KR200446628Y1 - Air-Injected Radiation Protective Clothing - Google Patents

Abstract

The present invention relates to an air-injection-type radiation protective clothing, the body covering the body, legs and arms, the body cover having an open neck, at least one through the body outlet, formed integrally with the hand portion of the body cover Gloves formed in the form of the hand is inserted, integrally formed on the foot portion of the body cover, foot cover formed in the form of the foot is inserted, connected to one side of the body cover, the air injection air A hood covering the upper body portion from the upper part of the tube, the body covering, the head covering, the hood covering having a hood outlet perforated at least one, a face window disposed in front of the hood covering, the face window formed of a transparent material, the hood It is disposed inside of the mask body surrounding the breathing nose and mouth, connected to one side of the mask body And a suction pipe communicating with the inside of the hood covering to supply air to the inside of the mask body, and connected to the other side of the mask body, and communicating with the hood covering with the outside to breathe inside the mask body. It includes a discharge pipe for discharging the air generated by the.

Air injection, radiation, radiation contaminants, protective clothing, mask part, hood

Description

Air Injection Type Radiation Protection Cloth

The present invention relates to an air injection type radiation protective suit.

In general, exposure to radiation such as neutrons, beta (β) rays, and gamma (γ) rays generated during operation of a nuclear power plant or radioisotope can cause serious damage to the human body and threaten life, such as cancer and genetic diseases. It is well known that it can cause illness.

Workers working at nuclear power plants or radioisotopes are more likely to be exposed to radiation. In particular, maintenance and operation checks should be carried out in areas where workers are likely to be exposed in the presence of radiation exposure to the outside due to breakdowns in the operation checks or the facilities themselves.

At this time, the worker is carrying out the operation check and maintenance of the nuclear power plant while wearing protective clothing so as to prevent skin contamination or exposure to the body.

Conventional protective clothing for preventing skin contamination or exposure to the body by radioactive materials have been used separately from the mask and the cover provided with a face window which is supplied with air to breathe on the operator's face, and the visibility can be secured. .

However, in the general protective clothing, the working time is determined according to the remaining amount of air supplied to the mask, so that the working time is short, and the face window is blurred due to respiration, which makes it difficult to secure a visual field.

Accordingly, recently, the protective clothing according to the prior art is continuously injecting air into the interior using a polyvinyl chloride (PVC) material which is a sealed material that prevents air from leaking to the outside while the external radioactive material is blocked. And air-injected protective clothing that is circulated as the injected air is discharged.

Prior art air-injected protective clothing increases working time as the air is continuously supplied, ensures visibility, and improves the ability of the injected air to shield radiation.

However, the air-injected protective clothing of the prior art has a problem that the air inside the protective clothing is exhausted when the air injection is stopped, there is a lack of air, the shortage of air caused by the lack of air.

In addition, the air-injected protective clothing of the prior art is formed of a polyvinyl chloride material, there is a problem that harmful substances such as dioxins are generated during incineration treatment by collecting in a contaminated state with a radioactive material.

In addition, the air-injected protective clothing of the prior art has a problem that the worker is difficult to work because the worker is performing the work with the air injected therein, the air is filled in the joints such as the elbow or the knee and the movement is unnatural due to the difficulty of bending. There was this.

The problem to be solved by the present invention is to stop the discharge of air to the outside when the injection of air is stopped by using a material that does not generate carcinogens such as dioxin during incineration, the oxygen generating device is activated to oxygen By supplying, it is possible to safely cope with air blocking, so that the operator can work in the radiation zone, to provide an air-injected radiation protective suit with improved stability.

Air-injected radiation protective suit according to an embodiment of the present invention is wrapped around the body, legs and arms, the neck portion is open, the body covering having a body outlet through at least one, is installed on the open side of the body covering The body opening is opened and closed so that the body can be worn and worn, disposed on the elbow and knee portion of the body covering, the joint wrinkles that can be folded in a pleated form, integrally with the hand portion of the body covering It is formed, the glove formed in the form of the hand is inserted, integrally formed on the foot portion of the body covering, the foot cover formed in the form that the foot is inserted, disposed in the lower portion of the foot cover, preventing slipping It can be a non-slip body, connected to one side of the body covering, the air injection tube is injected air, the body A hood covering covering the upper body portion from the top of the coating, the head covering being able to cover the head, the hood outlet having at least one perforated hood outlet disposed on the front surface of the hood covering, and a face window formed of a transparent material, on one side of the hood covering A hood opening that is partially opened and closed to block and close the inside and the outside of the hood coating, a mask body disposed inside the hood and surrounding a breathing nose and mouth, and one side of the mask body A suction pipe connected to the inside of the hood cover and supplying air to the inside of the mask body, and connected to the other side of the mask body, and connected to the hood cover and the outside to the inside of the mask body. A discharge pipe for discharging the air generated by the breathing, the air injected into the air injection pipe Is supplied to the inside of the covering hood and the suction through the suction tube into the nose and mouth, located in the interior of the mask body, the exhalation caused by breathing is discharged to the outside of the hood covering through the discharge pipe.

In addition, the body covering and the hood covering is disposed on the inner surface and the outer surface of the endothelial made of a polyvinyl alcohol (PVA) transparent film material, and the embossed polyvinyl alcohol (PVA) nonwoven material It may comprise a skin made of.

And, it is inserted into one side of the body cover, the injection valve which is connected to the air inlet pipe to adjust the amount of air injected, is inserted into the body outlet, it is possible to adjust the amount of air discharged from the body cover And a hood discharge valve inserted into the body discharge valve and the hood discharge port, and configured to adjust an amount of air discharged from the hood covering, and the air injected while the supply amount is controlled by the injection valve is the body discharge valve. And the discharge from the hood discharge valve may be discharged to the outside.

In addition, the suction pipe is connected to the suction pipe, the supply amount of the air supplied into the mask body is controlled to prevent the backflow, and is connected to the discharge pipe, the air discharged by breathing in the inside of the mask body The discharge valve may include a discharge valve to prevent backflow, and the air sucked into the intake valve may be sucked while preventing the reverse flow into the nose and mouth located inside the mask body, and the nose and nose by breathing. The air discharged from the mouth may be discharged to the outside while preventing the backflow to the discharge valve.

In addition, the housing is disposed in the interior of the body, has a suction port for air is sucked on one side, has an oxygen generating space on the inside, the other side has a housing for discharging the oxygen generated in the oxygen generating space, the housing An oxygen generator which is disposed inside of the air inlet and reacts with the air sucked from the suction port, and is disposed on one side of the suction port, and sucks air to the oxygen generator side through the suction port; It is disposed on one side of the outlet, it may further include a discharge fan for supplying the oxygen generated in the oxygen generator to the inside of the body coating through the outlet.

According to an embodiment of the present invention, one side of the coating in which the air is injected is formed with a discharge port for discharging the injected air, the discharge port is provided with a discharge valve for controlling the discharge of the air discharged, By blocking the discharge of air in the air to be evacuated while exhausting the air inside, there is an advantage to improve the safety.

In addition, the coating is formed of triple layers of polyvinyl alcohol (PVA) transparent film and non-woven fabric, in which air contaminants are blocked while radioactive pollutants are blocked from the skin, thereby preventing swelling even at a thin thickness. The generation of pollutants at the time is suppressed has the advantage of minimizing environmental pollution.

In addition, the mask installed on the surface where the worker breathes when the cloth is worn is provided with an intake pipe that is injected with air to prevent backflow and an outlet pipe that prevents backflow while discharging air to the outside. During exhalation, the air is discharged to the outside after breathing, so that a visual field is secured and only clean air remains inside.

In addition, an oxygen generating device is installed inside the coating to react with carbon dioxide contained in the air to generate oxygen. Even long time external activities are possible, there is an advantage that the safety is improved.

In addition, as the coating is continuously filled with the supplied air, the user can use the filled air for breathing to enable smooth breathing, and an air layer is formed to protect the user from external shock, thereby improving safety. .

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. Like parts are designated by like reference numerals throughout the specification.

Then the air-injected radiation protective suit according to an embodiment of the present invention looks at with reference to FIGS.

1 is a perspective view showing an air-injected radiation protective suit according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the air-injected radiation protective suit of Figure 1, Figure 3 is a cross-sectional view taken along line III-III of FIG. .

1 to 3, the air injection type radiation protective suit 100 according to an embodiment of the present invention includes a body portion 110, a hood portion 120, and a mask portion 130.

Body 110 is wrapped around the user's torso, arms and legs, the body cover 111, the body opening 112, the neck opening 112, the glove 113, the foot cover 114, the anti-slip body (open) 115, air inlet tube 116, inlet valve 117, and body outlet valve 119. Body cover 111 is manufactured in a form that can wrap the user's torso, arms and legs, the neck is open. The open neck portion of the body sheath 111 allows the user's head and neck to be positioned. When the user wears the body covering 111, the body, arms and legs are wrapped, and the head and neck are positioned in an exposed state. The body covering 111 may shield radiation so that the user may be prevented from being exposed, and a sealing material in which the injected air does not leak to the outside is used.

Such, the inner and outer sides of the body coating 111 is disposed a body shell 111a embossed with a polyvinyl alcohol nonwoven material, between the body shell 111a the body inner shell (111b) of a polyvinyl alcohol transparent film material ) Is placed. That is, the body covering 111 is formed of a body shell 111a is disposed inside and outside, the body inner shell 111b is disposed between the body shell 111a and tripled. Triple body cover 111 is easy to operate because it does not stretch more than a certain volume even if it is pressurized from the inside by the injected air. The body shell 111a is embossed to reduce wear due to contact, and is manufactured in the form of a nonwoven fabric to have good feel and improved activity. Body endothelium 111b is made of a transparent film material to improve the shielding ability of radiation and airtight performance.

Here, polyvinyl alcohol is a colorless powder obtained by hydrolyzing polyvinyl acetate (vinyl acetate resin) with a high molecular compound. It is soluble in water and insoluble in common organic solvents. It is a raw material of vinylon and is also used in paints, adhesives, emulsion emulsions and the like. When polyvinyl alcohol is incinerated after contamination by radiation, no harmful substances are generated, thereby minimizing environmental pollution.

The body covering 111 may have a joint wrinkle body 111c formed at a joint portion that can be bent, such as an elbow and a knee. The joint corrugated body 111c is disposed in the form of wrinkles in a portion that is bent at the time of the user's work or movement, thereby improving convenience for the user.

The body opening 112 is arranged to open and close one side of the body covering 111. When the user opens the body opening 112, the body covering 111 is expanded and can be easily worn. After wearing, the body covering 111 is closed to reduce the body covering 111 to maintain a worn state. Can be.
The glove 113 is disposed on both hands of the body covering 111 and surrounds both hands. The glove is integrally provided with the body covering 111 to prevent the hand portion from being exposed to radiation. The glove 113 may be made of any conventional material that is shielded from radiation and prevents leakage of air.

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The foot cover 114 is disposed on both foot portions of the body covering 111 and surrounds both feet. The foot cover 114 is provided integrally with the body covering 111 to prevent the foot portion from being exposed to radiation. The foot cover 114 may be made of any conventional material that is shielded from radiation and prevents leakage of air.

The non-slip member 115 is disposed under the foot cover 114 and is located between the floor and the foot cover. The non-slip member 115 is prevented from sliding during movement by the foot wrapped in the foot cover 114. The non-slip member 115 may be any conventional material that is non-slip.

The air injection pipe 116 is connected to one side of the body cover 111, the air supply source (not shown) is connected to the air is supplied. Although the air source is not shown in the present specification, it is apparent to those skilled in the art that the air supply device and the air storage device are conventional. The air injection pipe 116 injects air supplied from the air source into the body sheath 111. The air injected through the air inlet tube 116 is supplied to the inside of the body covering 111 to improve the shielding performance of the radiation, and to form an air layer between the user and the body covering 111.

The injection valve 117 is connected to the air injection pipe 116 and is penetrated to the body cover 111. The injection valve 117 may adjust the injection amount of air injected through the air injection pipe 116. The injection valve 117 adjusts the injection amount of air injected from the air injection pipe 116. The injection valve 117 prevents the injected air from flowing back into the air injection pipe 116.

The body covering 111 penetrates at least one, and a body outlet 118 through which air can be discharged is formed. The body outlet 118 discharges air injected into the air injection pipe 116. Air injected from the air inlet tube 116 is circulated inside the body covering 111 and is discharged through the body outlet 118.

Body discharge valve 119 is installed in the body outlet 118, the discharge of the air discharged through the body outlet 118 is adjusted. Air discharged through the body outlet 118 is prevented from flowing back to the body discharge valve 119. The body discharge valve 119 is controlled to discharge the air injected into the air injection pipe 116. The body discharge valve 119 prevents the discharge of air in the body covering 111 by blocking the body outlet 118 when the air is discharged and the supply of air is stopped. Therefore, even when the supply of air is stopped, it is possible to evacuate while breathing using the air remaining inside the body covering 111, thereby improving safety.

The hood part 120 surrounds the user's head and neck and has a hood cover 121, a face window 122, a hood discharge valve 124, and a hood opening 125 that are worn on the body cover 111. It includes. The hood sheath 121 may cover the upper body and is worn over the body sheath 111. The hood sheath 121 is wrapped so that the head can be protected from radiation. The hood covering 121 is supplied with the air injected into the body coating 111 through the air injection pipe 116 to allow the user to breathe.

The hood envelope 121a embossed with a polyvinyl alcohol nonwoven material is disposed on the inside and the outside of the hood sheath 121, and the hood envelope 121b of the polyvinyl alcohol transparent film material is disposed between the hood envelope 121a. ) Is placed. That is, the hood covering 121 has a hood shell 121a disposed inside and outside, and a hood inner shell 121b is disposed between the hood shell 121a and formed in three layers. The hood cover 121 formed in three layers does not stretch more than a predetermined volume even when the inside is pressed by the injected air, so that the activity is easy. The hood shell 121a is embossed to reduce wear due to contact, and is manufactured in the form of a nonwoven fabric to have a good feel and improve activity. Hood endothelial 121b is made of a transparent film material to improve the shielding ability of radiation and airtight performance.

The face window 122 is disposed on the front surface of the hood cover 121 and is formed of a transparent material so that a user's view can be secured. The user may recognize an external object through the face window 122 disposed on the front surface of the hood cover 121. The face window 122 may be a polyvinyl alcohol transparent film that is a material that does not contaminate the environment when incineration due to radiation shielding ability and air sealing performance and radiation pollution.

The hood outlet 121 is formed with at least one hood outlet 123 penetrated therethrough. Air supplied into the hood sheath 121 is discharged through the hood outlet 123. That is, the air supplied through the air inlet tube 116 is supplied to the body covering 111 and the hood covering 121, the supplied air is discharged to the outside through the body outlet 118 and the hood outlet 123 do.

The hood discharge valve 124 is disposed in the hood outlet 123 and the discharge of the air discharged to the hood outlet 123 is adjusted. The hood discharge valve 124 is installed at the hood discharge port 123 to prevent the discharged air backflow. In addition, in case of an emergency in which the injection of air is blocked, the hood is discharged to the hood outlet 123 by the hood discharge valve 124 to keep the breathing until the user evacuates, thereby improving safety.

The hood opening 125 may be disposed on one side of the hood covering 121, and a user may open and close the outside and the inside of the hood covering 121 by an operation. The hood opening 125 is opened to allow breathing in an emergency where air is not injected or breathing is difficult. However, the hood opening 125 can only be used in an emergency and there is a risk of radiation exposure after opening. Therefore, it can only be used in situations where breathing is difficult in an emergency.

The mask unit 130 includes a mask body 131, a suction pipe 132, a suction valve 133, a discharge pipe 134, and a discharge valve 135 disposed inside the hood sheath 121 so that a user breathes. do. The mask body 131 is disposed inside the hood covering 121 and is positioned on the nose and mouth of the user. The mask body 131 is installed at a position in contact with the nose and the mouth when the hood covering 121 is worn so that the user can breathe. The mask body 131 is disposed on the user's nose and mouth when the hood cover 121 is worn to allow breathing.

The suction pipe 132 is connected to one side of the mask body 131, and the inside of the body covering 111 and the mask body 131 are connected to each other. The air injected into the body covering 111 is introduced into the mask body 131 through the suction pipe 132, and the introduced air is sucked to allow the user to breathe. That is, the air supplied through the air injection pipe 116 is supplied to the body covering 111 to form an air layer, and is supplied to the nose and mouth of the user through the suction pipe 132 connected to the body covering 111.

The suction valve 133 is connected to the suction pipe 132, and the supply amount of air supplied to the mask body 131 is adjusted. The intake valve 133 is provided so that the supply amount of air supplied through the intake pipe 132 is adjusted, and the reverse flow is prevented. The intake valve 133 is supplied with air for the user's breathing, and prevents backflow when discharged after the breathing.

The discharge pipe 134 is connected to the other side of the mask body 131 and penetrates through the hood cover 121. The discharge pipe 134 connects the inside of the mask body 131 and the outside of the hood covering 121. Discharge pipe 134 is installed to allow the user to discharge the air discharged after breathing to the outside. When the user discharges the carbon dioxide mixed air by breathing is discharged to the outside through the discharge pipe 134.

The discharge valve 135 is connected to the discharge pipe 134, the discharge of the air discharged from the mask body 131 is adjusted. The discharge valve 135 controls the discharge amount discharged through the discharge pipe 134 and prevents the connected external air from flowing back. The discharge valve 135 regulates the discharge of air discharged by respiration, and prevents the air contaminated with external radiation from flowing back. In addition, frost that is generated while the exhaust air collides with the face window 122 by respiration can be prevented by discharging the exhaust air to the outside.

In addition, the state of use of the air-injected radiation protective suit according to an embodiment of the present invention will be described with reference to FIG.

First, a user performing a work in a place exposed to radiation when operating a nuclear power plant or a radioisotope facility wears a body covering 111. The user wears gloves 113 and the foot cover 114 integrally formed on the body covering 111 to the hands and feet, and wears the joint corrugated body 111c to the elbow and the knee.

After the body cover 111 is worn, the user wears the hood cover 121 from the head to the upper body portion, and the entire body of the user wears the body cover 111 and the hood cover 121 to be wrapped. When the hood sheath 121 is worn, the mask body 131 installed therein is worn to be located at the nose and the mouth portion where the user can breathe.

When the body sheath 111 and the hood sheath 121 are finished wearing, the air injection pipe 116 connected to the air source is connected to one side of the body sheath 111. The air supplied from the air source is injected into the body sheath 111 through the air injection pipe 116. The injected air is also supplied inside the hood sheath 121 to form an air layer between the user and the body sheath 111 and the hood sheath 121. The supplied air is discharged through the body outlet 118 and the hood outlet 123 formed in the body cover 111 and the hood cover 121. Therefore, when the air is continuously supplied, the air is discharged from the body cover 111 and the hood cover 121 to form an air layer having a predetermined amount of air therein. The body outlet 118 and the hood outlet 123 are provided with a body discharge valve 119 and a hood discharge valve 124, the discharge of air is controlled.

When air is supplied to the body covering 111, the air supplied to the suction pipe 132 connected to one side of the mask body 131 is sucked and supplied to the user's nose and mouth to enable breathing. Exhaust air generated after the user's breath is discharged to the outside through the discharge pipe 134 is connected to the outside of the mask body 131 to the outside.

At this time, the suction pipe 132 is provided with a suction valve 133, to prevent the back flow of the supplied air, and to prevent the air discharged after the respiration to enter the suction pipe 132. In addition, a discharge valve 135 is installed in the discharge pipe 134 to prevent backflow of the discharged air, and to prevent the air sucked in the suction pipe 132 from leaking to the outside.

The air is supplied to the body covering 111 and the hood covering 121 to form an air layer, and the user sucks air into the suction pipe 132 connected to the air layer, and after the user breathes, the user discharges to the outside through the discharge pipe 134. Move to the work position and perform the work. In addition, the elbows and knees are formed with a joint pleated body (111c) improves the convenience of operation when the user moves.

When the user stops supplying air during the moving operation, the body discharge valve 119 and the hood discharge valve 124 are closed to prevent the air supplied therefrom from being discharged to the outside. Therefore, even if the air supply is interrupted, accidents are prevented by leaving the area where the user may be exposed to radiation while breathing using the air remaining inside.

In an emergency where breathing is difficult because the radiation-hazardous area does not escape to the remaining air, a situation in which air cannot be breathed may occur. In a difficult breathing situation, the hood opening 125 may be opened to allow the user to breathe even when exposed to radiation.

In addition, the air-injected radiation protective suit according to another embodiment of the present invention will be described with reference to FIGS. 5 and 6.

5 is a perspective view showing an air injection type radiation protective suit according to another embodiment of the present invention, Figure 6 is a cross-sectional view of the main portion showing the state of use of the air injection type radiation protective suit of FIG.

5 and 6, the air injection type radiation protective suit 100 according to another embodiment of the present invention is the body portion 110, the hood portion 120, the mask portion 130, and the oxygen generator 140. ). Here, the components of the body portion 110, the hood portion 120, and the mask portion 130 are substantially the same as the air-injected radiation protective clothing 100 shown in Figures 1 to 4, so that description thereof will be omitted. do.

The oxygen generator 140 is disposed inside the body covering 111, and the housing 141, the oxygen generator 145, the suction fan 146, and the discharge fan 147, through which air is generated, generates oxygen. ). The housing 141 is disposed inside the body covering 111 and has an oxygen generating space 144 therein. One side of the housing 141 is formed with an inlet 142 through which the air inside the body covering 111 flows, and the other side of the housing 141 has an outlet through which the introduced air is supplied via the oxygen generating space 144 ( 143 is formed.

The oxygen generator 145 is disposed in the oxygen generating space 144, and reacts with air introduced from the suction port 142 to generate oxygen. The oxygen generator 145 may include an oxygen generator capable of generating oxygen. Oxygen generators may include all means for generating normal oxygen, sodium peroxide (Na ₂ O ₂ ), potassium peroxide (potassium peroxide, K ₂ O ₂ ), calcium peroxide (CaO) ₂ ), lithium peroxide (Li ₂ O ₂ ), sodium superoxide (NaO ₂ ), potassium peroxide (potassium peroxide, KO ₂ ) and the like may be used.

The suction fan 146 is disposed inside the housing 141 and is located at the suction port 142 side. The suction fan 146 is operated to suck air into the body sheath 111.

The discharge fan 147 is disposed inside the housing 141 and is located at the discharge port 143 side. The discharge fan 147 is operated to supply the generated oxygen into the body cover 111 after the oxygen is generated by the air sucked in the inlet 142.

Oxygen generator 140 is improved in stability as the air generation is stopped to extend the time to evacuate by generating oxygen in the interior of the closed body sheath 111.

Although the preferred embodiment of the present invention has been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

1 is a perspective view showing an air injection type radiation protective suit according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view showing the air-injected radiation protective suit of FIG. 1. FIG.

3 is a cross-sectional view taken along line III-III of FIG. 1;

4 is a use state diagram showing a state of use of the air-injected radiation protective suit of FIG.

Figure 5 is a perspective view of the air injection type radiation protective suit according to another embodiment of the present invention.

Fig. 6 is a sectional view of principal parts showing a state of use of the air-injected radiation protective suit of Fig. 5.

* Description of the symbols for the main parts of the drawings *

100: protective clothing 110: body

111: body covering 111a: body shell

111b: body endothelium 111c: articular pleated body

112 body opening 113 glove

114: foot cover 115: slipper

116: air injection pipe 117: injection valve

118: body outlet 119: body outlet valve

120: hood portion 121: hood coating

121a: hood jacket 121b: hood jacket

122: face window 123: hood outlet

124: hood discharge valve 125: hood opening

130: mask portion 131: mask body

132: suction pipe 133: suction valve

134: discharge pipe 135: discharge valve

140: oxygen generator 141: housing

142: inlet 143: outlet

144: oxygen generating space 145: oxygen generator

146: suction fan 147: discharge fan

Claims (5)

A body sheath covering the torso, legs and arms, the body covering having an open neck and at least one penetrating body outlet, Is installed on the open side of the body covering, the body opening to be opened and closed so that the body can be worn, Arranged in the elbow and knee portion of the body cloth, the joint wrinkles can be folded in the form of wrinkles, Gloves formed integrally with the hand portion of the body coating, the hand is inserted into the form, Is formed integrally with the foot portion of the body covering, the foot cover formed in the form that the foot is inserted, Is disposed in the lower portion of the foot cover, the anti-slip body that can be slipped, Is connected to one side of the body cover, the air injection pipe is injected air, A hood covering covering the upper body portion from above the body covering, covering the head and having a hood outlet through at least one, A face window disposed on the front surface of the hood covering and formed of a transparent material, Is installed on one side of the hood coating, the hood opening which is partially opened and closed to block and close the inside and outside of the hood coating, A mask body disposed inside the hood and surrounding the breathing nose and mouth, A suction pipe connected to one side of the mask body and communicating with an inside of the hood coating to supply air to the inside of the mask body; and A discharge pipe connected to the other side of the mask body and communicating with the hood covering and the outside to discharge air generated by breathing inside the mask body; Including; The air injected into the air inlet tube is supplied to the hood covering inside and sucked into the nose and mouth located inside the mask body through the suction tube, and the exhalation generated by the breathing is applied to the hood covering through the outlet tube. Discharged to the outside Pneumatic radiation protective clothing. The method of claim 1, The body covering and the hood covering Endothelial, consisting of polyvinyl alcohol (PVA) transparent film material, and A sheath disposed on the inner and outer surfaces of the endothelium and made of embossed polyvinyl alcohol (PVA) nonwoven material Air-injected radiation protective clothing comprising a. The method of claim 1, An injection valve inserted into one side of the body coating and connected to the air injection pipe to adjust the amount of air injected; A body discharge valve inserted into the body outlet and configured to control an amount of air discharged from the body coating; A hood discharge valve inserted into the hood outlet and configured to control an amount of air discharged from the hood sheath; Further provided, The air injected while the supply amount is adjusted by the injection valve may be discharged to the outside while the discharge is controlled in the body discharge valve and the hood discharge valve. Pneumatic radiation protective clothing. The method of claim 1, A suction valve connected to the suction pipe and configured to prevent a backflow while controlling an amount of air supplied into the mask body; A discharge valve connected to the discharge pipe and controlling the discharge of air discharged by respiration inside the mask body to prevent backflow Including; The air sucked into the intake valve may be sucked while preventing backflow into the nose and mouth located inside the mask body, and the air discharged from the nose and mouth by respiration is prevented from flowing backward to the discharge valve to the outside. Exhaustable Pneumatic radiation protective clothing. The method of claim 1, A housing disposed inside the body coating, having a suction port for inhaling air on one side, an oxygen generating space on the inside, and a discharge port for discharging oxygen generated in the oxygen generating space on the other side; An oxygen generator disposed inside the housing and configured to generate oxygen by reacting air sucked from the suction port; Is disposed on one side of the suction port, the suction fan for sucking air to the oxygen generator side through the suction port, and Is disposed on one side of the discharge port, the discharge fan for supplying the oxygen generated in the oxygen generator to the inside of the body coating through the discharge port Air-injected radiation protective suit further comprising.

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