RU2804812C2 - In-ear earphone - Google Patents

Abstract

FIELD: acoustics; headphones.

SUBSTANCE: in-ear earphone, comprising a housing, including an outer part and a part installed by the user inside the external auditory canal during operation of the earpiece up to its second turn, electroacoustic transducers are located in the housing and a part of the housing installed inside the auditory canal is made with the possibility of repeating the internal shape of the auditory canal when its installed in the auditory canal of a specific user, the electro-acoustic transducers installed in this part of the housing are placed with the possibility of shifting relative to the housing when it is bent, and the wires leading to them are flexible, in addition, the part of the housing installed inside the external auditory canal, in its front part is equipped with a flexible sealing nozzle, while the electro-acoustic transducers are equipped with acoustic channels, the outputs of which are located in the front part of the housing, installed inside the ear canal, while the acoustic channels are made flexible.

EFFECT: improved sound quality.

5 cl, 10 dwg

Description

TECHNICAL FIELD

The invention relates to designs of devices for emitting sound, more precisely to designs of headphones installed in the external auditory canal.

BACKGROUND ART

Headphones installed in the ear are usually called in-ear headphones, or in-ear headphones. Most of them are inserted at the very beginning of the external auditory canal. Headphones that are inserted deeper inside the ear canal are rare and are usually called in-ear headphones.

The use of in-ear headphones allows you to improve sound quality by increasing the output of electroacoustic transducers, reducing nonlinear distortions, as well as longitudinal low-frequency resonances.

The design of such headphones also makes it possible to significantly reduce the negative impact on the quality of sound experienced by the listener from such well-known effects as “blockage of the ear canal” and the so-called “bone transmission”. The deep installation of the in-ear headphone body itself allows you to orient the directional patterns of its speakers in such a way that they are maximally aligned with the so-called “main vector of sound propagation in the ear canal.

The main obstacle to the use of in-ear headphones is the complex shape of the ear canal, in which there is a first turn of the ear canal and a second turn, as well as the presence of an individual anatomical shape of the external auditory canal of each possible consumer. These anatomical features of the auditory canals are well illustrated in the diagram of the external auditory canal (Fig. 1) and in the cast of the auditory canal (Fig. 2).

The most suitable location for the acoustic insulation of the ear canal and the sound signal output of the in-ear earphone is the area of the so-called “Second Turning” of the ear canal. This location is characterized not only by its local expansion in all three dimensions, but also by the transition in this place of an area of weakly sensitive to mechanical stress and fairly elastic cartilage tissue (where the skin thickness is about one mm) to a bone area 5 (where the skin thickness is about a tenth fractions of mm, and where the pain syndrome begins to appear).

One of the well-known solutions to this problem in recent years has become the so-called “custom” ear monitors (CIEMs - Custom-In-The-Ear-Monitors), namely, in-ear headphones made based on individual impressions of the users’ ear canals. All the necessary components of the structure are located inside an individually molded case, and the sound from the speakers inside is distributed either through “sound guide” tubes installed on their acoustic outputs, or through sound channels drilled from them in the case material https://stereopravda. com/ru/blog/76/.

However, such in-ear headphones are piecemeal and difficult to manufacture and cannot be widely used.

A technical solution is known according to patent RU2621362, in-ear earphone, publication 06/02/2017, IPC H04R 1/10. The in-ear earphone contains at least three electroacoustic transducers installed in the housing. The housing is designed to be located in the external auditory canal, while the front part of the housing, when using the earphone, is located in the area of the Second Turn of the external auditory canal. The first electroacoustic transducer is installed in the front part of the housing, the remaining electroacoustic transducers are installed along the length of the housing and are equipped with coaxial acoustic channels, the outputs of which are located in the front part of the housing. The front part of the body is teardrop-shaped with an expansion corresponding to a typical ear canal and is equipped with a flexible sealing nozzle.

Despite the effective design of this solution, it is suitable for a relatively small number of potential users, especially those whose ear canal has pronounced turns.

DISCLOSURE OF INVENTION

The technical result of the claimed invention is to improve sound quality due to the optimal installation of an in-ear earphone in the ear canal of a particular user and increase the physical comfort of use.

The in-ear earphone contains a housing, including an outer part and a part that is installed when the earphone is used by the user inside the external auditory canal up to its Second Turn. The housing contains at least one electroacoustic transducer, and the part of the housing installed inside the ear canal is configured to repeat the internal shape of the ear canal when installed in the ear canal of a particular user. In this case, the electroacoustic transducers installed in this part of the housing are placed with the possibility of shifting relative to the housing when it is bent, and the wires leading to them are made flexible. In addition, the part of the housing installed inside the external auditory canal is equipped with a flexible sealing nozzle in its front part.

In particular, the part of the housing installed inside the ear canal, with the ability to repeat the internal shape of the ear canal when installed in the ear canal of a particular user, can be made of a flexible, plastic material. In addition, the part of the housing installed inside the ear canal can be made of heat-shrinkable material.

In addition, electroacoustic transducers can be additionally equipped with acoustic channels, the outputs of which are located in the front part of the housing, installed inside the ear canal, while the acoustic channels are made flexible.

In particular, electroacoustic transducers in the part of the housing installed inside the ear canal can be placed in flexible and plastic inserts.

In addition, the part of the housing installed inside the ear canal can be configured to function as a sound channel.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. Figure 1 shows a cross-sectional view of the external auditory canal.

In FIG. Figure 2 shows a typical cast of the external auditory canal.

In FIG. Figure 3 shows an in-ear earphone installed in the external auditory canal.

In FIG. Figure 4 shows a side view of the in-ear earphone before installation in the ear canal.

In FIG. Figure 5 shows the in-ear earphone in front view.

In FIG. 6 shows the flexible insert in front view.

In FIG. Figure 7 shows an in-ear earphone with one electroacoustic transducer.

In FIG. Figure 8 shows an in-ear earphone with one electroacoustic transducer installed in the front part.

In FIG. Figure 9 shows an in-ear earphone with one electroacoustic transducer installed in the middle part.

In FIG. Figure 10 shows a cross-section of an in-ear earphone with one electroacoustic transducer.

OPTIONS FOR IMPLEMENTING THE INVENTION

The main design feature of the in-ear earphone is that its part, located in the external auditory canal 1 on one side, is flexible enough to be placed up to the second turn 3 of the external auditory canal 1 (Fig. 1, Fig. 3) and be sufficiently stable in shape to penetrate the external auditory canal with its bends in three dimensions, overcoming the resistance of friction against the walls of the external auditory canal 1. In this case, when inserting an in-ear earphone, the consumer should not experience pain when the in-ear earphone overcomes the first turn 2 and the second turn 3 external auditory canal 1 and the auditory canal in places where bone tissue 5 comes close.

The in-ear earphone (Fig. 3, Fig. 4, Fig. 7 - Fig. 9) has a housing 6, consisting of a part 7 located at the entrance to the external auditory canal 1 and a part 8 located inside the said passage 1. Moreover, part 8 the housing 6 of the in-ear earphone is designed to repeat the internal shape of the ear canal when installed in the ear canal of a particular user. For this purpose, part 8 of housing 6 is made of thin-walled, flexible, plastic material, for example, rubber-like material or flexible

plastic. In addition, in order to optimize production, part 8 of the housing 6 can be made of heat-shrinkable flexible and plastic material. In particular, the front part 8 of the housing 6 can be made in a teardrop shape (Fig. 5), repeating the typical shape of the external auditory canal in the area of the Second Turn 3.

Inside the housing 6, primarily in part of the housing 8, there are several electroacoustic transducers 9 (Fig. 3 - Fig. 4). Electroacoustic transducers 9 are primarily made as balanced armature transducers from the manufacturer of the corresponding components, for example Knowles, from large to small. The use of transducers of various series, each of which operates in optimal mode, gives the resulting full-fledged sound. When other types of small-sized electroacoustic transducers appear, they can also be used in the proposed design.

In FIG. Figure 3 shows an example of an implementation when, in a flexible and plastic part of the housing 8, designed to repeat the internal shape of the ear canal 1, when installed in the ear canal of a particular user, electroacoustic transducers 9 are installed in the housing with the ability to shift relative to the housing when it is bent, which is ensured by that they are not rigidly attached to the body itself.

Another option for installing electroacoustic transducers in the housing is shown in Fig. 4 and Fig. 6 and also in FIG. 9 and Fig. 10. Each electroacoustic transducer 9 is placed in flexible inserts 12. Flexible inserts 12 are the support of one or several electroacoustic transducers 9, are made of plastic material, such as relatively soft polyethylene or silicone, and when the flexible part of the body 8 is placed in the external auditory canal 1 of the user, they bend , following the bend of the housing, while holding the electroacoustic transducer approximately in the part 8 of the housing where it was originally placed. Electroacoustic transducers 9, when there are several of them in the housing, can be equipped with acoustic channels 11, which output acoustic vibrations to the output of the in-ear earphone. In this case, the flexible inserts 12 (Fig. 6) contain

holes 15 for installing electroacoustic transducers 9 and holes 16 for passage and support of acoustic channels 11.

The wires 13 leading to the electroacoustic transducers 9 are also made flexible (Fig. 3, Fig. 8).

An in-ear earphone may also contain one electroacoustic transducer. If it is installed at the beginning of the flexible part 8 of the housing 6 (Fig. 7), then the internal space 14 of this part 8 serves as the audio channel of the earphone. The electroacoustic transducer 9 can be installed in the middle part 8 of the housing 6 (Fig. 9), or at its end (Fig. 8). In the front part 8 of the housing 6 there is a flexible sealing nozzle 10 made of silicone, which plays the role of acoustic insulation to form an acoustic chamber.

In-ear headphones are installed in the external auditory canal 1 (Fig. 3). The front part 8 of the housing 6 is located in the area of the Second Turn of the external auditory canal 1 and, thanks to the flexibility and plasticity of the front part 8 of the housing and the flexibility of the acoustic channels 11 and wires 13, takes the shape of the acoustic channel of a specific user. The teardrop-shaped and plastic shape of the front part 8 of the housing (Fig. 5) not only helps to ensure increased comfort for installing headphones, but also, with the help of a flexible sealing nozzle 10, helps ensure sufficiently stable acoustic isolation of the sound volume in front of the eardrum 4, as well as correct in relation to it, the orientation of the front part of the earphone body 8.

This design of headphones ensures the deepest possible “fit” in the external auditory canal, while electroacoustic transducers sound the minimum volume of air in front of the eardrum 4.

INDUSTRIAL APPLICABILITY

This headphone design provides, on the one hand, high listening quality, volume, clarity and richness of sound, and on the other hand, increased physical comfort of use.

In-ear headphones can be produced industrially.

Claims (5)

1. An in-ear earphone containing a housing, including an outer part and a part that is installed when the earphone is used by the user inside the external auditory canal up to its second turn; electroacoustic transducers are located in the housing and a part of the housing installed inside the ear canal is made with the ability to repeat the internal shape of the auditory canal passage when installing it in the ear canal of a particular user, while the electroacoustic transducers installed in this part of the housing are placed with the possibility of shifting relative to the housing when it is bent, and the wires leading to them are made flexible, in addition, a part of the housing is installed inside the external auditory canal , in its front part is equipped with a flexible sealing nozzle, while the electroacoustic transducers are equipped with acoustic channels, the outputs of which are located in the front part of the housing, installed inside the ear canal, and the acoustic channels are made flexible. 2. An in-ear earphone according to claim 1, characterized in that the part of the housing installed inside the ear canal, with the ability to repeat the internal shape of the ear canal when installed in the ear canal of a particular user, is made of flexible, plastic material. 3. In-ear earphone according to claim 2, characterized in that the part of the housing installed inside the ear canal is made of heat-shrinkable material. 4. In-ear earphone according to claim 1, characterized in that the electroacoustic transducers in the part of the body installed inside the ear canal are placed in flexible and plastic inserts. 5. In-ear earphone according to claim 1, characterized in that the part of the housing installed inside the ear canal is configured to perform the function of an audio channel.