KR101369932B1 - Temperature measuring device of a voice coil in speaker - Google Patents

Abstract

The present invention relates to a temperature measuring device of a speaker voice coil and, more specifically, to a temperature measuring device capable of not only reducing working time but also improving the accuracy of a measured value when measuring the heating temperature of the voice coil. To achieve the forementioned purposes, the present invention includes: a voltage generator which provides a predetermined DC voltage to be applied in the voice coil; a D/A converter which applies the DC voltage which is provided from the voltage generator in the voice coil by converting the DC voltage into a reference voltage of a predetermined magnitude; a signal generator which outputs a signal for driving the voice coil; an amplifier which drives the voice coil by amplifying the signal of the signal generator; a filter which blocks an AC voltage and passes only a DC voltage in a voltage which is generated by driving the voice coil; an A/D converter which converts the DC voltage which passes through the filter into a digital signal; and a micro-processor which controls the D/A converter and converts a DC voltage which is measured by the A/D converter into the heating temperature of the voice coil by comparing the DC voltage with the reference voltage. The present invention is able to not only reduce working time but also improve the accuracy of a measured value when measuring the temperature of a voice coil because the heating temperature of the voice coil can be automatically measured by an easy setting of a user.

Description

Speaker voice coil temperature measuring device {TEMPERATURE MEASURING DEVICE OF A VOICE COIL IN SPEAKER}

The present invention relates to a speaker voice coil temperature measuring apparatus, and more particularly, to a speaker voice coil temperature measuring apparatus capable of quickly and accurately performing temperature measurement on a voice coil mounted as an internal component of a speaker.

A speaker is an acoustic device that emits sound waves by converting an electrical signal into vibration of a diaphragm to generate a small density wave in the air. The principle of vibration of the diaphragm provided in the speaker uses the phenomenon that low frequency is generated when the diaphragm vibrates at low frequency by Lorentz force generated when current flows through the voice coil placed in the magnetic field, and high frequency is generated when vibrating at high frequency. At this time, even with the same frequency, the larger the amplitude, the higher the sound pressure level, the louder the sound.

Here, since the voice coil is wound in a bobbinless type and attached to the diaphragm, heat is generated from the voice coil during high output or when used for a long time, thereby causing a problem in speaker performance.

Therefore, it can be seen that the measurement of the exothermic temperature of the voice coil during the manufacture of the speaker is very important. In order to measure the temperature of the voice coil, a voice coil temperature measuring apparatus for manually adjusting a DC voltage applied to a coil when measuring the temperature rise of the voice coil has been proposed.

1 is a block diagram illustrating a conventional speaker voice coil temperature measuring apparatus.

As shown in Fig. 1, a signal generator 2 for outputting a driving signal of the speaker 1 voice coil, an amplifier 3 for amplifying the signal of the signal generator 2, and a DC voltage to the voice coil are shown. A power supply 4 for applying a power supply, a variable resistor 5 for adjusting a DC voltage of the power supply 4, a current limiting resistor 6 for limiting a current amount of a DC voltage applied to the voice coil, A ripple cancellation filter 7 for removing ripple of the DC voltage applied to the voice coil, a noise removing filter 8 for removing an AC signal from the signal applied to the voice coil and passing only a DC signal, and the voice coil It consists of a voltmeter 9 for measuring the DC voltage applied to.

The conventional speaker voice coil temperature measuring device configured as described above adjusts the variable resistor 5 until the DC voltage applied to the voice coil of the speaker 1 reaches a set value, and after checking the current ambient temperature, The voice coil is driven by amplifying the signal of the signal generator 2. Accordingly, the impedance of the voice coil made of copper wire is increased by the heat generation of the voice coil. In this case, the noise removing filter 8 removes the AC component of the signal generator 2 and the DC voltage applied from the power supply 4. Passed the bay. Finally, the voltage value measured by the voltmeter 9 is read, and the value is increased from the initial set value, and the temperature change rate can be calculated using the temperature coefficient of the copper wire.

However, in the conventional speaker voice coil temperature measuring apparatus as described above, when the DC voltage applied for the temperature measurement is adjusted, the operator must read the voltmeter while adjusting the variable resistance, so that the working time may be delayed and the measured value may be inaccurate. There is a problem that the productivity is lowered.

KR 10-2006-0014662 A

SUMMARY OF THE INVENTION An object of the present invention is to provide a speaker voice coil temperature measuring apparatus capable of shortening the working time and improving the accuracy of a measured value when measuring the heating temperature of a voice coil. .

The above object is, according to an embodiment of the present invention, in the speaker voice coil temperature measuring apparatus for measuring the heating temperature generated by applying a DC voltage to the voice coil of the speaker, a predetermined direct current to be applied to the voice coil A voltage generator for providing a voltage; A D / A converter converting the DC voltage provided from the voltage generator into a reference voltage having a predetermined magnitude and applying the same to the voice coil; A signal generator for outputting a signal for driving the voice coil; An amplifier for driving the voice coil by amplifying the signal of the signal generator; A filter which blocks an AC voltage and passes only a DC voltage at a voltage generated as the voice coil is driven; An A / D converter for converting the DC voltage passed through the filter into a digital signal; And a microprocessor that controls the D / A converter and converts the DC voltage measured from the A / D converter into the heat generation temperature of the voice coil by comparing the DC voltage with the reference voltage. Achieved by a measuring device.

The apparatus may further include a temperature measuring device for measuring the indoor temperature and converting the same into a digital signal, wherein the measured indoor temperature is converted into a digital signal and transmitted to the microprocessor.

The heat generation temperature of the voice coil calculated by the microprocessor is expressed by the following equation.

It is characterized by obtaining by.

Where I is the current, V _S is the reference voltage applied from the D / A converter, V _L is the voltage across the voice coil, R _c is the current limiting resistor, and Rt is the room temperature (room temperature). V _LS is the voltage across the voice coil at room temperature, V _LE is the voltage across the voice coil during driving, RT is the resistance of the voice coil during driving, and T _i is the temperature measuring instrument. Is the room temperature measured at, Q _coil is the temperature coefficient of the voice coil, and T _T is the measured exothermic temperature.)

According to the present invention configured and acting as described above, the heating temperature of the voice coil can be automatically measured by the user's easy setting, thereby reducing the working time as well as improving the accuracy of the measured value. It can be effective.

1 is a block diagram showing a conventional speaker voice coil temperature measuring apparatus;
2 is a block diagram illustrating a speaker voice coil temperature measuring apparatus according to an exemplary embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Speaker voice temperature measuring apparatus according to an embodiment of the present invention, as shown in Figure 2, the voltage generator 20 for providing a predetermined DC voltage to be applied to the voice coil of the speaker 1, and the voltage generator A D / A converter 30 for converting the DC voltage provided from 20 into a reference voltage having a predetermined magnitude and applying it to the voice coil, a signal generator 40 for outputting a signal for driving the voice coil; An amplifier 50 that amplifies the signal of the signal generator 40 to drive the voice coil, a filter 60 which cuts off an AC voltage and passes only a DC voltage at a voltage generated as the voice coil is driven; An A / D converter 70 for converting the DC voltage passed through the filter 60 into a digital signal, and the D / A converter 30 to control the DC voltage measured from the A / D converter 70. Compared with the reference voltage And a microprocessor 80, which in terms of the heating temperature of the coil device.

According to the present invention configured as described above, in order to measure the temperature of the voice coil, since the DC voltage applied to the voice coil must be known first, the voltage generator 20 should be provided with a stable DC voltage. The DC voltage provided from the generator 20 is adjusted to a reference voltage of a predetermined size by the control of the microprocessor 80 and then applied to the voice coil. In this case, the indoor temperature is measured and input to the microprocessor 80. For this purpose, it is preferable to further include a temperature measuring instrument (not shown) for measuring the indoor temperature and converting it into a digital signal. The processor 80 is electrically connected to transmit a digital signal.

Next, the voice coil must be driven through the signal generator 40 and the amplifier 50, where the signal generator 40 generates an AC signal such as a sine wave or music.

Next, heat is generated as the voice coil is driven. At this time, since the impedance of the coil is increased by the heat generation, the reference voltage applied to the first is also increased. Here, since both terminals of the voice coil are mixed with alternating current and direct current, the alternating voltage is removed through the filter 60 and only the direct current voltage is passed.

Next, the DC voltage passing through the filter 60 is converted into a digital signal through the A / D converter 70 and transmitted to the microprocessor 80.

Next, the microprocessor 80 compares the DC voltage signal input from the A / D converter 70 to the heat generation temperature of the voice coil by comparing with the reference voltage signal initially set through the D / A converter 30. In this regard, the heat generation temperature T _T of the voice coil calculated by the microprocessor 80 may be obtained by Equation 1 below.

Where I is the current, V _S is the reference voltage applied from the D / A converter, V _L is the voltage across the voice coil, R _c is the current limiting resistor, and Rt is the room temperature (room temperature). Is the resistance of the voice coil, V _LS is the voltage across the voice coil at room temperature, V _LE is the voltage across the voice coil during driving, RT is the resistance of the voice coil during driving, and T _i is the temperature measuring instrument. Measured room temperature, Q _coil is the temperature coefficient of the voice coil.

For example, if V _S is 1 V, T _i is 20 ° C., V _LS is 0.02 V, Q _coil is 0.00385 per 1 ° C., and V _LE is 0.04 V, then 290.57 ° C. is obtained by the above equation (1). Become.

On the other hand, the microprocessor 80 may be electrically connected to the computer terminal 90 so as to be in data communication, and this configuration facilitates automatic setting and data input / output.

In addition, the voice coil electrically connected to the D / A converter 30 and the filter 60 is connected to the heat generation measuring unit 10 in the form of a terminal box, as shown in FIG. Make it work. The heat generation unit 10 may be formed in various forms, and in particular, a multi-socket form for testing a plurality of voice coils is preferable.

According to the present invention described so far, it is possible to automatically measure the heat generated temperature of the voice coil by the user's easy setting, thereby reducing the working time and improving the accuracy of the measured value when measuring the temperature of the voice coil. . In addition, since the product having a large number of speakers, such as 5.1 channel, 9.1 channel can be measured at a time, work efficiency is improved.

The foregoing has outlined rather broadly the features and technical advantages of the present invention in order that the claims of the invention to be described below may be better understood. The embodiments described above are susceptible to various modifications and changes within the technical scope of the present invention by those skilled in the art. These various modifications and changes are also within the scope of the technical idea of the present invention, and will be included in the claims of the present invention described below.

1: speaker 2: signal generator
3: amplifier 4: power supply
5: Variable resistor 6: Current limiting resistor
7: Ripple Rejection Filter 8: Noise Rejection Filter
9: voltmeter
10: heating measurement unit 20: voltage generator
30: D / A Converter 40: Signal Generator
50: amplifier 60: filter
70: A / D converter 80: microprocessor
90: computer terminal

Claims (3)

In the speaker voice coil temperature measuring apparatus for measuring the heating temperature generated by applying a DC voltage to the voice coil of the speaker,
A voltage generator for providing a predetermined DC voltage to be applied to the voice coil;
A D / A converter converting a DC voltage provided from the voltage generator into a reference voltage having a predetermined magnitude and applying the same to the voice coil;
A signal generator for outputting a signal for driving the voice coil;
An amplifier for driving the voice coil by amplifying the signal of the signal generator;
A filter which blocks an AC voltage and passes only a DC voltage at a voltage generated as the voice coil is driven;
An A / D converter for converting the DC voltage passed through the filter into a digital signal; And
And a microprocessor for controlling the D / A converter and converting the DC voltage measured from the A / D converter to the heat generation temperature of the voice coil by comparing the DC voltage with the reference voltage. Device. The method of claim 1,
It further includes a temperature measuring device for measuring the room temperature and converting it into a digital signal,
The speaker voice coil temperature measuring apparatus of claim 1, wherein the room temperature measured by the temperature measuring instrument is converted into a digital signal and transmitted to the microprocessor. 3. The method of claim 2,
The exothermic temperature (T _T ) of the voice coil calculated by the microprocessor is

The temperature measuring device of the speaker voice coil, characterized in that obtained by.
Where I is the current, V _S is the reference voltage applied from the D / A converter, V _L is the voltage across the voice coil, R _c is the current limiting resistor, and Rt is the room temperature (room temperature). V _LS is the voltage across the voice coil at room temperature, V _LE is the voltage across the voice coil during driving, RT is the resistance of the voice coil during driving, and T _i is the temperature measuring instrument. Is the room temperature measured at, Q _coil is the temperature coefficient of the voice coil, and T _T is the measured exothermic temperature.)

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