The present invention relates to a full-face-type helmet comprising an outer shell having a ventilation opening in a chin region substantially opposing the chin of a helmet wearer (to be referred to as a “wearer” hereinafter) such as the rider of a motorcycle, and an impact absorbing liner disposed inside the outer shell. The present invention also relates to a full-face-type helmet comprising an outer shell having a ventilation opening in a chin region substantially opposing the chin of the wearer, an impact-on-the-chin-and-cheek absorbing liner disposed inside the outer shell, and a blockish inside pad for the cheek attached to the inner surface of the impact-on-the-chin-and-cheek absorbing liner. The present invention is optimally applied to an off-road driving full-face-type helmet such as a motocross helmet.
In off-road driving such as motocross, when running through an unlevel land, the rider may receive large vibration through the motorcycle or take a large action to maintain the balance of the motorcycle, and hence the amount of exercise of the rider is large. Therefore, conditions that should be considered by the rider when selecting a helmet include being lightweight, facilitating breathing, providing a large view, ensuring coolness, and the like.
As a helmet that satisfies the above conditions, conventionally, a so-called jet-type helmet through which the rider's face is open largely is used. With the jet-type helmet, however, it is difficult to protect the rider's chin effectively. Hence, as the helmet manufacturing technique improved afterwards, a full-face-type helmet which is lightweight, facilitates breathing and provides a large view, thus suitable for off-road driving of, e.g., a motocross has appeared. Such an off-road driving full-face-type helmet is disclosed in, e.g., U.S. Pat. No. 4,555,816.
The off-road driving full-face-type helmet disclosed in U.S. Pat. No. 4,555,816 comprises a large opening at the center of the chin cover to supply external air to near the wearer's mouth. In the helmet of U.S. Pat. No. 4,555,816, in order to introduce external air to the wearer's head as well, small openings for introducing external air into the head cover are provided to the left and right sides, respectively, of the large opening described above.
Furthermore, in the full-face-type helmet of U.S. Pat. No. 4,555,816, air passages to relatively move the external air from the small openings in the chin cover to inside the head cover are formed between an outer shall integrally molded of the chin cover and head cover, and an impact-on-the-chin absorbing liner for the chin cover and an impact-on-the-head absorbing liner for the head cover. More specifically, ventilation ridge grooves are formed in the outer surfaces of the impact-on-the-chin absorbing liner and impact-on-the-head absorbing liner, respectively, to substantially communicate with each other, thereby forming the air passage comprising the ventilation ridge grooves and the outer shell disposed outside them.
In the full-face-type helmet of U.S. Pat. No. 4,555,816 having the above arrangement, an external air introducing through hole extending through the impact-on-the-head absorbing liner in the direction of thickness must be formed near the side head region of the impact-on-the-head absorbing liner in order to introduce external air into the interior of the impact-on-the-head absorbing liner (that is, a head accommodating space of the helmet) through the terminal end portion of the air passage. Also, the air passage as described above is formed to introduce external air into the head cover through small openings formed in the chin cover. In the air passage, external air that has flown for a comparatively long distance along the ventilation ridge grooves formed in the outer surfaces of the impact-on-the-chin absorbing liner and impact-on-the-head absorbing liner, respectively, must bend substantially at a right angle at the through hole. As the resistance against the external air flow is large, the external air cannot flow well from the small openings formed in the chin cover into the head cover.
Hence, in the full-face-type helmet of U.S. Pat. No. 4,555,816, ventilation in the full-face-type helmet is not performed well unless the driving speed of the motorcycle is maintained at a certain degree. In the driving state wherein the driving speed is comparatively low and the amount of exercise of the rider is comparatively large, as in a case wherein the rider runs through an unlevel land on a motorcycle, ventilation of the interior of the full-face-type helmet is not performed well. Consequently, vapor generated by perspiration of the rider's head fills the interior of the full-face-type helmet to increase the unpleasantness of the rider as the wearer.
In the full-face-type helmet of U.S. Pat. No. 4,555,816, the impact-on-the-head absorbing liner must moderate the impact acting on the helmet by absorbing it while deforming. If the through hole extending through the impact-on-the-head absorbing liner in the direction of the thickness is formed near the side head region of the impact-on-the-head absorbing liner, the performance of moderating the impact may degrade near the side head region of the impact-on-the-head absorbing liner provided with the through hole. Hence, the through hole extending through the impact-on-the-head absorbing liner in the direction of thickness is largely restricted in its size and position.
Hence, according to the present invention, the defects as described above of the conventional full-face-type helmet such as an off-road driving helmet can be corrected effectively with a comparatively simple arrangement.
It is, therefore, the main object of the present invention to provide a full-face-type helmet such as an off-road driving helmet, in which ventilation of the interior of the full-face-type helmet is performed well by external air flowing in from a chin region, and a ventilation through hole extending through an impact absorbing liner substantially in the direction of its thickness need not be particularly formed in a region including the side head region and its vicinity of the impact absorbing liner for the external air flowing in from the chin region.
According to the first aspect of the present invention, there is provided a full-face-type helmet comprising an outer shell having a first ventilation opening in a chin region substantially opposing the chin of a wearer, and an impact absorbing liner disposed inside the outer shell. The impact absorbing liner has an impact-on-the-chin absorbing portion comprising a liner main body portion and a sheet-like backing plate which is arranged on an inner surface of the liner main body portion. The liner main body portion comprises a second ventilation opening substantially opposing the first ventilation opening, and a ventilation ridge groove which is formed in the inner surface of the liner main body portion and communicates with the second ventilation opening. In this case, the impact-on-the-chin absorbing portion can comprise an impact-on-the-chin absorbing portion of an impact-on-the-chin-and-cheek absorbing liner.
According to the second aspect of the present invention, there is provided a full-face-type helmet comprising an outer shell having a first ventilation opening in a chin region substantially opposing the chin of a wearer, an impact-on-the-chin-and-cheek absorbing liner disposed inside the outer shell, and a blockish inside pad for the cheek which is attached to the inner surface of the impact-on-the-chin-and-cheek absorbing liner. The impact-on-the-chin-and-cheek absorbing liner comprises a liner main body portion and a sheet-like backing plate (in other words, a pad attaching plate) which is arranged on an inner surface of the liner main body portion and to which the blockish inside pad for the cheek is attached. The liner main body portion comprises a second ventilation opening substantially opposing the first ventilation opening, and a ventilation ridge groove which is formed in the inner surface of the liner main body portion and communicates with the second ventilation opening.
According to either one of the first and second aspects of the present invention, unlike in the case of a conventional full-face-type helmet such as an off-road driving helmet, after external air has flown for a comparatively long distance along ventilation ridge grooves respectively formed in the outer surfaces of the impact-on-the-chin absorbing liner and impact-on-the-head absorbing liner, the external air need not bend substantially at a right angle at a through hole. Therefore, after being introduced into the outer shell from the first ventilation opening formed in the chin region of the outer shell, the external air can immediately bend to flow into the start end portions of the ventilation ridge groove formed in the inner surface of the liner main body portion of the impact absorbing liner. External air inflow to the start end portion of the ventilation ridge groove and external air outflow from the terminal end portion of the ventilation ridge groove can accordingly be performed comparatively well. Thus, ventilation of the interior of the full-face-type helmet can be performed well by the external air inflow from the chin region.
According to either one of the first and second aspects of the present invention, unlike in the case of a conventional full-face-type helmet such as an off-road driving helmet, a ventilation through hole need not be formed in a region including the side head region and its vicinity of the impact-on-the-head absorbing liner to extend substantially in the direction of thickness of the impact-on-the-head absorbing liner. Therefore, unlike in a case wherein such a ventilation through hole must be formed, limitations on the size and position of the ventilation through hole are not imposed on the present invention.
According to the second aspect of the present invention, the sheet-like backing plate to which the blockish inside pad for the cheek is attached can cover the ventilation ridge groove formed in the inner surface of the liner main body portion. Therefore, a full-face-type helmet, ventilation of the interior of which can be performed well and in which a ventilation through hole need not be particularly formed in the region including the side head part and its vicinity of the impact absorbing liner, can be provided with a comparatively simple arrangement.
According to either one of the first and second aspects of the present invention, the sheet-like backing plate preferably comprises a third ventilation opening substantially opposing the second ventilation opening. In this case, part of the external air that has passed through the first and second ventilation openings in the chin region of the full-face-type helmet flows into a region including the wearer's mouth and its vicinity through the third ventilation opening. According to either one of the first and second aspects of the present invention, the sheet-like backing plate preferably comprises a projection (preferably, a substantially ring-like projection) which is formed of at least part of the peripheral portion (preferably, substantially the entire peripheral portion) of the third ventilation opening and faces the second ventilation opening. In this case, the flowing direction of another part of the external air is changed by the projection of the sheet-like backing plate so the external air shifts toward the ventilation ridge groove. The projection thus serves as a deflector or baffle against the external air flow. Therefore, in either case, ventilation of the interior of the full-face-type helmet can be performed further well with a comparatively simple arrangement.
According to the present invention, the sheet-like backing plate may comprise a pair of left and right sheet-like backing plates and a substantially central sheet-like backing plate interposed between the pair of left and right sheet-like backing plates, and the third ventilation opening may be formed in the substantially central sheet-like backing plate. In this case, the projection can be formed on the substantially central sheet-like backing plate.
According to the present invention, a liner main body portion of the impact-on-the-chin-and-cheek absorbing liner may comprise a pair of left and right liner main body portions, and the second ventilation opening may be formed by abutting a first missing portion formed in the left liner main body portion and a second missing portion formed in the right liner main body portion to be in a substantially abutting state. According to the present invention, an average thickness of the sheet-like backing plate may fall within a range of 0.25 mm to 4 mm, preferably within a range of 0.5 mm to 2 mm, and more preferably within a range of 0.75 mm to 1.4 mm.
According to the present invention, the ventilation ridge groove may have a start end facing the second ventilation opening and a terminal end which is formed in an end face of the liner main body portion in a region including an upper end portion and its vicinity of the liner main body portion. In this case, the ventilation ridge groove can extend from the start end substantially backward, bend substantially upward substantially arcuately, then extend substantially upward and reach the terminal end which is present in a region including a side head region and its vicinity of the impact-on-the-chin-and-cheek absorbing liner substantially opposing a side head part of the helmet wearer.
According to the present invention, the ventilation ridge groove is preferably covered with the sheet-like backing plate. According to the present invention, the ventilation ridge groove may gradually widen, at a start end portion thereof which faces the second ventilation opening, substantially into a trumpet shape, when seen from the front, from a terminal end side thereof toward the start end. Furthermore, according to the present invention, the ventilation ridge groove may gradually widen, at a terminal end portion thereof opposite to the start end portion thereof which faces the second ventilation opening, substantially into a trumpet shape, when seen from the front, from a start end side thereof toward said terminal end.
According to the present invention, an average width of a main part of the ventilation ridge groove (when the start end portion and/or a terminal end portion thereof forms a trumpet-shaped portion, the trumpet-shaped portion is excluded) may fall within a range of 4 mm to 16 mm and preferably within a range of 6 mm to 11 mm. According to the present invention, an average depth of a main part of the ventilation ridge groove (when the start end portion and/or a terminal end portion thereof forms a trumpet-shaped portion, the trumpet-shaped portion is excluded) may fall within a range of 2 mm to 8 mm and preferably within a range of 3 mm to 5.5 mm. Furthermore, according to the present invention, an average sectional area of a main part of the ventilation ridge groove (when the start end portion and/or a terminal end portion thereof forms a trumpet-shaped portion, the trumpet-shaped portion is excluded) may fall within a range of 8 mm2 to 80 mm2 and preferably within a range of 12 mm2 to 40 mm2.
According to the present invention, an area of the third ventilation opening (when the third ventilation opening comprises a plurality of ventilation openings, a total area thereof) may fall within a range of 3 cm2 to 40 cm2 and preferably within a range of 6 cm2 to 20 cm2. According to the present invention, an area of the second ventilation opening (when the second ventilation opening comprises a plurality of ventilation openings, a total area thereof) in an outer surface of the liner main body portion may fall within a range of 8 cm2 to 100 cm2 and preferably within a range of 16 cm2 to 46 cm2. According to the present invention, an area of the second ventilation opening (when the second ventilation opening comprises a plurality of ventilation openings, a total area thereof) in an inner surface of the liner main body portion may fall within a range of 6 cm2 to 80 cm2 and preferably within a range of 12 cm2 to 38 cm2. According to the present invention, a value obtained by subtracting an area of the second ventilation opening (when the second ventilation opening comprises a plurality of second ventilation openings, a total thereof) in an inner surface of the liner main body portion from an area of the second ventilation opening (when the second ventilation opening comprises a plurality of second ventilation openings, a total thereof) in an outer surface of the liner main body portion may fall within a range of 2 cm2 to 20 cm2 and preferably within a range of 4 cm to 8 cm2. Furthermore, according to the present invention, a value obtained by subtracting an area of the third ventilation opening (when the third ventilation opening comprises a plurality of third ventilation openings, a total thereof) from an area of the second ventilation opening (when the second ventilation opening comprises a plurality of second ventilation openings, a total thereof) in an inner surface of the liner main body portion may fall within a range of 3 cm2 to 40 cm2 and preferably within a range of 6 cm2 to 18 cm2.
The above, and other, objects, features and advantages of this invention will become readily apparent from the following detailed description thereof which is to be read in connection with the accompanying drawings.
An embodiment obtained by applying the present invention to an off-road driving full-face-type helmet will be described in “(1) Schematic Description of Helmet as a Whole” and “(2) Specific Description of Ventilation System” with reference to the accompanying drawings.
(1) Schematic Description of Helmet as a Whole
As shown in
The shield plate 4 closes the window opening 3 when located at the backward pivoting position shown in
As shown in
As has been known, the outer shell 11 shown in
As shown in
The sheet-like backing plate 27 which is substantially arcuate when seen from the top includes three pieces, i.e., a pair of left and right sheet-like backing plates 33 and a substantially central sheet-like backing plate 28 which is present between the pair of left and right sheet-like backing plates 33. The left sheet-like backing plate 33, substantially central sheet-like backing plate 28 and right sheet-like backing plate 33 are sequentially and substantially abutted against each other to be in a substantially abutting state on the inner surfaces of the pair of left and right liner main body portions 25, and accordingly cover substantially the entire inner side surfaces of the pair of left and right liner main body portions 25 substantially arcuately when seen from the top.
As has been known, the liner main body portion of the impact-on-the-head absorbing liner 21 shown in
The backing cover 22 for the head shown in
The pair of left and right blockish inside pads 24 for the cheeks shown in
The pair of left and right liner main body portions 25 of the impact-on-the-chin-and-cheek absorbing liner 23 shown in
More specifically, each of the pair of left and right sheet-like backing plates 33 and substantially central sheet-like backing plate 28 can be formed by molding an elastic, preferably non-permeable thin soft sheet material made of polyethylene, another soft synthetic resin, or the like into an appropriate shape. The average thickness of each of the pair of left and right sheet-like backing plates 33 and substantially central sheet-like backing plate 28 shown in
As shown in
As shown in
As shown in
(2) Specific Description on Ventilation System
As shown in
As shown in
The front end portions of the pair of left and right liner main body portions 25 of the impact-on-the-chin-and-cheek absorbing liner 23 shown in
The third ventilation opening 46 shown in
As shown in
As shown in
More specifically, in the embodiment shown in the drawings, the average width, average depth and average sectional area of the main part of the ventilation ridge groove (in other words, air passage) 51 shown in
(a) the average width of the main part of the ventilation ridge groove (in other words, air passage) 51 falls within a range of 4 mm to 16 mm (6 mm to 11 mm)
(b) the average depth of the main part of the ventilation ridge groove (in other words, air passage) 51 falls within a range of 2 mm to 8 mm (3 mm to 5.5 mm), and
(c) the average sectional area of the main part of the ventilation ridge groove (in other words, air passage) 51 falls within a range of 8 mm2 to 80 mm2 (12 mm2 to 40 mm2).
Regarding the width and sectional area of the start end of the substantially trumpet-shaped start end portion 52 shown in
The size (that is, area) of the third ventilation opening 46 (in other words, the central opening of the ventilation hole rim member 29) shown in
The second ventilation opening 47 shown in
Regarding the above respects, from the viewpoint of practice, the present invention generally preferably satisfies the numerical ranges described in the following items (d) to (j). The numerical ranges in parentheses described in the following items (d) to (j) are more preferable numerical ranges which are satisfied in the present invention.
(d) the area of the third ventilation opening 46 (when a plurality of openings 46 are provided, their total area) falls within a range of 3 cm2 to 40 cm2 (6 cm2 to 20 cm2),
(e) the area of the second ventilation opening 47 (when a plurality of ventilation openings 47 are provided, their total area) in the outer surfaces of the liner main body portions 25 falls within a range of 8 cm2 to 100 cm2 (16 cm2 to 46 cm2), and the area of each missing portion 45 (when a plurality of missing portions 45 are provided with each liner main body portion 25, their total area) in the outer surface of each of the pair of right and left liner main body portions 25 falls within a range of 4 cm2 to 50 cm2 (8 cm2 to 23 cm2),
(f) the area of the second ventilation opening 47 (when a plurality of openings 47 are provided, their total area) in the inner surfaces of the liner main body portions 25 falls within a range of 6 cm2 to 80 cm2 (12 cm2 to 38 cm2), and the area of each missing portion 45 (when a plurality of missing portions 45 are provided with each liner main body portion 25, their total area) in the inner surface of each of the pair of right and left liner main body portions 25 falls within a range of 3 cm2 to 40 cm2 (6 cm2 to 19 cm2),
(g) the value obtained by subtracting the area described in the above item (f) of the second ventilation opening 47 in the inner surfaces of the liner main body portions 25 from the area described in the above item (e) of the second ventilation opening 47 in the outer surfaces of the liner main body portions 25 falls within a range of 2 cm2 to 20 cm2 (4 cm2 to 8 cm2), and the value obtained by subtracting the area described in the above item (f) of each missing portion 47 in the outer surface of each of the pair of left and right liner main body portions 25 from the area described in the above item (d) of each missing portion 47 in the outer surface of each of the pair of left and right liner main body portions 25 falls within a range of 1 cm2 to 10 cm2 (2 cm2 to 4 cm2),
(h) the value obtained by subtracting the area described in the above item (d) of the third ventilation opening 46 from the area described in the above item (e) of the second ventilation opening 47 in the inner surfaces of the liner main body portions 25 falls within a range of 3 cm2 to 40 cm2 (6 cm2 to 18 cm2),
(i) the area of that projection of the substantially central sheet-like backing plate 28 which projects toward the second ventilation opening 47 in the inner surfaces of the pair of left and right liner main body portions 25 with a substantially equal width or the like falls within a range of 1.5 cm2 to 20 cm2 (3 cm2 to 9 cm2), and
(j) the average projection width of that projection 48 of the substantially central sheet-like backing plate 28 which projects toward the second ventilation opening 47 in the inner surfaces of the pair of left and right liner main body portions 25 falls within a range of 3 mm to 12 mm (4.5 mm to 8 mm).
The areas and projection width described in the above items (d) to (j) and the like are values obtained when the third and second ventilation openings 46 and 47 (including the missing portions 45) and projection 48 shown in
As described above, the front end portions of the pair of left and right liner main body portions 25 of the impact-on-the-chin-and-cheek absorbing liner 23 shown in
Of the impact-on-the-chin-and-cheek absorbing liner 23 shown in
A dustproof sheet made of a mesh-like dustproof material such as permeable, dustproof urethane foam can be arranged on the inner surface (more specifically, a portion between the inner surface of the air supply port forming member 42 and the outer surface of the substantially central sheet-like backing plate 28) of the air supply port forming member 42 shown in
The ventilation system of the full-face-type helmet 1 having the above arrangement shown in
More specifically, when the wearer wearing the full-face-type helmet 1 drives off-road or the like on a motorcycle, the external air (that is, the outer air) relatively flows into the vent ports (that is, the first ventilation openings) 43 serving as the air supply ports of the air supply port forming member 42 of the chin ventilator mechanism 41 substantially from the front surface. Part of the external air that has passed through the vent ports 43 relatively passes through the second ventilation opening 47 serving as an air supply port formed between the front end portions of the pair of left and right liner main body portions 25, and the third ventilation opening 46 serving as an air supply port formed in the substantially central sheet-like backing plate 28, and relatively flows into a region comprising the chin and its vicinity of the wearer (in other words, a region comprising the mouth and its vicinity).
Another part of the external air that has passed through the vent ports 43 relatively flows into the second ventilation opening 47 and the respective start end portions 52 of the pair of left and right air passages 51 respectively formed in the impact-on-the-chin-and-cheek absorbing liners 23. As shown in
The set of left and right external air currents (that is, air currents) relatively flowing into the respective start end portions 52 of the pair of left and right air passages 51 respectively flow through the pair of left and right air passages 51 shown in
Respective upper end portions 59 of the pair of left and right ventilation ridge grooves 57 are continuous to the another pair of left and right ventilation ridge grooves (in other words, air passages) 56. Hence, the set of left and right air currents relatively flowing along the pair of left and right ventilation ridge grooves 57 from their lower end portions 58 toward their upper end portions 59 mix with another set of left and right air currents relatively flowing in the pair of left and right ventilation ridge grooves 56 backward from the front portions. The mixed air currents then relatively flow in the pair of left and right ventilation ridge grooves 57 backward. The set of left and right air currents, another set of left and right air currents, and the set of left and right mixed air currents partly or entirely diffuse in a head accommodating space 60, when flowing in the ventilation ridge grooves 56 and 57, and are discharged outside through the exhaust hole of the head rear-side ventilator mechanism (not shown), the lower end of the head accommodating space 60, the vent hole 10 and the like. In the above description on the operation of the ventilation system, a description on the operation of ventilator mechanisms (not shown) (that is, the vertex ventilator mechanism, head rear-side ventilator mechanism and the like) other than the chin ventilator mechanism 41, and on air passages (not shown) related to these ventilator mechanisms are omitted.
Having described a specific preferred embodiment of this invention with reference to the accompanying drawings, it is to be understood that the invention is not limited to that precise embodiment, and that various changes and modifications may be effected therein by one skilled in the art without departing from the scope or spirit of the invention as defined in the appended claims.
For example, in the embodiment described above, the present invention is applied to the full-face-type helmet 1 in which the chin cover cannot be raised. However, the present invention can also be applied to a full-face-type helmet serving also as a jet-type helmet in which the chin cover can be raised.
In the embodiment described above, the liner main body portion of the impact-on-the-chin-and-cheek absorbing liner 23 comprises the left liner main body portion 25 and right liner main body portion 25. Alternatively, a liner main body portion in which the left liner main body portion 25 and right liner main body portion 25 are integrally molded can be used instead.
In the embodiment described above, the sheet-like backing plate 27 which is substantially arcuate when seen from the top comprises three pieces, i.e., the pair of left and right sheet-like backing plates 33 and the substantially central sheet-like backing plate 28. Alternatively, the three sheet-like backing plates 33 and 28 may be integrally molded to be sequentially continuous so the sheet-like backing plate 27 comprises one piece. Either one of the pair of left and right sheet-like backing plates 33, and the substantially central sheet-like backing plate 28 may be integrally molded so the sheet-like backing plate 27 comprises two pieces. The sheet-like backing plate 27 which is substantially arcuate when seen from the top may comprise only a pair of left and right sheet-like backing plates, in the same manner as in the case of the pair of left and right liner main body portions 25. In this case, missing portions may be formed respectively in the abutting portions of the pair of left and right sheet-like backing plates, so the pair of left and right missing portions form the third ventilation opening 46.
In the embodiment described above, the pair of left and right missing portions 47 respectively formed in the pair of left and right liner main body portions 25 form the second ventilation opening 47 in the liner main body portions 25. Alternatively, either one of the pair of left and right liner main body portions 25 may be formed long while the remaining one may be formed short, and a closed-loop-like ventilation opening similar to the second ventilation opening 47 may be formed in only the long liner main body portion 25.
In the embodiment described above, the third ventilation opening 46 is formed in the sheet-like backing plate 27. If external air need not flow into the third ventilation opening 46 toward the wearer's chin, the third ventilation opening 46 can be eliminated to form a closed surface. If a shutter (not shown) which opens/closes the third ventilation opening 46 is provided, the third ventilation opening 46 can be opened/closed, and its opening proportion can be changed.
In the embodiment described above, the channel spaces that respectively form the pair of left and right air passages to be respectively formed in the impact-on-the-chin-and-cheek absorbing liner 23 comprise only the pair of left and right ventilation ridge grooves 51 respectively formed in the pair of left and right liner main body portions 25. Alternatively, if a pair of left and right second ventilation ridge grooves are also formed in the sheet-like backing plate 27 to respectively oppose the pair of left and right ventilation ridge grooves 51, the pair of left and right ventilation ridge grooves 51 and the pair of left and right second ventilation ridge grooves can form a pair of left and right air passages. In place of the second ventilation ridge grooves, projections that project toward the ventilation ridge grooves 51 can be formed on the sheet-like backing plate 27 along the air passages 51 partly or entirely. In any of these cases, one or a plurality of pores can be formed in the sheet-like backing plate 27 so as to allow part of the air current flowing through the air channels 51 to flow in toward the inner side of the sheet-like backing plate 27.
In the embodiment described above, the male hooks 37 are formed on the outer surfaces of the pair of left and right inside pads 24, and the female hooks 35 are formed on the sheet-like backing plate 27. Alternatively, one or a plurality of, or all the female hooks 35 can be replaced with male hooks 37, and the original male hooks 37 that corresponded to the replacing female hooks 35 can be replaced with female hooks 35. Attaching tools to attach the pair of left and right inside pads 24 to the sheet-like backing plate 27 need not be round hooks each comprising a female hook 35 and male hook 37, but can be a surface fastener or the like.
Number | Date | Country | Kind |
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2005-206859 | Jul 2005 | JP | national |
Number | Name | Date | Kind |
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4555816 | Broersma | Dec 1985 | A |
4627115 | Broersma | Dec 1986 | A |
6289521 | Ikeda | Sep 2001 | B1 |
20070250991 | Pierce | Nov 2007 | A1 |
Number | Date | Country |
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3332577 | Mar 1985 | DE |
3419302 | Nov 1985 | DE |
Number | Date | Country | |
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20070011797 A1 | Jan 2007 | US |