KR20130141966A - Sound transducer with sound pressure controlling function corresponding - Google Patents

Abstract

The present invention relates to an acoustic transducer and, especially, to an acoustic transducer with a sound pressure adjustment function, which is capable of amplifying the sound pressure of an electrical signal while maintaining the amplitude of the electrical signal (acoustic signal) applied from an external source and the temperature of the acoustic transducer in a range of a desired reference value. The acoustic transducer with a sound pressure adjustment function according to the present invention comprises: a frame; a magnetic circuit which is installed in the frame; a voice coil which receives an electrical signal to be vibrated by a mutual electromagnetic force with the magnetic circuit; and a diaphragm which is vibrated by the vibration of the voice coil to generate sound. The acoustic transducer includes a sound pressure correction device which processes an electrical signal applied from an external source on the basis of gain data and applies the processed electrical signal to the voice coil, wherein the sound pressure correction device amplifies or attenuates an applied electrical signal depending on the gain data such that the amplitude of the diaphragm is within the maximum allowable amplitude and the temperature of the voice coil is within the maximum allowable temperature. [Reference numerals] (1100) Gain determination device;(700) Sound pressure correction circuit unit;(AA) Amplitude properties;(BB) Temperature properties

Description

SOUND TRANSDUCER WITH SOUND PRESSURE CONTROLLING FUNCTION CORRESPONDING}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an acoustic transducer, and more particularly, to an acoustic transducer having a sound pressure control function for amplifying sound pressure while maintaining the amplitude of an electrical signal (sound signal) applied from the outside and the temperature of the acoustic transducer within a desired reference value.

1 is a cross-sectional view of an acoustic transducer according to the prior art.

As shown in this figure, a general acoustic conversion apparatus (speaker) includes a frame 1, a yoke 2 inserted and mounted inside the frame 1, a yoke 2 for transmitting a magnetic flux to the yoke 2, An inner ring magnet 3 and an outer ring magnet 4 receiving the magnetic flux from the inner ring magnet 3 or the outer ring magnet 4 and receiving the magnetic flux from the inner ring magnet 3 or the outer ring magnet 4 to transmit magnetic flux perpendicularly to the voice coil 7, A voice coil 7 in which a part is inserted into the gap between the inner ring magnet 3 and the inner ring top plate 5 and the outer ring magnet 4 and the outer ring top plate 6, A diaphragm 8 for attaching the voice coil 7 to the inside to generate vibration due to the vertical movement of the voice coil 7 and a protector 10 for protecting the diaphragm 8, ).

The outgoing line of the voice coil 7 is attached and fixed to the bottom surface of the diaphragm 8 by using a bonding wire and a groove (not shown) formed in the frame 1 through the side surface of the frame 1 And is soldered to the terminal 14 along the outer side surface of the frame 1, respectively.

Further, a damper (not shown) may be installed under the diaphragm to structurally control the knitting vibration and to prevent the lead wire of the voice coil 7 from being cut off, thereby enhancing the reliability of the acoustic conversion apparatus. In the application of the conventional micro speaker, the vibration source was relatively stable due to a large number of used sound sources, and in many cases, the damper was not applied in consideration of the number of parts and the work process, but communication technology developed and use of the low frequency sound source The damper is used more often.

However, since the conventional micro speaker module has a small total volume (size), it has a disadvantage that the bass reproduction performance is poor and the overall balance of the sound is poor.

An object of the present invention is to provide a sound converting device having a sound pressure adjusting function to enable sound pressure correction / adjustment within a sound converting device having a small total volume.

In addition, the present invention provides an acoustic transducer having a sound pressure control function having an electrical configuration capable of applying power to a sound pressure correction circuit portion and applying an acoustic signal to a sound pressure correction circuit portion and then applied to a voice coil The purpose is to provide.

It is another object of the present invention to provide an acoustic transducer having a regenerative force and a sound pressure control function capable of improving sound balance due to miniaturization of the acoustic transducer.

It is also an object of the present invention to provide an acoustic transducer having a sound pressure control function such that the diaphragm is kept within the maximum allowable temperature while approaching the maximum allowable amplitude even in a small volume.

The acoustic transducer having a sound pressure control function of the present invention generates a sound by vibrating by a vibration of a voice coil and a voice coil, which are vibrated by mutual electromagnetic forces with the magnetic circuit and a magnetic circuit installed in the frame and the magnetic circuit. An acoustic transducer comprising a diaphragm, comprising: a sound pressure correction device for processing an electric signal applied from the outside based on gain data and applying the same to a voice coil, wherein the sound pressure correction device has an amplitude within the maximum allowable amplitude, The amplified or attenuated electric signal is applied according to the gain data so that the temperature of the voice coil is within the maximum allowable temperature.

In addition, the sound pressure correction device stores the gain data for each frequency or frequency band corresponding to the volume.

Also, the sound pressure correction device stores gain data in which the gain is set higher than the case where the volume is relatively large in the low band frequency band below the resonance frequency when the volume is small.

In addition, the sound pressure correction device is composed of a FPCB substrate that serves to apply an electrical signal to the voice coil, and a sound pressure correction circuit that is installed on the FPCB substrate to process the electrical signal applied from the outside to the voice coil through the FPCB substrate. .

In addition, the sound pressure correction method of the sound transducer according to the present invention is to measure the amplitude characteristics of the sound transducer in the operation state of the sound pressure correction circuit, the amplitude of the diaphragm is maintained within the maximum allowable amplitude on the basis of the measured amplitude characteristics Determining a sound pressure correction gain, a first setting step of setting gain data including the determined gain in the sound pressure correction circuit, measuring a temperature characteristic of the acoustic transducer in an operating state of the sound pressure correction circuit; On the basis of the measured temperature characteristics, determining whether the temperature of the voice coil is maintained within the maximum allowable temperature, and in the determining step, corrects the gain of the frequency or frequency band where the temperature of the voice coil exceeds the maximum allowable temperature And a second setting step of setting the gain data including the modified gain in the sound pressure correction circuit. The.

In addition, the sound pressure correction method repeatedly performs the temperature characteristic measurement step, the determination step and the second setting step.

In addition, the sound pressure correction method repeatedly performs the amplitude characteristic measurement step, the gain determination step and the first setting step.

The present invention provides an acoustic transducer having a sound pressure adjustment function corresponding to a volume that enables sound pressure correction / adjustment within an acoustic transducer having a small total volume.

The acoustic transducer provided by the present invention can prevent the acoustic transducer itself from being reduced in size due to the provision of a sound pressure correction circuit to reduce the bass reproduction force.

In addition, the acoustic transducer provided by the present invention is advantageous in that it is not necessary to provide a separate component for connecting a chip by providing a negative pressure correction circuit on an FPCB substrate that applies an electrical signal from the outside.

In addition, the acoustic transducer provided by the present invention can increase the space utilization by placing the chip in the enclosure space provided in the frame.

In addition, the present invention has an electrical configuration capable of applying power to a sound pressure correction circuit section, applying an acoustic signal to a sound pressure correction circuit section, and then applying the sound signal to a voice coil, have.

Further, the present invention can improve regenerative force and negative balance due to miniaturization of the acoustic transducer.

In addition, the present invention has the effect of adjusting the sound pressure while keeping the diaphragm close to the maximum allowable amplitude and within the maximum allowable temperature even in a small volume.

1 is a cross-sectional view of a conventional acoustic transducer,
2 is an exploded perspective view of an acoustic transducer according to an embodiment of the present invention,
3 is a cross-sectional view of an acoustic transducer according to an embodiment of the present invention,
FIG. 4 is a view illustrating a negative pressure correction circuit unit provided on an FPCB substrate and an FPCB substrate included in an acoustic transducer according to an embodiment of the present invention;
5 is a view illustrating a terminal portion of an FPCB substrate included in an acoustic transducer according to an embodiment of the present invention,
6 is a view showing a combined state of a frame and a magnetic circuit included in the sound converting apparatus according to an embodiment of the present invention,
7 shows an embodiment of the sound pressure correction circuit portion 700,
8 is a graph showing a relationship between frequency and vibration displacement according to volume (volume);
9 is a schematic configuration diagram of a gain setting system,
10 is a graph showing temperature characteristics of the acoustic transducer;
11 is a flowchart of a sound pressure correction method of the acoustic transducer.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 2 is an exploded perspective view of an acoustic transducer according to an embodiment of the present invention, and FIG. 3 is a top view of the acoustic transducer according to an embodiment of the present invention. The sound conversion apparatus according to an embodiment of the present invention includes a frame 100 and a magnetic circuit 200 provided in the frame 100 and including a yoke 210, a permanent magnet 220, a top plate 230, The voice coil 300 vibrates due to the mutual electromagnetic force in the space between the side surface of the yoke 210 and the permanent magnet 220 and vibrates due to the vibration of the voice coil 300 to generate sound, A diaphragm 400 including a side diaphragm 410 and a suspension for transmitting an electric signal to the voice coil 300 and holding vibration of the diaphragm 400 and a terminal for receiving an electric signal from an external terminal A lower cover 620 that is coupled to the lower surface of the frame and protects the components of the sound conversion device, and a lower cover 620 that is disposed at the uppermost portion and protects the components of the sound conversion device. And is mounted on the FPCB substrate 500, And a sound pressure correction circuit part (700) for optimizing the acoustic characteristics of the incense conversion device.

The frame 100 is provided with a magnetic circuit 200 including a yoke 210, a permanent magnet 220 and a top plate 230 at the center. Therefore, the center is provided with an empty space for installing the magnetic circuit 200, and the enclosure 140 (see FIG. 6), which is a resonance space outside the magnetic circuit 200, is provided. A vibrating member to which the voice coil 300, the vibration plate 400, and the FPCB substrate 500 are attached is provided on the frame 100. [ A voice coil 300 is attached to a lower portion of the FPCB substrate 500 and a side diaphragm 410 is attached to the voice coil 300 at a predetermined distance from an attachment portion of the voice coil 300. The center diaphragm 420 is attached to the upper portion of the FPCB substrate 500. 4), which is a portion where the voice coil 300 and the diaphragm 400 are attached to the FPCB substrate 500, is seated on the upper portion of the frame 100 and is formed by being bent from the suspension portion 510 The side connection portion 520 (see FIG. 4) is located on the side of the frame 100. The terminal portion 530 bent from the side connection portion 520 and positioned in parallel with the suspension portion 510 is seated in the lower portion of the frame 100.

After the magnetic circuit 200 and the vibration member are installed in the frame 100, the protector 610 is coupled to the upper portion of the frame 100 and the lower cover 620 is coupled to the lower portion of the frame 100, To protect the components installed in the vehicle.

The voice coil 300 is bonded to the suspension unit 510 by soldering or the like, and attached to the suspension unit 510 by a tape or other adhesive. The vibration of the diaphragm 400 can be made only in the upward and downward directions by the suspension unit 510 to prevent the abnormal vibration such as the split vibration and the knitting vibration, thereby improving the sound quality. The diaphragm 400 includes a center diaphragm 420 located at the center and a side diaphragm 410 located outside the center diaphragm 420 and formed in a ring shape. The center diaphragm 420 has a dome shape protruding upward and the side diaphragm 410 has a dome shape protruding downward. The center diaphragm 420 is attached to the upper portion of the suspension portion 510 and the side diaphragm 410 is attached to the lower portion of the suspension portion 510.

On the other hand, the center diaphragm 420 and the side diaphragm 410 may be made of a film of the same material as necessary or may be made of a film of another material. The center diaphragm 420 is made of a thermoplastic film such as PE or PP, and UV molding or the like may be performed as needed. The side diaphragm 410 may be manufactured by laminating a thermoplastic film such as PE or PP and a thermoplastic urethane film such as TPU. Since the center diaphragm 420 and the side diaphragm 410 have different tone ranges, the side diaphragm 410 increases ductility and elasticity to improve the acoustic characteristics of the low frequency band. The center diaphragm 420 is lightweight, So that the acoustic characteristics of the medium and high frequency bands can be improved.

FIG. 4 is a view showing a negative pressure correction circuit unit provided on an FPCB substrate and an FPCB substrate included in an acoustic transducer according to an embodiment of the present invention.

The FPCB substrate 500 of the acoustic transducer according to the embodiment of the present invention includes a suspension part 510 and a frame part 500 which are positioned on the upper surface of the frame 100 and to which the voice coil 300 and the diaphragm 400 are attached, The side connection portion 530 located on the side surface of the frame 100 connects the terminal portion 520 where the sound pressure correction circuit portion 700 is installed, the suspension portion 510 and the terminal portion 520, .

The suspension part 510 includes a seating part 512 which is an edge of the frame 100 and a central part 514 to which the diaphragm 400 under the voice coil 300 is attached and a seating part 512 and a middle part 514 And a connection portion 516 for providing a damping effect. An electrical signal is transmitted to the voice coil 300 through the FPCB conductive pattern formed on the suspension unit 510. [ The conductive pattern of the FPCB may be connected to the central portion 514 via the seating portion 512 and the connection portion 516 and a bonding portion (not shown) may be provided on the central portion 514 to be soldered to the voice coil 300.

The terminal unit 520 is installed on a lower surface of the frame 100 and includes an installation surface 522 through which an electrical signal from the outside can be installed on the terminal 524 and the sound pressure correction circuit unit 700. A total of four terminals 524 are formed and a lead line connected to the terminal 524 is a (+) pole, a negative pole, and a power source (+ DC, GND / -DC) of an acoustic signal . An FPCB pattern capable of transmitting an electrical signal is also formed in the terminal unit 520 and the side connection unit 530 so that the electric signal transmitted through the terminal 524 passes through the side connection unit 530 and the suspension unit 510 To be transmitted to the voice coil (300). The frame 100 is formed with a side connection receiving groove 170 (see FIG. 4) in which the side connection portion 530 is inserted and a terminal receiving groove 180 (see FIG. 2) into which the terminal portion 520 is inserted, 100) are formed with a terminal lead-out hole 190 (see FIG. 2) so that the terminal 524 can be drawn out of the frame 100. The FPCB substrate 500 is installed in the frame 100 and then the lower cover 620 is coupled to the lower portion of the frame 100 to protect the components of the FPCB substrate 500 and other acoustic transducer devices.

5 is a view illustrating a terminal portion of an FPCB substrate included in an acoustic transducer according to an embodiment of the present invention. The terminal portion 520 of the FPCB substrate 500 is provided with terminals 524 at four corners and an electric signal is inputted from the terminal 524 to the sound pressure correction circuit portion 700 or inputted through the sound pressure correction circuit portion 700 Conductive patterns 524a, 524b, 524c, 524d, 524e and 524f for transmitting signals to the voice coil 300 are formed. Two of the conductive patterns 524a, 524b, 524c, 524d, 524e and 524f are signal input patterns 524a and 524b for receiving an electric signal from an electric device in which a sound conversion device such as a cellular phone is installed, And power supply patterns 524c and 524d which are connected to the input of the sound pressure correction circuit part 700 for supplying power from the electric device and become + DC and -DC / GND, and the remaining two are patterns from the sound pressure correction circuit part 700 Output patterns 524e and 524f for outputting a signal processed by the voice coil 300. As shown in Fig.

A conductive pattern is naturally formed also in the side connection portion 530 and the suspension portion 510 for electrical connection between the signal output patterns 524e and 524f and the voice coil 300. [

6 is a view illustrating a combined state of a frame and a magnetic circuit included in the sound converting apparatus according to an embodiment of the present invention. The frame 100 is provided with a magnetic circuit 200 including a yoke 210, a permanent magnet 220 (see FIG. 2), and a top plate 230 at the center. Therefore, the center of the yoke 210 is provided with an empty space for installing the magnetic circuit 200, and includes an inner wall 110 having a shape corresponding to the circumference of the yoke 210 and to which the yoke 210 can be coupled. An outer wall 120 forming an outer shape of the frame 100 is formed at a predetermined distance from the inner wall 110. A plurality of ribs 130 connecting the outer wall 120 and the inner wall 110 are provided and a space formed between the inner wall 110 and the outer wall 120 and the rib 130 is enclosed by the enclosure 140 . The sound pressure correcting circuit unit 700 may be provided in a part of the enclosure 140 so that the sound pressure correcting circuit unit 700 may be integrated into the sound converting apparatus. When the sound pressure correction circuit unit 700 is integrally provided in the sound conversion apparatus, it is advantageous in that it is easy to assemble and the parts are easily managed. The sound pressure correction circuit part 700 can be installed anywhere on the FPCB board 500 so that the sound pressure correction circuit part 700 is formed on one side of the side opposite to the side connection part 630, 100 of the present invention.

A seating surface 150 on which the side diaphragm 410 or the suspension unit 510 of the FPCB substrate 500 or the protector 610 can be placed is formed on the upper surface of the outer wall 120 of the frame 100. The four corners of the upper surface of the outer wall 120 of the frame 100 are provided with protrusions for facilitating positioning of the side diaphragm 410 or the suspension unit 510 of the FPCB substrate 500 or the protector 610 160 may be formed. The lateral connection receiving grooves 170 are formed at one outer side surface of the outer wall 120 of the frame 100 to accommodate the side connection portions 630 of the FPCB substrate 500. [ 3) for inserting the terminal part 520 is formed on the lower surface of the frame 100 and a terminal 524 is drawn out to the side of the frame 100 to the outside of the frame 100 A terminal lead-out hole 190 (see FIG. 3) is formed.

The sound pressure correction circuit unit 700 may basically be an element that performs an equalizer function and an amplification function. That is, the sound pressure correction circuit unit 700 is a device that can adjust the gain or gain of an electric signal or an electric signal to be inputted to the sound conversion apparatus according to a frequency or a frequency band.

In the present embodiment, the sound pressure correction circuit portion 700 and the FPCB substrate 500 are referred to as one sound pressure correction device. The sound pressure correction circuit portion 700 processes the electric signal received from the outside and applies it to the voice coil 300 Function.

Fig. 7 shows an embodiment of the sound pressure correction circuit section 700. Fig.

In this embodiment, the sound pressure correction circuit portion 700 is used as a digital speaker module and can also be used as a receiver module. The sound pressure correction circuit 700 includes a converter 710 that receives an electric signal as an input signal and converts the digital signal into an analog signal, an LPF (low-pass filter) 712 that processes a low-frequency band of the analog signal, (Dynamic Range Compression) 714 that receives a signal from the input unit 712 and dynamically adjusts the size of the output according to the magnitude of the input signal, and a HPF A DRC 714 that receives a signal from the HPF 716 and dynamically limits the size of the output according to the magnitude of the input signal to limit the DRC 714, And a summation unit 720 for summing and outputting signals from the DRC 718. In the present embodiment, in the case of DRCs 716 and 718, enhanced DRC may be applied to reduce the sound pressure only in some bands. The gain of the sound pressure correction circuit unit 700 can be adjusted / set to control the increase / decrease of the desired gain for each frequency band.

The converter 710 may be a digital-analog converter or a digital-analog converter depending on the type of the signal (analog signal, digital signal) input to the sound pressure correction circuit portion 700 An analog-to-digital converter may be used.

8 is a graph showing a relationship between frequency and vibration displacement according to volume. As shown in the figure, it is confirmed that the vibration displacement of the diaphragm 400 when the volume is large (0.8 cc) is larger than the vibration displacement when the volume is small (0.4 cc, 0.3 cc, 0.2 cc).

The volume means the back volume of the enclosure. The back volume is a space connected to the back hole of the acoustic transducer including the back of the diaphragm and plays a role of stiffness when the diaphragm moves.

As the volume (volume) increases, the stiffness of the air decreases as the diaphragm vibrates. As a result, the vibration power increases and the sound pressure becomes higher than when the diaphragm having a smaller volume in the frequency band before the resonance point vibrates. Also, the stiffness is lowered as compared with the case where the volume is small as a whole, and the resonance frequency is relatively lower than in the case where the volume is small. If the volume is small, the vibrating plate basically vibrates less than the designed space where the vibrating plate can vibrate, so that a relatively large amount of vibration space is left. It is necessary to set the gain of the sound pressure correction circuit section 700 in accordance with the volume and the frequency band so that the vibration characteristics are similar or equal to each other.

In the graph, when the amplitude at the resonance frequency of 0.8 cc is assumed as the maximum allowable amplitude, the smaller the volume, the higher the gain can be adjusted in the low frequency band or the low frequency band.

Therefore, in the present invention, the gain for the input signal is given and output in consideration of the low band frequency or the low band frequency band below the resonance frequency and the volume of the acoustic transducer. In addition, in a particular situation, when attenuation processing for the input signal is required, the processing thereof may of course also be performed.

In order to reduce the gain for the attenuation process and increase the gain for the amplification process, the following gain setting system is required.

9 is a schematic configuration diagram of a gain setting system. In detail, the characteristic measuring apparatus 1000 includes an amplitude characteristic measuring unit for measuring the amplitude displacement of the diaphragm according to the volume of the acoustic transducer. Here, the characteristic measuring apparatus 1000 may include an oscillator for generating and applying electrical signals of various frequencies / frequency bands to the acoustic transducer, and an ultraviolet inspector for measuring vibration displacement. The amplitude characteristic measurement unit measures the state in which the sound pressure correction circuit unit 700 is not installed or operated in the acoustic transducer.

In addition, the gain setting device 1100 determines the gain for raising to the maximum allowable amplitude or the desired amplitude based on the amplitude displacement data according to the volume confirmed by the amplitude characteristic measurement beam.

Here, the maximum allowable amplitude is confirmed by the design value of the acoustic transducer, and is determined by the minimum value of the distance between the diaphragm and the upper protector, the distance between the diaphragm and the lower magnetic circuit, and the distance between the voice coil and the lower yoke. In other words, the minimum amplitude that can cause a touch during vibration corresponds to the maximum allowable amplitude.

The gain setting apparatus 1100 generates and stores a gain table for each frequency or each frequency band for the sound pressure correction circuit unit 700 including the determined gain. For example, the gain table may be set as shown in Table 1.

In Table 1, the frequency band may be set, for example, Band1 (0 to 100 Hz) and Band2 (101 to 200 Hz).

The gain setting device 1100 causes the setting according to the gain table described above to the sound pressure correction circuit unit 700 of the acoustic transducer, and the sound pressure correction circuit unit 700 receives a signal input to generate a gain according to the set gain table. Will be processed and output. The gain setting device 1100 corresponds to a device capable of setting a parameter according to the gain table in the microchip type sound pressure correction circuit portion 700. [

In order to obtain an accurate gain table as shown in Table 1, the sound pressure correction circuit unit 700 is set in accordance with a gain table corresponding to each volume (individual volume) set by the gain setting device 1100, and again the characteristic measuring device ( 1000 may measure the amplitude displacement of the diaphragm with respect to the acoustic transducer to see if it rises to the maximum allowable amplitude or to the desired amplitude, and may supplement the previous gain table.

In addition, the characteristic measuring apparatus 1000 includes a temperature characteristic measuring unit for measuring the temperature of the voice coil 300 for each frequency. The temperature characteristic measuring unit includes a voice coil temperature meter, which is a device for estimating the temperature of the voice coil 300 by using a resistance change rate of the voice coil 300, and a cause of heat generation in the acoustic transducer of the voice coil 300. Temperature is used to evaluate the temperature of the acoustic transducer.

In the gain determination system of the present invention, after the sound pressure correction circuit 700 is set by the gain data according to the amplitude characteristic, the temperature characteristic measurement is performed on the amplitude corrected acoustic transducer.

10 is a graph showing temperature characteristics of the acoustic transducer. As shown in Fig. 10, a sample (acoustic transducer) graph (first graph) before amplitude correction and a sample (acoustic transducer) graph (second graph) after amplitude correction are shown. In the case of the first graph, since it is before amplitude correction (non-installation or non-operation of the sound pressure correction circuit 700), that is, before gain correction (amplification correction) is performed. In the case of the second graph, since the amplitude is corrected (installation and operation of the sound pressure correction circuit 700), it is corrected so that the amplitude is increased, that is, after the gain correction (amplification correction) is performed.

As shown in Fig. 10, it is confirmed that the temperature is significantly increased in comparison with the first graph, especially in the low band frequency region of 1 kHz or less.

In the case of an electric device (for example, a mobile communication terminal) provided with an acoustic transducer, a maximum allowable temperature for protecting the electric device is determined. Therefore, even in the case of an acoustic transducer after amplitude correction, it is necessary to measure the characteristics so that the measured temperature falls within this maximum allowable temperature range, and if the frequency or frequency band exceeds the maximum allowable temperature, adjust the gain downward. There is.

For example, when the maximum allowable temperature is 180 ° C, for the frequency band of 500 to 600Hz in the second graph, it corresponds to about 183 ° C. The gain can be adjusted down.

11 is a flowchart of a sound pressure correction method of the acoustic transducer.

In detail, in operation S20, the characteristic measuring apparatus 1000 measures the amplitude characteristic of the acoustic transducer in a state in which the sound pressure correction circuit 700 is stopped (or not mounted).

In step S22, the gain determining apparatus 1100 obtains the amplitude characteristic from the characteristic measuring apparatus 1000 to determine a gain that can increase or decrease the amplitude to within the maximum allowable amplitude or the desired amplitude, and the determined The gain data (table) including the gain is set (stored) in the sound pressure correction circuit unit 700.

In operation S24, the characteristic measuring apparatus 1000 measures the temperature characteristic of the acoustic transducer in which the gain-corrected sound pressure correction circuit 700 is operated.

In operation S26, the gain determination apparatus 1100 analyzes the temperature characteristic obtained from the characteristic measurement apparatus 1000 to determine a frequency or frequency band exceeding the maximum allowable temperature. If there is a frequency or frequency band in which the temperature included in the obtained temperature characteristic exceeds the maximum allowable temperature, the flow proceeds to step S28, otherwise the process ends.

In step S28, the gain determination device 1100 analyzes the obtained temperature characteristic and attenuates the gain of the frequency or frequency band exceeding the maximum allowable temperature, thereby performing gain correction. The gain determination device 1100 sets the gain data thus modified to the sound pressure correction circuit unit 700. Then, by repeating steps S24 to S28, the temperature characteristics at all frequencies or frequency bands are corrected to be within the maximum allowable temperature.

Thus, the volumetric gain data is corrected to satisfy both the maximum allowable amplitude and the maximum allowable temperature.

As described above, the present invention is not limited to the specific preferred embodiments described above, and any person having ordinary skill in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. It is to be understood that such changes may be made, and such changes will fall within the scope of the claims.

100: frame 200: magnetic circuit
210: yoke 220: permanent magnet
230: Top plate 300: Voice coil
400: diaphragm 410: side diaphragm
420: center diaphragm 500: FPCB substrate
510: Suspension part 520: Side connection part
530: Terminal part 522: Mounting surface
524: terminal

Claims (7)

In a sound conversion device comprising a frame, a magnetic circuit installed in the frame, a voice coil that receives an electrical signal and vibrates by mutual electromagnetic forces with the magnetic circuit, and a diaphragm that vibrates by vibration of the voice coil and generates sound.
It includes a sound pressure correction device for processing the electrical signal applied from the outside based on the gain data to apply to the voice coil,
The sound pressure correction device converts an amplified or attenuated electric signal according to the gain data so that the amplitude of the diaphragm is within the maximum allowable amplitude and the voice coil is within the maximum allowable temperature. Device. The method of claim 1,
The sound pressure correction device is a sound converting device having a sound pressure control function, characterized in that for storing the gain data for each frequency or frequency band corresponding to the volume. 3. The method of claim 2,
The sound pressure compensating device has a sound pressure control function, characterized in that, when the volume is small, the gain data is set to have higher gain than the case where the volume is relatively large in the low band frequency band below the resonance frequency. 4. The method according to any one of claims 1 to 3,
The sound pressure correction device is composed of an FPCB substrate that serves to apply an electrical signal to the voice coil, and a sound pressure correction circuit that is installed on the FPCB substrate to process an electric signal applied from the outside and applies the voice signal to the voice coil through the FPCB substrate. Sound transducer with sound pressure control function. Measuring an amplitude characteristic of the sound transducer in the stopped state of the sound pressure correction circuit unit;
Determining a sound pressure correction gain such that the amplitude of the diaphragm is kept within the maximum allowable amplitude based on the measured amplitude characteristic;
A first setting step of setting gain data including the determined gain in the sound pressure correction circuit;
Measuring a temperature characteristic of the acoustic transducer in an operating state of the sound pressure correction circuit;
Determining whether the temperature of the voice coil is maintained within the maximum allowable temperature based on the measured temperature characteristic;
And in the determining step, a second setting step of correcting a gain of a frequency or a frequency band in which the temperature of the voice coil exceeds the maximum allowable temperature and setting gain data including the corrected gain in the sound pressure correction circuit. Sound pressure correction method of the sound transducer. The method of claim 5,
The sound pressure correction method is a sound pressure correction method of the acoustic transducer, characterized in that to perform the temperature characteristic measurement step, the determination step and the second setting step repeatedly. The method of claim 5,
The sound pressure correction method includes repeating the amplitude characteristic measurement step, the gain determination step, and the first setting step.

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