CN117601228A - Geological polymer preparation device and implementation method using iron tailings as raw material - Google Patents

Abstract

The invention discloses a geopolymer preparation device using iron tailings as raw material and an implementation method, and belongs to the field of tailings brick making. The geopolymer preparation device using iron tailings as raw material includes a base, and both left and right parts of the rear end of the base are There are two support rods fixedly connected. A sliding hole is provided in the middle of the support rod. A placement cavity is provided at the lower end of the sliding hole. A first compression spring is fixedly connected to the middle of the placement cavity. Permanent magnets are fixedly connected to both the front and rear parts of the lower end of the sliding hole. The support rod The middle part is located in the middle of the sliding hole and is slidingly connected with a supporting block. The lower end of the supporting block is fixedly connected with iron blocks at the front and rear parts. The upper end of the support rod is fixedly connected with an L-shaped bracket. A water storage tank is fixedly connected between the two L-shaped brackets, which can be realized. The viscosity of the iron tailings is controlled through a linkage device, so that the iron tailings and water are evenly mixed, and the elastic rod removes the gaps in the iron tailings inside the cavity before the iron tailings are statically pressed to prevent the iron tailings from becoming bricks. Strength is too low.

Description

Geological polymer preparation device and implementation method using iron tailings as raw material

Technical field

The present invention relates to the field of brick making from tailings, and more specifically, to a geopolymer preparation device and implementation method using iron tailings as raw material.

Background technique

Tailings are the materials left after refining ore. Iron tailings, as the residue left after refining iron ore, is often used for recycling. Among them, brick making from iron tailings is a common application method.

Traditional iron tailing brick making on the market requires iron tailings, curing agent and water to be mixed in a certain proportion for static brick pressing. Iron tailings with different viscosities require different proportions of water, making it difficult for workers to handle the water. The proportion is controlled, and it is not easy to visually detect whether the iron tailings and water are mixed evenly. The iron tailings are easy to produce internal voids before being put into the cavity for static pressing, resulting in voids in the bricks after static pressing, which affects the strength of the bricks. reduce.

Contents of the invention

1. Technical problems to be solved

In view of the problems existing in the prior art, the purpose of the present invention is to provide a geopolymer preparation device and implementation method using iron tailings as raw materials, which can control the viscosity of the iron tailings through a linkage device, so that the iron tailings The ore and water are stirred evenly, and the elastic rod removes the iron tailings gaps inside the cavity before the iron tailings are statically pressed to prevent the iron tailings from being too low in strength after being bricked.

2.Technical solutions

In order to solve the above problems, the present invention adopts the following technical solutions.

A geopolymer preparation device using iron tailings as raw material includes a base. A static pressure module is fixedly installed on the upper front end of the base. Two support rods are fixedly connected to the left and right parts of the rear end of the base. The support rods A sliding hole is provided in the middle, and a placement cavity is provided at the lower end of the sliding hole. A first compression spring is fixedly connected to the middle of the placement cavity. Permanent magnets are fixedly connected to both the front and rear parts of the lower end of the sliding hole. The middle part of the support rod is located at There is a supporting block slidingly connected to the middle part of the sliding hole, and iron blocks are fixedly connected to the front and rear parts of the lower end of the supporting block;

Among them, an L-shaped bracket is fixedly connected to the upper end of the support rod, a water storage tank is fixedly connected between the two L-shaped brackets, and a cylindrical tube is fixedly connected to the lower end of the water storage tank. Under the outer wall of the cylindrical tube There are multiple water outlets at equal angles in one half;

Among them, a storage tank is fixedly connected between the two supporting blocks, a discharge port is provided at the lower end of the storage tank, a switch module is installed in the middle of the discharge port, and a switch module is installed in the middle of the storage tank. Stirring device, a supporting plate is fixedly connected to the middle part of the support rod on the right side, a servo motor is fixedly installed on the upper end of the supporting plate, a second helical gear is fixedly installed on the output end of the servo motor, and a second helical gear is fixedly installed on the upper end of the base. The first linear module has a support device installed in the middle of the first linear module. There is a horizontal plate fixedly connected between the static pressure module and the two support rods. The left and right parts of the front end of the horizontal plate are A strip hole is provided, and a plurality of mold cavities are provided in the middle of the front end of the horizontal plate. Second linear modules are installed on both left and right ends of the horizontal plate. The two second linear modules are slidably connected with a molded structure, the molded structure includes a frame body, the left and right ends of the frame body are fixedly connected with connecting bars, and the lower part of the front end of the frame body is fixedly connected with two elastic rods. The viscosity of the iron tailings is controlled through a linkage device, so that the iron tailings and water are evenly mixed, and the elastic rod removes the gaps in the iron tailings inside the cavity before the iron tailings are statically pressed to prevent the iron tailings from becoming bricks. Strength is too low.

Further, the stirring device includes a rotating rod, two cross-shaped rods are fixedly connected in the middle of the rotating rod, a stirring piece is fixedly connected between the two cross-shaped rods, and the ends of the cross-shaped rods are counterclockwise. A linkage device is fixedly connected, and a scraper is fixedly connected to the lower end of the rotating rod, so that the stirring device can stir the iron tailings and water inside the storage tank.

Further, the linkage device includes a housing, a pressure sensor is fixedly installed in the middle of the housing, two second compression springs are fixedly connected to the middle of the housing, and a pressure block is slidably connected to the middle of the housing, so A pressure rod is fixedly connected to the middle part of the briquette, so that the linkage device can control the opening and closing of the switch module when the iron tailings are stirred evenly and within a suitable range.

Further, a rubber plug is fixedly connected to the upper end of the stirring device, and a first helical gear is fixedly connected to the lower end of the stirring device, so that the stirring device can control the outflow of water through the rubber plug, and the stirring device can control itself through the first helical gear. Turn.

Further, the support device includes an electric lifting rod, the upper end of the electric lifting rod is fixedly connected to a pressure-bearing plate, the left and right ends of the pressure-bearing plate are provided with strip grooves, and the middle parts of the strip grooves are fixed at equal intervals. Multiple clamping blocks are connected so that the pallet device can perform pressure-bearing operations when iron tailings are pressed into bricks.

Further, the stirring device rotates at the center of the bottom of the storage tank, and the first helical gear can be meshed with the second helical gear, and the rubber plug matches the inside of the cylindrical tube, making it difficult for the stirring device to come out of the middle of the storage tank. , and the second helical gear can drive the first helical gear to rotate.

Further, the pressure sensor is electrically connected to the switch module, and the static pressure module, the electric lifting rod, the first linear module and the second linear module are electrically connected, and the connecting strip is electrically connected to the second linear module. Matching allows the pressure sensor to control the opening and closing of the switch module, and the static pressure module, electric lifting rod, first linear module and second linear module can work in conjunction.

Further, the internal material of the elastic rod is elastic rubber, and the elastic rod matches the strip hole, so that the elastic rod can rebound and knock the block, and the elastic rod can move in the middle of the strip hole.

Further, the end of the pressure block away from the housing is fixedly connected with a wide plate, and the end of the pressure block close to the housing is provided with an annular bump, so that the pressure block can sense the internal viscosity of the iron tailings, and the pressure block can sense the internal viscosity of the iron tailings. It is not easy to come out from the middle of the shell.

The implementation method of a geopolymer preparation device using iron tailings as raw material includes the following steps:

S1. Pour the iron tailings and curing agent into the storage tank. The storage tank descends so that the first helical gear and the second helical gear come into contact and mesh;

S2. The stirring device stirs the iron tailings in the storage tank, and at the same time, water flows from the water storage pipe into the storage tank;

S3. The linkage device controls the switch module to open, and the material inside the storage tank is scraped out from the discharge port by the scraper;

S4. The static pressure module performs a static pressure brick-forming operation on the material, and then the electric lifting rod descends. The first linear module moves the support device forward to remove the formed iron tailings bricks.

3. Beneficial effects

Compared with the existing technology, the advantages of the present invention are:

(1) This solution uses a linkage device to control the viscosity of the iron tailings, so that the iron tailings and water are evenly stirred, and the elastic rod removes the gaps in the iron tailings inside the cavity before the iron tailings are statically pressed to avoid iron The strength of tailings after brick formation is too low.

(2) The linkage device can monitor the internal viscosity of the iron tailings through the pressure received by the pressure sensor, and the eight linkage devices can detect whether the iron tailings are stirred evenly.

(3) The elastic rod is deformed by the clamping block, and the elastic rod rebounds and hits the clamping block, which reduces the internal gaps of the iron tailings located inside the cavity and improves the strength of the iron tailings after they are statically pressed into bricks.

Description of drawings

Figure 1 is an overall perspective view of the present invention;

Figure 2 is an overall split view of the present invention;

Figure 3 is a partially cut-away perspective view of the support rod and storage tank of the present invention;

Figure 4 is a partial half-section perspective view of the rubber stopper and water outlet tank of the present invention;

Figure 5 is a partial perspective view of the support rod part of the present invention;

Figure 6 is a perspective view of the stirring device of the present invention;

Figure 7 is a half-section perspective view of the linkage device of the present invention;

Figure 8 is a partial half-section partial front view of the support rod and storage tank of the present invention;

Figure 9 is a partial working principle diagram of the support rod and storage tank of the present invention;

Figure 10 is a perspective view of the pallet device of the present invention;

Figure 11 is a partial half-section front view of the elastic rod and frame of the present invention;

Figure 12 is a working principle diagram of the elastic rod of the present invention.

Description of numbers in the figure:

1. Base; 2. Support rod; 3. Sliding hole; 4. First compression spring; 5. Permanent magnet; 6. Support block; 7. Iron block; 8. L-shaped bracket; 9. Water storage tank; 10. Cylindrical tube; 11. Water outlet; 12. Storage tank; 13. Discharge port; 14. Switch module; 15. Stirring device; 1501. Rotary rod; 1502. Cross-shaped rod; 1503. Stirring blade; 1504. Linkage device; 1505, scraper; 15041, housing; 15042, pressure sensor; 15043, second compression spring; 15044, pressure block; 15045, pressure rod; 16, rubber plug; 17, first helical gear; 18. Supporting plate; 19. Servo motor; 20. Second helical gear; 21. First linear module; 22. Supporting device; 2201. Electric lifting rod; 2202. Pressure-bearing plate; 2203. Strip groove; 2204. Card block; 23. Horizontal plate; 24. Strip hole; 25. Cavity; 26. Second linear module; 27. Frame; 28. Connecting strip; 29. Elastic rod; 30. Static pressure module.

Detailed ways

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention; obviously, the described embodiments are only some of the embodiments of the present invention, not all of them. Based on The embodiments of the present invention and all other embodiments obtained by those of ordinary skill in the art without creative efforts fall within the scope of protection of the present invention.

In the description of the present invention, it should be noted that the orientation or positional relationship indicated by the terms "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the orientation shown in the drawings. or positional relationships are only for the convenience of describing the present invention and simplifying the description, but do 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 therefore cannot be understood as a limitation of the present invention. In addition, the terms "first" and "second" are used for descriptive purposes only and are not to be understood as indicating or implying relative importance.

In the description of the present invention, it should be noted that, unless otherwise clearly stated and limited, the terms "installed", "provided with", "set/connected", "connected", etc., should be understood in a broad sense, such as " "Connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be an adapted model component. Internal connectivity. For those of ordinary skill in the art, the specific meanings of the above terms in the present invention can be understood on a case-by-case basis.

Please refer to Figure 1-12. A geopolymer preparation device using iron tailings as raw material includes a base 1. A static pressure module 30 is fixedly installed on the upper front end of the base 1, and two static pressure modules 30 are fixedly connected to the left and right sides of the rear end of the base 1. Support rod 2. A sliding hole 3 is provided in the middle of the supporting rod 2. A placement cavity is provided at the lower end of the sliding hole 3. A first compression spring 4 is fixedly connected to the middle of the placement cavity. Permanent magnets 5 are fixedly connected to both the front and rear parts of the lower end of the sliding hole 3. The middle part of the support rod 2 is located in the middle part of the sliding hole 3 and is slidingly connected to a supporting block 6. The lower end of the supporting block 6 is fixedly connected to an iron block 7 at the front and rear parts;

Among them, an L-shaped bracket 8 is fixedly connected to the upper end of the support rod 2, a water storage tank 9 is fixedly connected between the two L-shaped brackets 8, a cylindrical tube 10 is fixedly connected to the lower end of the water storage tank 9, and the lower half of the outer wall of the cylindrical tube 10 A plurality of water outlets 11 are provided in some parts at equal angles;

Among them, a storage tank 12 is fixedly connected between the two supporting blocks 6. A discharge port 13 is provided at the lower end of the storage tank 12. A switch module 14 is installed in the middle of the discharge port 13. A stirring device is rotatably connected to the middle of the storage tank 12. In the device 15, a supporting plate 18 is fixedly connected to the middle part of the support rod 2 on the right side. A servo motor 19 is fixedly installed at the upper end of the supporting plate 18. A second helical gear 20 is fixedly installed at the output end of the servo motor 19. A third helical gear 20 is fixedly installed at the upper end of the base 1. A linear module 21. A supporting platform device 22 is installed in the middle of the first linear module 21. A transverse plate 23 is fixedly connected between the static pressure module 30 and the two support rods 2. The left and right parts of the front end of the transverse plate 23 are provided with There are strip holes 24, and a plurality of cavities 25 are opened in the middle of the front end of the horizontal plate 23. Second linear modules 26 are installed on both left and right ends of the horizontal plate 23. There is a molding structure slidingly connected between the two second linear modules 26. The molded structure includes a frame 27. The left and right ends of the frame 27 are fixedly connected with connecting bars 28. The lower part of the front end of the frame 27 is fixedly connected with two elastic rods 29.

Please refer to Figure 5-8. The stirring device 15 includes a rotating rod 1501. Two cross-shaped rods 1502 are fixedly connected in the middle of the rotating rod 1501. A stirring blade 1503 is fixedly connected between the two cross-shaped rods 1502. The end of the cross-shaped rod 1502 A linkage device 1504 is fixedly connected to each other counterclockwise, and a scraper 1505 is fixedly connected to the lower end of the rotating rod 1501 so that the stirring device 15 can stir the iron tailings and water inside the storage tank 12 . The linkage device 1504 includes a housing 15041. A pressure sensor 15042 is fixedly installed in the middle of the housing 15041. Two second compression springs 15043 are fixedly connected to the middle of the housing 15041. A pressure block 15044 is slidably connected to the middle of the housing 15041. The middle of the pressure block 15044 is A pressure rod 15045 is fixedly connected, so that the linkage device 1504 can control the opening and closing of the switch module 14 when the iron tailings are stirred evenly and suitable to reach a suitable range.

Please refer to Figure 4-9. The upper end of the stirring device 15 is fixedly connected with a rubber stopper 16, and the lower end of the stirring device 15 is fixedly connected with a first helical gear 17, so that the stirring device 15 can control the outflow of water through the rubber stopper 16, and the stirring device 15 can The first helical gear 17 controls its own rotation. The support device 22 includes an electric lifting rod 2201. The upper end of the electric lifting rod 2201 is fixedly connected with a pressure-bearing plate 2202. The left and right ends of the pressure-bearing plate 2202 are provided with strip grooves 2203. There are multiple fixedly connected strip grooves 2203 equidistantly in the middle. The clamping block 2204 enables the supporting platform device 22 to perform pressure-bearing operation when the iron tailings are pressed into bricks.

Please refer to Figure 3-10. The stirring device 15 rotates at the center of the bottom of the storage tank 12, and the first helical gear 17 can be meshed with the second helical gear 20, and the rubber stopper 16 matches the inside of the cylindrical tube 10, so that the stirring The device 15 is not easy to escape from the middle part of the storage tank 12, and the second helical gear 20 can drive the first helical gear 17 to rotate. The pressure sensor 15042 is electrically connected to the switch module 14, and the static pressure module 30, the electric lifting rod 2201, the first linear module 21 and the second linear module 26 are electrically connected, and the connecting bar 28 is electrically connected to the second linear module 15042. The module 26 is matched so that the pressure sensor 15042 can control the opening and closing of the switch module 14, and the static pressure module 30, the electric lifting rod 2201, the first linear module 21 and the second linear module 26 can work in conjunction .

Please refer to Figure 2-7. The internal material of the elastic rod 29 is elastic rubber, and the elastic rod 29 matches the strip hole 24, so that the elastic rod 29 can rebound and knock the block 2204, and the elastic rod 20 can be in the strip shape. Hole 24 middle movement. The end of the pressure block 15044 away from the housing 15041 is fixedly connected with a wide plate, and the end of the pressure block 15044 close to the housing 15041 is provided with an annular bump, so that the pressure block 15044 can sense the internal viscosity of the iron tailings, and the pressure block 15044 can sense the internal viscosity of the iron tailings. 15044 is not easy to come out from the middle part of the housing 15041.

During processing, turn on the servo motor 19, pour water into the water storage tank 9, and then pour the iron tailings and curing agent into the storage tank 12. After the storage tank 12 descends under the action of gravity, 5 pairs of permanent magnets The iron block 7 performs a magnetic attraction operation. The first helical gear 17 and the second helical gear 20 are meshed and connected. At the same time, the rubber stopper 16 descends. Water flows out through the water outlet hole 11 into the storage tank 12. The servo motor 19 passes through the second helical gear 20. The first helical gear 17 is driven to rotate, and the first helical gear 17 drives the stirring device 15 to rotate. The stirring device 15 stirs the iron tailings and water. When the iron tailings inside the storage tank 9 reach a suitable viscosity, the pressure The block 15044 enters the appropriate depth inside the housing 15041. At this time, the pressure exerted by the pressure rod 15045 on the pressure sensor 15042 is within the appropriate range. When the pressures received by the eight pressure sensors 15042 are all within the appropriate range, the pressure sensor 15042 controls The switch module 14 is opened, and the switch module 14 no longer blocks the discharge port 13. The scraper 1505 scrapes the mixed iron tailings out of the discharge port 13. At this time, the internal weight of the storage tank 12 decreases, and in the first Under the action of the compression spring 4, the storage tank 12 rises, and the rubber plug 16 blocks the water outlet hole 11 again;

The mixed iron tailings scraped out from the discharge port 13 fall between the frame 27 and the horizontal plate 23. The second linear module 26 drives the frame 27 to reciprocate forward and backward, and the iron tailings fall into the mold cavity 25 and Between the pallet devices 22, during the reciprocating motion of the frame 27, the elastic rod 29 is limited and bent by the blocking block 2204. Afterwards, due to the rebound effect of the elastic rod 29, the elastic rod 29 knocks the last blocking block 2204, so that the The pressure plate 2202 vibrates, and the pressure-bearing plate 2202 vibrates the iron tailings on the upper side to reduce the gaps inside the iron tailings. Then the static pressure module 30 statically presses the iron tailings inside the cavity 25 into bricks, and finally the electric The lifting rod 2201 descends to lower the iron tailings bricks and the pressure-bearing plate 2202. The first linear module 21 controls the pallet device 22 to move forward to transport the bricks of iron tailings out. It is possible to control the viscosity of the iron tailings through the linkage device 1504 so that the iron tailings and water are evenly stirred, and the elastic rod 29 removes the iron tailings gaps inside the cavity 25 before the iron tailings are statically pressed to avoid iron tailings. The strength of tailings after brick formation is too low.

The above are only preferred specific embodiments of the present invention; however, the protection scope of the present invention is not limited thereto. Any person familiar with the technical field who is familiar with the technical field shall make equivalent substitutions or changes based on the technical solutions and improvement concepts of the present invention within the technical scope disclosed in the present invention, and shall be covered by the protection scope of the present invention.

Claims (10)

1. A geopolymer preparation device using iron tailings as raw material, including a base (1). A static pressure module (30) is fixedly installed on the upper front end of the base (1). It is characterized by: the base (1) Two support rods (2) are fixedly connected to the left and right parts of the rear end. A sliding hole (3) is provided in the middle of the support rod (2). A placement cavity is provided at the lower end of the sliding hole (3). The placement cavity A first compression spring (4) is fixedly connected to the middle part, permanent magnets (5) are fixedly connected to both the front and rear parts of the lower end of the sliding hole (3), and the middle part of the support rod (2) is slidably connected to the middle part of the sliding hole (3). There is a supporting block (6), and the lower end and the front and rear parts of the supporting block (6) are fixedly connected with iron blocks (7); Among them, an L-shaped bracket (8) is fixedly connected to the upper end of the support rod (2), and a water storage tank (9) is fixedly connected between the two L-shaped brackets (8). The water storage tank (9) A cylindrical tube (10) is fixedly connected to the lower end, and a plurality of water outlets (11) are provided at equal angles in the lower half of the outer wall of the cylindrical tube (10); Among them, a storage tank (12) is fixedly connected between the two supporting blocks (6), and a discharge port (13) is provided at the lower end of the storage tank (12). The middle part of the discharge port (13) A switch module (14) is installed, a stirring device (15) is rotatably connected to the middle of the storage tank (12), and a supporting plate (18) is fixedly connected to the middle of the support rod (2) on the right side. A servo motor (19) is fixedly installed on the upper end of the supporting plate (18), a second helical gear (20) is fixedly installed on the output end of the servo motor (19), and a first linear module is fixedly installed on the upper end of the base (1). (21), a supporting platform device (22) is installed in the middle of the first linear module (21), and a horizontal plate is fixedly connected between the static pressure module (30) and the two support rods (2) (23), the left and right parts of the front end of the horizontal plate (23) are provided with strip holes (24), and the middle part of the front end of the horizontal plate (23) is provided with a plurality of mold cavities (25). ) A second linear module (26) is installed at both left and right ends, and a molding structure is slidably connected between the two second linear modules (26). The molding structure includes a frame (27), and the frame The left and right ends of the body (27) are fixedly connected with connecting bars (28), and the lower part of the front end of the frame (27) is fixedly connected with two elastic rods (29). 2. The geopolymer preparation device using iron tailings as raw material according to claim 1, characterized in that: the stirring device (15) includes a rotating rod (1501), and the middle part of the rotating rod (1501) is fixedly connected There are two cross-shaped rods (1502). A stirring blade (1503) is fixedly connected between the two cross-shaped rods (1502). The ends of the cross-shaped rods (1502) are fixedly connected with a linkage device (1502) counterclockwise. 1504), the lower end of the rotating rod (1501) is fixedly connected with a scraper (1505). 3. The geopolymer preparation device using iron tailings as raw material according to claim 2, characterized in that: the linkage device (1504) includes a shell (15041), and the middle part of the shell (15041) is fixedly installed. There is a pressure sensor (15042), two second compression springs (15043) are fixedly connected to the middle part of the housing (15041), and a pressure block (15044) is slidingly connected to the middle part of the housing (15041). The pressure block (15044) A pressure rod (15045) is fixedly connected in the middle. 4. The geopolymer preparation device using iron tailings as raw material according to claim 1, characterized in that: a rubber stopper (16) is fixedly connected to the upper end of the stirring device (15), and the stirring device (15) The lower end is fixedly connected with a first helical gear (17). 5. The geopolymer preparation device using iron tailings as raw material according to claim 1, characterized in that: the support device (22) includes an electric lifting rod (2201), and the electric lifting rod (2201) A pressure-bearing plate (2202) is fixedly connected to the upper end. There are strip grooves (2203) at both left and right ends of the pressure-bearing plate (2202). A plurality of clamping blocks are fixedly connected to the middle part of the strip groove (2203). (2204). 6. The geopolymer preparation device using iron tailings as raw material according to claim 4, characterized in that: the stirring device (15) rotates at the center of the bottom of the storage tank (12), and the first helical gear ( 17) can be meshed and connected with the second helical gear (20), and the rubber plug (16) matches the inside of the cylindrical tube (10). 7. The geopolymer preparation device using iron tailings as raw material according to claim 3, characterized in that: the pressure sensor (15042) is electrically connected to the switch module (14), and the static pressure module (30), the electric lifting rod (2201), the first linear module (21) and the second linear module (26) are electrically connected, and the connecting bar (28) matches the second linear module (26). 8. The geopolymer preparation device using iron tailings as raw material according to claim 1, characterized in that: the internal material of the elastic rod (29) is elastic rubber, and the elastic rod (29) and the strip hole (24) matches. 9. The geopolymer preparation device using iron tailings as raw material according to claim 3, characterized in that: one end of the briquette (15044) away from the housing (15041) is fixedly connected with a wide plate, and the briquette (15044) is fixedly connected to a wide plate. (15044) An annular bump is provided at one end close to the housing (15041). 10. The implementation method of the geopolymer preparation device using iron tailings as raw material according to claim 1, characterized in that: it includes the following steps: S1. Pour the iron tailings and curing agent into the storage tank (12). The storage tank (12) descends so that the first helical gear (17) and the second helical gear (20) are in contact and mesh; S2. The stirring device (15) stirs the iron tailings in the storage tank (12), and at the same time, water flows from the water storage pipe (9) into the storage tank (12); S3. The linkage device (1504) controls the switch module (14) to open, and the material inside the storage tank (12) is scraped out from the outlet (13) by the scraper (1505); S4. The static pressure module (30) statically presses the material into bricks. Afterwards, the electric lifting rod (2201) descends, and the first linear module (21) moves the support device (22) forward to move the formed iron Remove the tailings bricks.