The present application claims priority from Japanese Patent Application No. 2018-057203, which was filed on Mar. 23, 2018, the disclosure of which is herein incorporated by reference in its entirety.
The following disclosure relates to a bass reflex port and a bass reflex type speaker.
A bass reflex type speaker is mainly applied to a subwoofer. Recently, there is desired a subwoofer capable of providing high output. However, when the output of the subwoofer is increased, a flow rate of the air that flows inside and outside a housing via a bass reflex port is increased, so that extraneous (or abnormal) noise is easily generated. Therefore, measures for reducing generation of extraneous noise have been required. There is conventionally proposed a measure for reducing generation of extraneous noise in which an end portion of a bass reflex port has a flare shape. For instance, Japanese Patent Application Publication No. 2016-27730 discloses such a measure.
The technique described above has some effects of reducing extraneous noise. However, there still remains a problem that extraneous noise is generated from the bass reflex port when levels of input signals supplied to a speaker unit are increased, even where end portions of the bass reflex port near opposite ends thereof are formed to have a flare shape.
Accordingly, an aspect of the disclosure is directed to a technique of reducing extraneous noise generated from a bass reflex port, even where levels of input signals are high.
In one aspect of the disclosure, a bass reflex port includes: a tubular body portion; and a surface forming portion which is board-like, and continuous to an inner wall of the tubular body portion and which has a surface extending radially outwardly from an opening end of the tubular body portion disposed in a housing of a speaker, wherein the surface forming portion extends linearly in a direction away from a tube axis of the tubular body portion in a cross section parallel to the tube axis.
In another aspect of the disclosure, a bass reflex type speaker including a bass reflex port includes: a housing of the speaker; a tubular body portion; and a surface forming portion which is board-like, and continuous to an inner wall of the tubular body portion and which has a surface extending radially outwardly from an opening end of the tubular body portion disposed in the housing of the speaker, wherein the surface forming portion extends linearly in a direction away from a tube axis of the tubular body portion in a cross section parallel to the tube axis.
In the bass reflex port constructed as described above, the air that flows between a space inside the housing of the speaker and a space outside thereof is guided by the inner wall of the tubular body portion and the surface of the surface forming portion, so that separation of the air flow is not likely to occur in the vicinity of the opening end of the tubular body portion disposed in the housing. Accordingly, it is possible to decrease air turbulence in the bass reflex port and accordingly reduce extraneous noise.
The above and other objects, features, advantages and technical and industrial significance of the disclosure will be better understood by reading the following detailed description of embodiments of the disclosure, when considered in connection with the accompanying drawings, in which:
There will be hereinafter explained embodiments of the disclosure with reference to the drawings.
The housing 10 is a rectangular parallelepiped constituted by six panels. In one of the six panels of the housing 10, namely, in a front panel that functions as a baffle panel, the speaker unit SP is disposed.
The bass reflex port 20 is a hollow tubular body portion having a substantially cylindrical shape. The bass reflex port 20 is sectioned into: a straight portion 22 whose cross-sectional area (i.e., an area of a cross section of a space enclosed with an inner wall of the bass reflex port 20 in a direction perpendicular to the center axis ax) is constant in a direction in which the center axis ax extends; and flare portions 24, 25 that function as inlets and outlets (openings) of the air at opposite ends of the straight portion 22. The flare portion 24 has a shape whose cross-sectional area gradually increases from the proximity of a boundary between the straight portion 22 and the flare portion 24 toward an opening end 28. The opening end 28 of the flare portion 24 is located at an upper surface of the housing 10 and forms an opening portion on the upper surface of the housing 10. The flare portion 25 has a flare shape whose cross-sectional area gradually increases from the proximity of a boundary between the straight portion 22 and the flare portion 25 toward an opening end 29. The opening end 29 of the flare portion 25 is located inside the housing 10. The opening end 29 is the inlet and outlet of the bass reflex port 20 inside the housing 10.
The present embodiment adopts the first structure shown in
Furthermore, in the present embodiment, in addition to the above first measure, the second structure is adopted for the purpose of taking the second measure for preventing generation of extraneous noise. In the present embodiment, as shown in
In the structure shown in
In the present embodiment, the distance h between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 is determined so as not to cause a discontinuous change in a cross-sectional area of the air-flow passage. Specifically, the distance h is determined as follows. In an instance where the distance between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 is defined as h and a distance from the center axis ax of the bass reflex port 20 to a cross section of the air flow is defined as r, a cross-sectional area S2 (as one example of a cross-sectional area of an air-flow passage between an inside housing first surface and an inside housing second surface at the opening end 29 of a flare portion) of the air flow that radially moves in the space between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 is 2πrh, i.e., S2=2πrh, which means that the cross-sectional area S2 becomes greater in proportion to the distance r from the center axis ax of the bass reflex port 20 to the cross section of the air flow. In an instance where the opening end 29 has a circular shape with a radius r0 (as one example of an instance where a cross section of an air-flow passage in a direction perpendicular to a tube axis of a tubular body portion has a circular shape with a radius r0), the distance h between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 is determined to be r0/2. By thus determining the distance h, a cross-sectional area S (as one example of a perpendicular cross-sectional area of an air-flow passage at the opening end 29 of the flare portion 25, in a direction perpendicular to a tube axis) of an air-flow passage in the flare portion 25 at the opening end 29 is πr02, and the cross-sectional area S2 of the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 at the opening end 29 is 2πr0h=2πr0(r0/2)=πr02. Thus, the cross-sectional area S2 and the cross-sectional area S are equal to each other. Accordingly, when the air flow moves from the bass reflex port 20 to the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40, there is not caused a discontinuous change in the cross-sectional areas of the air-flow passages. Depending upon various conditions such as a shape of the flare portion 25 and so forth, the cross-sectional area S2 of the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 at the opening end 29 may coincide with a cross-sectional area S1 of an air-flow passage inside the straight portion 22 (as one example of a perpendicular cross-sectional area of an air-flow passage in a straight portion in a direction perpendicular to a tube axis), instead of the cross-sectional area S of the air-flow passage inside the flare portion 25 at the opening end 29. Alternatively, the cross-sectional area S2 of the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 at the opening end 29 may coincide with the cross-sectional area S of the air-flow passage in the flare portion 25 at a position near the opening end 29. It is idealistically preferable to determine the cross-sectional area S2 of the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 at the opening end 29 as described above. As long as there is maintained such a relationship that discontinuity in the cross-sectional area of the air-flow passage is relatively small, it is possible to prevent generation of extraneous noise. Specifically, generation of extraneous noise is effectively prevented by setting the cross-sectional area S2 of the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 at the opening end 29 so as to fall within a range from about one time the cross-sectional area S1 of the air-flow passage in the straight portion 22 to about 2.5 times the cross-sectional area S of the air-flow passage in the flare portion 25 at the opening end 29.
Respective planar shapes of the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 may be any arbitrary ones.
In the first example shown in
In the above-described structure, when a vibration plate of the speaker unit SP is vibrated, vibration of a pressure in the inside of the housing 10 is generated by the vibration of the vibration plate. When the inside of the housing 10 is highly pressurized, there is generated an air flow that flows from the inside of the housing 10 to an outside of the housing 10 via the air-flow passage between the inner wall surface 32 of the guiding portion 30 and the opposed surface 42 of the wall 40 and the bass reflex port 20. On the other hand, when the pressure in the housing 10 is lowered, there is generated an air flow that flows from the outside of the housing 10 to the inside of the housing 10 via the bass reflex port 20 and the air-flow passage between the wall 40 and the guiding portion 30. At this time, the bass reflex port 20 and the housing 10 function as a Helmholtz resonator having a resonance frequency in the neighborhood of the lowest frequency in a flat sound pressure band in output characteristics of the bass reflex type speaker 101.
In the above-described bass reflex type speaker 101, in a section from the inside of the bass reflex port 20 to the air-flow passage between the guiding portion 30 and the wall 40, the air flow is guided by the inner wall surface 32 of the guiding portion 30, and the cross-sectional areas of the air-flow passages are not rapidly changed. Accordingly, while the bass reflex port 20 and the housing 10 function as the Helmholtz resonator, the air flow is guided by an inner wall of the bass reflex port 20 and the inner wall surface 32 of the guiding portion 30, so that the air flow is unlikely to be separated. Further, since a large adverse pressure gradient is not generated in an air-flow passage which is constituted by the air-flow passage inside the bass reflex port 20 and the air-flow passage between the guiding portion 30 and the wall 40, extraneous noise due to separation of the air flow can be reduced. In the bass reflex type speaker 101, the air flow that flows from the bass reflex port 20 to the space between the guiding portion 30 and the wall 40 moves radially such that the cross-sectional area of the air flow gradually increases, and flows out to the inside of the housing 10. On the other hand, discharge of the air flow from the inside of the housing to the outside of the housing 10 takes the contrary process. Accordingly, over an entire section of the air-flow passage, separation of the air flow can be prevented and extraneous noise can be reduced.
In the present embodiment, an inner wall surface of the straight portion 22 of the bass reflex port 20 and the inner wall surface 32 of the guiding portion 30 which is opposed to the wall 40 are connected to each other by an inner wall surface of the flare portion 25 which forms a curved surface. No steps are present between the inner wall surface of the straight portion 22 and the inner wall surface of the flare portion 25, and no steps are present between the inner wall surface of the flare portion 25 and the inner wall surface 32 of the guiding portion 30. Thus a region from the inner wall surface of the straight portion 22 of the bass reflex port 20 to the inner wall surface 32 of the guiding portion 30 forms a continuously and smoothly curved surface. Accordingly, in the present embodiment, a cross-sectional area of the air-flow passage enclosed by the inner wall of the bass reflex port 20 continuously increases from a position near the opening inside the bass reflex port 20 that forms a boundary between the straight portion 22 and the flare portion 25 to the guiding portion 30. Therefore, in a process in which the air flow moves from the bass reflex port 20 to the air-flow passage between the guiding portion 30 and the wall 40, it is possible to prevent separation of the air flow from the inner wall of the bass reflex port 20 and reduce extraneous noise.
The bass reflex type speaker as the comparative example is a bass reflex type speaker that comprises a bass reflex port having flare portions at opposite ends thereof, each flare portion having an elliptic cross section. The input audio signal is an audio signal in movie contents. In this example, as the input audio signal to the speaker, there is used, among audio signals in movie contents, a 0.25-second part picked out of signals for reproducing sounds of low pitch in which extraneous noise is likely to become a problem.
As apparent from the frequency characteristics SP0 of the input audio signal shown in
On the other hand, in the bass reflex type speaker 101 in the present embodiment, an increase in sound pressure level SP2 of an output sound in a high range with respect to sound pressure level SP0 of the input audio signal is smaller than that in the comparative example. That is, in the present embodiment, sound pressure level of extraneous noise is smaller than that in the comparative example. According to the present embodiment described above, extraneous noise can be more effectively reduced than the comparative example.
In the first modification, the opposed surface (the inner wall surface) 32 of the guiding portion 30 that is opposed to the wall 40 in the housing 10 is disposed at an angle that is greater than 180 degrees and smaller than 270 degrees with respect to the inner wall of the straight portion 22 of the bass reflex port 20. The opposed surface 42 of the wall 40 in the housing 10 that is opposed to the guiding portion 30 protrudes in a mountain-like manner such that a region thereof opposed to the opening of the bass reflex port 20 becomes an apex. In the cross-sectional view of
As shown in
The third modification also ensures the effect similar to the first embodiment. Further, in this modified arrangement, a radius of curvature at each position of an inner wall from the inner wall of the straight portion 22 to the inner wall surface 32 of the guiding portion 30 via the inner wall of the flare portion 25 is greater than that in the first embodiment, so that separation of the air flow from the inner wall can be effectively prevented. Furthermore, according to the arrangement, the wall 40 in the first embodiment is unnecessary, enabling the bass reflex type speaker 101c to be inexpensive. In the third modification, since the bottom surface 12 of the housing 10 is disposed closer to the flare portion 25 of the bass reflex port 20, the housing 10 is downsized as compared with the first embodiment.
In the bass reflex type speaker 102 according to the present embodiment, a wall 50 (as one example of an outside housing surface forming portion) is additionally provided to the structure of the bass reflex type speaker 101 in the first embodiment. An opposed surface 52 of the wall 50 is opposed to an upper surface 14 of the housing 10 with a distance g therebetween. In the present embodiment, while a space inside the bass reflex port 20 is connected to a space inside the housing 10 via the air-flow passage between the guiding portion 30 and the wall 40 as in the first embodiment, the space inside the bass reflex port 20 is connected to a space outside the housing 10 (more precisely, a space that is located outside the housing 10 and is not located between the wall 50 and the housing 10). In the cross-sectional view of
In the present embodiment, in an instance where a radius of the opening end (an opening circular region) 28 of the flare portion 24 is identical with a radius of the opening end (an opening circular region) 29 of the flare portion 25, the distance g may coincide with the distance h between the guiding portion 30 and the wall 40. In an instance where the radius of the opening end (the opening circular region) 28 of the flare portion 24 and the radius of the opening end (the opening circular region) 29 of the flare portion 25 differ from each other, the distance g may be calculated in the same manner as that in which the distance h is calculated in the first embodiment. In other words, where the radius of the opening circular region of the flare portion 24 is r0, the distance g is set to be r0/2, for example.
In the above structure, a cross-sectional area of an air-flow passage between the upper surface 14 of the housing 10 and the opposed surface 52 of the wall 50 at the opening end 28 is equal to (or close to) the cross-sectional area of the opening end 28 of the flare portion 24, so that, in a section of an air-flow passage that is constituted by a section inside the bass reflex port 20 and a section between the housing 10 and the wall 50, a discontinuous change in the cross-sectional area of the air-flow passage can be prevented.
In the present embodiment, both of air turbulence in the opening of the bass reflex port 20 in the inside of the housing 10 and air turbulence in the opening thereof communicating with the outside of the housing 10 can be prevented, so that extraneous noise can be more effectively reduced than in the first embodiment.
In the first modification, similarly to the first modification of the first embodiment, the opposed surface (the inner wall surface) 32 of the guiding portion 30 that is opposed to the opposed surface 42 of the wall 40 in the housing 10 is disposed at an angle that is greater than 180 degrees and smaller than 270 degrees with respect to the inner wall of the straight portion 22 of the bass reflex port 20. The wall 40 in the housing 10 that is opposed to the guiding portion 30 protrudes in a mountain-like manner such that a region thereof opposed to the opening of the bass reflex port 20 becomes an apex. Other aspects of the bass reflex type speaker 102a are similar to those in the second embodiment. In the cross-sectional view of
This modified arrangement also ensures the effect similar to the second embodiment. Further, in the modified arrangement, a radius of curvature at each position of an inner wall from the inner wall of the straight portion 22 to the inner wall surface 32 of the guiding portion 30 via the inner wall of the flare portion 25 is greater than that in the second embodiment, so that separation of the air flow from the inner wall can be effectively prevented.
This modified arrangement also ensures the effect similar to the second embodiment. Further, in the modified arrangement, a radius of curvature at each position from the inner wall of the straight portion 22 to the upper surface 14 of the housing 10 via the inner wall of the flare portion 24 is greater than that in the second embodiment, so that separation of the air flow from the inner wall of the air-flow passage can be effectively prevented.
This modified arrangement also ensures the effect similar to the second embodiment. Further, in the modified arrangement, a radius of curvature at each position of the inner wall from the inner wall of the straight portion 22 to the inner wall surface 32 of the guiding portion 30 via the inner wall of the flare portion 25 is greater than that in the second embodiment. Furthermore, similarly to the second modification, a radius of curvature at each position from the inner wall of the straight portion 22 to the upper surface 14 of the housing 10 via the inner wall of the flare portion 24 is greater than that in the second embodiment. Accordingly, separation of the air flow from the inner wall of the air-flow passage can be effectively prevented.
According to thus modified arrangement, the wall 40 is unnecessary, enabling the bass reflex type speaker 102d to be inexpensive. Further, in the arrangement, since the bottom surface 12 of the housing 10 is disposed closer to the flare portion 25 of the bass reflex port 20, the housing 10 is downsized as compared with the second embodiment.
Although not illustrated, the same modifications as in the first through the third modifications of the second embodiment may be applied to the fourth modification.
While there have been explained embodiments of the present disclosure, it is to be understood that the disclosure may be embodied otherwise. Other embodiments will be explained below.
(1) In the illustrated embodiments, the bass reflex port is attached to the upper surface of the housing. The bass reflex port may be attached to either one of an upper surface, a lower surface, a left-side surface, a right-side surface, a front surface, and a rear surface.
(2) The housing, the bass reflex port and the guiding portion may be integrally formed or may be separately produced and then connected to each other. Further, the bass reflex port and the guiding portion may be integrally formed. In the illustrated embodiments, the bass reflex port is formed as the tubular body portion, and the guiding portion is added to the bass reflex port. A structure in which the guiding portion is added to the bass reflex port as the tubular body portion may be employed as a bass reflex port.
(3) In the first embodiment, the distance h between the guiding portion 30 and the wall 40 may be constant, or may be increased in a direction away from the center axis ax of the bass reflex port 20. In this arrangement, a gradient in which a cross-sectional area of the air-flow passage between the guiding portion 30 and the wall 40 increases in the direction away from the center axis ax of the bass reflex port 20 can become large. Accordingly, even in a situation in which respective areas of the guiding portion 30 and the wall 40 cannot be increased, a cross-sectional area of the air flow flowing between the guiding portion 30 and the wall 40 can be increased to permit the air to flow out to the inside of the housing 10, enabling extraneous noise to be reduced.
(4) In the illustrated embodiments, portions of the bass reflex port 20 except the opening (the inlet and outlet) thereof are disposed so as to be spaced apart from the walls of the housing 10. A part of a side surface of the bass reflex port 20 from one opening to the other opening may be fixed to a wall of the housing 10. A wall of the housing 10 may form a part of the side surface of the bass reflex port 20. In those arrangements, there may be disposed the guiding portion 30 having a shape extending radially outwardly from a section except a section fixed to the wall of the housing among sections over an entire circumference of the opening of the bass reflex port 20.
(5) A length of the guiding portion 30 (or the wall 40) in a direction extending toward the inner wall of the housing may be within a range by reaching the inner wall of the housing. Further, a part of the outer circumference of the guiding portion 30 (or the wall 40) extending radially from the opening of the bass reflex port 20 may reach the inner wall of the housing. However, the guiding portion 30 is constructed such that at least a part of the outer circumference of the guiding portion 30 (or the wall 40) does not reach the inner wall of the housing and does not contact the inner wall of the housing. That is, it is required that the guiding portion 30 and the wall 40 do not divide a space in the housing.
(6) The wall 40 may not be identical with the guiding portion 30 in size or planar shape. The wall 40 may have a size and a planar shape that enable the opening end 29 to be covered.
(7) A part of the bass reflex port 20 may be disposed outside the housing 10.
(8) While the present disclosure is embodied as the bass reflex type speaker disclosed in the illustrated embodiments, the present disclosure may be embodied as a bass reflex port in which the bass reflex port 20 (i.e., the tubular body portion) in the illustrated embodiments and the guiding portion 30 are integrally formed or as a bass reflex port in which the bass reflex port 20 (i.e., the tubular body portion), the guiding portion 30, and the wall 40 are integrally formed.
(9) In the first embodiment, in addition to the first measure, the second measure is also employed. Where a desired effect for preventing generation of extraneous noise is ensured only by the first measure, only the first measure may be employed. This is true of the other embodiments. In other words, similarly to the first structure of the first embodiment illustrated in
Number | Date | Country | Kind |
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2018-057203 | Mar 2018 | JP | national |