NL1006505C2 - Testing system for bespoke hearing aid insert - Google Patents

Abstract

Uses air pressure test to ensure that there are no leakage paths which could give rise to acoustic feedback problems. Also produces figure for likely audio attenuation of any damping rings inside the insert.

Description

VO.OG 1157

Title: Method and device for testing an otoplasty

The invention relates to an apparatus for testing the function, in particular the damping and / or leak-tightness, of otoplastics. An otoplastic is a custom-made plastic earmold that is worn in the auditory canal 5 and is usually provided with a channel extending through it with a predetermined diameter. An otoplasty can be part of a hearing aid or serve as a personal hearing protector for noise nuisance.

In case the otoplastic is part of a hearing aid, the “leak tightness”, in other words the leak-free sealing of the auditory canal by the otoplastic in situ, determines the proper functioning of the hearing aid. Thanks to a leak-tight closure of the auditory canal, the otoplastic prevents the phenomenon of feedback (whistling of the hearing aid).

In case an otoplastic is used as a personal hearing protector, a damping element, usually based on the low-pass principle, is usually mounted in 20 or on the channel passing through the otoplastic. If necessary, the leak-tightness of the otoplasty in situ (during wearing), and on the other hand the damping value of the otoplasty, or the damping element, determine the correct functioning of the otoplastic as a hearing protector. It is clear to a person skilled in the art that the measured attenuation value of an otoplastic is only achieved when the otoplastic actually seals the auditory canal in situ in a leak-tight manner.

There is therefore a need for a measuring device that is capable of objectively correct operation, or

30 check "leak tightness" of the otoplasty in situ. More particularly, the invention also aims to provide a measuring device which is able to determine or check the damping value of the otoplasty, or the damping element, in an objective and rapid manner. It is an object of this invention to provide a 1006505 1 2 measuring device with such a characteristic.

The invention is based on the insight that there is a relationship between the air flow resistance and the damping value of an otoplastic, or the damping element. If the airflow resistance of the otoplastic in situ is maximum, it can be deduced that the otoplastic also seals the auditory canal in a leak-tight manner, so that the measured attenuation value is also the actual attenuation value of the otoplastic 10 during wearing.

The advantage of determining the attenuation via the measurement of the air flow resistance is that time-consuming tests such as double audiometry or insertion-gain measurement, and especially the subjective aspects thereof, such as: the interpretation of the 15 audiometres, are hearing status, reaction speed, etc. be avoided.

The second advantage is that a distinction can be made between the quality of the fit of an otoplastic -the leak-tightness- on the one hand, and the damping value of the otoplastic on the other hand. In this way, the correct corrective measures can be taken: either adjusting the shape of the otoplasty or adjusting the damping value.

Another advantage is that the device generates a continuous measuring signal that always, essentially without time delay, and therefore also under changing test conditions such as eg chewing speech and head movements of the test person, the good function (leak tightness) of registers the otoplasty in situ.

These and other aspects, features and advantages of the present invention are illustrated in the following description, with reference to the drawings.

Figure 1 is a schematic representation of the leak-tightness measurement of an otoplastic in situ.

Figure 2 is a schematic representation of the determination of the damping value of an otoplasty with a damping element, based on the low-pass principle.

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Figure 3 is a schematic representation of the operation of the device.

Figure 1 schematically shows the auditory canal 11 and a tympanic membrane 12. In the auditory canal 11 an otoplastic 5 is placed, with a channel 13 connecting the free space 14 to the space 15 between tympanic membrane 12 and otoplastic 5.

The measuring device 17 is connected to the otoplastic 5 by means of a connecting hose 4 and pressure 10 can be built up in the space 15. If the air flow resistance becomes maximum (e.g. 10 Pa) and remains constant for a certain period (e.g. 2 seconds), the otoplastic 5 is leak-tight. Since the nature of the otoplasty is not the subject of the present invention and knowledge of it is not necessary for an understanding of an expert, it will not be further described.

Figure 2 schematically illustrates the test set-up to test the damping value of an otoplasty or the damping element. The measuring device 17 is connected by means of a connecting hose 4 to an otoplastic 5 with a channel 13, in which (or 20 on which) a damping element 16 is arranged. The free space is 14. The air flow resistance of the otoplasty, or the damping element 16, can thus be determined. The device 8 then determines the damping by means of conversion tables.

Figure 3 illustrates the operation of the device of the present invention. The measuring device 8 contains a source 1 for supplying a gas with a constant, preferably adjustable, pressure. The gas can be air. The source 30 contains a storage vessel in which the gas is at a fairly high storage pressure, which storage vessel is provided with a pressure reducing valve. The source may also include an air pump and a buffer vessel with an inlet and an outlet, the air pump supplying gas to the inlet of the buffer vessel and the outlet of the buffer vessel acting as the outlet of the source. Other means of creating the source will be apparent to those skilled in the art. Preferably, the source 100650514 is provided with means to ensure a constant outlet pressure such as, for example, a pressure reducing valve or a PID controller. For the sake of simplicity, such means have not been illustrated.

The measuring device further comprises a reference flow resistance 2 with a predetermined flow resistance Rref. In one embodiment, the reference flow resistance 2 is defined by a small passage opening, in an otherwise gas-impermeable body, which passage opening may be made with the aid of a laser. The reference 10 resistor 2 is connected to the source 1 via a first connecting hose 3. The flow resistance R3 of 3 is negligible compared to the flow resistance Rref of the reference resistance 2.

The reference flow resistance 2 is connected to the otoplastic via a second connecting hose 4. The flow resistance of the second connecting hose is indicated by R4. The exit side of the otoplasty is connected to either the space between the eardrum and the otoplasty (fig. 1, no. 15), or to the free space (fig. 2, 20, no. 14). The device further comprises a first pressure sensor 6 for measuring the pressure P6 at the output of source 1 or. the input of the reference flow resistance 2, and a second pressure sensor 7 for measuring the pressure P7 at the output side of the reference flow resistance 2. The sensors 6 and 25 7 generate pressure-related measuring signals which are applied to a signal processing device 8, eg a programmed computer. It is clear to a person skilled in the art that the two pressure sensors preferably provide the same signals at the same pressure values. In a calibration procedure 30, the two pressure sensors can be calibrated relative to each other, because with the source 1 switched off and / or with the connecting hose 4 closed, the pressure at the two sensors must at that moment give equal signals. It is further noted that the atmospheric pressure value does not influence the measurement results, since the pressure values are measured with respect to atmospheric pressure.

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Similar to Ohm's law for electrical signals, the following relationship holds for the signals received by computer 8 P7 5 Rs = Rref. - R4 (formula 1) M 6, where R5 indicates the flow resistance of the otoplasty. The value of R4 can be determined by a single measurement in the absence of the otoplasty. In this case, R5 in the formula 1 is equal to zero.

The computer 8 is programmed to continuously process the measurement data P6 and P7 based on the formula 1, using the known quantities Rref and R4, to calculate the flow resistance R5 of the otoplastic, and 15 to calculate a damping value from the flow resistance R5 D calculated on the basis of a computer-associated memory 9 in which data relating to the relationship between the flow resistance R5 and the damping is stored, as explained below.

The computer 8 is further programmed to show the data thus obtained on a display 10. The said relationship between the flow resistance R5 and the damping can be explained as follows.

Audiograms were made in test subjects. Thereby, sound was supplied to those persons with a known loudness and a known frequency. The frequency used was 1000 Hz. The invention is also applicable to other frequencies. By varying the volume, it was investigated which volume the test subject could just perceive - threshold value 1.

Then, in those subjects, an otoplasty with a damping element was placed in the ear canal and the said measurement was repeated - threshold value 2. The difference between threshold value 1 and threshold value 2 is the attenuation D. These measurements were then repeated with the same otoplastics 1006505 '6 with damping elements with greater or less damping capacity.

Subsequently, the flow resistance of these otoplastics with different damping elements was determined, using the measuring method as described beforehand to determine a relationship between the flow resistance and the damping values obtained. The aforementioned relationship can be expressed as follows.

D = A + B10 log! 1 + yr-S ~~ ~ (Formula 2) l Rs + R * + Rhone 10 where:

D is the attenuation expressed in dB

Rbone is a constant representative of the sound conduction through bone 15 A and B are constants.

The constants A, B and Rbone can be determined by using calibrated damping elements and / or calibrated hoses, the damping of which is known at the said frequency. To determine the values of those constants, the number of calibration measurements with different calibrated damping elements or calibration hoses must be at least three; preferably several calibration measurements are performed.

The constants A and B are device constants and can be assumed known after a calibration procedure to measure the attenuation of multiple otoplastics. In contrast, the constant Rbone is a constant associated with the user of the otoplasty. A fixed value can be assumed for this constant, ie an average determined by measuring Rbone in a group of test subjects. For greater accuracy, the user's Rbone can be individually determined. In principle, such a procedure only has to be carried out once for that user.

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A memory 9 is associated with the computer 8, in which data is stored relating to said relationship (formula 2) between damping and the flow resistance. Such data may, for example, be stored in the form of a table, 5 as is clear to a person skilled in the art. The value Rbone can be manually entered into the computer 8, but according to a further aspect of the present invention, the memory 9 contains the relevant information related to a group of persons. For example, a health service can store the relevant information of the 10 employees in the memory 9. If a certain employee then arises, the computer 8 is provided with the information identifying the employee in question, on which the computer 8 the relevant value of Rbone retrieves from memory.

Likewise, it is also possible to determine the "leak-proof" occlusion of the ear canal by an otoplastic in situ. When an overpressure is reached that is equal to the maximum capacity of the pump (eg 10 Pa) and that overpressure remains constant during a certain period (eg 2 sec), 20 it can be concluded from this that the otoplastic in situ seals the auditory canal shutdown.

It is clear to the skilled person that the scope of the present invention as defined by the claims is not limited to the embodiments shown and discussed in the drawings, but that the embodiments of the invention shown are possible within the scope of the inventive idea. to change or modify. It is also possible to install the signal processing device 8 of the measuring device in such a way that the measuring data is sent to a data processing device (not shown), in order to further process the measuring results electronically.

1006505 8

It is also possible, for example, that the calculation of a value for the flow resistance R3 is skipped and that the damping D is directly derived from the measured pressure values P6 and P7 according to the formula 3 5 ΡΊ

D. - L_____. D

Λref p _ p Λbone D = A + B '0 log1 + γ v- ”(Formula 3) Ρη ^ ref η η ^ b ° ne V Ρη -PJ \ 1006505

Claims (6)

Method for determining the sound damping, or the leak-tightness, of an otoplasty, comprising a body to be introduced into the ear canal with a channel extending through it, whether or not provided with a damping element; the airflow resistance of said channel being measured. 2. Method according to claim 1, characterized in that the value for the sound damping, or the leak-tightness, is derived from the measured resistance value using a pre-prepared empirical conversion table or conversion formula. 3. A method according to claim 1 or 2, wherein gas, preferably air, is supplied to the otoplastic at a predetermined pressure via a reference flow resistance, the pressure being measured before and after the reference flow resistance, and wherein the flow resistance of said channel is determined from the 20 measured pressure values. Measuring device for carrying out the method according to any one of the preceding claims, comprising (fig. 3): a source (1) of gas with a predetermined pressure; 25 a reference flow resistance (2); means (3) for connecting the source to an input of the reference flow resistance; means (4) for connecting an output of the reference flow resistance to an otoplasty; 30 a first pressure sensor (6) for measuring the pressure at the input of the reference flow resistance (2); a second pressure sensor (7) for measuring the pressure at the output of the reference flow resistance (2); a signal processing device (8) that receives measurement signals from 1006505 said pressure sensors (6 and 7); a memory (9) associated with the signal processing device (8), which stores data relating to the relationship between flow resistance (R5) and damping (D); a display (10) associated with the signal processing device (8). Measuring device according to claim 4, wherein the signal processing device (8) is adapted to calculate the flow resistance (R5) of the connected otoplastic from the measured pressure values, and to calculate this from and based on the information in the memory (9 ), calculate the value of the sound attenuation (D), and to display the value of the attenuation thus calculated via the display. Measuring device according to claim 4 or 5, wherein the signal processing device (8) is arranged to send the results of the measurement to a computer or other data processing device. 1n "« 505