CN113480207A

CN113480207A - Building gypsum regeneration method

Info

Publication number: CN113480207A
Application number: CN202110876376.9A
Authority: CN
Inventors: 不公告发明人
Original assignee: Heilongjiang Qianfu Construction Machinery Equipment Co ltd
Current assignee: Heilongjiang Qianfu Construction Machinery Equipment Co ltd
Priority date: 2021-07-29
Filing date: 2021-07-29
Publication date: 2021-10-08

Abstract

The invention relates to the field of building gypsum regeneration, and discloses a building gypsum regeneration method, which uses building gypsum regeneration equipment, wherein the building gypsum regeneration equipment comprises a processing box body, the processing box body is divided into an upper box body and a lower box body, the top end of the upper box body is provided with a first feeding hole, the side surface of the lower box body is provided with a first discharging hole and a first discharging hole, the first feeding hole is connected with a first feeding pipeline, the other end of the first feeding pipeline is connected with a pretreatment component, the pre-lower box body is provided with a filter pressing component, the bottom of the lower box body is provided with a collection and discharge component, and the collection and discharge component corresponds to the filter pressing component in position, so that the building gypsum can be recycled, and the environmental pollution caused by improper treatment of gypsum in a large amount of building garbage is avoided.

Description

Building gypsum regeneration method

Technical Field

The invention relates to the field of building gypsum regeneration, in particular to a building gypsum regeneration method.

Background

The recovery of gypsum is of great significance in construction, and if the gypsum is not treated properly, inflammable and highly toxic hydrogen sulfide is discharged to pollute soil and underground water. However, if properly treated, the regenerated gypsum can maintain the same physical and mechanical properties as conventional gypsum at a relatively lower cost. The existing method for recovering the building gypsum is not perfect, the problem of recovering and utilizing the building gypsum is difficult to solve, and the newly recovered gypsum also contains a great amount of impurities and can be really used for the subsequent use, so that the improvement is necessary.

Disclosure of Invention

The present invention is directed to a method for regenerating building gypsum, which solves the above problems of the prior art.

The invention is realized by the following modes: the building gypsum regeneration method uses a building gypsum regeneration device, the building gypsum regeneration device comprises a processing box body, a first bearing plate is fixedly arranged inside the processing box body, the processing box body is divided into an upper box body and a lower box body by the first bearing plate, a first feed inlet is formed in the top of the upper box body, a first Y-shaped guide pipe is arranged at the position of the first feed inlet and extends towards the inside of the upper box body, a pretreatment part is connected to the other end of the first Y-shaped guide pipe, the pretreatment part is arranged on the bottom surface of the upper box body, an annular second bearing plate is fixedly arranged on the inner side of the lower box body, a filter pressing part is connected into the annular second bearing plate, a collection part is fixedly arranged on the bottom surface of the lower box body, and the collection part corresponds to the position of the filter pressing part.

The pretreatment component comprises a gypsum crushing box body and a mixing box body, the gypsum crushing box body comprises a first arc-shaped track arranged on the inner wall of the gypsum crushing box body, two first sliding blocks are symmetrically arranged in the first arc-shaped track, each first sliding block is connected with a first rotating rod, two groups of deflector rods are symmetrically arranged on the first rotating rod in a staggered manner, each group of deflector rods comprises two deflector rods, the other end of the first rotating rod is connected with a first rotating block, the upper end of the first rotating block is provided with a second rotating rod, a second rotating block is arranged on the second rotating rod, the second rotating rod extends to the inside of the second rotating block, the other end of the first rotating block is fixedly provided with a third rotating rod, two first sliding bases are symmetrically arranged at the inner bottom of the gypsum crushing box body, each sliding base is internally provided with an arc-shaped first sliding plate in a sliding mode, and the other end of the arc-shaped first sliding plate can be tightly attached to the side face of the third rotating rod.

The third dwang other end is equipped with the third turning block, third turning block perpendicular to third dwang direction both ends symmetry is equipped with two fourth dwang, every the fourth dwang downside is equipped with the infusion head, the third turning block lower extreme has set firmly the fifth dwang, the fifth dwang other end is equipped with the clamp plate, the inboard bottom symmetry of mixing box is equipped with two second sliding base, it is equipped with the second sliding plate to slide in the second sliding base, a set of drainage hole has been seted up to the mixing box bottom surface, every group the drainage hole includes seven drainage holes, the drainage hole runs through in mixing box bottom surface and first bearing plate.

The filter pressing component comprises a first sleeve connected with an annular second bearing plate, a second Y-shaped guide pipe is connected to the upper end of the first sleeve, circular second sliding tracks are formed in two sides of the upper end of the first sleeve, a second sliding block is arranged in the circular second sliding tracks in a sliding mode, three sixth rotating rods are connected to the other side of the second sliding block, a first roller is connected to the other end of each sixth rotating rod, a filter hole is formed in the first roller, third sliding bases are symmetrically arranged at the bottoms of the inner sides of the first roller, third sliding plates are arranged in the third sliding bases in a sliding mode, a second sleeve is connected to the outer side of the first roller, first sliding grooves corresponding to the filter hole are formed in the second sleeve, a first sliding rod is arranged in each first sliding groove in a sliding mode, and a first spring for sliding reset is arranged between each first sliding groove and the first sliding rod, and a magnetic plate is arranged between the two sleeves and the first sliding groove.

The collecting component comprises a first circular collecting tank located on the bottom surface of the lower box body, the first collecting tank is located under the first roller, a first discharge hole is formed in one side of the first circular collecting tank, a second collecting tank is formed in the periphery of the first collecting tank, the second collecting tank corresponds to the second sleeve in position, and two second discharge holes are symmetrically formed in the two sides of the second collecting tank.

A first conveying pipeline is arranged inside the second rotating block, a first conveying groove is formed inside the first conveying pipeline, a rotating sealing cover is arranged in the conveying groove, a second conveying groove is formed in the rotating sealing cover, a seventh rotating shaft is arranged in the rotating sealing cover in a rotating mode, a third conveying groove is formed in the seventh rotating shaft and communicated with the second rotating groove, and the other end of the third rotating groove is connected with the two infusion heads.

The second sliding groove is formed in the inner top end of the first arc-shaped rail, the fourth sliding plate is arranged in the second sliding groove in a sliding mode, and a second spring used for sliding reset is arranged between the fourth sliding plate and the second sliding groove.

An electric control wire is arranged in the second rotating block and connected with the second rotating block, the other end of the electric control wire is connected with a first motor, and a second motor is arranged on the outer side of the circular second sliding track.

And a third discharge port communicated with the first discharge port is formed below the working box body, and fourth discharge ports communicated with the second discharge port are formed in two sides of the working box body.

All parts in the working box body are made of anti-corrosion materials, and the first conveying pipeline and the electric control line are made of telescopic materials.

Advantageous effects

The invention provides a paint spraying device for a bridge steel truss through improvement, which has the following improvements and advantages compared with the prior art:

1. through setting up track, first rotation pole, first slider, realized also can realize first rotation pole and drive other parts vertical reciprocating motion when the pivoted, make the filter-pressing effect better.

2. Through setting up magnetic sheet and first slide bar, realized keeping away from the filter-pressing part at the clamp plate and going on clearing up the mud that probably exists in the filtration pore.

3. Through setting up collection device with the gypsum that the filter-pressing is good and the wet-dry separation of liquid of centrifugation play, reduced the pollution to the environment and promoted the filter-pressing effect.

Drawings

The invention is further explained below with reference to the figures and examples:

FIG. 1 is a schematic isometric view of the present invention;

FIG. 2 is a schematic view of a partial isometric configuration of the present invention;

FIG. 3 is a schematic top cross-sectional view of the present invention;

FIG. 4 is a front sectional structural view of the present invention;

FIG. 5 is a schematic cross-sectional view of the upper housing of the present invention;

FIG. 6 is a schematic cross-sectional view of the lower casing of the present invention;

FIG. 7 is a schematic cross-sectional structural view at A in FIG. 4;

FIG. 8 is an enlarged view of FIG. 5 at B;

fig. 9 is an enlarged view of fig. 4 at C.

In the figure, a processing box 1, a first bearing plate 105, an upper box 103, a lower box 104, a first feed port 101, a first Y-shaped conduit 201, a pretreatment part 2, an annular second bearing plate 302, a press filter part 3, a collection part 4, a gypsum crushing box 202, a mixing box 203, a first arc-shaped rail 206, a first slider 205, a first rotating rod 221, a deflector rod 222, a first rotating block 209, a second rotating rod 328, a second rotating block 323, a third rotating rod 329, a first sliding base 211, an arc-shaped first sliding plate 210, a third rotating block 217, a fourth rotating rod 219, a transfusion head 218, a fifth rotating rod 330, a pressing plate 214, a second sliding base 212, a second sliding plate 216, a drainage hole 213, a first sleeve 303, a second Y-shaped conduit 314, a circular second sliding rail 301, a second rotating rod 331, a sixth rotating rod 312, a first roller 332, a filter hole 311, a third sliding base 306, a third sliding plate 307, a second sleeve 333, a first sliding groove 308, a first sliding rod 309, a first spring 310, a magnetic plate 334, a first circular collecting groove 403, a first discharging hole 305, a second collecting groove 401, a second discharging hole 402, a first conveying pipeline 324, a first conveying groove 325, a rotary sealing cover 326, a second conveying groove 327, a seventh rotary shaft 335, a third conveying groove 220, a second sliding groove 320, a fourth sliding plate 322, a second spring 321,

an electrical control line 208, a first motor 204, a second motor 304, a third port 102, and a fourth port 106.

Detailed Description

The present invention will be described in detail with reference to fig. 1 to 9, and the technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention, and the motor in the present invention is the prior art, and for convenience of description, the motor in the drawings of the present specification is only a schematic structural diagram, and its internal structure and specific arrangement are the same as those in the prior art in "mechanical design manual".

As shown in fig. 1-9, the present invention is a building gypsum regeneration method, which uses a building gypsum regeneration apparatus, the building gypsum regeneration apparatus includes a processing box 1, a first bearing plate 105 is fixedly disposed inside the processing box 1, the processing box is divided into an upper box 103 and a lower box 104 by the first bearing plate, a first feeding port 101 is disposed at the top of the upper box 103, a first Y-shaped conduit 201 is disposed at the first feeding port 101 and extends into the upper box, a pretreatment component 2 is connected to the other end of the first Y-shaped conduit, the pretreatment component 2 is disposed at the bottom of the upper box 103, an annular second bearing plate 302 is fixedly disposed inside the lower box, a filter pressing component 3 is connected inside the annular second bearing plate 302, a collection component 4 is fixedly disposed at the bottom of the lower box 104, and the collection component 4 corresponds to the filter pressing component 3.

Pretreatment component 2 includes that the box 202 is smashed to the gypsum and mixes box 203, box 202 is smashed to the gypsum includes that box 202 inner wall is smashed to the gypsum has seted up first arc track 206, the symmetry is equipped with two first sliders 205 in the first arc track 206, connect first dwang 221 on every first slider 205, the symmetry is crisscross to be equipped with two sets of driving levers 222 on the first dwang, every group driving lever 222 contains two driving levers, first dwang 209 is connected to first dwang 221 other end, first dwang 209 is equipped with second dwang 328 on the first dwang 209 upper end, be equipped with second dwang 323 on the second dwang 328, second dwang 328 extends to inside the second dwang 323, the third dwang 329 has been set firmly to the first dwang 209 other end, the bottom symmetry is equipped with two first sliding bases 211 in box 202 is smashed to the gypsum, it is equipped with first sliding plate 210 of arc to slide in each sliding base, the first sliding plate 210 other end of arc can be hugged closely with third dwang 329 side.

The other end of the third rotating rod 329 is provided with a third rotating block 217, the third rotating block 217 is symmetrically provided with two fourth rotating rods 219 at two ends perpendicular to the direction of the third rotating rod 329, the lower side of each fourth rotating rod 219 is provided with a transfusion head 218, the lower end of the third rotating block 217 is fixedly provided with a fifth rotating rod 330, the other end of the fifth rotating rod 330 is provided with a pressing plate 214, the inner side bottom of the mixing box body 203 is symmetrically provided with two second sliding bases 212, a second sliding plate 216 is arranged in the second sliding bases in a sliding manner, the bottom surface of the mixing box body 203 is provided with a set of drainage holes 213, each set of drainage holes 213 comprises seven drainage holes, and the drainage holes run through the bottom surface of the mixing box body 203 and the first bearing plate 105.

The filter pressing component 3 comprises a first sleeve 303 connected with an annular second bearing plate 302, the upper end of the first sleeve 303 is connected with a second Y-shaped guide pipe 314, two sides of the upper end of the first sleeve 303 are provided with circular second sliding rails 301, a second sliding block 331 is arranged in the circular second sliding rails 301 in a sliding manner, the other side of the second sliding block 331 is connected with three sixth rotating rods 312, the other end of the sixth rotating rod 312 is connected with a first roller 332, the first roller 332 is provided with a filter hole 311, the bottom of the inner side of the first roller 332 is symmetrically provided with a third sliding base 306, a third sliding plate 307 is arranged in the third sliding base 306 in a sliding manner, the outer side of the first roller 332 is connected with a second sleeve 333, the second sleeve 333 is internally provided with a first sliding groove 308 corresponding to the filter hole 331, each first sliding groove 308 is internally provided with a first sliding rod 309 in a sliding manner, and a first spring 310 for sliding restoration is arranged between the first sliding groove 308 and the first sliding rod 309, a magnetic plate 334 is provided between the two sleeves 333 and the first sliding groove 308.

The collecting component 4 comprises a first circular collecting tank 403 located on the bottom surface of the lower box 104, the first collecting tank 403 is located under the first roller 332, a first discharge hole 305 is formed in one side of the first circular collecting tank 403, a second collecting tank 401 is formed around the first collecting tank 403, the second collecting tank 401 corresponds to the second sleeve 333 in position, and two second discharge holes 402 are symmetrically formed in two sides of the second collecting tank 401.

The first conveying pipeline 324 is arranged in the second rotating block 323, the first conveying groove 325 is arranged in the first conveying pipeline 324, the rotating sealing cover 326 is arranged in the conveying groove 325, the second conveying groove 327 is arranged in the rotating sealing cover 326, the seventh rotating shaft 335 is rotatably arranged in the rotating sealing cover 326, the third conveying groove 220 is arranged in the seventh rotating shaft 335 and is communicated with the second rotating groove 327, and the other end of the third rotating groove 220 is connected with the two liquid conveying heads 218.

A second sliding groove 320 is arranged at the top end in the first arc-shaped rail 206, a fourth sliding plate 322 is arranged in the second sliding groove 320 in a sliding manner, and a second spring 321 for sliding reset is arranged between the fourth sliding plate 322 and the second sliding groove.

An electric control wire 208 is arranged in the second rotating block 323 and connected with the second rotating block 323, the other end of the electric control wire 208 is connected with the first motor 204, and a second motor 304 is arranged outside the circular second sliding track 301.

A third discharge port 102 communicated with the first discharge port 305 is formed below the working box body 1, and fourth discharge ports 106 communicated with the second discharge port 402 are formed on two sides of the working box body 1.

All parts in the work box 1 are made of anti-corrosion materials, and the first conveying pipeline 324 and the electric control line 208 are made of telescopic materials.

The invention also provides a regeneration method of the building gypsum, which comprises the following specific steps:

the first step is as follows: the power is turned on and the arcuate first sliding bar 210 is controlled to close with the second sliding bar 216 and the third sliding bar 307 to feed gypsum through the first Y-shaped conduit 201 into the apparatus.

The second step is that: at this time, the first motor 204 provides power for the second rotating rod 328, the second rotating rod 328 drives the first rotating block 209 to rotate, the first rotating rod 221 and the first sliding block 205 slide on the first arc-shaped track 206, the third rotating rod 329 reciprocates up and down under the action of the track 206, the second motor 304 provides power for the circular second sliding track 301, and gypsum reaches the gypsum crushing box 202 through the first Y-shaped guide pipe 201.

The third step: the driving lever 222 rotates and moves up and down in the gypsum crushing box 202, and the gypsum is continuously crushed by the driving lever 22. At this time, the arc-shaped first sliding plate 210 is controlled to be opened, and the gypsum falls down to the mixing box 203.

The fourth step: water and sulfuric acid are sequentially added into lime through the crushed gypsum in the mixing box body 203 through the first conveying pipeline 324, liquid is sprayed out through the liquid conveying head 218 at the moment, the liquid conveying head 218 rotates under the driving of the third rotating block 217 to enable the lime and the liquid to form a vortex, the mixing is more sufficient, the second sliding plate 216 is opened after the lime is fully mixed and neutralized, the first motor 204 is stopped, the third rotating block 217 stops rotating, and lime mud flows to the second Y-shaped guide pipe 314 through the drainage hole 213.

The fifth step: the mixed lime mud flows to the first roller 332 through the second Y-shaped conduit 314, the first motor 204 is started, the third rotating block 217 starts to rotate, the first roller 332 rotates at a high speed at the moment, water in the lime mud flows to the second sleeve 333 through the filter hole 311 under the action of centrifugal force, the fifth rotating rod 330 and the pressing plate 214 are driven by the third rotating block 217 to rotate and vertically reciprocate under the action of centrifugal force, the pressing plate performs extrusion motion on the lime mud at the moment, and the lime mud is simultaneously extruded under the action of centrifugal force, so that the lime mud is better in filter pressing effect.

And a sixth step: when the first slider 205 slides to the highest point in the first arc-shaped track 206, the first slider 205 presses the fourth sliding plate 322 into the second sliding groove 320, at this time, the magnetic plate 334 generates a repelling effect on the first sliding rod 309, the first sliding rod 309 extends in a direction away from the magnetic plate 334 and extends into the filter hole 311, when the first slider 205 leaves the highest point of the first arc-shaped track 206, the fourth sliding plate 322 returns to the initial position under the action of the second spring 321, the repelling effect of the magnetic plate 334 on the first sliding rod 309 disappears, and the first sliding rod 309 slides back to the initial state under the action of the first spring 310, so as to clean mud possibly existing in the filter hole 311.

The seventh step: under the filter pressing effect of the filter pressing and filtering component 3, water in the lime mud flows into the second collecting tank 401, flows from the second discharging port 402 to the fourth discharging port 106, flows out and is collected, at the moment, the third sliding plate 307 is opened, and the lime after filter pressing falls into the first circular collecting tank 403 and slides out of the third discharging port 102 through the first discharging port 305 to be collected.

Eighth step: when the first motor 204 is started for the second time, the arc-shaped first sliding plate 210 can be closed, and untreated lime is put into the gypsum crushing box 202 through the first Y-shaped guide pipe 201, so that the pretreatment effect is realized, and the working efficiency is accelerated.

And step nine, crushing, mixing, filter pressing and collecting the new gypsum.

The above description is only for the preferred embodiment of the present invention and is not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A building gypsum regeneration method uses a building gypsum regeneration device, the building gypsum regeneration device comprises a processing box body (1), a first bearing plate (105) is fixedly arranged in the processing box body (1), the processing box body is divided into an upper box body (103) and a lower box body (104) by the first bearing plate, a first feeding hole (101) is formed in the top of the upper box body (103), a first Y-shaped conduit (201) is arranged at the position of the first feeding hole (101) and extends towards the interior of the upper box body, the other end of the first Y-shaped conduit is connected with a pretreatment part (2), the pretreatment part (2) is arranged on the bottom surface of the upper box body (103), an annular second bearing plate (302) is fixedly arranged on the inner side of the lower box body, a filter pressing part (3) is connected in the annular second bearing plate (302), and a collection part (4) is fixedly arranged on the bottom surface of the lower box body (104), the collecting component (4) corresponds to the filter pressing component (3) in position.

2. The method for regenerating building gypsum according to claim 1, wherein: pretreatment part (2) including the box (202) is smashed to the gypsum and mixes box (203), first arc track (206) has been seted up including the box is smashed to the gypsum to gypsum crushing box (202) inner wall, first arc track (206) interior symmetry is equipped with two first sliders (205), every connect first dwang (221) on first slider (205), the symmetry is crisscross on first dwang and is equipped with two sets of driving lever (222), every group driving lever (222) contain two driving levers, first dwang (209) is connected to first dwang (221) other end, first dwang (209) upper end is equipped with second dwang (328), be equipped with second dwang (323) on second dwang (328), second dwang (328) extend to inside second dwang (323), first dwang (209) other end has set firmly third dwang (329), two first sliding bases (211) are symmetrically arranged at the bottom in the gypsum crushing box body (202), an arc-shaped first sliding plate (210) is arranged in each sliding base in a sliding mode, and the other end of each arc-shaped first sliding plate (210) can be attached to the side face of the third rotating rod (329) in a clinging mode.

3. The method for regenerating building gypsum according to claim 2, wherein: the third dwang (329) other end is equipped with third turning block (217), third turning block (217) perpendicular to third dwang (329) direction both ends symmetry is equipped with two fourth dwang (219), every fourth dwang (219) downside is equipped with infusion head (218), third turning block (217) lower extreme has set firmly fifth dwang (330), fifth dwang (330) other end is equipped with clamp plate (214), mix box (203) inboard bottom symmetry and be equipped with two second sliding bottom (212), it is equipped with second sliding plate (216) to slide in the second sliding bottom, a set of drainage hole (213) has been seted up to mixed box (203) bottom surface, every group drainage hole (213) include seven drainage holes, the drainage hole runs through in mixed box (203) bottom surface and first bearing plate (105).

4. The method for regenerating building gypsum according to claim 3, wherein: the filter pressing component (3) comprises a first sleeve (303) connected with an annular second bearing plate (302), a second Y-shaped guide pipe (314) is connected to the upper end of the first sleeve (303), a circular second sliding track (301) is formed in two sides of the upper end of the first sleeve (303), a second sliding block (331) is arranged in the circular second sliding track (301) in a sliding mode, three sixth rotating rods (312) are connected to the other side of the second sliding block (331), the other end of each sixth rotating rod (312) is connected with a first roller (332), a filter hole (311) is formed in the first roller (332), a third sliding base (306) is symmetrically arranged at the bottom of the inner side of the first roller (332), a third sliding plate (307) is arranged in the third sliding base (306) in a sliding mode, a second sleeve (333) is connected to the outer side of the first roller (332), a first sliding groove (308) corresponding to the filter hole (331) is formed in the second sleeve (333), a first sliding rod (309) is arranged in each first sliding groove (308) in a sliding mode, a first spring (310) for sliding reset is arranged between each first sliding groove (308) and the corresponding first sliding rod (309), and a magnetic plate (334) is arranged between each two sleeves (333) and the corresponding first sliding groove (308).

5. The method for regenerating building gypsum according to claim 4, wherein: the collecting component (4) comprises a first circular collecting tank (403) located on the bottom surface of the lower tank body (104), the first collecting tank (403) is located under a first roller (332), a first discharging hole (305) is formed in one side of the first circular collecting tank (403), second collecting tanks (401) are formed in the periphery of the first collecting tank (403), the second collecting tanks (401) correspond to second sleeves (333) in position, and two second discharging holes (402) are symmetrically formed in the two sides of the second collecting tanks (401).

6. The method for regenerating building gypsum according to claim 5, wherein: a first conveying pipeline (324) is arranged inside the second rotating block (323), a first conveying groove (325) is formed inside the first conveying pipeline (324), a rotating sealing cover (326) is arranged in the conveying groove (325), a second conveying groove (327) is formed in the rotating sealing cover (326), a seventh rotating shaft (335) is arranged in the rotating sealing cover (326) in a rotating mode, a third conveying groove (220) is formed in the seventh rotating shaft (335) and communicated with the second rotating groove (327), and the other end of the third rotating groove (220) is connected with the two liquid conveying heads (218).

7. The method for regenerating building gypsum according to claim 6, wherein: the inner top end of the first arc-shaped track (206) is provided with a second sliding groove (320), a fourth sliding plate (322) is arranged in the second sliding groove (320) in a sliding mode, and a second spring (321) for sliding reset is arranged between the fourth sliding plate (322) and the second sliding groove.

8. The method for regenerating building gypsum according to claim 7, wherein: an electric control wire (208) is arranged in the second rotating block (323) and connected with the second rotating block (323), the other end of the electric control wire (208) is connected with the first motor (204), and a second motor (304) is arranged on the outer side of the circular second sliding track (301).

9. The method for regenerating building gypsum according to claim 8, wherein: a third discharge hole (102) communicated with the first discharge hole (305) is formed below the working box body (1), and fourth discharge holes (106) communicated with the second discharge hole (402) are formed in two sides of the working box body (1).

10. The method for regenerating building gypsum according to claim 9, wherein: all parts in the work box body (1) are made of anti-corrosion materials, and the first conveying pipeline (324) and the electric control line (208) are made of telescopic materials.