WO2001052592A2

WO2001052592A2 - Headphones

Info

Publication number: WO2001052592A2
Application number: PCT/EP2001/000286
Authority: WO
Inventors: Begeré OLIVER
Original assignee: Oliver Begere
Priority date: 2000-01-11
Filing date: 2001-01-11
Publication date: 2001-07-19
Also published as: DE10000666A1; WO2001052592A3

Abstract

The invention relates to a set of headphones which is provided for exposing at least one ear (20) to sound and which is equipped with an electroacoustic transducer (22) having a sound propagation center axis (26) and equipped with a holding device (11) for holding the transducer (22). The holding device (11) holds the transducer (22) in such a manner that the sound propagation center axis (26) thereof is oriented with a horizontal angle (α) ranging from 30° to 60° toward the ear in a manner that is ventrally inclined with regard to a median plane. In addition, the holding device can be adjusted in such a manner that a free space (23) is formed between the transducer (22) and the ear (20). This prevents sound emitted by the transducer from directly entering the auditory canal of the ear so that a spatial sound effect is produced.

Description

headphone

The invention relates to headphones with an electroacoustic transducer.

The human auricle has a sound-shaping property, which results from splitting the incoming sound into two sound paths of different lengths within the auricle. Depending on the sound angle of incidence, the incoming sound signal is also deformed with respect to its amplitude. The size of the running time difference and the type and size of the deformation of the sound signal change depending on both the horizontal and the vertical angle of the incident sound. The deformed scallops reached through the auditory canal and the auditory canal to the inner ear and are finally analyzed in the auditory center for their spatial information. In conventional headphones, either the ear cup of a hearing person is irradiated over a large area with an electromagnetic transducer arranged near the ear cup, or the auditory canal entrance is sounded with a button-type earphone arranged on or in the auditory canal entrance. It is common to both earphone types that the sound-shaping property of the auricle does not or only to a minor extent. While the sound is introduced directly into the ear canal entrance in the case of the button-like earphones, the sound is emitted simultaneously from all angles of the ear from all angles of the ear in the case of a near-ear and relatively large-area sound generation. As a result, the position of the sound source seems to be right next to the ear or even in the head for the hearing person. In order to create a better spatial listening experience, methods for changing the sound signal accordingly are known. Here, the sound signal is changed by digital signal processing in the same way that it came from the distant sound source through the auricle. This process requires the digitization of the sound signal, its digital processing and the subsequent analogization. This process is therefore cumbersome and time-consuming.

The object of the invention is to provide a headphone that enables improved spatial hearing.

This object is achieved according to the invention with the features of claim 1.

The headphones according to the invention have a holding device which holds the electromagnetic transducer in such a way that its central axis of sound propagation is inclined ventrally at a horizontal angle of 30 ° -60 ° to a median plane of the headphones or the head is directed towards the ear. The holding device is adjustable or flexible in such a way that a free space is formed between the transducer and the ear. The transducer is therefore not placed directly on the ear by the holding device, but is held at a fixed minimum distance from the ear. For this purpose, the holding device can have a spacer, which is supported on the relevant side of the head in the vicinity of the relevant ear. The spacer can also be inserted in the form of a sound-permeable spacer between the transducer and the ear in the free space. Such a spacer consists, for example, of an almost completely sound-permeable plastic compound. The present headphones are so-called open headphones. The two measures, namely the provision of an acoustically free space between the electroacoustic transducer and the ear and the horizontal inclination of the transducer to the front, ensure that the sound emitted by the transducer cannot enter the ear canal directly, but in front of it Entry into the ear canal opening is first deformed in the auricle. By providing a free space and arranging the transducer beforehand, the sound waves laterally reflected from the outside of the auricle and the noises generated by blood flow in the ear can spread freely and are not reflected back onto the auricle by the transducer. This avoids further distortion of sound. Due to the spaced arrangement of the transducer, the auricle is no longer voilflachiα from a large spectrum of incidence angles, but only from a small-angle preferred direction. The sound emitted by the transducer thus reaches the pinna like d. it also principally for those coming from a more distant sound source Sound is the case. The headphones thus produce a sound image that is similar to that of a sound source further away. The sound striking the auricle is changed by the auricle in the same way as is the case for sound from a distant sound source. The sound that is changed accordingly by the auricle finally reaches the auditory canal and is finally perceived by the hearing apparatus and hearing center as a sound source that is located in front of the head of the hearing person.

The headphones preferably have a sound guide tube which adjoins the electroacoustic transducer and whose central longitudinal axis is approximately aligned with and with the sound propagation center axis of the transducer. The sound emitted by the transducer is channeled and concentrated in a single preferred direction by the sound guide tube directly connected to the transducer. The sound channeled and bundled in this way is directed at a horizontal angle of 30 ° - 60 ° from the front towards the ear of the hearing person. The sound emitted by the transducer therefore only hits the auricle from a preferred direction. The sound emitted by the transducer and directed through the sound guide tube reaches the auricle, as would be the case for the sound coming from a further distant sound source. The headphones therefore produce a sound image that corresponds approximately to that of a sound source further away. The directional sound hitting the auricle is changed by the auricle in the same way that αics would apply to the sound from a more distant sound source. The sound changed in this way through the auricle finally reaches the auditory canal and is perceived by the hearing apparatus and hearing center approximately as if it were in front of the head of the hearing person located sound source. The sound guide tube is aligned approximately with the earpiece of the hearing person.

The sound guide tube is preferably cylindrical. As tests have shown, the desired acoustic effect is achieved particularly well with a cylindrical sound guide tube which is placed directly on the transducer. In this way, a good concentration and alignment of the sound emitted by the transducer is achieved.

According to a preferred embodiment, the sound propagation center axis of the transducer or the sound guide tube is inclined at a horizontal angle of approximately 45 ° to the median plane of the headphones or the head. The arrangement of the transducer or the sound guide tube in approximately 45 ° produces a good spatial sound impression, as tests have shown.

The sound guide tube is preferably circular in cross section, but can also be elliptical or shaped differently.

The medial opening of the sound guide tube is preferably inclined at a horizontal angle of approximately 30 ° to the median plane. The medial sound guide tube opening is thus inclined at approximately the same angle as the ear cup protruding from the head is inclined to the median plane. The plane αei sound tube opening is therefore roughly parallel to the base plane of the auricle. In this way, the free space between the sound guide tube and the auricle is approximately the same at every point. The sound emerging from the sound guide tube has one at every point cover approximately the same distance until they hit the pinna. This creates a natural spatial sound image.

The sound propagation center axis of the transducer or the central longitudinal axis of the sound guide tube is preferably inclined with a vertical angle of at most 20 ° to a transverse plane of the headphones or the head. This means that the sound guide tube or the transducer is only slightly inclined upwards or downwards towards the auricle. The sound source seems to be at the front for the hearing person, but not at the top or bottom.

According to a preferred embodiment, a vertical slot is provided in the area of the sound guide tube on the transducer side. The converter, e.g. B. a circular speaker, for example, is only directly connected to the sound guide tube with its half circumference. The second half of the transducer circumference is separated from the sound guide tube by a slot. As tests have shown, this results in a particularly good sound.

A perforated screen is preferably provided in the medial region of the sound guide tube. The aperture of the pinhole can have a diameter of 1/4 to 1/2 of the inside diameter of the sound guide tube. As a result, the sound generated by the transducer and finally emerging from the medial opening of the sound guide tube is bundled. As a result, the spatial character of the au. ^L the sound of the sound coming out of the pipe is improved.

According to a preferred embodiment, the inside of the sound guide ring is provided with a sound-damping coating lined. The sound-damping coating reduces reflections of the sound on the inside of the sound guide pipe, so that essentially only axially propagating sound waves reach the pipe opening. This also improves the spatial impression of the sound heard by a person.

The converter rear side is preferably designed to be open, so that the membrane of the converter can move freely and largely without damping.

According to a preferred embodiment, the holding device is adjustable in such a way that the central sound propagation axis of the transducer or the central longitudinal axis of the sound guide tube leads 5 - 60 mm above the auditory canal entrance to a region of the upper anthelix of the ear. The holding device can also be adjustable such that the vertical and / or the horizontal angle to the median plane is also adjustable. In this way, the central longitudinal axis of the sound guide tube can be aligned precisely with the area of the upper anthelix of the ear, which, as tests have shown, results in a very good spatial hearing pressure of the hearing person.

A transducer with a sound guide tube is preferably provided on the holding device with mirror symmetry to the median plane, so that it is a stereo headphone.

An exemplary embodiment of the headphones according to the invention is explained in more detail below with reference to the figures. Show it :

1 is a top view of a headphone according to the invention,

2 the headphones of FIG. 1 in a side view from the right side of the body,

Fig. 3, the headphones of Fig. 1 with a longitudinally cut sound guide tube, and

Fig. 4 shows a human ear in a detailed representation.

In Figs. 1 and 2, a headphone 10 is shown, which essentially consists of a headband 12, two side brackets 14, 14 'attached to it laterally and two earphones 16, 16' each attached to the earpiece holders 14, 14 '. A holding device 11 is formed by the headband 12 and the two hearing holders 14, 14 '. The headband 12 is firmly seated on the head 18 of a hearing person who has an ear 20, 20 'on both sides of the head 18. The two earphone holders 14, 14 'are designed as flexible, thin tubes, for example in the form of so-called goosenecks, which means that the earphones 16, 16' in height, at a distance and in all three spatial axes define their angle to the ears 20, 20 'to a certain extent Limits are adjustable.

Each receiver 16, 16 'essentially consists of an electroacoustic transducer 22, 22', which is fastened to an acoustic control tube 2, 24 '. The center axis of the sound arrangement (26, 26 ') of the transducer 22, 22' is axially adjacent to or aligned with a central axis 26, 26 'of the transducer 22, 22', that is, it is identical. The central longitudinal axis 26, 26 'is in each case at a horizontal angle α of approximately 45 ° to one Median plane 28, 28 'of head 18 or headphone 10 is inclined forward.

The transducer 22 and the cylindrical sound guide tube 24 are circular in cross section and have a constant inner diameter of approximately 5.0 cm. The sound guide tube 24, 24 'consists of a thin-walled cylinder tube 30 made of GRP or CFRP plastic. The sound guide tube 24 is completely coated on its inside with a sound-damping coating. The length of the tube is approximately 6.0 cm.

The medial opening 34 of the sound guide tube 24 is inclined at a horizontal angle β of approximately 30 ° to the median plane 28 ″. It therefore has approximately the same horizontal inclination to the median plane 28 ″ as the auricle 21 of the ear 20.

At the transducer end of the sound guide tube 24, 24 ', a vertical slot 36 is provided, which extends over approximately 180 °. The vertical slot 36 has an axial length of a few millimeters and allows sound waves to exit the sound guide tube 24.

A perforated diaphragm 38 is arranged in the medial area of the sound guide tube 24, the opening diameter of the diaphragm opening 40 being approximately 1/3 of the inner diameter of the sound guide tube 24.

The back of the converter 22 is open.

As shown in FIG. 2, the central longitudinal axis 26 of the sound guide tube 24 is approximately parallel to a transverse plane of the headphones 10 or the head 18, but can also be inclined at a vertical angle of up to 20 ° upwards or downwards to the transverse plane of the headphones 10. The holding device 11 and in particular the earphone holder 14, 14 ′ are adjusted when the headphone 10 is on so that the central longitudinal axis 26 of the sound guide tube 24 is approximately 20 mm high h above the auditory canal entrance 46. Ideally, the central longitudinal axis 26 of the sound guide tube 24 should be directed towards the upper area of the Anthelix 48.

The sound guide tube opening 34 is arranged with a free space 23 of approximately 0.5-2 cm apart from the respective ear 20, 20 '.

The sound coming from the transducer 22 and arriving at the ear 20 is divided in the upper region of the Anthelix 48 and runs on the one hand along the lower flank of the Anthelix 48 to the concha 50 through the auditory canal entrance 46 into the auditory canal 52, and on the other hand through the brim-like trained helix 54 back into the concha 50 and finally through the auditory canal entrance 46 into the auditory canal 52. The difference in transit time of the two signal paths shown is approximately 0.2 ms. The most pronounced deformation of an occurring sound signal appears at a horizontal angle of the incident sound of approximately 45 ° to the median plane 28, as in the present headphone 10.

In particular, because listening to multi-channel, for example stereophonic sound signal sources, the Hor result is very spatially pronounced, in terms of a spatial depth as well as the width of the horpan panorama. The entire horpanorama is completely eoen, and is clearly in front of the hearing. Person. In particular, di.es applies to monaural sound sources, which also appear to be clearly in front of the hearing person when they are aimed at both ears at the same time.

A further improvement in the spatiality of the sound image can be achieved by partially closing the opening 34 of the sound guide tube 24. Here, the area of the concha 50 of the ear 20 is shadowed against sound emerging directly from the sound tube 24. A further improvement can possibly be achieved in that the dorsal edge at the opening 34 of the sound guide tube 24 is bent medially inward by approximately 45 °.

Claims

Expectations

1. headphones for sound reinforcement at least one ear (20), with

an electroacoustic transducer (22) with a sound propagation central axis (26), and

a holding device (11) for holding the transducer (22)

characterized

that the holding device (11) holds the transducer (22) in such a way that its central sound propagation axis (26) is directed ventrally inclined at a horizontal angle (α) of 30 ° -60 ° to a median plane (28 ') towards the ear (20), and

that the holding device (11) is adjustable in such a way that a free space (23) is formed between the transducer (22) and the ear (20).

2. Headphones according to claim 1, characterized in that connected to the transducer (22) is a sound guide tube (24) with a central longitudinal axis (26) which is aligned with the central sound propagation axis (26) of the transducer (22), the free space ( 23) is formed between the sound guide tube (24) and the ear (20).

3. Headphones according to claim 2, characterized in that the sound guide tube '24) is cylindrical.

4. Headphones according to one of claims 1 - 3, characterized in that the sound transmission center axis (26) of the transducer (22) is inclined at a horizontal angle (α) of approximately 45 ° to the median plane (28 ').

5. Headphones according to one of claims 2-4, characterized in that the medial opening (34) of the sound guide tube (24) is inclined at a horizontal angle (β) of approximately 30 ° to the median plane (28 '').

6. Headphones according to one of claims 1-5, characterized in that the sound propagation center axis (26) of the transducer (22) is inclined with a vertical angle of at most 20 ° to a transverse plane of the headphones.

7. Headphones according to one of claims 2-6, characterized in that a vertical slot (36) is provided in the transducer-side region of the sound guide tube (24).

8. Headphones according to one of claims 2-7, characterized in that a pinhole (38) is provided in the medial region of the sound guide tube (24).

9. Headphones according to claim 8, characterized in that the opening diameter of the pinhole (38) is approximately 1/4 to 1/2 of the inner diameter of the sound guide tube (24).

10. Headphones according to one of claims 2-9, characterized in that the inside of the sound guide ronres (24) is lined with a sound-absorbing coating (32).

11. Headphones according to one of claims 1-10, characterized in that the back of the transducer (22) is designed to be open.

12. Headphones according to one of claims 1-11, characterized in that the holding device (11) is adjustable such that the sound propagation center axis

(26) of the transducer (22) leads to an area 5 - 60 mm above the ear canal entrance (46) to an upper area of the anthelix (48) of the ear (20).

13. Headphones according to one of claims 1-12, characterized in that on the holding device (11) two transducers (22, 22 '), each with a sound guide tube (24, 24') are provided mirror-symmetrically to the median plane.

14. Headphones according to one of claims 1-13, characterized in that the free space (23) in the direction of the sound propagation center axis (26) is at least 10 mm long.