JP2024011995A - Helmet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a helmet capable of effectively forming air flow between an accommodating unit and the outside of the helmet.

SOLUTION: A helmet 1 of this disclosure includes: a cap body 10 that has an opening 11a and forms an outer shape; a blower unit 30 that is attached to a back surface 12b of the cap body 10 and blows air between inside and outside of the cap body 10; a partition 20 that is arranged along an inner surface of the cap body 10; an accommodating unit 11b that is formed inside the cap body 10 continuously with the opening 11a of the cap body 10; and a flow path F that guides air flowing by the blower unit 30 between the accommodation unit 11b and outside of the cap body 10, wherein the partition 20 has through holes (28a, 28b) that partition the accommodating unit 11b and the flow path F inside the cap body 10 and communicate the accommodating unit 11b with the flow path F.

SELECTED DRAWING: Figure 10

COPYRIGHT: (C)2024,JPO&INPIT

Description

The present disclosure relates to a helmet.

2. Description of the Related Art Conventionally, techniques related to helmets equipped with air blowers have been known from the viewpoint of measures against heat. For example, Patent Document 1 discloses a helmet with a built-in blower that can improve both the strength of the cap body and the blowing efficiency. Such a helmet has a cap body having an opening in the upper rear part, a shock absorbing liner, and a blower that is disposed in the opening and can be rotated forward and backward. The liner has a downwardly opening recess on its inner surface. The recesses include a first recess that passes under the top of the cap body and is long in the front and back and whose rear end faces the opening, and a second recess that is located around the top of the cap body 2 and communicates with the first recess and opens left and right. and a recess.

JP 2018-150661 Publication

In such conventional technology, a flow path through which air flows and a housing section that accommodates the top of a worker's head, for example, are clearly separated inside the helmet, and the air flow is controlled between the housing section and the outside of the helmet. Not enough consideration was given to effective formation.

An object of the present disclosure is to provide a helmet that can effectively form an air flow between a housing part and the outside of the helmet.

This disclosure:
(1)
a cap body having an opening and forming an outer shape;
a blower unit attached to the back surface of the cap body and blowing air between the inside and outside of the cap body;
a partition portion disposed along the inner surface of the cap body;
an accommodating portion formed inside the cap body continuously with the opening of the cap body;
a flow path that guides air flowing by the blowing section between the storage section and the outside of the cap body;
Equipped with
The partition section partitions the accommodating section and the flow path inside the cap body, and has a through hole that communicates the accommodating section and the flow path.
Helmet,
It is.

(2)
In the helmet described in (1) above,
The partition portion has a base portion disposed along the back surface of the helmet, and a pair of extending portions extending in a bifurcated shape from the base portion along both side surfaces of the helmet,
The flow path may include an internal space that is formed between the partition portion and the inner surface of the cap body, and that extends from the back surface portion to the both side surface portions.

(3)
In the helmet described in (2) above,
The base portion may cover the entire ventilation opening of the ventilation section from the inside of the cap body.

(4)
In the helmet described in (2) or (3) above,
The base portion may have a plurality of the through holes.

(5)
In the helmet described in any one of (2) to (4) above,
The extending portion may have a plurality of the through holes.

(6)
In the helmet described in (5) above,
In the extension part, the diameter of the through hole closest to the back surface may be smaller than the diameter of the through hole furthest from the back surface.

(7)
In the helmet described in (6) above,
The extending portion may have a plurality of through holes arranged from the back side toward the tip of the extending portion, the hole diameter of which gradually increases from the back portion toward the tip.

(8)
The helmet according to any one of (2) to (7) above,
The device may further include a protuberance on the outer surface of the side surface that protrudes along the flow path located on the opposite side of the outer surface.

(9)
In the helmet described in any one of (1) to (8) above,
The partition portion may include a partition member configured to be detachably attached to the cap body.

(10)
The helmet according to any one of (1) to (9) above,
It may further include a sound absorbing material disposed in the flow path.

(11)
The helmet according to any one of (1) to (10) above,
further comprising a sensor section attached to the cap body,
The blower unit may be turned on when the outside air temperature detected by the sensor unit exceeds a threshold value, and may be turned off when the outside air temperature is below the threshold value.

(12)
In the helmet described in (11) above,
The air blower may increase its output as the outside air temperature increases.

According to the present disclosure, it is possible to provide a helmet that can effectively form air flow between the housing section and the outside of the helmet.

FIG. 1 is a perspective view showing the appearance of a helmet according to an embodiment of the present disclosure. FIG. 2 is a front view of the helmet of FIG. 1; FIG. 2 is a rear view of the helmet of FIG. 1; FIG. 2 is a right side view of the helmet of FIG. 1; FIG. 2 is a left side view of the helmet of FIG. 1; FIG. 2 is a top view of the helmet of FIG. 1; FIG. 2 is a bottom view of the helmet of FIG. 1; FIG. 2 is a functional block diagram showing part of the configuration of the helmet shown in FIG. 1. FIG. FIG. 2 is a perspective view showing the appearance of a partition member installed inside the helmet of FIG. 1. FIG. FIG. 2 is a sectional view taken along the line XX in FIG. 1. FIG. FIG. 2 is a sectional view taken along the XI-XI arrow line in FIG. 1. FIG. 2 is a flowchart illustrating an example of a method for blowing air into the helmet of FIG. 1. FIG. FIG. 7 is a perspective view showing the appearance of a helmet according to a first modification. FIG. 7 is a perspective view showing the appearance of a helmet according to a second modification.

Hereinafter, one embodiment of the present disclosure will be mainly described with reference to the accompanying drawings.

FIG. 1 is a perspective view showing the appearance of a helmet 1 according to an embodiment of the present disclosure. FIG. 2 is a front view of the helmet 1 of FIG. 1. FIG. 3 is a rear view of the helmet 1 of FIG. 1. FIG. 4 is a right side view of the helmet 1 in FIG. 1. FIG. 5 is a left side view of the helmet 1 in FIG. 1. FIG. 6 is a top view of the helmet 1 in FIG. 1. FIG. 7 is a bottom view of the helmet 1 of FIG. 1. FIG. 8 is a functional block diagram showing a part of the configuration of the helmet 1 in FIG. 1.

In the present disclosure, the "upper surface side" corresponds to, for example, the top side of the helmet 1. The "bottom side" corresponds to, for example, the side opposite to the top side, and corresponds to the opening 11a side, which will be described later. The "vertical direction" corresponds to, for example, the direction connecting the opening 11a and the apex. The "left-right direction" corresponds to, for example, a direction connecting a pair of side surfaces 12c, which will be described later. The "front-back direction" corresponds to, for example, a direction connecting a front section 12a and a back section 12b, which will be described later.

As shown in FIG. 7, the helmet 1 according to one embodiment has two main components: a cap body 10 and a partition member 20. The partition member 20 corresponds to a "partition part" described in the claims. As shown in FIG. 8, the helmet 1 includes, in addition to the cap body 10 and the partition member 20, a blower section 30, a power supply section 40, a sensor section 50, a connector section 60, a switching section 70, and a control section 80.

The cap body 10 is made of acrylonitrile butadiene styrene (ABS), polyethylene (PE), polycarbonate (PC), FRP made of polyester resin reinforced with glass resin, polyarylene sulfide (PAS) such as polylactic acid (PLA), polyphenylene sulfide (PPS), etc. ), and any resin material such as polyetheretherketone (PEEK). The cap body 10 is formed into a dome shape as shown in FIGS. 1 to 7. The cap body 10 forms the outer shape of the helmet 1.

As shown in FIG. 7, the cap body 10 has an opening 11a formed on the bottom side of the helmet 1. The cap body 10 has a first accommodating portion 11b formed inside the cap body 10 so as to be continuous with the opening 11a. The first accommodating section 11b corresponds to a "accommodating section" described in the claims. The first accommodating portion 11b accommodates, for example, the top of the head of a user as a worker.

As shown in FIGS. 1 to 6, the cap body 10 has a main body portion 12 that is formed continuously from the opening 11a and surrounds the space inside the cap body 10 including the first accommodating portion 11b from the outside. The main body part 12 has a front part 12a located at the front of the helmet 1 and a back part 12b located at the back of the helmet 1. The main body part 12 has a pair of side parts 12c that connect the front part 12a and the back part 12b on both sides in the left-right direction. The main body portion 12 has an upper surface portion 12d that connects a front portion 12a, a back portion 12b, and a pair of side portions 12c on the upper surface side of the helmet 1.

The cap body 10 has a first protrusion 13 that protrudes one step outward from the outer surface of the side surface 12c. The first raised portion 13 continuously extends from the back surface portion 12b to the front surface portion 12a via the upper surface side portion of the side surface portion 12c.

As shown in FIGS. 4 and 5, the edge E1 on the bottom side of the first protruding portion 13 draws a parabola from the end on the bottom side of the back surface portion 12b toward the top surface side, and extends toward the top surface side of the front surface portion 12a. down to the parts. The edge E2 on the upper surface side of the first raised portion 13 extends from the upper surface side end of the back surface portion 12b to the center portion of the front portion 12a in the vertical direction while drawing a curve along the edge of the upper surface portion 12d.

The first raised portion 13 is formed in a streamlined shape, and is widest on the back side 12b and becomes narrower toward the front side 12a. For example, the width of the first raised portion 13 corresponds to the vertical width between the edge E1 and the edge E2.

As shown in FIGS. 1 and 6, the cap body 10 has a second protrusion 14 that protrudes one step outward from the outer surface of the upper surface 12d at the center portion of the upper surface 12d in the left-right direction. The second raised portion 14 extends continuously from the back surface portion 12b to the front surface portion 12a.

Each of the pair of edges E3 located on both sides of the second raised portion 14 in the left-right direction draws a wavy line-like shape along the up-down direction from the end on the upper surface side of the back surface portion 12b, and extends toward the upper surface side of the front surface portion 12a. reaches the end of the A pair of edges E3 of the second raised portion 14 are formed to be line symmetrical in the left-right direction.

The second raised portion 14 is widest at the central portion in the front-rear direction, and becomes narrower as it goes from the central portion toward the front portion 12a side. For example, the width of the second raised portion 14 corresponds to the left-right width between the pair of edges E3.

As shown in FIGS. 3 to 6, the cap body 10 has a second accommodating portion 15 that largely protrudes outward at the back surface portion 12b. The second accommodating part 15 has a ventilation louver 15a formed in the upper half of the second accommodating part 15. The second accommodating section 15 accommodates the blower section 30 inside the louver 15a.

As shown in FIG. 4 , the second accommodating portion 15 accommodates the connector portion 60 at the lower end on the right side of the second accommodating portion 15 . The second accommodating portion 15 exposes the terminal portion of the connector portion 60 accommodated inside the second accommodating portion 15 to the outside. The second accommodating portion 15 accommodates the connector portion 60 so that a corresponding mating connector can be connected to the connector portion 60 from the outside.

As shown in FIG. 5 , the second accommodating portion 15 accommodates the switching portion 70 at the lower end portion on the left side of the second accommodating portion 15 . The second accommodating part 15 exposes the operation part of the switching part 70 accommodated inside the second accommodating part 15 to the outside. The second accommodating section 15 accommodates the switching section 70 so that the user can perform a switch operation on the switching section 70.

The second accommodating section 15 accommodates the power supply section 40 in a state located directly below the air blowing section 30 located inside the louver 15a. The second accommodating part 15 accommodates the power supply part 40 inside the second accommodating part 15 in a state where it is completely hidden from the outside. The second housing section 15 houses the control section 80 in a state located directly below the power supply section 40 . The second accommodating part 15 accommodates the control part 80 inside the second accommodating part 15 in a state where it is completely hidden from the outside. The second accommodating section 15 accommodates the sensor section 50 in a state where it is located on the left side with respect to the blowing section 30 located inside the louver 15a. The second accommodating part 15 accommodates the sensor part 50 inside the second accommodating part 15 in a state where it is completely hidden from the outside.

The air blower 30 accommodated in the second housing section 15 includes an arbitrary air blowing mechanism. For example, the blower section 30 includes a fan having a motor and rotary blades that are rotated around a predetermined axis by the motor. The air blower 30 includes, for example, a highly silent fan. The blower section 30 is attached to the back surface 12b of the cap body 10 and flows air between the inside and the outside of the cap body 10. For example, the blower section 30 takes in air from outside the cap body 10 and sends the air into the inside of the cap body 10 . That is, the air blower 30 generates wind toward the inside of the cap body 10.

The power supply section 40 housed in the second housing section 15 includes an arbitrary battery that supplies power for realizing the ventilation operation using the ventilation section 30 in the helmet 1 . The power supply unit 40 includes, for example, a secondary battery. The power supply section 40 may include, for example, a lithium ion battery that can be charged via the connector section 60, or any battery that can be charged without contact.

The sensor section 50 housed in the second housing section 15 includes an arbitrary sensor element for realizing air blowing control using the air blowing section 30 in the helmet 1. The sensor unit 50 includes, for example, a temperature sensor. The sensor unit 50 detects the outside air temperature around the helmet 1 using, for example, a temperature sensor attached to the cap body 10. The sensor section 50 outputs the detected outside air temperature to the control section 80 as a detection signal.

The connector section 60 accommodated in the second housing section 15 includes any connectors necessary for realizing the ventilation operation using the ventilation section 30 in the helmet 1. The connector section 60 includes, for example, a USB (Universal Serial Bus) connector. The connector section 60 is connected to an external power source via a cable such as a USB cable, and is used to charge the power source section 40 by receiving necessary power.

The switching unit 70 accommodated in the second housing unit 15 includes an arbitrary switch for switching the state of the air blowing operation using the air blowing unit 30 in the helmet 1. The switching unit 70 switches on/off the blowing operation using the blowing unit 30, for example. In addition, the switching unit 70 switches the air blowing operation between a state where air blowing is controlled using the sensor unit 50 and a state where air blowing is not controlled using the sensor unit 50, as described later. That is, the switch included in the switching unit 70 has a first switching position where the air blowing unit 30 is operated steadily, a second switching position where the air blowing unit 30 is controlled based on a detection signal from the sensor unit 50, and a second switching position where the air blowing unit 30 is controlled based on a detection signal from the sensor unit 50. and a third switching position for stopping the operation of 30.

The control section 80 housed in the second housing section 15 includes an arbitrary control circuit for realizing air blowing control using the air blowing section 30 in the helmet 1. For example, the control unit 80 includes one or more processors implemented in the control circuit. In one embodiment, a "processor" is a general purpose processor or a dedicated processor specialized for a particular process, but is not limited thereto. The control unit 80 is communicably connected to each component shown in FIG. 8 that constitutes the helmet 1, and controls the operation of the helmet 1 as a whole.

FIG. 9 is a perspective view showing the appearance of the partition member 20 attached to the inside of the helmet 1 shown in FIG. FIG. 10 is a sectional view taken along the line XX in FIG. 1. FIG. 11 is a sectional view taken along the XI-XI arrow line in FIG. In FIGS. 9 and 10, for the purpose of simple illustration in the drawings, illustration of the above-mentioned blower section 30, power supply section 40, sensor section 50, connector section 60, switching section 70, and control section 80 is omitted.

The partition member 20 is formed into the shape shown in FIGS. 9 to 11 using any resin material such as ABS, PE, PC, FRP, PAS such as PLA, and PPS, and PEEK. The partition member 20 may be made of the same material as the cap body 10, or may be made of a different material from the cap body 10. The partition member 20 is arranged along the inner surface of the cap body 10 and is attached inside the cap body 10. The partition member 20 is configured to be detachable from the cap body 10.

The partition member 20 has a base 21 arranged along the back surface 12b of the helmet 1. The partition member 20 has a pair of extending portions 22 that extend from the base 21 in a bifurcated manner along both side surfaces 12c of the helmet 1. The partition member 20 has a plurality of first attachment portions 23 a that protrude toward the inner surface of the cap body 10 from the surface of the partition member 20 that faces the inner surface of the cap body 10 . A total of five first attachment parts 23a are provided, two in the upper half of each extension part 22 and one in a part of the base 21 close to the upper end thereof. The partition member 20 has second mounting portions 23b that are recessed on both left and right sides in the vertical center of the base portion 21.

In the partition member 20, a plurality of first attachment portions 23a are fitted into corresponding holes protruding from the inner surface of the cap body 10, and a plurality of second attachment portions 23b are provided protruding from the inner surface of the cap body 10. It is removably attached to the cap body 10 by fitting with a corresponding protrusion.

The partition member 20 has a first holding portion 24 located in the upper half of the base 21 and protruding from the surface of the base 21 . A blower section 30 is attached to the first holding section 24 . The first holding section 24 holds the blower section 30 . The partition member 20 has a second holding portion 25 formed directly below the first holding portion 24 . A power supply section 40 is attached to the second holding section 25 . The second holding section 25 holds the power supply section 40 . The partition member 20 has a third holding portion 26 formed directly below the second holding portion 25 . A control section 80 is attached to the third holding section 26 . The third holding section 26 holds the control section 80.

The partition member 20 has a fourth holding part 27 located in the upper half of the base 21 on the left side side part 12c side with respect to the first holding part 24. A sensor section 50 is attached to the fourth holding section 27 . The fourth holding section 27 holds the sensor section 50.

The partition member 20 has two first through holes 28a arranged in the left-right direction at the upper end of the base 21. The base 21 has a plurality of first through holes 28a. The partition member 20 has ten second through holes 28b arranged in the front-rear direction in the extending portion 22. The extending portion 22 has a plurality of second through holes 28b. In the extending portion 22, the hole diameter of the second through hole 28b closest to the back surface portion 12b is smaller than the hole diameter of the second through hole 28b on the side of the front surface portion 12a that is farthest from the back surface portion 12b. More specifically, in the extension part 22, the plurality of second through holes 28b are arranged from the back part 12b side to the front end of the extension part 22 on the front part 12a side, and are arranged from the back part 12b to the front end. The pore diameter gradually increases towards the end.

A space S is formed between the cap body 10 and the partition member 20. The space S includes a housing space S1 located inside the second housing part 15. The accommodation space S1 includes a first accommodation space S11 that accommodates the blower section 30 and the sensor section 50. The accommodation space S1 is formed directly below the first accommodation space S11 and includes a second accommodation space S12 that accommodates the power supply unit 40. The accommodation space S1 includes a third accommodation space S13 that is formed directly below the second accommodation space S12 and accommodates the connector section 60, the switching section 70, and the control section 80.

The base portion 21 covers the entire ventilation opening of the ventilation section 30 arranged in the first accommodation space S11 from the inside of the cap body 10. The base 21 covers the entire ventilation section 30 from the first storage section 11b side so that the ventilation port of the ventilation section 30 arranged in the first storage space S11 is not exposed to the first storage section 11b.

The space S includes an interior space S2 located in the upper half of the space S. The internal space S2 is a space between the ventilation port of the ventilation section 30 arranged in the first housing space S11 and the base 21, and a space between the inner surface of the side surface section 12c of the cap body 10 and the extension section 22. and, including. The helmet 1 further includes a flow path F that guides the air flowing by the ventilation section 30 between the first housing section 11b and the outside of the cap body 10. The flow path F is formed between the partition member 20 and the inner surface of the cap body 10, and includes an internal space S2 that extends from the back surface portion 12b to both side surface portions 12c.

The partition member 20 partitions the first accommodating portion 11b and the flow path F inside the cap body 10. The through holes including the first through hole 28a and the second through hole 28b of the partition member 20 communicate the first accommodating portion 11b and the flow path F. As shown in FIG. 11, the first raised portion 13 is raised on the outer surface of the side surface portion 12c along the flow path F located on the opposite side of the outer surface.

When the blowing section 30 operates, air flows through the flow path F between the first accommodating section 11b and the outside of the cap body 10. For example, air is guided from the outside to the inside of the cap body 10 by the blower 30 and flows through the flow path F. The air flowing through the flow path F flows from each of the through holes including the first through hole 28a and the second through hole 28b to the first accommodating portion 11b. Therefore, wind flows from the outside of the cap body 10 toward the first accommodating portion 11b. Air blown by the air blower 30 flows into the first housing portion 11b from three directions: the back surface portion 12b and the upper end portions of both side surfaces 12c.

FIG. 12 is a flowchart showing an example of a method for blowing air into the helmet 1 shown in FIG. With reference to FIG. 12, a flow of processing executed by the control unit 80 mainly using the ventilation unit 30 in an example of the ventilation method for the helmet 1 shown in FIG. 1 will be described.

The flowchart shown in FIG. 12 starts, for example, when the user wears the helmet 1 in a cool place and switches the switch included in the switching unit 70 from the third switching position to the second switching position. The flowchart shown in FIG. 12 shows a case where the user then moves from a cool place to a hot place, returns to a cool place again, and switches the switch included in the switching unit 70 from the second switching position to the third switching position. ends at The air blowing method shown in FIG. 12 is performed by the helmet 1 assuming the above-mentioned situation, and is merely an example.

In step S100, the user operates the switch included in the switching section 70 of the helmet 1 to switch the air blowing section 30 from the third switching position where the air blowing section 30 is turned off based on the detection signal from the sensor section 50. the switch to the second switching position which controls the

In step S101, the control unit 80 of the helmet 1 detects the outside air temperature around the helmet 1 using the sensor unit 50.

In step S102, the control unit 80 of the helmet 1 determines whether the outside temperature detected by the sensor unit 50 in step S101 exceeds a first threshold value. When the control unit 80 determines that the outside air temperature exceeds the first threshold value, it executes the process of step S104. If the control unit 80 determines that the outside air temperature does not exceed the first threshold value, it executes the process of step S103. The first threshold value serving as a criterion for determination may be fixed to a predetermined temperature in advance by, for example, the manufacturer or the user of the helmet 1, or may be appropriately set by the user according to the usage status of the user.

In step S103, if the control unit 80 of the helmet 1 determines in step 102 that the outside air temperature does not exceed the first threshold value, it maintains the operation of the air blowing unit 30 in an OFF state. That is, the control unit 80 does not rotate the rotor blades of the fan included in the blower unit 30 .

In step S104, the control unit 80 of the helmet 1 turns on the blower unit 30 if it is determined in step S102 that the outside temperature exceeds the first threshold. That is, the control unit 80 starts the operation of the air blowing unit 30 and rotates the rotor blade of the fan included in the air blowing unit 30. The blower section 30 is turned on when the outside temperature detected by the temperature sensor included in the sensor section 50 exceeds a first threshold value.

In step S105, the control unit 80 of the helmet 1 uses the sensor unit 50 to appropriately detect the outside air temperature around the helmet 1, and adjusts the output of the blower unit 30 according to the outside air temperature detected by the sensor unit 50. . For example, the controller 80 increases the output of the blower 30 as the outside temperature increases. That is, the blower unit 30 increases its output as the outside air temperature detected by the sensor unit 50 increases. For example, the control unit 80 lowers the output of the blower unit 30 as the outside temperature decreases. That is, the blower unit 30 lowers its output as the outside air temperature detected by the sensor unit 50 is lower.

In step S106, the control unit 80 of the helmet 1 uses the sensor unit 50 to appropriately detect the outside air temperature around the helmet 1, and determines whether the outside air temperature detected by the sensor unit 50 has become equal to or lower than the second threshold. judge. When the control unit 80 determines that the outside air temperature has become equal to or lower than the second threshold value, the control unit 80 executes the process of step S108. If the control unit 80 determines that the outside air temperature remains above the second threshold, it executes the process of step S107. The second threshold value serving as a criterion for determination may be fixed at a predetermined temperature in advance by, for example, the manufacturer or the user of the helmet 1, or may be appropriately set by the user according to the user's usage situation.

In step S107, if the control unit 80 of the helmet 1 determines that the outside temperature remains above the second threshold in step S106, the control unit 80 of the helmet 1 maintains the on state of the air blowing unit 30. That is, the control unit 80 does not stop the rotation of the rotor blade of the fan included in the blower unit 30 .

In step S108, the control unit 80 of the helmet 1 turns off the blower unit 30 if it is determined in step S106 that the outside air temperature has become equal to or lower than the second threshold. That is, the control unit 80 stops the operation of the air blowing unit 30, and stops the rotation of the rotor blade of the fan included in the air blowing unit 30. The blower section 30 is turned off when the outside temperature detected by the temperature sensor included in the sensor section 50 becomes equal to or lower than the second threshold.

The second threshold is, for example, an arbitrary value that is equal to or less than the first threshold. When the second threshold value is the same value as the first threshold value, the blower unit 30 is turned on when the outside air temperature detected by the sensor unit 50 exceeds the same threshold value, and is turned off when the outside temperature is below the threshold value.

In step S109, the subsequent flow changes depending on whether the switching position of the switch included in the switching unit 70 has been changed. For example, when the switching position of the switch included in the switching unit 70 switches from the second switching position to the third switching position, the control unit 80 of the helmet 1 ends the process. If the switching position of the switch included in the switching unit 70 remains at the second switching position, the control unit 80 of the helmet 1 executes the process of step S101 again.

For example, the user operates a switch included in the switching unit 70 of the helmet 1 to switch from a second switching position where the air blowing unit 30 is controlled based on a detection signal from the sensor unit 50 to a second switching position where the air blowing unit 30 is turned off. 3 Switch the switch to the switching position. Thereby, the control unit 80 of the helmet 1 ends the process.

The above flowchart similarly applies, for example, when the user wears the helmet 1 in a hot place and switches the switch included in the switching unit 70 from the third switching position to the second switching position.

According to the helmet 1 according to the embodiment as described above, it is possible to effectively form an air flow between the first housing portion 11b and the outside of the helmet 1. In the helmet 1, the partition member 20 partitions the first accommodating part 11b and the flow path F inside the cap body 10, so that the first accommodating part 11b, in which the top of the user's head is accommodated, and the flow path F are separated. Can be clearly separated. The helmet 1 is capable of causing air to flow through clearly demarcated flow paths F to form an air flow throughout a predetermined area around the first housing portion 11b. Thereby, the helmet 1 can send the air that has flowed over the entire predetermined area around the first accommodating part 11b to the first accommodating part 11b through the through hole of the partition member 20. That is, the helmet 1 can improve air permeability and uniformly send air from the outside of the cap body 10 to the inside of the first accommodating part 11b. As described above, the user wearing the helmet 1 can effectively receive the wind from the air blower 30 at the top of the head, and can receive the cooling effect of the air blower 30.

In the helmet 1, the flow path F includes the internal space S2 that extends from the back surface portion 12b along both side surface portions 12c, so that air can be distributed over the entire area along the back surface portion 12b and both side surface portions 12c around the first accommodating portion 11b. It is possible to form a flow of Thereby, the helmet 1 can send the air that has flowed over the entire area around the first accommodating part 11b to the first accommodating part 11b through the through hole of the partition member 20. That is, the helmet 1 can improve ventilation and uniformly send air from the outside of the cap body 10 to the inside of the first housing part 11b from three directions. Therefore, the cooling effect of the above-mentioned air blower 30 becomes even more remarkable.

In the helmet 1, the base 21 covers the entire ventilation opening of the ventilation section 30 from the inside of the cap body 10, thereby blocking the operating noise of the fan included in the ventilation section 30 and reducing the noise felt by the user wearing the helmet 1. can improve sex. In the helmet 1, since the ventilation opening of the ventilation section 30 is not exposed in the first housing section 11b in which the top of the user's head is accommodated, the base section 21 can reduce the operating noise of a fan or the like that reaches the user's ears. In the helmet 1, when the blower section 30 includes a highly silent fan, such quietness can be further improved.

In the helmet 1, since the base portion 21 has a plurality of first through holes 28a, more air can be sent from the back surface portion 12b side into the first housing portion 11b where the top of the user's head is accommodated. Therefore, the cooling effect of the above-mentioned air blower 30 becomes even more remarkable.

In the helmet 1, since the extending portion 22 has a plurality of second through holes 28b, more air can be sent from the side surface portion 12c into the first accommodating portion 11b in which the top of the user's head is accommodated. can. Therefore, the cooling effect of the above-mentioned air blower 30 becomes even more remarkable.

In the helmet 1, in the extending portion 22, the hole diameter of the second through hole 28b closest to the back surface portion 12b is smaller than the hole diameter of the second through hole 28b furthest from the back surface portion 12b, so that a flow path is formed on the back surface portion 12b side. The amount of air flowing from F into the first housing portion 11b can be suppressed. Thereby, the helmet 1 can maintain the amount of air up to the position of the second through hole 28b that is farthest from the back surface portion 12b. Therefore, the helmet 1 can form an air flow on the flow path F over the entire predetermined area around the first housing portion 11b. As described above, the helmet 1 can improve air permeability and send air more uniformly from the outside of the cap body 10 to the inside of the first accommodating part 11b. As a result, the cooling effect by the air blower 30 described above becomes even more remarkable.

In the helmet 1, the plurality of second through holes 28b are arranged in the extending portion 22 from the back side 12b toward the tip thereof, and the hole diameter gradually increases from the back side 12b toward the tip. It is possible to maintain the amount of air on the side. Therefore, the helmet 1 can more effectively form the air flow on the flow path F over the entire predetermined area around the first accommodating part 11b. As described above, the helmet 1 can improve air permeability and send air more uniformly from the outside of the cap body 10 to the inside of the first accommodating part 11b. As a result, the cooling effect by the air blower 30 described above becomes even more remarkable.

The helmet 1 has a first protrusion 13 on the outer surface of the side surface 12c that protrudes along the flow path F located on the opposite side of the outer surface, thereby forming a first accommodating section in which the top of the user's head is accommodated. The flow path F can be formed without narrowing the space inside 11b. In addition, the helmet 1 can protect the top of the head located inside the first housing part 11b by absorbing impact from the outside by the first raised part 13. In the helmet 1, the flow path F can be formed outside the first accommodating part 11b while maintaining the size of the safe protected space by the first accommodating part 11b. The helmet 1 can achieve both safety and breathability.

In the helmet 1, the partition member 20 is configured to be detachable from the cap body 10, so that the partition member 20 can be removed from the cap body 10 and easily replaced. For example, in the helmet 1, even if the partition member 20 is damaged for some reason, the partition member 20 can be removed from the cap body 10 and easily replaced. That is, the helmet 1 can improve maintainability.

In the helmet 1, the blower unit 30 is turned on when the outside air temperature detected by the sensor unit 50 exceeds a threshold value, and is turned off when it is below the threshold value, so that the air blower unit 30 is turned on only when necessary for the user wearing the helmet 1. The blower section 30 can be operated by doing so. Thereby, the helmet 1 can realize power saving and extend the usable time of the battery included in the power supply unit 40. Therefore, the helmet 1 can be used for a longer period of time with one charge of the battery included in the power supply section 40. As a result, convenience for the user using the helmet 1 is improved.

The helmet 1 can change the output of the fan included in the ventilation section 30 depending on the temperature by increasing the output of the ventilation section 30 as the outside temperature is higher. For example, the helmet 1 can rapidly increase the output of the air blower 30 when the user wearing the helmet 1 moves from a cool indoor environment to an outdoor environment under the scorching sun. The helmet 1 can increase the amount of change in the output of the air blower 30 depending on the temperature difference per unit time. Therefore, the helmet 1 can also rapidly increase the output of the air blower 30 only when necessary for the user wearing the helmet 1. Thereby, the helmet 1 can realize power saving, and the above-mentioned effects regarding the convenience of the user who uses the helmet 1 are more prominently achieved.

Although the present disclosure has been described based on the drawings and embodiments, it should be noted that those skilled in the art can make various changes and modifications based on the present disclosure. It should therefore be noted that these variations and modifications are included within the scope of this disclosure. For example, the functions included in each configuration or each step can be rearranged to avoid logical contradictions, and multiple configurations or steps can be combined or divided into one. .

For example, the shape, size, arrangement, orientation, number, etc. of each component described above are not limited to what is illustrated in the above description and drawings. The shape, size, arrangement, orientation, number, etc. of each component may be arbitrarily configured as long as the function can be realized.

In the embodiment described above, it has been described that the flow path F includes the internal space S2 that extends from the back surface portion 12b along both side surface portions 12c according to the shape of the partition member 20, but is not limited thereto. The flow path F may be formed in any area located around the first accommodating portion 11b. For example, the flow path F may be continuously formed from the back surface portion 12b to the front surface portion 12a via both side surface portions 12c. That is, the flow path F is formed in an annular shape on the upper surface portion 12d side of the first accommodating portion 11b by the back surface portion 12b, the pair of both side surface portions 12c, and the space between the inner surface of the front portion 12a and the partition member 20. The entire periphery of the first accommodating portion 11b may be surrounded from four directions: front, rear, left, and right.

FIG. 13 is a perspective view showing the appearance of a helmet 1 according to a first modification. FIG. 14 is a perspective view showing the appearance of a helmet 1 according to a second modification. As shown in FIGS. 13 and 14, the flow path F may include an internal space that extends from the back surface portion 12b to the top surface portion 12d instead of the pair of both side surface portions 12c. At this time, the helmet 1 may have only the second raised part 14 formed on the upper surface part 12d without having the first raised part 13 formed on the side surface part 12c. The flow path F may be formed inside the second protrusion 14 so as to extend in the front-rear direction along the second protrusion 14 .

As shown in FIG. 13, the second raised portion 14 may extend continuously from the back surface portion 12b to the vertical center of the front portion 12a. Each of the pair of edges E3 located on both sides of the second raised portion 14 in the left-right direction extends from the upper end of the back surface portion 12b to the center portion of the front portion 12a in the vertical direction while drawing a parabola-like shape. It's okay to reach that point. The pair of edges E3 of the second raised portion 14 may be formed to be line symmetrical in the left-right direction. The second raised portion 14 may be formed with a substantially uniform left and right width along the front-rear direction.

As shown in FIG. 14, the second raised portion 14 may extend continuously from the back surface portion 12b to the vertical center of the front portion 12a. Each of the pair of edges E3 located on both sides of the second raised portion 14 in the left-right direction extends from the upper end of the back surface portion 12b to the center portion of the front portion 12a in the vertical direction while drawing a shape like a wavy line. It's okay to reach that point. The pair of edges E3 of the second raised portion 14 may be formed to be line symmetrical in the left-right direction. The second raised portion 14 may be formed in a tapered shape so that the left and right width becomes narrower from the back surface portion 12b toward the front surface portion 12a.

The flow path F is a combination of the bifurcated one in the above embodiment and the one formed on the upper surface part 12d in the first modification or the second modification, and extends from the back surface 12b to both side surfaces 12c and the upper surface. It may also include an internal space that extends in a trifurcated shape along 12d.

In the above embodiment, it has been described that the base 21 of the partition member 20 covers the entire ventilation opening of the ventilation section 30 from the inside of the cap body 10, but the present invention is not limited thereto. The base 21 of the partition member 20 may cover only a portion of the ventilation port of the ventilation section 30 from the inside of the cap body 10, or may not cover the ventilation port at all, as long as quietness is maintained. You can.

In the above embodiment, the base 21 has been described as having two first through holes 28a, but the present invention is not limited to this. The base 21 may have three or more first through holes 28a, or may have only one first through hole 28a. The base 21 does not need to have the first through hole 28a. For example, the base portion 21 may have only one first through hole 28a formed with a large hole diameter in the center portion in the left-right direction of the portion facing the ventilation port of the ventilation portion 30.

In the embodiment described above, the extension portion 22 has been described as having ten second through holes 28b, but the present invention is not limited thereto. The extending portion 22 may have a plurality of second through holes 28b in any other number, or may have only one second through hole 28b. The extending portion 22 does not need to have the second through hole 28b. For example, the extending portion 22 may have only one second through hole 28b formed with a large hole diameter at the center in the front-rear direction.

In the embodiment described above, in the extending portion 22, the diameter of the second through hole 28b closest to the back surface portion 12b is smaller than the diameter of the second through hole 28b furthest from the back surface portion 12b. Not done. In the extending portion 22, the hole diameter of the second through hole 28b closest to the back surface portion 12b may be larger than the hole diameter of the second through hole 28b furthest from the back surface portion 12b, or may be the same.

In the embodiment described above, it has been described that the diameter of the plurality of second through holes 28b in the extending portion 22 gradually increases from the back surface portion 12b toward the tip of the extending portion 22, but the present invention is not limited thereto. The diameters of the plurality of second through holes 28b arranged from the back surface portion 12b side toward the tip of the extension portion 22 may have different regularities. For example, the pore size may alternately have one minimum value and one maximum value. That is, the plurality of second through holes 28b may be arranged so that short diameter holes and long diameter holes are alternately repeated from the back surface portion 12b side toward the tip of the extension portion 22. Without being limited to the above, the diameters of the plurality of second through holes 28b arranged from the back surface portion 12b side toward the tip of the extension portion 22 may be completely irregular.

In the extension part 22, the number of the plurality of second through holes 28b may gradually increase from the back surface part 12b toward the tip of the extension part 22 instead of or in addition to the hole diameter.

Although in the embodiment described above, the partition member 20 is configured to be detachable by fitting into the cap body 10, the partition member 20 is not limited thereto. The partition member 20 may be configured to be removable from the cap body 10, for example, by screwing or engaging. The partition member 20 may be attached to the cap body 10 such that it cannot be attached to or detached from the cap body 10. The partition member 20 may be configured to be non-removable as part of the structure of the cap body 10, for example, by integral molding and adhesion.

In the above embodiment, it has been explained that the flow path F includes the internal space S2, but the present invention is not limited thereto. In addition to the internal space S2, the helmet 1 may further include a sound absorbing material disposed in the flow path F. That is, a sound absorbing material may be placed at an appropriate position in the internal space S2 that constitutes the flow path F. Thereby, the above-mentioned effect regarding quietness becomes more remarkable.

Although in the embodiment described above, the cap body 10 is made of any resin material, it is not limited thereto. The cap body 10 may be made of any metal material.

Although in the embodiment described above, the partition member 20 is made of any resin material, the present invention is not limited thereto. The partition member 20 may be made of any metal material.

The partition member 20 may be formed of any material that allows sound insulation, sound absorption, etc. by itself. For example, the partition member 20 may be formed of a resin material with a high sound absorption effect, such as vibration-proof rubber, silicone, and urethane. Thereby, the above-mentioned effect regarding quietness becomes more remarkable.

In the embodiment described above, the helmet 1 has been described as having the sensor section 50, but the helmet 1 is not limited to this. Helmet 1 may not include sensor section 50. Although it has been explained that the helmet 1 performs control such that the blower section 30 is turned on when the outside air temperature detected by the sensor section 50 exceeds a threshold value, and turned off when the outside temperature is below the threshold value, but the present invention is not limited to this. Helmet 1 does not need to perform such control. At this time, the switch included in the switching unit 70 of the helmet 1 does not have a second switching position that controls the ventilation unit 30 based on the detection signal from the sensor unit 50, but operates the ventilation unit 30 steadily. It may have only the first switching position and the third switching position where the operation of the air blower 30 is stopped.

In the embodiment described above, it has been explained that the helmet 1 performs control to increase the output of the blower section 30 as the outside air temperature is higher, but the helmet 1 is not limited to this. Helmet 1 does not need to perform such control.

In the above embodiment, the first accommodating section 11b is described as accommodating, for example, the top of the head of the user as a worker, but the present invention is not limited thereto. The first accommodating portion 11b may accommodate the top of the head of any user other than the worker.

In the above embodiment, it has been explained that the air blower 30 takes in air from outside the cap body 10 and sends the air into the inside of the cap body 10, but the invention is not limited to this. Instead of or in addition to such an operation, the blowing section 30 may send air from the inside of the cap body 10 to the outside. The blower unit 30 may be configured such that the fan can freely rotate in forward and reverse directions. In the above embodiment, the air flow and the effects related to the air flow described in the case based on forward rotation can be reversed and the same explanation can be applied when the rotation is reversed.

In the above embodiment, it has been explained that the power supply section 40 may include a lithium ion battery that can be charged via the connector section 60, or any battery that can be charged without contact, but the power supply section 40 is not limited to this. Not done. The power supply section 40 is not limited to such a secondary battery, and may include a non-rechargeable primary battery. The power supply unit 40 may alternatively or additionally include a solar cell. Such a solar cell may be installed on at least one of the surface of the first raised portion 13 and the surface of the second raised portion 14 in the helmet 1 shown in FIG. The helmet 1 reduces the possibility that the solar cells will be damaged by external impact when the solar cells are installed on the surface of the first raised portion 13 compared to when the solar cells are installed on the surface of the second raised portion 14. Can be reduced.

In the above embodiment, the sensor unit 50 is described as including, for example, a temperature sensor, but is not limited thereto. Sensor section 50 may alternatively or additionally include any other sensors. For example, the sensor unit 50 may include a humidity sensor, an atmospheric pressure sensor, and the like.

In the above embodiment, the connector section 60 is described as including, for example, a USB connector, but is not limited thereto. The connector section 60 may include any other connector other than the USB connector that can realize the air blowing operation using the air blower section 30 in the helmet 1.

1 helmet 10 cap body 11a opening 11b first accommodating part (accommodating part)
12 Main body part 12a Front part 12b Back part 12c Side part 12d Top part 13 First raised part (raised part)
14 Second raised portion 15 Second storage portion 15a Louver 20 Partition member (partition portion)
21 Base 22 Extending part 23a First attachment part 23b Second attachment part 24 First holding part 25 Second holding part 26 Third holding part 27 Fourth holding part 28a First through hole (through hole)
28b Second through hole (through hole)
30 Blower section 40 Power supply section 50 Sensor section 60 Connector section 70 Switching section 80 Control section E1 Edge E2 Edge E3 Edge F Channel S Space S1 Accommodation space S11 First housing space S12 Second housing space S13 Third housing space S2 Internal space

Claims (12)

a cap body having an opening and forming an outer shape;
a blower unit attached to the back surface of the cap body and blowing air between the inside and outside of the cap body;
a partition portion disposed along the inner surface of the cap body;
an accommodating portion formed inside the cap body continuously with the opening of the cap body;
a flow path that guides air flowing by the blowing section between the storage section and the outside of the cap body;
Equipped with
The partition section partitions the accommodating section and the flow path inside the cap body, and has a through hole that communicates the accommodating section and the flow path.
Helmet. The helmet according to claim 1,
The partition portion has a base portion disposed along the back surface of the helmet, and a pair of extending portions extending in a bifurcated shape from the base portion along both side surfaces of the helmet,
The flow path is formed between the partition portion and the inner surface of the cap body, and includes an internal space that extends from the back surface portion to the both side surface portions.
Helmet. The helmet according to claim 2,
The base part covers the entire ventilation opening of the ventilation part from the inside of the cap body.
Helmet. The helmet according to claim 2 or 3,
The base has a plurality of through holes,
Helmet. The helmet according to claim 2 or 3,
The extending portion has a plurality of the through holes,
Helmet. The helmet according to claim 5,
In the extending portion, the hole diameter of the through hole closest to the back surface portion is smaller than the hole diameter of the through hole furthest from the back surface portion.
Helmet. The helmet according to claim 6,
The extending portion has a plurality of through holes arranged from the back side toward the tip of the extending portion, the hole diameter of which gradually increases from the back side toward the tip.
Helmet. The helmet according to claim 2 or 3,
Further comprising a protuberance on the outer surface of the side surface that protrudes along the flow path located on the opposite side of the outer surface.
Helmet. The helmet according to any one of claims 1 to 3,
The partition section includes a partition member configured to be detachably attached to the cap body.
Helmet. The helmet according to any one of claims 1 to 3,
further comprising a sound absorbing material disposed in the flow path;
Helmet. The helmet according to any one of claims 1 to 3,
further comprising a sensor section attached to the cap body,
The blower section is turned on when the outside air temperature detected by the sensor section exceeds a threshold value, and is turned off when the outside temperature is below the threshold value.
Helmet. The helmet according to claim 11,
The air blower increases the output as the outside air temperature increases;
Helmet.

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