KR101849265B1 - Safety charging apparatus for air respirators - Google Patents

Abstract

The present invention relates to a container safe charging box for an air respirator, which installs a door stopper apparatus in the charging box, in which a container for the air respirator is placed, as a means to prevent a door from opening and leading to damage by an impact in case of an explosion, since the whole box including the door is able to keep firm structural strength against an impact in case of an explosion. Accordingly, the present invention is able to protect a worker in case of an explosion of a container for an air respirator, to reduce secondary damage due to a broken charging box, and to secure safety and durability. The present invention is able to install a diaphragm for absorbing an impact and an absorption material in the charging box, where the air respirator is placed, and interpose a buffer structure between the charging box and a controller, to realize a new structure of charging box which absorbs a primary impact and noise from an explosion in case of an explosion of the air respirator, and to protect a worker from an impact in case of an explosion, thereby allowing the charging box to be reused even after the explosion and simultaneously minimizing damage to the controller. In addition, the present invention is able to install a spiral-structured multiple filter structure on the bottom side of the charging box, to rapidly discharge internal air (internal pressure) in case of an explosion, and to minimize discharge of scattered materials toward the outside such as fragments of textile materials, or the like, thereby protecting the safety of a worker as much as possible in case of an explosion of the air respirator.

Description

[0001] The present invention relates to a safety charging apparatus for air respirators,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a safety recharging case for an air respirator, and more particularly, to a safety recharging case for an air respirator that safely recharges breathable compressed air into a respiratory container used by a firefighter, a skin scuba or the like.

In general, firefighters who perform rescue work in case of fire, skin scuba that enjoys underwater sports or underwater work, and patients who need breathing air for medical purposes use a respiratory container filled with breathing air And breathing.

These air respirator containers are filled with new respiratory air if the remaining amount is reduced after use. If left unused for about 3 to 4 months even if not used, it will prevent contamination of air inside the air respirator. In order to do this, it is necessary to discharge the residual air and then fill it with new breathing air.

Current air respirator containers are filled with new respiratory air, compressed air at normal pressure (general air of about 20% oxygen and about 80% nitrogen) at high pressure using an air respirator container filling device, Products that circulate, and products that distribute oxygen and nitrogen in liquid form in a container separately.

In the case of breathing air, oxygen and nitrogen are used separately depending on the application such as aquatic sports, medical use, and general industrial use, and the concentration of oxygen or nitrogen is appropriately adjusted to suit the intended use.

In general, there is a problem of explosion accident during charge because the breathing air is charged at a high pressure of about 200 to 300 bar when the respiratory air is filled in the air respiratory container used by a firefighter or a skin scuba.

Explosions during the filling of the breathing air are occasionally caused by the use of an aged air respirator or a damaged air respirator, and explosion occurs mainly during the process of charging respiratory air.

Thus, when the container for an air respirator explodes during charging, the impact is given to the door, which is the weakest part of the structure, to the operator, and the impact is applied to the inner wall of the charging device, Eventually the recharging device can not be reused.

In addition, fine powder and carbon fibers are broken and blown together with the metal chunk fragments, which can prevent the outer blowout of the metal chunk fragments, but the outer blowout of the fine powder and the broken carbon fibers is practically difficult to prevent, there is a problem.

In other words, carbon fiber is a rigid fiber such as steel, and when a piece of fiber material strong like wire is ejected to the outside, it seriously injures the worker.

In addition, since the charging unit of the charging apparatus that receives the explosive force and the controller for controlling the charging unit are integrated, there is a problem that the components of the control unit such as the gauge of the controller due to the internal explosion impact are damaged. In addition, Which can lead to very dangerous situations.

In view of the above, Korean Patent No. 10-1638829 discloses a "high-pressure air-filling chamber for breathing" and Korean Patent No. 10-1686580 proposes a "high-pressure air-filling chamber for breathing".

The above-mentioned " high-pressure air safety filling box for breathing " and " high-pressure air filling filling device for breathing " have adopted a structure for preventing the occurrence of safety accident by dispersing the pressure during explosion of the air box. However, The problem can not be solved, and it can be seen that it is insufficient to prevent fine powder or carbon fiber from being blown from the outside.

Korean Patent No. 10-1638829 Korean Patent No. 10-1686580

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a door stopper device as a means for preventing a door from being opened and broken by an impact at the time of explosion inside a charging case in which a container for an air- It is possible to safely protect the operator in the event of explosion of the container for the air respirator by implementing a new type of safety filling box that can maintain the rigid structural rigidity of the entire filling box including the door against the impact at the time of explosion. The present invention provides a safety filling container for an air respirator that can secure safety and durability such that it can reduce secondary damage caused by a fire.

Another object of the present invention is to provide a shock absorbing diaphragm and an absorber inside a charging compartment in which an air respirator is disposed and to provide a shock absorbing structure between a charging compartment and a controller, It is possible to protect the operator from the impact at the time of explosion as well as to be able to reuse the filling chamber even after the explosion and to minimize the damage of the controller, Container safe filling box.

Still another object of the present invention is to provide a multi-filter structure having a spiral structure at the lower part of a filling compartment to rapidly blow out internal air (internal pressure) at the time of explosion, The present invention provides a safety filling container for an air respirator that can protect the safety of an operator in the event of an air respiratory explosion.

In order to accomplish the above object, the present invention provides a safety filling container for an air respirator, which has the following features.

The safe filling case for an air respirator according to an embodiment of the present invention comprises a filling case body in the form of a box structure having a filling chamber formed therein, A filling door provided with a handle and a plurality of container receiving openings on the inner side and a door which is installed on the inner upper side of the filling door main body and which is interlocked by a door closing and opening operation and a door handle bending operation and clamps or unclamps And a door stopper device.

Such a safety filling compartment for an air respirator is characterized by being able to prevent deformation or breakage of the filling compartment main body including door opening which is filled with an impact upon explosion of the air respirator by the door clamping action of the door stopper device.

The air purifier safe filling compartment is connected to the lower part of the filling compartment and communicates with the filling compartment, and further includes a buffer box for damping the impact by using a horizontal partition plate on the upper inflow side and a vertical partition plate can do.

Further, the door handle may be installed on both side walls of the door, while being rotatably supported by a handle hinge, and interlocked with the door stopper device side through both ends of the door handle.

At both ends of the door handle, a knob guide roll for guiding the rotation of the door handle may be installed while moving along the arc-shaped slot formed on both side walls of the door.

The filler door may be provided with a switch operation bar which can be turned on / off by contacting the valve switch of the compressed air opening / closing valve provided on the wall surface side of the filling chamber.

According to a preferred embodiment of the present invention, the door stopper device includes a stopper frame provided on the side of the charging compartment, an up-down shock absorber installed in a vertical posture at a lower end of the stopper frame and interlocked with the operation of the stopper plate, And a stopper plate provided on the upper end of the stopper frame for hanging the side wall of the stopper plate and moving downward of the stopper plate, And a lock / unlock shock absorber for restricting the lock / unlock shock absorber.

Here, the stopper plate of the door stopper device can be guided by the guide bushes and the guide bars, which are mounted on the stopper frame side and the stopper plate side, respectively, and are slidably engaged with each other.

The stopper plate of the door stopper device may be provided with a stopper roll which is in contact with the front end of the door handle when the door stopper is interlocked with the door handle side.

According to another aspect of the present invention, there is provided a safe filling compartment for an air purifier, comprising: a box-type filling compartment provided with a door capable of opening and closing and capable of receiving an air respirator therein; A controller for controlling compressed air to be charged into the air respirator and a means for absorbing the impact generated when the air respirator is blown is installed on the inner wall surface of the charging chamber, A shock absorbing partition made of a beam structure, and a shock absorbing shock absorbing material adhered to the back surface of the shock absorbing partition.

Here, the shock-absorbing partition is composed of a beam member having a frame structure having a plurality of supports at the rear and a steel plate attached to the front face of the beam member, It can be installed in a possible structure.

In addition, the safety filling compartment for the air respirator is installed in a structure communicating with the lower part of the filling compartment, and has an air vent at one side thereof. The air ventilation compartment safe filling compartment is arranged in multiple stages with a spiral structure, And a non-product collecting box in which the non-product collecting box is installed.

Here, the non-product collection filter is formed in an arc shape, and a plurality of unit collecting filters having different diameters are disposed in a spiral shape in a coaxial structure along the vertical direction, It is possible to arrange them in the order of increasing diameters and arranging concentric circles facing each other.

Each of the unit collection filters of the non-product collection filter at this time can be arranged such that both ends are partially overlapped with each other.

The air respiratory safety filling device may further include a plurality of buffer members interposed between the bottom surface of the controller and the top surface of the filling compartment to absorb impact transmitted to the controller.

Such a cushioning member may be made of an air spring, a vibration proof rubber, a spring, or the like.

The safety filling container for an air respirator provided in the present invention has the following effects.

First, a door stopper device for preventing a door from being opened and broken due to an impact at the time of an explosion is installed in a charging case in which a container for an air respirator is disposed. By maintaining structural rigidity, it is possible to secure safety and durability such that the operator can be safely protected at the time of explosion of the container for the air respirator and the secondary damage due to damage of the filling box can be reduced.

Second, since the impact absorbing diaphragm made of the iron H-beam structure resistant to impact absorption and the shock absorber made of a material such as sponge or rubber having excellent sound insulation and shock absorbing function are provided, And the explosion noise can be effectively absorbed, and the operator can be safely protected from the impact at the time of explosion, and after the explosion, only the shock absorbing means damaged inside can be replaced and the recharging can be reused, which is advantageous in terms of economy .

Third, by installing a multi-filter structure with a spiral structure at the bottom of the filling compartment, it is possible to minimize metal scattering and carbon fiber powder at the time of explosion, minimize external scattering, So that it is possible to prevent a dangerous situation in which a worker is injured by the explosion due to an explosion, and thus it is possible to protect the safety of the operator as much as possible.

Fourth, there is an effect that it is possible to minimize the damage to the gauge, the operation unit, and the like, which can prevent the shock at the time of explosion from being transmitted to the controller side through the buffering means such as an air spring or the like between the charging case and the controller.

FIG. 1 is a perspective view of a safety filling container for an air purifier according to an embodiment of the present invention. FIG.
3 and 4 are a perspective view and a side view showing a state in which a main body cover is filled in a safe filling compartment of a container for an air respirator according to an embodiment of the present invention
5 to 8 are a perspective view, a front view, a plan view, and a side view, respectively, of a door stopper device in a safety filling compartment for an air respirator according to an embodiment of the present invention.
FIG. 9 is a side view showing an operating state of a door stopper device in a safety filling compartment for an air respirator according to an embodiment of the present invention
10 and 11 are perspective views showing a safety filling container for an air respirator according to another embodiment of the present invention.
12 to 14 are cross-sectional views illustrating a container for safely filling a container for an air respirator according to another embodiment of the present invention
FIG. 15 is a cross-sectional view showing a state in which an impact is absorbed upon explosion of a container for an air respirator in a container for safely filling a container for an air respirator according to another embodiment of the present invention

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view illustrating a safety filling container for an air purifier according to an embodiment of the present invention. FIGS. 3 and 4 are perspective views illustrating a safety filling container for an air purifier according to an embodiment of the present invention. Fig. 6 is a perspective view and a side view showing a state in which the main body cover is removed. Fig.

As shown in FIGS. 1 to 4, the air purifier safe filling compartment reinforces the structural rigidity of the filling compartment main body and reinforces the binding structure of the filling compartment door so as to fill the air purifying compartment with air for breathing When the container for an air respirator is exploded in the course of the operation of the air conditioner, the explosion impact at this time can effectively prevent damage to the main body, as well as opening and breakage of the main body.

For this purpose, the air purifier safe filling compartment includes a filling compartment 110 in which a compartment 100 is formed.

The filling chamber 110 has a rectangular box shape formed by assembling a metal plate having a predetermined thickness, and a filling chamber 100 is formed in the inside of the filling chamber 110 to accommodate an air respiratory container.

A control box 250 having various kinds of gauges, switches and the like is installed on the upper part of the charging case main body 110. The control box 25 is operated and controlled by the control box 25, Charging control (for example, smart residual pressure release control before filling the container).

A filter box 260 for removing impurities in the compressed air for breathing, which is filled in the air respiratory container, is installed at the rear of the filling body 110.

Particularly, a rectangular cushion box 180 is provided at a lower portion of the filling body 110 to serve as a chamber capable of absorbing and canceling an impact at the time of explosion.

The cushioning box 180 is disposed to extend from the bottom of the filling body 110 to the bottom of the filter box 260 and to be communicated with the filling chamber 100 of the filling body 110 do.

A horizontal buffer plate 160 having a perforated plate structure is installed on the upper inflow side of the cushioning box 180, that is, the upper inflow side connected to the charging chamber 100 side. .

A vertical partition 170 for partitioning the inner space into two spaces is provided in the middle of the buffer box 180. A plurality of holes are formed in the vertical partition 170, Space can be communicated with each other.

At this time, the vertical diaphragm 170 serves to secondarily reduce the primary reduced impact.

In addition, a vertical reinforcing plate 270 is provided on the entire inner space of the cushioning box 180, and even when the impact force is transmitted to the inside of the cushioning box 180 by the vertical reinforcing plate 270 thus installed, It is possible to secure a rigid support rigidity on the front side of the box 180. [

Accordingly, when an explosion occurs in the internal filling chamber 100 of the filling body 110, the explosive impact force is transmitted to the lower cushioning box 180, and the explosive impact force transmitted to the lower cushioning box 180 is transmitted to the horizontal cushioning plate 160 and / Can be substantially canceled while being absorbed and reduced while passing through the vertical partition 170 and passing through the inner space of the cushioning box 180.

The air purifier safe filling compartment includes a filling door 140 as a means for opening and closing the internal filling compartment 100 of the filling compartment 110.

The filling door 140 is formed in a rectangular plate shape having both side walls as a means for closing or opening a front opening portion of the filling body 110 and mounting a container for an air respirator, And is rotatably supported via a door hinge 350 to a bearing 280 fixed to a wall on both sides of the inner side of the door 110.

Accordingly, the filling door 140 can be opened and closed while being rotated around the door hinge 350 on both lower ends thereof.

At this time, the other end of the opening / closing shock absorber 290, which is temporarily supported at the wall side of the filling door main body 110 and assists opening and closing operations of the filling door 140, So that the filling door 140 exhibits a slow opening / closing mode through elastic support provided by the opening / closing shock absorber 290.

That is, the filling door 140 can be opened and closed slowly, without being rapidly opened or closed even in the state where the container for air respirator, which is a heavy object, is stationary.

A plurality of container receiving openings 130 are installed on the inner surface of the filling door 140 so as to receive the air respiratory container. The container receiving opening 130 at this time is a circular tube having an open top and a closed bottom A plurality of, for example, two, three, four, etc. vertically arranged in parallel to the inside of the filling door 140 can be provided.

That is, a two-sphere type having two container receptacles as shown in Fig. 2A, a three-sphere type having three container receptacles as shown in Fig. 2B, and a four-sphere type having four container receptacles as shown in Fig.

In addition, a vertical reinforcing plate 300 and a horizontal reinforcing plate 310, which are bent in a substantially trapezoidal cross-sectional shape, for reinforcing the rigidity of the filling door 140 are provided, and the vertical reinforcing plate 300, And the horizontal reinforcing plate 310 is disposed between the container receiving openings 130 on both sides and welded to the inner surface of the filling door 140 by welding or the like while being disposed between the container receiving openings 130. [ And is arranged in a horizontal posture while being fixed.

Since the vertical reinforcing plate 300 and the horizontal reinforcing plate 310 are reinforced on the side of the filling door 140 and the container receiving side 130, So that damage or deformation of the filling door 140 can be minimized.

The horizontal reinforcing plate 310 is connected to an end of a connector (not shown), that is, a compressed air hose (not shown), which is fastened to a container for an air respirator, A plurality of connector mounting holes 340 are formed for mounting a connector to be fastened to the connector.

Thus, in a state in which a container for an air respirator (not shown) is housed in the container holding port 130, a connector placed in the connector mounting hole 340 of the horizontal reinforcing plate 310 on one side thereof, (Not shown) of the upper injection valve, the preparation for filling the breathing air can be easily completed.

A slot 200 is formed at one side of an upper end of each of the sidewalls of the filling door 140 so as to define a trajectory of an arc shape along the vertical direction. The slot 200 at this time is formed with a door handle The handle guide roll 210 of the first and second guide rollers 120 and 120 is inserted into the guide guide roll 210 to receive the movement guide.

In particular, a contact end 320 having a gently rounded shape is formed at the upper end of each side wall of the filling door 140, and a pressing end 330 protruding inward is formed.

The contacting end 320 and the pressing end 330 are naturally formed by cutting the upper end portions of both side walls of the filling door 140 into a predetermined shape. The stopper roll 150g is brought into contact with the lower portion of the stopper roll 150g of the door stopper device 150 to be described later so as to slightly lift up the stopper roll 150g and to push the stopper roll 150g upwardly, Lock shock absorber 150d of the door stopper device 150 when the door is closed.

Accordingly, when the door is closed, the contact end 320 slightly raises the stopper roll 150g, so that the stopper plate 150b can be lifted up slightly. As a result, the lock 150b / The unlock shock absorber 150d is released from the interference from the stopper plate 150b and the pressing end 330 presses the rod of the lock / unlock shock absorber 150d in this state, A series of operations of the components of the apparatus 150 can be performed smoothly.

At the upper end of the sidewalls of the filling door 140, a roll receiving groove 360 is formed at a position adjacent to the front side of the contact end 320 and downwardly in the form of a depressed roll receiving groove 360. At this time, The stopper roll 150g of the door stopper device 150 can be positioned.

That is, in the door closing process, the stopper roll 150g, which has rolled on the contact end 320 of the filling door 140, completely stops the stopper plate 150b when the door is completely closed, So that it can be positioned.

The charging door 140 is provided with a door handle 120 as a means for opening and closing the door.

The door handle 120 includes a handle 120a horizontally disposed in the left-right direction of the door and a connecting rod 120b horizontally extending from both ends of the handle 120a and extending horizontally in the front- .

The connecting rod 120b on both sides of the door handle 120 is supported by the handle hinge 190 on the side wall of the door 140 filled with the middle portion of the door handle 120. Accordingly, the door handle 120 is supported by the handle hinge 190 and can be installed in a structure rotatable up and down about the handle hinge 190 at this time.

A knob guide roll 210 is provided at both ends of the door knob 120, that is, at the tip of each of the connecting rods 120b. The knob guide roll 210 at this time is attached to both sides of the door And is positioned in the slot 200 formed on the side wall and can guide the rotation operation of the door knob 120 while moving along the slot 200.

Particularly, in the case of the door handle 120, the door handle 120 can be interlocked with the door stopper device 150 side by using a rotatable structural characteristic.

That is, before the filling door 140 is opened, the locking state of the door stopper device 150 hanging the filling door 140 is released. At this time, the handle 120a of the door handle 120 is held The upper end of the connecting portion 120b of the door handle 120 is pushed up and the stopper roll 150g of the door stopper device 150 is pushed upward so that the upper end of the filling door 140 The stopper plate 150b is lifted upward and at the same time the engagement of the door 140 is released. Therefore, the door can be easily opened while releasing the door lock.

On the other hand, the charging door 140 is provided with a switch operation bar 240 as means for automatically starting the supply of the compressed air for breathing automatically when the door is closed.

For example, a compressed air opening / closing valve 220 connected to a compressed air hose (not shown) is installed on the inner side wall surface side of the filling chamber main body 110, and the compressed air opening / A valve switch 230 is provided for valve opening and closing operations.

At this time, the valve switch 230 is a pivot type switch type, which is formed in an elongated rod shape, and is positioned in a vertical posture at a position close to the inner inner wall surface of the filling chamber body 110.

For the ON / OFF operation of the valve switch 230, the inner surface of the filling door 140, for example, the horizontal reinforcing plate 320 installed on the filling door side, A bent bar bar-shaped switch operation bar 240 is provided.

Accordingly, when the filling door 140 is closed, the distal end portion of the switch operation bar 240 pushes the valve switch 230 of the compressed air opening and closing valve 220 inward, and eventually the switch operation bar 240 So that the compressed air can be supplied through the compressed air hose while the compressed air opening and closing valve 220 is opened.

Of course, when the filling door 140 is opened, the valve switch 230 of the compressed air opening / closing valve 220 and the switch operating bar 240 are separated from each other, and the valve switch 230 is restored to its vertical posture At this time, the compressed air opening and closing valve 220 is closed so that the compressed air supplied through the compressed air hose can be shut off.

FIGS. 5 to 8 are a perspective view, a front view, a plan view, and a side view, respectively, of a door stopper device in a safety filling container for an air respirator according to an embodiment of the present invention.

As shown in FIGS. 5 to 8, the door stopper device interlocks with the filling door opening / closing operation and the door handle bending operation, thereby restricting the door closing state for safety during explosion or the like during filling of the compressed air, And to open the door when the container for air respirator for compressed air filling is stored.

To this end, a stopper frame 150a, which is a combination of both a bending vertical member and a bar-shaped horizontal member that connects the bending vertical member, is disposed at the inner upper end of the charging body 110, that is, The stopper frame 150a is installed in such a structure that the stopper frame 150a is fixed to the inner surface of the front plate and the inner surface of the ceiling plate.

An up-down shock absorber 150c is installed at a horizontal end of the lower end of the bending-type vertical member of the stopper frame 150a in a vertical posture with the rod up, and the vertical end of the upper end of the bending- The lock / unlock shock absorber 150d is installed in a horizontal posture with the load forward through the shock absorber bracket 150h.

The up-down shock absorber 150c installed in this way serves to properly support the load of the stopper plate 150b (i.e., to prevent the stopper plate from being rapidly lowered by the load) by using its own damping force, The lock / unshock shock absorber 150d serves to regulate the downward movement of the stopper plate 150b by using a rod that advances at the time of depression release by using the self-damping force.

Particularly, the stopper plate 150b is provided to hang the upper end front surface of the charging door 140 while moving up and down.

The stopper plate 150b includes a cross bar 150b-1 disposed horizontally and horizontally along the widthwise direction of the door and a vertical bar 150b-1 extending vertically from both ends of the cross bar 150b- 2, and the cross bar 150b-1 at this time is hooked in a state of obstructing the upper end front face of the substantially filled door 140. As shown in FIG.

The stopper plate 150b is supported by the up-down shock absorber 150c and can be installed in a structure associated with the operation of the up-down shock absorber 150c.

For example, a guide bar 150f is vertically installed on the outer surface of each vertical bar 150b-2 of the stopper plate 150b to support upper and lower ends by two bar blocks 150i, The guide bar 150f is coupled to the guide bush 150e provided on the back surface of the stopper frame 150a so as to be slidable.

The lower end of the guide bar 150f is connected to the rod of the up-down shock absorber 150c via a coupling or the like.

Accordingly, the stopper plate 150b can be installed on the side of the up-down shock absorber 150c using the guide bar 150f and can be guided in the up-down operation.

The stopper plate 150b is restricted from moving downward by the lock / unshock shock absorber 150d when the door is closed. To this end, the vertical base 150b-2 of the stopper plate 150b is provided with a latching end And the stopper 150j is formed with a rod of the lock / unlock shock absorber 150d, so that the downward movement of the stopper plate 150b can be restricted.

A stopper roll 150g having a freely rotatable structure is provided on the inner surface of the sidewall of the stopper plate 150b, that is, the inner surface of the vertical base 150b-2. The stopper roll 150g at this time is fixed to the door handle 120 and can be lifted up to a certain height and brought into contact with the contact ends 320 formed on the upper ends of the walls of the filling door 140 and lifted up and slightly raised .

For example, when the door is opened, the front end of the connecting rod 120b can be lifted up by lowering the door handle 120 downward. When the door is closed, the contact end 320 ) Can be lifted slightly below the stopper roll 150g.

The operating state of the door stopper device constructed as described above will be described below.

FIG. 9 is a side view showing an operating state of a door stopper device in a safe filling compartment for an air respirator according to an embodiment of the present invention.

9, since the pressing end 330 on the side of the filling door 140 presses the rod of the lock / unlock shock absorber 150d in the door closed state (A), the lock is released, The stopper plate 150b of the stopper device 150 is lowered down to its maximum extent by its own weight and the cross bar 150b-1 at this time closes the upper end front of the filling door 140 from the front side, The charging door 140 is not opened unless the door 120 is operated.

Particularly, even when explosion occurs during filling of the container for the air respirator and explosive charging force is applied to the door 140, the door 140 is deformed due to the firm locking action of the door stopper device 150 It is possible to reduce the damage of the door 140 to the utmost and safely protect the operator who stands in front of the door 140.

When the filling door 140 is opened for charging the air chamber for the air purifier in the filling chamber 100 of the filling chamber 110, the worker pushes the door knob 140 downward, The stopper plate 150b of the door handle 140 pushes up the stopper roll 150g in the stopper plate 150b and at the same time the stopper plate 150b is moved upward do.

The stopper plate 150b is lifted up and the door of the filling door 140 is opened and the rod of the lock / unshock shock absorber 150d is moved forward. In addition, the stopper plate 150b The stopper plate 150b does not descend any more because the stopper 150j of the stopper plate 150b is slightly caught by the rod of the lock / unlock shock absorber 150d which is forwardly protruding from the stopper plate 150b. (B).

In this state, the operator holds the air respirator container in the container receiving port 130 in the charging door 140, and then connects the connector (not shown) on one side to the upper injection valve of the air respirator container The stopper plate of the door stopper device 150 is lowered to restrain the upper end front surface of the filling door 150. At the same time, The valve switch 230 is folded by the switch operation bar 240 of the air valve 220 so that the compressed air opening and closing valve 220 is opened and the compressed air is supplied through the compressed air hose, The compressed air for breathing can be charged.

Meanwhile, the safe ventilation of the air respirator according to another embodiment of the present invention will be described as follows.

FIGS. 10 and 11 are perspective views illustrating a safe filling compartment for an air purifier according to another embodiment of the present invention, and FIGS. 12 to 14 are cross- to be.

As shown in FIGS. 10 to 14, the air purifier safe filling compartment includes shock absorbing means and non-product collecting means to easily absorb and collect shocks and non-explosions when the air respirator container is exploded , So that the entire apparatus can be reused even after the air respirator container is exploded.

To this end, the container for safely inserting the air respirator includes a charging compartment 12 as a means for providing an accommodation space for charging the air respirator 11.

The filling compartment 12 is made up of a rectangular box-shaped steel structure with an open bottom.

A rectangular door 10 is formed on the front surface of the charging compartment 12 and the door 10 can be opened or closed while being rotated by using a hinge 21 at the lower end with a handle at an upper end of the door .

Of course, although not shown, the door 10 is provided with a known locking means, so that the closed state can be maintained by being locked on the charging side in the closed state, and the door 10 can be opened when the locking means is unlocked. .

In addition, although not shown, a plurality of holes may be formed at the upper end of the wall of the filling compartment 12 to allow the piping flow extending from the controller side to enter the filling compartment in which the air respirator is accommodated.

A container holder 22 is formed on the inner wall surface of the door 10 via an impact absorbing partition wall 14 to be described later. A state in which the air respirator 11 is placed in the container holder 22 So that the filling operation of the breathing air can be performed.

In addition, the air purifier safe filling compartment includes a controller 13 as a means for controlling and operating the compressed air (breathing air) charged when charging the container for an air respirator.

The controller 13 is installed on the upper part of the filling box 12, and includes switches for controlling the pressure, gauges for checking the pressure, buttons for operating the operator, various kinds of lamps and valves, And various kinds of piping for connection with the piping.

Herein, the controller can be applied to a conventional controller used for charging the air respirator, and the overall usage method related to the structure, operation, operation of the controller, and preparation for connecting the controller side piping to the air respirator, And any method that is commonly known in the art can be employed without any particular limitation.

The controller 13 is installed in a structure that is supported by a plurality of buffer members 20, so that the controller 13 can minimize the influence of the impact upon the vessel explosion.

For example, between the four corners of the bottom surface of the controller 13 and four corners of the upper surface of the filling chamber 12, a buffer member 20 (shown in FIG. 1) for absorbing shock transmitted to the controller 13 And the controller 13 can be installed while receiving elastic support by the buffer members 20 at four places on the bottom surface.

The buffer member 20 may be an air spring, a vibration proof rubber, a spring, or the like. In an embodiment of the present invention, four air holes It shows an example of applying spring.

Therefore, when the air conditioner is exploded in the filling chamber 12, the upward movement of the controller 13 is mostly absorbed by the buffering action of the buffer member 20, that is, the air spring, There is an advantage that an expensive controller can be reused such that almost no impact is transmitted and the controller 13 can be prevented from being damaged from an impact at the time of an explosion.

In addition, the air safety respiratory container safe containment compartment includes a shock absorbing partition wall 14 and a shock absorbing shock absorber 15 as a means for substantially absorbing the shock when the container for an air respirator explodes.

The shock-absorbing barrier ribs 14 are made of steel plates and iron beams, and are made of iron beams 14b having the shape of a rectangle frame and having support rods 14a at four corners on the rear side, And a square iron plate 14c attached to the front surface of the beam member 14b by welding or the like.

These shock absorbing partitions 14 are arranged side by side on the inner wall surface of the filling chamber 12, for example, on the rear wall surface, the left and right wall surfaces, and the ceiling wall surface as well as the inner surface of the door 10 And is installed in a detachable structure via the bolt fastening structure by using the support table 14a of the beam member 14b in this state.

Accordingly, the shock-absorbing partition wall 14, which is damaged due to the impact of the air respirator after the explosion, can be easily detached from the side of the wall surface by releasing the bolt fastening portion on the side of the wall surface for filling the support base 14a. The partition wall 14 can be easily replaced.

The shock absorbing cushion material 15 is made of a sponge or a rubber material, and is capable of acting as a sound absorbing means as well as an impact shock upon explosion.

The shock absorbing shock absorber 15 may have a substantially rectangular block shape and may be installed on the rear surface of the plate 14c of the shock absorbing partition 14 through an adhesive or the like.

Accordingly, the shock absorbing partition wall 14 exhibiting the structural support rigidity at the time of the air respirator explosion in the filling box 12 is firstly absorbed and reduced by the explosion impact, and subsequently the shock absorbing cushion material 15 is subjected to the residual shock So that the shock and noise during the explosion of the container can be completely absorbed and removed.

In addition, the air safety respirator safe containment compartment includes an ash collecting compartment 18 as a means for effectively collecting non-products (fine metal debris, carbon fiber powder, etc.) ejected during container explosion.

The non-product collecting box 18 is formed of a rectangular box-shaped steel structure having an upper part and is installed at a lower end of the filling compartment 12 so as to be integrally connected.

In this way, the non-product collecting box 18 and the filling box 12 can communicate with each other, so that the non-product generated when the explosion inside the filling box immediately collects the non- So that it can be introduced into the inside.

A jet port 16 is formed at one side of the lower end of the non-product collecting box 18, for example, at the lower end of the front or rear surface or the lower end of the lower port. As shown in FIG.

Particularly, the non-product collecting box 18 is provided with an non-product collecting filter 17 that collects non-product generated at the time of explosion of the container and absorbs a part of the impact.

The non-product collecting filter 17 has a structure in which a plurality of unit collecting filters 19 are formed in a spiral structure and are arranged in multiple stages and supported by a filter holder 23 extending from the wall surface side of the non- Respectively.

Each of the unit collecting filters 19 has a substantially semicircular arc shape and has a relatively different diameter from each other. The plurality of unit collecting filters 19 have a coaxial structure along the vertical direction And arranged in a spiral manner.

That is, the unit collection filter 19 having the smallest diameter is disposed on the upper side, and the unit collecting filters 19 having the larger diameter are arranged in order as the downwardly directed unit filter 19 is arranged. Are arranged concentrically facing each other.

Each of the unit collection filters 19 can be arranged such that the both ends of the unit collection filters 19 partially overlap with each other while maintaining a constant gap in the horizontal direction. As a result, the unit collection filters 19, So that a conical spiral path can be formed.

Here, the non-product collecting filter 19 may be an industrial filter such as a mesh net type, a metal fiber type, a sintered mesh filter type, a powder filter type, or the like.

Therefore, the non-product such as metal chunk fragments, fine powder, broken carbon fibers, and the like, which is generated during the air respirator explosion in the filling compartment 12, flows into the lower non-product collecting compartment 18, Collecting filter 17, and the residual pressure continues to pass through the jet port 16 of the non-product collecting box 18. [0042] As shown in FIG.

FIG. 15 is a cross-sectional view illustrating a state in which an impact is absorbed when a container for an air respirator is exploded in a safe filling compartment for an air breathing apparatus according to an embodiment of the present invention.

(Not shown) extending from the controller 13 side is connected to the air respirator 11 so as to perform breathing The air respirator 11, which has been charged due to aging or the like, may explode while charging the air.

When the air respirator 11 explodes in this way, the impact due to the explosion at this time is applied to the shock absorbing partition wall 14 and the shock absorbing shock absorber 15 provided on the inner wall of the filling chamber 12, Absorbing partition 14 and the shock absorbing cushioning material 15 absorb most of the impact and noise, and at the same time, the shock absorbing partition wall 14 and the shock absorbing cushioning material 15 Which can be damaged, while protecting the safety of the operator, the charger itself is hardly damaged.

Therefore, after replacing the damaged shock absorbing partition wall 14 and the shock absorbing shock absorber 15 after the explosion with a new one, the recharging unit 12 can be reused as it is.

At the same time, the arsenic generated by the explosion of the air respirator 11 is introduced into the lower arsenic collector 18 and then led along the helical path of the arsenic collection filter 17, It can be collected and removed.

In addition, the pressure due to the impact can also be substantially attenuated while passing through the helical path, and the internal air can also be quickly discharged to the outside.

Accordingly, it is possible to completely solve the problem of injuring the operator due to the non-product generated at the time of explosion.

In addition, even when the impact at the time of explosion is transmitted to the controller 13, the buffer member 20 can attenuate the shock, so that the controller 13 can be prevented from being damaged. As a result, (13) can be reused.

As described above, according to the present invention, by using the locking action of the door stopper device provided on the side of the filling compartment, the closed state of the door to be filled is firmly maintained, and when an impact due to explosion is applied during charging the container for the air respirator It is possible to restrain the opening of the door of the filling door, thereby minimizing the damage or damage of the filling door as well as the door of the filling door. Accordingly, it is possible to ensure safety of the operator and durability of the filling door.

In addition, by implementing a safe filling box equipped with an internal shock absorbing diaphragm that combines a steel H-beam structure that is resistant to shock absorption and a sound insulation and shock absorber such as a sponge or rubber material, the primary shock and explosion noise , And the explosion can be reused by replacing only the damaged damage-absorbing diaphragm.

In addition, in the present invention, by applying a multi-stage collection box having a spiral structure which minimizes the metal scattering and the scattering of the carbon fiber powder at the time of explosion of the container, it is possible to help the explosive force And it is possible to minimize the outflow of the scattered water.

In addition, in the present invention, by applying a shock absorbing member for shock absorption between the controller and the filling chamber, the controller can be reused by reducing the damage of the controller due to the container explosion.

100: Charging chamber
110: Charging case Body
120: Door handle
130: container holder
140: Charging door
150: Door stopper device
160: Horizontal damping plate
170: vertical diaphragm
180: cushion box
190: Handle hinge
200: Slot
210: handle guide roll
220: Compressed air opening and closing valve
230: Valve switch
240: Bar for switch operation
250: Control box
260: Filter box
270: vertical reinforcement plate
280: Bearings
290: Shock absorber for opening and closing
300: vertical reinforcement plate
310: Horizontal stiffening plate
320: Contact stage
330: Pressure stage
340: Hole for connector mounting
350: Door hinge
360: roll receiving groove
10: Door
11: Air respirator
12: Charging
13: Controller
14: Shock absorption barrier
14a: Support
14b: beam member
14c: Plate
15: Cushioning for shock absorption
16: Outlet
17: Non-product collection filter
18: Collecting non-product
19: Unit collection filter
20: buffer member
21: Hinge section
22: container holder
23: Filter support

Claims (15)

A filling body 110 in the form of a box-shaped structure having a filling chamber 100 formed therein and a door handle 120 installed on a front portion of the filling body 110 and being openable and closable, A door 130 is provided in the upper part of the inside of the filling body 110 and the door closing and opening operation is interlocked with the opening of the door handle 130, 140 for clamping or unclamping the door stopper device (150)
It is possible to prevent deformation or breakage of the filling compartment main body including the opening of the door, which is filled with an impact at the time of explosion of the container of the air respirator by the door clamping action of the door stopper device,
The door stopper device 150 includes a stopper frame 150a provided on the side of the charging main body 110 and an up-down lock mechanism 150 installed in a vertical posture at the lower end of the stopper frame 150a and interlocked with the operation of the stopper plate 150b. A shock absorber 150c and a stopper plate 150b connected to and supported by the rod of the up-down shock absorber 150c for selectively engaging or releasing the upper end of the upper end of the charging door 140, And a lock / unlock shock absorber (150d) provided in a horizontal posture at the upper end of the frame (150a) to restrict downward movement of the stopper plate (150b) while hanging the side wall of the stopper plate (150b) Respiratory container safe filling container.
The method according to claim 1,
A cushioning box 160 connected to the lower portion of the filling body 110 and communicating with the filling chamber 100 to dampen the impact by using the horizontal cushioning plate 160 at the upper inflow side and the vertical partition 170 at the mid- (180). ≪ / RTI >
The method according to claim 1,
The door handle 120 is supported on both side walls of the door 140 by a handle hinge 190 so that the door handle 120 is interlocked with the door stopper device 150 through both ends of the door handle 120. [ Features an air respirator container for safe filling.
The method of claim 3,
A handle guide roll 210 for guiding the rotation of the door handle is installed at both ends of the door handle 120 while moving along arc-shaped slots 200 formed on both side walls of the door 140 Wherein said container is a container for air respirators.
The method according to claim 1,
It is possible to turn on / off the valve switch 230 while being in contact with the valve switch 230 of the compressed air opening / closing valve 220 provided on the wall surface side of the filling chamber 110 Wherein a bar for operating the switch (240) is installed.
delete The method according to claim 1,
The stopper plate 150b of the door stopper device 150 is installed on the stopper frame side and the stopper plate side so that the guide bush 150e and the guide bar 150f can be guided in vertical movement Wherein said container is a container for an air respirator.
The method according to claim 1,
The stopper plate 150b of the door stopper device 150 is provided with a stopper roll 150g which is in contact with the front end of the door handle 120 when the door handle 120 is interlocked with the side surface of the side wall. Containers for air respirators that can safely be charged.
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