The present invention relates to a fastening structure of an upper of a shoe, and a shoe.
Eyelets for inserting a shoelace are typically arranged left-right symmetrical and evenly spaced. Various proposals have been made in order to improve the fitting property of the upper to the foot (see, for example, the first patent document (FIG. 12) and the second patent document (FIG. 1)).
These documents disclose shoes having a partially widened interval between eyelets in each of the left and right eyelet rows.
These documents, however, fail to disclose improvement in the fitting property by the uneven interval setting.
One preferred aspect of the present invention is to improve the fitting property of the upper through the setting of eyelet intervals in the left and right eyelet rows.
Prior to describing the configuration of the present invention, the principle of the present invention will be described with reference to
The fastening force Fi at each eyelet is given by Expression (100) below.
F
i
=T*cos θi1+T*cos θi2 (100)
where T*cos θi1 and T*cos θi2 are each a component force of tension T in the foot width direction
The sum ΣFi of fastening forces in the foot width direction from the shoelace 40 is the sum ΣFi=(F1+F2+ . . . +Fi+ . . . Fn) obtained by adding together the fastening forces Fi. It is believed that the greater the sum ΣFi, the more likely the upper will fit the foot.
Now, assuming that the tension of the shoelace is uniform, the sum ΣFi of fastening forces increases by making the inclination angle θi1 and the inclination angle θi2 of
Now, if the eyelets are arranged generally evenly spaced (equidistant) as in the typical example of
In one aspect, a fastening structure of the present invention is a fastening structure of an upper of a shoe, wherein:
the upper defines a left eyelet row and a right eyelet row arranged along a longitudinal direction of the shoe;
the left and right eyelet rows each at least include a first eyelet on a tip side, and a second eyelet, a third eyelet and a fourth eyelet that are arranged in this order from the first eyelet toward a posterior side;
a first average interval D1 is defined as an average value between an interval in the longitudinal direction between the first eyelet and the second eyelet of the left eyelet row and that of the right eyelet row;
a second average interval D2 is defined as an average value between an interval in the longitudinal direction between the second eyelet and the third eyelet of the left eyelet row and that of the right eyelet row;
a third average interval D3 is defined as an average value between an interval in the longitudinal direction between the third eyelet and the fourth eyelet of the left eyelet row and that of the right eyelet row; and
Expressions (1) and (10) below are satisfied.
D
1
>D
2
<D
3 (1)
1.0*(D1+D2)>D1>0.6*(D1+D2) (10)
In this aspect, the second average interval D2 is smaller than the first average interval D1 and the third average interval D3. Therefore, as compared with a case where average intervals Di are equal, the sum ΣFi of fastening forces will be larger.
The present inventors sought for an eyelet arrangement that maximizes the sum ΣFi where the distance from the eyelet HL1, HR1 on the anterior side to the eyelet HLn, HRn on the posterior side is generally constant and the number of eyelets is constant. As a result, the present inventors found that the sum ΣFi is maximized when the average intervals D1 to Dn between eyelets of each eyelet row are alternately large and small as shown in
In a preferred embodiment of the present invention, the first average interval D1 is defined as an average value between an interval in the longitudinal direction between the first eyelet and the second eyelet of the left eyelet row and that of the right eyelet row; the second average interval D2 is defined as an average value between an interval in the longitudinal direction between the second eyelet and the third eyelet of the left eyelet row and that of the right eyelet row; and the third average interval D3 is defined as an average value between an interval in the longitudinal direction between the third eyelet and the fourth eyelet of the left eyelet row and that of the right eyelet row; and Expressions (1) and (10) below are satisfied.
D
1
>D
2
<D
3 (1)
1.0*(D1+D2)>D1>0.6*(D1+D2) (10)
In this case, the second average interval D2 between the first average interval D1 and the third average interval D3 is small, and the average intervals are alternately large and small, which can increase the total fastening. Therefore, it is possible to improve the fitting property.
As shown in Expression (10) above, the second average interval D2 is smaller than the first average interval D1. Therefore, the sum ΣFi of fastening forces increases as compared with a case where the average intervals Di are equal. This increases the fastening force at the second eyelet, where a large fastening force is needed, and it is possible to improve the fitting property.
Preferably, as shown in Expression (30) below, the third average interval D3 is set to a value that is greater than 0.65 times (D3+D4 (fourth average interval)). This increases the sum ΣFi of the fastening force as compared with a case where D3=D4, as will be described below.
More preferably, Expression (5) below is further satisfied.
1.0*(D2+D3)>D3>0.65*(D2+D3) (5)
In this expression, the third average interval D3 of
Note that also in
Preferably, the left and right eyelet rows each further include a fifth eyelet posterior to the fourth eyelet; a fourth average interval D4 is defined as an average value between an interval in the longitudinal direction between the fourth eyelet and the fifth eyelet of the left eyelet row and that of the right eyelet row; and Expression (6) below is satisfied.
D
1
>D
4
<D
3 (6)
In this case, the fourth average interval D4 is smaller than the first average interval D1 and the third average interval D3, which can increase the total fastening. Therefore, it is possible to improve the fitting property.
Preferably, Expression (7) below is further satisfied.
(D1+D2)>(D3+D4) (7)
A plurality of tendons extend along the longitudinal direction near the surface of the instep. These tendons rise when the toes are flexed. If the upper hinders this rise, it prevents smooth flexing of the foot. Particularly, the extensor hallucis longus tendon rises significantly above the MP joint. Therefore, it is preferred that the eyelets are arranged with a greater average interval between the first to third eyelets, which is located close to the MP joint, than between the third to fifth eyelets, which is remote from the MP joint.
That is, if the eyelets are arranged according to Expression (7) above, the fastening force at the first to third eyelets arranged with a large average interval is less likely to hinder the flexing of the foot, and it is therefore likely to realize smooth flexing of the foot while maintaining a high fitting property.
As will be described below, if the fourth average interval D4 is set to be sufficiently smaller than the second average interval D2, the fastening force may further increase.
Therefore, it is preferred that Expression (8) or (9) below is satisfied.
D
4
<D
2 (8)
(D2/D1)>(D4/D3) (9)
That is, depending on the application, the fastening force may be configured to be higher in the vicinity of the middle foot portion than the tip, as shown in Expression (9) above.
Conversely, depending on the application, the fastening force may be configured to be higher in the vicinity of the tip than the middle foot portion, as shown in Expression (9′) below.
(D2/D1)<(D4/D3) (9′)
Preferably, the fourth eyelet and the fifth eyelet are spaced apart from each other in a foot width direction, and an interval W4 between the fourth eyelet and the fifth eyelet in the foot width direction is greater than the fourth average interval D4.
If the fourth average interval D4 is decreased, the distance between eyelets may be too small, thereby partially lowering the strength of the upper, and making it more likely for the upper to rip due to the fastening force. For this, the ripping can be prevented by increasing the interval W4 in the foot width direction between the fourth eyelet and the fifth eyelet.
Any feature illustrated and/or depicted in conjunction with one of the aforementioned aspects or the following embodiments may be used in the same or similar form in one or more of the other aspects or other embodiments, and/or may be used in combination with, or in place of, any feature of the other aspects or embodiments.
The present invention will be understood more clearly from the following description of preferred embodiments taken in conjunction with the accompanying drawings. Note however that the embodiments and the drawings are merely illustrative and should not be taken to define the scope of the present invention. The scope of the present invention shall be defined only by the appended claims. In the accompanying drawings, like reference numerals denote like components throughout the plurality of figures.
Embodiments of the present invention will now be described with reference to the drawings.
In
In
As shown in
The shoelace 40 engages with the upper 41 at the eyelets for pulling together the left side (the medial side) of the upper and the right side (the lateral side) of the upper, and fitting the side foot portions of the upper to the foot.
While eyelets are through holes formed in the upper in this example, eyelets may be rings attached to the through holes. Alternatively, eyelets may be loops or U-shaped metals.
In the present fastening structure of
In the case of an athletic shoe, the number of eyelets is in many cases six for each of the left and right eyelet rows and, accordingly, the number of eyelets may be six for each of the left and right eyelet rows. The number of eyelets may be four on each side. When it is seven on each side, it is often the case that the shoelace 40 is not inserted through the seventh eyelets.
In
That is, it is expressed as follows.
First average interval D1: the value obtained by averaging the intervals in the longitudinal direction Y between the first eyelets HL1, HR1 and the second eyelets HL2, HR2 for the left and right eyelet rows.
Second average interval D2: the value obtained by averaging the intervals in the longitudinal direction Y between the second eyelets HL2, HR2 and the third eyelets HL3, HR3 for the left and right eyelet rows.
Third average interval D3: the value obtained by averaging the intervals in the longitudinal direction Y between the third eyelet HL3, HR3 and the fourth eyelet HL4, HR4 for the left and right eyelet rows.
Fourth average interval D4: the value obtained by averaging the intervals in the longitudinal direction Y between the fourth eyelet HL4, HR4 and the fifth eyelet HL5, HR5 for the left and right eyelet rows.
Herein, while the longitudinal direction Y may be considered as the longitudinal direction of the shoe, it only means the front-rear direction of the shoe in the present invention, and the direction does not need to be strictly defined. The reason is as follows.
As shown in
On the other hand, the present invention is defined by the differences or the ratio between the average intervals D1 to D4 of
On the other hand, this similarly applies also to a case where the left and right eyelet rows are asymmetric with each other as shown in the example of
In
That is, D1 to D3 are represented as shown in expressions below.
D
1=(L1+R1)/2
D
2=(L2+R2)/2
D
3=(L3+R3)/2
In other words, the ith average interval a is represented as the average value between the interval Li in the longitudinal direction Y between the left-side ith eyelet HLi and the left-side (i+1)th (next posterior) eyelet HLi+1 and the interval Ri in the longitudinal direction between the right-side ith eyelet HRi and the right-side (i+1)th (next posterior) eyelet HRi+1.
Another method for obtaining the average interval a of a final product of a shoe as shown in
In such a case, for the left-side eyelet row of eyelets HLi of
Then, the average value between the eyelet intervals Li and Ri is obtained as shown in the expression below.
D
i=(Li+Ri)/2
Note that as the method for obtaining intervals Li and Ri and the average interval Di between eyelets of the final product of
Next, the order among and the ratio between the average intervals D1 to D4 of
In the example of
D
1
>D
2
<D
3 (1)
D
1
>D
4
<D
3 (6)
1.0*(D1+D2)>D1>0.6*(D1+D2) (10)
1.0*(D3+D4)>D3>0.65*(D3+D4) (30)
The reason why the average intervals D1 to D4 are set as described above will now be described.
Referring to
Prior to the discussion, a reinforcement area was determined that is necessary to efficiently transmit the fastening force Fi from the shoelace to the upper. As a result of the calculation, it was found that the area α represented by a dotted pattern of
Now, how the area α has been determined as shown in
On the medial side of
On the lateral side of
Now, in
Therefore, it is preferred that the ratio D1/(D1+D2) is set to a value that is greater than 0.5. Thus, it is preferred that D1≥D2.
On the other hand, when the ratio D1/(D1+D2) of
Therefore, the first average interval D1 and the second average interval D2 preferably satisfy Expression (10) below, and more preferably satisfy Expression (11) below.
1.0*(D1+D2)>D1>0.6*(D1+D2) (10)
1.0*(D1+D2)>D1>0.65*(D1+D2) (11)
In Expressions (10) and (11) above, the value of the ratio D1/(D1+D2) is preferably greater than 0.6, and more preferably greater than 0.65. Note that since D2 takes a value that is greater than 0, the ratio D1/(D1+D2) is a value that is smaller than 1.
Next, in
When the ratio D3/(D3+D4) comes closer to 0 from 0.5, the sum ΣFi of fastening forces increases. However, this is on the precondition that the second average interval D2 is decreased as described above. Therefore, in
Therefore, it is preferred that the ratio D3/(D3+D4) is set to a value that is greater than 0.5. Thus, it is preferred that D3>D4.
On the other hand, when the ratio D3/(D3+D4) of
Therefore, the relationship between the third average interval D3 and the fourth average interval D4 preferably satisfies Expression (30) below, more preferably satisfies Expression (31) below, and most preferably satisfies Expression (32) below.
1.0*(D3+D4)>D3>0.65*(D3+D4) (30)
1.0*(D3+D4)>D3>0.7*(D3+D4) (31)
1.0*(D3+D4)>D3>0.75*(D3+D4) (32)
In Expressions (30) to (32) above, the value of the ratio D3/(D3+D4) is preferably greater than 0.65, more preferably greater than 0.7, and most preferably greater than 0.75. Note that since the fourth average interval D4 takes a value that is greater than 0, the ratio D3/(D3+D4) is a value that is smaller than 1.
Now, the positions at which the fourth to fifth eyelets are provided typically coincide with the middle foot portion and posterior to the toes. Therefore, there is less foot deformation, and the fourth eyelet HL4 (HR4) and the fifth eyelet HL5 (HR5) can be arranged spaced apart from each other in the foot width direction as shown in
That is, in the case of this example, the fourth eyelet HR4 (HL4) and the fifth eyelet HR5 (HL5) are spaced apart from each other in the foot width direction, and the interval W4 between the fourth eyelet and the fifth eyelet in the foot width direction is greater than the fourth average interval D4. In the case of FIG. 5A, while D3/(D3+D4) is set to be about 0.83, the shoelace can be arranged as shown in
From the discussion above, it can be seen that the relationship between the second average interval D2 and the fourth average interval D4 satisfies Expressions (8) and (9) below.
D
2
>D
4 (8)
(D2/D1)>(D4/D3) (9)
Note that there is no particular limitation on the upper limit of the large average interval a for the small average interval A as long as the shoelace can be arranged by providing the interval Wi (e.g., see W4) in the foot width direction.
Next, the relationship between the eyelet arrangement and the toes will be discussed.
When the tip of the big toe of the foot is raised, the extensor hallucis longus tendon significantly deforms upward. The area where the extensor hallucis longus tendon deforms significantly is directly above the MP joint, and is typically the area where the first eyelet HL1, HR1 of
Therefore, it will be preferred that the first to third eyelets are arranged more coarsely than the third to fifth eyelets as shown in Expression (7) below.
(D1+D2)>(D3+D4) (7)
Next, the relationship between the second average interval D2 and the third average interval D3 of
In light of the relationship between the third average interval D3 and the fourth average interval D4 of
Moreover, since ΣFi increases as the value of the ratio D3/(D3+D4) of
1.0*(D2+D3)>D3>0.6*(D2+D3) (5)
1.0*(D2+D3)>D3>0.65*(D2+D3) (50)
Note that the setting is such that D3/(D2+D3)=0.69 in the example of
As shown in
Since Li=Ri and Di=(Li+Ri)/2 as described above, Di=Li=Ri. Therefore, in the case of this example, the relational expressions (1), . . . , for the average intervals Di similarly hold true and apply for the eyelet intervals Li of the left row and for the eyelet intervals Ri of the right row.
Now, since the inclination angles θ12, etc., of
Next, an example of the specific structure of the upper will be described.
As shown in
In
In
As shown in these figures, the positions of the left and right eyelets may be asymmetric with each other. The number of eyelets may be four on each side or six on each side.
Now, where the left and right eyelet positions are asymmetric with each other as shown in
Next, the result of testing the actual foot conformity effect will be described. A foot conformity comparison was performed between an experimental example of this example shown in
While preferred embodiments have been described above with reference to the drawings, various obvious changes and modifications will readily occur to those skilled in the art upon reading the present specification.
For example, a heel counter that is continuous with the seventh eyelets may be provided in the heel portion.
The tongue in the central portion of the upper may be absent.
The number of eyelets may be four, five or eight or more on each side.
The eyelets may be arranged in an inclined direction along the ridgeline of the instep or may be arranged in the opposite arrangement, in which case the average intervals may be obtained in the longitudinal direction along the ridgeline, etc.
Thus, such changes and modifications are deemed to fall within the scope of the present invention, which is defined by the appended claims.
While the average intervals D1 to D4 are constant with typical structures, the average intervals D1 to D4 inevitably vary slightly depending on the manufacturing process. The differences between average intervals with the present fastening structure is preferably more than that caused by such variations.
The present invention is applicable to shoes having a lacing structure using a shoelace.
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2018/046294 | 12/17/2018 | WO | 00 |