CN215692998U - Old material recycling system for increasing sulfur capacity - Google Patents

Abstract

The utility model discloses an old material recycling system for increasing sulfur capacity, which comprises a dust removal device, wherein the dust removal device comprises a first agent chamber, a second agent chamber and a third agent chamber, a first agent chamber feed port is formed in the upper end of the first agent chamber, a first agent chamber waste material discharge port is formed in the bottom end of the first agent chamber, a second agent chamber feed port is formed in the upper end of the second agent chamber, a second agent chamber waste material discharge port is formed in the upper end of the second agent chamber, a third agent chamber feed port is formed in the upper end of the third agent chamber, a third agent chamber waste material discharge port is formed in the bottom end of the third agent chamber, a smoke inlet is formed in the first agent chamber, the first agent chamber is communicated with the second agent chamber, the second agent chamber is communicated with the third agent chamber, and a smoke outlet is formed in the third agent chamber. The first agent chamber, the second agent chamber and the third agent chamber are respectively added with sulfur capacity agents with different new and old degrees, so that the old sulfur capacity agents are recycled, the potential of the desulfurizer can be dug up, and the utilization rate of the desulfurizer is greatly improved.

Description

Old material recycling system for increasing sulfur capacity

Technical Field

The utility model relates to the field of flue gas desulfurization, in particular to a used material recycling system for increasing sulfur capacity.

Background

For the conventional calcium-based moving bed full-dry type desulfurization and dust removal system at present, a plurality of desulfurization bins are arranged side by side, and the original flue gas passes through the desulfurizer from the lower part of the desulfurizer bin to the upper part of the desulfurizer bin and is discharged. From the trend of flue gas, it is easy to know that the closer to the flue gas inlet, the higher the utilization rate of the desulfurizer, that is, because the flue gas is fluid, the flue gas is difficult to flow to the position of the desulfurizer far away from the flue gas port, and the utilization rates of the desulfurizer in the desulfurization bins far away from the flue gas inlet are low, so that the utilization rate of the desulfurizer is usually less than 50% after the desulfurizer in the desulfurization bins is discharged, the utilization rate of the desulfurizer is low, and the waste of the desulfurizer is also caused by the direct discharge of the desulfurizer with desulfurization effect.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a system for recycling old materials with increased sulfur capacity, which solves one or more technical problems in the prior art and at least provides a beneficial choice or creation condition.

The technical scheme adopted for solving the technical problems is as follows:

the utility model provides an increase used material recycling system of sulfur capacity, includes dust collector, dust collector includes first dose room, second dose room, third dose room, the upper end of first dose room is provided with first dose room feed inlet, the bottom of first dose room is provided with first dose room exhaust outlet, the upper end of second dose room is provided with second dose room feed inlet, the upper end of second dose room is provided with second dose room exhaust outlet, the upper end of third dose room is provided with third dose room feed inlet, the bottom of third dose room is provided with third dose room exhaust outlet, first dose room is provided with into the mouth, first dose room with second dose room intercommunication, second dose room with third dose room intercommunication, third dose room is provided with out the mouth.

The utility model has the beneficial effects that:

when the device is used, the old sulfur capacity agent, the semi-new sulfur capacity agent and the new sulfur flux are sequentially placed into the first agent chamber, the second agent chamber and the third agent chamber, flue gas passes through the first agent chamber, the second agent chamber and the third agent chamber in sequence to be desulfurized and dedusted, the sulfur concentration of the flue gas passing through the first agent chamber, the second agent chamber and the third agent chamber is reduced in sequence, the old sulfur capacity agent is placed into the first agent chamber to filter, adsorb and deduste the flue gas with high sulfur concentration, the semi-new sulfur capacity agent is placed into the second agent chamber to filter, adsorb, dedust and desulfurize the flue gas with high sulfur concentration, and the new sulfur flux is placed into the third agent chamber to filter, adsorb, dedust and desulfurize the flue gas with low sulfur concentration. After the desulfurizing agent is used for a period of time, the new sulfur flux can be placed into the second agent chamber for use when becoming a semi-new sulfur capacity agent, the semi-new sulfur capacity agent can be placed into the first agent chamber for use when becoming an old sulfur capacity agent, the potential of the desulfurizing agent in different stages is fully exerted, the new sulfur flux has good desulfurizing performance, the semi-new sulfur capacity agent has general desulfurizing performance, and the old sulfur capacity agent does not have the desulfurizing performance but has good filtering and dust removing performance. The potential of the desulfurizer can be dug to the full by recycling the old sulfur capacity agent through sectional feeding, and the utilization rate of the desulfurizer is greatly improved. Macroscopically, the sulfur capacity is increased, the usage amount of the desulfurizer is reduced, and the operation cost is saved.

As a further improvement of the above technical solution, the used material recycling system further includes a first material changing device and a second material changing device, the first material changing device is provided with a first material changing feed end and a first material changing discharge end, the second material changing device is provided with a second material changing feed end and a second material changing discharge end, the first material changing feed end is disposed at the third agent room waste discharge port, the first material changing discharge end is disposed at the second agent room feed port, the second material changing feed end is disposed at the second agent room waste discharge port, and the second material changing discharge end is disposed at the first agent room feed port.

The first material changing device automatically changes the materials in the third agent chamber into semi-new sulfur-containing agents and then puts the materials into the second agent chamber for use; the second reloading device automatically puts the materials which are changed into the old sulfur-containing agent in the second agent chamber into the first agent chamber for use without manual reloading.

As a further improvement of the above technical solution, the first material changing device includes a first belt-type material changing and discharging conveyor, a first bucket elevator, and a first belt-type material changing and feeding conveyor, the first belt-type material changing and discharging conveyor is provided with a first belt-type material changing and discharging end and a first belt-type material changing and feeding end, the first bucket elevator is provided with a first bucket material lifting port and a first bucket material lifting port, the first belt-type material changing and feeding conveyor is provided with a second belt-type material changing and discharging end and a second belt-type material changing and feeding end, the first belt-type material changing and feeding end is arranged at the third agent chamber waste material discharging port, the first belt-type material changing and discharging end is arranged at the first bucket material lifting port, the second belt-type material changing and feeding end is arranged at the first bucket material lifting port, and the second belt-type material changing and feeding end is arranged at the second agent chamber material feeding port;

the second reloading device comprises a second belt reloading discharging conveyor, a second bucket elevator and a second belt reloading feeding conveyor, the second belt reloading discharging conveyor is provided with a third belt reloading discharging end and a third belt reloading feeding end, the second bucket elevator is provided with a second bucket elevator discharging port and a second bucket elevator feeding port, the second belt reloading feeding conveyor is provided with a fourth belt reloading discharging end and a fourth belt reloading feeding end, the third belt reloading feeding end is arranged at a second agent chamber waste discharging port, the third belt reloading discharging end is arranged at the second bucket elevator feeding port, the fourth belt reloading feeding end is arranged at the second bucket elevator feeding port, and the fourth belt reloading feeding end is arranged at the first agent chamber feeding port.

In actual use, the first dose chamber, the second dose chamber and the third dose chamber are large in size, the quantity of old materials to be replaced is large, and the first belt type material changing and discharging conveyor, the first bucket elevator, the first belt type material changing and feeding conveyor, the second belt type material changing and discharging conveyor, the second bucket elevator and the second belt type material changing and feeding conveyor can be used for stably and quickly replacing a large quantity of old materials when the first dose chamber, the second dose chamber and the third dose chamber are large in size.

As a further improvement of the above technical scheme, the used material recycling system further comprises a feeding device, the feeding device comprises a third bucket elevator and a third belt type feeding conveyor, the third bucket elevator is provided with a third bucket elevator discharge hole and a third bucket elevator feed hole, the third belt type feeding conveyor is provided with a third belt type feeding end and a third belt type discharge end, the third belt type feeding end is arranged at the third bucket elevator discharge hole, and a third agent chamber feed hole automatically adds new sulfur flux into a third agent chamber.

As a further improvement of the above technical scheme, the feeding device further comprises a raw material bin and a fourth belt type feeding conveyor, the upper end of the raw material bin is provided with a raw material feeding hole, the lower end of the raw material bin is provided with a raw material discharging hole, the fourth belt type feeding conveyor is provided with a fourth belt type feeding end and a fourth belt type discharging end, the fourth belt type feeding end is arranged at the raw material discharging hole, and the fourth belt type discharging end is arranged at the third hopper lifting feeding hole.

The new sulfur flux is stored in the raw material bin, and can be directly and automatically added in the subsequent process, so that the manual operation is reduced, and the fourth belt type feeding conveyor is convenient to stably and continuously convey the new sulfur flux.

As a further improvement of the above technical scheme, the feeding device further comprises a fourth bucket elevator, a fifth belt type feeding conveyor, the fourth bucket elevator is provided with a fourth bucket elevator discharge port and a fourth bucket elevator feed port, the fifth belt type feeding conveyor is provided with a fifth belt type feeding end and a fifth belt type discharge end, the fifth belt type feeding end is arranged at the fourth bucket elevator discharge port, the fifth belt type discharge end is arranged at the raw material feed port, and new sulfur flux is conveniently added into the raw material bin.

As a further improvement of the above technical solution, the used material recycling system further comprises a discharging device, the discharging device comprises a waste bin, a fifth bucket elevator, a sixth belt type feeding conveyor and a seventh belt type feeding conveyor, the upper end of the waste bin is provided with a waste material feeding port, the upper end of the waste bin is provided with a waste material discharging port, the fifth bucket elevator is provided with a fifth bucket elevator discharging port and a fifth bucket elevator feeding port, the sixth belt type feeding conveyor is provided with a sixth belt type feeding end and a sixth belt type discharging end, the seventh belt type feeding conveyor is provided with a seventh belt type feeding end and a seventh belt type discharging end, the sixth belt type feeding end is arranged at the waste material discharging port of the first dosing chamber, the sixth belt type discharging end is arranged at the feeding port of the fifth bucket elevator, the seventh belt type feeding end is arranged at the discharging port of the fifth bucket elevator, the seventh belt type discharging end is arranged at the waste material feeding port.

The completely used sulfur capacity agent is stored in the waste bin, and the replacement of the used sulfur capacity agent is automatically carried out, so that the manual operation is reduced.

As a further improvement of the technical scheme, a gate valve and a discharge valve are arranged at the waste material outlet of the first dosing chamber and the material inlet of the dosing chamber, so that the desulfurization dosage can be conveniently adjusted.

As a further improvement of the technical scheme, the first agent chamber, the second agent chamber and the third agent chamber are all in cylindrical structures, the diameters of the lower ends of the first agent chamber, the second agent chamber and the third agent chamber are all decreased from top to bottom in sequence, the effect of collecting the desulfurizer is achieved, and unloading is facilitated.

As a further improvement of the technical scheme, the smoke inlet is arranged on the side wall of the lower surface of the first agent chamber, and the smoke outlet is arranged on the side wall of the upper surface of the third agent chamber, so that the contact between the smoke and the desulfurizer is increased, and the desulfurization and dust removal capacity of the desulfurizer is fully exerted.

Drawings

The utility model is further described with reference to the accompanying drawings and examples;

fig. 1 is a schematic structural diagram of an embodiment of the used material recycling system for increasing sulfur capacity according to the present invention, wherein two arrows respectively represent an upward direction and a downward direction.

Detailed Description

Reference will now be made in detail to the present preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to like elements throughout.

In the description of the present invention, it should be understood that the orientation or positional relationship referred to in the description of the orientation, such as the upper, lower, front, rear, left, right, etc., is based on the orientation or positional relationship shown in the drawings, and is only for convenience of description and simplification of description, and does not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention.

In the description of the present invention, if words such as "a plurality" are described, the meaning is one or more, the meaning of a plurality is two or more, more than, less than, more than, etc. are understood as excluding the present number, and more than, less than, etc. are understood as including the present number.

In the description of the present invention, unless otherwise explicitly limited, terms such as arrangement, installation, connection and the like should be understood in a broad sense, and those skilled in the art can reasonably determine the specific meanings of the above terms in the present invention in combination with the specific contents of the technical solutions.

Referring to fig. 1, the old material recycling system for increasing sulfur capacity of the present invention is implemented as follows:

in this embodiment, an old material recycling system for increasing sulfur capacity includes a dust removing device, a first material changing device 210, a second material changing device 220, a feeding device 300, and a discharging device 400.

The feeding device 300 comprises a third bucket elevator 310 and a third belt-type feeding conveyor 320, the third bucket elevator 310 is provided with a third bucket elevator discharge hole and a third bucket elevator feed hole, the third belt-type feeding conveyor 320 is provided with a third belt-type feeding end and a third belt-type discharge end, the third belt-type feeding end is arranged at the third bucket elevator discharge hole, and the third agent chamber feed hole 131 automatically adds new sulfur flux into the third agent chamber 130.

The upper end of former feed bin 330 is provided with the raw materials feed inlet, and the lower extreme of former feed bin 330 is provided with the raw materials discharge gate, and fourth belt feed conveyor 340 is provided with fourth belt feed end and fourth belt discharge end, and the fourth belt feed end sets up in raw materials discharge gate department, and the fourth belt discharge end sets up in third fill lifting feed inlet department.

The new sulfur flux is stored in the raw material bin 330, and can be directly and automatically added later, so that manual operation is reduced, and the fourth belt-type feeding conveyor 340 can stably and continuously convey the new sulfur flux conveniently.

Fourth bucket elevator 350 is provided with fourth bucket elevator discharge gate and fourth bucket elevator feed inlet, and fifth belt feed conveyor 360 is provided with fifth belt feed end and fifth belt discharge end, and the fifth belt feed end sets up in fourth bucket elevator discharge gate department, and the fifth belt discharge end sets up in raw materials feed inlet department, conveniently adds new sulphur flux into raw materials storehouse 330.

The feeding flow of the feeding device 300 in this embodiment is as follows: the new desulfurizer is conveyed to the fourth bucket elevator feed inlet by a forklift, the fourth bucket elevator 350 lifts the new desulfurizer to the height of the raw material feed inlet, the new desulfurizer is conveyed to the raw material bin 330 by the fifth belt type feed conveyor 360, the new desulfurizer in the raw material bin 330 is discharged to the fourth belt type feed conveyor 340 through the raw material discharge outlet, the new desulfurizer is conveyed to the third bucket elevator feed inlet of the third bucket elevator 310 by the fourth belt type feed conveyor 340, the new desulfurizer is lifted to the height of the agent chamber feed inlet 111 of the third agent chamber 130 by the third bucket elevator 310, and then the new desulfurizer is conveyed into the third agent chamber 130 by the third belt type feed conveyor 320. The new desulfurizer is automatically stored in the raw material bin 330, and after the raw material bin 330 is full of the new desulfurizer, the desulfurizer in the third agent chamber 130 can be automatically replaced next time, so that the times of manually adding the new desulfurizer are reduced. The desulfurizer can also be directly and automatically conveyed into the third agent chamber 130, thereby improving the automation degree.

In other embodiments, the feeding device 300 may include only the third bucket elevator 310 and the third belt feeding conveyor 320, and when in use, the new desulfurizing agent is manually or by other means such as a forklift into the third bucket elevator inlet of the third bucket elevator 310, lifted by the third bucket elevator 310 to the height of the agent chamber inlet 111 of the third agent chamber 130, and then conveyed into the third agent chamber 130 by the third belt feeding conveyor 320, so as to be automatically replaced with the new desulfurizing agent.

In other embodiments, the infeed apparatus 300 may include only the third hopper 310, the third belt feed conveyor 320, the raw material bin 330, and the fourth belt feed conveyor 340. At this time, the new desulfurizing agent may be added to the raw material silo 330 by other means, such as manual introduction, or by a single other conveyor.

In this embodiment, the dust removing device includes a first dose chamber 110, a second dose chamber 120, and a third dose chamber 130, the upper end of the first dose chamber 110 is provided with a first dose chamber inlet 111, the bottom end of the first dose chamber 110 is provided with a first dose chamber waste outlet 112, the upper end of the second dose chamber 120 is provided with a second dose chamber inlet 121, the upper end of the second dose chamber 120 is provided with a second dose chamber waste outlet 122, the upper end of the third dose chamber 130 is provided with a third dose chamber inlet 131, the bottom end of the third dose chamber 130 is provided with a third dose chamber waste outlet 132, the first dose chamber 110 is provided with a smoke inlet 115, the first dose chamber 110 is communicated with the second dose chamber 120, the second dose chamber 120 is communicated with the third dose chamber 130, and the third dose chamber 130 is provided with a smoke outlet 116.

In order to facilitate discharging, the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130 are all cylindrical structures, and the diameters of the lower ends of the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130 are all decreased from top to bottom in sequence, so that the desulfurizer is collected, and discharging is facilitated. The smoke inlet 115 is arranged on the side wall of the lower surface of the first agent chamber 110, and the smoke outlet 116 is arranged on the side wall of the upper surface of the third agent chamber 130, so that the contact between the smoke and the desulfurizer is increased, and the desulfurization and dust removal capability of the desulfurizer is fully exerted. In other embodiments, first dose chamber 110, second dose chamber 120, and third dose chamber 130 can have other cylindrical configurations.

The process of desulfurization and dust removal comprises the following steps: old sulfur capacity agents, semi-new sulfur capacity agents and new sulfur fusing agents are sequentially placed into the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130, the smoke passes through the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130 in sequence to be desulfurized and dedusted, the sulfur concentration of the smoke passing through the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130 is reduced in sequence, the old sulfur capacity agents are placed into the first agent chamber 110 to filter, adsorb and deduste the smoke with high sulfur concentration, the semi-new sulfur capacity agents are placed into the second agent chamber 120 to filter, adsorb, dedust and desulfurize the smoke with high sulfur concentration again, and the new sulfur fusing agents are placed into the third agent chamber 130 to filter, adsorb, dedust and desulfurize the smoke with low sulfur concentration. After a period of time, the new sulfur flux in the third agent chamber 130 becomes a semi-new sulfur capacity agent, the semi-new sulfur capacity agent in the second agent chamber 120 becomes an old sulfur capacity agent, at this time, the old sulfur capacity agent in the first agent chamber 110 is discharged, the old sulfur capacity agent in the second agent chamber 120 is placed into the first agent chamber 110, the semi-new sulfur capacity agent in the third agent chamber 130 is placed into the second agent chamber 120, and the new sulfur capacity agent is added into the third agent chamber 130; after the sulfur flux is used for a period of time, the sulfur fluxes in the first agent chamber 110, the second agent chamber 120 and the third agent chamber 130 are adjusted, after the sulfur flux is used for a period of time, the sulfur flux can be placed into the second agent chamber 120 for use when new sulfur flux becomes semi-new sulfur volume agent, the semi-new sulfur volume agent becomes old sulfur volume agent and can be placed into the first agent chamber 110 for use, the potential of the desulfurizer in different stages is fully exerted, the new sulfur flux has good desulfurization performance, the semi-new sulfur volume agent has general desulfurization performance, and the old sulfur volume agent does not have desulfurization performance but has good filtering and dust removing performance. The potential of the desulfurizer can be dug to the full by recycling the old sulfur capacity agent through sectional feeding, and the utilization rate of the desulfurizer is greatly improved. Macroscopically, the sulfur capacity is increased, the usage amount of the desulfurizer is reduced, and the operation cost is saved.

In other embodiments, the replacement of the old sulfur solvent, the semi-new sulfur solvent, and the new sulfur solvent may be performed manually or by other pipeline methods. In the present embodiment, the replacement of various sulfur-containing agents is performed by using the first and second refueling devices 210 and 220.

The first refueling device 210 comprises a first belt-type refueling discharge conveyor 211, a first bucket elevator 212 and a first belt-type refueling feed conveyor 213, the first belt-type refueling discharge conveyor 211 is provided with a first belt-type refueling discharge end and a first belt-type refueling feed end, the first bucket elevator 212 is provided with a first bucket discharge port and a first bucket feed port, the first belt-type refueling feed conveyor 213 is provided with a second belt-type refueling discharge end and a second belt-type refueling feed end, the first belt-type refueling feed end is arranged at the third agent chamber waste discharge port 132, the first belt-type refueling discharge end is arranged at the first bucket feed port, the second belt-type refueling feed end is arranged at the first bucket feed port, and the second belt-type refueling feed end is arranged at the second agent chamber feed port 121;

the second material changing device 220 includes a second belt-type material changing discharging conveyor 221, a second bucket elevator 222, and a second belt-type material changing feeding conveyor 223, the second belt-type material changing discharging conveyor 221 is provided with a third belt-type material changing discharging end and a third belt-type material changing feeding end, the second bucket elevator 222 is provided with a second bucket elevator discharging port and a second bucket elevator feeding port, the second belt-type material changing feeding conveyor 223 is provided with a fourth belt-type material changing discharging end and a fourth belt-type material changing feeding end, the third belt-type material changing feeding end is disposed at the second dosage chamber waste material discharging port 122, the third belt-type material changing discharging end is disposed at the second bucket elevator feeding port, the fourth belt-type material changing feeding end is disposed at the second bucket elevator feeding port, and the fourth belt-type material changing feeding end is disposed at the first dosage chamber feeding port 111.

In practical use, the first dose chamber 110, the second dose chamber 120 and the third dose chamber 130 have large volumes, and the number of the replaced used materials is large, and the first belt-type material-changing and discharging conveyor 211, the first bucket elevator 212, the first belt-type material-changing and feeding conveyor 213, the second belt-type material-changing and discharging conveyor 221, the second bucket elevator 222 and the second belt-type material-changing and feeding conveyor 223 can be adopted to stably and quickly replace a large amount of used materials when the first dose chamber 110, the second dose chamber 120 and the third dose chamber 130 have large volumes. The first material changing device 210 automatically changes the material in the third agent chamber 130 into the material of the semi-new sulfur-containing agent and then puts the material into the second agent chamber 120 for use; the second refueling device 220 automatically puts the material in the second agent chamber 120 which becomes the old sulfur-containing agent into the first agent chamber 110 for use without manual refueling.

The used material recycling system further comprises a discharging device 400, the used material recycling system further comprises the discharging device 400, the discharging device 400 comprises a waste bin 410, a fifth bucket elevator 420, a sixth belt-type feeding conveyor 430 and a seventh belt-type feeding conveyor 440, a waste material feeding port is arranged at the upper end of the waste bin 410, a waste material discharging port is arranged at the upper end of the waste bin 410, a fifth bucket elevator 420 is provided with a fifth bucket elevator discharging port and a fifth bucket elevator feeding port, the sixth belt-type feeding conveyor 430 is provided with a sixth belt-type feeding end and a sixth belt-type discharging end, the seventh belt-type feeding conveyor 440 is provided with a seventh belt-type feeding end and a seventh belt-type discharging end, the sixth belt-type feeding end is arranged at the first dosage chamber waste material discharging port 112, the sixth belt-type discharging end is arranged at the fifth bucket elevator feeding port, the seventh belt-type feeding end is arranged at the fifth bucket elevator discharging port, the seventh belt type discharging end is arranged at the waste material feeding port.

The completely used sulfur capacity agent is stored in the waste bin 410, and the replacement of the used sulfur capacity agent is automatically carried out, so that the manual operation is reduced.

Further, the agent chamber waste material outlet 112 and the agent chamber feed inlet 111 are both provided with a gate valve 500 and a discharge valve 600, so that the desulfurization agent amount can be conveniently adjusted, the discharge valve 600 also adopts a star-shaped discharge valve, and the star-shaped discharge valve can quantitatively and continuously discharge materials.

It should be noted that each bucket elevator and the belt conveyor referred by the present invention are the prior art, and the present invention is not described in detail herein.

While the preferred embodiments of the present invention have been illustrated and described, it will be understood by those skilled in the art that the present invention is not limited to the details of the embodiments shown and described, but is capable of numerous equivalents and substitutions without departing from the spirit of the utility model as set forth in the claims appended hereto.

Claims (10)

1. A used material recycling system for increasing sulfur capacity is characterized by comprising:

the dust removal device comprises a first dose chamber (110), a second dose chamber (120) and a third dose chamber (130), wherein a first dose chamber feed port (111) is formed in the upper end of the first dose chamber (110), a first dose chamber waste discharge port (112) is formed in the bottom end of the first dose chamber (110), a second dose chamber feed port (121) is formed in the upper end of the second dose chamber (120), a second dose chamber waste discharge port (122) is formed in the upper end of the second dose chamber (120), a third dose chamber feed port (131) is formed in the upper end of the third dose chamber (130), a third dose chamber waste discharge port (132) is formed in the bottom end of the third dose chamber (130), a smoke inlet (115) is formed in the first dose chamber (110), the first dose chamber (110) is communicated with the second dose chamber (120), and the second dose chamber (120) is communicated with the third dose chamber (130), the third agent chamber (130) is provided with a smoke outlet (116).

2. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

old material recycling system still includes first device (210) and second device (220) of reloading, first device (210) of reloading is provided with first feed end and the first discharge end of reloading, and second device (220) of reloading is provided with second feed end and the second discharge end of reloading, first feed end of reloading set up in third dose room exhaust opening (132) department, first discharge end of reloading set up in second dose room feed inlet (121) department, second feed end of reloading set up in second dose room exhaust opening (122) department, second discharge end of reloading set up in first dose room feed inlet (111) department.

3. The system for recycling old materials with increased sulfur capacity as claimed in claim 2, wherein:

the first reloading device (210) comprises a first belt reloading discharging conveyor (211), a first bucket elevator (212) and a first belt reloading feeding conveyor (213), the first belt-type material changing and discharging conveyor (211) is provided with a first belt-type material changing and discharging end and a first belt-type material changing and feeding end, the first bucket elevator (212) is provided with a first bucket lifting port and a first bucket lifting port, the first belt-type material-changing feeding conveyor (213) is provided with a second belt-type material-changing discharging end and a second belt-type material-changing feeding end, the first belt-type refuelling feed end is arranged at the third agent room waste discharge opening (132), the first belt-type material changing discharge end is arranged at the first hopper lifting feed opening, the second belt-type material changing feed end is arranged at the first hopper lifting feed opening, and the second belt-type material changing feed end is arranged at the second agent chamber feed opening (121);

the second material changing device (220) comprises a second belt type material changing and discharging conveyor (221), a second bucket elevator (222) and a second belt type material changing and feeding conveyor (223), the second belt type material changing and discharging conveyor (221) is provided with a third belt type material changing and discharging end and a third belt type material changing and feeding end, the second bucket elevator (222) is provided with a second bucket elevator discharge hole and a second bucket elevator feed hole, the second belt type material changing and feeding conveyor (223) is provided with a fourth belt type material changing and discharging end and a fourth belt type material changing and feeding end, the third belt-type refueling feed end is arranged at the second agent chamber waste discharge opening (122), the third belt type material changing discharge end is arranged at the second bucket lifting feed inlet, the fourth belt type material changing feed end is arranged at the second bucket lifting feed inlet, and the fourth belt type material changing feed end is arranged at the first dosing chamber feed inlet (111).

4. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

old material recycling system still includes feed arrangement (300), feed arrangement (300) include third bucket elevator (310), third belt feed conveyor (320), third bucket elevator (310) is provided with third bucket elevator discharge gate and third bucket elevator feed inlet, third belt feed conveyor (320) are provided with third belt feed end and third belt discharge end, third belt feed end set up in third bucket elevator discharge gate department, third agent room feed inlet (131).

5. The system for recycling old materials with increased sulfur capacity as claimed in claim 4, wherein:

feed arrangement (300) still includes former feed bin (330), fourth belt feed conveyor (340), the upper end of former feed bin (330) is provided with the raw materials feed inlet, the lower extreme of former feed bin (330) is provided with the raw materials discharge gate, and fourth belt feed conveyor (340) is provided with fourth belt feed end and fourth belt discharge end, fourth belt feed end set up in raw materials discharge gate department, fourth belt discharge end set up in third fill is carried feed inlet department.

6. The system for recycling old materials with increased sulfur capacity as claimed in claim 5, wherein:

feed arrangement (300) still includes that the fourth fill is carried machine (350), fifth belt feed conveyor (360), fourth fill is carried machine (350) and is provided with the fourth fill and carries the discharge gate and the fourth fill and carry the feed inlet, fifth belt feed conveyor (360) are provided with fifth belt feed end and fifth belt discharge end, fifth belt feed end set up in discharge gate department is carried to the fourth fill, fifth belt discharge end set up in raw materials feed inlet department.

7. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

the used material recycling system further comprises a discharging device (400), the discharging device (400) comprises a waste bin (410), a fifth bucket elevator (420), a sixth belt type feeding conveyor (430) and a seventh belt type feeding conveyor (440), a waste material feeding hole is formed in the upper end of the waste bin (410), a waste material discharging hole is formed in the upper end of the waste bin (410), a fifth bucket elevator discharging hole and a fifth bucket elevator feeding hole are formed in the fifth bucket elevator (420), a sixth belt type feeding end and a sixth belt type discharging end are arranged on the sixth belt type feeding conveyor (430), a seventh belt type feeding end and a seventh belt type discharging end are arranged on the seventh belt type feeding conveyor (440), the sixth belt type feeding end is arranged at the waste material discharging hole (112) of the first dosage chamber, the sixth belt type discharging end is arranged at the fifth bucket elevator feeding hole, the seventh belt feed end is arranged at the fifth bucket lifting outlet, and the seventh belt discharge end is arranged at the waste feed inlet.

8. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

the first agent chamber waste material outlet (112) and the agent chamber feed inlet (111) are provided with a gate valve (500) and a discharge valve (600).

9. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

the first dose chamber (110), the second dose chamber (120) and the third dose chamber (130) are all cylindrical structures, and the diameters of the lower ends of the first dose chamber (110), the second dose chamber (120) and the third dose chamber (130) are sequentially reduced from top to bottom.

10. The system for recycling old materials with increased sulfur capacity as claimed in claim 1, wherein:

the smoke inlet (115) is arranged on the side wall of the lower surface of the first dose chamber (110), and the smoke outlet (116) is arranged on the side wall of the upper surface of the third dose chamber (130).

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