The present technology relates to a headphone.
A headphone has been used as a device through which sound output from an audio reproduction device is heard. A typical headphone includes a headband provided in contact with the head of a user, and housings provided on the left and right ends of the headband. Each of the housings accommodates an audio output means constituted by a speaker or the like. There are known a considerable number of types and folding systems of a headphone (Patent Document 1, Patent Document 2). A known foldable headphone often includes two or three, or more folding rotational shafts disposed on each of an L side and an R side.
However, in case of a headphone provided with many folding rotational shafts, a user operating this headphone is required to perform a complicated folding operation, as has been a problem of this type of headphone.
The present technology has been developed in consideration of this problem. It is an object of the present technology to provide an easily foldable headphone.
For solving the above-mentioned problem, the present technology is directed to a headphone including: a headband; a pair of housing support portions, one and the other of which are provided at one and the other ends of the headband, respectively; a pair of rotational shafts, one and the other of which rotatably connect one and the other of the pair of housing support portions to the headband, respectively; a pair of housings, one and the other of which are provided on one and the other of the pair of housing support portions, respectively, wherein, in a folded state of the housing support portions as a result of a rotation, the pair of housings are disposed in positions contained within an area inside an arc formed by the headband and the housing support portions in an opened state of the housing support portions, and are located side by side without crossing each other; and a pair of ear pads, one and the other of which are provided on one and the other of the pair of housings, respectively.
According to the present technology, a headphone becomes easily foldable.
Embodiments according to the present technology are hereinafter described with reference to the drawings. The description will be presented in the following order.
<1. First Embodiment>
[1-1. Configuration of Headphone]
<2. Second Embodiment>
[2-1. Configuration of Headphone]
<3. Modified Examples>
[1-1. Configuration of Headphone]
The headband 110 is curved along the head of a user, and brought into contact with the top of the head of the user in a wearing state to support the entire headphone 100. The headband 110 is constituted by synthetic resin such as plastic, or metal, for example, and has flexibility produced by predetermined rigidity and elasticity of the headband 110. Accordingly, the headband 110 is capable of pressing the housings 150 and the ear pads 160 toward the side of the head of the user during wearing of the headphone 100, thereby maintaining the wearing state of the headphone 100. A cushioning member such as rubber may be provided on a portion of the inner surface of the headband 110 in contact with the top of the head of the user.
One and the other of the rotational shafts 120 are provided on one and the other ends of the headband 110, respectively, to rotatably connect the arms 130 to the headband 110. Each of the rotational shafts 120 is tilted at a predetermined angle in a diagonal direction. The detailed configuration of the rotational shafts 120 will be described later. According to the first embodiment, the L side rotational shaft 120 and the R side rotational shaft 120 are disposed at bilaterally symmetric positions.
The arms 130 are slightly curved along the side of the head of the user. The arms 130 are rotatably connected with the one and the other ends of the headband 110, respectively, with the rotational shafts 120 interposed between the arms 130 and the headband 110. Each of the arms 130 is foldable as illustrated in
The sliders 140 are slidable in the up-down direction along the inner side surfaces of the arms 130. The sliders 140 support the housings 150, wherefore the user is capable of shifting the housings 150 in the up-down direction by sliding the sliders 140 along the arms 130. The arms 130 and the sliders 140 correspond to housing support portions according to the claims.
During wearing of the headphone 100, each of the housings 150 and each of the ear pads 160 are aligned with a position facing the corresponding ear of the user by adjustment of the position of the corresponding slider 140 in accordance with the size of the head of the user, the distance between the ear and the top of the head, and others. This alignment produces fitting comfort in accordance with physical features and preferences of the user. When the headphone 100 is not used, each of the sliders 140 is slid to a folding position located at the upper end of a slidable range to bring the headphone 100 into a compact condition. This point will be described later.
The housings 150 connected with the sliders 140 face the inside of the headphone 100. The housings 150 are supported by the sliders 140 in such a condition that each of the housings 150 can perform a twisting action. In this case, the direction of each of the housings 150 changes in accordance with the shape of an area around the ear of the user during wearing of the headphone 100, wherefore the housing 150 comes to the position facing the ear in a state appropriate for the shape of the side of the head of the user. Connection between the sliders 140 and the housings 150 will be detailed later.
Each of the housings 150 functions as an accommodating unit for accommodating an audio processing circuit, a speaker (both not shown), and others inside the housing 150. Each of the housings 150 is constituted by synthetic resin such as plastic, for example. The audio processing circuit executes predetermined audio signal processes, such as a noise canceling process, a signal amplifying process, and an equalizing process. The speaker outputs audio signals processed by the audio processing circuit in the form of sound.
Each of the ear pads 160 is configured to have elasticity, and provided on the corresponding housing 150 on a surface facing the side of the head of the user. Each of the ear pads 160 interposed between the corresponding housing 150 and the side of the head of the user functions as a cushioning member between the housing 150 and the side of the head of the user. More specifically, the ear pads 160 prevent discomfort or pain given to the user from the housings 150 made of hard and not easily deformable material and coming in direct contact with the side of the head of the user during wearing of the headphone 100.
In addition, each of the ear pads 160 has a function of improving sound quality, such as enhancement of reproduction of a low range, by sealing a space formed by the ear pad 160 and the side of the head of the user when the ear pad 160 is ring-shaped. Moreover, each of the ear pads 160 has a function of preventing leakage of sound to the outside after output of sound from the speaker. Furthermore, each of the ear pads 160 has a function of blocking noise entering from the outside to allow the user to more easily hear sound generated from the speaker.
Each of the cords 170 is a cord into which a lead, a ground line and the like are inserted, as a cord through which audio signals are transmitted. One end of each of the cords 170 is connected with the audio processing circuit accommodated in the corresponding housing 150. A plug (not shown) is provided at the other end of each of the cords 170. This plug is connected with an audio reproduction device (not shown) such as an MP3 (MPEG Audio Layer-3) player for connection between the headphone 100 and the audio reproduction device. According to the example illustrated in
The cord 170 may be connected with only either the L side housing 150 or the R side housing 150. In this case, an L channel lead, an R channel lead, and a ground line are inserted into the cord 170. A connection cord (not shown) is further provided between the housing 150 connected with the cord 170, and the other housing 150 not connected with the cord 170 to drive the speaker within the other housing 150 not connected with the cord 170. This connection cord is connected with the cord 170 or the audio processing circuit within the housing 150 connected with the cord 170, and inserted into the sliders 140, arms 130, and the headband 110 to connect with the audio processing circuit within the other housing 150. Audio signals are transmitted via this connection cord to the audio processing circuit of the other housing 150 not connected with the cord 170.
According to the headphone 100 in the first embodiment, one of the L side and R side sliders 140 is initially slid along the arm 130 to the upper end of the slidable range as illustrated in
These steps are also performed for the other slider 140 and arm 130. In this case, the arm 130 corresponding to the one slider 140 is folded after sliding of the one slider 140, whereafter the arm 130 corresponding to the other slider 140 is folded after the sliding of the other slider 140. However, both the arms 130 may be folded after sliding of both the sliders 140.
When the L side arm 130 and the R side arm 130 are folded, the headphone 100 comes into a folded state as illustrated in
Each of the housings 150 makes a directional change from a state facing a plane I located at equal distances from the L side and R side housings 150 in the use state (state in
A configuration of the rotational shafts 120 is now described. As discussed above, the rotational shafts 120 are tilted in a diagonal direction with respect to the plane I located at equal distances from the L side and R side housings 150. As illustrated in
Initially, an optimum position of one of the housings 3 in the folded state of the headphone 1 is determined. It is preferable that this position corresponds to such a position that the size of the headphone 1 becomes the minimum in the folded state. Based on this determination, a folding position A of the band 2 is determined in accordance with the position of the housing 3 and the length of the band 2 as illustrated in
Subsequently, arbitrary two points are determined on the housing 1 and/or on the band 2 as illustrated in
Subsequently, the band 2 is folded at the determined folding position A as illustrated in
Then, a plane Mb is determined between the point B and the point B′ as a plane located at equal distances from the point B and the point B′ as illustrated in FIG. 4D. The plane Mb is considered as a group of points located at equal distances from the two points B and B′. Similarly, a plane Mc is determined between the point C and the point C′ as a plane located at equal distances from the points C and C′. The plane Mc is considered as a group of points located at equal distances from the two points C and C′.
As illustrated in
According to this embodiment, the headband 110 and the arm 130 are connected with each other via the rotational shaft 120, in which condition the arm 130 is foldable in accordance with rotation of the arm 130 as described with reference to
The tilt of the rotational shaft 120 in a diagonal direction realizes folding of the arm 130 and a change of the direction of the housing 150 by one rotation around the axis of the rotational shaft 120. The one rotation of the arm 130 changes the direction of the housing 150 facing the plane I located at equal distances from the left and right housings 150 in the use state. A conventional headphone requires two or more operations, including one operation for folding the headphone, and one operation for changing the direction of the housing. However, the headphone 100 according to the present technology realizes folding of the headphone 100 and a change of the direction of the housing 150 by one arm rotation.
As illustrated in
As illustrated in
As illustrated in
Configurations of the arm 130 and the slider 140 are now described.
As illustrated in
As illustrated in
A plurality of use-state projections 133 are provided on the inner side surface of the arm 130. The engaging projection 141 of the slider 140 is caught by the plurality of use-state projections 133 at the time of fixture of the position of the housing 150. A range of the use-state projections 133 coincides with a range of sliding of the slider 140 for adjustment of the position of the housing 150 by the user during use of the headphone 100. This range is therefore referred to as a use range. The use-state projections 133 correspond to a first position fixing mechanism according to the claims. The housing 150 and the ear pad 160 is aligned with the position facing the ear of the user by adjusting the position of the slider 140 in accordance with the size of the head of the user, the distance between the ear and the top of the head, or other conditions, and fixing the adjusted position of the slider 140. This alignment produces fitting comfort in accordance with physical features and preferences of the user.
According to the example illustrated in
In addition, one folded-state projection 134 is provided in an upper part of the inner side surface of the arm 130. The folded-state projection 134 fixes the position of the housing 150 at the time of folding of the headphone 100. The position of the folded-state projection 134 coincides with the position of the housing 150 at the time of folding of the arm 130. Accordingly, this position is referred to as a folding position. The folded-state projection 134 corresponds to a second position fixing mechanism according to the claims.
There is provided a range containing no projection between the use range and the folded-state position. No projection is provided in the range between the use range and the folded-state position, wherefore the slider 140 is capable of smoothly sliding in the range between the use range and the folded-state position. The range between the use range and the folded-state position is hereinafter referred to as a smooth range.
As illustrated in
As a result, the engaging projection 141 of the slider 140 is caught by the use-state projections 133 for fixation of the position of the slider 140. Accordingly, the housing 150 is fixable to a position corresponding to a preference of the user. In this case, the user realizes that the position of the housing 150 has been adjusted based on the click feeling given to the user when the engaging projection 141 of the slider 140 climbs over the use-state projections 133.
When the headphone 100 is not used and desired to be folded, the slider 140 is slid through the smooth range toward the folding position. As a result, the engaging projection 141 of the slider 140 is caught by the folded-state projection 134, whereby the slider 140 is fixed to the folding position of the slider 140.
No projection is provided in the smooth range between the use range and the folding position. Accordingly, the user is capable of smoothly sliding the slider 140 in the smooth range. The smooth range is neither the range for fixing the position of the housing 150 during use, nor a range for positioning the housing 150 during storage. Accordingly, no projection needs to be formed in the smooth range. The absence of a projection in the smooth range allows the user to easily and rapidly slide the slider 140. Accordingly, folding of the headphone 100 rapidly finishes.
As described above, the slidable range of the slider 140 according to the present technology is wider than the position changeable range of the housing 150 during use of the headphone 100. According to this structure, the housing 150 is slidable to the upper end of the arm 130 at the time of storage of the headphone 100, thereby increasing the compactness of the headphone 100.
The connection between the slider 140 and the housing 150 is now described.
An elongated recess 151 is formed substantially at the center of the surface of the housing 150 on the side opposite to the side where the ear pad 160 is provided. As illustrated in
As illustrated in
The slider 140 and the housing 150 are connected with each other via a screw of the like inserted into the connection hole 153 of the housing 150 in a state of abutment between the recessed spherical surface 143 of the slider 140 and the projecting spherical surface 152 of the housing 150. As a result, the projecting spherical surface 152 of the housing 150 becomes slidable with respect to the recessed spherical surface 143 of the slider 140 as illustrated in
The housing 150 is tiltable in the longitudinal direction as discussed with reference to
The headphone 100 according to the first embodiment is constructed as described above. An area surrounded by the headband 110 and the arm 130 (hatched area) in the use state is herein defined as illustrated in
Moreover, as illustrated in
According to this embodiment, both folding of the arm 130 and a directional change of the housing 150 are achievable by one rotation of the arm 130 around the axis of the one rotational shaft 120. Accordingly, the user is capable of rapidly and easily completing folding of the headphone 100. Moreover, only a pair of the rotational shafts 120 are needed as rotational shafts. In this case, the number of parts decreases, wherefore the manufacturing cost lowers.
The slider 140 is slidable wider than the use range corresponding to the position changeable range of the housing 150 during use of the headphone 100. In this case, the slider 140 is allowed to slide above the use range during folding. Accordingly, compactness of the headphone 100 increases.
At the time of folding of the arm 130, the slider 140 is slid to position the housing 150 at the upper end side of the arm 130 (in the vicinity of the center of the headphone 100 in the longitudinal direction). As a result, both the housings 150 are positioned side-by-side in the folded state as illustrated in
In the folded state, the housings 150 do not cross each other. In other words, the L side housing 150 is positioned on the left side of the headphone 100. On the other hand, the R side housing 150 is positioned on the right side of the headphone 100. In this case, such a condition that the housings 150 cross each other, i.e., that the L side housing 150 is positioned on the right side of the headphone 100, and that the R side housing 150 is positioned on the left side of the headphone 100 does not occur. Accordingly, entanglement of the cords 170 connected with the housings 150 is avoidable.
Furthermore, in the folded state of the headphone 100, each of the ear pads 160 faces in the same direction as illustrated in
[2-1. Configuration of Headphone]
A second embodiment according to the present technology is hereinafter described.
The headband 210 is curved along the head of a user, and brought into contact with the top of the head of the user in a wearing state to support the entire headphone 200. The headband 210 is constituted by synthetic resin such as plastic, or metal, for example, and has flexibility produced by predetermined rigidity and elasticity of the headband 210. Accordingly, the headband 210 is capable of pressing the housings 240 and the ear pads 250 toward the side of the head of the user in the wearing state, thereby maintaining the wearing state of the headphone 200. A cushioning member such as rubber may be provided on a portion of the inner surface of the headband 210 in contact with the top of the head of the user.
According to the second embodiment, both ends of the headband 210 constitute sliders 211. The headband 210 expands and contracts in accordance with sliding of each of the sliders 211. Each of the hangers 230 shifts upward or downward with respect to the headband 210 in accordance with sliding of the corresponding slider 211.
During use of the headphone 200, each of the housings 240 and each of the ear pads 250 are aligned with a position facing the ear of the user by adjustment of the degree of expansion and contraction of the slider 211 in accordance with the size of the head of the user, the distance between the ear and the top of the head, or other conditions. This alignment produces fitting comfort in accordance with physical features and preferences of the user. On the other hand, when the headphone 200 is not used, the slider 211 is contracted to make the headphone 200 compact for storing space saving of the headphone 200.
The rotational shaft 220 is provided at an end of each of the sliders 211 of the headband 210 to rotatably support the corresponding hanger 230 with respect to the slider 211. The rotational shaft 220 is tilted with respect to the plane I located at equal distances from the left and right housings 240, similarly to the first embodiment. According to the second embodiment, the L side rotational shaft 220 and the R side rotational shaft 220 are disposed at bilaterally symmetric positions. The configuration of the rotational shafts 220 will be described later.
Each of the hangers 230 is provided at the tip of the corresponding slider 211 of the headband 210 to rotatably support the corresponding housing 240. Each of the hangers 230 rotatably supports the housing 240 via support pins (not shown) projecting inward from a pair of tips of the hanger 230. According to this structure, the direction of the housing 240 changes in accordance with the shape of an area around the ear of the user during wearing of the headphone 200, wherefore the housing 2405 is allowed to face the ear in a condition appropriate for the side shape of the head of the user. The hanger 230 corresponds to a support portion of the housing 240 according to the claims.
The housing 240 functions as an accommodating unit for accommodating an audio processing circuit, a speaker (both not shown), and others inside the housing 240. The housing 240 is made of synthetic resin such as plastic, for example. The audio processing circuit executes predetermined audio signal processes, such as a noise canceling process, a signal amplifying process, and an equalizing process. The speaker outputs audio signals processed by the audio processing circuit in the form of sound.
The ear pad 250 is configured to have elasticity, and provided on a surface of the housing 240 on the side opposite to the side of the head of the user. Each of the ear pads 250 interposed between the corresponding housing 240 and the side of the head of the user functions as a cushioning member between the housing 240 and the side of the head of the user. More specifically, the ear pad 250 prevents discomfort or pain given to the user from the housing 240 made of hard and not easily deformable material and coming into direct contact with the side of the head of the user during waring of the headphone 200.
In addition, each of the ear pads 250 has a function of improving sound quality, such as enhancement of reproduction of a low range, by sealing a space formed by the ear pad 250 and the side of the head of the user when the ear pad 250 is ring-shaped. Moreover, each of the ear pads 160 has a function of preventing leakage of sound to the outside after output of sound from the speaker. Furthermore, each of the ear pads 250 has a function of blocking noise entering from the outside to allow the user to more easily hear sound generated from the speaker.
Each of the cords 260 is a cord into which a lead, a ground line and the like are inserted, as a cord through which audio signals are transmitted. One end of each of the cords 260 is connected with the audio processing circuit accommodated in the housing 240. A plug (not shown) is provided at the other end of the cord 260. This plug is connected with an audio reproduction device (not shown) such as an MP3 player for connection between the headphone 2001 and the audio reproduction device.
The cord 260 may be only connected with either the L side housing 240 or the R side housing 240. In this case, an L channel lead, an R channel lead, and a ground line are inserted into the cord 260. A connection cord (not shown) is further provided between the housing 240 connected with the cord 260, and the other housing 240 not connected with the cord 260 to drive the speaker within the other housing 240 not connected with the cord 260. This connection cord is connected with the cord 260 or the audio processing circuit within the housing 240 connected with the cord 260, and inserted into the sliders 211, arms, and the headband 210 to connect with the audio processing circuit within the other housing 240. Audio signals are transmitted via this connection cord to the audio processing circuit within the other housing 240 not connected with the cord 260.
According to the headphone 200 in the second embodiment, each of the hangers 230 is folded toward the headband 210 when the headphone 200 is not used as illustrated in
Connection between the slider 211 of the headband 210 and the hanger 230 is now described.
The rotational shaft 220 is tilted in a diagonal direction with respect to the plane I located at equal distances from the left and right housings 240 as illustrated in
It is preferable that the rotational shaft 220 is disposed at an angle approximately in a range from 4° to 14° with respect to an X axis perpendicular to a Y axis dividing an arc of the headband 210 into equal two parts in the front view of the headphone 200, as illustrated in
It is further preferable that the rotational shaft 220 is disposed at an angle approximately in a range from 9° to 19° with respect to a Z axis substantially in parallel with the width direction of the headband 210 in the side view of the headphone 200 as illustrated in
It is further preferable that the rotational shaft 220 is disposed at an angle approximately in a range from 27° to 37° with respect to the X axis substantially in parallel with the longitudinal direction of the headband 210 in the top view of the headphone 200 as illustrated in
In this case, the hanger side connection portion 231 is caught by the first click 213 as illustrated in
A transition from the folded state to the use state is now described.
At the time of a transition from the use state to the folded state, the recessed portion 232 of the hanger side connection portion 231 climbs over the third click 215, whereby the hanger 230 is brought into the folded state as illustrated in
A configuration for allowing a twisting action of the housing 240 is now described.
As illustrated in
The headphone 200 according to the second embodiment is constructed as described above. According to the first embodiment, the rotational shaft 120 corresponding to a fulcrum of the rotation for folding is disposed above the slider 140. According to the second embodiment, however, the rotational shaft 220 is disposed below the slider 211. In this case, the headphone 200 having either of these configurations is easily foldable, and becomes compact in size in a condition after folding.
An area (hatched area) inside the headphone 200 in the use state is herein defined as illustrated in
According to the headphone 200 in the second embodiment, it is preferable that the housing 240 is tilted at an angle in a range within ±45° with respect to the plane II substantially in parallel with the headband 210 in the side view of the headphone 200 in the folded state, similarly to the first embodiment.
According to the second embodiment, folding of the headphone 200 is achievable by one rotation of the hanger 230 around the axis of the one rotational shaft 220. Accordingly, the user is capable of rapidly and easily completing folding of the headphone 200.
Moreover, both the housings 240 are positioned side-by-side in the folded state illustrated in
In the folded state, the housings 240 do not cross each other in the folded state. In other words, the L side housing 240 is positioned on the left side of the headphone 200. On the other hand, the R side housing 240 is positioned on the right side of the headphone 200. In this case, such a condition that the housings 240 cross each other, i.e., that the L side housing 240 is positioned on the right side of the headphone 200, and that the R side housing 240 is positioned on the left side of the headphone 200 does not occur. Accordingly, entanglement of the cords 260 connected with the housings 240 is avoidable.
Furthermore, in the folded state of the headphone 200, each of the ear pads 250 faces in the same direction as illustrated in
While the specific embodiments of the present technology have been described, the present technology is not limited to the respective embodiments described herein, but includes various modifications made based on the technical concepts of the present technology.
A headphone 300 according to this modified example is constituted by a headband 310, rotational shafts 320, arms 330, sliders 340, housings 350, ear pads 360, and cords 370. The respective configurations are similar to the corresponding configurations of the first embodiment, wherefore explanation of these configurations is not repeated herein.
According to the first embodiment described above, the pair of rotational shafts 120 on the L side and the R side are disposed at bilaterally symmetric positions. On the other hand, according to the headphone 300 in the modified example, the pair of rotational shafts 320 on the L side and the R side are bilaterally asymmetric.
When the rotational shafts 320 at the folding positions of the arms 330 are bilaterally asymmetric, the headphone 300 in the folded state comes to a position illustrated in
The present technology may have the following configurations.
(1)
A headphone including:
a headband;
a pair of housing support portions, one and the other of which are provided at one and the other ends of the headband, respectively;
a pair of rotational shafts, one and the other of which rotatably connects one and the other of the pair of housing support portions to the headband, respectively;
a pair of housings, one and the other of which are provided on one and the other of the pair of housing support portions, respectively, wherein, in a folded state of the housing support portions as a result of a rotation, the pair of housings are disposed in positions contained within an area inside an arc formed by the headband and the housing support portions in an opened state of the housing support portions, and are located side by side without crossing each other; and
a pair of ear pads, one and the other of which are provided on one and the other of the pair of housings, respectively.
(2)
The headphone according to (1) noted above, wherein the rotational shafts are tilted to allow folding of the housing support portions and directional changes of the ear pads after the folding by one rotation.
(3)
The headphone according to (1) or (2) noted above, wherein the pair of ear pads face substantially in the same direction in the folded state of the housing support portions.
(4)
The headphone according to any one of (1) to (3) noted above, wherein each of the housing support portions includes an arm connected with the headband via the corresponding rotational shaft, and a slider slidably provided with respect to the arm and sliding along the arm to adjust the position of the corresponding housing.
(5)
The headphone according to (4) noted above, wherein a slidable range of the slider is wider than a position changeable range of the housing during use of the headphone by a user.
(6)
The headphone according to (5) noted above, wherein each of the housing support portions includes a first position fixing mechanism for fixing the position of the corresponding housing in the position changeable range of the corresponding housing during use of the headphone.
(7)
The headphone according to (6) noted above, wherein the first position fixing mechanism is capable of fixing the corresponding housing to a plurality of positions.
(8)
The headphone according to (5) noted above, wherein each of the housing support portions includes a second position fixing mechanism for fixing the position of the corresponding housing in an area out of the position changeable range of the corresponding housing during use of the headphone.
(9)
The headphone according to (4) noted above, wherein each of the sliders is disposed below the corresponding rotational shaft.
(10)
The headphone according to any one of (1) to (9) noted above, wherein the pair of rotational shafts are disposed at bilaterally symmetric positions.
(11)
The headphone according to any one of (1) to (10) noted above, wherein each of the housings is movable in accordance with a side shape of the head of the user.
(12)
The headphone according to any one of (1) to (11) noted above, wherein each of the housings is movable in accordance with a side shape of the head of the user.
(13)
The headphone according to any one of (1) to (12) noted above, wherein
one and another cords are connected with one and the other of the pair of housings, respectively, and
the cords are connected in such positions that each connection portion for connection between the corresponding housing and the corresponding cord does not contact the other connection portion in the folded state of the pair of housing support portions.
(14)
The headphone according to (4) noted above, wherein the arms in the folded state overlap with each other at a position where the housings are present during use of the headphone by the user.
(15)
The headphone according to any one of (1) to (14) noted above, wherein the housing support portions are hangers that support the housings.
(16)
The headphone according to (15) noted above, wherein
the headband includes sliders each of which moves the corresponding hanger upward and downward, and
each of the sliders is disposed above the corresponding rotational shaft.
(17)
The headphone according to any one of (1) to (16) noted above, wherein each of the housings is contained within ±45° with respect to a plane substantially in parallel with the headband in a side view in the folded state of each of the housing support portions.
(18)
The headphone according to (2) noted above, wherein
the rotational shaft is disposed at an angle within a range from 4° to 22° with respect to an X axis direction perpendicular to a Y axis direction that divides the arc of the headband into two equal parts in a front view,
the rotational shaft is disposed at an angle within a range from 9° to 29° with respect to a Z axis direction substantially in parallel with a width direction of the headband in a side view, and
the rotational shaft is disposed at an angle within a range from 27° to 39° with respect to the X axis in a top view.
(19)
The headphone according to (18) noted above, wherein the rotational shaft is disposed at an angle of 17° with respect to the X axis in the front view, an angle of 24° with respect to the Z axis in the side view, and an angle of 34° with respect to the X axis in the top view.
(20)
The headphone according to (18) noted above, wherein the rotational shaft is disposed at an angle of 9° with respect to the X axis in the front view, an angle of 14° with respect to the Z axis in the side view, and an angle of 32° with respect to the X axis in the top view.
Number | Date | Country | Kind |
---|---|---|---|
2013-137181 | Jun 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/002383 | 5/1/2014 | WO | 00 |