KR101818333B1 - A heatproof clothing for firefighting - Google Patents

Abstract

The present invention relates to a fire extinguisher, and is intended to safeguard disaster prevention personnel and the like by a cool air circulation in the event of an emergency disaster such as a fire or an earthquake.
In order to achieve the above object, the present invention provides a heat-dissipating apparatus, comprising: a body of heat dissipating apparatus which is formed of a dual structure of an outer shell and an inner shell to form a tubular enclosed space capable of expanding or contracting in volume through gas supply between the shells of the double structure; The compressed gas to be supplied through the gas introduction pipe dispersed in each part of the closed space is filled in the gas capsule so as to be interrupted by the control valve and the control valve is opened and closed by the lever operation by the user or the valve opening / A gas supply part for discharging or shutting off the gas into the tubular enclosed space through the gas introduction pipe, and at least one temperature sensor installed on the inner surface of the heat radiation device main body to detect the temperature of the user's body, A valve opening / closing signal for opening / And a capsule control unit for controlling the operation of the supply unit so as to provide a fire extinguishing unit for a fire extinguisher. When an emergency disaster such as a fire or an earthquake occurs, Provides cold air supply and circulation to safeguard disaster emergency personnel from external thermal shocks.

Description

{A heatproof clothing for firefighting}

The present invention relates to a fire extinguisher, and more particularly, to a fire extinguisher which is capable of being quickly worn by a fire fighter, a paramedic, or a general public performing fire suppression or lifesaving in the event of an emergency such as a fire or an earthquake, The present invention relates to a fire extinguisher which can safely protect persons from external thermal shocks by supplying and circulating cool air into the heat radiator.

Generally, in the event of a disaster such as a fire or an earthquake, firefighters or paramedics who are engaged in special tasks such as suppressing a fire or rescuing people in a high temperature flame, or workers working in the furnace of a steel plant, When an accident occurs, most of the time, you are in danger of being exposed to the danger of death. Therefore, you should always wear a heat shield that protects your body from hot flames and can block high heat radiation.

FIG. 1 is a view showing a conventional general heat dissipating apparatus. The heat dissipating apparatus 1 includes a heat dissipating apparatus 1, a heat dissipating apparatus 2, a heat dissipating glove 3, a heat dissipating hood 4, and a heat dissipating apparatus 5.

Such a heat-insulating clothing may be worn to protect the body or to block radiant heat at a fire-fighting or lifesaving fire in the field of fire, but since the fire-fighting or rescue should be free after the wear, By weight.

However, in the case of the above-mentioned conventional heat radiation clothes, the covering is manufactured by stacking the most basic essential materials required for body protection and heat dissipation, and thus has an excessive weight of about 22 to 25 kg as a total weight. Or life-saving work.

In addition, in the case of the above-mentioned conventional heat-radiating apparatus, since each component is separated into individual structures, individual wearing is required according to a predetermined order when worn, so that the wearing time is disadvantageously increased.

In this connection, Korean Patent Registration No. 10-0860380 (Registered on Sep. 19, 2008, hereinafter abbreviated as "Patent Document 1") has a lightweight structure capable of achieving an overall weight reduction by forming an integral structure not only up and down, A technique relating to a high-temperature thermal insulating sheath is known.

According to Patent Document 1, in a heat releasing device comprising a laminate coating for protecting a body from an external flame, the heat releasing device comprises an image portion provided with a front jacquard on the front surface thereof so as to be easily worn, And the lower part of the lower part of the lower part of the lower part of the lower part of the lower part of the main body, .

In addition, Korean Patent No. 10-0899991 (Registered on May 22, 2009, hereinafter abbreviated as "Patent Document 2") discloses a method for reducing the weight and activity of a high-temperature thermal insulating clothing worn by a fire- And a method for manufacturing a high-temperature heat-insulating cloth layer laminate structure and an integrated high-heat heat-radiation cover fabricated using the same.

According to Patent Document 2, there are provided a high heat-shielding fiber weaving fabric, a first carbon felt fabric for dispersing heat that has passed through a high heat-shielding fiber weaving fabric, an aluminum evaporation fabric for shielding heat dispersed from the first carbon felt fabric, A second carbon felt fabric for dispersing heat therethrough, an aluminum evaporation heat resistant fabric for intercepting / dispersing heat dispersed in the second carbon felt fabric, an aramid felt fabric for dispersing heat through the aluminum evaporation heat resistant fabric, And the thermally dispersing process after the heat shielding step is repeated in three stages, thereby making it possible to more effectively block the high-temperature heat transmitted from the outside by forming the integral high-temperature heat insulating clothes with the laminated structure , It is possible to prevent deformation of the material due to high-temperature radiant heat and to improve the durability of the heat-insulating clothes.

However, in the case of the former type of heat dissipation apparatus as described above, it is easy to be worn with the integral structure in the case of the electrons, but there is a limit to protect the body from the high temperature flame. In the latter case, It is difficult to provide effective heat dissipation because it is heat-dissipating, and it can not supply cold air to the inside, so there is a limit to lowering the temperature when exposed to a high temperature flame or internal air once, so that the disaster emergency personnel can not be safely protected from external thermal shock There was a possibility that a problem would occur.

KR 10-0860380 B1 2008.09.19 Registration KR 10-0899991 B1 Registered on May 22, 2009

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a fire-fighting apparatus for a fire-fighter, a paramedic, And it is possible to circulate the inflated space while inflating the inner space of the heat insulating case when there is a risk of exposure or exposure to a high temperature flame, thereby protecting the human life safely from external thermal shocks .

Another technical problem to be solved by the present invention is that the inner skin can be detached from the outer skin so that the outer skin of the inner skin can be easily separated from the inner skin of the heat-insulating work clothes or other special clothes worn by users working in a job group, The present invention is intended to provide a fire extinguisher which can be selectively and conveniently used by users working in a high-risk occupation group.

In order to accomplish the above object, an embodiment of the present invention is characterized in that a door is formed in a closed form so as to cover the entire body of a user and an opening which is opened and closed by a zipper so that a user can wear and take off A heat dissipation unit main body which is composed of an inner skin which is integrally cut by a two-layer coating so as to cover the inner skin and an outer skin which entirely surrounds the inner skin to form a tubular sealed space capable of expanding or contracting in volume through gas supply between the two- And is filled in the gas capsule so that the compressed gas to be supplied through the gas introduction pipe dispersedly disposed in each part of the tube-shaped closed space of the heat-radiating body is interrupted by the control valve, and the lever operation by the user or the valve opening / The control valve is opened and closed by the signal, And at least one temperature sensor provided on an inner surface of the body of the heat-radiating body to detect a temperature of the user's body and to measure the temperature of the gas capsule on the basis of one or more predetermined temperature values t1 and t2. And a capsule control unit for outputting a valve opening / closing signal for opening / closing the control valve and controlling the operation of the gas supply unit.

The thermal insulating cover for a fire extinguisher according to an embodiment of the present invention is provided with a pressure sensor for detecting the internal pressure of the tubular enclosed space installed at one side of the heat radiation casing body so that the measured pressure value of the pressure sensor is set to a predetermined first pressure value p1, Type airtight space and forcibly discharging the compressed gas supplied to the inside of the tubular closed space and stopping below a predetermined second pressure value p2 to block the forced exhaust of the compressed gas supplied into the tubular closed space, As shown in FIG.

The fire extinguisher according to the present invention as described above has the following advantages. Firstly, it can be quickly worn when an urgent situation occurs, so that it can cope with an emergency quickly, and firefighters or lifesaving agents It is possible to safely protect firefighters and disaster prevention personnel from thermal shocks by inflating the main body of the heat-radiating apparatus so as to supply cold air and circulate it.

Fig. 1 is a view showing an example of a conventional fire extinguisher for general use.
2 is a cross-sectional view illustrating a configuration of a fire extinguisher for fire fighting according to an embodiment of the present invention.
3 is a perspective view showing the state of use of the fire extinguisher for firefighting according to the embodiment of the present invention.
4 is a block diagram illustrating a configuration of a control circuit mounted for controlling the operation of a gas supply unit in a heat insulating packaging for fire according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the structure and operation of a fire extinguisher for fire fighting according to the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the words or words used in the present specification and claims are not to be construed in a conventional or dictionary sense and that the inventor can properly define the concept of a term in order to describe its invention in the best possible way And should be construed in light of the meanings and concepts consistent with the technical idea of the present invention. Therefore, it should be understood that the embodiments described herein and the configurations shown in the drawings are only the most preferred embodiments of the present invention, and that various equivalents and modifications may be substituted for them at the time of the present application shall.

FIG. 2 is a cross-sectional view illustrating a configuration of a fire extinguisher for fire fighting according to an embodiment of the present invention, FIG. 3 is a perspective view of a fire extinguisher for fire fighting according to an embodiment of the present invention, FIG. 2 is a block diagram illustrating a configuration of a control circuit mounted for controlling the operation of a gas supply unit in a fire extinguishing heat radiation suit according to an embodiment of the present invention. The heat radiation suit for a fire extinguishing unit according to an embodiment of the present invention includes a heat radiation body 10, a gas supply unit 20, (30), and the present invention having such a structure may further comprise an exhaust valve (40), and may be configured in another embodiment.

As shown in Figs. 2 and 3, the heat-radiating body 10 includes an inner skin 10b that is integrally cut by a two-layer coating so as to form a closed space therein, and a skin 10a that encloses the inner skin as a whole The inner and outer skins 10b and 10a are formed so as to cover the user's body as a whole and are separated from each other by separate sheaths. (11) which is opened and closed by a zipper so that a user can wear and take off from the tubular hermetic space (10a) and a tubular hermetically sealed space (11b) capable of expanding or contracting in volume through gas supply is provided between the two- 10c. At this time, the entrance 11 is formed separately on the inner and outer shells 10b and 10a, so that the fire-fighting or lifesaving agent (or the fire-fighting agent) It is preferable to form a zipper which is formed to extend from the inside of the arm of the one side portion to the waist and the thigh portion along the side line and is heat-treated and flame-proofed so as to prevent inflow of a high temperature flame into the inside of the heat- . In addition, the inner skin 10b configured as described above is formed as a separate body from the outer skin 10a so that it can be separated from the outer skin 10a and incorporated in another special outerwear if necessary.

The inner skin 10b and the outer skin 10a constituting the heat-radiating body 10 are formed at corresponding positions of at least one joint part selected from the shoulders, elbows, cuffs, hips, knees and ankles And folded portions 12 made of warp or wrinkle or bendable material, respectively, so that the limbs can freely move. This is because when the gas is tightly supplied to the inside of the tubular closed space 10c, for example, the arms and legs can not move freely due to the pressure of the gas, ) Are provided at each joint, thereby enabling free movement during fire suppression or lifesaving work.

The inner skin 10b and the outer skin 10a constituting the heat-radiating body 10 according to the present invention have a front portion at the point where the head and the body portion are connected to each other and a head portion and a hand and foot portion at each of the wrist and ankle And cut-out portions 13a-13c which are separately opened and closed by a zipper so as to be detached and sewn separately. When the cutouts 13a to 13c are formed, the remaining parts except for the head, the hands and the feet are worn first, and then the head, the hands and the feet are finally worn. It is possible to easily worn the clothes, and the actions such as conversation, walking and gripping are more natural than when the heat-radiating body 10 including the head, the hand and the foot is fully worn, Will be able to perform.

The inner skin 10b and the outer skin 10a constituting the heat-radiating body 10 according to the present invention are basically constructed such that a sight window 14 for securing visibility of firefighters and disaster prevention personnel and a ventilation opening 15 for respiration . In the case of such a sight window 14, it is preferable to use a transparent plastic that is specially reinforced so as not to be damaged by an external impact. In the case of the ventilation opening 15, one or more ventilation holes are formed . In particular, in the case of the ventilation opening 15, when a situation requiring the wearing of the oxygen breathing apparatus occurs at the fire suppression site, the oxygen breathing apparatus may be connected to smoothly perform the oxygen supply. Although not illustrated in the present invention, May be integrally provided in the heat-radiating body 10.

The tubular closed space 10c formed in the inner skin 10b of the body 10 is formed into a plurality of individual spaces separated into one or more regions by a plurality of separation membranes 10d as illustrated in FIG. . In this case, each of the gas supply pipes 23 distributed in the respective portions of the tubular closed space 10c is also connected to the respective individual spaces via one or more control valves 21a, It is natural that it should be arranged.

The inner skin 10b constituting the heat-radiating body 10 may further include a waist belt 50 for supporting the gas capsule 21 and the capsule control unit 30 on the waist.

The gas supply unit 20 includes a gas capsule 21, an operation lever 22 and at least one gas introduction pipe 23. The gas supply unit 20 includes a tubular sealed space 10c of the inner skin 10b constituting the heat- The compressed gas to be supplied through the gas introduction pipe 23 dispersedly disposed in each portion of the capsule shell 21 is filled in the gas capsule 21 so as to be interrupted by the control valve 21a and is supplied with a lever operation by the user or a valve opening / The control valve 21a is opened and closed to discharge or cut the compressed gas into the tubular closed space 10c through the gas introduction pipe 23. [ As shown in FIG. 2, the gas supply units 20 may be provided on both sides of the inner surface 10b of the body 10, and one or more gas supply units 20 may be selectively provided.

The gas capsule 21 is filled in the main body of the capsule so that the compressed cold gas to be supplied to the tubular sealed space 10c is interrupted by the control valve 21a and the lever operation by the user or the valve The control valve 21a is opened by the open signal to release the compressed gas into the tubular closed space 10c and the control valve 21a is closed by the valve closing signal by the capsule control unit 30 to open the tubular closed space 10c, Thereby preventing the gas from being discharged. The gas capsule 21 is preferably a gas capsule which is filled with cold gas which expands the volume of the tubular enclosed space 10c and cools the temperature. In particular, it is preferable that the cold gas compressed and filled in the gas capsule 21 is filled with a gas which is harmless to the human body and has no danger of explosion when a fire occurs.

The operation lever 22 is fixed at one end to the control valve 21a of the gas capsule 21 and at the other end is configured to constitute the heat radiation body 10 so that the user can manually pull the control valve 21a to open the control valve 21a The outer surface of the outer casing 10a.

The at least one gas introduction pipe 23 is made of a flexible flexible pipe capable of bending or bending or bending, And is dispersedly disposed in each portion of the tubular closed space 10c so that gas can be supplied to each portion. Particularly, the gas introducing pipe 23 is connected at its one end to the rear end of the control valve 21a of the gas capsule 21 to form a flow path so as to receive the cool gas released at the time of opening the control valve, The refrigerant gas branched and opened at least at one or more places in the closed space 10c to distribute the refrigerant gas supplied from the gas capsule 21 to the respective portions of the tubular closed space 10c to expand the volume of the tubular closed space evenly .

The capsule control unit 30 includes at least one temperature sensor 31a-31m as illustrated in Figs. 2 to 4. The at least one temperature sensor 31a-31m installed at the inner surface 10b of the heat- -31m) and outputs a valve opening / closing signal for opening / closing the control valve 21a of the gas capsule 21 based on at least one predetermined temperature value t1 (t2) 20). One or more of these temperature values (t2, t2) may be determined by a firefighter or lifesaving agent (or a firefighting agent) or an ordinary user when the temperature is lowered by exposure to a hot flame or by a supplied cold gas The first temperature value t1 is a predetermined temperature reference value for the supply of the coolant gas upon exposure to the high temperature flame and the second temperature value t2 is a temperature value preset for the protection of the body of the general user, This value is set in advance at the time of designing, or may be designated by the program manager at the time of programming of the capsule control unit 30 as necessary It is possible.

The at least one temperature sensor 31a-31m is dispersed and installed at each position of the tubular closed space 10c so as to be in contact with the inner skin 10b of the heat-radiator body 10 as shown in Fig. 2, The temperature is measured at one or more parts of the body near the endothelium 10b. At this time, the respective temperature sensors 31a to 31m may be dispersed in the head portion, the front portion of the body portion, and the arms and leg portions of the left and right sides, respectively, as illustrated in FIG.

Based on this configuration, the capsule control unit 30 senses the user's body temperature as a temperature measurement value detected by each of the temperature sensors 31a to 31m, and when the temperature measurement value is equal to or higher than a predetermined first temperature value t1 ), A valve opening signal for opening the valve of the gas capsule 21 to supply cold air is output, and when the temperature measurement value is equal to or lower than a predetermined second temperature value t2 (equal to or lower than t2 The control logic can be configured to output a valve closing signal for closing the valve of the gas capsule 21 to shut off the cold air supply.

On the other hand, the capsule control unit 30 can be programmed to separately control one or more control valves 21a so as to preferentially supply compressed gas through the gas introduction pipe 23 at a predetermined position. In this case, the tubular closed space 10c of the heat-radiator body 10 should be formed as a plurality of individual spaces each separated into one or more regions by a plurality of the separation membranes 10d as illustrated in Fig. 2, Each of the gas introduction pipes 23 of the gas supply part 20 dispersedly disposed in each part of each of the first to the fourth control valves 10a, 10b and 10c is also branched separately in each individual space via one or more control valves 21a.

The gas capsule 21 and the capsule control unit 30 may be fixed and supported by a waist belt 50 provided at the waist of the inner skin 10b of the heat- Particularly, the capsule control unit 30 is provided with a plurality of temperature sensors 31a-31m and control valves 21a-31m via at least one flexible connector (not shown in the figure, but a normal flexible connector can be used) And the exhaust valve 40 and the like. Therefore, the capsule control unit 30 can be attached to the outer side of the inner skin 10b or can be installed to be exposed to the outside of the outer skin 10a. When the capsule control unit 30 is installed to be exposed to the outside of the outer skin 10a, A flexible connector that penetrates the sheath of the sheath should be provided so as to be energized or separated from the electric elements provided on the inner sheath through the flexible connector.

The heat radiation body 10 of this structure can separate the inner skin 10b from the outer skin 10a simply as needed and in this case the capsule control portion 30 can also be easily separated by the flexible connector. In this case, the capsule control unit 30 is provided with a plurality of temperature sensors 31a-31c attached to the inner skin 10b through a flexible connector, and the inner skin 10b separated from the outer skin 10a can be used in a separate special- 31m, the control valve 21a, the exhaust valve 40, and the like.

The exhaust valve 40 is provided on the inner surface 10b of the heat-radiating body 10 as illustrated in Figs. 2 and 3 and includes a pressure sensor for sensing the inner pressure of the tubular sealed space 10c of the inner surface 10b Built in. This exhaust valve 40 operates when the measured pressure value of the pressure sensor becomes equal to or higher than a predetermined first pressure value p1 (equal to or higher than p1) to thereby supply the compressed gas supplied into the tubular closed space 10c When the measured pressure value of the pressure sensor becomes equal to or less than a predetermined second pressure value p2 (equal to or lower than p2), the operation is stopped and the compression applied to the inside of the tubular closed space 10c It blocks the forced exhaust of gas. Since the automatic forced exhaust and stop operation of the exhaust valve 40 enables automatic supply and circulation of cool air for inflating and expanding the heat radiation body in the tubular closed space 10c to be automatically performed, If exposed to high temperature flames or high temperature in the area where earthquakes occur, it will be possible to safely protect firefighters and disaster prevention personnel from thermal shocks.

The overall operation of the fire extinguisher for fire fighting according to the present invention having such a constitution and the action and effect of the fire extinguisher will be described.

When an emergency occurs in a fire or disaster occurrence place, the zipper of the entrance 11 and each of the cutouts 13a-13c of the main body 10 is opened to open the exit 11 and the cutout 13a- 13c so as to protect the respective parts by wearing the trunk, the legs and the arms in order and then wearing the body and finally the head, the hands and the feet, Close it again.

The control valve 21a of the gas supply unit 20 is opened and the control valve 21a and the gas introduction pipe 23 are opened at the side of the gas capsule 21, And the entire body of the heat-radiating body 10 is cooled and swollen by the cool gas to protect the fire-fighting tube and the disaster prevention personnel from the high temperature.

When the temperature of the inside of the heat-radiating apparatus body is increased due to the exposure of the fire-fighting apparatus and the disaster prevention personnel wearing the heat-insulating apparatus main body in such a state by the high-temperature flame or the like, one or more temperature sensors 31a to 31m are inside the tubular enclosed space 10c And the capsule control unit 30 detects the temperature of the user's body by the temperature measurement values detected by the respective temperature sensors 31a to 31m And outputs a valve opening signal for opening the control valve 21a of the gas capsule 21 when a temperature measurement value equal to or higher than a preset first temperature value t1 is sensed to output a valve opening signal for opening the gas capsule 21 The refrigerant gas can be supplied to the respective portions of the tubular closed space 10c of the heat-radiator body 10 through the control valve 21a and the gas introduction pipe 23. [ In this state, the capsule control unit 30 senses the user's body temperature as a temperature measurement value detected by each of the temperature sensors 31a-31m, and detects a temperature measurement value equal to or lower than a predetermined second temperature value t2 The control valve 21a is closed by outputting a valve closing signal for closing the valve of the gas capsule 21 so that no more cold gas is supplied.

When the internal pressure of the tubular closed space 10c gradually increases due to the supply of the cool gas and the internal pressure becomes higher than the predetermined first pressure value p1, The exhaust valve is automatically operated so that the compressed refrigerant gas supplied to the inside of the tubular closed space 10c is forcedly exhausted. When the measured pressure value of the pressure sensor is lower than a predetermined second pressure value p2 by the forced exhaust, the operation is stopped and the forced exhaust of the compressed gas supplied into the tubular closed space 10c is blocked.

Since the automatic forced exhaust and stop operation of the exhaust valve 40 as described above enables the cool air supply and circulation for inflating and expanding the main body of the heat radiation casing to be automatically performed inside the tubular closed space 10c, Firefighters and firefighters can be safely protected from thermal shocks when exposed to high temperature flames or high temperatures in a fire or earthquake area.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Modification is possible. Accordingly, it is intended that the scope of the invention be defined solely by the claims appended hereto, and that all equivalent or equivalent variations thereof fall within the scope of the present invention.

10: heat-radiating body 10a: sheath
10b: inner skin 10c: tubular sealed space
10d: separator 11: entrance
12: Bond section 13a-13c:
14: viewing window 15: ventilation opening
20: gas supply part 21: gas capsule
21a: Control valve 22: Operation lever
23: gas introduction pipe 30: capsule control unit
31a-31m: Temperature sensor 40: Exhaust valve
50: Waist belt

Claims (12)

And is provided with an entrance 11 which is opened and closed by a zipper so that a user can wear and take off the user's body on one side and is integrally formed by a double layer coating so as to form a closed space therein A tubular enclosed space 10c capable of expanding or contracting in volume through the supply of gas is formed between the two layers of the inner skin 10b of the inner skin 10b and an outer skin 10a covering the inner skin 10b as a whole (10);
The compressed gas to be supplied through the gas introduction pipe 23 which is provided on one side of the heat-radiating body 10 and is dispersedly disposed in each part of the tube-shaped closed space 10c of the heat-radiating body 10 is supplied to the control valve 21a The control valve 21a is opened or closed by a lever operation by a user or a valve opening / closing signal of the capsule control unit so that the compressed gas is supplied to the tubular closed space (not shown) through the gas introduction pipe 23 A gas supply part 20 for discharging or shutting off the gas to be supplied to the gas supply part 10c;
One or more temperature sensors 31a-31m provided on the inner skin 10b of the heat-radiating body 10 detect ambient temperature of the user's body and determine the temperature of the gas capsule < RTI ID = 0.0 > A capsule control unit 30 for outputting a valve opening / closing signal for opening / closing the control valve 21a of the control unit 21 to control the operation of the gas supply unit 20; And
And a pressure sensor for detecting the internal pressure of the tubular sealed space is installed so that the measured pressure value of the pressure sensor is operated at a predetermined first pressure value p1 or more, And an exhaust valve (40) for forcibly exhausting the compressed gas supplied to the tubular hermetically sealed space and stopping the forced evacuation of the compressed gas supplied to the inside of the tubular hermetically sealed space at a temperature lower than a predetermined second pressure value (p2) Wherein the heat radiating member is made of a thermoplastic resin. delete 2. The fuel cell system according to claim 1, wherein the gas supply unit (20)
The compressed gas to be supplied to the tubular closed space 10c is filled inside so as to be interrupted by the control valve 21a and the control valve 21a is opened by the lever operation by the user or the valve opening signal by the capsule control part 30 And the control valve 21a is closed by a valve closing signal from the capsule control unit 30 to shut off the gas discharge into the tubular closed space 10c, (21);
One end portion of the gas capsule 21 is fixed to the control valve 21a and the other end portion of the gas capsule 21 is connected to the control lever 21a, (22); And
The gas-tight space 10c of the heat-radiating body 10 is dispersed in each part of the tubular closed space 10c so that gas can be supplied to each part of the tubular enclosed space 10c and one end thereof is connected to the gas capsule 21, And the other side end portion is branched and opened at least at one or more positions in the tubular closed space 10c to introduce at least one gas for dispersing and supplying the gas supplied from the gas capsule 21 to each portion of the tubular closed space 10c And a pipe (23). The capsule endoscope according to claim 1, wherein the capsule control unit (30)
One of which is disposed at each position of the tubular closed space 10c so as to be in contact with the inner surface 10b of the heat-radiating body 10 to measure at least one body ambient temperature near the inner surface 10b of the heat- Temperature sensors 31a-31m,
A valve opening signal for opening the valve of the gas capsule 21 at a temperature equal to or higher than a predetermined first temperature value t1 by sensing a temperature around the user's body as a temperature measurement value detected by the temperature sensors 31a to 31m, And outputs a valve closing signal for closing the valve of the gas capsule (21) at a temperature lower than a predetermined second temperature value (t2). The electronic apparatus according to claim 1, wherein the heat-radiator body (10)
The outer skin 10a and the inner skin 10b located at least one joint part selected from the shoulders, elbows, wrists, the hip joints, the knees and the ankles are composed of a soft folded portion 12 that can bend or bend or bend Features a fire extinguisher. The gas sensor according to claim 3, wherein the gas capsule (21)
And a coolant gas filled in the tube-shaped hermetically sealed space to expand the volume and cool the temperature. The gas supply system according to claim 3, wherein the gas introduction pipe (23)
Wherein the flexible pipe is made of flexible flexible pipe capable of bending, bending or bending. The method according to claim 1,
The tubular enclosed space 10c of the heat-radiator body 10 is formed of a plurality of individual spaces each separated into one or more regions by a plurality of separating films 10d,
The gas supply unit 20 is configured such that each of the gas introduction pipes 23 dispersedly disposed in each part of the tubular closed space 10c is branched and disposed independently of each individual space through one or more control valves 21a ,
Characterized in that the capsule control unit (30) separately controls one or more control valves (21a) so as to preferentially supply the compressed gas selectively through the gas introduction pipe (23) at a predetermined position. The electronic apparatus according to claim 1, wherein the heat-radiator body (10)
And the outer cover is composed of an inner skin and an outer skin of a heat-treated and flame-resistant material. The electronic apparatus according to claim 1, wherein the heat-radiator body (10)
13a-13c, 13a-13c, 13a-13c, 13a-13c, 13a-13c which are opened and closed by a zipper so that the head, the hand, and the foot are separately separated from each other by the front part, the wrist point and the ankle point of the point where the head and the body part are connected, ) Are formed on the inner surface of the case. delete delete

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