DE2448506A1 - Overload protection circuit for loudspeakers - has temperature sensor monitoring vibrating coil and controlling output power of amplifier system - Google Patents

Abstract

The overload protection circuit, for loudspeakers, has a temperature sensor which is used to reduce the output power of the amplifier according to the temperature of the vibrating coil. The temperature sensor may be a temperature sensitive resistor which is kept in good thermal contact with the vibrating coil, or it may be the coil itself -- i.e. changes in the resistance of the coil due to changes of temperature may be monitored. Another method uses an electronic model of the behavious of the loudspeaker and obtains the criterion for controlling the input power from this.

Description

Circuit arrangement for protecting dynamic loudspeakers from overload.

To protect dynamic loudspeakers from overload, it is common to to dimension the amplifier used for control so that the maximum The output power is less than the power that the loudspeaker can produce in continuous operation can handle without harm.

Or the amplifier is dimensioned, e.g. through a suitable choice the time constants in the power supply so that it briefly has a high peak power releases, which then decreases with longer duration.

The effectiveness of all of these procedures depends on the course of the low frequency signal given to the speaker. It is true that such Dimension circuits so that they are suitable for certain types of program (e.g.

either symphonic music or pop music) work adequately. However, they meet with a changing program because of the greatly different amplitude distributions their purpose only inadequate.

The method described below avoids this disadvantage and ensures optimum use of the loudspeaker capacity for all types of program.

According to the invention, the criterion for reducing the amplifier power a variable is used that provides a reliable statement as to whether the loudspeaker is used overloaded or not, namely the temperature of the voice coil.

Fig.1 shows an embodiment. On the voice coil S is a further coil S 'made of resistance wire with a high positive temperature coefficient upset. The current I caused by the voltage U leaves the relay Re at attract low temperatures. As soon as the voice coil temperature increases, increase the resistance of S 'decreases, the current I decreases, and finally the relay drops and disconnects the speaker from the amplifier.

Another possible design is shown in Fig.2. The output of the amplifier A low DC voltage, preferably several hundred millivolts, is superimposed on V; at R there is a voltage drop, the one caused by the direct voltage Component is filtered out by a low pass. Because of the temperature dependence of the ohmic voice coil resistance, this voltage is a measure of the voice coil temperature. If the temperature is too high, you can use a voltage-dependent amplifier V 'die Reduce the input voltage of the loudspeaker-driving amplifier V.

For speakers with negative motion, where as little as possible the interaction between amplifier and loudspeaker is to be interfered with, a version according to Fig. 3 is particularly suitable.

The thermal behavior of the loudspeaker is simulated electrically: A current I that is proportional to the instantaneous magnitude of the amplifier power N. and corresponds to the heat influx Ith, one becomes the heat capacity of the voice coil corresponding Kx capacity C impressed. The resistance R simulates the thermal resistance between the voice coil and the environment. A voltage U is now established at C, which is an exact measure for the excess temperature g of the voice coil. This tension can then be used, for example, for an optical overload indicator.

The power-proportional current I can be obtained approximately by squaring the amplifier output voltage and then converting it into one Current.

Claims (4)

Patent claims: G Circuit arrangement to protect dynamic loudspeakers from overload, characterized in that the output power of the used for control Amplifier is decreased depending on the temperature of the voice coil. 2. Circuit arrangement according to Claim 1, characterized in that a temperature-dependent resistor to determine the voice coil temperature element is brought into close thermal contact with the voice coil. 3. Circuit arrangement according to Claim 1, characterized in that To determine the voice coil temperature, the voice coil resistance is dependent on it is measured. 4. Circuit arrangement gam. Claim 1, characterized in that an electrical analog model from the quantities amplifier power, heat capacity the voice coil and the thermal resistance of the voice coil to the environment derives a quantity EESshs which corresponds to the voice coil temperature.