JP2018053387A - Cooling garment for hot site work - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cooling garment for hot site work which provides a sufficient cool feeling to a human body, easy loading of dry ice, good workability of workers, and satisfies the criteria of flame retardancy.SOLUTION: The cooling garment comprises a garment body 10 and a pocket portion 11 provided inside the garment body 10 to contain dry ice. The fiber material constituting the cooling garment consists of flame-retardant fibers. Therefore, the garment meets the flame retardancy criteria as a garment worn in high temperature environments represented by blast furnaces, electric furnaces, welding/fusing, shipbuilding, glass manufacturing and processing, etc., and ensures operator's safety. Additionally, since the garment utilizes the cold heat of the dry ice contained in the pocket portion 11, it has no additional device or tube for circulating liquid and the workability does not decline. Furthermore, since the pocket portion 11 is provided inside the garment body 10, the cold heat of the dry ice contained in the pocket portion 11 does not escape to the outside and easily acts on the body, and thus efficiently giving a cool feeling to the operator.SELECTED DRAWING: Figure 1

Description

The present invention relates to a cooling garment for hot work that can be worn in a high temperature environment to cool an operator's body and prevent a trouble caused by heat such as heat stroke.

  Cooling clothes are worn to protect the worker's body in a high temperature environment from damage caused by the high temperature. As prior art documents regarding such cooling clothing, the applicant has grasped the following Patent Documents 1 to 4.

Patent Documents 1 and 2 relate to a technique in which a flow path for circulating a fluid is provided in clothing and the worker is cooled by the circulation of the fluid.
Patent Documents 3 and 4 relate to a technique in which a pocket for storing cooling dry ice is provided in clothing and the worker is cooled by the dry ice.

[Patent Document 1]
Patent Document 1 (Japanese Patent Laid-Open No. 2014-77207) cools a liquid fluid (such as water) with a cold storage agent in a fluid container (such as polyurethane). The liquid fluid is circulated in a flow path (tube made of silicon rubber or polyurethane) in the cooling garment by an electric pump. Thereby, the cooling clothing which gives a cool feeling to an operator is disclosed. In this cooling garment, a pump unit and a heat exchanger are attached to the back side of the body.

The above Patent Document 1 has the following description.
[Summary] [Solution] The cooling garment includes flow paths 9a and 9c through which fluid circulates, an electric pump through which the fluid circulates, a fluid container 12 that communicates with the flow path and holds the fluid, and a heat insulating material. And an insulating container 5. The fluid container 12 is stored inside the heat insulating container 5 in contact with the cold storage agent 13, and the fluid is cooled by heat exchange. The electric pump circulates the cooled fluid by sending it to the flow path 9a attached to the cooling garment.

[Patent Document 2]
Patent Document 2 (Japanese Patent Laid-Open No. 2003-113507) is the best with a structure similar to Patent Document 1. A storage part for obtaining cold heat is arranged separately from the vest, and dry ice is used as a heat source for cold heat. The antifreeze cooled by dry ice is supplied to the vest using a pipe. Disclosed is a method in which an antifreeze is circulated through a tube in a vest and an operator obtains cold.

The above Patent Document 2 has the following description.
[Summary] [Solution] A heat source 4 such as a dry ice or cold insulation material or a heat source 4 such as a warmer or bean charcoal and a heat transfer pipe 5 into which a liquid that conducts heat from the heat source 4 is injected are stored in a container body 6. At the same time, cold water or hot water in the heat transfer pipe 5 is circulated by the pump 8 and is passed through a flow path formed in the clothing such as the jacket 1 in the middle of circulation, thereby providing cold or hot heat to the wearer.

  The cooling clothing of Patent Documents 3 and 4 uses the cold heat of dry ice. There is no additional device or tube for circulating fluid as in Patent Documents 1 and 2.

[Patent Document 3]
Patent document 3 (Unexamined-Japanese-Patent No. 2011-1669) discloses the cooling clothing which obtains cold without circulating a cooling fluid. This cooling garment is formed of a mesh material, and a pocket portion for inserting a cold insulation material is arranged outside the cooling garment. A block-shaped dry ice with an appropriate size is wrapped with a paper material and put into a pocket to obtain a cool feeling.

The above Patent Document 3 has the following description.
[Summary] [Solution] Use of the mesh material 2 on the entire surface of the body cooling garment 1 makes air permeability better than that of a normal fabric. The chest pocket portion 30, the back pocket portion, the ventral pocket portion 34, and the neck pocket portion formed of the same mesh material 2 contain paper material packaging dry ice pieces, which can cool the body by the cold air. it can.
[0021]... The mesh material 2 having a large number of small holes arranged on the entire surface is used for the fabric of the body cooling garment 1 as a whole. In the front body 3, a chest pocket portion 30 is provided symmetrically at a position corresponding to the chest portion 20, and a ventral side pocket portion 34 is provided symmetrically at a portion corresponding to both abdominal side portions 24. ...
[0022] ... For the fabric of the body cooling garment 1, the mesh material 2 is used as a whole as in the front view of FIG. A neck pocket portion 36 is provided at a portion corresponding to the neck portion 26. Further, a back pocket portion 32 is provided one above the other at the portion corresponding to the back portion 22 in the back body 4. In portions corresponding to the two ventral side portions 24, ventral side pocket portions 34 are provided symmetrically.
[0025]... The pocket portion 7 is also made of the mesh material 2 like the body of the body cooling garment 1. Further, a flap-shaped mesh material 12 is sewn to a portion where the insertion port 19 of the pocket portion 7 formed on the upper side of the pocket portion forming mesh material 11 can be closed.
[0029]... By using the mesh material 2 over the entire surface of the body cooling garment 1, air permeability becomes better than that of a normal fabric. Also, as shown in FIG. 4, since the mesh material 2 is used for the entire surface of the pocket portion 7, in FIG. 5, the cool air 56 from the paper material dry ice 54 is sufficiently transmitted to the body side and the outside side. Will be able to. Further, since the entire surface is formed of the mesh material 2, drying is quick after washing to remove dirt. ...
[0030] A large number of small holes in the mesh material 2 should have a rhombus shape with a length of about 3 mm and a width of about 2 mm, and the thickness of the fabric should be about 1 mm, but may be changed appropriately depending on the state of use. Is possible. ...

[Patent Document 4]
Patent Document 4 (Japanese Patent Laid-Open No. 52-15747) discloses a jacket-like cooling garment. A block of dry ice is loaded into a pocket (loose knit nylon, etc.) formed inside the jacket. Three pieces of the above-mentioned dry ice having an appropriate size are put in a bag called a mesh carrier. This carrier is then placed in an insulating sleeve of a laminate layer made of plastic film. This insulating sleeve is further loaded into the pocket.

The above Patent Document 4 has the following description.
[Gazette, page 2, lower left column, line 10 to lower right column, line 6] In FIGS. 1 to 4, reference numeral 10 denotes a cooling jacket for a human body worn by an operator W or another person who requires cooling. Show the whole. The jacket 10 has a somewhat conventional appearance and includes a barrel 11, a right sleeve 12 and a left sleeve 13. The body 11 is substantially chisel-shaped and includes a quilted nylon outer shell 14 (FIG. 4) and a nylon inner shell or ** 15 which is sewn to the outer shell and attached by other methods. . The quilted outer shell includes a pair of nylon sheets 16, 17 that are sewn along * 18 (see FIG. 1) to form a closed pocket or space filled with insulator 19. . The chiyotsuki body is provided with an arm opening for attaching a sleeve. ――In addition, “*” is a character that the applicant could not read.
[Gazette, page 3, upper right column, 1st to 4th lines] Next, in FIG. 2, a pair of pockets 27 and 28 extending substantially vertically are provided at the rear of the jacket. A pocket 29 is also attached to the left half of the front portion of the jacket.
[Gazette, page 3, upper right column, lines 9 to 12] Each pocket is formed to hold one or more lump of dry ice, and when dry ice is inserted, the upper end of the pocket Is closed by suitable closing means.
[Gazette, page 3, lower left column, lines 1 to 16] Dry ice is held almost evenly by carrier 37 (FIG. 6) formed of two layers of mesh or net material in the longitudinal direction of each pocket. Is done. The two-layer mesh is almost the same shape as the rectangular pocket, and is sewn along one side 38 of the long side surface, the upper end 39 and the bottom end 40. The mesh is further sewn along horizontal lines 41 and 42 to form three ice pockets 43 between horizontal seams. Three lumps 44 of dry ice are inserted into the interior of the carrier 37 from the open side of the pocket, and the carrier is further inserted into an insulating sleeve or pocket 45 that opens upward. The insulating sleeve 45 shown in the figure is composed of a commercially available two-layer plastic film laminate layer, one of which is formed of a sheet of insulating material containing air bubbles 46.
[Gazette, page 4, upper left column, lines 6 to 9] The pocket is made of a porous material such as woven cotton or loose-knitted nylon so that carbon dioxide gas can be easily diffused or penetrated by the pocket.

JP 2014-77207 A JP 2003-113507 A JP 2011-1669 A JP 52-15747 A

〔Workability〕
The cooling garments such as Patent Document 1 and Patent Document 2 described above are complicated additional devices such as a container for storing the circulating fluid, a pump for cooling the circulating fluid, and a temperature sensor in order to obtain the necessary cooling heat by the cold insulation function and the circulating function. is necessary.
When these additional devices are mounted on the cooling garment side, they are heavy and bulky, leading to a reduction in work efficiency. Even if these additional devices are separated from the cooling garment, the work is performed in a state where the cooling garment and the additional device are connected by a tube or the like, and workability is poor. Since the tube for circulating the circulating fluid is drawn around the cooling garment itself, the feeling of wearing is insane and workability is poor.

〔Flame retardance〕
Some business establishments in Japan use standards that all materials must be flame retardant for work clothes used in working environments such as blast furnaces, forging plants, electric furnaces, welding / melting, shipbuilding, and glass manufacturing. The majority.
However, although the cooling garments of Patent Documents 1 to 4 are all intended for workers in a high temperature environment, there is no mention of the flame retardancy of the material. The fact is that the above-mentioned criteria are not considered at all.

  The cooling garment disclosed in Patent Document 1 uses a polyurethane container as a fluid container, and a tube made of silicone rubber or polyurethane as a tube through which a fluid flows. For this reason, it is clear that it does not meet the above-mentioned flame retardance standards.

  Since the above-mentioned patent document 3 wraps dry ice with a flammable paper material, it is clear that the above-mentioned flame retardant standard is not met. In this document, most of the cooling clothing is formed of a mesh material. Although there is no mention of the material in this document, the mesh material must generally be formed of a flammable material such as polyester. This is because it is extremely difficult to form a known flame retardant material in a mesh shape. That is, it is clear that Patent Document 3 does not conform to the above-described flame retardance standard.

  In addition, in the cooling garment of Patent Document 3, dry ice is loaded into a pocket provided on the outside of the garment. Therefore, structurally, it is difficult to incorporate cold heat into the human body. For this reason, mesh fabric that allows easy passage of cold air is used. In addition, the mesh dough cannot retain the cold heat of dry ice. The cold heat of the dry ice in the outer pocket passes through the mesh, and even if it enters the inside, it quickly falls out. Thus, this cooling garment is not structured to effectively cool the human body.

  In the above-mentioned Patent Document 4, the body 11 is made of quilted nylon. The insulating sleeve is formed from a plastic film. The pocket is made of loose-knitted nylon or the like. For this reason, it is clear that the above-mentioned flame retardant standards are not met.

Moreover, in the cooling clothing of the above-mentioned patent document 4, in order to avoid excessive cooling of the human body due to the dry ice coming into contact with the human body, the dry ice is wrapped in a bag-like double or triple, and finally in the pocket inside the clothing. Load it.
In this format, even if dry ice sublimates and it is not possible to secure a sufficient cooling sensation, new dry ice cannot be easily loaded. Since it is necessary to take off the insulating sleeve and the carrier from the inside and load the dry ice again, the working efficiency is extremely low.

〔sweating〕
In addition, in a high-temperature environment such as a blast furnace, electric furnace, welding / melting, shipbuilding, glass manufacturing / processing, the workers are also sweating. If it is cooled with dry ice without sweat being absorbed, it can partially freeze and damage the skin. For this reason, it is desirable that the material used for the cooling garment is not only flame retardant but also exhibits sufficient hygroscopicity.

In high temperature environments represented by operations such as blast furnaces, electric furnaces, welding / melting, shipbuilding, glass manufacturing / processing, cooling clothing is used to protect workers' bodies from high temperatures.
As in Patent Documents 1 and 2, those using a circulating fluid have a complicated structure and reduce workability.
As in Patent Documents 3 and 4, those using dry ice have a problem in flame retardancy.
In this way, cooling clothing that ensures the workability of workers, provides sufficient cooling sensation to the human body, is easy to load dry ice, meets the standards of flame retardancy, and has sufficient moisture absorption The fact is that it was not provided.

〔the purpose〕
The present invention has been made with the following object in order to solve the above problems.
To provide a cooling garment for hot work that gives a sufficient cooling sensation to the human body, is easy to load with dry ice, has good workability for workers, satisfies the flame retardant standards, and has sufficient moisture absorption.

In order to achieve the above object, the cooling garment for hot work according to claim 1 employs the following configuration.
The cooling garment includes a garment main body and a pocket portion that is provided inside the garment main body and accommodates dry ice,
The fiber material which comprises the said cooling clothing consists of a flame-retardant fiber.

In addition to the structure of Claim 1, the following structure was adopted for the cooling garment for hot work according to Claim 2.
The pocket part is provided with a flap,
The said flap is comprised with the fiber raw material which consists of a flame-retardant fiber.

In addition to the structure of Claim 1 or 2, the following structure was employ | adopted for the cooling garment for hot-work work of Claim 3.
The flame retardant fiber is one in which a base material mainly made of cotton is impregnated with a phosphonium compound.

In addition to the structure as described in any one of Claims 1-3, the following structure was employ | adopted for the cooling garment for hot-work work of Claim 4.
The pocket portion has a laminated structure in which a plurality of cloths are stacked on the inside portion.

Since the fiber material which comprises the said cooling garment consists of a flame-retardant fiber, invention of Claim 1 is a high-temperature environment represented by operations, such as a blast furnace, an electric furnace, welding and fusing, shipbuilding, and glass manufacture and processing. Even if it meets the flame retardant standards for clothes to be worn and sparks blown to the cooling clothes, it is possible to prevent the fiber material from burning up and to ensure the safety of workers.
Moreover, since the cold heat of the dry ice accommodated in the pocket part is used, there is no additional device or tube for circulating fluid, and workability does not deteriorate. further. Since the pocket part is provided inside the garment body, the cold heat of the dry ice contained in the pocket part easily acts on the body without escaping to the outside, and the efficiency of giving a cool feeling to the worker is good.

  According to a second aspect of the present invention, the pocket is provided with a flap, and the flap is made of a fiber material made of flame-retardant fiber. For this reason, it complies with the flame retardant standard as clothes to be worn under the various high temperature environments described above, and the safety of the operator can be ensured. Even if it is the inside of the clothes, the flaps are provided by jumping out of the clothes and are structurally flammable.

  According to a third aspect of the present invention, the flame retardant fiber is obtained by impregnating a base material mainly made of cotton with a phosphonium compound. For this reason, when a flame-retardant fiber touches a fire, the flame retardance by the impregnated phosphonium compound is exhibited, and a worker's safety can be ensured. Further, since the base material is mainly made of cotton, it exhibits hygroscopicity and absorbs sweat from the worker in a high temperature environment. Troubles such as icing with dry ice and damaging the skin while sweat is not absorbed can be prevented.

According to a fourth aspect of the present invention, the pocket portion has a laminated structure in which a plurality of cloths are overlapped at an inner portion. For this reason, at least a plurality of cloths are present between the dry ice contained in the pocket and the human body wearing the cooling clothes. Therefore, it is possible to moderate the power of the dry ice acting on the human body moderately, prevent the occurrence of frostbite, and ensure safety. Dry ice can be easily loaded because dry ice can be accommodated in the pocket as it is.

It is a figure explaining the cooling garment for hot work work of 1st Embodiment of this invention. (A) is the front surface side, and (B) is the back surface side. It is a figure explaining the cooling garment for heat station work of the said 1st Embodiment. (A) is the front back side, and (B) is the back back side. It is a side view explaining the cooling garment for heat station work of the said 1st Embodiment. It is a figure explaining a pocket part. It is a figure explaining the cooling garment for hot work work of 2nd Embodiment of this invention. (A) is the front surface side, and (B) is the back surface side. It is a figure explaining the cooling garment for heat station work of the said 2nd Embodiment. (A) is the front back side, and (B) is the back back side. It is a side view explaining the cooling garment for hot work work of the said 2nd Embodiment.

  Next, an embodiment for carrying out the present invention will be described.

[First Embodiment]
FIGS. 1-4 is 1st Embodiment which shows the cooling garment for hot-work work to which this invention was applied.

[Overall structure]
1-3 is a figure which shows the whole structure of the cooling garment (henceforth "cooling garment") for the hot work of this embodiment.

  As for the said cooling garment, the clothing main body 10 is formed in the best shape as a whole. The garment body 10 is configured such that a front body 1 and a back body 2 are connected by a shoulder 3, and a standing collar 4 is provided from an upper part of the front body 1 to an upper part of the back body 2. A fastener 5 for opening and closing is attached to the center of the front body 1. In the garment body 10, the front body 1 and the back body 2 are not sewn from the portion corresponding to the sleeve to the side, and are open.

Two front belts 6 are respectively attached to the left and right sides of the front body 1. The front belt 6 has a length-adjusting buckle 6a, and a D-ring 6b is attached to the tip.
Two rear belts 7 are respectively attached to the left and right sides of the back body 2. The rear belt 7 has a buckle 7a for adjusting the length.
By passing the front end portion of the rear belt 7 through the D-ring 6b of the front belt 6 and connecting the front belt 6 and the rear belt 7, the side portions between the front body 1 and the back body 2 are connected.

  A slit 14 for inserting a harness is provided at the upper center of the back body 2.

  Piping with a piping tape 8 is applied to the periphery of the front body 1, the back body 2, and the standing collar 4 to prevent fraying.

  Above the slit 14 inside the back body 2 is provided a printing unit 9 for displaying the quality of the textile product, the washing method, and the like. By displaying the quality and washing method of the textile product on the printing unit 9, the use of the display tag is abolished.

[Pocket]
The cooling garment includes a garment body 10 and a pocket portion 11 that is provided inside the garment body 10 and accommodates dry ice.
In this specification, when referring to the pocket part generically, reference numeral 11 is attached, when referring to the pocket part of the front body 1, reference numeral 11a is attached, and when referring to the pocket part of the rear body 2, reference numeral 11b is attached. When the pocket portion of the standing collar 4 is pointed out, explanation will be given with reference numeral 11c.

  In this example, four pocket portions 11 a are arranged inside the front body 1, and five pocket portions 11 b and 11 c are arranged inside the back body 2.

Inside the front body 1, two pocket portions 11 a are arranged on the left and right, respectively.
Inside the back body 2, two pocket portions 11 b are arranged on the left and right, respectively, and one pocket portion 11 c is arranged at the inner center of the standing collar 4.

FIG. 4 is a view for explaining the structure of each of the pocket portions 11.
The pocket portion 11 is provided with tacks 12 on the left and right sides of the lower side to make a gusset for containing dry ice.
The pocket portion 11 has a laminated structure in which a plurality of cloths are stacked on the inside portion. In this example, five pieces of cloth having a thickness of 0.49 mm are laminated.

  The pocket portion 11 is provided with a flap 13 that covers the upper opening. The flap 13 has a laminated structure in which a plurality of cloths are stacked. In this example, two cloths are laminated. The flap 13 is fastened to the pocket portion 11 with a snap button 13a.

[Material]
The fiber material which comprises the said cooling clothing consists of a flame-retardant fiber.
That is, the garment body 10 including the front body 1, the back body 2, and the standing collar 4 is composed of flame retardant fibers. The said pocket part 11 is also comprised from the flame-retardant fiber. The fiber material constituting the flap 13 is also made of flame retardant fiber.

  The piping tape 8 is also a flame retardant fiber. The yarn used for stitching each fiber part is preferably a flame retardant fiber.

  As the flame retardant fiber, a material in which a base material mainly composed of cotton is impregnated with a phosphonium compound can be used. A cotton fabric subjected to a flame retardant treatment (for example, the method disclosed in JP-A-8-13345) can be used (for example, trade name “Provan”: Daiwabo Co., Ltd.).

The flame retardant mechanism of the flame retardant fiber subjected to such a flame retardant treatment is as follows. When the flame retardant fiber is exposed to fire, the propane polymer covering the cotton fiber is decomposed, delaying the combustion of the fiber. Propane polymer decomposes to form phosphorus pentoxide, dehydrates cotton fibers and gradually carbonizes. Phosphorus pentoxide becomes polyphosphoric acid and blocks oxygen, making it more difficult to spread. The fiber structure of cotton maintains its shape firmly while carbonizing.
The flame-retardant fiber is self-extinguishing and carbonizes during combustion, so the dough does not melt. Carbonizes the fabric when ignited and prevents it from spreading. During combustion, it does not melt easily due to shrinkage and does not melt. The LOI value is 28 to 32, and high flame retardancy is realized.
(Quoted from Daiwabo PROBAN catalog)

  The tape to which the element (service tooth) of the fastener 5 is attached is also a flame retardant fiber. For example, those using meta-type aramid fibers (including flame retardant) can be used. Specifically, for example, YKK Corporation's flame retardant metal fastener 5RG can be used.

  Parts other than each said fiber raw material are metal. Specifically, the buckles 6a and 7a, the D ring 6b, the snap button 13a, the elements (service teeth) constituting the fastener 5 and the slider are each made of metal.

〔how to use〕
The cooling clothing of this embodiment is worn in a state where dry ice cut into an appropriate size is accommodated in the pocket portion 11. The dry ice accommodated in the pocket part 11 can be, for example, about 60 mm × 24 mm × 120 mm and about 250 g in size.

  Dry ice is accommodated in the pocket portion 11 from the upper opening exposed by turning the flap 13. Thereafter, the flap 13 is fastened to the pocket portion 11 with the snap button 13a. This prevents dry ice from jumping out of the clothes during work, ensuring safety.

  Moreover, since the pocket part 11 has a laminated structure in which a plurality of cloths are stacked on the inner part (in this example, five cloths are stacked), the cold heat of the dry ice contained in the pocket part 11 is directly applied to the human body. The power is moderated moderately. Moreover, since the upper half of the pocket part 11 is covered with the flap 13, the power which the cold of the dry ice accommodated in the pocket part 11 acts directly on a human body is further relieved. Further, by the cold insulation action that covers the pocket portion 11 with the flap 13, the vaporization speed of the dry ice can be delayed, and the dry ice can be prolonged.

  The cold air in which the dry ice is vaporized in the pocket portion 11 does not pass through the cloths stacked in the pocket portion 11 but flows out from the upper opening of the pocket portion 11. At this time, since the upper opening of the pocket portion 11 is covered with the flap 13, the cold air flowing out from the upper opening of the pocket portion 11 changes the direction downward along the flap 13. The cold air flows along the surface of the trunk of the worker who wears the cooling clothes, and can give a cool feeling evenly to the trunk of the worker.

[Summary]
The cooling clothing of this embodiment uses a fiber material as a flame-retardant fiber. Moreover, parts other than said each fiber raw material were made into metal. As a result, even if sparks fly into the cooling garment, the fiber material is prevented from burning and the safety of the operator can be ensured.

  In the cooling clothing of this embodiment, the quality of the textile product, the washing method, and the like are displayed on the printing unit 9, and the use of the display tag is abolished. Further, fraying was prevented by piping with the piping tape 8. This eliminates flammable parts from which thin cloths and threads pop out, improving safety.

[Second Embodiment]
FIGS. 4-6 is 2nd Embodiment which shows the cooling garment for hot-work work to which this invention was applied.

In the second embodiment, the lower half of the garment body 10 is removed and only the upper half is configured. In this example, two pocket portions 11 a are arranged inside the front body 1, and three pocket portions 11 b and 11 c are arranged inside the back body 2.
Inside the front body 1, one pocket portion 11a is disposed on each of the left and right sides. Inside the back body 2, one pocket portion 11 b is disposed on each of the left and right sides, and one pocket portion 11 c is disposed at the inner center of the standing collar 4.

  Other than that, it is the same as that of 1st Embodiment shown in FIGS. 1-4, the same code | symbol was attached | subjected to the same part and description was abbreviate | omitted.

[Effect of each embodiment]
Each of the above embodiments has the following effects.

Each of the above embodiments is worn in a high temperature environment typified by operations such as blast furnaces, electric furnaces, welding / cutting, shipbuilding, glass manufacturing / processing, etc. Even if the flame retardant standards for clothing are met and sparks fly to the cooling clothing, the fiber material is prevented from burning up and the safety of workers can be ensured.
Moreover, since the cold heat of the dry ice accommodated in the pocket part 11 is utilized, there is no additional device or tube for circulating fluid, and workability does not deteriorate. further. Since the pocket portion 11 is provided inside the garment main body 10, the cold heat of the dry ice stored in the pocket portion 11 easily acts on the body without escaping to the outside, and the efficiency of giving a cool feeling to the worker is good. .

  In each of the above embodiments, the pocket portion 11 is provided with a flap 13, and the flap 13 is made of a fiber material made of flame-retardant fiber. For this reason, it complies with the flame retardant standard as clothes to be worn under the various high temperature environments described above, and the safety of the operator can be ensured. Even if it is the inside of the clothes, the flaps are provided by jumping out of the clothes and are structurally flammable.

  In each of the embodiments described above, the flame retardant fiber is obtained by impregnating a base material mainly made of cotton with a phosphonium compound. For this reason, when a flame-retardant fiber touches a fire, the flame retardance by the impregnated phosphonium compound is exhibited, and a worker's safety can be ensured. Further, since the base material is mainly made of cotton, it exhibits hygroscopicity and absorbs sweat from the worker in a high temperature environment. Troubles such as icing with dry ice and damaging the skin while sweat is not absorbed can be prevented.

  In each of the above-described embodiments, the pocket portion 11 has a laminated structure in which a plurality of cloths are stacked on the inside portion. For this reason, at least a plurality of cloths exist between the dry ice accommodated in the pocket portion 11 and the human body wearing the cooling clothes. Therefore, it is possible to moderate the power of the dry ice acting on the human body moderately, prevent the occurrence of frostbite, and ensure safety. Dry ice can be easily loaded because dry ice can be accommodated in the pocket as it is.

[Modification]
The above has described a particularly preferred embodiment of the present invention. However, the present invention is not intended to be limited to the illustrated embodiment, and can be implemented by being modified in various aspects, and the present invention includes various modifications. This is the purpose.

  For example, as a flame retardant fiber, a base material mainly made of cotton and impregnated with a phosphonium compound (trade name “Provan”: Daiwa Boseki Co., Ltd.) is used, but the present invention is not limited to this. Incombustible fiber can be used. For example, those based on meta-aramid fibers (trade name “Conex”: Teijin Limited: LOI value 27 to 29), those based on modacrylic fibers (trade name “Kanekalon”: Kaneka Corporation: LOI value 27 to 38), non- Those made of halogen-added polyester fibers (trade name “Anfra”: Toray Industries, Inc .: LOI value 28) can be used.

In addition, it is possible to attach a reflector for ensuring safety at night or in a dark place.

1: Front body 2: Back body 3: Shoulder part 4: Stand collar 5: Fastener 6: Front belt 6a: Buckle 6b: D ring 7: Rear belt 7a: Buckle 8: Piping tape 9: Printing part 10: Garment body 11 : Pocket part 11a: Pocket part (front body)
11b: Pocket part (back body)
11c: Pocket (standing collar)
12: Tack 13: Flap 13a: Snap button 14: Slit

Claims (4)

The cooling garment includes a garment main body and a pocket portion that is provided inside the garment main body and accommodates dry ice,
A cooling garment for hot work, wherein the fiber material constituting the cooling garment is made of flame-retardant fiber. The pocket part is provided with a flap,
The cooling garment for hot work according to claim 1, wherein the flap is made of a fiber material made of flame-retardant fiber. The cooling garment for hot work according to claim 1 or 2, wherein the flame retardant fiber is a base material mainly made of cotton impregnated with a phosphonium compound. The hot clothes for working in a hot place according to any one of claims 1 to 3, wherein the pocket portion has a laminated structure in which a plurality of cloths are stacked on a portion located on the inside.

Images