture(s) which allow acoustic energy to propagate from the cavity to the surrounding acoustic medium are located in areas of lower pressure oscillation amplitude, and transducing elements are located in areas of higher pressure oscillation amplitude.
The description above describes the idealized case of an acoustic mode in a closed, rigid box. In practice, the pressure oscillation amplitude would be reduced near apertures which allow pressure waves to propagate through from the cavity to the external acoustic medium.
There is a minimum necessary Lz related to the viscous penetration depth,
where v is the kinematic viscosity of the medium. Significantly smaller than this value will result in energy being lost to heat through thermo-viscous boundary layer effects at the walls. The clear advantage of this solution over a typical matching layer is that it can be much smaller in thickness than
(where λ is the wavelength) because this utilizes a mode that is not in parallel with the path of acoustic energy transfer to influence the transfer of the acoustic energy.
It need not, however, be small in z as in this example. If desired a tall, thin cavity can be designed with a high-pressure antinode occurring near the actuator. This may be beneficial in applications in which compacting larger numbers of transducers in a small surface area is required, but thickness restrictions are relaxed instead. For instance, take the mode shape l=0, m=0 and n=1 of the acoustic medium as before where in this case Lz=L. Here the angular frequency is instead given by
and the acoustic pressure is given by
which in this example has only dependence on z. Using a long actuator in the form of a strip that extends away from the aperture and bends with maximum displacement at the opposite location in z is advantageous here. This is because the high-pressure antinode and thus the most suitable instantaneous acoustic impedance must occur in this example at the furthest point where z=L.
Further examples may be constructed, especially in cases where there is at least one dimension that does not have length limiting requirements, as shown in
To achieve even higher acoustic pressure, it may be reasonable to construct a cavity wherein the mode shape is defined by l=0, m=0 and n=3. In this case, there are two antinodes present in the along the length of the acoustic cavity. Unlike the above examples, these antinodes are out of phase and swap every half period of the progressive wave mode present in the cavity. By driving into both antinodes at their respective high-pressure points in the cycle, with two transducers transferring energy with each driven π radians out of phase, higher pressures and thus further increased acoustic impedances may be generated which would lead to more efficient energy transfer to the acoustic medium. In another embodiment, a single actuator could be situated such that during one phase of its motion it applies displacement into one antinode of the structure and during the opposite phase excites motion at the other antinode. This could be accomplished through mechanical coupling to a flexible surface at the second antinode location. Alternatively, a small pocket of gas could provide coupling to a flexible surface. In another arrangement, the actuator could be designed to operate in an ‘S’-shaped mode where half is moving into the structure and half is moving out during one polarity of drive which reverses at the other polarity. This would then be matched to a structure containing out-of-phase antinodes at the surfaces of maximum displacement.
The example cavities described in the previous two paragraphs describe tubular-shaped embodiments of the invention with one primary dimension extending longer than the other two. An advantage of this arrangement is that the cavity need not extend directly normal to the transducing element but can curve if necessary. This acts like a waveguide to direct and steer the acoustic wave while still developing the mode structure necessary to be an effective matching layer. The effective cavity cross-section which helps maintain the acoustic mode will follow the acoustic wave-front through the cavity. An estimate of the path of the cavity mode can be made by connecting an imaginary line from the center of the transducing element to center of the blocking plate through the cavity while maximizing the average distance at any point on the line to the side walls. Taking cross sections using this line as a normal can adequately estimate the mode structure. Bending and altering the cavity cross section can, for instance, enable shrinking the effective spacing in an array arrangement. This could be done by arranging a network of matching cavities from an array of transducers with a given pitch and reducing and skewing the opposite blocking plate side of the cavity so that the pitch is narrower on the aperture side. This embodiment could also be used to change the effective array arrangement from, for example, rectilinear to hexagonal packing.
A further variation on this theme may be considered if the transducer is required to have a wider spread of frequency variability. If there are two axes in which the mode numbers {l, m, n} are non-zero (such as the mode of the first example l=2, m=2, n=0), then the ω for each non-zero axis may be effectively perturbed to shift the peak of the resonant mode to different frequencies when each axis is considered as a separate resonant system. An embodiment of this perturbation of w may be realized by modifying the geometry internal cavity from a square prism to a rectangular prism, wherein the deviation from a square prism is indicative of the separation of the two resonant peaks. When these peaks are close together, they may be considered as a de facto single (but potentially broader) peak. When these w deviate, it has the effect of broadening the resonant peak of the output, enabling reduced manufacturing tolerances to be used or allowing the driven frequency to vary from the resonant frequency without experiencing sharp loss of output. This broader response is at the expense of reduced output at the peak frequency.
A similar analysis can be done for an arbitrary shaped structure or cavity. Some, like a cylindrical cavity, can be solved analytically in a way that is similar to the previous examples, while others will need the help of numerical simulations such as finite element analysis to predict where, when and how the appropriate high-pressure antinodes will form. The design goal is to have an acoustic mode which yields a pressure distribution that spatially mimics the displacement of the actuator mounted in the acoustic transducer structure at the desired frequency of oscillation.
If an enclosed cavity is designed to hold and maintain the resonant mode in place, apertures should ideally be added to the surface of the resonant cavity to allow a portion of the acoustic field in the cavity to escape into the bulk medium on every cycle. The exact shape and placement of the apertures does not lend itself to closed-form analytic analysis. In general, the size should be kept small compared to the larger length dimensions of the mode in the cavity so that they do not substantially disturb the cavity mode; apertures that are too large will cause a significant loss of acoustic pressure in the cavity and will cause the desired impedance effect to wane. Too small, however, and not enough acoustic pressure will escape per cycle therefore reducing the efficacy of the cavity as a matching layer. An aperture shape which substantially corresponds to an equiphasic portion of the acoustic mode shape will also help prevent significant disturbance of the mode shape. Some examples of apertures are given in
A. Blocking Plate Structure Design
The blocking plate structure forms a cavity 795 positioned immediately next to the actuating face of the acoustic transducing element assembly which represents the primary transfer surface for moving kinetic energy into the acoustic medium. The acoustic resonant frequency of this cavity in this embodiment is chosen to match the substantially radial mode to increase the power radiated by the transducer into the propagation medium. This is possible because the small cavity 795 between the transducing element and the blocking front plate of
Aperture examples are shown in
Further, it is possible to tune the frequency of the acoustic resonance of the cavity that, when coupled to the transducing element that has its own operating frequency, may provide desirable characteristics of the acoustic output (e.g. broadband, high on-axis pressure, high radiated acoustic power). The transducing element operating frequency may be different from the acoustic resonant frequency. When the resonant frequency of the cavity and the operating frequency of the transducing element are closely matched, the radiated acoustic power is greatest. A further performance improvement may be realized if the transducing element and acoustic cavity resonance are mode-shape matched, i.e. the displacement profile of the transducing element oscillation is substantially similar to the pressure mode shape of the acoustic resonance excited in the medium.
It may also be advantageous to use a mix of a frequency that activates the impedance matching effect and one or more further frequencies that constitute the desired output (which may also be in conjunction with multiple transducing elements). Due to the impedance matching effect, this would not behave linearly when compared to each of the frequency components in isolation, and so in applications where design simplicity, small size and high output efficiency is important while the high ultrasonic frequencies may be disregarded, such as in small speaker units, this may be used to achieve more commercially viable designs.
From this it can be seen that matching the displacement profile to the mode shape is not an absolute requirement for the blocking plate and surrounding structure to be effective, since the radiated power from a simple piston-mode actuator (e.g. piezoelectric actuator in thickness-mode) can be increased by the presence of the blocking plate with surrounding structure as shown in
B. Blocking Plate Coupled to Bending-Mode Piezoelectric Actuator
In this embodiment, the displacement profile of the actuator is well-matched to the radial mode acoustic pressure distribution in the cavity. In addition, the blocking plate structure is used to define the motion of the actuator as well as the geometry of the cavity. The blocking plate structure heavily constrains motion of the actuator at the perimeter of the cavity where the structure becomes substantially stiffer, owing to the greater thickness of material in this region. The structure similarly does not constrain motion at the center of the actuator where the center of the cavity and thus the high-pressure antinode is located. This allows the displacement of the actuator to follow the desired bending shape when actuated, which is very similar in profile to the acoustic pressure distribution depicted in
1. Tuning the Resonant Frequency
Returning to
Table 3 below shows example dimensions to tune to cavity to 3 different frequencies of operation.
While not necessary, the transducing element radius and cavity radius are typically chosen to be the same. Table 3 shows that the rcavity 750 can be either sub-wavelength or greater than a wavelength, while still increasing the radiated acoustic power over a transducing element with no blocking plate.
Table 3 shows that, for a given blocking plate and supporting structure thickness hblocking 720 and cavity height hcavity 730 (both 0.2 mm), radiated power can be increased by a cavity with radius either substantially smaller than or greater than the target wavelength. Data is taken from a two-dimensional axisymmetric simulation about the centerline of the transducer using a pressure acoustics finite element model (COMSOL).
In addition to rcavity, the width of waperture 760 can be used to tune the resonant frequency of the cavity.
The central region must still be partially blocked by the blocking front plate, such that the width of the aperture, waperture<0.9rcavity. Yet there also exists a lower limit on the width of the outlet, relating to the oscillatory boundary layer thickness,
(where v is the kinematic viscosity of the medium), at the operating frequency, f, such that waperture>2δ. Below this value, a significant proportion of the acoustic energy is lost via viscous dissipation at the outlet.
The resonant frequency of the radial acoustic mode excited is only weakly dependent on the cavity height, hcavity (730), as shown in
Taking an example from
Table 4 shows that, for a given blocking plate thickness and cavity height (both=0.2 mm), radiated acoustic power can be increased by the blocking plate over a large range of frequencies. Aperture width is adjusted to maximize radiated power for each frequency. Data is taken from a two-dimensional axisymmetric simulation about the centerline of the transducer using a pressure acoustics finite element model (COMSOL).
A similarly lower limit on the cavity height exists as with the aperture channel width, namely that the viscous penetration depth places a rough lower limit on the cavity size, namely hcavity>2δ, for identical reasoning to before. An upper bound on the cavity height is also required to ensure the dominant acoustic resonant mode is the designed radial mode. This requires
where λ is the acoustic wavelength at the transducer operating frequency.
These limitations on the cavity height hcavity also have bearing on other embodiments of this invention which may not be planar, may not have the same configuration of dimensions or may not even have a similar intended resonant mode. As before, the viscous penetration depth will limit the thinness of the thinnest dimension of the structure available, dissipating more of the energy as heat as the viscous penetration depth is reached as the minimal limit of the internal dimensions of the structure or cavity. Other thin modes generated will also require that their thinnest dimension has substantially similar limitations in order to achieve the correct mode constrained by the structure, as each mode intended will have specific dimensional requirements. Moving too far from these requirements may cause a jump in the resonant mode excited and thus deleteriously affect the efficiency obtained from the addition of the tuned structure as described previously in this document.
The phase of pressure oscillations varies in the longitudinal and radial directions. In the radial direction, at a given z height, the pressure at the center of the cavity is out of phase with the pressure close to the tube's inner circumference as shown in the graph 1880 of
Similarly,
2. Advantages of the Blocking Plate
The frequency of operation of the blocking plate matching structure is dependent largely on the in-plane dimensions (rcavity, waperture) and is relatively invariant to the thickness dimensions (hcavity, hblocking). (For typical matching layers/structures, it is the thickness that is the critical parameter.) This allows the matching structure with the blocking plate to have a lower thickness and thus in this embodiment a lower profile than other matching layers across a wide frequency range. The matching structure with the blocking plate can be manufactured with conventional manufacturing techniques and to typical tolerances, again in contrast to other more conventional matching layers/structures. It is unintuitive that adding a blocking plate can improve acoustic output, given that a large fraction of the propagation area of the transducing element is blocked by the plate itself
The advantages of the acoustic structure including the blocking plate relative to the alternative matching structures detailed above are described below.
1. Conventional matching layers are typically close to
(where λ denotes the primary wavelength required of the acoustic transducer) thick, whereas the novel acoustic structure including the blocking plate described here can achieve improve transmission efficiency with a thinner structure. In addition, conventional impedance matching layers require complex manufacturing processes to produce the low acoustic impedance materials, whereas the novel acoustic structure described herein can be manufactured using conventional processes e.g. machining, injection molding, etching. Furthermore, low acoustic impedance materials typically lack robustness, whereas the required structure to implement this invention can be fabricated out of more rigid and robust engineering materials such as aluminum.
2. The blocking plate can achieve performance improvements with a thinner structure than a plate with a regular array of sub-wavelength holes as described in Toda, particularly at low ultrasonic frequencies.
3. In the case of the thin film matching layer described in Toda, performance depends strongly on dimensions parallel to the propagation direction. This may be limiting at high frequencies (>>80 kHz), where the spacing of the thin film from the transducing element requires tight tolerances that are not reasonably achievable. However, the blocking plate and supporting structure can be manufactured with typical industry tolerances in at least machining and etching. Moreover, thin polymer films lack robustness, whereas the blocking plate with its supporting structure can be fabricated out of a single piece of a more rigid and robust engineering materials such as aluminum.
4. The acoustic structure described can achieve the same or greater performance improvements with a thinner structure than an acoustic horn, particularly at low ultrasonic frequencies.
5. Helmholtz resonators are limited by the requirement that the dimensions of the resonator must be substantially smaller than the wavelength at the operating frequency. This requires a substantially sub-wavelength transducing element, which limits the power output and constrains what transducing elements can be used with this matching concept. The supporting structure and blocking plate that forms the cavity in this embodiment are not required to be substantially sub-wavelength in diameter so can accommodate larger transducing elements. One of the differences between the foregoing design and a Helmholtz resonator is that this design drives an acoustic resonance that does not have spatially uniform pressure (in the case of this invention it must harbor a chosen acoustic mode that has substantially non-uniform acoustic pressure with radial pressure variation) which then has an opening/pipe at the far end. This has been in previous sections shown to be generalizable to any structure with a non-uniform pressure (pipe, sphere, horn, etc.). This encompasses any enclosed volume with a mode structure and an opening.
One embodiment of the invention is an acoustic matching structure comprising a cavity which, in use, contains a fluid, the cavity having a substantially planar shape. The cavity is defined by two end walls bounding the substantially planar dimension and a side wall bounding the cavity and substantially perpendicular to the end walls, with the cavity having an area Acavity given by the average cross-sectional area in the planar dimension in the cavity between the end walls. The side wall of the cavity may be circular or may have another shape in which case the effective side wall radius rcavity defined as: rcavity=(Acavity/π)1/2. At least one aperture is placed in at least one of the end walls and side walls; wherein the cavity height hcavity is defined as the average separation of the end walls, and rcavity and hcavity, satisfy the inequality: rcavity is greater than hcavity. In operation, a transducing element acting on one of the cavity end walls generates acoustic oscillations in the fluid in the cavity; and, in use, the acoustic oscillations in the fluid in the cavity cause pressure waves to propagate into a surrounding acoustic medium.
A further embodiment of the invention is an acoustic matching layer comprising: a cavity which, in operation, contains a fluid, the cavity having a substantially planar shape with two end walls bounding the substantially planar dimension and an area Acavity given by the average cross-sectional area in the planar dimension of the cavity between the end walls. One of the end walls may be formed by a transducing element and another may be formed by a blocking plate. The cavity has an effective side wall radius rcavity defined as: rcavity=(Acavity/π)1/2 and the cavity height hcavity is defined as the average separation of the end walls. In operation, the cavity supports a resonant frequency of acoustic oscillation in the fluid, wherein the frequency determines a wavelength defined by
where c is the speed of sound in the fluid, wherein hcavity is substantially less than half a wavelength wherein rcavity is substantially equal to or greater than half a wavelength, and at least one aperture is placed in at least one of the end walls and side walls, at least one acoustic transducing element is located on at least one of the end walls and side walls. The resulting acoustic cavity constrains the acoustic medium in the cavity to induce a resonant mode that substantially improves the transfer of acoustic energy from the transducing element to the medium outside the aperture.
A further embodiment of the invention is an acoustic matching layer comprising: a cavity which, in operation, contains a fluid, the cavity having a substantially tubular shape, two end walls bounding the ends of the tubular dimension, wherein a centerline is defined as a line within the cavity which connects the geometric center of one end wall to the geometric center of the other end wall and traverses the cavity in such a way that it maximizes its distance from the nearest boundary excluding the end walls at each point along its length, an area Acavity given by the average cross-sectional area of the cavity between the end walls where the cross-sections are taken with a normal along the centerline, wherein the cavity has an effective side wall radius rcavity defined as: rcavity=(Acavity/π)1/2; wherein the cavity height hcavity is defined as the length of the centerline, wherein, in operation, the cavity supports a resonant frequency of acoustic oscillation in the fluid wherein the frequency determines a wavelength defined by
where c is the speed of sound in the fluid wherein rcavity is substantially less than half a wavelength, wherein hcavity is substantially equal to or greater than half a wavelength. At least one aperture is placed in at least one of the end walls and side walls and at least one acoustic transducing element is located on at least one of the end walls and side walls. The resulting acoustic cavity constrains the acoustic medium in the cavity to induce a resonant mode that substantially improves the transfer of acoustic energy from the transducing element to the medium outside the aperture
A further embodiment of the invention is an acoustic matching layer comprising: a blocking plate present in the path of acoustic energy transfer into the bulk medium; wherein, in operation, the presence of the blocking plate excites an acoustic mode; wherein at least one axis has a dimension that is substantially less than half a wavelength at the resonant frequency in the cavity, and; wherein at least one axis has a dimension that is substantially equal to or greater than half a wavelength at the resonant frequency in the cavity.
In any of the above embodiments, the transducing element may be an actuator which causes oscillatory motion of one or both end walls in a direction substantially perpendicular to the planes of the end walls.
Embodiments below relate to longitudinal and other (not-radial) cavity modes.
One embodiment is acoustic matching structure comprising: a cavity which, in operation, contains a fluid, the cavity having a substantially tubular shape, two end walls bounding the ends of the tubular dimension, wherein a centerline is defined as a line within the cavity which connects the geometric center of one end wall to the geometric center of the other end wall and traverses the cavity in such a way that it maximizes its distance from the nearest boundary excluding the end walls at each point along its length.
The cavity area Acavity given by the average cross-sectional area of the cavity between the end walls where the cross-sections are taken with a normal along the centerline, wherein the cavity has an effective side wall radius rcavity defined as: rcavity=(Acavity/π)1/2; wherein the cavity height hcavity is defined as the length of the centerline, wherein, in operation, the cavity supports a resonant frequency of acoustic oscillation in the fluid; wherein the frequency determines a wavelength defined by
where c is the speed of sound of sound in the fluid, rcavity is substantially less than half a wavelength, hcavity is substantially equal to or greater than half a wavelength. At least one aperture is placed in at least one of the end walls and side walls, and at least one acoustic transducing element is located on at least one of the end walls and side walls. The resulting acoustic cavity constrains the acoustic medium in the cavity to induce a resonant mode that substantially improves the transfer of acoustic energy from the transducing element to the medium outside the aperture.
A further embodiment is an acoustic matching structure comprising: a blocking plate present in the path of acoustic energy transfer into the bulk medium; wherein, in operation, the presence of the blocking plate excites an acoustic mode; wherein at least one axis has a dimension that is substantially less than half a wavelength at the resonant frequency in the cavity, and; wherein at least one axis has a dimension that is substantially equal to or greater than half a wavelength at the resonant frequency in the cavity.
r
cavity=(Acavity/π)1/2; and
While the foregoing descriptions disclose specific values, any other specific values may be used to achieve similar results. Further, the various features of the foregoing embodiments may be selected and combined to produce numerous variations of improved haptic systems.
In the foregoing specification, specific embodiments have been described. However, one of ordinary skill in the art appreciates that various modifications and changes can be made without departing from the scope of the invention as set forth in the claims below. Accordingly, the specification and figures are to be regarded in an illustrative rather than a restrictive sense, and all such modifications are intended to be included within the scope of present teachings.
Moreover, in this document, relational terms such as first and second, top and bottom, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. The terms “comprises,” “comprising,” “has”, “having,” “includes”, “including,” “contains”, “containing” or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises, has, includes, contains a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. An element proceeded by “comprises . . . a”, “has . . . a”, “includes . . . a”, “contains . . . a” does not, without more constraints, preclude the existence of additional identical elements in the process, method, article, or apparatus that comprises, has, includes, contains the element. The terms “a” and “an” are defined as one or more unless explicitly stated otherwise herein. The terms “substantially”, “essentially”, “approximately”, “about” or any other version thereof, are defined as being close to as understood by one of ordinary skill in the art. The term “coupled” as used herein is defined as connected, although not necessarily directly and not necessarily mechanically. A device or structure that is “configured” in a certain way is configured in at least that way but may also be configured in ways that are not listed.
The Abstract of the Disclosure is provided to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims. In addition, in the foregoing Detailed Description, it can be seen that various features are grouped together in various embodiments for the purpose of streamlining the disclosure. This method of disclosure is not to be interpreted as reflecting an intention that the claimed embodiments require more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive subject matter lies in less than all features of a single disclosed embodiment. Thus, the following claims are hereby incorporated into the Detailed Description, with each claim standing on its own as a separately claimed subject matter.
This application claims benefit to the following two provisional applications: 1) U.S. Provisional Application Ser. No. 62/665,867, filed May 2, 2018; and 2) U.S. Provisional Application Ser. No. 62/789,261, filed Jan. 7, 2019.
Number | Date | Country | |
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62789261 | Jan 2019 | US | |
62665867 | May 2018 | US |
Number | Date | Country | |
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Parent | 16401148 | May 2019 | US |
Child | 17164345 | US |