HU176273B - Continuous volume and tone control for hearing aids - Google Patents

Abstract

The circuit comprises a capacitor (C), the first pole (X) of which is connected via a charging resistor (R1) and a pair of charging electrodes (A) to the negative terminal (-UT) of a voltage source at the control input of the four-terminal network, and via a discharging resistor (R2) and a pair of discharging electrodes (B) to the second pole (+) of the capacitor (C). This second pole is connected to the positive terminal (+) of the voltage source at the control input of the four-terminal network. The pairs of electrodes (A, B) are constructed as separate metal electrodes on the surface. The capacitor (C) and the two resistors (R1, R2) are dimensioned in such a manner that the charging and discharging constant is greater than 0.1 s. The volume increases or decreases by touching one or the other metal electrodes (A, B) with one finger. As a result, the usual potentiometer controls can be omitted in hearing aids. <IMAGE>

Description

Circuit arrangement for continuously adjusting the volume and / or tone of hearing aids

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BACKGROUND OF THE INVENTION The present invention relates to a circuit arrangement for continuously adjusting the volume and / or tone of a hearing aid device having a four-pole switch with variable electrical transmission properties between its input terminal and its output terminal.

Almost everywhere electrical equipment is used to control the volume and / or tone, potentiometers are arranged as a voltage divider in four poles, and the electrical transmission property (e.g. damping or frequency travel) of the four poles is determined by the position of the potentiometer pickup. In hearing aids, the use of detachable potentiometers presents both manufacturing and user difficulties.

In hearing aids, the high amplification of the devices (about 90 dB) also amplifies the contact noise of the remover, which can become intolerable even after a short period of use. Contact noise 20 can be controlled by providing a more precise and noise-free design of the potentiometers, but this is very difficult to achieve with the small amount required. With a small size, producing reliable potentiometers that run smoothly over a long period of time is very costly and not technically complete.

It is also difficult to adjust the volume during use. It should be borne in mind that the vast majority of patients using such devices are elderly, and find it difficult to turn the potentiometer wheel properly.

The operability and reliability of hearing aids was largely determined by the quality of the potentiometer used, and the training of the potentiometer also influenced the size and price of the appliances.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a circuit arrangement that eliminates conventional potentiometer control for hearing aids which virtually eliminates control noise and does not require any particular skill.

It has been discovered that potentiometer control can be replaced by electronic control in which the electrical transmission properties of the four-pole control are determined by the instantaneous voltage of a charge storage capacitor and can be directly touched by a patient touching a charge or discharge electrode. regulate.

Accordingly, the circuitry of the present invention is characterized in that a first armature of a charge storage capacitor is connected to one of its voltage braids via a charging resistor and a pair of charge electrodes, and to a second armature via its discharge arm and discharge electrode pair. The first armament of the charge storage capacitor is connected to the control input of the four-pole controller, the electrode pairs are metal electrodes isolated from each other and terminated on separate parts of the surface of the hearing aid, the charge storage capacitor and the charging Greater than 0.1 second.

The solution outlined above eliminates the aforementioned disadvantages of potentiometer control, the volume increases continuously while the charge electrode pair is touched and decreases continuously when the discharge electrode pair is touched.

In a preferred embodiment of the invention, the four-pole control transistor is a field-controlled transistor having a gate electrode coupled to a first electrode of a charge storage capacitor, its source and sink electrodes forming a member of a voltage divider, and it is connected to the output connector and the sink electrode is connected via a load resistor to the earthed end of the voltage divider.

By using a field-controlled transistor, the controller can be designed as a passive circuit with a voltage-controlled resistance value of four poles, the control characteristic of which corresponds favorably to the sense logarithmic sound pressure level of the ear.

In another preferred embodiment of the invention, the pairs of electrodes are formed by gold plated tubular rivets terminated on the side panel of the hearing aid device and metal cores with a gold plated surface isolated on islands, for example, by Teflon rings.

The invention will now be described in more detail with reference to the drawing, in which: FIG

Fig. 1 is a schematic diagram of an exemplary embodiment of a circuit arrangement according to the invention and a

Figure 2 is a sectional view showing the structure of the electrode pair.

The circuit arrangement of the present invention is incorporated into the housing of a hearing aid device not shown in the drawing. The amplifier chain of the hearing aid device is connected in series with 1 input terminal and 2 output terminals of the arrangement. The circuit arrangement comprises two circuits, the first of which comprises the charging and discharging circuit of the charge storage capacitor C. One arm of the C charge storage capacitor is grounded and the other arm x is connected via a charging resistor R1 and a pair of charge electrodes to one of the Uf corners of the device voltage source. Between the armor x and the earth is a discharge circuit consisting of a discharge resistor R2 and a pair of discharge electrodes B connected in series. The drawing also illustrates an exemplary embodiment of a pair of charge electrodes A. This pair of electrodes consists of a gold-plated tube rivet 8 fixed in a bore on the side of the body of the hearing aid device by riveting, an insulating insert 3 inserted therein, preferably a tetrafluoroethylene tube, and a metal core 4 inserted. The outer surface of the tube rivet 8 and the metal core 4 are approximately the same, and when touched with a finger, a skin resistance of about 5 to 100 ohm connects the gold-plated electrodes, i.e. the tube rivet 8 and the metal core 4. The tube rivet 8 of the charge electrode pair A is connected via line 5 to the U _T corner of the voltage source and the metal core 4 through line 6 to the upper end of the charging resistor R1. The discharge electrode pair 8 has a similar structure, but its structure is not shown separately in the drawing.

The second circuit is comprised of a four-pole regulator connected between the input terminal 1 and the output terminal 2, which in the exemplary embodiment consists of a field-effect transistor Tr, input and output coupling capacitors C1 and C2, voltage divider R 'and load resistor R3. The sink-source path of the Tr field-controlled transistor forms a voltage divider with a voltage divider resistor R, where the division ratio is determined by the instantaneous resistance value of the sink source path. The load resistance R3 serves to close the DC circuit of the absorbing electrode D and the source electrode S. The gate electrode G of the Tr field-controlled transistor is connected to the arm x of the charge storage capacitor C.

The operation of the circuit arrangement according to the invention is very simple. Between one and two input and output terminals of the attenuation value is related to the charge storage capacitor C, the instantaneous voltage of the field effect transistor Tr, the drain path of the spinning pil lanatnyi resistance value of _5. The AC charge storage capacitor is a high-quality, low-loss capacitor of about 150 nF that holds its charge for a long time. The resistor RI θ has a high ohmic resistance, preferably between 10 and 20 µm, and in addition, the transient resistance of the finger touching the charge electrode pair A is substantially neutral at the resistance value. The charging electrodes is touched, a charge storage capacitor ₅ kon C commenced upon charging current from the power source begins to charge exponentially, proportionally the voltage divider attenuation decreases. The attenuation decrease is perceived as an increase in volume. When the desired volume is reached, the charge electrode pair A is released. The charge storage capacitor C then retains its charge and the set volume remains unchanged for a long time.

When touching the discharge electrode pair B through the discharge resistor R2 (which is also about 10 to 20 Mohm at ₅ ), the charge storage capacitor C is discharged slowly, thereby increasing the damping of the voltage divider and decreasing the volume continuously.

From the above it can be seen that the invention solved the volume and equalization task without the use of a θ potentiometer and any other moving parts, and the handling of the control was greatly simplified. This solution is particularly advantageous in the use of hearing aids built into spectacle frames, since the absence of a relatively large potentiometer makes installation easier.

From the foregoing, it will be apparent to those skilled in the art that, for example, the four-pole regulator may be of active design, or the pairs of electrodes may be formed from gold-plated studs or other metal objects placed side by side. Therefore, the invention should not be limited to the exemplary embodiment.

Claims (3)

A circuit arrangement for continuously adjusting the volume and / or tone of hearing aids having a four-pole variable electrical transmission characteristic between an input terminal and an output terminal, characterized by a charge storage capacitor (C) having a first armature on a charging resistor (R1). connected via a charging electrode pair (A) to one corner of a voltage braid, and via a discharge resistor (R2) and a discharge electrode pair (B) to its second armature, this second armature being connected to the other corner of the voltage source; connected to the inputs of the four-pole controller, the charging and discharging electrode pairs (A, and B) consist of metal electrodes isolated from one another and terminated on separate portions of the surface of the hearing aid, stároló capacitor (C) and 5 to the charging and discharging resistors (Ri, R2) are dimensioned such that they have determined the larger charge and discharge time constant of 0.1 seconds. The circuit arrangement of claim 1 Embodiment 10, characterized in that the gate electrode (G) of the four-pole field-effect transistor (Tr) is connected to the first armor (x) of the charge storage capacitor (C), and its source and sink electrodes (S and D) form 15 voltage divider inputs via input coupling capacitor (C1) to input connector (1) and output via output coupling capacitor (C2) to output connector (2) and load resistor electrode (D) 20 (R3) is connected to the earthed end of the voltage divider. An embodiment of a circuit arrangement according to claim 1, characterized in that the charging and discharging electrode pairs (A and B) are They are made of gold plated tube rivets (8) guided to the side panel (7) of the device and metal cores (4) with a gold surface on the islands.