CN114471804A

CN114471804A - Lime milk carbonization reaction furnace for extracting building calcium carbonate

Info

Publication number: CN114471804A
Application number: CN202210025823.4A
Authority: CN
Inventors: 刘有禄
Original assignee: Individual
Current assignee: Dexing Lixing Calcium Industry Co ltd
Priority date: 2022-01-11
Filing date: 2022-01-11
Publication date: 2022-05-13
Anticipated expiration: 2042-01-11
Also published as: CN114471804B

Abstract

The invention relates to a reaction furnace, in particular to a lime milk carbonization reaction furnace for extracting building calcium carbonate. The technical problem to be solved is as follows: provided is a method. A lime milk carbonization reaction furnace for extracting building calcium carbonate comprises: the supporting frame is symmetrically arranged at the bottom of the main frame; the grinding frame is arranged at the bottom in the main frame, and two first pressing rods are arranged on one side of the main frame in a sliding manner; the grinding plate is connected between the two first pressure rods and is in sliding contact with the bottom in the grinding frame; two first springs are connected between the grinding plate and the main frame. The invention achieves the effect of quantitative feeding and ensuring more comprehensive oxidation of lime milk; through the rotation of fourth pivot and division board, so can realize the effect of ration unloading to make things convenient for the effect that lime breast can fully react with carbon dioxide.

Description

Lime milk carbonization reaction furnace for extracting building calcium carbonate

Technical Field

The invention relates to a reaction furnace, in particular to a lime milk carbonization reaction furnace for extracting building calcium carbonate.

Background

Calcium carbonate is an important building material and has a wide industrial application. Can be used as filler in rubber, plastic, paper making, paint and ink industries.

Generally, when calcium carbonate is extracted, lime milk is placed in a reaction furnace, then carbon dioxide is introduced, so that the lime milk reacts with the carbon dioxide and calcium carbonate precipitates are generated, and thus, the lime milk cannot be quantitatively fed in a mode of manufacturing the calcium carbonate, and the lime milk and the carbon dioxide may not fully react.

Therefore, a lime milk carbonization reaction furnace for extracting calcium carbonate from building, which can perform quantitative discharging and ensure the oxidation of lime milk, needs to be designed.

Disclosure of Invention

In order to overcome the defect that quantitative feeding of lime milk cannot be carried out and the lime milk and carbon dioxide can not be fully reacted, the technical problem to be solved is as follows: the lime milk carbonization reaction furnace for extracting the building calcium carbonate can discharge materials quantitatively and ensure the oxidation of the lime milk more comprehensively.

The technical scheme of the invention is as follows: a lime milk carbonization reaction furnace for extracting building calcium carbonate comprises: the supporting frame is symmetrically arranged at the bottom of the main frame; the grinding frame is arranged at the bottom in the main frame, and two first pressing rods are arranged on one side of the main frame in a sliding manner; the grinding plate is connected between the two first pressure rods and is in sliding contact with the bottom in the grinding frame; two first springs are connected between the grinding plate and the main frame; the main frame is provided with a material pouring mechanism; the material taking mechanism is arranged on the front side of the grinding frame.

In one embodiment, the material pouring mechanism comprises: the main frame is provided with a first fixing column; the motor is arranged on the first fixing column, and an output shaft of the motor is rotatably connected with the main frame; the middle of one side of the main frame is rotatably provided with a first rotating shaft; the first rotating shaft and the output shaft of the motor are both provided with belt pulleys, and a flat belt is connected between the two belt pulleys; the first rotating shaft is provided with a first gear lack; the middle of one side of the main frame, which is close to the first rotating shaft, is rotatably provided with the second rotating shaft, and the second rotating shaft is positioned at the lower side of the first rotating shaft; the first straight gear is arranged on the second rotating shaft and meshed with the first missing gear; the clamping block is arranged on the second rotating shaft in a sliding mode; the second spring is connected between the clamping block and the second rotating shaft; the top of the grinding frame is provided with a reaction frame; the middle of the front sides of the left part and the right part of the reaction frame is provided with a second fixed column third rotating shaft, the second fixed column is rotatably provided with a third rotating shaft, the third rotating shaft is connected with the clamping block in a sliding manner, and the third rotating shaft is rotatably connected with the reaction frame; the third rotating shaft is provided with a first rotating rod which is positioned outside the reaction frame; a torsion spring is connected between the first rotating rod and the second fixing column and sleeved on the third rotating shaft; the third rotating shaft is provided with a material supporting plate; the arc slide rail, reaction frame upside are equipped with the arc slide rail, and first bull stick is connected with arc slide rail slidingtype.

In one embodiment, the material taking mechanism comprises: the first sliding blocks are arranged on two sides of the grinding frame in a sliding mode; the separation plate is connected between the two first sliding blocks; the middle of one side of the separation plate is provided with a first handle.

In one embodiment, the gas injection mechanism further comprises: the lower side of the grinding frame is connected with a third fixing column; the air cylinder is arranged on the third fixing column; the gas pipe is communicated between the gas cylinder and the grinding frame; the switch is arranged at the top of the gas pipe in a sliding manner; the third spring is connected between the switch and the gas pipe; one side of the first rotating rod is connected with a second pressure rod; the connecting rod is connected with both sides of the switch.

In one of them embodiment, still including unloading mechanism, unloading mechanism includes: the upper sides of the inner walls of the two sides of the main frame are symmetrically provided with fourth fixing columns; the material storage box is connected between the fourth fixed columns; the bottom of the storage box is rotatably provided with a fourth rotating shaft; the middle of the fourth rotating shaft is provided with a partition plate; the fourth rotating shaft is provided with a second straight gear in a sliding manner; the output shaft of the motor is provided with a second gear; and the second missing gear is meshed with the second straight gear.

In one embodiment, the device further comprises a disengaging mechanism, wherein the disengaging mechanism comprises: the first rotating rod is connected with a first rotating rod; the push plate is arranged on one side of the fourth rotating shaft in a sliding mode and is positioned on the left side of the second straight gear; and a fourth spring is connected between the push plate and the fourth rotating shaft.

In one of them embodiment, still including stop gear, stop gear includes: the fifth fixing column is symmetrically arranged on the upper side of the grinding frame; the clamping columns are arranged on the fifth fixing column in a sliding mode; the clamping columns are provided with first wedge-shaped blocks; fifth springs are connected between the first wedge-shaped blocks and the fifth fixing columns and sleeved on the clamping columns; the pull rings are connected to the clamping columns; the second wedge block is symmetrically arranged at the top of the blocking plate.

In one embodiment, the device further comprises a closing mechanism, wherein the closing mechanism comprises: the second sliding blocks are arranged on two sides of the top of the storage box in a sliding mode; the sealing cover is connected between the two second sliding blocks; the second handle is arranged at the top of the sealing cover.

The beneficial effects are that: 1. the invention achieves the effect of quantitative feeding and ensuring more comprehensive oxidation of lime milk;

2. according to the invention, the fourth rotating shaft and the partition plate rotate, so that the quantitative blanking effect can be realized, and the lime milk can fully react with carbon dioxide conveniently;

3. according to the invention, the supporting plate intermittently rotates, so that the prepared calcium carbonate can be poured into the grinding frame, and manual pouring is not needed;

4. according to the invention, the first pressure lever is continuously pulled leftwards and rightwards, so that the grinding plate moves leftwards and rightwards, and the calcium carbonate in the grinding frame can be ground.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a schematic structural view of a first partial body of the material pouring mechanism of the present invention.

FIG. 5 is a schematic view of a second partial structure of the pouring mechanism of the present invention.

Fig. 6 is a schematic perspective view of a third part of the material pouring mechanism of the present invention.

Fig. 7 is a schematic perspective view of a fourth part of the material pouring mechanism of the present invention.

Fig. 8 is a schematic perspective view of a material taking mechanism according to the present invention.

FIG. 9 is a schematic diagram of a first partial body structure of the gas injection mechanism of the present invention.

FIG. 10 is a schematic diagram of a second partial structure of the gas injection mechanism of the present invention.

Fig. 11 is a schematic structural view of a first partial body of the blanking mechanism of the present invention.

Fig. 12 is an enlarged schematic perspective view of part a of the present invention.

Fig. 13 is a schematic structural view of a second partial body of the blanking mechanism of the invention.

Fig. 14 is a perspective view of the detachment mechanism of the present invention.

Fig. 15 is a schematic perspective view of the limiting mechanism of the present invention.

Fig. 16 is a schematic perspective view of the closing mechanism of the present invention.

In the reference symbols: 1-support frame, 2-main frame, 3-grinding frame, 4-grinding plate, 5-first spring, 6-first press rod, 7-material pouring mechanism, 71-first fixed column, 72-motor, 73-flat belt, 74-first rotating shaft, 75-first gear lacking, 76-second rotating shaft, 77-first straight gear, 78-clamping block, 79-third rotating shaft, 710-second spring, 711-second fixed column, 712-torsion spring, 713-first rotating rod, 714-arc slide rail, 715-reaction frame, 716-material supporting plate, 8-material taking mechanism, 81-first slide block, 82-separation plate, 83-first handle, 9-gas injection mechanism, 91-third fixed column, 92-gas storage cylinder, 93-air pipe, 94-switch, 95-second pressure lever, 96-connecting rod, 97-third spring, 10-blanking mechanism, 101-fourth fixed column, 102-material storage box, 103-second missing gear, 104-second straight gear, 105-fourth rotating shaft, 106-separating plate, 11-disengaging mechanism, 111-second rotating rod, 112-push plate, 113-fourth spring, 12-limiting mechanism, 121-fifth fixed column, 122-pull ring, 123-clamping column, 124-fifth spring, 125-first wedge block, 126-second wedge block, 13-closing mechanism, 131-sealing cover, 132-second sliding block and 133-second handle.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings.

Example 1

The utility model provides a building calcium carbonate draws and uses lime milk carbonization reacting furnace, as shown in fig. 1-3, including support frame 1, main frame 2, grind frame 3, lapping plate 4, first spring 5, first depression bar 6, material mechanism 7 and extracting mechanism 8 fall, 2 bottom bilateral symmetry formulas of main frame are equipped with support frame 1, the bottom is equipped with grinds frame 3 in the

main frame

2, 2 right side slidingtype of main frame are equipped with two first depression bars 6, be connected with lapping plate 4 between 6 left sides of two first depression bars, lapping plate 4 and the contact of the bottom slidingtype in grinding frame 3, be connected with two first springs 5 between lapping plate 4 and the main frame 2, be equipped with material mechanism 7 on the main frame 2, it is equipped with extracting mechanism 8 to grind 3 front sides of frame.

The user can draw calcium carbonate through this reacting furnace, the user can place lime breast in pouring mechanism 7, pour lime breast in grinding frame 3 through pouring mechanism 7 intermittent type nature, promote first depression bar 6 and grinding plate 4 to the left side afterwards, first spring 5 is compressed, extrude through grinding plate 4 and pulverize lime breast, the user is when not exerting force to first depression bar 6, under first spring 5's reset action, first depression bar 6 and grinding plate 4 move to the right side and reset, the user can remove about grinding plate 4 and first depression bar 6 repeatedly, thereby can pulverize lime breast, and take out through extracting mechanism 8.

Example 2

On the basis of embodiment 1, as shown in fig. 4-8, the material pouring mechanism 7 includes a first fixing column 71, a motor 72, a flat belt 73, a first rotating shaft 74, a first missing gear 75, a second rotating shaft 76, a first straight gear 77, a clamping block 78, a third rotating shaft 79, a second spring 710, a second fixing column 711, a torsion spring 712, a first rotating rod 713, an arc-shaped sliding rail 714, a reaction frame 715 and a material supporting plate 716, the first fixing column 71 is disposed on the upper side of the right portion of the main frame 2, the motor 72 is disposed on the first fixing column 71, an output shaft of the motor 72 is rotatably connected with the main frame 2, the first rotating shaft 74 is rotatably disposed in the middle of the right portion of the main frame 2, belt pulleys are disposed on both the first rotating shaft 74 and the output shaft of the motor 72, the flat belt 73 is connected between the two belt pulleys, the first missing gear 75 is disposed on the first rotating shaft 74, the second rotating shaft 76 is rotatably disposed in the middle of the right portion of the main frame 2, the second rotating shaft 76 is positioned at the lower side of the first rotating shaft 74, the second rotating shaft 76 is provided with a first straight gear 77, the first straight gear 77 is meshed with the first gear 75, the second rotating shaft 76 is provided with a clamping block 78 in a sliding manner, a second spring 710 is connected between the clamping block 78 and the second rotating shaft 76, the top of the grinding frame 3 is provided with a reaction frame 715, the middle of the front sides of the left and right parts of the reaction frame 715 is provided with a second fixed column 711, the second fixed column 711 is provided with a third rotating shaft 79 in a rotating manner, the third rotating shaft 79 is connected with the clamping block 78 in a sliding manner, the left side of the third rotating shaft 79 is connected with the reaction frame 715 in a rotating manner, the right side of the third rotating shaft 79 is provided with a first rotating rod 713, the first rotating rod 713 is positioned at the right side of the reaction frame 715, a torsion spring 712 is connected between the first rotating rod 713 and the second fixed column 711 is connected between the torsion spring 712, the torsion spring 712 is sleeved on the third rotating shaft 79, the middle of the third rotating shaft 79 is provided with a material supporting plate 716, the upper side of the right part of the reaction frame 715 is provided with an arc-shaped sliding rail 714, the first rotating rod 713 is slidably coupled to the arc-shaped sliding rail 714.

The user can place lime cream in the reaction frame 715, then introduce carbon dioxide into the reaction frame 715, so that the lime cream reacts with the carbon dioxide to generate calcium carbonate precipitate, then start the motor 72, the output shaft of the motor 72 rotates, the first rotating shaft 74 and the first gear 75 are driven to rotate through the belt pulley and the flat belt 73, the first gear 75 is meshed with the first straight gear 77, the first gear 75 rotates one eighth of a circle, the first straight gear 77 rotates one circle, the first straight gear 77 drives the second rotating shaft 76 and the fixture block 78 to rotate, and further drives the third rotating shaft 79, the rotating rod and the retainer plate 716 to rotate, the torsion spring 712 deforms, at this time, the calcium carbonate precipitate above the retainer plate 716 can drop downwards into the grinding frame 3, when the first rotating rod 713 slides to the rear position of the arc-shaped sliding rail 714, the first rotating rod 713 can not rotate any more, because the motor 72 keeps the starting state all the time, at this time, the fixture block 78 moves inward, the second spring 710 is compressed, and at this time, the fixture block 78 is no longer connected to the third rotating shaft 79, so that under the reset action of the torsion spring 712, the third rotating shaft 79, the rotating rod and the retainer plate 716 rotate reversely to reset, when the first missing gear 75 is not meshed with the first straight gear 77, the retainer plate 716 is kept in a horizontal state all the time, at this time, the material can be continuously fed into the reaction frame 715, and the lime cream on the retainer plate 716 can react with the carbon dioxide for a certain time, when the second rotating shaft 76 drives the fixture block 78 to rotate again to be matched with the third rotating shaft 79, the second spring 710 drives the fixture block 78 to reset, the fixture block 78 is connected to the third rotating shaft 79 again, and the calcium carbonate can be continuously precipitated and poured into the grinding frame 3 by repeating the above steps.

The material taking mechanism 8 comprises a first sliding block 81, a blocking plate 82 and a first handle 83, the first sliding block 81 is arranged on the left side and the right side of the front part of the grinding frame 3 in a sliding mode, the blocking plate 82 is connected between the two first sliding blocks 81, and the first handle 83 is arranged in the middle of the front side of the blocking plate 82.

When the calcium carbonate precipitation in the grinding frame 3 is completely ground, the user can move the blocking plate 82 upward by the first handle 83, then take out the ground calcium carbonate, and then apply no force to the first handle 83, at which time the blocking plate 82 is moved downward to be reset.

Example 3

On the basis of embodiment 2, as shown in fig. 9 to 16, the polishing device further includes a gas injection mechanism 9, the gas injection mechanism 9 includes a third fixing column 91, an air cylinder 92, a gas pipe 93, a switch 94, a second pressure lever 95, a connecting rod 96 and a third spring 97, the third fixing column 91 is connected to the lower side of the rear portion of the polishing frame 3, the air cylinder 92 is arranged on the third fixing column 91, the gas pipe 93 is communicated between the front side of the air cylinder 92 and the polishing frame 3, the switch 94 is slidably arranged on the top of the gas pipe 93, the third spring 97 is connected between the switch 94 and the gas pipe 93, the second pressure lever 95 is connected to the rear side of the first rotating lever 713, and the connecting rods 96 are connected to the left and right sides of the switch 94.

When the first rotating rod 713 drives the second pressing rod 95 to rotate towards the rear side, the second pressing rod 95 is in contact with the connecting rod 96, the connecting rod 96 is pressed downwards, the switch 94 is further driven to move downwards, the third spring 97 is compressed, the switch 94 is started at the moment, carbon dioxide in the air storage cylinder 92 is ventilated to the reaction frame 715 through the air pipe 93, when the first rotating rod 713 drives the second pressing rod 95 to rotate towards the front side, the third spring 97 drives the switch 94 to move upwards, after the ventilation of the carbon dioxide is completed, a user can press the switch 94 again to close the carbon dioxide, and therefore the carbon dioxide in the air storage cylinder 92 is not ventilated to the reaction frame 715 through the air pipe 93 any more.

Still including unloading mechanism 10, unloading mechanism 10 is including fourth fixed column 101, storage case 102, the gear 103 is lacked to the second, straight-teeth gear 104, fourth pivot 105 and division board 106, equal fore-and-aft symmetry formula of 2 left and right sides inner wall upsides of main frame is equipped with fourth fixed column 101, be connected with storage case 102 between the fourth fixed column 101, storage case 102 bottom rear side rotation formula is equipped with fourth pivot 105, be equipped with division board 106 in the middle of the fourth pivot 105, fourth pivot 105 right side slidingtype is equipped with second straight-teeth gear 104, be equipped with the gear 103 is lacked to the second on the output shaft of motor 72, the gear 103 is lacked to the second and the meshing of second straight-teeth gear 104.

The user can place lime breast in storage case 102, motor 72 output shaft rotates and drives the second and lacks gear 103 and rotate, lack gear 103 and second straight-tooth gear 104 meshing through the second, make fourth pivot 105 rotate with division board 106, so lime breast in storage case 102 can intermittent type unloading to reaction frame 715 in, when second lacks gear 103 and second straight-tooth gear 104 meshing, fourth pivot 105 and division board 106 no longer rotate this moment, and no longer with lime breast unloading to reaction frame 715 in, so can realize the effect of automatic unloading.

The separation mechanism 11 is further included, the separation mechanism 11 includes a second rotating rod 111, a push plate 112 and a fourth spring 113, the second rotating rod 111 is connected to the front side of the first rotating rod 713, the push plate 112 is slidably arranged on the right side of the fourth rotating shaft 105, the push plate 112 is located on the left side of the second straight gear 104, and the fourth spring 113 is connected between the push plate 112 and the fourth rotating shaft 105.

The first rotating rod 713 drives the second rotating rod 111 to rotate towards the rear side, the second rotating rod 111 pushes the push plate 112 towards the right side, so that the push plate 112 pushes the second straight gear 104 towards the right side, the fourth spring 113 is stretched, at this time, the second straight gear 104 is not meshed with the second missing gear 103, when the second rotating rod 111 rotates towards the front side to reset, the second rotating rod 111 does not abut against the push plate 112 any more, the push rod moves towards the left side to reset under the resetting action of the fourth spring 113, in the process that the second straight gear 104 is separated from the second missing gear 103, the milk of lime is reacting with carbon dioxide, and a user can manually move the second straight gear 104 towards the left side, so that the second straight gear 104 can be continuously meshed with the second missing gear 103.

Still including stop gear 12, stop gear 12 is including fifth fixed column 121, pull ring 122, card post 123, fifth spring 124, first wedge 125 and second wedge 126, grind the anterior upside bilateral symmetry formula of frame 3 and be equipped with fifth fixed column 121, it all is equipped with card post 123 all to slide on the fifth fixed column 121, card post 123 rear side all is equipped with first wedge 125, be connected with fifth spring 124 between first wedge 125 all and the fifth fixed column 121, fifth spring 124 all overlaps on card post 123, card post 123 front side all is connected with pull ring 122, separation plate 82 top bilateral symmetry formula is equipped with second wedge 126.

When the blocking plate 82 drives the second wedge-shaped block 126 to move upwards, the second wedge-shaped block 126 abuts against the first wedge-shaped block 125, and pushes the first wedge 125 and the catch 123 to the front side, so that the fifth spring 124 is compressed, when the second wedge 126 is moved upward not to contact the first wedge 125, under the reset action of the fifth spring 124, the first wedge-shaped block 125 and the clamping column 123 move to the rear side for resetting, in this way, the first wedge 125 and the second wedge 126 are combined, so that the blocking plate 82 does not move downward, the user can take out the ground calcium carbonate conveniently, the user can pull the pull ring 122, so that the catch 123 and the first wedge 125 no longer abut against the second wedge 126, the fifth spring 124 is compressed, when the blocking plate 82 moves downwards to reset, the user does not apply force to the pull ring 122 any more, and the fifth spring 124 drives the first wedge-shaped block 125 and the clamping column 123 to move backwards to reset.

Still including closing mechanism 13, closing mechanism 13 is equipped with second slider 132 including closing cap 131, second slider 132 and second handle 133, the equal slidingtype second slider 132 that is equipped with in the storage case 102 top left and right sides, is connected with closing cap 131 between two second sliders 132, and closing cap 131 top rear side is equipped with second handle 133.

The user can pull the second handle 133 to pull the cover 131 to the rear side, and then the user can place the lime cream in the storage tank 102, and after the placement is completed, the user moves the cover 131 reversely to reset through the second handle 133.

The above description is only an example of the present invention and is not intended to limit the present invention. All equivalents which come within the spirit of the invention are therefore intended to be embraced therein. Details not described herein are well within the skill of those in the art.

Claims

1. The utility model provides a building calcium carbonate draws and uses lime cream carbonization reacting furnace which characterized in that: comprises the following steps:

the supporting frame (1) and the main frame (2) are arranged, and the supporting frame (1) is symmetrically arranged at the bottom of the main frame (2); the grinding frame (3), the first pressure lever (6) of the grinding frame (3) is arranged at the bottom in the main frame (2), and two first pressure levers (6) are arranged on one side of the main frame (2) in a sliding manner; the grinding plate (4) is connected between the two first pressure rods (6), and the grinding plate (4) is in sliding contact with the inner bottom of the grinding frame (3); two first springs (5) are connected between the grinding plate (4) and the main frame (2); the material pouring mechanism (7), the main frame (2) is provided with the material pouring mechanism (7); the material taking mechanism (8) is arranged on the front side of the grinding frame (3).

2. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 1, wherein: the material pouring mechanism (7) comprises:

the first fixing column (71), the main frame (2) is provided with the first fixing column (71); the motor (72) is arranged on the first fixing column (71), and an output shaft of the motor (72) is rotatably connected with the main frame (2); a first rotating shaft (74), wherein the middle of one side of the main frame (2) is rotatably provided with the first rotating shaft (74); belt pulleys are arranged on the flat belt (73), the first rotating shaft (74) and the output shaft of the motor (72), and the flat belt (73) is connected between the two belt pulleys; the first gear (75) is arranged on the first rotating shaft (74); the middle of one side, close to the first rotating shaft (74), of the main frame (2) is rotatably provided with the second rotating shaft (76), and the second rotating shaft (76) is positioned on the lower side of the first rotating shaft (74); the first straight gear (77) is arranged on the second rotating shaft (76), and the first straight gear (77) is meshed with the first gear (75); the fixture block (78) is arranged on the second rotating shaft (76) in a sliding mode; the second spring (710) is connected between the clamping block (78) and the second rotating shaft (76); the top of the grinding frame (3) is provided with a reaction frame (715); the middle of the front sides of the left and right parts of the reaction frame (715) is provided with a second fixing column (711) and a third rotating shaft (79), the second fixing column (711) is rotatably provided with the third rotating shaft (79), the third rotating shaft (79) is connected with the clamping block (78) in a sliding manner, and the third rotating shaft (79) is rotatably connected with the reaction frame (715); the first rotating rod (713) is arranged on the third rotating shaft (79), and the first rotating rod (713) is positioned on the outer side of the reaction frame (715); a torsion spring (712) is connected between the first rotating rod (713) and the second fixing column (711), and the torsion spring (712) is sleeved on the third rotating shaft (79); the third rotating shaft (79) is provided with a material supporting plate (716); the reaction frame (715) is provided with an arc-shaped sliding rail (714), the upper side of the reaction frame (714) is provided with the arc-shaped sliding rail (714), and the first rotating rod (713) is connected with the arc-shaped sliding rail (714) in a sliding manner.

3. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 2, wherein: the material taking mechanism (8) comprises:

the first sliding block (81) is arranged on both sides of the grinding frame (3) in a sliding manner; the blocking plate (82) is connected between the two first sliding blocks (81); the middle of one side of the baffle plate (82) is provided with a first handle (83).

4. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 3, wherein: still including gas injection mechanism (9), gas injection mechanism (9) including:

the lower side of the grinding frame (3) is connected with a third fixing column (91); the air cylinder (92) is arranged on the third fixing column (91); the air pipe (93) is communicated between the air cylinder (92) and the grinding frame (3); the switch (94), the top of the air pipe (93) is provided with a switch (94) in a sliding way; a third spring (97), and the third spring (97) is connected between the switch (94) and the air delivery pipe (93); one side of the first rotating rod (713) is connected with the second pressure rod (95); the connecting rod (96) is connected with both sides of the switch (94).

5. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 4, wherein: still including unloading mechanism (10), unloading mechanism (10) including:

the upper sides of the inner walls of the two sides of the main frame (2) are symmetrically provided with the fourth fixing columns (101); the storage box (102) is connected between the fourth fixing columns (101); a fourth rotating shaft (105), wherein the bottom of the storage box (102) is rotatably provided with the fourth rotating shaft (105); the middle of the fourth rotating shaft (105) is provided with a separation plate (106); the fourth rotating shaft (105) is provided with a second straight gear (104) in a sliding manner; a second gear (103) is arranged on the output shaft of the motor (72); and the second spur gear (104), and the second missing gear (103) is meshed with the second spur gear (104).

6. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 5, wherein: still including breaking away from mechanism (11), breaking away from mechanism (11) including:

the first rotating rod (713) is connected with the second rotating rod (111); the push plate (112) is arranged on one side of the fourth rotating shaft (105) in a sliding mode, and the push plate (112) is located on the left side of the second straight gear (104); and a fourth spring (113) is connected between the push plate (112) and the fourth rotating shaft (105).

7. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 6, wherein: still including stop gear (12), stop gear (12) including:

the fifth fixing columns (121), the fifth fixing columns (121) are symmetrically arranged on the upper side of the grinding frame (3); the clamping columns (123) are arranged on the fifth fixing column (121) in a sliding manner; the first wedge-shaped block (125) is arranged on each clamping column (123); fifth springs (124) are connected between the first wedge blocks (125) and the fifth fixing columns (121), and the fifth springs (124) are sleeved on the clamping columns (123); the pull rings (122) are connected to the pull rings (122) and the clamping columns (123); the top of the second wedge-shaped block (126) and the top of the blocking plate (82) are symmetrically provided with the second wedge-shaped block (126).

8. The lime milk carbonization reaction furnace for extracting architectural calcium carbonate as claimed in claim 7, wherein: still including closing mechanism (13), closing mechanism (13) including:

the second sliding blocks (132) are arranged on two sides of the top of the storage box (102) in a sliding manner; the sealing cover (131) is connected between the two second sliding blocks (132); the second handle (133), the top of the cover (131) is provided with the second handle (133).