KR20210059887A - a Safety Cap - Google Patents

Abstract

The present invention relates to a safety helmet. The safety helmet includes: a gas buffer layer (11) in which gas is injected; an absorption layer (12) coupled thereon to the gas buffer layer (11); and a protective layer (13) disposed on top of the absorption layer (12), wherein the protective layer (13) comprises a neck protective covering (133) for protection of the back part of the head.

Description

Safety Cap {a Safety Cap}

The present invention relates to a hard hat, and specifically relates to a hard hat capable of generating a safety rescue signal while being made in a foldable shape while effectively absorbing an impact, thereby improving the convenience of carrying or storing.

When a disaster such as an earthquake occurs, the head needs to be protected from various kinds of falling objects, and a hard hat or a protective cap may be used for this. In addition, it is necessary to protect the head from accidents that occur during the operation of driving means such as two-wheeled vehicles, kickboards or bicycles, and a helmet or hard hat to protect the head from accidents occurring in rock climbing or similar sports or leisure activities is required. It is known in the art. Patent Registration No. 10-1648754 discloses a protective helmet for fire fighting that is installed in a cell to have an optimal radius of curvature for a shield and a visor that opens and closes a wearer's face. In addition, Patent Registration No. 10-1915529 discloses a multifunctional safety helmet that can be used in the process of an emergency accident such as a disaster or a collapse of a facility. In order to protect the head from the impact caused by the collision of the head due to an accident such as a collision of a falling object or a fall, the hard hat or hard hat needs to be made in a structure capable of absorbing the shock. The impact is advantageously absorbed in stages, and needs to be applied in a gas-absorbing manner. In addition, it is advantageous to have a structure that can be easily applied in a necessary situation while the hard hat or hard hat is made in a structure that is simple to carry or store. However, the prior art does not disclose a head protection means having such a structure.

The present invention has the following objects to solve the problems of the prior art.

Prior art 1: Patent registration number 10-1648754 (Sancheong Co., Ltd., 2016.08.17. Announcement) Fire protection helmet Prior Art 2: Patent Registration No. 10-1915529 (Kim Jin-woo, 2019.01.07. Announcement) Patent Corporation Plus

An object of the present invention relates to a safety helmet capable of being folded while the shock is effectively absorbed by a multi-stage shock absorbing structure and capable of generating a rescue signal in a crisis situation.

According to a preferred embodiment of the present invention, the helmet includes a gas buffer layer into which gas is injected; An absorbent layer coupled above the gas buffer layer; And a protective layer disposed above the absorbent layer 12, and the protective layer includes a neck protective cover for protecting the rear portion of the head.

According to another suitable embodiment of the invention, it comprises a fold line formed in the protective layer 13.

According to another suitable embodiment of the present invention, a communication means capable of wireless communication with an external electronic device is included.

The safety helmet according to the present invention effectively blocks the transmission of the shock to the head by absorbing or buffering the shock step by step. The hard hat according to the present invention is made in a structure in which the upper part is folded, so that it is convenient to carry or store. In addition, the safety helmet according to the present invention automatically generates a rescue signal in a crisis situation so that safety measures can be quickly taken.

1A and 1B show an embodiment of a hard hat according to the present invention.
Figure 2 shows an embodiment of the folding structure of the helmet according to the present invention.
3 and 4 show an embodiment of a structure to which the helmet according to the present invention is applied.
5 and 6 show an embodiment in which the hard hat according to the present invention is applied to a disaster situation.

In the following, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the embodiments are for a clear understanding of the present invention, and the present invention is not limited thereto. In the following description, components having the same reference numerals in different drawings have similar functions, so if they are not necessary for the understanding of the invention, they will not be described repeatedly, and well-known components will be briefly described or omitted, but the present invention It should not be understood as being excluded from the embodiment of.

1A and 1B show an embodiment of the hard hat 10 according to the present invention.

1A and 1B, the helmet 10 includes a gas buffer layer 11 into which gas is injected; An absorbent layer 12 coupled upwardly to the gas buffer layer 11; And a protective layer 13 disposed above the absorbent layer 12, and the protective layer 13 includes a neck protective cover 133 for protecting the rear portion of the head.

The hard hat 10 can be used to protect the head in a disaster situation such as an earthquake, work in a hazardous area, a sport activity such as rock climbing, a driving process of an electric board or two-wheeled vehicle, a child's activity, or a similar activity. have. The hard hat 10 may be stored in a predetermined place or carried, and may be worn in a disaster situation or during an activity process. For example, the hard hat 10 may be stored in a place for storing disaster protection items, and a disaster such as an earthquake occurs and may be worn on the head. Alternatively, it can be carried on the human body or in a storage bag, and worn on the head for activities or for work. The hard hat 10 may have a function of protecting an impact applied to the head by being worn on the head during various activities or in various situations. The hard hat 10 may have a structure in which a plurality of layers are stacked, and different layers may have different density, elasticity, elasticity, hardness, or shock absorption characteristics. Thereby, the impact can be absorbed or buffered in stages, thereby effectively weakening. The gas buffer layer 11 may be a layer that comes into contact with the head, and may be, for example, an air bag structure. The gas buffer layer 11 may have a hemispherical shape or a similar shape as a whole and may be made of various structures that can be worn on the head. The gas buffer layer 11 may have an expansion space in which gas is injected to expand therein, and may be made of a nylon material, polyethylene terephthalate (PET), or an elastic material capable of expansion by application of a similar pressure. Optionally, gas is previously injected into the gas buffer layer 11 to be sealed to maintain the expanded state. The gas buffer layer 11 may be expanded by injection of gas or by the injected gas, or may have various structures capable of maintaining an expanded state. The gas buffer layer 11 may have a hemispherical shape capable of covering a person's head, and a gas buffer structure may be formed in at least a portion of the interior in contact with the head. The outer surface of the gas buffer layer 11 may be coated with a polyurethane or silicone material to improve airtightness. The absorbent layer 12 may be bonded to the upper side of the gas buffer layer 11, and the absorbent layer 12 may have a shape covering the outer surface of the gas buffer layer 11, and have a hemispherical shape or a similar shape as a whole. An absorbent body 121 that is; And a receiving gap 122 that compensates for deformation due to an impact applied to the absorbent body 121. As shown in FIG. 1B, the absorbing body 121 may have a function of absorbing an impact by being disposed between the gas buffer layer 11 and the protective layer 13, based on the center of the gas buffer layer 11 The enemy can also be made in a shape that covers a part. The receiving gap 122 may be, for example, a fan shape extending from the center to the circumferential surface, but may be made in various structures according to the deformation characteristics of the absorbent body 121. However, the receiving gap 122 may be selectively formed, and accordingly, the absorbent layer 12 may be formed of the absorbent body 121. The absorbing body 121 may have a function of absorbing shock by structural deformation according to the shock, and may have a foam structure made of, for example, various materials. For example, the absorbent body 121 may be made of various synthetic resin foam materials, for example, acrylic foam, polyurethane foam, polypropylene foam, silicone foam, or similar synthetic resin foam. Alternatively, the absorbent layer 12 may be made of rubber, elastomer, silicone or similar elastic material. The absorbent layer 12 may be made of a memory foam material or memory elastan foam, and may be made of a viscoelastic polyurethane foam, a low-elastic polyurethane foam or a high density memory foam material. Optionally, when the absorbent layer 12 is made of a memory foam material, the outer surface may be a flame retardant coating or a non-flammable coating, for example, a fluorine-based, polytetrafluoroethylene or similar material may be a flame retardant coating. Memory foam can be combustible, and there is a risk of fire at a disaster site. The above risks can be avoided by the flame retardant coating. A protective layer 13 may be bonded above the absorbent layer 12. The protective layer 13 may be made of, for example, polyethylene vinyl acetate (EVA), polycarbonate, reinforced glass fiber, ABS (Acrylonnitrile Butadiene Styrene) resin, or a similar material, but is not limited thereto. The protective layer 13 has a hemispherical impact body 131; Avoidance visor 132 coupled in the shape of a hat visor in front of the impact body 131; And a neck protection cover 133 extending downwardly to the rear of the impact body 131 to protect the impact applied to the neck region. In addition, a light emitting display unit 134 formed on the outer surface of the impact body 131 may be included. The protective layer 13 may be formed as a whole, but the neck protective cover 133 may optionally be made into a fastening structure. While the impact body 13 is made of a solid material, for example, it may be a part where an impact object such as a falling object directly collides. The outer surface of the impact body 13 may be made of a rigid material so that it is not damaged by impact. The protective layer 13 may itself be made in a structure in which a part of the impact can be absorbed. For example, the inner part of the protective layer 13 has a higher strength and a higher density than the absorbing layer 12. It can be made of a material, for example polypropylene or a similar material. The protective layer 13 may be made of the same or similar material as the helmet or various types of hard hats used in hazardous workplaces, whereby the present invention is not limited. The avoidance visor 132 is formed in a shape protruding toward the front of the impact body 131 to prevent falling objects from falling in the direction of the human body, and the avoidance visor 132 may be made integrally with the impact body 13. have. A neck protection cover 133 may be formed at the rear of the impact body 13, and the neck protection cover 133 may have a structure extending downward from a circular edge of the impact body 131. The neck protective cover 133 may be made in a shape that covers the side of the neck while covering the nape of the neck, and may be made integrally or independently with the impact body 131 and combined. The neck protective cover 133 may be made in a structure that can be bent inward or outward with the edge of the impact body 131 or the upper portion of the neck protective cover 133, and preferably folds inward. Can be made with When the neck protective cover 133 has a structure that can be folded inward based on the edge of the impact body 131, the inner surface of the neck protective cover 133 may overlap the inner surface of the gas buffer layer 11 It can be made into a structure. The neck protective cover 133 may be made in various structures, and the present invention is not limited thereby.

At least one light-emitting display unit 134 may be formed on an outer circumferential surface of the impact body 131, and the light-emitting display unit 134 may be made of a fluorescent material or a structure that emits light by a power source such as a battery. I can. The light-emitting display unit 134 makes it easy for rescue personnel to find the wearer of the hard hat 1s0 while making it easy to find the hard hat 10 in a state in which the power supply is cut off in a disaster situation. The light emitting display unit 134 may be made in various shapes and is not limited to the presented exemplary embodiment.

The safety helmet according to the present invention is made of a folded structure, so that the convenience of storage or the convenience of portability may be improved.

Figure 2 shows an embodiment of the folding structure of the helmet according to the present invention.

Referring to FIG. 2, at least a portion of the protective layer 13 may be folded based on the fold line FL. As described above, the impact body 131 of the protective layer 13 may be made of a solid material and may have a hemispherical shape as a whole. The impact body 131 made of such a material and structure may be made in a folded structure, whereby the total volume of the hard hat 10 may be reduced. For example, a folding line FL may be formed in a circular shape at a portion extending by a predetermined length along the outer surface with respect to the upper central portion of the impact body 131. Further, the upper portion of the convex lens shape may be made into a concave lens shape with a boundary of the fold line FL by pressing the upper portion of the fold line FL in a downward direction or pulling it in a downward direction. In addition, by applying a force in the opposite direction, the impact body 131 may return to its original shape. Optionally, by applying a force in a direction inclined with respect to the upper center of the impact body 131 may be folded based on the fold line. The fold line FL is made to have a relatively thin thickness compared to other parts of the impact body 131, or as shown in FIG. 2, by forming a horizontal ring band based on the fold line FL, the fold line ( The upper part of FL) can be folded under the applied pressure. As described above, the neck protective cover 133 may be folded inwardly, folded outwardly and overlapped with the gas buffer layer, or may be overlapped with the impact body 131. Optionally, the avoidance visor 132 may have a folded structure, but is not necessarily required. In such a folded state, the helmet 10 may have a small extended length as a whole and have a concave cylinder shape on the upper surface, thereby making it easy to store or carry. The chin strap 135 may be formed on the hard hat 10, and the chin strap 135 may be accommodated in the gas buffer layer in a storage or carrying state, or may be accommodated in another suitable position. And as the folded portion is unfolded, the chin strap 135 may be exposed to the outside and used.

3 and 4 show an embodiment of a structure to which the helmet according to the present invention is applied.

3 and 4, the hard hat may have a shape of a hat or helmet that can be worn on the head as a whole, and a state worn by wearing means 31a and 31b that can be coupled to each other can be stably maintained. The neck protective cover 133 is made independently and can be connected to the rear portion of the edge of the impact body 131 of the protective layer by means of connection means (33a, 33b) that can be easily folded or bent such as a connection pad or a connection string. have. The neck protection cover 133 may be overlapped on the inner surface of the gas injection pad 34 in the storage process by the connection means 33a and 33b. The light emitting display unit 134 may be formed on the upper portion of the impact body 131 and the neck protection cover 133, and a pair of fastening units 31a and 31b may be coupled to both sides of the hard hat. Tightenable fastening parts that can be coupled to each other may be coupled to a pair of fastening units 31a and 31b. The pair of fastening units 31a and 31b may have various structures that can be tightened while wearing a hard hat, and are not limited to the presented embodiments. As described above, an absorbent layer may be bonded to the inside of the protective layer, and the absorbent layer may be an absorbent pad layer of a pad structure. The absorbent pad layer may be coupled to the inner surface of the impact body 131, and the absorbent edge 35 may be formed along the circumferential edge of the absorbent layer. The absorbent edge 35 may be made of the same or similar material as the absorbent layer, or may be made of a soft material such as cotton or fiber, and may be made in a structure capable of contacting the head. In addition, the edge of the gas injection pad 34 corresponding to the gas buffer layer may be coupled to the absorption edge 35 extending in a circular shape. In addition, one end of each of the pair of fastening units 31a and 31b may be coupled to the absorption edge 35. The gas injection pad 34 may have a structure in which the edge is attached to the absorption edge 35 and the inner portion of the edge is separated from the absorption layer. The gas injection pad 34 may have a structure in which a plurality of gas expansion cells 341 are formed while being hemispherical or circular as a whole. Gas can be injected into each gas expansion cell 341, and at least two different gas expansion cells 341 allow gas flow, or each gas expansion cell 341 restricts gas flow. Independent areas can be formed. The gas injection pad 34 may be made of the same or similar material as the absorption layer, and may be made of, for example, a material that can be stretched and contracted by the pressure of the gas filled therein. The gas injection pad 34 may be divided into a plurality of areas by at least one separation area 342 extending in the circumferential direction from the center, and the separation area 342 may be divided into two areas forming the gas injection pad 34. The surfaces may have a structure in which the surfaces are bonded to each other, or a structure in which a portion of the surfaces bonded along the length direction is cut. Optionally, a gas flow path connecting different gas expansion cells 341 may be formed in the separation region 342. The gas expansion cell 341 may have a structure extending in a direction perpendicular to the extending direction of the separation region 342. A plurality of gas expansion cells 341 may be disposed in each area, the extension length thereof becomes smaller toward the center direction. The gas expansion cell 341 can be made in various structures and is not limited to the presented embodiment.

4 shows an embodiment of a structure in which the upper portion of the impact body 131 is depressed downward based on the fold line FL. The fold line FL may be made to be relatively weak compared to other parts of the impact body 131 while being generally circular, or may be formed so that the upper part and the lower part can be structurally folded like a corrugated structure. Due to the structure in which the circumferential surface is coupled to the absorption edge 35 and the remaining portion is separated from the absorption layer, the gas injection pad 34 is not damaged and can be stably maintained in the process of folding or folding. I can. In addition, even if some of the gas expansion cells 341 are damaged, the gas injection pad 34 may have an impact relief function due to a structure that is separated from each other. Optionally, the absorption edge 35 and the gas injection pad 34 may be formed in a detachable coupling structure, so that the gas injection pad 34 may have a replaceable structure. In addition, the neck protective cover 133 may be formed of a protective covering layer made of the same or similar material as the protective layer, and an absorbent pad made of the same or similar material as the absorbent layer while being bonded to the inner surface of the protective covering layer. The neck protective cover 133 may be formed of various multi-layered structures capable of absorbing external shocks, and is not limited to the exemplary embodiments presented.

5 and 6 show an embodiment in which the hard hat according to the present invention is applied to a disaster situation.

5 and 6, the hard hat may include communication means 51 and 61 capable of wireless communication with external electronic devices. The helmet can be used in disaster situations such as earthquakes, fires, and collapses, as well as in hazardous workplaces, leisure activities, use of means of transportation, or in the course of children's play. When an object impacts the impact body 131 from the outside while the hard hat is worn, the impact applied to the head may be alleviated by the hard hat. A communication means 51 in which, for example, a communication chip capable of short-range wireless communication may be disposed in the impact body 131 or other suitable location. The communication means 51 may include an impact detection sensor, and the impact detection sensor may have a wake-up function for starting the operation of the communication chip according to a predetermined magnitude of the impact. The impact detection sensor can also detect an impact IM that occurs when the wearer falls and hits the ground G, and can initiate the operation of the communication chip according to the magnitude of the impact. When an impact larger than a predetermined size is detected by the impact detection sensor or a state in which the wearer has fallen, the operation of the communication chip may be started. When the communication chip is activated, for example, a portable electronic device carried by the wearer or a similar relay electronic device 52 may be started. The relay electronic device 52 may transmit dangerous state or location information to the protective electronic devices 53a, 53b, 53c accessible to the manager or guardian. The protective electronic devices 53a, 53b, 53c are, for example, a workplace. It may be an electronic device capable of wireless communication with various types of relay electronic devices 52, such as a management server of a guardian, a smart phone of a guardian, an electronic device of an accident handling agency, or an electronic device of an administrator. May detect an accident situation, may have a GPS function while enabling short-range wireless communication, and may optionally have an IOT function capable of communicating with various electronic devices in the vicinity.

As shown in Fig. 6, the communication means 61 may have a function of transmitting a disaster situation. For example, the communication means 61 may have an RF transmission module, and the RF transmission module may transmit identification information identifying each hard hat to the information reception module 63. In the event of an accident, the operation of the communication means 61 may be initiated by the operating means or by detection of the situation, and the communication means 61 transmits an RF signal to a structure 62 such as an entrance. It can be transmitted to the information receiving module 63. The information receiving module 63 may receive an RF signal transmitted from at least one hard hat and transmit it to the external electronic device 64 through wireless communication. In addition, when buried below or above the ground G by the collapsed structure DB, the communication means 61 is operated to transmit an RF signal to various external electronic devices 64. As described above, the communication means 61 may also transmit location information and may have an IOT function. The hard hat may include various means or communication means capable of detecting a dangerous situation, and is not limited to the presented embodiments.

The safety helmet according to the present invention effectively blocks the transmission of the shock to the head by absorbing or buffering the shock step by step. The hard hat according to the present invention is made in a structure in which the upper part is folded, so that it is convenient to carry or store. In addition, the safety helmet according to the present invention automatically generates a rescue signal in a crisis situation so that safety measures can be quickly taken.

The present invention has been described in detail above with reference to the presented embodiments, but those of ordinary skill in this field will be able to make various modifications and modifications without departing from the technical spirit of the present invention with reference to the presented embodiments. . The present invention is not limited by such modifications and modifications, but is limited by the claims appended below.

10: hard hat
11: gas buffer layer 12: absorption layer
13: protective layer 31a, 31b: wearing means
33a, 33b: impact means 34: gas injection pad
35: absorption edge 51, 61: communication means
121: absorbent body 122: accommodating gap
131: impact body 132: avoidance visor
133: neck protective cover 134: light-emitting display unit
135: chin strap 341: gas expansion cell
342: separation area

Claims (3)

A gas buffer layer 11 into which gas is injected;
An absorbent layer 12 coupled upwardly to the gas buffer layer 11; And
It consists of a protective layer 13 disposed above the absorbent layer 12,
The protective layer 13 is a hard hat including a neck protective cover 133 for protecting the rear portion of the head. The helmet according to claim 1, further comprising a fold line (FL) formed on the protective layer (13). The safety helmet according to claim 1, further comprising a communication means (51, 61) capable of wireless communication with an external electronic device.

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