CN113771185A

CN113771185A - Gypsum slat production facility

Info

Publication number: CN113771185A
Application number: CN202110831037.9A
Authority: CN
Inventors: 张永会
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-07-22
Filing date: 2021-07-22
Publication date: 2021-12-10

Abstract

The invention discloses gypsum batten production equipment, relates to the technical field of building material production equipment, and aims to solve the problems that raw materials are not easy to stir more uniformly by traditional gypsum batten production equipment. The automatic core pulling machine can stir raw materials more uniformly, improves the quality of gypsum battens, realizes automatic core pulling, reduces the task load of workers, cleans a core body, avoids the influence of slurry on the core body on secondary pouring, uniformly shakes the slurry, reduces the generation of bubbles, is convenient for forming the gypsum battens, reduces the generation of defective products, can perform automatic demoulding, conveys the gypsum battens away and is convenient for the workers to work next step.

Description

Gypsum slat production facility

Technical Field

The invention relates to the technical field of building material production equipment, in particular to gypsum batten production equipment.

Background

The gypsum lath is a kind of gypsum board, it is a kind of gypsum board, regard building gypsum as the substrate, mix with the inorganic light aggregate, the hollow lath made of inorganic fiber reinforcement, mainly used in the non-bearing inner wall of the building, regard gypsum hollow lath as the inner partition wall of the building, except having the same advantage with gypsum block, its weight in the unit area is lighter, the efficiency of construction is higher, can make the building dead weight lighten, the foundation bears the weight and diminishes, can reduce the construction cost effectively. The length of the lath is determined according to the storey height of the building, so that the construction efficiency is higher.

But traditional gypsum lath production facility is difficult for making raw materials stirring more even to reduce the quality of gypsum lath, be difficult for realizing automatic loosing core, increased staff's task volume, and pouring the in-process, be difficult for evenly shaking slurry, thereby easily produce the bubble, for this reason, provided a gypsum lath production facility and solved above scheduling problem.

Disclosure of Invention

Objects of the invention

In order to solve the technical problems in the background art, the invention provides gypsum batten production equipment, which can enable raw materials to be stirred more uniformly, improve the quality of gypsum battens, realize automatic core pulling, reduce the task load of workers, clean a core body, avoid the influence of slurry on the core body on secondary pouring, uniformly vibrate the slurry, reduce the generation of bubbles, facilitate the molding of the gypsum battens, reduce the generation of defective products, can carry out automatic demolding, convey the gypsum battens away and facilitate the next-step work of the workers.

(II) technical scheme

The invention provides gypsum batten production equipment which comprises a first box body, a first partition plate, a first movable plate, a movable rod and a support column, wherein a double-shaft motor is fixedly connected to the top of the first box body, the double-shaft motor is started to enable a third gear to rotate, the output end of the bottom of the double-shaft motor is welded with the third gear, the top of the first partition plate is rotatably connected with a stirring box, the top of the first partition plate is fixedly connected with two water tanks, the top of the first movable plate is fixedly connected with a second box body, one side, close to each other, of the movable rod is welded with a core body penetrating through and extending into the second box body, the core body can move left and right to complete core pulling, a push rod motor is fixedly connected to the inner wall of the front side of the first box body, and the push rod motor can withdraw formed gypsum.

Preferably, the welding of double-shaft motor's top output end has first belt pulley, and first belt pulley rotates and to make the sixth belt pulley rotate, the welding of the bottom of third gear has the set-square pole, the second gear has all been welded to the three-end of set-square pole, the bottom fixedly connected with stirring roller of set-square pole.

Preferably, the both sides of first baffle and the both sides inner wall fixed connection of first box, the bottom fixedly connected with passage of first baffle, the passage is put through with the agitator tank mutually, two feeders of the top fixedly connected with of first box, the equal fixedly connected with connecting pipe in bottom of feeder hopper, the one end and the agitator tank fixed connection of feeder hopper are kept away from to the connecting pipe, annular through hole has been seted up to the outer lane of agitator tank, makes things convenient for the feeding.

Preferably, the bottom fixedly connected with control door of water tank, the water pipe that runs through and extend to first baffle bottom has been cup jointed to the bottom of water tank, the even five shower nozzles of fixedly connected with in bottom of water pipe wash the core, one side fixedly connected with that keeps away from each other of water tank runs through and extends to the outer inlet tube of first box, the delivery port has been seted up to the bottom of first box.

Preferably, the bottom both sides of first baffle are rotated and are connected with two sets of second belt pulleys and third belt pulley, the both sides inner wall sliding connection of first box has first fly leaf, the bottom of third belt pulley all welds the first pivot that runs through and extend to first fly leaf bottom, first pivot is rotated and is made first bevel gear rotate, the first bevel gear of bottom fixedly connected with of first pivot, the threaded rod is all welded to the bottom of second belt pulley, the third belt pulley rotates and to make the second belt pulley rotate, the second belt pulley rotates and to make the threaded rod rotate, the screwed pipe has been cup jointed to the outer lane screw of threaded rod, one side sliding connection that the screwed pipe is close to each other has the apron, the one end of keeping away from first baffle of stock guide and the top fixed connection of apron.

Preferably, one side fixedly connected with that the solenoid kept away from each other runs through and extends to the head rod of first fly leaf bottom, the one end fixedly connected with second fly leaf that the solenoid was kept away from to the head rod, the front and the inner wall sliding connection of first box have two first racks, the one end sliding connection that first rack is close to each other has the movable rod, the bottom of movable rod and the top sliding connection of first fly leaf.

Preferably, the front and back inner walls of the first box body are rotatably connected with two first gears, the left inner wall of the first box body is rotatably connected with a second rotating shaft which penetrates through and extends out of the first box body, the second rotating shaft rotates to enable the cams to rotate, the outer ring of the second rotating shaft is welded with two cams, two second bevel gears and a fourth bevel gear, and the right end of the second rotating shaft is fixedly connected with a fifth belt pulley.

Preferably, the first fixed cover of back fixedly connected with of first box, the third pivot has been cup jointed to the inner circle of first fixed cover, the sixth belt pulley rotates and to make the third pivot rotate, the top welding of third pivot has the sixth belt pulley, the bottom fixedly connected with fifth bevel gear of third pivot, the third pivot rotates and to make fifth bevel gear rotate.

Preferably, the top of support column is rotated and is connected with the fifth pivot, the right-hand member welding of fifth pivot has the fourth belt pulley, and the conveyer belt has been cup jointed to the outer lane of fifth pivot, the conveyer belt rotates and to transport fashioned gypsum board away, makes things convenient for the staff to carry out work on next step, the fourth pivot has been cup jointed to the back of first box, third bevel gear has all been welded at the both ends of fourth pivot.

Preferably, the inner walls of the two sides of the first box body are welded with first springs, one ends, close to each other, of the first springs are welded with fixed contact pieces, the two sides of each fixed contact piece are connected with support rods in a sliding mode, one ends, far away from each other, of the support rods are fixedly connected with the inner walls of the two sides of the first box body, the fixed contact pieces are electrically connected with the control door, one sides, far away from each other, of the movable rods are fixedly connected with movable contact pieces, the movable contact pieces move in opposite directions and can be in contact with the fixed contact pieces, therefore, the control door in the water tank is opened, water in the water tank is sprayed out through the spray head, and the core body is cleaned.

Compared with the prior art, the technical scheme of the invention has the following beneficial technical effects:

1. the device passes through double-shaft motor, agitator tank, third gear, stirring roller isotructure, wherein starts through double-shaft motor and can make third gear revolve, and third gear revolve can make the set-square pole rotate, and the set-square pole rotates and can make second gear revolve and stirring roller rotate, and second gear revolve ability can make agitator tank antiport to with raw materials stirring more even, improve the quality of gypsum slat.

2. The device passes through threaded rod, screwed pipe, head rod and first gear isotructure, wherein rotates through the threaded rod and to make screwed pipe up-and-down motion, and screwed pipe up-and-down motion makes head rod up-and-down motion when making, and head rod up-and-down motion can make first gear revolve, and first gear revolve movable rod side-to-side motion, movable rod side-to-side motion can make the core side-to-side motion, realizes automatic loosing core, has reduced staff's task volume.

3. The device passes through structures such as water tank, core, control door and fixed contact, wherein can make movable contact move in opposite directions through the movable rod motion in opposite directions, and movable contact move in opposite directions can contact with fixed contact to make the control door in the water tank open, make the water in the water tank pass through the shower nozzle blowout, wash the core, avoid thick liquids on the core to influence the secondary and pour.

4. The device passes through biax motor, the cam, first fly leaf and second pivot isotructure, wherein start through biax motor and to make the fourth pivot rotate, thereby can make positive third bevel gear rotate, positive third bevel gear can rotate and can make fourth bevel gear rotate, fourth bevel gear rotates and can make the second pivot rotate, the second pivot is rotated and can be made second bevel gear and cam rotation, rotate through the cam and make first fly leaf up-and-down motion, evenly shake the thick liquids, the gypsum lath shaping of being convenient for has reduced the production of substandard product.

5. The device passes through push rod motor, second pivot, fifth belt pulley and conveyer belt isotructure, wherein when the gypsum slat breaks away from the second box, start the push rod motor, the push rod motor starts to move the gypsum slat to the conveyer belt on, the second pivot is rotated and is made and to be able to make the fourth belt pulley rotate, the fourth belt pulley rotates and to be able to make the fifth pivot rotate, the fifth rotates and to be able to make the conveyer belt rotate to transport the gypsum slat away, make things convenient for the staff to carry out work on next step.

6. To sum up, the device can make raw materials stirring more even, improves the quality of gypsum lath, realizes loosing core automatically, has reduced staff's task volume, washs the core, avoids the thick liquids on the core to influence the secondary and pours, evenly shakes slurry, has reduced the production of bubble, and the gypsum lath shaping of being convenient for has reduced the production of substandard product, can carry out the automatic drawing of patterns, transports the gypsum lath away, makes things convenient for staff to carry out work on next step.

Drawings

FIG. 1 is a schematic front view of a gypsum lath production facility according to the present invention.

FIG. 2 is a schematic diagram of a side view of a part of a gypsum lath production apparatus according to the present invention.

FIG. 3 is a schematic top view of a part of a gypsum lath manufacturing apparatus according to the present invention.

FIG. 4 is an enlarged partial view of a part A of a gypsum lath manufacturing apparatus according to the present invention.

FIG. 5 is a schematic view of a partial bottom view of a gypsum lath manufacturing apparatus according to the present invention.

FIG. 6 is a top view of the first right gear of the apparatus for producing gypsum lath according to the present invention.

FIG. 7 is a schematic top view of the left first rack of the apparatus for producing gypsum lath according to the present invention.

Reference numerals: 1. a first case; 2. a first pulley; 3. a double-shaft motor; 4. a stirring box; 5. a stirring roller; 6. a second pulley; 7. a water tank; 8. a first separator; 9. a third belt pulley; 10. a fourth belt pulley; 11. a first rotating shaft; 12. a first gear; 13. a first movable plate; 14. a first bevel gear; 15. a fifth belt pulley; 16. a second rotating shaft; 17. a second bevel gear; 18. a first connecting rod; 19. a cam; 20. a second case; 21. a third bevel gear; 22. a fourth bevel gear; 23. a second movable plate; 24. a core body; 25. a movable rod; 26. A first rack; 27. a solenoid; 28. a cover plate; 29. a threaded rod; 30. a push rod motor; 31. A sixth belt pulley; 32. a third rotating shaft; 33. a first fixing sleeve; 34. a fifth bevel gear; 35. A support pillar; 36. a fourth rotating shaft; 37. a triangular rod; 38. a second gear; 39. a third gear.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Example 1: as shown in fig. 1 and 5, a first belt pulley 2 is welded at the top output end of a double-shaft motor 3, the double-shaft motor 3 is started to enable a third gear 39 and the first belt pulley 2 to rotate, a triangular rod 37 is welded at the bottom of the third gear 39, the third gear 39 rotates to enable the triangular rod 37 to rotate, second gears 38 are welded at three ends of the triangular rod 37, the triangular rod 37 rotates to enable the second gear 38 and a stirring roller 5 to rotate, the stirring roller 5 is fixedly connected at the bottom of the triangular rod 37, and the stirring box 4 can rotate in the reverse direction due to the rotation of the second gear 38, so that raw materials are stirred more uniformly, and the quality of gypsum laths is improved;

example 2: as shown in figures 1 and 4, two sides of a first clapboard 8 are fixedly connected with inner walls at two sides of a first box body 1, a material guide pipe is fixedly connected at the bottom of the first clapboard 8 and is communicated with a stirring box 4, two feed hoppers are fixedly connected at the top of the first box body 1 and are communicated with the first box body 1, a control door is fixedly connected at the bottom of a water tank 7, a water pipe which penetrates through and extends to the bottom of the first clapboard 8 is sleeved at the bottom of the water tank 7, five spray heads are uniformly and fixedly connected at the bottom of the water pipe, a water inlet pipe which penetrates through and extends out of the first box body 1 is fixedly connected at one side of the water tank 7 which is far away from each other, first springs are welded at the inner walls at two sides of the first box body 1, a fixed contact piece is welded at one end of the first springs which is close to each other, support rods are slidably connected at two sides of the fixed contact piece, one end of the support rods which is far away from each other is fixedly connected with the inner walls at two sides of the first box body 1, the fixed contact piece is electrically connected with the control door, one sides of the movable rods 25, which are far away from each other, are fixedly connected with movable contact pieces, and the movable contact pieces move in opposite directions and can be contacted with the fixed contact pieces, so that the control door in the water tank 7 is opened, water in the water tank 7 is sprayed out through the spray head, the core body 24 is cleaned, and secondary pouring is prevented from being influenced by slurry on the core body 24;

example 3: as shown in fig. 1, 6 and 7, two sets of second belt pulleys 6 and third belt pulleys 9 are rotatably connected to two sides of the bottom of the first partition 8, the third belt pulleys 9 are rotatable to enable the second belt pulleys 6 to rotate, first movable plates 13 are slidably connected to inner walls of two sides of the first box 1, first rotating shafts 11 penetrating and extending to the bottoms of the first movable plates 13 are welded to the bottoms of the third belt pulleys 9, the third belt pulleys 9 are rotatable by the rotation of the first rotating shafts 11, first bevel gears 14 are fixedly connected to the bottoms of the first rotating shafts 11, the first rotating shafts 11 are rotatable by the rotation of the first bevel gears 14, threaded rods 29 are welded to the bottoms of the second belt pulleys 6, the threaded rods 29 are rotatable by the rotation of the second belt pulleys 6, screw tubes 27 are sleeved on outer ring threads of the threaded rods 29, the screw tubes 27 are movable up and down by the rotation of the threaded rods 29, a cover plate 28 is slidably connected to one side of the screw tubes 27 close to each other, the screw 27 moves up and down to move the cover plate 28 up and down, one end of the material guide plate far away from the first partition plate 8 is fixedly connected with the top of the cover plate 28, one side of the screw 27 far away from each other is fixedly connected with a first connecting rod 18 penetrating and extending to the bottom of the first movable plate 13, one end of the first connecting rod 18 far away from the screw 27 is fixedly connected with a second movable plate 23, a first rack 26 moves to move a movable rod 25, the front and inner walls of the first box 1 are slidably connected with two first racks 26, one end of the first rack 26 close to each other is slidably connected with the movable rod 25, the bottom of the movable rod 25 is slidably connected with the top of the first movable plate 13, the front and inner walls of the first box 1 are rotatably connected with two first gears 12, the first gear 12 can rotate by the up and down movement of the first connecting rod 18, the first gear 12 rotates the movable rod 25 to move left and right, the movable rod 25 moves left and right to enable the core body 24 to move left and right, so that automatic core pulling is realized, and the task load of workers is reduced;

example 4: as shown in fig. 1, a second rotating shaft 16 penetrating and extending to the outside of the first box 1 is rotatably connected to the inner wall of the left side of the first box 1, the second rotating shaft 16 can rotate to enable a cam 19, a second bevel gear 17 and a fourth bevel gear 22 to rotate, two cams 19, two second bevel gears 17 and a fourth bevel gear 22 are welded to the outer ring of the second rotating shaft 16, a fifth belt pulley 15 is fixedly connected to the right end of the second rotating shaft 16, the fifth belt pulley 15 can rotate due to the rotation of the second rotating shaft 16, the first movable plate 13 moves up and down due to the rotation of the cam 19 to uniformly vibrate slurry, so that the gypsum lath can be conveniently molded, and the generation of defective products is reduced;

example 5: as shown in fig. 1 and 2, a first fixing sleeve 33 is fixedly connected to the back of the first box 1, a third rotating shaft 32 is sleeved on an inner ring of the first fixing sleeve 33, a sixth belt pulley 31 rotates to enable the third rotating shaft 32 to rotate, a sixth belt pulley 31 is welded on the top of the third rotating shaft 32, a fifth bevel gear 34 rotates to enable a fifth bevel gear 34 to rotate, the back third bevel gear 21 rotates due to the rotation of the fifth bevel gear 34, a fifth bevel gear 34 is fixedly connected to the bottom of the third rotating shaft 32, a fifth rotating shaft is rotatably connected to the top of a supporting pillar 35, a fourth belt pulley 10 is welded on the right end of the fifth rotating shaft, the fifth rotating shaft rotates due to the rotation of the fourth belt pulley 10, a conveyor belt is sleeved on an outer ring of the fifth rotating shaft, a fourth rotating shaft 36 is sleeved on the back of the first box 1, the fourth rotating shaft 36 rotates to enable the third bevel gear 21 to rotate, the fourth bevel gear 22 rotates due to the rotation of the third bevel gear 21, third bevel gears 21 are welded at two ends of the fourth rotating shaft 36, and the conveyor belt can rotate by rotating the fifth rotating shaft, so that the gypsum lath is carried away, and workers can work next step conveniently.

In the invention, raw materials of gypsum lathes are poured into a stirring box 4 through a feed hopper, a double-shaft motor 3 is started, the double-shaft motor 3 is started to enable a third gear 39 and a first belt pulley 2 to rotate, the first belt pulley 2 rotates to enable a sixth belt pulley 31 to rotate, the sixth belt pulley 31 rotates to enable a third rotating shaft 32 to rotate, the third rotating shaft 32 rotates to enable a fifth bevel gear 34 to rotate a back third bevel gear 21 to rotate, the back third bevel gear 21 rotates to enable a fourth rotating shaft 36 to rotate, the fourth rotating shaft 36 rotates to enable a front third bevel gear 21 to rotate, the front third bevel gear 21 rotates to enable a fourth bevel gear 22 to rotate, the fourth bevel gear 22 rotates to enable a second rotating shaft 16 to rotate, the second rotating shaft 16 rotates to enable a second bevel gear 17 and a cam 19 to rotate, the second bevel gear 17 rotates to enable a first bevel gear 14 to rotate, the first bevel gear 14 rotates to enable the first rotating shaft 11 to rotate, the rotation of the first rotating shaft 11 can enable the third belt pulley 9 to rotate, the rotation of the third belt pulley 9 can enable the second belt pulley 6 to rotate, the rotation of the second belt pulley 6 can enable the threaded rod 29 to rotate, and the rotation of the threaded rod 29 can enable the screw pipe 27 to move up and down;

when the screw 27 moves downwards to enable the screw to move downwards, the first connecting rod 18 moves downwards to enable the first gear 12 to rotate, the first gear 12 rotates to enable the first rack 26 to move relatively, the first rack 26 moves relatively to enable the movable rod 25 to move relatively, the movable rod 25 moves relatively to enable the core 24 to move relatively, after raw materials are stirred, a control door at the bottom of the stirring box 4 is controlled to enable slurry to enter the second box body 20 through the material guide pipe, the first movable plate 13 moves up and down through the rotation of the cam 19 to uniformly vibrate the slurry, after gypsum laths are formed, the screw 27 moves upwards to enable the first gear 12 to rotate, the first gear 12 rotates to enable the first rack 26 to move oppositely, the first rack 26 moves oppositely to enable the movable rod 25 to move oppositely, and the movable rod 25 moves oppositely to enable the core 24 to move oppositely, the core body 24 can be separated from the second box body 20 by the movement of the core body 24 in the opposite direction, the movable rods 25 can be moved in the opposite direction to make the movable contact pieces move in the opposite direction, the movable contact pieces can be contacted with the fixed contact pieces by the movement of the movable contact pieces in the opposite direction, so that the control door in the water tank 7 is opened, water in the water tank 7 is sprayed out through the spray head, the core body 24 is cleaned, meanwhile, the screw pipe 27 moves upwards to make the first connecting rod 18 move upwards, the first connecting rod 18 moves upwards to make the second movable plate 23 move upwards, the second movable plate 23 moves upwards to make the formed gypsum lath move upwards, when the gypsum lath is separated from the second box body 20, the push rod motor 30 is started to move the gypsum lath to the conveying belt, the second rotating shaft 16 rotates to make the fifth belt pulley 15 rotate, the fifth belt pulley 15 rotates to make the fourth belt pulley 10 rotate to make the fifth rotating shaft rotate, the fifth rotational rotation can rotate the conveyor belt to carry the gypsum lath away.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such changes and modifications that fall within the scope and bounds of the appended claims, or equivalents of such scope and bounds.

Claims

1. The utility model provides a gypsum lath production facility, includes first box (1), first baffle (8), first fly leaf (13), movable rod (25) and support column (35), a serial communication port, top fixedly connected with double-shaft motor (3) of first box (1), the welding of the bottom output of double-shaft motor (3) has third gear (39), the top of first baffle (8) is rotated and is connected with agitator tank (4), two water tank (7) of top fixedly connected with of first baffle (8), the top fixedly connected with second box (20) of first fly leaf (13), one side welding that movable rod (25) are close to each other has core (24) that run through and extend to in second box (20), the positive inner wall fixedly connected with push rod motor (30) of first box (1).

2. The gypsum lath producing device as claimed in claim 1, wherein a first belt pulley (2) is welded at the top output end of the double-shaft motor (3), a triangular rod (37) is welded at the bottom of the third gear (39), a second gear (38) is welded at the three ends of the triangular rod (37), and a stirring roller (5) is fixedly connected at the bottom of the triangular rod (37).

3. The gypsum lath production equipment as claimed in claim 1, wherein two sides of the first partition plate (8) are fixedly connected with inner walls of two sides of the first box body (1), a material guiding pipe is fixedly connected with the bottom of the first partition plate (8), the material guiding pipe is communicated with the stirring box (4), two feeding hoppers are fixedly connected with the top of the first box body (1), connecting pipes are fixedly connected with the bottoms of the feeding hoppers, one ends of the connecting pipes, far away from the feeding hoppers, are fixedly connected with the stirring box (1), and annular through holes are formed in the outer ring of the stirring box (4).

4. The gypsum lath production equipment as claimed in claim 1, wherein a control door is fixedly connected to the bottom of the water tank (7), a water pipe penetrating through and extending to the bottom of the first partition plate (8) is sleeved on the bottom of the water tank (7), five nozzles are uniformly and fixedly connected to the bottom of the water pipe, a water inlet pipe penetrating through and extending to the outside of the first box body (1) is fixedly connected to one side of the water tank (7) far away from each other, and a water outlet is formed in the bottom of the first box body (1).

5. The gypsum lath producing equipment as claimed in claim 3, wherein two sets of second pulleys (6) and third pulleys (9) are rotatably connected to two sides of the bottom of the first partition (8), the inner walls of two sides of the first box body (1) are connected with a first movable plate (13) in a sliding way, the bottom of the third belt pulley (9) is welded with a first rotating shaft (11) which penetrates through and extends to the bottom of the first movable plate (13), the bottom of the first rotating shaft (11) is fixedly connected with a first bevel gear (14), threaded rods (29) are welded at the bottoms of the second belt pulleys (6), spiral tubes (27) are sleeved on the outer ring threads of the threaded rods (29), one side of the screw pipes (27) close to each other is connected with a cover plate (28) in a sliding way, one end of the material guide plate, which is far away from the first partition plate (8), is fixedly connected with the top of the cover plate (28).

6. The gypsum lath producing equipment as claimed in claim 5, wherein one side of the screw pipes (27) far away from each other is fixedly connected with a first connecting rod (18) which penetrates through and extends to the bottom of the first movable plate (13), one end of the first connecting rod (18) far away from the screw pipes (27) is fixedly connected with a second movable plate (23), the front surface and the inner wall of the first box body (1) are slidably connected with two first racks (26), one end of the first racks (26) close to each other is slidably connected with a movable rod (25), and the bottom of the movable rod (25) is slidably connected with the top of the first movable plate (13).

7. The gypsum lath producing device as claimed in claim 6, wherein the front and back inner walls of the first box (1) are rotatably connected with two first gears (12), the left inner wall of the first box (1) is rotatably connected with a second rotating shaft (16) which penetrates through and extends out of the first box (1), the outer ring of the second rotating shaft (16) is welded with two cams (19), two second bevel gears (17) and a fourth bevel gear (22), and the right end of the second rotating shaft (16) is fixedly connected with a fifth belt pulley (15).

8. The gypsum lath producing device as claimed in claim 1, wherein a first fixing sleeve (33) is fixedly connected to the back of the first box (1), a third rotating shaft (32) is sleeved on the inner ring of the first fixing sleeve (33), a sixth belt pulley (31) is welded on the top of the third rotating shaft (32), and a fifth bevel gear (34) is fixedly connected to the bottom of the third rotating shaft (32).

9. The gypsum lath production equipment as claimed in claim 1, wherein a fifth rotating shaft is rotatably connected to the top of the supporting column (35), a fourth belt pulley (10) is welded to the right end of the fifth rotating shaft, a conveyor belt is sleeved on the outer ring of the fifth rotating shaft, a fourth rotating shaft (36) is sleeved on the back surface of the first box body (1), and third bevel gears (21) are welded to both ends of the fourth rotating shaft (36).

10. The apparatus for producing gypsum lath according to claim 2, claim 4, claim 7, claim 8 and claim 9, wherein the raw material of gypsum lath is poured into the stirring tank 4 through the hopper, the biaxial motor 3 is started to rotate the third gear 39 and the first pulley 2, the first pulley 2 is rotated to rotate the sixth pulley 31, the sixth pulley 31 is rotated to rotate the third shaft 32, the third shaft 32 is rotated to rotate the fifth bevel gear 34 to rotate the rear third bevel gear 21, the rear third bevel gear 21 is rotated to rotate the fourth shaft 36, the fourth shaft 36 is rotated to rotate the front third bevel gear 21, the front third bevel gear 21 is rotated to rotate the fourth bevel gear 22, and the fourth bevel gear 22 is rotated to rotate the second shaft 16, rotation of the second shaft 16 rotates the second bevel gear 17 and the cam 19, rotation of the second bevel gear 17 rotates the first bevel gear 14, rotation of the first bevel gear 14 rotates the first shaft 11, rotation of the first shaft 11 rotates the third pulley 9, rotation of the third pulley 9 rotates the second pulley 6, rotation of the second pulley 6 rotates the threaded rod 29, and rotation of the threaded rod 29 moves the threaded pipe 27 up and down.