JP2017092630A - Step-flow-type horn - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a horn for improving the sound quality by preventing a horn specific vibration sound of a horn type speaker from being generated.SOLUTION: A passage 31 leads sound waves. An area of an opening 37 is larger than that of the opening 32. Step parts 33a to 33f are arranged at a predetermined interval along the direction from the opening 32 toward the opening 37. Connection parts 35a to 35e connect between the step parts 33a to 33f. The cross-sectional area of the passage 31 continuously changes in the connection parts 35a to 35e, discontinuously changes in the step parts 33a to 33f and is larger on the opening 37 side than that on the opening 32 side.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a horn used for a speaker or the like.

The speaker converts an electrical signal into sound. The mainstream speaker includes, for example, a cone type and a horn type. In the cone type speaker, sound waves are directly diffused and radiated from a cone type diaphragm. On the other hand, a horn type speaker collects a small-amplitude sound wave radiated from a diaphragm with a relatively small drager unit by a phase converter, and the horn expands and radiates it.
The horn type speaker includes, for example, a combination type in which a driver unit and a horn are directly connected, and a separate type having a throat that connects the driver unit and the horn. The combination type is often used for horn type speakers for high sounds, and the separate type is often used for horn type speakers for medium and high sounds.
Since the horn type speaker expands the sound wave generated by the driver unit with the horn, the amplitude of the sound wave generated by the driver unit may be small. As a result, distortion generated by the diaphragm of the driver unit and the like can be greatly reduced, and the expression of the speed feeling is high with high transit characteristics, light generation of sound. The cone type has a heavy burden caused by forcibly driving the diaphragm to obtain a predetermined sound pressure, whereas the horn type does not have such a heavy burden and produces a sound close to the original sound in nature. be able to.
Because of these advantages, horn type speakers are used in many audio systems. It is also widely used as a loudspeaker in large halls and event venues.

JP 2006-340140 A

A horn type speaker generates a vibration sound peculiar to a horn (so-called “squeal”) due to the sound pressure on the inner surface. In addition, the sound quality may be contaminated, for example, a reflected sound is generated due to reflection on the inner surface, and a sound wave is delayed.
An object of the present invention is to solve such problems and improve sound quality, for example.

The horn according to the present invention includes a passage for guiding sound waves, and the passage includes a first opening, a second opening having a larger area than the first opening, and the second opening from the first opening. A plurality of step portions arranged at a predetermined interval along a direction toward the opening, and a connection portion that connects between the plurality of step portions, and the cross-sectional area of the passage includes the connection portion , Continuously changing, discontinuously changing in the stepped portion, and being larger on the second opening side than on the first opening side.
The interval between the step portions is preferably 17 mm or more and 68 mm or less.
The height of the stepped portion is preferably 1.7 mm or more and 13.6 mm or less.
The cross-sectional area of the passage on the first opening side of the stepped portion is preferably a theoretical value of the passage.
The speaker according to the present invention includes the horn and a driver unit that is disposed on the first opening side of the horn and generates a sound wave that passes through the horn.
A throat for connecting between the driver unit and the horn; the throat includes a path for guiding a sound wave generated by the driver unit and transmitting the sound wave to the horn; and the throat path is a path of the throat It is preferable to have a step portion in which the cross-sectional area changes discontinuously.
The passage of the throat preferably has an opening connected to the first opening of the horn that is slightly smaller than the first opening of the horn.

According to the horn of the present invention, it is possible to suppress the influence of reflection on the wall surface of the passage, to reduce sound contamination, and to improve sound quality.
If the horn is adopted as a speaker, it is possible to obtain a sound quality close to that of the natural world.
If a similar step portion is provided in the throat or at the boundary between the throat and the horn, the effect can be further enhanced.

FIG. 3 is a front view showing the horn type speaker according to the first embodiment. II-II sectional drawing which shows the horn type speaker of Embodiment 1. FIG. FIG. 3 is an III-III end view showing the horn type speaker of the first embodiment. The figure which shows the cross-sectional area of a channel | path. The front view which shows the horn type speaker of Embodiment 2. FIG. VI-VI sectional drawing which shows the horn type speaker of Embodiment 2. FIG. VII-VII sectional drawing which shows the horn type speaker of Embodiment 2. FIG.

(Embodiment 1)
The horn type speaker 10 shown in FIGS. 1 to 3 has the following configuration.
<Driver unit 11>: An electric signal is converted into a sound wave. For example, a diaphragm (not shown) and a phase converter (not shown) are incorporated, and a driver inputs an electric signal to drive the diaphragm, thereby emitting sound waves in the F direction.
<Throat 12>: Connects between the driver unit 11 and the horn 13. A passage 21 is provided inside. The passage 21 has two openings 22 and 27 and penetrates the throat 12 in the FB direction. The opening 22 is circular, for example, is on the B side of the throat 12 and is connected to the driver unit 11. The opening 27 is, for example, a square, is on the F side of the throat 12, and is connected to the horn 13. The sound wave generated by the driver unit 11 enters the passage 21 through the opening 22, is guided by the passage 21, exits from the opening 27, and is transmitted to the horn 13.
<Horn 13>: The sound wave generated by the driver unit 11 is enlarged and radiated to the outside. A passage 31 is provided inside. The passage 31 has two openings 32 and 37 and passes through the horn 13 in the FB direction. The opening 32 is, for example, a square that is slightly larger than the opening 27 of the throat 12, is on the B side of the horn 13, and is connected to the throat 12. The opening 37 is on the F side of the horn 13 and is released to the outside. The area of the opening 37 is larger than the area of the opening 32. The sound wave generated by the driver unit 11 enters the passage 31 from the opening 32, is guided by the passage 31, and is radiated to the outside from the opening 37.

As shown in FIGS. 2 and 3, a plurality of step portions 33 a to 33 f are provided inside the passage 31. Each step part 33a-33f is provided in the position where the distance from a sound source is constant over the perimeter along the inner surface of the channel | path 31. As shown in FIG. The same constant interval is provided between the opening 32 and the step B 33 on the most B side, between adjacent steps, and between the step F on the most F side and the opening 37. ing. This interval is determined based on the speed of sound (340 m / s [meter per second]). According to the experiment, the effect of improving the sound quality is high when it is 17 mm [millimeter] or more and 68 mm or less, and the effect is the highest when it is 34 mm.
A connection portion 34 connects the opening 32 and the stepped portion 33a on the most B side. Adjacent steps are connected by connecting portions 35a to 35e. The step portion 33 f on the most F side and the opening 37 are connected by a connecting portion 36.

Similar to the passage 31 of the horn 13, a stepped portion 23 is also provided inside the passage 21 of the throat 12. The step part 23 may be not only one but plural. The step portion of the horn 13 is provided between the opening 22 and the step portion 23 and between the step portion 23 and the opening 27 (in the case where there are a plurality of step portions 23, the step portion 23 includes the adjacent step portions 23). The same fixed interval is provided.
Further, since the opening 32 of the horn 13 is slightly larger than the opening 27 of the throat 12, a step portion similar to the inside of the passages 21 and 31 is formed at the connection portion between the throat 12 and the horn 13.

As shown in FIG. 4, the cross-sectional area S of the passage 31 changes discontinuously (or abruptly) at each of the step portions 33 a to 33 f, and other portions (that is, the connection portions 34, 35 a to 35 e and 36). ) Continuously (or smoothly). As a result, diffuse reflection is promoted and radiation is dispersed, so that sound contamination is reduced.
The sectional area on the F side (opening 37 side) of each stepped portion 33a to 33f (that is, the area of the portion surrounded by the boundary line 332 between the stepped portion and the connecting portion adjacent to the F side) is the B side ( It is larger than the cross-sectional area at the side of the opening 32 (that is, the area of the portion surrounded by the boundary line 331 between the step portion and the connection portion adjacent to the B side).

According to experiments, when the width of each of the step portions 33a to 33f (that is, the interval between the boundary lines 331 and 332) is 1.7 mm or more and 13.6 mm or less, the effect is high. Becomes sharper, and conversely, the larger the width, the softer the tone.
The width of each step portion 33a to 33f may be different for each step portion. For example, the width of the stepped portion may be reduced (for example, about 5 mm) in the range close to the opening 32, and the width of the stepped portion may be increased (for example, about 7 mm) in the range close to the opening 37.
Further, there may be a portion having a different width in one step portion. For example, in the UD direction where the width of the passage 31 is narrow, the width of the step portion is reduced (for example, about 3 mm), and in the LR direction where the width of the passage 31 is wide, the width of the step portion is increased (for example, about 7 mm). May be.
The same applies to the step portion 23 and the step portion formed at the boundary portion between the throat 12 and the horn 13 due to the difference in size between the opening 27 and the opening 32.

The cross-sectional area of each step 33a to 33f on the B side (inner circumferential line) is equal to the theoretical value of the horn. For example, in the case of an exponential horn (exponential horn or exponential horn), the theoretical value of the cross-sectional area S is S ₀ · exp (m · x). However, S ₀ is the incident area of the sound wave at the opening 32. exp is an exponential function with the base of the natural logarithm (Napier number) as the base. x is the distance from the opening 32. m is a flare constant, and m = 4π · f _c / c. π is the circumference ratio. f _c is the cut-off frequency. c represents the speed of sound.
Since the opening 27 of the throat 12 is slightly smaller than the opening 32 of the horn 13, the sound wave incident area S ₀ in the opening 32 is not the area of the opening 32 but the area of the opening 27.
The theoretical value may be a theoretical value of another horn such as a hyperbolic horn (a hyperbolic horn or a hyperbolic function horn).

On the other hand, the cross-sectional area of the passage 31 in the other part is larger than the theoretical value.
For this reason, each connection part 34,35a-35e, and 36 inclines inside rather than the case of a theoretical value. As a result, the traveling direction of the sound wave reflected by the connecting portions 34, 35a to 35h and 36 is shifted, the influence of the reflection is reduced, and the dirt of the sound is reduced. Further, by reducing the cross-sectional area, the speed of sound can be increased and the delay of sound waves can be eliminated.

Since the passage 31 of the horn 13 has such a shape, reflection and radiation are improved, and due to the synergistic effect, the high range is extended and the mid and low range is tightened. As a result, the sound image becomes clear, the sound rises and falls quickly, and the sound quality has a good tempo. In addition, the contact near the horn wall surface is improved, the directivity is improved, the sound quality is smoothed, and the void in stereo is improved. Thereby, the sound quality close | similar to the sound of nature can be acquired as a whole.
Not only the passage 31 of the horn 13 but also the passage 21 of the throat 12 has the same shape, so that the effect can be further enhanced.

(Embodiment 2)
A horn type speaker 10A shown in FIGS. 5 to 7 includes a driver unit 11, a throat 12, and a horn 13A.
The driver unit 11 and the throat 12 are the same as the horn type speaker 10 of the first embodiment.
In the horn 13A, the shape of the opening 37 is a planar shape perpendicular to the FR direction. Similarly, the step portions 33a to 33d are also planar shapes perpendicular to the FR direction. The rest is the same as the horn 13 of the first embodiment.

  Even when the horn 13A has such a shape, the same effects as those of the first embodiment can be obtained.

The embodiment described above is an example for facilitating understanding of the present invention. The invention is not limited thereto, but includes various modifications, changes, additions or removals without departing from the scope defined by the appended claims. This can be easily understood by those skilled in the art from the above description.
For example, the horn according to the present invention can be applied not only to an audio reproduction system but also to a megaphone or a hand microphone.

  10, 10A horn type speaker, 11 driver unit, 12 throat, 21, 31 passage, 22, 27, 32, 37 opening, 23, 33a to 33f stepped portion, 24, 26, 34, 35a to 35e, 36 connecting portion, 13, 13A Horn, 331, 332 Borderline, S cross-sectional area.

Claims (7)

With a passage that guides sound waves,
The passage is
A first opening;
A second opening having a larger area than the first opening;
A plurality of step portions arranged at predetermined intervals along a direction from the first opening toward the second opening;
A connecting portion for connecting the plurality of steps;
Have
The cross-sectional area of the passage is
In the connection part, it changes continuously,
The step changes discontinuously and is larger on the second opening side than on the first opening side,
Horn. The interval between the stepped portions is not less than 17 mm and not more than 68 mm.
The horn of claim 1. The height of the step is 1.7 mm or more and 13.6 mm or less.
The horn according to claim 1 or 2. The cross-sectional area of the passage on the first opening side of the step is a theoretical value of the passage.
The horn according to any one of claims 1 to 3. A horn according to any one of claims 1 to 4,
A driver unit that is disposed on the first opening side of the horn and generates a sound wave that passes through the horn;
With a speaker. Comprising a throat connecting between the driver unit and the horn;
The throat is
A path for guiding sound waves generated by the driver unit and transmitting the sound waves to the horn;
The passage of the throat
Having a step portion in which a cross-sectional area of the passage of the throat changes discontinuously,
The speaker according to claim 5. The passage of the throat
Having an opening connected to the first opening of the horn, slightly smaller than the first opening of the horn,
The speaker according to claim 6.

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