KR102306429B1 - Recycling apparatus for dry chemical powder of fire extinguisher - Google Patents

Abstract

The present invention provides a powder extinguishing agent regeneration device capable of regenerating the powder extinguishing agent used in the powder fire extinguisher. The powder extinguishing agent regeneration device includes a radiating barrel in which the powder extinguishing agent contained in an extinguished extinguisher is stored; an agitator for agitating and drying the powder fire extinguishing agent transferred from the radiating barrel; a separation body for separating and sorting the powdered extinguishing agent dried in the agitator; and a finished product storage in which the powdered extinguishing agent selected from the separation body is stored, wherein the agitator includes a stirring body that accommodates and stirs the powder extinguishing agent; and an air dryer connected to the stirring body and supplying dried air to the inside of the stirring body.

Description

Powder extinguishing agent regeneration device of fire extinguisher

The present invention relates to a powder extinguishing agent regeneration device for a fire extinguisher, and more particularly, to a powder extinguishing agent regeneration device for a fire extinguisher that collects and regenerates a powder extinguishing agent from a waste extinguisher so that it can be reused.

A fire extinguisher is a portable device that cools burning material or shuts off oxygen. Such fire extinguishers may be classified, such as powder fire extinguishers, carbon dioxide fire extinguishers, halon fire extinguishers, and the like. Among them, a powder fire extinguisher is a fire extinguisher commonly used a lot, and is a fire extinguisher that is radiated by pressing a fine powder for fire extinguishing.

After such a powder extinguisher is used for extinguishing a fire, it is necessary to collect the residual powder extinguishing agent remaining in the container of the powder extinguisher for reuse. In addition, in the case of a powder fire extinguisher stored without being used for a long time, the powder fire extinguishing agent may be agglomerated in the container, and in this case, it is necessary to discard the powder fire extinguisher.

These powder fire extinguishing agents must be treated separately as substances that can pollute the surrounding environment or harm the human body. However, it is not easy to process powder extinguishing agents, and there are not many studies that can be recycled.

Republic of Korea Patent Registration No. 10-2041782 (2019.11.01.)

The problem to be solved by the present invention is to provide a powder extinguishing agent regeneration device capable of regenerating the powder extinguishing agent used in the powder fire extinguisher.

A powder extinguishing agent regenerating device according to an embodiment of the present invention includes: a spinning tube in which the powdered extinguishing agent accommodated in the discarded fire extinguisher is stored; agitator for agitating and drying the powder extinguishing agent transferred and supplied from the spinning tube; Powder to be separated and screened from the dry powder fire extinguishing agent in the agitator; and a finished product storage in which the powder extinguishing agent selected from the powder is stored, and the stirrer includes a stirring body in which the powder extinguishing agent is accommodated, and agitating; and an air dryer connected to the stirring body and supplying dried air to the inside of the stirring body.

The air dryer may supply dried air through the upper end of the stirring body.

The stirrer may further include a first discharge pipe disposed on the upper end of the stirring body and through which air of the stirring body is discharged to the outside.

A first air filter for filtering the powder extinguishing agent contained in the stirring body is not discharged to the outside may be installed in the first discharge pipe.

The stirrer may further include one or more first heat sources installed in the stirring body and heating the internal air of the stirring body.

The spinning tube, the spinning body in which the powder extinguishing agent is accommodated; and a second heat source installed inside the radiation body and heating the air of the radiation body in order to prevent the powder fire extinguishing agent from adhering to the inner wall of the radiation body.

The radiation tube may further include a second discharge pipe disposed on the upper end of the radiation body, through which the air of the radiation body is discharged to the outside.

A second air filter for filtering the powder extinguishing agent accommodated in the spinning body is not discharged to the outside may be installed in the second discharge pipe.

According to the present invention, in the process of stirring the powdered extinguishing agent in the agitator, as the air dried in the air dryer is supplied into the agitator, the powdered extinguishing agent is effectively stirred in the agitator and can be recycled.

In addition, by heating the dried air supplied from the air dryer as a heat source, there is an effect that can increase the drying effect of the agitated powder extinguishing agent by increasing the internal temperature of the agitator.

1 is a schematic diagram showing a powder extinguishing agent regenerating device according to an embodiment of the present invention.
2 is a view showing a stirrer of the powder extinguishing agent regenerating device according to an embodiment of the present invention.
Figure 3 is a view showing the radiation tube of the powder extinguishing agent regenerating device according to an embodiment of the present invention.

Hereinafter, specific embodiments for implementing the present invention will be described in detail with reference to the drawings.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, when it is said that a component is 'connected', 'supported', 'connected', 'supplied', 'transferred', or 'contacted' to another component, it is directly connected, supported, connected, It should be understood that supply, delivery, and contact may occur, but other components may exist in between.

The terminology used herein is only used to describe specific embodiments and is not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In addition, in this specification, the expression of the upper side, the lower side, the side, etc. is described with reference to the drawings in the drawings, and it is clarified in advance that if the direction of the object is changed, it may be expressed differently. For the same reason, some components are exaggerated, omitted, or schematically illustrated in the accompanying drawings, and the size of each component does not fully reflect the actual size.

Also, terms including an ordinal number such as 1st, 2nd, etc. may be used to describe various components, but the components are not limited by these terms. These terms are used only for the purpose of distinguishing one component from another.

The meaning of "comprising," as used herein, specifies a particular characteristic, region, integer, step, operation, element and/or component, and other specific characteristic, region, integer, step, operation, element, component, and/or group. It does not exclude the existence or addition of

Figure 1 is a schematic view showing a powder extinguishing agent regenerating device according to an embodiment of the present invention, Figure 2 is a view showing a stirrer of the powder extinguishing agent regenerating device according to an embodiment of the present invention. Figure 3 is a view showing the radiation tube 200 of the powder extinguishing agent regenerating device according to an embodiment of the present invention.

1 to 3, the powder fire extinguishing agent regenerating device 10 according to an embodiment of the present invention will be described. The powder extinguishing agent regenerating device 10 according to the present embodiment is a device for recovering and regenerating the powdered extinguishing agent from the discarded fire extinguisher. This powder extinguishing agent regeneration device 10 includes a stirrer 100 , a spinning barrel 200 , a storage tank 300 , a powder 400 , and a finished product storage 500 .

The agitator 100, the powder fire extinguishing agent collected in the spinning barrel 200 is supplied from the spinning barrel 200, and agitates the supplied powder extinguishing agent. The agitator 100 agitates the powdered extinguishing agent to loosen the agglomeration, and serves to remove moisture contained in the powdered extinguishing agent through the stirring process. To this end, the agitator 100 includes a stirring body 110 , a first discharge pipe 120 , a first heat source 130 , and an air dryer 140 .

The stirring body 110 has a space that can accommodate the powder extinguishing agent therein. A ribbon 111 and a shaft 113 are installed inside the stirring body 110 .

The ribbon 111 moves the powdered extinguishing agent in an upward direction so that the powdered extinguishing agent can be stirred while rotating in the stirring body 110, and falls downward by the load of the powdered extinguishing agent.

The shaft 113 serves as a rotation axis on which the ribbon 111 can rotate.

Therefore, in the stirring body 110, the powder fire extinguishing agent may be dried through rotation, and the powder agglomerated by moisture or the like may be disturbed.

The first discharge pipe 120 is a pipe through which air in the stirring body 110 is discharged. Air dried by the air dryer 140 is supplied to the inside of the stirring body 110 while the powder extinguishing agent is dried, and the air that has passed through the powder extinguishing agent can be discharged to the outside through the first discharge pipe 120. have.

At this time, the first air filter 122 is installed in the first discharge pipe 120 . The first air filter 122 serves to filter the powder fire extinguishing agent from the agitator 100 through the first discharge pipe 120 . Therefore, clean air may be discharged to the outside through the first air filter 122 .

The first heat source 130 is disposed inside the stirring body 110, a plurality may be disposed. The first heat source 130 heats the internal air of the stirring body 110 so that the internal temperature of the agitator 100 has a predetermined temperature range (eg, a temperature range of 40 to 120 degrees).

As such, the internal temperature of the stirring body 110 may be increased by the plurality of first heat sources 130 , thereby increasing drying and stirring efficiency of the powder extinguishing agent.

In this embodiment, the plurality of first heat sources 130 may be disposed on the inner upper end of the stirring body 110, as shown in FIG. In addition, the plurality of first heat sources 130 may be respectively disposed on both sides based on the position where the first exhaust pipe 120 is disposed.

The air dryer 140 supplies dried air to the inside of the stirring body 110 . Dry air supplied to the inside of the stirring body 110 through the air dryer 140 may increase the effect of drying the powdered fire extinguishing agent stirred in the stirring body 110 . The air dryer 140 is disposed adjacent to the stirring body 110 so that the dried air can be supplied from the top of the stirring body 110 .

The air dryer 140 may remove moisture, etc. contained in the air by sucking the surrounding air, and supply the dried air into the stirring body 110 . To this end, the air dryer 140 may remove moisture from the air by using a desiccant, a coolant, and a chemically treated absorbent therein.

For example, the air dryer 140 may be removed by cooling the air using a refrigerator to condense moisture, and then a refrigeration air dryer that supplies dried air may be used.

Alternatively, the air dryer 140 dries compressed air using a moisture adsorbent such as activated alumina, silica gel, or molecular sieve, and dries the air using a heater or steam heat to supply dried air. can

In addition, the air dryer 140 may be a dissolution-type air dryer using a surface absorption method for gradually drying moisture from the surface may be used.

As the air dried in the air dryer 140 continuously flows into the stirring body 110 in this way, the internal pressure of the stirring body 110 may be increased. Accordingly, the internal air of the stirring body 110 may be discharged to the outside through the first discharge pipe 120 to maintain the internal pressure of the stirring body 110 .

Furthermore, as the internal air temperature of the stirring body 110 rises above a predetermined temperature by the first heat source 130 , the air smoothly through the first discharge pipe 120 disposed at the top of the stirring body 110 . may be discharged to the outside.

Of course, in this process, a part of the powder extinguishing agent together with the air may be introduced into the first discharge pipe 120, but cannot be discharged to the outside by the first air filter 122, and the inside of the stirring body 110 again. may remain in

Accordingly, dry air is provided while the powdered extinguishing agent is agitated in the stirring body 110 and falling from the top to the bottom, so that the drying effect of the powdered extinguishing agent can be increased.

The radiation barrel 200 is provided to collect the powder extinguishing agent from the extinguished extinguisher. The radiation tube 200 includes a radiation body 210 , a second discharge pipe 220 , and a second heat source 230 .

The spinning body 210 is stored inside the powder extinguishing agent is collected. The spinning body 210 may have a predetermined space so that the powder fire extinguishing agent can be collected therein.

And the powder extinguishing agent collected in the spinning body 210 may be transferred to the agitator 100 . In the spinning body 210, an injection hole 212 may be formed on at least one surface to collect the powder extinguishing agent.

The injection port 212 is a place where the powder extinguishing agent is injected, and is formed so that the injection port of the fire extinguisher can be inserted into the injection port 212 . In this embodiment, the fire extinguisher collects the powder fire extinguishing agent sprayed from the fire extinguisher through the injection port 212 in the radiation body 210 without separate decomposition.

Accordingly, a plurality of injection holes 212 may be formed in the radiation body 210 . And a cover may be formed on the plurality of injection ports 212 to be opened only when the injection port of the fire extinguisher is plugged.

As described above, when the powder fire extinguishing agent contained in the fire extinguisher is sprayed to the radiation body 210 through the plurality of injection holes 212 formed in the radiation body 210, the spray is sprayed by the pressure of carbon dioxide gas or nitrogen gas contained in the fire extinguisher. The powder fire extinguishing agent may be collected in the spinning body 210 .

However, in some cases, when the fire extinguisher is aged and does not operate normally, the powder fire extinguishing agent may be sprayed after filling the gas from the outside. Alternatively, by separating the valve and cap of the fire extinguisher, the powder fire extinguishing agent accommodated in the fire extinguisher may be accommodated in the radiation body 210 .

In addition, a monitoring window 214 may be formed on at least one surface of the radiation body 210 . The monitoring window 214 is a window through which the user can check the inside of the radiation body 210, and may be made of a material such as glass or quartz. This monitoring window 214 may not be opened as it is used for the purpose of checking the inside of the radiation body 210 from the outside.

The second discharge pipe 220 is disposed on the upper end of the radiation body 210 . The second discharge pipe 220 is provided to adjust the pressure inside the radiation body 210 . When the powder extinguishing agent is discharged from the fire extinguisher, the powder extinguishing agent and a predetermined gas are discharged together, and the pressure inside the spinning body 210 may increase by the gas discharged in this way. Therefore, the air inside the radiation body 210 is discharged through the second discharge pipe 220 , so that the internal pressure of the radiation body 210 may not increase.

And a second air filter 222 may be installed in the second discharge pipe 220 . The powder extinguishing agent collected in the radiation body 210 by the second air filter 222 may not be discharged to the outside through the second discharge pipe 220 .

In addition, a second heat source 230 may be disposed inside the radiation body 210 . A plurality of second heat sources 230 may be installed inside the radiation body 210 , and as shown in FIG. 3 , may be disposed on the inner wall surface of the radiation body 210 .

This second heat source 230 raises the internal temperature of the radiation body 210, and as the internal temperature of the radiation body 210 rises in this way, the powder extinguishing agent is prevented from adhering to the inner wall surface of the radiation body 210 can be

The storage tank 300 is agitated by the agitator 100 and dried powder extinguishing agent is temporarily stored. Since the powder fire extinguishing agent rises to a predetermined temperature while passing through the spinneret 200 and the agitator 100, the storage tank 300 can lower the temperature of the powder extinguishing agent by storing the powder extinguishing agent for a predetermined time.

The powder 400 is to sort and separate the powder fire extinguishing agent, and it is possible to separate the powder extinguishing agent through a pick-up plate for sorting. At this time, the powder 400 may vibrate the slit sorting plate to separate the powdered extinguishing agent from foreign substances, and only the powdered extinguishing agent may be selected.

At this time, the foreign material separated from the powder 400 may be discharged to the outside through a separate path.

The finished product storage 500 stores the powdered extinguishing agent from which foreign substances are removed through the powder 400 .

In this embodiment, regeneration of the powder extinguishing agent is made through the spinneret 200, the agitator 100, the storage tank 300, the powder 400 and the finished product storage 500, and in each section, the powder extinguishing agent is It may be conveyed through a conveying device such as a screw or a conveyor belt. For example, the powder fire extinguishing agent discharged from the spinning tube 200 through the lower end of the spinning tube 200 is transferred to the upper end of the stirrer 100 through a transfer device, and the powder fire extinguishing agent is transferred to the stirrer 100 through the upper end of the stirrer 100 . ) can be supplied internally.

As described above, the detailed description of the present invention has been made by the embodiments with reference to the accompanying drawings, but since the above-described embodiments have only been described with preferred examples of the present invention, the present invention is limited only to the above embodiments. It should not be understood, and the scope of the present invention should be understood as the following claims and their equivalents.

10: Powder extinguishing agent regeneration device
100: agitator
110: stirring body
111: ribbon
113: shaft
120: first discharge pipe
122: first air filter
130: first heat source
140: air dryer
200: radiation barrel
210: radiating body
212: inlet
214: watch window
220: second discharge pipe
222: second air filter
230: second heat source
300: storage tank
400: powder
500: finished product storage

Claims (8)

A fire extinguisher in which the powder extinguishing agent contained in the discarded fire extinguisher is stored;
a stirrer for agitating and drying the powder fire extinguishing agent transferred from the spinning tube;
Powder to be separated and screened from the dry powder fire extinguishing agent in the agitator; and
Includes a finished product storage in which the powder fire extinguishing agent selected from the powder is stored,
The stirrer,
The powder extinguishing agent is accommodated therein, the stirring body to be stirred; and
It is connected to the stirring body and includes an air dryer for supplying dried air to the inside of the stirring body,
The air dryer is a refrigeration-type air dryer that cools air using a refrigerator to condense and remove moisture and then supplies dried air, dry compressed air using a moisture absorbent, and dry the air by using heat It is one of an adsorption type air dryer that supplies air and a dissolution type air dryer that uses a surface absorption method that gradually dries moisture from the surface,
The stirrer,
It is disposed on the upper end of the stirring body, including a first discharge pipe through which the air of the stirring body is discharged to the outside,
A first air filter for filtering the powder extinguishing agent contained in the stirring body is installed in the first discharge pipe so as not to be discharged to the outside,
The stirrer,
It is installed in the interior of the stirring body, comprising at least one first heat source for heating the internal air of the stirring body,
The radiation tube,
The spinning body in which the powder extinguishing agent is accommodated; and
It is installed in the inside of the radiation body, comprising a second heat source for heating the air of the radiation body to prevent the powder fire extinguishing agent from adhering to the inner wall of the radiation body,
Powder extinguishing agent regeneration device. The method according to claim 1,
The air dryer supplies dried air through the upper end of the stirring body,
Powder extinguishing agent regeneration device. delete delete delete delete The method according to claim 1,
The radiation tube,
It is disposed on the upper end of the radiation body, further comprising a second exhaust pipe through which the air of the radiation body is discharged to the outside,
Powder extinguishing agent regeneration device. 8. The method of claim 7,
A second air filter for filtering the powder extinguishing agent contained in the spinning body is installed in the second discharge pipe so as not to be discharged to the outside,
Powder extinguishing agent regeneration device.

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