JP2010203015A - Helmet and size-adjusting device for head band - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a helmet having excellent contactness of the helmet in the case of wearing the helmet by a person and a size-adjusting device for a head band enabling easy adjustment of the size of the head band with a single hand. <P>SOLUTION: The size-adjusting device 3 for the head band includes: the head band 5 having a straight part 13, a first circular arc part 15 and a second circular arc part 17 to form a band, wherein the circular arc parts 15, 17 form a downwardly convex form at the back of a helmet body 7 in the case of engaging the circular arc parts 15, 17 with each other to form a loop and attaching the loop to the helmet body 7 of the helmet 1; a head band guide 9 to guide the circular arc parts 15, 17; and a head band-adjusting body 11 to change the size of the loop head band 5 by rotating the body. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a protective cap and a headband size adjusting device used for the protective cap, and more particularly to a size adjusting device by rotating a handle (knob).

  2. Description of the Related Art Conventionally, a protective cap having a headband that is partially curved (arc-shaped) so as to wrap the back of the head of the wearer of the protective cap and that can be adjusted in size with a single touch is known (for example, Patent Documents). 1).

  When adjusting so that the size of the headband is reduced with the above-mentioned conventional protective cap, hold one size adjustment part of the headband with the left hand and use the right hand to place the other end of the headband into one size. Inserted into the adjustment section.

  When adjusting to increase the size of the headband, hold the size adjustment part of the headband with your left hand and press the size adjustment button.Use the right hand to move the other end of the headband to the other side. Pulled out from the size adjustment section.

Japanese Patent No. 4041365

  In the above-mentioned conventional protective cap, since the portion of the headband that wraps the back of the headband has an arc shape, the adhesion of the protective cap (headband) when the wearer wears the protective cap is excellent, The fit for the wearer is good. However, in the conventional protective cap, it is necessary to use both hands for adjusting the size of the headband. In addition, wearers of protective caps (persons engaged in work at nuclear power plants or power companies) often wear gloves, and there is a problem that it is difficult to adjust the headband when wearing gloves. .

  The present invention has been made in view of the above-mentioned problems. The wearability of the protective cap (headband) when the wearer wears a protective cap is excellent, and the wearer wears gloves, for example. However, it is an object of the present invention to provide a protective cap and a headband size adjusting device that can easily adjust the size of the headband with one hand.

  The invention according to claim 1 is a linear part, a first arcuate part formed at one end of the linear part, and a second arcuate form formed at the other end of the linear part. Each of the arc-shaped portions is formed in a ring shape by engaging the arc-shaped portions with each other and installed in a cap body of a protective cap. A headband that protrudes downward from the cap body, a headband guide body that guides each arc-shaped portion so that the arc-shaped portions of the headband engage with each other, and a headband guide body A headband adjusting body which is provided so as to be capable of rotational positioning and changes the size of the annular headband by rotating when the headband guide body guides each arc-shaped portion of the headband. A headband size adjusting device having

  According to a second aspect of the present invention, in the headband size adjusting apparatus according to the first aspect, a pinion is formed on the headband adjusting body, and the first arc-shaped portion includes the pinion and the pinion. A first rack that meshes is formed, and a second rack that meshes with the pinion is formed in the second arc-shaped portion, and the headband is based on the amount of rotation of the headband adjusting body. In order to make the movement amount of each arcuate portion relative to the guide body equal to each other, the pitches of the first rack and the pitch of the second rack are different from each other. It is a size adjustment device.

  According to a third aspect of the present invention, in the headband size adjusting apparatus according to the first or second aspect, the headband guide body is formed in a cylindrical shape, and each arc-shaped portion is a headband guide. The headband guide body and the respective arcuate portions guided by the headband guide body are guided by the through-holes of the headband guide body. A headband size adjusting device configured to be the smallest in the central portion of the headband guide body in the direction in which the hole extends and gradually increase toward the end of the headband guide body. It is.

  According to a fourth aspect of the present invention, in the headband size adjusting device according to any one of the first to third aspects, a part of the headband adjusting body is outside the headband guide body. Exposed, and at least one of the exposed portion of the headband adjustment body and the headband guide body is provided with a reinforcing portion for reinforcing the support strength of the headband adjustment body by the headband guide body. This is a headband size adjusting device.

  A fifth aspect of the present invention is a protective cap including the headband size adjusting device according to any one of the first to fourth aspects.

  According to the present invention, the adhesiveness of the protective cap (headband) when the wearer wears the protective cap is excellent, and even if the wearer wears gloves, for example, the headband can be easily attached with one hand. There is an effect that the size can be adjusted.

It is an expanded view which shows schematic structure of the headband 5 used for the size adjustment apparatus 3 of the headband in the protective cap 1 which concerns on embodiment of this invention. It is the figure which looked at the state which the wearer wore the protective cap 1 in which the size adjustment apparatus 3 of the headband was installed afterwards. It is the figure which looked at the state where the wearer wore the protective cap 1 in which the size adjustment device 3 of the headband was installed from the side. FIG. 3 is an exploded view of the headband size adjusting device 3, as viewed from the rear. FIG. 5 is a view of the headband size adjusting device 3 as seen from the rear in the same manner as in FIG. 4. It is VI arrow directional view in FIG. In FIG. 6, it is a figure which shows the state which removed the upper member 49. FIG. It is a figure which shows the VIII-VIII cross section in FIG. It is a figure which shows the headband adjustment body 11, (b) is a B arrow directional view in (a), (c) is a C arrow directional view in (b). It is a figure which shows the lower side member 51 of the headband guide body 9, (b) is a B arrow directional view in (a). It is a figure which shows the upper side member 49 of the headband guide body 9, (b) is a B arrow view in (a). It is a figure which shows the modification of the headband adjustment body 11, (b) is a B arrow directional view in (a), (c) is a C arrow directional view in (b).

  FIG. 1 is a developed view showing a schematic configuration of a headband 5 used in a headband size adjusting device 3 in a protective cap 1 according to an embodiment of the present invention, and FIG. 2 is a headband size adjusting device 3. FIG. 3 is a view of a state in which the wearer wears the protective cap 1 in which the wearer is installed. FIG. 3 is a side view of the state in which the wearer wears the protective cap 1 in which the headband size adjusting device 3 is installed. It is the figure seen from the direction.

  A protective cap (safety cap) 1 includes a bowl-shaped cap body 7, an impact absorbing liner (not shown) installed inside the cap body 7, a headband 5 and this size adjusting device 3, and a chin strap ( (Not shown), and the cap body 7 is supported by the wearer's head when the headband 5 contacts the wearer's head when the wearer wears the protective cap 1 To cover the head.

  A headband size adjusting device (hereinafter referred to as “size adjusting device”) 3 forms a headband 5 installed in a cap body 7 in an annular shape, and the diameter (peripheral length; Size), and includes a headband 5, a headband guide body 9, and a headband adjustment body 11.

  The headband 5 includes a linear portion 13, a first arc-shaped portion 15, and a second arc-shaped portion 17 and is formed in a band shape. The linear portion 13 is formed at the middle portion of the headband 5 in the longitudinal direction, and the first arc-shaped portion 15 is formed at one end portion of the linear portion 13 in the longitudinal direction. The part 17 is formed at the other end of the linear part 13 in the longitudinal direction.

  Further, when the respective arc-shaped portions 15 and 17 are engaged with each other (for example, overlapped) and formed in an annular shape (in a flat belt shape) and installed on the cap body 7 of the protective cap 1, the respective arc-shaped portions 15 and 17 are formed. Center C1 is located on the top side of the cap body 7 (see FIG. 2), and each arcuate portion 15 and 17 protrudes below the cap body 7 behind the cap body 7 (below the linear portion 13). (See FIG. 2 and FIG. 3).

  Note that not all of the arc-shaped portions 15 and 17 are overlapped with each other, and the size of the headband 5 is changed when it becomes an annular shape. Between the distal end portion (right end portion in FIG. 1) of the arc-shaped portion 15 and the intermediate portion in the longitudinal direction of the first arc-shaped portion 15 (may be the base end portion 19 that is a boundary with the linear portion 13). Even in the base portion 21 that is the boundary between the existing portion, the distal end portion (left end portion in FIG. 1) of the second arc-shaped portion 17 and the longitudinal portion of the second arc-shaped portion 17 (the linear portion). And the parts existing between them are superimposed on each other.

  The headband guide body 9 guides the arc-shaped portions 15 and 17 so that the arc-shaped portions 15 and 17 of the headband 5 overlap each other and the headband 5 is formed in an annular shape.

  The headband adjusting body 11 is provided on the headband guide body 9 so as to be rotatable and positionable. When the headband guide body 9 guides the arc-shaped portions 15 and 17 of the headband 5, the headband adjustment body 11 rotates with respect to the headband guide body 9, so that the diameter of the annular headband 5 is increased. (Size; length in which the arc-shaped portions 15 and 17 overlap each other) is changed.

  The headband adjusting body 11 is formed with a pinion (a pinion whose center axis coincides with the rotation center axis C2 of the headband adjusting body 11) (see FIG. 9). A first rack 25 is formed in the first arc-shaped portion 15 along the arc of the first arc-shaped portion 15 (substantially parallel to the arc). A second rack 27 is formed in the second arc-shaped portion 17 along the arc of the second arc-shaped portion 17 (substantially parallel to the arc) (see FIG. 1).

  The first rack 25 meshes with a portion on one side of the pinion 23 of the headband adjusting body 11, and the second rack 27 is on the other side of the pinion 23 of the headband adjusting body 11. It meshes with the part (see FIGS. 4 and 7). The portion of the pinion 23 meshing with the second rack 27 is opposite to the portion of the pinion 23 meshing with the first rack 25 with the rotation center axis C2 of the headband adjusting body 11 in between. Is located. For example, in FIG. 4, the portion of the pinion 23 that meshes with the first rack 25 is located below the center axis C2, and the portion of the pinion 23 that meshes with the second rack 27 is the center axis. Located above C2.

  Further, the amount of movement of each arc-shaped portion 15, 17 relative to the headband guide body 9 due to the amount of rotation of the headband adjusting body 11 (the arc-shaped portions 15, 17 move in opposite directions, and thus more accurately. (The absolute value of the movement amount of each arcuate portion 15, 17) is equal to each other, the pitch of the first rack 25 and the pitch of the second rack 27 are different from each other. ing.

  The headband guide body 9 is formed in a cylindrical shape, and each arcuate portion 15, 17 is configured to enter the through-hole of the headband guide body 11 and be overlapped and guided.

  The amount of the gap G between the headband guide body 9 and each of the arcuate portions 15 and 17 guided by the headband guide body 9 is such that the through-holes of the headband guide body 9 extend. It is the smallest at the center of the guide body 9, and gradually increases toward the end of the headband guide body 9 (see FIG. 5).

  The headband 5 is formed in an annular shape using the headband guide body 9 provided with the headband adjustment body 11, and the headband adjustment body 11, the headband guide body 9, and the headband 5 are combined with the cap body 7. The amount of the gap G gradually changes in the vertical direction of the cap body 7 and is almost constant in the front-rear direction of the cap body 7 (the direction perpendicular to the paper surface of FIG. 4). It has become.

  Here, the size adjusting device 3 will be described in more detail.

  As shown in FIGS. 4 to 8 and the like, the headband guide body 9 has a cylindrical shape and is formed in an arc shape similar to the arc-shaped portions 15 and 17 that overlap each other. The headband adjusting body 11 is the longitudinal direction of the headband guide body 9 (the direction through which the through-hole of the headband guide body 11 passes; the longitudinal direction of the arcuate portions 15 and 17 guided by the headband guide body 9. ) In the width direction of the headband guide body 9 (the width direction of the arc-shaped portions 15 and 17 guided by the headband guide body 9).

  In a state where the headband guide body 9 provided with the headband adjusting body 11 guides the arc-shaped portions 15 and 17 of the headband 5, as described above, the arc-shaped portions 15 overlapping each other. , 17 are located in the through-holes of the headband guide body 9 (the respective arcuate portions 15 and 17 overlapping each other are surrounded by the headband guide body 9).

  Further, the first arcuate portion 15 extends into the through hole of the headband guide body 9 from one end in the longitudinal direction of the headband guide body 9 over a predetermined length from the tip, and the second arcuate portion 17 also extends from the tip to the head from the other end in the longitudinal direction of the headband guide body 9 over a predetermined length (approximately the same length as the length of the first arcuate portion 15 entering the headband guide body 9). It enters the inside of the band guide body 9.

  When the headband adjusting body 11 rotates, the overlapping length of the arc-shaped portions 15 and 17 of the headband 5 changes, and the first circle entering the through hole of the headband guide body 9. The length of the arc-shaped portion 15 and the length of the second arc-shaped portion 17 entering the through hole of the headband guide body 9 are changed at an equal rate.

  For example, when the headband adjusting body 11 is rotated by an angle α in a predetermined direction with respect to the headband guide body 9, the first arcuate portion 15 is further passed through the through-hole of the headband guide body 9 by a predetermined length L1. The second arc-shaped portion 17 also enters the through-hole of the headband guide body 9 by a predetermined length L1, and the overlapping length of the arc-shaped portions 15 and 17 is increased. The size of 5 is made smaller. Further, since the headband adjusting body 11 is rotationally positioned, the size of the annular headband 5 once set is determined by applying an external force to the headband adjusting body 11 so that the headband adjusting body 11 is moved to the headband. As long as it does not rotate with respect to the guide body 9, it is maintained.

  The headband 5 is formed in an annular shape by using the headband guide body 9 provided with the headband adjustment body 11, and the headband adjustment body 11, the headband guide body 9 and the headband 5 are installed on the cap body 7. In this state (headband installation state), the other portions (the straight portions 13) other than the arc-shaped portions 15 and 17 of the headband 5 are slightly above the annular opening of the cap body 7. Inside the cap body 7, along the annular opening of the cap body 7, it exists from one side of the cap body 7 through the front to the other side (see FIG. 3).

  Further, in the headband installation state, the arc-shaped portions 15 and 17 and the headband guide body 9 of the headband 5 are located behind the cap body 7 below the opening of the cap body 7 (FIG. 2). FIG. 3). That is, the arc-shaped portions 15 and 17 and the headband guide body 9 of the headband 5 protrude in an arc shape on the rear side of the cap body 7 at the rear of the cap body 7 and overlap each other. The arcuate portions 15 and 17 and the central portion of the headband guide body 9 in the longitudinal direction are located on the lowermost side.

  Further, in the headband installation state, the headband adjusting body 11 protrudes from the headband guide body 9 in the rearward outside of the cap body 7 in the direction rearward, and is slightly oblique to the front-rear direction of the cap body 7 (front The rotation is positioned around an axis C2 extending obliquely (with the side positioned upward and the rear side positioned downward) (see FIG. 3).

  Note that the terms “upper” and “lower” used in this specification are in a state where the wearer of the protective cap 1 is standing. When the wearer wears the protective cap 1 with the headband installed, the annular headband 5 comes into contact with and surrounds the head of the wearer, and the cap body 7 is almost fixed to the wearer's head. It has become so. The headband 5 is provided with a locking portion 29 for installing the headband 5 on the cap body 7.

  More specifically, the headband 5 is integrally formed in a band shape by molding using a flexible material such as resin, for example. And in the state which is not cyclic | annular, the headband 5 is expand | deployed by flat form as shown in FIG.

  The linear portion 13 of the headband 5 is formed in a thin and elongated flat plate shape, and the first arc-shaped portion 15 extends in a straight line in the longitudinal direction in addition to being formed in a thin and elongated flat plate shape. It does not exist, and it bends and extends in an arc shape having a predetermined radius of curvature. Further, the first arcuate portion 15 extends from one end portion in the longitudinal direction of the linear portion 13 and is formed integrally with the linear portion 13. At the boundary 19 between the first arcuate part 15 and the linear part 13, the first arcuate part 15 does not bend sharply with respect to the linear part, and one side in the width direction of the linear part 13 ( It is gently bent in the lower part of FIG. Further, the center of the arc of the first arc-shaped portion 15 is located on the other side in the width direction of the linear portion 13 (upper side in FIG. 1). Furthermore, the longitudinal tip of the first arcuate portion 15 is formed in a semicircular shape.

  In addition, an oval first through-hole (a through-hole penetrating in the thickness direction of the first arc-shaped portion 15) 31 is formed at a substantially central portion of the first arc-shaped portion 15. Yes. The first oval through-hole 31 is bent in an arc shape in the longitudinal direction in the same manner as the first arc-shaped portion 15. The width and length of the first oval through-hole 31 are smaller than those of the first arcuate portion 15, and the longitudinal direction of the first oval through-hole 31 is the first It coincides with the longitudinal direction of the arcuate portion 15, and the width direction of the first oval through hole 31 coincides with the width direction of the first arcuate portion 15.

  A first rack 25 is formed in the first oval through hole 31. The first rack 25 has one side in the width direction of the first oval through-hole 31 (the longer side of two large arc-shaped sides facing each other; It is formed by repeating triangular or trapezoidal irregularities over almost the entire length of the side edge.

  The second arcuate portion 17 and the second oval through hole 33 are formed in the same manner as the first arcuate portion 15 and the first oval through hole 31. The second arcuate portion 17 and the second oval through-hole 33 pass through the center of the linear portion 13 in the width direction of the linear portion 13 (the longitudinal direction and the thickness direction of the linear portion 13). Are formed symmetrically with respect to a straight line L1 extending in a direction orthogonal to the vertical direction of FIG. That is, it is substantially formed in the left-right direction in FIG.

  However, the installation form of the second rack 27 formed in the second arcuate portion 17 and the first rack 25 formed in the first arcuate portion 15 are different.

  That is, the second rack 27 is not the other side in the width direction of the second oval through-hole 33 (not the longer side of the two large arc-shaped sides facing each other). The shorter side (the upper side in FIG. 1) is formed by repeating triangular or trapezoidal irregularities over almost the entire length.

  Further, the pitch of the second rack 27 is smaller than the pitch of the first rack 25. More specifically, the length of the side on which the first rack 25 is formed (the length of a large arc-shaped side when it is assumed that no rack is present) is the side on which the second rack 27 is formed. The length of the side on which the first rack 25 is formed and the length of the side on which the second rack 27 is formed, the pitch of the first rack 25 and the first The ratio of the pitch of the two racks 27 is equal to each other.

  The first arc-shaped portion 15 and the second arc-shaped portion 17 are coincident with each other in the width direction, and overlap with each other in the thickness direction so that an annular headband 5 is formed. ing.

  That is, in the state shown in FIG. 1, the central portion of the linear portion 13 is left on the paper surface, and the headband 5 is bent so that the first arcuate portion 15 side is in front of the paper surface of FIG. After that, the second arcuate part 17 is curved so that the second arcuate part 17 comes closer to the front than the first arcuate part 15, and the first arcuate part 15 and the second circle are curved. When the arcuate portions 17 are aligned with each other in the thickness direction with their positions in the width direction aligned, the state shown in FIG. 4 is obtained. The arcuate portions 15 and 17 shown in FIG. 4 are turned over from those shown in FIG.

  Each arcuate portion 15 and 17 is formed with a step 35 in the thickness direction (see FIGS. 1 and 8). By engaging these steps 35 with each other, when the arc-shaped portions 15 and 17 are overlapped with each other, the arc-shaped portions 15 and 17 are easily aligned with each other in the width direction. Thus, the respective arc-shaped portions 15 and 17 overlapping each other are easily moved in the longitudinal direction.

  More specifically, as shown in FIG. 1, the first arcuate portion 15 includes a first thick portion 37 that is a thick portion and a first thin portion 39 that is a thin portion. It is configured. The thickness of the first thick portion 37 is slightly thicker than the thickness of the linear portion 13, and the thickness of the first thin portion 39 is slightly thinner than the thickness of the linear portion 13. Yes. The boundary (step) 35 between the first thick portion 37 and the first thin portion 39 is formed at the center in the width direction of the first arc-shaped portion 15, and the first arc-shaped portion 15. It extends in an arc shape in the longitudinal direction. Further, the first thick portion 37 is formed on the side where the rack 25 is formed, and the first thin portion 39 is formed on the side where the rack 25 is not formed. Thus, by forming the rack 25 in the thick portion 37, the strength of the rack 25 can be increased.

  Similarly, the second arcuate portion 17 is also composed of a second thick portion 41 and a second thin portion 43, and the second thick portion 41 is on the side where the rack 27 is formed. The second thin portion 43 is formed on the side where the rack 27 is not formed.

  Then, when the arc-shaped portions 15 and 17 are overlapped with each other, as shown in FIG. 8, these steps 35 are engaged with each other. As understood from FIG. 8, when the respective arc-shaped portions 15 and 17 are overlapped with each other, the thickness in the overlapped portion is almost constant in any portion of the overlapped portion. In addition, a cross section (a cross section taken along a plane perpendicular to the longitudinal direction of each arc-shaped portion 15, 17) at a portion where each arc-shaped portion 15, 17 is overlapped with each other is an elongated rectangular shape.

  As shown in FIGS. 5 and 6, the headband guide body 9 includes a main body portion 45 formed in a rectangular cylindrical shape for guiding the arcuate portions 15 and 17 that overlap each other, and a headband adjustment. An annular headband adjusting body installation portion 47 for installing the body 11 is provided. Further, the headband guide body 9 can be divided into two members (an upper member 49 and a lower member 51) in order to facilitate the installation of the headband 5 and the headband adjusting body 11 on the headband guide body 9. (See FIG. 4 etc.). Each of the members 49 and 51 that can be divided is made of a material such as resin, and is integrally formed by molding, for example.

  In addition, the following description is made on the assumption that the headband guide body 9 is not divided into the upper member 49 and the lower member 51 for easy understanding.

  A cross section of the main body 45 of the headband guide body 9 (a cross section taken along a plane perpendicular to the longitudinal direction of the main body 45) is formed in a rectangular ring shape as shown in FIG. The height of the inner rectangle in the cross section of the main body 45 is slightly larger than the width of each arcuate portion 15, 17, and the width of the inner rectangle in the cross section of the main body 45 of the headband guide body 9. (Dimension in the left-right direction in FIG. 8) is slightly larger than the thickness of the arcuate portions 15 and 17 that overlap each other. Thus, the arc-shaped portions 15 and 17 can be guided by the main body 45 of the headband guide body 9 so that the arc-shaped portions 15 and 17 overlap each other, and are guided in this way. Each arcuate portion 15, 17 can move with respect to the main body portion 45 of the headband guide body 9 in this longitudinal direction (a direction orthogonal to the paper surface of FIG. 8).

  Further, the main body 45 of the headband guide body 9 is bent in an arc shape in this longitudinal direction (direction orthogonal to the paper surface of FIG. 8) in the same manner as the arc-shaped portions 15 and 17 overlapped with each other. Yes. That is, the main body portion 45 of the headband guide body 9 has four plate-like portions (first plate-like portion 53, second plate-like portion 55, third plate-like portion 57, 4 plate-like portions 59) and formed into a rectangular cylinder (see FIG. 5).

  When the headband 5 formed in an annular shape by the headband guide body 9 is installed in the cap body 7, the first plate-like portion 53 is located on the head side of the wearer of the protective cap 1 and contacts the head The second plate-like portion 55 is a portion located on the opposite side of the first plate-like portion 53 with the arc-shaped portions 15 and 17 overlapping each other in between, The third plate-like portion 57 is a portion that connects the first plate-like portion 53 and the second plate-like portion 55 to each other above the respective arc-shaped portions 15 and 17 that overlap each other. The fourth plate-like portion 59 is a portion that connects the first plate-like portion 53 and the second plate-like portion 55 to each other below the respective arc-shaped portions 15 and 17 that are overlapped with each other. is there.

  Note that the lengths of the second plate-like portion 55 and the fourth plate-like portion 59 (the dimensions in the left-right direction in FIG. 5) are substantially equal to each other, but the first plate-like portion 53 is the first plate-like portion 53. The second plate-like portion 55 and the fourth plate-like portion 59 are longer, and the third plate-like portion 57 is shorter than the second plate-like portion 55 and the fourth plate-like portion 59. Yes. Thereby, the freedom degree of the play of each arc-shaped part 15 and 17 with respect to the main-body part 45 of the headband guide body 9 is enlarged, enlarging the area of the main-body part 45 of the headband guide body 9 which contacts a wearer's head. The headband 5 and the headband guide body 9 can be easily matched with the shape of the wearer's head.

  The headband adjustment body installation portion 47 of the headband guide body 9 is provided at the center portion of the main body portion 45 of the headband guide body 9 (center portion of the second plate-like portion 55). A center axis C2 (the same axis as the rotation center axis of the headband adjusting body 11) C2 of the headband adjusting body installation portion 47 extends in the thickness direction of the first plate-like portion 53 and the second plate-like portion 55. The headband adjustment body installation portion 47 is provided so as to protrude from the second plate-like portion 55. Further, a short columnar internal space 61 is formed between the headband adjusting body installation portion 47 and the second plate-like portion 55 (see FIG. 7).

  The headband adjusting body 11 is molded, for example, with resin or the like. As shown in FIG. 9, the pinion 23, the annular ratchet teeth 63, the columnar or cylindrical main body 65, and the like. And a disc-shaped handle portion 67. The pinion 23, the ratchet tooth portion 63, the columnar or cylindrical main body portion 65, and the disc-shaped handle portion 67 are arranged coaxially in this order. The outer diameter of the main body portion 65 is larger than the outer diameter of the pinion 23, and the outer diameter of the handle portion 67 is larger than the outer diameter of the main body portion 65. The ratchet teeth 63 are formed on the end surface of the main body 65 (the end surface on the pinion 23 side). Further, on the outer periphery of the main body 65, there is provided a biasing portion 71 having elasticity for biasing the ratchet teeth 63 to the ratchet claw (projection) 69 (see FIG. 10A). .

  A portion closer to the pinion 23 than the intermediate portion (intermediate portion in the direction of the axis C2) in the main body portion 65 of the headband adjusting body 11 enters the headband guide body 9, and the main body portion 45 of the headband guide body 9 By engaging with the headband adjustment body installation portion 47, the headband adjustment body 11 rotates about the axis C <b> 2 with respect to the headband guide body 9.

  Further, in this engaged state, the pinion 23 is located in the through hole of the main body 45 of the headband adjusting body 9. Furthermore, the tip of the pinion 23 is engaged with the recess 73 of the first plate-like part 53 and supported by the main body 45 (see FIG. 7).

  The oval through holes 31 and 33 of the arcuate portions 15 and 17 that are guided by the headband guide body 9 and overlap each other substantially overlap each other, and the overlapping through holes 31 and 33 overlap each other. The first rack 25 is located on one side and the second rack 27 is located on the other side (see FIG. 4). Then, one end of the pinion 23 of the headband adjusting body 11 installed on the headband guide body 9 (a part of the teeth located on the lower side) is guided by the headband guide body 9 to each other. Is engaged with the first rack 25 of the first arcuate part 15 and the other end of the pinion 23 (the other part of the teeth located on the upper side) is the second arcuate part. It is engaged with 17 second racks 27.

  When the headband adjusting body 11 is rotated in this engaged state, the first arc-shaped portion 15 and the second arc-shaped portion 17 move in opposite directions, and the headband 5 The size is adjusted.

  In addition, on one end surface (the bottom surface on the main body 45 side) of the cylindrical internal space 61 formed between the headband adjustment body installation portion 47 and the second plate-like portion 55 of the headband adjustment body 11. Is provided with a protrusion 69 that engages with the ratchet teeth 63, and the biasing portion 71 of the headband adjusting body 11 presses the other end surface of the cylindrical inner space 61, thereby causing the ratchet teeth 63 is biased toward the protrusion 69, and the headband adjusting body 11 once rotated and positioned is not easily rotated. As a result, the size of the annular headband 5 once adjusted in size is not easily changed.

  Here, the division of the headband guide body 11 will be described.

  As shown in FIG. 4, the headband guide body 11 includes the rotation center axis C <b> 2 of the headband adjustment body 11, and extends in the longitudinal direction of the main body 45 along the arc of the main body 45 of the headband guide 11. The upper member 49 and the lower member 51 can be divided by an arcuate surface. As described above, the division is performed when the arc-shaped portions 15 and 17 and the headband adjusting body 11 are formed on the headband guide body 11.

  By the way, when the arc-shaped portions 15 and 17 are overlapped with each other to form the headband 5 in an annular shape and installed in the cap body 7 of the protective cap 1, the width direction of the headband 5 is the cap body 7 as already understood. Of the headband 5 substantially coincides with the direction in which the headband 5 is connected to each other, the thickness direction of the headband 5 substantially coincides with the thickness direction of the flesh of the cap body 7, and the longitudinal direction of the headband 5 The edge of the opening of the body 7 extends.

  Further, in the state where the headband 5 is installed in this way, the portion where the arcuate portions 15 and 17 overlap, the headband guide body 9 and the headband adjusting body 11 are located behind the cap body 7. The portion where the arcuate portions 15 and 17 overlap and the headband guide body 9 are located at the lowest position in the portion immediately behind the cap body 7.

  Further, by rotating the headband adjusting body 11, the lengths of the overlapping arc-shaped portions 15 and 17 change, but even if the length of the overlapping arc-shaped portions 15 and 17 is the longest. The second plate-like portion 55 and the fourth plate-like portion 59 are slightly longer than the overlapping length. When the lengths of the overlapping arc-shaped portions 15 and 17 are the longest, the third plate-shaped portion 57 is slightly shorter than the length of the overlapping arc-shaped portions.

  In addition, as shown in FIG. 5, the gaps (main body portions) between the through holes of the main body portion 45 of the headband guide body 9 and the arc-shaped portions 15 and 17 that overlap each other and are guided by the headband guide body 9. 45 is a gap in the height direction of the through-holes 45; a gap in the width direction of the arc-shaped portions 15 and 17 overlapping each other) G is a central portion in the longitudinal direction of the main body 45 of the headband guide body 9. It is the smallest and very small value, and gradually increases toward the end of the main body 45 of the headband guide body 9 in the longitudinal direction. On the other hand, the value of the gap in the width direction of the through hole of the main body 45 (the gap in the thickness direction of the respective arcuate portions 15 and 17 overlapping each other) is an almost constant and very small value. .

  The assembly procedure of the size adjusting device 3 will be described.

  This procedure may be performed in a state where the headband 5 is installed on the cap body 7, or may be performed in a state where the headband 5 is not installed.

  First, the arc-shaped portions 15 and 17 of the headband 5 shown in FIG. At this time, the overlapping length of the arcuate portions 15 and 17 is minimized. That is, the overlapping portions of the through holes 31 and 33 are made substantially circular.

  Subsequently, the pinion 23 of the headband adjusting body 11 is inserted into the through holes 31 and 33, and the arcuate portions 15 and 17 into which the pinion is inserted are connected to the lower member 51 (upper member 49) of the headband guide body 9. May be provided) (see FIG. 7).

  Subsequently, the upper member 49 is integrally installed on the lower member 51 by bonding or caulking using heat.

  Thereafter, if the headband adjusting body 11 is rotated, the size of the headband 5 can be adjusted.

  According to the size adjusting device 3, each arcuate portion 15, 17 is provided with the headband 5 that protrudes in an arc shape behind the cap body 7 and below the cap body 7, and rotates the headband adjuster 11. By doing so, since the size of the annular headband 5 can be changed, the adhesion of the protective cap 1 (headband 5) when the wearer wears the protective cap 1 can be made excellent. At the same time, even if the wearer wears gloves, for example, the size of the headband 5 can be easily adjusted with one hand.

  Further, according to the size adjusting device 3, since the moving amounts of the arc-shaped portions 15 and 17 due to the rotation amount of the headband adjusting body 11 are equal to each other, even if the size of the headband 5 is adjusted. Each of the arc-shaped portions 15 and 17 (headband guide body 11) is always positioned behind the cap body 7 without shifting to the side of the cap body 7, and is protected regardless of the size adjustment of the headband 5. The wearer of the cap 1 can obtain a good fit.

  Further, according to the size adjusting device 3, the gap G between the headband guide body 9 and the arcuate portions 15 and 17 guided by the headband guide body 9 is directed toward the end of the headband guide body 9. Accordingly, the degree of freedom of play of the arc-shaped portions 15 and 17 with respect to the headband guide body 9 can be increased, and the headband 5 and the headband guide body 9 can be attached to the wearer's head. It becomes easy to match the shape.

  By the way, in the size adjustment apparatus 3, the support strength of the headband adjustment body 11 may be reinforced.

  That is, a part of the headband adjusting body 11 is exposed outside the headband guide body 9 as already understood, and the other part of the headband adjusting body 11 is exposed inside the headband guide body 9. It enters and engages with the headband guide body 9.

  The exposed portion of the headband adjusting body 11 facing the headband guide body 9 and the portion of the headband guide body 9 facing the exposed portion (the annular plane of the headband adjusting body installation portion 47) At least one of 47A may be provided with a reinforcing portion 74 for reinforcing the support strength of the headband adjusting body 11 by the headband guide body 9.

  The reinforcing portion 74 can reinforce the support strength of the headband adjusting body 11 by the headband guide body 9 against an external force other than the moment around the rotation center axis C2 of the headband adjusting body 11.

  Specifically, as shown in FIG. 12, a spoke portion 75 is formed in the handle portion 67 of the headband adjusting body 11. In other words, the plurality of through holes 77 are arranged so as to equally distribute the circumferential direction of the handle portion 67.

  Therefore, each spoke part 75 is extended by a predetermined distance toward the cylindrical main body part 65 side. When the headband adjustment body 11 is installed on the headband guide body 9, each distal end portion (end portion on the pinion 23 side) 75 </ b> A of the spoke portion 75 becomes a rib, and the annular shape of the headband adjustment body installation portion 47. It contacts the flat surface 47A. As a result, the above-described support strength can be enhanced.

  In a normal state, a slight gap is formed between each tip 75A of the spoke portion 75 and the annular flat surface 47A of the headband adjustment body installation portion 47, and an external force is applied to the headband adjustment body 11. It may be configured that only the front end portions 75A of the spoke portions 75 and the annular flat surface 47A of the headband adjusting body installation portion 47 are in contact with each other.

  Due to such reinforcement, even if the protective cap 1 is accidentally dropped and an impact is generated on the headband adjusting body 11, the urging portion 71 of the headband adjusting body 11 is broken and damaged by the impact. Can be avoided.

DESCRIPTION OF SYMBOLS 1 Protective cap 3 Size adjustment apparatus 5 Headband 7 Cap body 9 Headband guide body 11 Headband adjustment body 13 Linear part 15 1st circular arc part 17 2nd circular arc part 23 Pinion 25 1st rack 27 1st rack Two racks 74 Reinforcement section G Gap

Claims (5)

A linear portion, a first arc-shaped portion formed at one end of the linear portion, and a second arc-shaped portion formed at the other end of the linear portion are formed in a band shape. When each arc-shaped portion is engaged with each other and formed into an annular shape and installed on the cap body of the protective cap, each arc-shaped portion protrudes below the cap body behind the cap body. With a headband;
A headband guide body for guiding the arc-shaped portions so that the arc-shaped portions of the headband engage with each other;
The headband guide body is provided so as to be rotatable and positionable. When the headband guide body guides each arc-shaped portion of the headband, the headband guide body rotates to change the size of the annular headband. A headband adjuster;
A headband size adjusting device comprising: The headband size adjusting apparatus according to claim 1,
A pinion is formed on the headband adjusting body,
The first arcuate portion is formed with a first rack that meshes with the pinion,
The second arcuate portion is formed with a second rack that meshes with the pinion,
In order to make the amount of movement of each arcuate portion relative to the headband guide body due to the amount of rotation of the headband adjustment body equal to each other, the pitch of the first rack and the second rack The headband size adjusting device, wherein the pitches of the headbands are different from each other. In the size adjustment apparatus of the headband of Claim 1 or Claim 2,
The headband guide body is formed in a cylindrical shape, and each arcuate portion is configured to be guided through a through hole of the headband guide body,
The amount of the gap between the headband guide body and each arcuate portion guided by the headband guide body is the direction in which the through hole of the headband guide body extends, and the center portion of the headband guide body The headband size adjusting device is characterized in that the size of the headband is configured to become the smallest and gradually increase toward the end of the headband guide body. In the size adjustment apparatus of the headband of any one of Claims 1-3,
A part of the headband adjustment body is exposed outside the headband guide body,
At least one of the exposed portion of the headband adjustment body and the headband guide body is provided with a reinforcing portion for reinforcing the support strength of the headband adjustment body by the headband guide body. Headband size adjustment device.   A protective cap comprising the headband size adjusting device according to any one of claims 1 to 4.

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