KR20190058998A - Apparetus combustion ash chamber with anti-scattering ashes switch - Google Patents

Abstract

The present invention relates to an ash chamber device having an anti-scattering switch of ash, and particularly, to an ash chamber device having an anti-scattering switch of ash capable of smoothly processing collected ash, while minimizing damage to peripheral components due to the generation of fine dust in a process in which the ash is collected in an ash chamber in which the ash, generated from a combustion furnace, is collected. According to the present invention, an ash chamber device having an anti-scattering switch of ash comprises: a flow portion (100) connected to a boiler (50) to allow ash (30), incombustible residue generated due to combustion of solid fuel, to flow outwardly from the boiler (50) connected to a combustion furnace (10), in the combustion furnace (10), a space in which the solid fuel is burned; a storage portion (200) detachably disposed in a lower portion of the flow portion (100) and in which the ash (30), which has fallen through the flow portion (100), is stored; and a fluid injection portion (300) formed to be connected from the outside to inside of the flow portion (100), and for cooling and storing the ash (30) while the ash, which has fallen to the storage portion (200), is prevented from being scattered inside the storage portion (200).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an anti-scattering device,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a re-box device having a re-scattering preventive switch, which minimizes the damage of peripheral parts due to generation of fine dust during re- Which is capable of handling a re-shake preventing switch.

In general, municipal waste or industrial waste is mostly disposed of by incineration in landfill or incinerator.

In the incinerator, the fuel is injected into the combustion chamber, and the fuel is combusted after having the combustion condition (Temperature, Turbulence, Time). In the combustion chamber, the spent waste or fuel is flame burned or pyrolyzed Or re-burns unburned gaseous material according to the fuel condition.

The incinerator uses solid waste fuel, which is not only sawdust or wood crumbs but also pelletized waste plastics generated at workplaces or homes, as a fuel. By burning such solid waste fuel to generate heat, boilers and cogeneration And the like have been developed.

Boilers that use solid waste fuel as a fuel are widely used because they do not use diesel / BC oil, which is a greenhouse gas emission source, because they have a low fuel cost and are environmentally friendly. But it is spreading to places such as municipal power generation facilities and cogeneration.

In the case of landfill of municipal waste or industrial waste, there is a large-scale site for disposal of a large amount of waste at a time, landfill cost, and soil environmental problems caused by leachate before stabilization. In the case of incineration, It is possible to dispose municipal wastes within the facility, but it is also necessary to rely on landfill disposal of incineration residues as well as excessive facility costs and the problem of the atmospheric environment due to incineration.

Therefore, in order to solve such problems, it is necessary to reduce the amount of landfill or reduce the amount of incineration. Such household waste is mostly classified at home, so that if household waste and industrial waste reduction efforts are not properly classified, Is difficult to achieve.

Finally, it is necessary to treat municipal waste or industrial waste before landfilling or incineration in landfill or incinerator. However, it is difficult to mechanically treat it and it is classified only by hand and only the landfill or incineration is required. .

Among the fuels, SRF has higher calorific value and lower price than anthracite, making it an alternative fuel for industrial and public institutions and heating fuel. As a result, in recent years, the local governments have been increasingly trying to use the SRF-based heating fuel.

As described above, when the solid waste fuel is burned, the waste and the solid fuel are burned and burned, and a large amount of ash is generated.

However, since the ash generated in this way flows into the re-box and is treated separately, a large amount of ashes is continuously dispersed in the process of flowing the ash from the combustion furnace to the re-box, and the fine dust is blown into the air, .

In addition, as the combustion furnace is incinerated and burnt, a large amount of ash is dispersed continuously in the course of ash flow from the combustion furnace to the rebox, and fine dust is blown in the air, There is a problem that the safety of the operator can not be guaranteed.

In addition, as the ash flows from the combustion furnace to the re-box, the ash is stored in a predetermined position, and the operator has to flatten the laminated material at a certain position from time to time, and additional ash and fine dust are generated in this process.

Patent Document Patent Registration No. 10-1230647

The present invention has been conceived to solve the above problems, and it is an object of the present invention to provide a re-box device provided with a fly ash preventive switch according to the present invention, which can prevent ashes from flowing from a combustion furnace to a re- And an object of the present invention is to provide a re-box device provided with a re-scattering prevention switch.

The reboxing device provided with the ash scattering preventive switch according to the present invention is characterized in that a large amount of ash and fine dust are applied to workers working in the vicinity of the combustion furnace in the process of ashes and combustion of the combustion furnace, Which is capable of shutting off an object to be shaken, and an anti-scattering switch which is capable of shutting off the object.

The re-box device provided with the ash-scattering preventive switch according to the present invention is characterized in that the ash box device for easily stacking and storing the ashes in a predetermined position while the ash flows into the re-box from the combustion furnace, The purpose is to provide.

In the reboxing device provided with the ash scattering preventive switch according to the present invention, ash material 30, which is a non-combustible residue generated in accordance with the combustion of solid fuel, in the combustion furnace 10, (100) connected to the boiler (50) so as to flow out of the boiler (50) connected to the boiler (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

The moving unit 100 includes a plurality of connecting pipes 110 connected to the boiler 50 and a corrugated pipe 110 formed between the connecting pipes 110 to adjust the length of the connecting pipe 110 And a sealing lid 130 which is connected to the connection pipe 110 and closes the upper part of the storage part 200 while sealing the upper part of the storage part 200.

The sealing lid 130 may be formed in a manner such that the material 30 dropped from the connection pipe 110 to the storage unit 200 flows in the storage unit 200 to the lower portion of the storage unit 200 And a step 134 formed at a lower portion of the sealing lid 130 to seal the upper edge of the storage unit 200 and seal the upper edge of the storage unit 200.

The fluid injecting unit 300 includes a cooler 310 connected to the inside of the moving unit 100 to minimize the scattering of the ashing 30 while spraying fluid to the ashing material 30, A planarizer (300) connected to the inside of the flow unit (100) and disposed at an adjacent position of the cooler (310) for spraying compressed air so as to flatten the material (30) 320).

The cooler 310 includes a cooling reservoir 312 disposed on the outer surface of the sealing lid 130 and storing the cooling water 311 to be sprayed to the ash 30, And a cooling nozzle 314 which penetrates the inside of the sealing lid 130 and discharges the cooling water 311 supplied from the cooling storage tank 312 to the ash 30.

The planarizer 320 is disposed on the outer surface of the sealing lid 130 in parallel with the cooler 310 and is provided with an air supply unit (not shown) capable of supplying compressed air to the material 30 dropped on the storage unit 200 And the air supply unit 322 is connected to the air supply unit 322. The compressed air supplied through the air supply unit 322 is dropped into the storage unit 200, And an air nozzle 324 that is sprayed onto the substrate 30 to allow the material 30 to be laminated flat.

The lid portion 100 may be configured such that the sealing lid 130 is separated from the storage portion 200 while the bellows pipe 120 is compressed and the sealing lid 130 is detached from the storage portion 200 It is possible to seal the upper portion.

The flow unit 100 includes a rotary valve 120 disposed below the bell pipe 120 and rotating while being rotated within the connection pipe 110 to control the flow and flow speed of the ash 30 flowing into the connection pipe 110, (140).

The storage unit 200 includes a storage body 210 through which the material 30 that has passed through the fluid unit 100 is dropped and stored, a bottom plate 220 that forms a bottom surface of the storage body 210, A load cell 230 connected to the bottom plate 220 for measuring the weight of the material 30 dropped on the bottom plate 220 and stacked thereon, A display 240 disposed on the moving part 100 so as to be able to confirm the movement of the storage body 210 and a supporting body 250 disposed on the lower part of the moving part 100, ).

The storage unit 200 is formed at a lower portion of the storage body 210 in a longitudinal direction of the storage body 210 to receive the storage body 210 from a fork 70 of the forklift, A fork hole 260 protruding in the longitudinal direction of the support body 250 on the inner bottom surface of the support body 250 to allow the body 210 to be separated and moved from the support body 250, A sliding protrusion 252 formed at a lower portion of the storage body 210 and connected to the sliding protrusion 252 for sliding the storage body 210, 212).

The storage body 210 may be detached from the support body 250 to prevent the storage body 210 from being scattered when the storage body 210 is moved. And a sealing film 270 closing the upper portion of the sealing film 270.

The reboxing device provided with the ash-scattering preventing switch according to the present invention prevents the ashes from flowing from the combustion furnace to the re-box or prevents the fine dust from being blown into the air, There is a technical effect that the ash can be processed.

The reboxing device provided with the ash scattering preventive switch according to the present invention blocks a large amount of ash and fine dust from being applied to an operator working in the vicinity of the combustion furnace in the process of flowing ashes from the combustion furnace to the rebox, And a safety effect that can prevent lung disease.

The re-box device provided with the ash-scattering preventing switch according to the present invention has a technical effect that the ash can be easily flattened while the ash flows into the re-box from the combustion furnace, thereby improving the production efficiency.

1 is a view showing a re-boxing apparatus provided with a re-scattering preventive switch according to the present invention.
Fig. 2 is a view showing a side cross-section according to Fig. 1. Fig.
Fig. 3 is a view showing a front section according to Fig. 1. Fig.
Fig. 4 is a view showing the use state according to Fig. 1. Fig.
5 is a view showing an embodiment of a re-boxing device provided with a re-scattering preventive switch according to the present invention. Below the crease
6 is a view showing the use state of Fig.
7 is a view showing another embodiment of the re-boxing device provided with the anti-scattering shutoff device according to the present invention. Sprinkling guide plate
8 is a view showing still another embodiment of the re-boxing device provided with the anti-scattering shutoff device according to the present invention. Planarization pneumatic
9 is a view showing another embodiment of the re-boxing device provided with the anti-scattering agent according to the present invention. Mobile sealing membrane
10 is a view showing the embodiment of Fig.
11 is a view showing still another embodiment of a re-boxing device provided with a re-scattering preventive switch according to the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with one embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views, and length and area, thickness, and the like may be exaggerated for convenience.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

In the following detailed description, for example, the shattering of the ash that minimizes the damage of the peripheral parts due to the generation of fine dust in the process of re-assembling the ash collected from the combustion furnace, It is needless to say that the technical arrangement of the reboxing device (in particular, the moving part and the fluid jetting part) having the opening and closing device can be equally applied.

1 is a view showing a re-boxing apparatus provided with a re-scattering preventive switch according to the present invention.

Fig. 2 is a side view according to Fig. 1; Fig.

Fig. 3 is a view showing a front section according to Fig. 1. Fig.

Fig. 4 is a view showing the use state according to Fig. 1. Fig.

1 to 4, the reboxing device having the ash-scattering preventing switch according to the present invention is a non-combustible residue generated in the combustion furnace 10, which is a space in which the solid fuel is burnt, (100) connected to the boiler (50) so that the ash (30) flows outwardly from the boiler (50) connected to the combustion furnace (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

The flow unit 100 serves to flow the ash 30 generated from the combustion furnace 10 and the boiler 50 to the storage unit 200. For this purpose, 50 and the storage unit 200 are interconnected.

The moving unit 100 includes a plurality of connecting pipes 110 connected to the boiler 50 and a connecting pipe 110 formed between the connecting pipes 110 to adjust the length of the connecting pipe 110 And a sealing lid 130 which is connected to the connection pipe 110 and covers the upper portion of the storage unit 200 while sealing the upper portion of the storage unit 200.

The connecting pipe 110 connects the boiler 50 and the sealing lid 130 to each other so that the material 30 flowing through the boiler 50 passes through the sealing lid 130, And thus can be stored.

At this time, a plurality of the connection pipes 110 may be arranged, and a plurality of the connection pipes 110 may be arranged in parallel with each other while connecting the boiler 50 and the sealing lid 130 at different positions.

The corrugated pipe 120 is disposed in each of the connection pipes 110.

The bellows pipe 120 can be compressed or expanded, and the entire length of the connection pipe 110 can be adjusted through compression or expansion.

The details and embodiments of the corrugated tube 120 will be described in more detail below.

The storage unit 200 is detachably disposed below the fluid unit 100 so that the materials 30 falling through the fluid unit 100 can be collected and stored, When the ash 30 is piled up by the set amount of the ashes 30, the ashes 30 are easily transported to the outside.

The storage unit 200 includes a storage body 210 in which the material 30 that has passed through the fluid unit 100 is dropped and stored and a bottom plate And a load cell 230 connected to the bottom plate 220 and measuring the weight of the material 30 dropped on the bottom plate 220 and stacked.

In addition, the storage unit 200 includes a display 240 disposed on the moving unit 100 so as to receive data information of the load cell 230 and to externally confirm the data, And a support body 250 fixedly formed to surround and support the storage body 210.

Here, the storage body 210 is disposed while being supported by the support body 250 with its top opened.

The support body 250 is horizontally opened to allow the storage body 210 to be drawn out of the support body 250 through the open portion of the wall surface, .

At this time, when the storage body 210 is inserted into the support body 250, the storage body 210 is supported by the support body 250.

When the storage body 210 is supported by the support body 250 in a state of being drawn into the support body 250, the upper portion opened by the seal lid 130 is kept in a sealed state .

The material 30 flowing through the connecting pipe 110 from the boiler 50 in a state in which the upper part of the storage body 210 opened by the sealing lid 130 is hermetically sealed is formed in the storage body 210, As shown in FIG.

The load cell 230 formed on the bottom of the bottom plate 220 forming the bottom of the storage body 210 measures the weight of the material 30 dropped on the bottom plate 220 to be stacked And the like.

The amount of the material 30 dropped onto the bottom plate 220 through the load cell 230 is received by the load cell 230 so that the amount of the material 30 accumulated on the bottom plate 220 Can be externally visible through the display 240, which is located on the display 130.

That is, the load cell 230 measures the amount of the material 30 dropped on the bottom plate 220 to measure the amount of the material 30 stacked in the storage body 210, 240 to the outside.

In one embodiment, the load cell 230 identifies data on the amount of the material 30 to be stacked on the storage body 210, and then transmits the accumulated data to the load cell 230 through a transceiver (not shown) 30 to the display 240 disposed on the sealing lid 130 and the amount of the material 30 inside the storage body 210 can be easily confirmed from the outside through the display 240 will be.

The amount of the material 30 stacked inside the storage body 210 is checked from the outside through the display 240 through the load cell 230. However, It is natural that a variety of configurations can be used.

The sealing lid 130 may be configured such that the material 30 dropped from the connection pipe 110 to the storage 200 flows into the storage 200 through the lower portion of the storage 200, And a step 134 formed at a lower portion of the sealing lid 130 and enclosing the upper edge of the storage part 200 and sealing the upper edge of the storage part 200.

That is, the sealing lid 130 seals the opened top of the storage body 210 while pressing the upper edge of the storage body 210 of the storage unit 200.

After the step 134 of the sealing lid 130 seals the open upper part of the storage body 210, the ash 30 of the boiler 50 passes through the connection pipe 110 to the storage body 210, .

The material 30 that is scattered in the storage body 210 during the inflow of the material 30 of the boiler 50 into the storage body 210 through the connection pipe 110 is formed at an inclination angle And is guided to fall on the bottom plate 220 of the storage body 210 while hitting the inclined surface 132 of the sealing lid 130.

Particularly, the flow unit 100 controls the flow and flow speed of the ash 30 that is disposed in the connection pipe 110 under the bell pipe 120 and flows into the connection pipe 110, And a rotary 140 for rotating the rotary shaft.

The rotary 140 is installed in the coupling pipe 110 and is connected to the connection pipe 110 extending below the bell pipe 120 and flows from the boiler 50 to the storage body 210, Thereby controlling the amount and flow rate of the ash 30.

That is, when the amount of the material 30 flowing from the boiler 50 to the storage body 210 is larger than the predetermined amount, the rotation of the rotary 140 is stopped and the connection pipe 110 is closed.

In order to control the flow speed of the material 30 flowing from the boiler 50 to the storage body 210, the rotation of the rotary 140 may be rotated faster or later than the predetermined rotation speed.

As a result, the rotary 140 supplies the material 30 flowing from the boiler 50 to the storage body 210 to be supplied to the storage body 210 in a fixed amount, 30) can be smoothly performed.

When the combustion chamber 10 and the boiler 50 are stopped or the storage body 210 is separated from the sealing lid 130 at the upper portion or the lower portion of the rotary 140, (Not shown) and a night gate (not shown) that can temporarily stop the material 30 from flowing into the storage unit 200. [

The shear slide (not shown) and the night gate (not shown) may be disposed at the upper or lower portion of the rotary 140 to temporarily close the moving unit 100 to temporarily hold the material 30 of the moving unit 100, When the combustion furnace 10 and the boiler 50 are operated again after completion of the maintenance, the front slide (not shown) and the night gate (not shown) The fluid unit 100 can be easily opened to allow the material 30 of the fluid unit 100 to flow to the storage unit 200 again.

The sealing lid 130 is separated from the storage body 210 and temporarily closes the moving part 100 through the front slide (not shown) and the night gate (not shown) It is possible to minimize the occurrence of condensation in the flow portion 100 or the corrosion due to the condensation.

Particularly, the connection pipe 110 and the bellows pipe 120 of the fluid unit 100 may be connected to each other by a flange (not shown).

Also, the bellows pipe 120 and the rotary 140 may be connected to each other by a flange (not shown).

In addition, the rotary 140 and the sealing lid 130 may be connected to each other by a flange (not shown).

The flange is used to facilitate the connection and separation of the connection pipe 110, the corrugated pipe 120, the rotary 140, and the sealing lid 130 during replacement and maintenance.

The fluid injecting unit 300 may cool the material 30 flowing from the boiler 50 to the storage body 210 and cool the material 30 stacked on the bottom plate 220 of the storage body 210 (30) is stacked on the lower part of the storage body (210) in a planarized manner while preventing the material (30) from being stacked in a deflected manner.

The fluid injecting unit 300 may include a cooler connected to the inside of the fluid flow unit 100 to minimize the scattering of the fluid 30 by spraying fluid to the fluid flow 30, 310).

The fluid injecting unit 300 includes a material 30 connected to the inside of the fluid flow unit 100 and disposed adjacent to the cooler 310 to be stacked on the storage unit 200 And a planarizer 320 for injecting compressed air so as to be flattened.

Here, the cooler 310 functions to cool the material 30 falling from the boiler 50 to the storage body 210.

In addition, the planarizer 320 may prevent the material 30 falling on the storage body 210 from being stacked in a deflected manner and to prevent the material 30 from being flatly deposited on the storage body 210 So that it can be stacked on the bottom plate 220.

The details of the cooler 310 and the planarizer 320 will be described in more detail below.

5 is a view showing an embodiment of a re-boxing device provided with a re-scattering preventive switch according to the present invention.

6 is a view showing the use state of Fig.

5 and 6, the reboxing device having the ash-scattering-preventing switch according to the present invention is characterized in that, in the combustion furnace 10 in which the solid fuel is combusted, the solid fuel (100) connected to the boiler (50) so as to flow outward from the boiler (50) connected to the combustion furnace (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

As described above, the moving unit 100 includes a plurality of connecting pipes 110 connected to the boiler 50, and a plurality of connecting pipes 110 formed between the connecting pipes 110, And a sealing lid 130 which is connected to the connection pipe 110 and covers the upper portion of the storage unit 200 while sealing the upper surface of the storage unit 200.

The sealing lid 130 may be formed in a manner such that the material 30 dropped from the connection pipe 110 to the storage unit 200 flows in the storage unit 200 to the lower portion of the storage unit 200 And a step 134 formed at a lower portion of the sealing lid 130 to seal the upper edge of the storage unit 200 and seal the upper edge of the storage unit 200.

The storage unit 200 includes a storage body 210 in which the material 30 that has passed through the fluid unit 100 is dropped and stored and a storage body 210 disposed at a lower portion of the fluid unit 100, 210 and a support body 250 fixedly formed so as to be supported and disposed.

 A plurality of the connecting pipes 110 may be arranged and a plurality of the connecting pipes 110 may be arranged in parallel with each other while connecting the boiler 50 and the sealing lid 130 at different positions.

The corrugated pipe 120 is disposed in each of the connection pipes 110.

The bellows pipe 120 can be compressed or expanded, and the entire length of the connection pipe 110 can be adjusted through compression or expansion.

(Not shown) connected to the lower portion of the outside of the bellows pipe 120, a motor (not shown) rotated in both directions to rotate the pinion in a bidirectional manner, The corrugated tube 120 can be compressed or expanded through the power of the compressor.

It should be understood that various configurations such as a worm gear, a pulley and a belt can be used if the corrugated tube 120 can be compressed or expanded.

In another embodiment, the corrugated tube 120 may be compressed or inflated by the user's pressure.

The lid 100 is compressed so that the lid 130 is separated from the storage 200 while the lid 120 is compressed and the lid 130 is expanded from the storage 200 Can be closed.

In one embodiment, when the storage body 210 is supported in the support body 250, the corrugated tube 120 is expanded and the overall length of the connection tube 110 is increased.

When the total length of the connection pipe 110 becomes longer as the bellows pipe 120 expands, the step 134 of the sealing lid 130 moves the upper rim of the storage body 210 upward And the upper part of the storage body 210 is closed while being pressurized.

In the state that the sealing lid 130 closes the upper portion of the storage body 210, the ash 30 can be introduced into the storage body 210 through the connection pipe 110.

At this time, the ash 30 flows into the storage body 210 and the ash 30 is scattered. The material 30 scattered upward in the storage body 210 has an inclination angle And collide with the inclined surface 132 and are stacked on the lower part of the storage body 210.

That is, since the inclined surface 132 forms an inclination angle, the material 30 to be scattered is caused to collide with the inclined surface 132, and then is guided to fall down to the lower portion of the storage body 210.

When the ash 30 is stacked within the storage body 210 by the user's predetermined amount, the bellows tube 120 is compressed and the sealing lid 130 is separated from the storage body 210.

That is, when the bellows pipe 120 is compressed, the entire length of the connection pipe 110 is shortened so that the sealing lid 130 is also lifted and lowered so that the step 134 is separated from the upper edge of the storage body 210 .

When the sealing lid 130 is separated from the storage body 210 while the step 134 is separated from the upper edge of the storage body 210, (Not shown).

As a result, the ash 30 of the storage body 210 can be drawn out of the support body 250 to treat the ashes 30 from the outside.

7 is a view showing another embodiment of the re-boxing device provided with the anti-scattering shutoff device according to the present invention.

8 is a view showing still another embodiment of the re-boxing device provided with the anti-scattering shutoff device according to the present invention.

7 and 8, the re-box device having the ash-scattering-preventing switch according to the present invention, in the combustion furnace 10, in which the solid fuel is combusted, (100) connected to the boiler (50) so as to flow outward from the boiler (50) connected to the combustion furnace (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

The fluid injecting unit 300 includes a cooler 310 connected to the inside of the moving unit 100 to minimize the scattering of the ashing 30 while spraying fluid to the ashing material 30, A planarizer (300) connected to the inside of the flow unit (100) and disposed at an adjacent position of the cooler (310) for spraying compressed air so as to flatten the material (30) 320).

The cooler 310 injects the coolant 311 into the storage body 210 through the connection pipe 110 and injects the coolant 311 into the storage body 210, Thereby cooling the heat exchanger.

The cooler 310 injects the cooling water 311 instantaneously when the ash 30 flows into the storage body 210 so that the ash 30 contains water to increase the mass so that the ash 30 smoothly flows To be stacked inside the storage body 210.

The cooler 310 includes a cooling reservoir 312 disposed on the outer surface of the sealing lid 130 and storing the cooling water 311 to be sprayed onto the ash 30, And a cooling nozzle 314 which is connected to the sealing lid 130 and penetrates into the sealing lid 130 and discharges the cooling water 311 supplied from the cooling storage tank 312 to the ash 30.

The cooling storage tank 312 of the cooler 310 is disposed on the outer surface of the sealing lid 130 while serving to store the cooling water 311.

The cooling nozzle 314 is connected to the cooling reservoir 312 and is disposed inside the sealing lid 130 through the sealing lid 130 to introduce the cooling water 311 into the storage body 210 To the material 30 to be sprayed.

The planarizer 320 is disposed on the outer surface of the sealing lid 130 in parallel with the cooler 310 and is provided with air which can supply the compressed air to the material 30 dropped on the storage unit 200 And may include a feeder 322.

The planarizer 320 is connected to the air supplier 322 and penetrates the inside of the closing lid 130 so that the compressed air supplied from the air supplier 322 is dropped into the storage unit 200 And an air nozzle 324 for spraying the laminated material 30 to allow the material 30 to be laminated flat.

 The planarizer 320 may be configured such that the material 30 flowing into the storage body 210 from the connection pipe 110 flows into the storage body 210 while being cooled by the cooler 310, 210, the compressed air is injected into the material 30, which is stacked in a deflected manner through the air nozzle 324, so that the material 30 is flattened.

For this purpose, the air supplier 322 is disposed on the outer surface of the sealing lid 130 while generating compressed air and supplying compressed air to the air nozzle 324.

The air nozzle 324 is disposed inside the sealing lid 130 through the sealing lid 130 while being connected to the air supplier 322 so that compressed air is accumulated in the storage body 210, So that the material 30 is sprayed onto the material 30 to allow the material 30 to be stacked flat inside the storage body 210.

As a result, the material 30 introduced into the storage body 210 through the coupling pipe 110 is cooled and flattened through the cooler 310 and the planarizer 320 will be.

9 is a view showing another embodiment of the re-boxing device provided with the anti-scattering agent according to the present invention.

10 is a view showing the embodiment of Fig.

9 and 10, the re-box device having the ash-scattering-preventing switch according to the present invention, in the combustion furnace 10 in which the solid fuel is combusted, (100) connected to the boiler (50) so as to flow outward from the boiler (50) connected to the combustion furnace (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

The storage body 210 may be detached from the support body 250 to prevent scattering of the material 30 stacked inside the storage body 210 during the movement of the storage body 210. [ And a sealing film 270 closing the upper portion of the storage body 210.

The user can confirm the stacked amount of the material 30 in the storage body 210 through the display 240 from outside when the material 30 is stacked within the storage body 210 by a predetermined amount.

When the ash 30 is stacked within the storage body 210 by the user's predetermined amount, the sealing lid 130, which is hermetically sealed at the upper portion of the storage body 210, 210).

When the sealing lid 130 is separated from the storage body 210, the storage body 210 is taken out from the inside of the support body 250.

At this time, the material 30 inside the storage body 210 may be scattered to the outside. To prevent this, the open upper part of the storage body 210 is closed by the sealing film 270.

When the storage body 210 is detached from the support body 250, the sealing body 270 may be folded on the upper side of the storage body 210. When the storage body 210 is separated from the support body 250, Thereby closing the open upper portion of the cover 210.

As long as the sealing film 270 can securely close the upper portion of the storage body 210, various materials having heat resistance such as synthetic resin and vinyl can be used.

11 is a view showing still another embodiment of a re-boxing device provided with a re-scattering preventive switch according to the present invention.

Referring to FIG. 1 to FIG. 4, the reboxing device provided with the anti-fogging anti-scattering agent according to the present invention is characterized in that, in the combustion furnace 10 in which the solid fuel is combusted, (100) connected to the boiler (50) so that the ash non-combustible residue (30) generated thereby flows outwardly from the boiler (50) connected to the combustion furnace (10); A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And a fluid ejecting part (300) connected to the inside of the moving part (100) so as to be cooled and stored while being prevented from being scattered in the storage part (200) (300).

In one embodiment, when the ash 30 is stacked within the storage body 210 by a predetermined amount of the user, the user confirms the stacked amount of the ashes 30 in the storage body 210 from the outside through the display 240 .

When the ash 30 is stacked within the storage body 210 by the user's predetermined amount, the sealing lid 130, which is hermetically sealed at the upper portion of the storage body 210, 210).

When the sealing lid 130 is separated from the storage body 210, the storage body 210 is taken out from the inside of the support body 250.

At this time, the storage body 210 can be taken out from the inside of the support body 250 using a forklift.

The storage unit 200 is formed at a lower portion of the storage body 210 in the longitudinal direction of the storage body 210 and is inserted into the fork 70 of the forklift. And a fork hole 260 through which the storage body 210 can be removed and moved from the support body 250.

That is, when the fork 70 of the forklift enters the fork hole 260 of the storage body 210 and then pulls it up or draws the storage body 210, the storage body 210 slides on the support body 250, So that it can be taken out to the outside of the support body 250.

The fork 70 of the forklift may be inserted into the body of the storage body 210 when the storage body 210 is further drawn into the support body 250 after the ash 30 inside the storage body 210 is treated from the outside, The storage body 210 is inserted into the fork hole 260 of the support body 210 and then the storage body 210 is pushed into the support body 250 so that the storage body 210 can be seated inside the support body 250.

The storage body 210 may slide while being pushed from the inner bottom surface of the support body 250. The storage body 210 may be slidably inserted into the storage body 200 so that the storage body 210 can slide smoothly inside the support body 250. [ A sliding protrusion 252 protruding in the longitudinal direction of the supporting body 250 on the lower surface of the supporting body 250 and connected to the lower portion of the storage body 210, And a sliding groove 212 formed at a lower portion of the body 210 to allow the storage body 210 to be slid while being connected to the sliding protrusion 252.

As a result, the sliding groove 212 of the lower part of the storage body 210 is slid while being connected to the sliding protrusion 252 of the supporting body 250, so that the storage body 210 is moved from the outside to the inside of the supporting body 250 It can be pulled in or taken out from the inside to the outside.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is to be understood that the invention may be embodied in many other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

10: combustion furnace 30: ash
50: boiler 70: fork
100: flow section 110: connection tube
120: corrugated tube 130: sealing lid
132: slope 134:
140: Rotary
200: storage part 210: support body
212: sliding groove 220: bottom plate
230: Load cell 240: Display
250: Support body 252: Sliding projection
260: fork hole 270: sealing film
300: fluid dispensing part 310: cooler
311: Cooling water 312: Cooling storage tank
314: Cooling nozzle 320: Planarizer
322: air feeder 324: air nozzle

Claims (11)

The boiler 50 is arranged in the combustion furnace 10 in which the solid fuel is combusted so that the ashless residue 30 which is generated as a result of the combustion of the solid fuel flows out of the boiler 50 connected to the combustion furnace 10, A moving unit 100 connected to the driving unit 100;
A storage unit 200 detachably installed at a lower portion of the fluid unit 100 to collect and store the materials 30 dropped through the fluid unit 100; And
A fluid injecting unit (not shown) which is connected to the inside of the moving unit 100 to cool the material 30 while being prevented from being scattered in the storing unit 200 while being dropped into the storing unit 200, 300), wherein the re-scattering preventing switch is provided.
The method according to claim 1,
The moving unit (100)
A plurality of connecting pipes 110 connected to the boiler 50,
A corrugated pipe 120 formed between the connection pipes 110 and capable of adjusting the length of the connection pipe 110,
And a closure cap (130) which is connected to the connection pipe (110) and covers the upper part of the storage unit (200) while sealing the closure cap (130).
3. The method of claim 2,
The sealing lid (130)
An inclined surface 132 for guiding the material 30 falling from the connection pipe 110 to the storage unit 200 to flow to the lower portion of the storage unit 200 in the storage unit 200,
And a step (134) formed at a lower portion of the sealing lid (130) to enclose the upper edge of the storage unit (200) and to seal the upper edge of the storage unit (200).
3. The method of claim 2,
The fluid injector (300)
A cooler 310 connected to the inside of the moving unit 100 to minimize the scattering of the ashing 30 while spraying fluid to the ashing material 30,
A planarizer 320 connected to the inside of the flow unit 100 and disposed inside the cooler 310 for spraying the compressed air so as to flatten the material 30 stacked on the storage unit 200, And an anti-fraying shut-off device comprising a non-fraying anti-scattering switch.
5. The method of claim 4,
The cooler (310)
A cooling storage tank 312 disposed on the outer surface of the sealing lid 130 and storing the cooling water 311 to be sprayed on the ash 30,
And a cooling nozzle 314 which is connected to the cooling reservoir 312 and penetrates the inside of the sealing lid 130 and discharges cooling water 311 supplied from the cooling storage tank 312 to the ash 30, A re-box device having a re-arcing prevention switch.
5. The method of claim 4,
The planarizer (320)
An air supplier 322 disposed on the outer surface of the sealing lid 130 in parallel to the cooler 310 and capable of supplying compressed air to the material 30 dropped in the storage unit 200,
The compressed air supplied through the air supply unit 322 is dropped into the storage unit 200 and falls into the stacked material 30 while being connected to the air supply unit 322, And an air nozzle (324) for spraying the material (30) and flattening the material (30).
3. The method of claim 2,
The moving unit (100)
The bellows tube 120 is compressed and the sealing lid 130 is separated from the storage part 200 so that the sealing lid 130 is expanded while sealing the upper part of the storage part 200. [ Box device in which the ash-scattering preventing switch is provided.
3. The method of claim 2,
The moving unit (100)
Further comprising a rotary (140) disposed below the bell tube (120) to rotate and control the flow and flow rate of the ash (30) disposed within the connection tube (110) A re-box device having a scatter-proof switch.
The method according to claim 1,
The storage unit (200)
A storage body 210 in which the material 30 passing through the fluid unit 100 is dropped and stored,
A bottom plate 220 forming a bottom surface of the storage body 210,
A load cell 230 connected to the bottom plate 220 to measure the weight of the material 30 to be dropped on the bottom plate 220,
A display 240 disposed on the moving unit 100 so as to receive data information of the load cell 230 and to externally confirm the data,
And a support body (250) disposed at a lower portion of the moving part (100) and fixed to the support body (210) so as to surround and support the storage body (210).
10. The method of claim 9,
The storage unit (200)
The storage body 210 is inserted into the storage body 210 in the longitudinal direction of the storage body 210 at the lower part of the storage body 210 to receive the storage body 210 from the fork 70 of the forklift, A fork hole 260 for allowing the handle to be removed and moved away from the fork hole 250,
A sliding protrusion 252 protruding in the longitudinal direction of the support body 250 at the lower surface of the support body 250 and connected to the lower portion of the storage body 210,
And a sliding groove 212 formed at a lower portion of the storage body 210 to allow the storage body 210 to slide while being connected to the sliding protrusion 252. [ Device.
11. The method of claim 10,
The storage body (210)
The storage body 210 may be separated from the support body 250 to prevent the accumulated material 30 from being scattered when the storage body 210 is moved. (270). ≪ / RTI >

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