JP3014077U - Life jacket - Google Patents

Abstract

(57) [Abstract] [Purpose] The present invention has an object to realize a cheap and safe life jacket that has good flexibility and does not interfere with the work even if the user bends forward and works. [Structure] The invention is a life garment comprising a synthetic fiber wrapping cloth and / or a rubber wrapping and a buoyant material of an independent foamed resin sheet, and air or gas in a small amount of 1/2 or less of the bag capacity A life jacket was constructed by mounting at least one enclosed air bag on the front surface of the life jacket as an aid to buoyancy.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a life jacket and a life preserver such as a "tie" for life protection against water accidents such as ship passengers, harbor construction workers, fishermen, yachts, boats and canoe passengers. .

[0002]

[Prior art]

 The life vests for preventing water accidents for passengers on ships are roughly classified as follows. (1) Inflatable life jacket The inflatable life jacket has a gas-filled cylinder, and has a structure that opens the valve with a string and inflates the life jacket with the enclosed gas to obtain buoyancy. In case of cylinder misfire, it has an insertion tube that blows air through the mouth. The gas filled in the cylinder is 100% used.

(2) Automatic inflatable life jacket This life jacket has a cylinder similar to the inflatable life jacket described above, and has a structure in which the life jacket automatically inflates when exposed to seawater or water. It also has an insertion tube that blows air through the mouth. Also in this case, 100% of the enclosed gas is used. (3) Solid-type life jacket This life jacket uses buoyancy material consisting of an independent foam resin sheet. (4) Breathing life jacket This buoyancy jacket uses buoyancy material consisting of an independent foam resin sheet and air blown from the mouth by the insertion tube for buoyancy.

[0004] In addition, the classification of life jackets according to their uses and the outline of the test criteria for each classification are as follows. (1) Vessel life jacket (inflatable / solid type) About 15 tons or more for ships with a buoyancy of 12 cm or more from the mouth in water is specified. Also, there are expansion type and solid type. The floating posture is a backward leaning posture, and the angle is about 20 ° to 50 °. (2) Life jacket for small vessels (expansion type / solid type) For vessels of (1) and below, the buoyancy is on condition that the mouth is above the surface of the water. Enter the category. The buoyancy is 7.5 kg or more, and the floating posture is a backward leaning posture. (3) Life jacket for work (inflatable / solid / expired type) For deck work and port side work, seafarer occupational safety regulations require the use. The condition for total buoyancy is 7.5 kg or more. In this case, the buoyancy of the combined exhaled foamed resin sheet is 6 kg or more, and 1.5 kg or more of air is fed within 5 seconds when the insertion tube is used. Note that, for example, 7.5 kg of buoyancy means the buoyancy measured 24 hours after suspending 7.5 kg of iron pieces in fresh water.

(4) In addition to this, in the case of the combined use of exhalation, there are the following test standards and the like. Wearing test It is necessary to wear it alone on the ground in the non-inflated state according to the instructions, and be able to wear it within 25 seconds without hindering the work. In addition, it is necessary that the expiratory air supply device can be easily operated with one hand while it is worn, and it is required to blow more than 1.5 kg of air by mouth within 5 seconds. Dive-in test It is necessary that you wear it in a non-inflated state and in an inflated state, and jump in from a height of 1 m so that there is no abnormality on your body and body and your mouth is above the water surface. Floating test Wearing in a non-inflated state and an inflated state, and checking the floating posture after standing upright, the face is kept above the water, and the posture is tilted backward from the vertical. Airtightness test It is necessary to apply an air pressure of 100 mmHg at room temperature and keep the air pressure at least 70 mmHg after 24 hours.

[0006] Generally, the life jackets classified according to the above-mentioned types have the following drawbacks. (1) In the case of an inflatable life jacket, anxiety about the failure of the cylinder and the supply of air by the mouth using the pinhole and the insertion tube of the bag may not be in time after the water falls. In addition, since there are cylinder-shaped protrusions on the garment, the work is hindered and it is difficult to determine the deterioration of the air supply function. Further, since the cylinder is used, the product is expensive and heavy. (2) The self-inflating life jacket has the same drawbacks as the above-mentioned inflatable life jacket. In addition, fishing workers may automatically inflate their life jackets when exposed to high waves. (3) The solid-type life jacket has the drawback of being bulky. (4) In the case of a life jacket with an exhalation breath, not only is it expensive because an insertion tube is required, but also the air supply operation is complicated.

[0007] Next, a life jacket that has been conventionally used will be described by giving an example. 16 is a front view of a conventional vest type life jacket, FIG. 17 is a sectional view taken along line xx of FIG. 16, and FIG. 18 is a perspective view of a buoyancy member of the life jacket. 16 to 18, 1 is a body of a life jacket, 2 is a covering cloth having a plurality of divided bag chambers, and 3 is a floating cloth of an independent foamed resin sheet inserted into each bag chamber of the covering cloth 2. Strength members, 5 are fasteners for opening and closing the front of the life jacket, and 6 is a string for fastening the hem of the life jacket.

As shown in FIGS. 16 and 17, the main body 1 of the life jacket includes a covering cloth 2 formed of synthetic fiber cloth or mesh and divided into a plurality of front and rear trunk portions. An independent foamed resin sheet 3 having elasticity, such as foamed polyethylene, is inserted as a buoyancy material into the bag chamber of the cloth 2. As shown in FIG. 11, the independent foamed resin sheet 3 is formed in conformity with the contour of the bag chamber of the covering cloth 2. When inserting the buoyancy material 3 into the bag chamber of the covering cloth 2, the buoyancy materials 3 are stacked as shown in FIG. 12 and inserted into the bag chamber of the covering cloth 2, and the buoyancy materials 3 are joined to each other. Not not. Therefore, each buoyancy member 3 can be independently bent, and the life jacket 1 is characterized by high flexibility.

FIG. 19 is an explanatory view of a cross section of another conventional life jacket, and FIG. 20 is a perspective view of a buoyant member used in FIG. The life jacket 1 shown in FIGS. 19 and 20 is formed such that the thickness of the chest and back is thin, and the upper part is thin and the lower part is thick. For this reason, the buoyancy material 3 to be inserted into the bag chamber of the covering cloth 2 is layered in a stepwise manner as shown in FIG. In this life jacket, a part of the thickest part of the buoyancy material 3 is heat-sealed to the bag chamber of the covering cloth 2. In this life jacket, since the lower part of the life jacket is thickly formed, there is a drawback in that workability is poor during work in which the lower portion must be bent.

[0010]

[Problems to be solved by the device]

 As described above, the conventional life jackets have various drawbacks. Since the life jacket shown in FIGS. 16 to 20 is formed by laminating thin sheet-shaped buoyancy members made of independent foaming resin, the flexibility is insufficient in common when working in a forward bending posture. Therefore, it was difficult to perform work while wearing the life jacket, and there was a request from the wearer of the life jacket to improve the life jacket.

The present invention has been made in order to solve the above-mentioned problems of the conventional life jacket, has a good bending property, and is an inexpensive and safe life saving device that does not interfere with the work even when the user bends forward and works. The purpose is to provide clothes.

[0012]

[Means for Solving the Problems]

 The invention is a synthetic fiber covering cloth and / or a rubber covering, a solid buoyant material having buoyancy made of an independent foamed resin, and a buoyancy made of rubber and / or synthetic resin for sealing gas. And a single or a plurality of bag-shaped buoyancy materials having a life jacket. In addition, the life garment is configured by selecting the total buoyancy of the solid buoyancy material and the bag-shaped buoyancy material as the reference value. In addition, a life jacket in which buoyancy is dispersed by enclosing gas in a plurality of bag-shaped buoyancy materials is constructed.

In addition, the present invention provides a life jacket made of synthetic fiber covering cloth and / or rubber covering and a buoyant member made of an independent foamed resin sheet, and air or gas of 1/2 or less of the bag capacity. An air bag containing a small amount of air bag is attached to the front of the life garment to assist at least one buoyancy. In addition, the present invention is directed to a life jacket made of synthetic fiber covering cloth and / or rubber covering cloth, in which an air bag in which air or gas is enclosed in a small amount of 1/2 or less of the bag capacity is provided in front of the life jacket. It is a life jacket made up of at least one piece attached to the surface to assist buoyancy. Further, the air bag constitutes a life jacket made of one kind of film or sheet selected from vinyl chloride, polyurethane resin, rubber and synthetic rubber. In addition, a life jacket is constructed by inserting an air bag between the lining cloth or between the lining and the lining and / or between the buoyancy member made of the independent foamed resin. In addition, a life jacket is constructed by enclosing a buoyancy material made of independent foaming resin in the air bag. In addition, a life jacket is constructed by inserting an air bag between the front and back of the covering cloth. In addition, the life garment is a type of life garment that is selected from a chiyochi type, a top-and-bottom tie type, a vest type, a jumper type, and a kappa type.

Further, the present invention is a chijo type in which a plurality of independent foamed resin sheets provided as buoyancy members and air bags filled with air are arranged inside the bag chambers on the front left and right sides of the body of the life jacket. In the life jacket, a plurality of independent foamed resin sheets are formed in a shape along the body shape, and a plurality of air bags are attached between the independent foamed resin sheets to form a life jacket. In addition, the air bag is a life jacket made of a rectangular film. In addition, a life jacket was constructed in which an air bag was filled with about 1/4 of the total volume of air. In addition, a life jacket made of ether type TPU film was used for the air bag. In addition, it constitutes a life jacket in which air bags are arranged from the shoulders to the hem.

[0015]

[Action]

 The buoyancy material of the life jacket is divided into the right and left foreground and rear view. For the buoyancy material on the left and right rear sides, seven coarse polyurethane sheets with a horizontal cutting line between two densely dense polyurethane sheets each having a shape corresponding to the body shape were used. There is. On the other hand, on the left and right sides of the front view, three air bags are interposed between two polyurethane sheets with a high density along the body shape. The air bag inside the front section is made of highly stretchable ether-type PUT, and is made into a slender rectangular shape with a length close to the maximum length. Inside each air bag, about 1/8 of the total volume of air is sealed in advance.

The life jackets in which the buoyancy materials are dividedly arranged on the right and left foreground and backside are worn by the passengers of the ship, the port operator, and the like. When a part of the air bladder is pushed by the movement of the upper body during work, the air in the pushed portion appropriately moves in the air bladder, and the pressing portion bends freely. In addition, since the cutting line is formed in the resin sheet having a coarse density, which is arranged at a later time, the resistance force due to the bending of the upper body hardly occurs. When entering a seawater wearing a life jacket, a solid buoyancy material consisting of a resin sheet produces 6 kg of buoyancy. The total buoyancy of the bladder reaches about 1.5 kg. Then, due to the buoyancy of the air bladder, the floating posture on the water surface is stably maintained in the backward tilt.

[0017]

【Example】

 Embodiment 1 FIG. 1 is a front view of a chijochi life jacket according to Embodiment 1 of the present invention, FIG. 2 is a rear view of the life jacket of FIG. 1, FIG. 3 is a sectional view taken along line xx of FIG. 1, and FIG. 4 is an air bag. , (A) is a side view and (b) is a plan view. 1 to 4, 1 is a life jacket, 2 is a covering cloth forming a bag chamber, 3 is an independent foam buoyant material of a resin sheet, 5 is a fastener, 6 is a string for fastening the hem of the life jacket 1, and 7 is Air bag, 8 is enclosed air.

As shown in the figure, the life vest 1 according to the present invention comprises the life vest 1 in which a buoyancy member 3 made of an independent foamed resin sheet and an air bag 7 are fitted inside a cloth 2 of cloth. The buoyancy of the independent foamed resin sheet 3 is set to 5.0 to 6.0 kg in this embodiment. The air bag 7 is made of a bag-shaped polyurethane film having a width of 100 mm and a length of 500 mm. The air bag 7 is filled with 250 cc of air 8 and sealed with a welder. Two air bags 7 are provided on each of the front left and right sides, and two air bags 7 are provided on the back, and a total of six air bags 7 are inserted. The inserted air bag 7 is fixed at its upper and lower ends between the buoyancy members 3 inside the covering cloth 2. Therefore, it is possible to take a stable floating posture while wearing the life jacket 1 underwater or in the sea.

The independent foamed resin sheet 3 which is the main buoyancy material is a polyethylene independent foamed resin sheet having a foaming ratio of about 30 to 40 times. It is not preferable that the ratio is more than that, because it easily collapses and becomes water bubbles and absorbs water. In addition to the above-mentioned polyurethane film, the material of the air bag 7 is selected from polyethylene, vinyl chloride, rubber, synthetic rubber and the like. Since polyethylene does not stretch, it easily tears, and vinyl chloride has poor cold resistance. Polyurethane film is most preferable because it has excellent cold resistance and elasticity, is used in all the current inflatable life jackets, and conforms to the type standards of the Ministry of Transport.

As shown in FIG. 4 (b), the air bag 7 is formed by bending a polyurethane film and sealing the open side 9 by, for example, heat sealing to form a rectangle with a width of about 10 cm and a length of about 50 cm. . The buoyancy member 3 may be enclosed in the air bag 7 as shown by the alternate long and short dash line in FIG. When the air bag 7 of this size is filled with air, that is, when the air bag 7 has a circular cross section, the inner volume is about 2000 cc (buoyancy is 2 kg). Therefore, the amount of air 8 that is ⅛ at the time of full distribution is 250 cc, and one air bag produces about 250 g of buoyancy.

The enclosed amount of air in the air bag 7 can be increased or decreased in accordance with the buoyancy of the buoyancy member 3. In the examples, the enclosed amount of air was set to a maximum of 1/2 of the total internal volume. Therefore, when a part of the air bladder 7 is pressed, the air 8 in the pressing part moves to another part. Since the air bladder 7 is inserted between the buoyancy members 3 as shown in FIG. 3, when the wearer bends forward as shown in FIG. 5, the air 8 at the bent portion 10 can freely move above and below the air bladder 7. Move to. Therefore, the thickness of the bent portion 10 becomes thin, and air resistance due to bending hardly occurs. Therefore, even if the wearer of the life jacket 1 moves his or her body during work, the resistance by the life jacket is hardly felt.

Embodiment 2 FIG. 6 is a front view of a life jacket according to Embodiment 2 of the present invention, FIG. 7 is a rear view, and FIG. 8 is an exploded view of the inner surface side. In the second embodiment of FIG. 6 as well, the same members as those of the first embodiment are designated by the same reference numerals, and the description will be partially duplicated but will be described in a little more detail. 6 to 8, 1 is a body of a life jacket, and 2 is a cover cloth. The covering cloth 2 is composed of a yellow outer material 2a and a lining material 2b made of synthetic resin. The outer surface 2a and the lining 2b of the covering cloth 2 are sewn together to form a main body 1 having four bag chambers 1a to 1d on the left and right sides of the front and back portions. For the outer material 2a and the inner material 2b, a cloth or mesh made of nylon fiber or the like having a hue determined by the test standard and low water absorption is used.

Reference numeral 3 is a solid buoyancy material made of an independent foamed resin sheet, 5 is a fastener, 6 is a string for connecting both sides of the main body 1 to tighten the hem, 7 is an air bag, 8 is air enclosed in the air bag 7. These members are as described in the first embodiment. Reference numeral 13 is a bead, and 14 is a retroreflective material that retroreflects light in an unspecified direction. The bead 13 borders the black and yellow front material 2a and lining 2b, and the retroreflective material 14 is attached to the front surfaces of both shoulders.

Reference numeral 15 is a plurality of eyelets provided on both sides of the back of the main body 1, 16 and 17 are large and small chest pockets, 18 is a hem pocket for storing the string 6, 19 is a whistle, and 20 is a connecting cloth. is there. The string 6 is tied in front from the eyelet 15 through a string passing hole around the hem, and a small chest pocket 17 accommodates a calling whistle 19 tied with a thin string. The connecting cloth 20 operatively connects the left and right back chambers 1c and 1d.

In particular, in Example 2, the air bag 7 is made of an ether type thermoplastic polyurethane resin (THERMO PLASTIC URETHANE ... TPU) film. The ether type TPU film has a high strength retention rate (tensile strength, breaking strength, elongation at break, mold resistance test in water resistance test), and changes in strength retention are extremely small even after long-term immersion in water.

Two thin resin sheets 3a as a buoyancy member 3 and an air bag 7 are housed in the left and right bag chambers 1a and 1b of the main body 1 as shown in FIGS. 9 and 10, respectively. There is. As the resin sheet 3a, a resin sheet 3a having a shape with a low density is used, and three air bags 7 are interposed between each of the two resin sheets 3a (see FIG. 10). As shown in FIG. 9 (the right drawing is omitted), the three air bags 7 have their upper ends overlapped and integrally welded to the resin sheet 3a, and their lower ends are fixed to each other with some offset. The structure in which the air bag 7 is fixed and the four-part structure of the bag chambers 1a to 1d smoothes the movement of the hem close to the waist of the wearer.

Further, two resin sheets 3a having a contour shape along the body shape are inserted on the rear viewing side of the main body 1 as in the front viewing. Further, instead of the air bag 7, seven resin sheets 3b made of slightly foamed independent expanded polyethylene are arranged in layers. Two-dot chain line 3c is a cutting line provided at two upper and lower positions in the horizontal direction of the resin sheet 3b, and is for absorbing the resistance due to the bending and stretching action of the back during wearing. For the resin sheets 3a and 3b, for example, Melloform and Literon (both product names) having a natural thickness of about 3 mm are suitable.

The operation of the life jacket of the second embodiment having such a configuration will be described below. The body 1 of the life jacket in which the buoyancy members 3 are separately arranged on the left and right foreground and backside is folded in four, for example, and stored compactly in an elongated box at the time of delivery. The fastener 5 is opened prior to use and is worn in a waistcoat type by the passengers of the ship, port workers, etc.

When the air bag 7 of the main body 1 is not used or is stationary during wearing as described above, the enclosed air 8 is scattered in unspecified positions in the internal space. When a part of the air bladder 7 is pushed along with the movement of the upper body by the wearer during work, the air 8 in the pushed portion appropriately moves in the air bladder 7 and the pressing portion flexes freely. Further, since the resin sheet 3a having a high density is thin, and the cutting line 3c is formed on the resin sheet 3b having a coarse density which is arranged at a later time, the resistance force due to the bending of the upper body hardly occurs.

When the body 1 of the life jacket is put on and put in the water, the solid buoyancy material 3 made of all the coarse and dense resin sheets 3a and 3b having a small specific gravity inserted into the body is about 6 kg in total. Buoyancy occurs. Further, each air bag 7 in the foreground is subjected to water pressure and pressed from the outside, and the enclosed air 8 is pushed up from below to form air tanks on all the air bags 7. The total buoyancy of the formed air tank reaches almost 1.5kg. The buoyancy of the air bladder 7 allows the floating posture on the water surface to be stably maintained in a backward tilt.

According to the life jacket of the second embodiment, the following effects are expected. Since the total buoyancy is maintained at 7.5 kg or more, it meets the above-mentioned test standards for small vessels and work. The buoyancy of the solid buoyancy material 3 of the combined use of exhaled air maintains the value of 6.0 kg or more, which is the test standard. The buoyancy member 3 of the combined use of exhaled air passes the regulation while holding the face in the unexpanded state and the inflated state at the water position of the test standard. Due to the buoyancy of the air bags 7 in the left and right bag chambers 1a and 1b at the time of the foreground, the backward floating posture of the solid air chamber combined type and the air filled combined type is maintained. Therefore, the wearability of the life jacket 1 becomes extremely good for the following reasons.

B. The air bag 7 is thinner than the solid buoyancy material 3, and the thickness at the foreground is 7 mm or less, so that an extremely thin life jacket is realized. B. Since the air bladder 7 is flexible, it adapts to the movement of the upper body. C. The amount of air enclosed is small (for example, 250cc ... 1/8 of the total enclosed volume), and there is almost no air resistance when worn. A 10 x 50 cm air bag can generate about 2 kg of buoyancy. D. The air bag 7 is arranged between the two resin sheets 3a, and is further surrounded by the outer material 2a and the inner material 2b. Therefore, the air bag 7 is resistant to external impacts and is less likely to be damaged. E. Since the six air bags 7 are provided, even if one is damaged, the function of the life jacket 1 can be fulfilled. F. Since the air bag 7 uses a stretchable TPU film, for example, when a needle of 2 mm or less is pierced, so-called tubeless function works so that air leakage does not occur in water within 1 m from the water surface. . G. In particular, if an ether type TPU film whose chemical characteristics do not change up to −45 ° C. is used as the material of the air bag 7, a life jacket suitable for winter and cold sea areas can be realized with high cold resistance.

FIG. 12 and FIG. 13 are front and rear views of a work life garment with upper and lower ties, which is another embodiment of the present invention, and FIG. 14 is a side view of a tie life garment according to yet another embodiment. . The life garment of FIGS. 12 to 14 is a top-and-bottom tie type connected to the lower garment 4. In particular, FIG. 14 shows that the upper garment and the lower garment 4 are connected to each other by the fastener 5, and the mesh-like cloth 11 is used between the back of the upper garment and between the front part and the back part of the lower garment 4. It is a cover-type life jacket that has a rubber part 12 on its part to make it easier to move. The buoyancy material 3 made of an independent foamed resin sheet is attached to the whole of these upper and lower connecting life jackets. FIG. 15 is an explanatory view of a jumper-type life jacket according to another embodiment with the front portion opened. In this case as well, the buoyancy member 3 made of an independent foamed resin sheet is attached to the whole, and the air bag 7 is attached to the outside.

In the embodiment of the present invention, the air bag was used as an example of assisting the buoyancy of the buoyancy material of the independent foamed resin sheet, but a synthetic fiber covering cloth and / or a rubber covering for lifesaving You may use only air bags for the buoyancy of your clothes. Further, as described with reference to FIG. 12 and thereafter, the present invention can be applied not only to the ordinary chijo type, but also to various life jackets such as a neck hanging type, a top-and-bottom tie type, a jumper type and a kappa type. In addition to the synthetic resin fiber surface and lining, a rubber garment may be used, and it can be removed by attaching an air bag as a buoyancy material to the life jacket by an appropriate means such as an adhesive, or by attaching it as a liner. Embodiments are also possible.

Further, although the air bag is arranged in the vertical direction, the air bag may be arranged in any direction such as sideways or diagonal, and it is necessary to equip at least one on the front surface from the viewpoint of ensuring safety. In addition to the polyurethane film, the material of the air bag 7 may be polyethylene, vinyl chloride, comb, synthetic rubber or the like, and the size is not limited to 10 cm × 50 cm, and various sizes may be combined. Good. Further, the gas to be enclosed may be a gas other than air, and the amount to be enclosed can be appropriately selected according to the specifications of the life jacket. Furthermore, the material, shape, and amount of use of the independent foamed resin sheet are not necessarily limited to those in the examples as long as the independent foamed resin sheet has a buoyancy force higher than the specified value. Further, as described above, the buoyancy member 3 formed of the conventional independent foam synthetic resin may be inserted together with the air bag 7.

[0036]

[Effect of device]

 The present invention includes a synthetic fiber covering cloth and / or a rubber covering, a solid buoyant material having a buoyant force made of an independent foaming resin, and a buoyant force made of rubber and / or a synthetic resin to enclose gas. And a single or a plurality of bag-shaped buoyancy members having a. In addition, a life jacket was constructed by selecting the total buoyancy of solid buoyancy material and bag-shaped buoyancy material as the standard value. In addition, a life jacket in which buoyancy was dispersed by enclosing gas in a plurality of bag-shaped buoyancy materials was constructed.

In addition, the present invention uses a life jacket composed of a synthetic fiber covering cloth and / or a rubber covering cloth and a buoyant member of an independent foamed resin sheet, and air or gas of 1/2 or less of the bag capacity. A life jacket was constructed by attaching at least one air bag containing a small amount on the front of the life jacket as an aid to buoyancy. In addition, the present invention is directed to a life jacket made of synthetic fiber covering cloth and / or rubber covering cloth, in which an air bag in which air or gas is enclosed in a small amount of 1/2 or less of the bag capacity is provided in front of the life jacket. A life jacket was constructed by attaching at least one piece to the surface as an aid to buoyancy. In addition, the air bag was made into a life jacket made of one kind of film or sheet selected from vinyl chloride, polyurethane resin, rubber and synthetic rubber. Further, a life jacket was constructed by inserting an air bag between the covering cloth or the surface of the covering and the lining and / or between the buoyancy member made of the independent foamed resin. In addition, a life jacket was constructed by enclosing a buoyancy material made of independent foamed resin in the air bag. In addition, a life jacket was constructed by inserting an air bag between the front and back of the covering cloth. In addition, the life jacket was one type selected from the chijo type, the top-and-bottom type, the vest type, the jumper type, and the kappa type.

In addition, the present invention is a chijo type in which a plurality of independent foamed resin sheets provided as buoyancy members and air bags filled with air are arranged inside the bag chambers on the front and left sides of the body of the life jacket. In the life jacket, a plurality of independent foam resin sheets were formed in a shape along the body shape, and a plurality of air bags were attached between the independent foam resin sheets to form a life jacket. In addition, a life jacket was constructed with an air bag made of a rectangular film. In addition, a life jacket was constructed in which an air bag was filled with about 1/4 of the total volume of air. In addition, a life jacket was constructed using an ether type TPU film in the air bag. In addition, a life jacket was constructed with air bags arranged from the shoulders to the hem.

As a result, the life jacket of the present invention has the following effects. (1) The overall life jacket has become thinner and the workability has been improved. Especially, the thickness of the chest is dramatically thinner than the type approved product. (2) With the air filling amount of the air bag of the above-mentioned example, it cannot be seen from the outside that the independent foamed resin sheet and the air bag are used together. It is enough to understand that the sealed air is pushed forward from one end. (3) Even if one air bag filled with air is punctured, it is safe because multiple air bags are inserted as a whole. (4) Since the amount of air enclosed in the air bag is very small, the air in the air bag moves to another location when the air bag is pressed partially or when the body is bent forward, or even when an object is pressed against the back, the air in the air bag moves to another location. Even if you lean forward, you can hardly feel the resistance of the life jacket. (5) Since the air bag is inserted between the buoyancy material and the buoyancy material, it is hard to break even if an object hits it. (6) Since there is a small amount of air in the air bag, there is almost no resistance due to the air pressure in the air bag, so there is little concern about air leakage due to pinholes.

Therefore, according to the present invention, it is possible to provide an inexpensive and safe life jacket that has good flexibility and does not hinder the work even when the user bends forward and works.

[Brief description of drawings]

FIG. 1 is a front view of a chijo type life jacket according to a first embodiment of the present invention.

FIG. 2 is a rear view of FIG.

3 is a sectional view taken along line XX of FIG.

4A is a side view and FIG. 4B is a plan view of the air bag of FIG.

FIG. 5 is an operation explanatory diagram of the first embodiment of the present invention.

FIG. 6 is a front view of a life jacket according to a second embodiment of the present invention.

FIG. 7 is a rear view of the second embodiment of the present invention.

FIG. 8 is a development view of the inner surface side of the second embodiment of the present invention.

FIG. 9 is an explanatory diagram showing the internal structure of the front side of the second embodiment of the present invention.

FIG. 10 is a sectional view showing the internal structure of the front side of the second embodiment of the present invention.

FIG. 11 is an explanatory view showing the internal structure on the back side of the second embodiment of the present invention.

FIG. 12 is a front view of a top-and-bottom type life jacket according to another embodiment of the present invention.

FIG. 13 is a rear view of FIG.

FIG. 14 is a side view of a cover-type life jacket according to another embodiment of the present invention.

FIG. 15 is a front view of a jumper-type life jacket according to another embodiment of the present invention.

FIG. 16 is a front view of a conventional life jacket.

FIG. 17 is a sectional view of a conventional life jacket.

FIG. 18 is a perspective view of a buoyancy member of a conventional life jacket.

FIG. 19 is a cross-sectional view of another conventional life jacket.

FIG. 20 is a perspective view of another conventional buoyancy member for life jacket.

[Explanation of symbols]

 1 Body of life jacket (life jacket) 1a Left front viewing bag 1b Right front viewing bag 1c Left back viewing bag 1d Right back viewing bag 2 Cover cloth 2a Outer fabric 2b Outer fabric 3 Independent foamed resin sheet buoyancy Material 3a Dense resin sheet 3b Coarse resin sheet 3c Cutting line 4 Underwear 5 Fusner 6 String 7 Air bag 8 Air 9 Side 10 Bending part 11 Mesh fabric 12 Rubber part 13 Bead edge 14 Retroreflective material 15 Eyelet 16 Chest pocket 17 Chest Pocket 18 Hem Pocket 19 Yobushi 20 Coupling Cloth

[Procedure amendment]

[Submission date] January 27, 1995

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be amended] Scope of utility model registration request

[Correction method] Change

[Correction content]

[Scope of utility model registration request]

Claims (15)

[Scope of utility model registration request] 1. A synthetic fiber covering cloth and / or a rubber covering, a solid buoyant material having a buoyancy composed of an independent foamed resin, and a buoyancy composed of a rubber and / or a synthetic resin for enclosing a gas. And a single or a plurality of bag-shaped buoyancy materials having a life jacket. 2. The life jacket according to claim 1, wherein the total buoyancy of the solid buoyancy material and the bag-shaped buoyancy material is selected as a reference value. 3. The life jacket according to claim 1, wherein gas is enclosed in the plurality of bag-shaped buoyancy members to disperse the buoyancy. 4. A life jacket composed of a synthetic fiber covering cloth and / or a rubber covering cloth and a buoyancy member of an independent foamed resin sheet,
A life jacket, characterized in that at least one air bag, in which a small amount of air or gas of less than 1/2 of the bag capacity is sealed, is attached to the front of the life jacket as an aid to buoyancy. 5. A life jacket made of a synthetic fiber covering cloth and / or a rubber covering cloth, and an air bag in which air or gas is enclosed in a small amount equal to or less than 1/2 of the bag capacity is provided in front of the life jacket. A life jacket, characterized in that at least one piece is attached to assist buoyancy. 6. The life jacket according to claim 4, wherein the air bag is made of one kind of film or sheet selected from vinyl chloride, polyurethane resin, rubber and synthetic rubber. 7. The air bag according to claim 5, wherein the air bag is inserted between the lining cloth or the surface of the lining and the lining, and / or between the buoyancy member made of the independent foamed resin. Life jacket. 8. A buoyancy member made of the independent foamed resin is enclosed in the air bag.
Or the life jacket described in 6 or 7. 9. The life jacket according to claim 5, wherein the air bag is inserted between the front and back of the covering cloth. 10. The life jacket according to claim 4, wherein the life jacket is one selected from a chijo type, a top and bottom coverall type, a vest type, a jumper type and a kappa type. Life jacket. 11. A chijo type life jacket in which a plurality of independent foamed resin sheets provided as buoyancy members and air bags enclosing air are arranged inside the bag chambers on the front and left sides of the body of the life jacket. A life preserver characterized in that a plurality of independent foamed resin sheets are formed in a shape along a body shape, and a plurality of the air bags are attached between the independent foamed resin sheets.
12. The life jacket according to claim 11, wherein the air bag is made of a rectangular film. 13. The life jacket according to claim 11 or 12, wherein the air bag is filled with an air amount of about ¼ of the total volume. 14. The ether type TPU is provided in the air bag.
The life jacket according to any one of claims 11 to 13, wherein a film is used. 15. The life jacket according to claim 11, wherein the air bag is arranged along the hem from the shoulder of the main body.