阅读说明：本技术 一种静电耳机 (Electrostatic earphone ) 是由 边仿 于 2021-08-09 设计创作，主要内容包括：本发明提出了一种静电耳机,将内嵌有纳米级金属层的以高分子聚合物材料为主体的微米级振膜悬挂在由两块固定电极板之间而形成高压恒定静电场,当音频信号加载到上述恒定静电场时,会调制静电电场力随之发生变化,驱动微米级振膜振动；提高了静电耳机的安全性、稳定性,并使静电耳机更趋于小型化。(The invention provides an electrostatic earphone.A micron-sized vibrating diaphragm which is embedded with a nano-sized metal layer and takes a high molecular polymer material as a main body is suspended between two fixed electrode plates to form a high-voltage constant electrostatic field, and when an audio signal is loaded to the constant electrostatic field, the force of the electrostatic field is modulated to change along with the constant electrostatic field, so that the micron-sized vibrating diaphragm is driven to vibrate; the safety and the stability of the electrostatic earphone are improved, and the electrostatic earphone tends to be miniaturized.)

1. An electrostatic earphone is characterized by comprising an audio signal input end, a boosting transformer and an electrostatic transducer; the electrostatic transducer comprises a micron-sized vibrating diaphragm, an upper electrode plate and a lower electrode plate, wherein the micron-sized vibrating diaphragm is positioned between the upper electrode plate and the lower electrode plate, an upper air gap is formed between the micron-sized vibrating diaphragm and the upper electrode plate, and a lower air gap is formed between the micron-sized vibrating diaphragm and the lower electrode plate; the micron-scale diaphragm main body material is a high molecular polymer, and a nano-scale metal layer is embedded in the middle plane of the micron-scale diaphragm main body material; the upper electrode plate and the lower electrode plate are respectively connected with one end of a high-voltage winding of the boosting transformer, the audio signal input end is connected with a low-voltage winding of the boosting transformer, and the metal layer of the micron-sized vibrating diaphragm is connected with the other end of the high-voltage winding of the boosting transformer.

2. The electrostatic earphone as claimed in claim 1, wherein the micron-sized diaphragm has a thickness of 1-10 μm and a surface potential of 300-350V.

3. The electrostatic earphone according to claim 1, wherein the metal layer has a thickness of 10-50nm and the material comprises iron, aluminum, titanium or beryllium.

4. The electrostatic earphone according to claim 3, wherein the metal layer has micropores radially distributed on the surface thereof.

5. An electrostatic earphone as claimed in claim 4, wherein the upper and lower surfaces of the metal layer are in close contact with the high molecular polymer without a gap.

6. The electrostatic earphone according to claim 4, wherein an air gap exists between the upper and lower surfaces of the metal layer and the high molecular polymer.

7. The electrostatic earphone according to claim 1, wherein the high molecular polymer is a poled polytetrafluoroethylene, polyethylene naphthalate, or fluorinated ethylene propylene copolymer.

8. An electrostatic earphone as claimed in claim 7, wherein the method of polarizing the high molecular polymer comprises heating the high molecular polymer material to a temperature slightly higher than the glass transition temperature of the high molecular polymer, and polarizing the material with an electric field of 1.0-3.0kV for 0.1-1h while maintaining the temperature constant.

9. The electrostatic earphone according to claim 1, wherein the upper air gap and the lower air gap are equal in thickness.

10. The electrostatic earphone according to claim 1, wherein the upper air gap and the lower air gap have unequal thicknesses.

11. The electrostatic earphone according to claim 1, wherein the audio signal input is connected to the low voltage winding of the step-up transformer via an integrated amplifier comprising a preamplifier, a volume potentiometer and a power amplifier.

12. An electrostatic earphone as claimed in claim 1, wherein the step-up transformer high voltage stage winding is connected to the upper electrode plate, the lower electrode plate and the metal layer via at least one overvoltage protector.

13. An electrostatic earphone as claimed in claim 12, wherein the step-up transformer high voltage stage winding is connected to the upper electrode plate, the lower electrode plate and the metal layer via two or more parallel overvoltage protectors.

14. The electrostatic earphone according to claim 13, wherein the overvoltage protector is provided with a pair of pins which respectively receive the audio signal voltages outputted as the windings of the high-voltage stage of the step-up transformer, and the overvoltage protection component is provided between the pins.

15. The electrostatic earphone according to claim 14, wherein the overvoltage protection component is a varistor.

Technical Field

The invention relates to the field of audio output equipment, in particular to an electrostatic earphone.

Background

The principle of the electrostatic earphone is that a vibrating diaphragm made of organic polymer material is suspended between two fixed metal polar plates, and a stable electrostatic field is formed between the polar plates and the vibrating diaphragm with metalized surface by applying direct-current high voltage. When an audio signal is loaded between the polar plate and the vibrating diaphragm, the electrostatic field is correspondingly changed under the modulation of audio alternating voltage, and the vibrating diaphragm is displaced relative to the polar plate under the alternating driving of the electric field force, so that vibration is generated. In principle, the structure of the unipolar plate can drive the diaphragm to generate corresponding vibration, but the driving force of the bipolar plate push-pull structure is larger, and the distortion is smaller, so that the existing electrostatic earphone basically adopts the bipolar plate push-pull driving structure. Compared with a moving coil earphone, the electrostatic earphone has the advantages that the lighter and thinner diaphragm brings faster speed, better transient response and stronger detail expression. And the vibrating membrane of the electrostatic earphone is a completely planar vibrating membrane clamped between two parallel fixed polar plates, and the received electric field force is completely uniform, so that linear driving can be realized, and no segmentation vibration exists. At present, the high-voltage electrostatic field of the electrostatic earphone adopts direct-current high voltage of more than 500V, the requirement on a voltage transformation device of the earphone is high, and the stability and the safety are poor.

Disclosure of Invention

In view of the above-mentioned disadvantages in the prior art, the present invention provides an electrostatic earphone, which includes an audio signal input terminal, a step-up transformer and an electrostatic transducer; the electrostatic transducer comprises a micron-sized vibrating diaphragm, an upper electrode plate and a lower electrode plate, wherein the micron-sized vibrating diaphragm is positioned between the upper electrode plate and the lower electrode plate, an upper air gap is formed between the micron-sized vibrating diaphragm and the upper electrode plate, and a lower air gap is formed between the micron-sized vibrating diaphragm and the lower electrode plate; the micron-scale diaphragm main body material is a high molecular polymer, and a nano-scale metal layer is embedded in the middle plane of the micron-scale diaphragm main body material; the upper electrode plate and the lower electrode plate are respectively connected with one end of a high-voltage winding of the boosting transformer, the audio signal input end is connected with a low-voltage winding of the boosting transformer, and the metal layer of the micron-sized vibrating diaphragm is connected with the other end of the high-voltage winding of the boosting transformer.

Preferably, the micron-sized diaphragm has a thickness of 1-10 μm and a surface potential of 300-350V.

Preferably, the metal layer has a thickness of 10-50nm and comprises iron, aluminum, titanium or beryllium.

Preferably, micropores are radially and uniformly distributed on the surface of the metal layer at the center.

Preferably, the upper surface and the lower surface of the metal layer are in gapless fit with the high polymer.

Preferably, an air gap exists between the upper surface and the lower surface of the metal layer and the high molecular polymer.

Preferably, the high molecular polymer is polytetrafluoroethylene, polyethylene naphthalate or fluorinated ethylene propylene copolymer which is subjected to polarization treatment.

Preferably, the method for polarizing the high molecular polymer comprises heating the high molecular polymer raw material to a temperature slightly higher than the glass transition temperature of the high molecular polymer, and polarizing with an electric field of 1.0-3.0kV for 0.1-1h, wherein the temperature is kept constant during the period.

Preferably, the upper air gap and the lower air gap are equal in thickness.

Preferably, the upper air gap and the lower air gap have unequal thicknesses.

Preferably, the audio signal input end is connected with the low-voltage level winding of the boosting transformer through an integrated amplifier consisting of a preamplifier, a volume potentiometer and a power amplifier.

Preferably, the step-up transformer high-voltage level winding is connected with the upper electrode plate, the lower electrode plate and the metal layer through at least one overvoltage protector.

Preferably, the step-up transformer high-voltage level winding is connected with the upper electrode plate, the lower electrode plate and the metal layer through more than two overvoltage protectors connected in parallel.

Preferably, the overvoltage protector is provided with a pair of pins which respectively receive the audio signal voltages outputted as the windings of the high-voltage stage of the step-up transformer, and the overvoltage protection component is provided between the pins.

Preferably, the overvoltage protection component is a varistor.

Because the high molecular polymer material has the special property of long-term charge retention after high-voltage electric field polarization, the high-voltage direct-current electrostatic field is generated only by the self charge of the polarized high molecular polymer material without external direct-current high voltage supply. A simplified electrostatic earphone with self-generated bias voltage can be developed.

Drawings

Fig. 1 is a schematic block diagram of an electrostatic earphone according to an embodiment of the present invention.

Fig. 2 is a schematic block diagram of another electrostatic earphone according to an embodiment of the present invention.

The device comprises an audio signal input end-1, a step-up transformer-2, an electrostatic transducer-3, a micron-sized vibrating diaphragm-4, an upper electrode plate-5, a lower electrode plate-6, a metal layer-7, an overvoltage protector-8 and an overvoltage protection component-9.

Detailed Description

In order to solve the problems that the existing electrostatic earphone has a complex structure and needs to be enhanced in stability and safety, the electrostatic earphone provided by the invention is realized by the following technical scheme:

example 1:

the present embodiment provides an electrostatic earphone, please refer to fig. 1, which includes an audio signal input terminal 1, a step-up transformer 2 and an electrostatic transducer 3; the electrostatic transducer 3 comprises a micron-sized vibrating diaphragm 4, an upper electrode plate 5 and a lower electrode plate 6, wherein the micron-sized vibrating diaphragm 4 is positioned between the upper electrode plate 5 and the lower electrode plate 6, an upper air gap is arranged between the micron-sized vibrating diaphragm 4 and the upper electrode plate 5, and a lower air gap is arranged between the micron-sized vibrating diaphragm 4 and the lower electrode plate 6; the main body material of the micron-scale vibrating diaphragm 4 is high molecular polymer, and a nanoscale metal layer 7 is embedded in the middle plane of the micron-scale vibrating diaphragm; the upper electrode plate 5 and the lower electrode plate 6 are respectively connected with one end of a high-voltage winding of the boosting transformer 2, the audio signal input end 1 is connected with a low-voltage winding of the boosting transformer 2, and the metal layer 7 of the micron-sized vibrating diaphragm 4 is connected with the other end of the high-voltage winding of the boosting transformer 2. The above arrangement can still realize the multi-group electrostatic transduction effect under the condition of smaller size, and the overall stability and the transduction effect of the electrostatic transducer 3 are improved.

Specifically, the thickness of the micron-sized diaphragm 4 is 1-10 μm, and the surface potential thereof is 300-350V.

Specifically, the thickness of the metal layer 7 is 10-50nm, and the material thereof contains iron, aluminum, titanium or beryllium.

Specifically, micropores are radially and uniformly distributed on the surface of the metal layer 7 at the center. The arrangement can fuse the high molecular polymers on the upper surface and the lower surface of the metal layer 7 into an integral structure, thereby improving the structural strength without influencing the electrostatic transduction effect; in addition, the metal layer 7 is embedded, so that the whole vibration performance of the micron-sized diaphragm 4 is better.

Specifically, the upper surface and the lower surface of the metal layer 7 are in gapless fit with the high molecular polymer.

Specifically, air gaps exist between the upper and lower surfaces of the metal layer 7 and the high molecular polymer.

Specifically, the high molecular polymer is polytetrafluoroethylene, polyethylene naphthalate or fluorinated ethylene propylene copolymer subjected to polarization treatment.

Specifically, the method for polarizing the high molecular polymer comprises the steps of heating the high molecular polymer raw material to a temperature slightly higher than the glass transition temperature of the high molecular polymer, and polarizing for 0.1-1h by using an electric field of 1.0-3.0kV, wherein the temperature is kept constant in the period.

Specifically, the upper air gap and the lower air gap are equal in thickness.

Specifically, the upper air gap and the lower air gap are not equal in thickness.

Specifically, the audio signal input end 1 is connected with a low-voltage level winding of a boosting transformer 2 through an integrated amplifier consisting of a preamplifier, a volume potentiometer and a power amplifier.

Because the high molecular polymer material has the special property of long-term charge retention after high-voltage electric field polarization, the high-voltage direct-current electrostatic field is generated only by the self charge of the polarized high molecular polymer material without external direct-current high voltage supply. A simplified electrostatic earphone with self-generated bias voltage can be developed.

Example 2:

referring to fig. 2, in the present embodiment, based on embodiment 1, the high-voltage winding of the step-up transformer 2 is connected to the upper electrode plate 5, the lower electrode plate 6 and the metal layer 7 through at least one overvoltage protector 8. The overvoltage protector 8 is arranged to prevent the high-voltage level winding of the booster transformer 2 from being dangerous due to overhigh voltage caused by faults.

Specifically, the high-voltage winding of the step-up transformer 2 is connected with the upper electrode plate 5, the lower electrode plate 6 and the metal layer 7 through more than two overvoltage protectors 8 connected in parallel.

Specifically, the overvoltage protector 8 is provided with a pair of pins that respectively receive the audio signal voltages output as the windings of the high-voltage stage of the step-up transformer 2, and the overvoltage protection component 9 is provided between the pins.

In particular, the overvoltage protection component 9 is a varistor.

It should be noted that the above-mentioned embodiments are provided for further detailed description of the present invention, and the present invention is not limited to the above-mentioned embodiments, and those skilled in the art can make various modifications and variations on the above-mentioned embodiments without departing from the scope of the present invention.