CN116922557A

CN116922557A - Gypsum board shaping belt feeder

Info

Publication number: CN116922557A
Application number: CN202311180962.5A
Authority: CN
Inventors: 李静; 王衍学; 刘智慧; 赵俊旺
Original assignee: Taishan Gypsum Xinzhou Co ltd
Current assignee: Taishan Gypsum Xinzhou Co ltd
Priority date: 2023-09-14
Filing date: 2023-09-14
Publication date: 2023-10-24
Anticipated expiration: 2043-09-14
Also published as: CN116922557B

Abstract

The application relates to a gypsum board forming belt conveyor, which relates to the field of gypsum board production equipment and comprises a base, wherein a conveying mechanism is arranged on the base and used for conveying gypsum boards, a driving mechanism is connected to the conveying mechanism and is arranged on the base, a cutting mechanism is arranged on the driving mechanism and used for cutting the gypsum boards; wherein, actuating mechanism includes: the driving bracket is fixedly arranged on the base; the sliding plate is slidably arranged on the driving bracket, and a double-sided rack is fixedly arranged on the sliding plate; the two driven half gears are symmetrically arranged on two sides of the double-sided rack, and the two driven half gears can be meshed with the double-sided rack. The application has the effect of improving the quality and efficiency of the gypsum board belt conveyor on the finished product of the gypsum board.

Description

Gypsum board shaping belt feeder

Technical Field

The application relates to the field of gypsum board production equipment, in particular to a gypsum board forming belt conveyor.

Background

The gypsum board is the most common material in building materials, has the advantages of heat preservation, heat insulation, fire prevention, sound insulation, energy conservation and environmental protection, is light and attractive, and is widely applied to various buildings as an inner partition wall, a cladding panel, a ceiling, a decorative board and the like.

The gypsum board needs the shaping cutting in the belt feeder transportation, need pause transportation at the cutting in-process belt feeder, and the transportation is low to continue transporting the gypsum board after waiting for the cutting to accomplish again. If the belt conveyor is transported continuously in the gypsum board cutting process, the gypsum board and the belt conveyor are caused to relatively displace, and then the gypsum board at the back is caused to be wrinkled, so that the quality of a gypsum board finished product is affected.

Aiming at the related technology, the gypsum board belt conveyor at the present stage cannot be continuously cut in the transportation process, and the quality and the efficiency of finished gypsum boards are affected.

Disclosure of Invention

The application provides a gypsum board forming belt conveyor, which aims to improve the quality and the efficiency of finished products of gypsum boards by the gypsum board belt conveyor.

The application provides a gypsum board forming belt conveyor, which adopts the following technical scheme:

the gypsum board forming belt conveyor comprises a base, wherein a conveying mechanism is arranged on the base and used for conveying gypsum boards, a driving mechanism is connected to the conveying mechanism and arranged on the base, and a cutting mechanism is arranged on the driving mechanism and used for cutting the gypsum boards;

wherein, the actuating mechanism includes:

the driving bracket is fixedly arranged on the base;

the sliding plate is slidably arranged on the driving bracket, the sliding plate is connected with the cutting mechanism, and a double-sided rack is fixedly arranged on the sliding plate;

the two driven half gears are symmetrically arranged on two sides of the double-sided rack, the two driven half gears can be meshed with the double-sided rack, and the two driven half gears are rotatably arranged on the driving support.

Through adopting above-mentioned technical scheme, place the gypsum board on transport mechanism, transport mechanism work and carry the gypsum board, drive actuating mechanism work when transport mechanism transported the gypsum board, driven semi-gear drive sliding plate with gypsum synchronous motion on the drive support, the sliding plate drives cutting mechanism and gypsum board synchronous motion, realize the segmentation to the gypsum board in step when the gypsum board transportation, improve gypsum board belt feeder to the finished product quality and the finished product efficiency of gypsum board.

Optionally, the driving mechanism further includes:

the first driving straight gear is rotatably arranged on the driving bracket;

the two driven spur gears are symmetrically and meshed with each other and connected to two sides of the first driving spur gear, the two driven spur gears are rotatably mounted on the driving support, and the two driven half gears are coaxially and fixedly mounted on the two driven spur gears respectively.

Through adopting above-mentioned technical scheme, first drive spur gear rotates and then drives two driven spur gears and rotate, and two drive spur gears rotate and then drive driven half gear rotation, and driven half gear rotation drives two-sided rack reciprocating motion on the drive support in the time of driving, improves the mechanical linkage nature of a gypsum board shaping belt feeder.

Optionally, the transport mechanism includes:

the two transportation straight gears are symmetrically and rotatably arranged on the base;

the two ends of the conveying toothed belt are respectively sleeved on the two conveying spur gears, and the conveying toothed belt is in meshed connection with the conveying spur gears;

and the conveying motor is fixedly arranged on the base, and the output end of the conveying motor is coaxial with one of the conveying spur gears and is fixedly connected with the conveying spur gear.

Through adopting above-mentioned technical scheme, transport mechanism during operation, start transport motor, transport motor work and then drive the transportation spur gear that is connected with transport motor and rotate, transport spur gear rotates and then drives transportation toothed belt operation, and another transportation spur gear rotates simultaneously to playing the supporting role to the transportation toothed belt under the transportation toothed belt drive, guarantees the transportation stationarity of transportation toothed belt. Meanwhile, the transportation spur gear connected with the transportation motor rotates to drive the driving mechanism to work, so that the mechanical linkage is improved, the division of the gypsum board is realized synchronously while the gypsum board is transported, and the quality and the efficiency of finished products of the gypsum board belt conveyor on the gypsum board are improved.

Optionally, the driving mechanism further includes:

the second driving straight gear is rotatably arranged on the driving bracket and is coaxial with and fixedly connected with the first driving straight gear;

the driving toothed belt is sleeved at one end of the driving toothed belt on the second driving spur gear and is in meshed connection with the second driving spur gear, and the other end of the driving toothed belt is in meshed connection with one of the transporting spur gears and is sleeved on the other transporting spur gear.

Through adopting above-mentioned technical scheme, transportation spur gear rotates and then drives the motion of drive toothed belt, and the motion of drive toothed belt then drives second drive spur gear and rotates, and second drive spur gear rotates and then drives first drive spur gear and rotate, improves the mechanical linkage nature of a gypsum board shaping belt feeder.

Optionally, the cutting mechanism includes a first telescopic link, first telescopic link stiff end fixed mounting is in on the sliding plate, first telescopic link active end fixed mounting has the cutter.

Through adopting above-mentioned technical scheme, the cutter drives first telescopic link and cutter removal to the cooperation of gypsum board cutting, and the travel speed is the same with transportation toothed belt conveying speed, and gypsum board is static relatively with the transportation toothed belt, and then avoids the cutting process to produce the influence to subsequent gypsum board, leads to the gypsum board to take place the fold, influences gypsum board finished product quality.

Optionally, the cutting mechanism further comprises a second telescopic rod, the fixed end of the second telescopic rod is fixedly installed on the driving bracket, and the movable end of the second telescopic rod is fixedly connected with the sliding plate;

the second telescopic link stiff end intercommunication has the bellows, the bellows keep away from the one end of second telescopic link with first telescopic link stiff end intercommunication.

Through adopting above-mentioned technical scheme, when actuating mechanism work and drive the sliding plate to the direction that is close to the second telescopic link and remove, second telescopic link length shortens, and the interior hydraulic fluid of second telescopic link gets into in the first telescopic link stiff end through the bellows, and first telescopic link length extends, and the cutter removes and cuts the gypsum board to the direction that is close to the transportation toothed belt, improves the mechanical linkage nature of a gypsum board shaping belt feeder.

Optionally, the air cooling device further comprises an air cooling mechanism, wherein the air cooling mechanism comprises a transmission assembly and an air supply assembly, and the transmission assembly is used for driving the air supply assembly;

wherein, the air supply subassembly includes:

the two impellers are rotatably arranged on the base;

the first air supply gear is coaxially and fixedly arranged on the impeller;

the second air supply gear is rotatably arranged on the driving bracket and is connected with the transmission assembly;

the air supply toothed belt is sleeved at one end of the air supply toothed belt and is rotatably mounted on the first air supply gear, and the other end of the air supply toothed belt is sleeved at the other end of the air supply toothed belt and is rotatably mounted on the second air supply gear.

Through adopting above-mentioned technical scheme, forced air cooling mechanism during operation, drive assembly drive second air supply gear rotates, and the second air supply gear rotates and then drives the work of air supply toothed belt, and the work of air supply toothed belt then drives first air supply gear and rotates, and first air supply gear rotates and then drives the impeller and rotate, and the impeller rotates and then accelerates the air velocity, carries out quick forced air cooling to the gypsum board, reduces the gypsum board setting time, improves gypsum board intensity, avoids the gypsum board to produce deformation in the transportation, improves gypsum board production quality.

Optionally, the transmission assembly includes:

the two sliding rods are fixedly arranged at two ends of the double-sided rack, and spiral grooves are formed in the two sliding rods;

the two fixing sleeves are symmetrically and fixedly arranged on the driving support, and the two sliding rods are respectively penetrated and slidably arranged in the two fixing sleeves;

the two drive bevel gears are respectively rotatably arranged at one ends of the two fixing sleeves, which are far away from each other, and the drive bevel gears are provided with through holes in a penetrating way;

one end of the fixed block is fixedly arranged on the inner wall of the through hole, and the other end of the fixed block is slidably arranged in the spiral groove;

the driven bevel gear is connected with the driving bevel gear in a meshed mode, and the driven bevel gear is coaxial and fixedly installed on the second air supply gear.

Through adopting above-mentioned technical scheme, during operation of forced air cooling mechanism, two-sided rack reciprocating motion on the drive support, two slide bars are moved and then drive two slide bars and slide in fixed sleeve, and the fixed block is rotated as the center in the helicla flute internal sliding in the helicla flute while slide bar is gliding, and the fixed block rotates and then drives driving bevel gear and rotate with fixed sleeve axis as the center, and driving bevel gear rotates and then drives driven bevel gear and rotate, and driven bevel gear rotates and then drives second air supply gear and rotate, improves the mechanical linkage nature of a gypsum board shaping belt feeder.

Optionally, the two driven bevel gears are arranged in a central symmetry manner;

the spiral grooves on the two sliding rods are identical in rotation direction.

Through adopting above-mentioned technical scheme, two driven bevel gears rotation direction is the same when the slide bar removes, and then makes two impeller rotation direction the same, and then accelerates the air velocity, carries out quick forced air cooling to the gypsum board, reduces the gypsum board setting time, improves gypsum board intensity, avoids the gypsum board to produce deformation in the transportation, improves gypsum board production quality.

Optionally, the wall of the spiral groove is subjected to smoothing treatment;

and one end of the fixed block, which is far away from the inner wall of the through hole, is subjected to smoothing treatment.

By adopting the technical scheme, the sliding smoothness of the fixed block in the spiral groove is improved, and the running stability of the air cooling mechanism is further improved.

In summary, the present application includes at least one of the following beneficial technical effects:

placing the gypsum board on a conveying mechanism, enabling the conveying mechanism to work and convey the gypsum board, driving a driving mechanism to work while conveying the gypsum board by the conveying mechanism, driving a sliding plate to synchronously move with gypsum on a driving bracket by a driven half gear, and driving a cutting mechanism to synchronously move with the gypsum board by the sliding plate, so that the division of the gypsum board is synchronously realized while conveying the gypsum board, and the finished product quality and the finished product efficiency of a gypsum board belt conveyor on the gypsum board are improved;

the cutter cuts the gypsum board, and the sliding plate drives the first telescopic rod and the cutter to move, the moving speed is the same as the conveying speed of the conveying toothed belt, and the gypsum board and the conveying toothed belt are relatively static, so that the influence of the cutting process on the subsequent gypsum board is avoided, the gypsum board is wrinkled, and the quality of a gypsum board finished product is influenced;

when the air cooling mechanism works, the transmission assembly drives the second air supply gear to rotate, the second air supply gear rotates to drive the air supply toothed belt to work, the air supply toothed belt works to drive the first air supply gear to rotate, the first air supply gear rotates to drive the impeller to rotate, the impeller rotates to accelerate the air flow rate, the gypsum board is rapidly cooled, the setting time of the gypsum board is shortened, the strength of the gypsum board is improved, deformation of the gypsum board in the transportation process is avoided, and the production quality of the gypsum board is improved.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present application for illustrating a transport mechanism;

FIG. 2 is a schematic diagram showing the structure of a drive belt according to an embodiment of the present application;

FIG. 3 is a schematic diagram showing the structure of a double-sided rack according to an embodiment of the present application;

FIG. 4 is a schematic diagram showing the structure of a cutting mechanism according to an embodiment of the present application;

fig. 5 is an enlarged view at a of fig. 1 according to an embodiment of the present application.

Reference numerals illustrate:

1. a base; 2. a transport mechanism; 21. transporting the toothed belt; 22. transporting spur gears; 23. a transport motor; 3. a driving mechanism; 31. a drive bracket; 32. driving the toothed belt; 33. a first drive spur gear; 34. a second driving spur gear; 35. a driven spur gear; 36. a driven half gear; 37. double-sided racks; 38. a sliding plate; 4. a cutting mechanism; 41. a first telescopic rod; 42. a second telescopic rod; 43. a cutter; 44. a bellows; 5. an air cooling mechanism; 51. an air supply assembly; 511. a first air supply gear; 512. an impeller; 513. a toothed belt for air supply; 514. a second air supply gear; 52. a transmission assembly; 521. a slide bar; 522. a spiral groove; 523. a fixed sleeve; 524. a drive bevel gear; 525. a through hole; 526. a fixed block; 527. driven bevel gears.

Detailed Description

The application is described in further detail below with reference to fig. 1-5.

The embodiment of the application discloses a gypsum board forming belt conveyor.

Referring to fig. 1, the gypsum board forming belt conveyor comprises a base 1, a conveying mechanism 2 is installed on the base 1, the conveying mechanism 2 is used for conveying gypsum boards, a driving mechanism 3 is connected to the conveying mechanism 2, the driving mechanism 3 is installed on the base 1, a cutting mechanism 4 and an air cooling mechanism 5 are installed on the driving mechanism 3, the driving mechanism 3 is used for driving the cutting mechanism 4 and the air cooling mechanism 5 to work, the cutting mechanism 4 is used for cutting gypsum boards, and the air cooling mechanism 5 is used for cooling and air drying the gypsum boards.

When the gypsum board forming belt conveyor works, gypsum boards are placed on the conveying mechanism 2, the conveying mechanism 2 works and conveys the gypsum boards, the conveying mechanism 2 drives the driving mechanism 3 to work while conveying the gypsum boards, meanwhile, the conveying mechanism 2 drives the cutting mechanism 4 to synchronously move with the gypsum boards, the driving mechanism 3 works and then drives the cutting mechanism 4 and the air cooling mechanism 5 to work, the division and air cooling of the gypsum boards are synchronously realized while the gypsum boards are conveyed, and the finished product quality and the finished product efficiency of the gypsum board belt conveyor to the gypsum boards are improved.

Referring to fig. 2 and 3, the transport mechanism 2 includes two transport spur gears 22, and the two transport spur gears 22 are symmetrically and rotatably mounted on the base 1. One of them transport straight gear 22 is coaxial and fixedly connected with transport motor 23 output, and transport motor 23 fixed mounting is on base 1, and transport motor 23 is the rotation motor, and transport motor 23 can drive transport straight gear 22 and regard its axis as the center rotation. The two transporting spur gears 22 are sleeved and connected with the transporting toothed belt 21 in a meshed manner. A transport spur gear 22 to which a transport motor 23 is connected to the drive mechanism 3.

When the transport mechanism 2 works, the transport motor 23 is started, the transport motor 23 works to drive the transport spur gear 22 connected with the transport motor 23 to rotate, the transport spur gear 22 rotates to drive the transport toothed belt 21 to operate, and the other transport spur gear 22 rotates under the drive of the transport toothed belt 21 and simultaneously plays a supporting role on the transport toothed belt 21, so that the transport stability of the transport toothed belt 21 is ensured. Meanwhile, the transportation spur gear 22 connected with the transportation motor 23 rotates to drive the driving mechanism 3 to work, so that the mechanical linkage is improved, the division and air cooling of the gypsum board are realized synchronously while the gypsum board is transported, and the quality and the efficiency of finished products of the gypsum board belt conveyor on the gypsum board are improved.

Referring to fig. 2, 3 and 4, the driving mechanism 3 includes a driving bracket 31, the driving bracket 31 is fixedly installed on the base 1, a sliding plate 38 is slidably installed on the driving bracket 31, and the sliding direction of the sliding plate 38 is the same as the transportation direction of the gypsum board. The slide plate 38 is connected to the cutting mechanism 4. The sliding plate 38 is fixedly provided with a double-sided rack 37, the length direction of the double-sided rack 37 is the same as the sliding direction of the sliding plate 38, and the double-sided rack 37 is connected with the air cooling mechanism 5. Two driven half gears 36 are arranged on two sides of the double-sided rack 37, and the two driven half gears 36 can be meshed with the double-sided rack 37. Both driven half gears 36 are rotatably mounted on the driving bracket 31, and the tooth surface angle of both driven half gears 36 is 180 °. In the initial state of the drive mechanism 3, the two driven half gears 36 are symmetrically arranged with respect to the double-sided rack 37, and in the initial state of the drive mechanism 3, the tooth surfaces of the two driven half gears 36 themselves are symmetrically arranged in a straight line direction, and the straight line direction is parallel to the length direction of the double-sided rack 37.

Referring to fig. 2, 3 and 4, a first driving spur gear 33 is rotatably mounted on the driving bracket 31. The first driving spur gear 33 is coaxially and fixedly mounted on a rotating shaft, and the rotating shaft is rotatably mounted on the driving bracket 31 in a manner of being rotatably mounted on the driving bracket 31. The first driving spur gear 33 is rotationally symmetric on both sides and is connected with two driven spur gears 35 in a meshing manner, the two driven spur gears 35 are symmetrically arranged about the double-sided rack 37, and the two driven spur gears 35 are respectively coaxial with and fixedly connected with the two driven half gears 36.

Referring to fig. 2, 3 and 4, the driving mechanism 3 further includes a second driving spur gear 34, the second driving spur gear 34 is rotatably mounted on the driving bracket 31, and the second driving spur gear 34 is coaxially and fixedly connected with the first driving spur gear 33. The second driving spur gear 34 is rotatably mounted on the driving bracket 31 by being coaxially sleeved and fixedly mounted on a rotating shaft connected to the first driving spur gear 33. The second driving spur gear 34 is sleeved with and engaged with a driving toothed belt 32, and one end of the driving toothed belt 32 far away from the second driving spur gear 34 is sleeved with and engaged with and connected with a transporting spur gear 22 connected with a transporting motor 23.

Referring to fig. 2, 3 and 4, the first driving spur gear 33, the second driving spur gear 34 and the driven spur gear 35 are all identical in shape and size to the transporting spur gear 22.

The transportation spur gear 22 connected with the transportation motor 23 rotates to drive the driving toothed belt 32 to move, the driving toothed belt 32 moves to drive the second driving spur gear 34 to rotate, the second driving spur gear 34 rotates to drive the first driving spur gear 33 to rotate, the first driving spur gear 33 rotates to drive the two driven spur gears 35 to rotate, the two driven spur gears 35 rotate to drive the driven half gear 36 to rotate, and the driven half gear 36 rotates to drive the double-sided rack 37 to move on the driving support 31. When one driven half gear 36 is meshed with the double-sided rack 37, the other driven half gear 36 is in a separated state with the double-sided rack 37, the driven half gear 36 rotates to drive the double-sided rack 37 to move to one end, and the double-sided rack 37 moves to drive the sliding plate 38 to synchronously move. When one driven half gear 36 is separated from the double-sided rack 37, the other driven half gear 36 is meshed with the double-sided rack 37 and drives the double-sided rack 37 to move to the other end. Thereby realizing the horizontal reciprocating movement of the slide plate 38 on the driving bracket 31. When the sliding direction of the sliding plate 38 is the same as the conveying direction of the conveying toothed belt 21, the sliding plate 38 and the conveying toothed belt 21 are at the same conveying speed, the sliding plate 38 drives the cutting mechanism 4 to move and synchronously move with the conveying toothed belt 21, and meanwhile, the cutting mechanism 4 cuts the gypsum board, so that the division of the gypsum board is synchronously realized while the gypsum board is conveyed, and the finished product quality and the finished product efficiency of the gypsum board belt conveyor on the gypsum board are improved.

Referring to fig. 1, 4 and 5, the cutting mechanism 4 includes a second telescopic rod 42, a fixed end of the second telescopic rod 42 is fixedly mounted on the driving bracket 31, a movable end of the second telescopic rod 42 is fixedly connected with the sliding plate 38, and an axial direction of the second telescopic rod 42 is in sliding antiparallel with the sliding plate 38. The telescopic length of the second telescopic rod 42 is always longer than the sliding length of the sliding plate 38. The fixed end of the second telescopic rod 42 far away from the sliding plate 38 is communicated with a corrugated pipe 44. The fixed end of the second telescopic rod 42 is filled with hydraulic fluid. The bellows 44 communicates with the first telescopic rod 41 at an end remote from the second telescopic rod 42. The bellows 44 is of a flexible plastic material and the bellows 44 is malleable in its length. The fixed end of the first telescopic rod 41 is fixedly arranged on the sliding plate 38, and the movable end of the first telescopic rod 41 is fixedly provided with a cutter 43. The axial direction of the first telescopic rod 41 is perpendicular to the conveying direction of the conveying toothed belt 21.

When the driving mechanism 3 works and drives the sliding plate 38 to move towards the direction approaching to the second telescopic rod 42, the length of the second telescopic rod 42 is shortened, hydraulic fluid in the second telescopic rod 42 enters the fixed end of the first telescopic rod 41 through the corrugated pipe 44, the length of the first telescopic rod 41 is extended, and the cutter 43 moves towards the direction approaching to the conveying toothed belt 21 and cuts the gypsum board. The cutter 43 cuts the gypsum board, and the sliding plate 38 drives the first telescopic rod 41 and the cutter 43 to move, the moving speed of the first telescopic rod 41 and the cutter 43 is the same as the conveying speed of the conveying toothed belt 21, and the cutter 43 and the conveying toothed belt 21 are relatively static, so that the influence of the cutting process on the subsequent gypsum board is avoided, the gypsum board is wrinkled, and the quality of a gypsum board finished product is influenced.

When the driving mechanism 3 works and drives the sliding plate 38 to move in the direction away from the second telescopic rod 42, the length of the second telescopic rod 42 is prolonged, the second telescopic rod 42 withdraws hydraulic liquid entering the fixed end of the first telescopic rod 41 into the second telescopic rod 42 through the corrugated pipe 44, the length of the first telescopic rod 41 is shortened, the reset of the cutting mechanism 4 is realized, the follow-up cutting of the gypsum board is facilitated, the working continuity of a gypsum board forming belt conveyor is improved, and the gypsum board forming efficiency is improved.

Referring to fig. 1 and 2, the air cooling mechanism 5 includes a transmission assembly 52 and an air supply assembly 51, and the transmission assembly 52 is used for driving the air supply assembly 51. The transmission assembly 52 is connected to the drive mechanism 3.

Referring to fig. 3, 4 and 5, the transmission assembly 52 includes two slide bars 521, the two slide bars 521 are coaxially and fixedly mounted at two ends of the double-sided rack 37, the two slide bars 521 are provided with spiral grooves 522, and the spiral grooves 522 on the two slide bars 521 are identical in rotation direction in the axial direction of the double-sided rack 37. The walls of the spiral groove 522 are smoothed to reduce the coefficient of friction of the walls of the spiral groove 522.

Referring to fig. 3, 4 and 5, two fixing sleeves 523 are symmetrically and fixedly mounted on the driving bracket 31, and two slide bars 521 are respectively penetrated and slidably mounted in the two fixing sleeves 523. The fixing sleeve 523 is disposed coaxially with the slide bar 521. The drive bevel gear 524 is rotatably installed at one end, away from each other, of the two fixed sleeves 523, the drive bevel gear 524 and the fixed sleeves 523 are coaxially arranged, relative displacement in the axial direction cannot occur between the drive bevel gear 524 and the fixed sleeves 523, the drive bevel gear 524 is provided with a through hole 525, the through hole 525 and the fixed sleeves 523 are coaxially arranged, and the diameter of the through hole 525 is larger than that of the slide rod 521. Fixedly connected with fixed block 526 on the inner wall of through-hole 525, the one end slidable mounting that the fixed block 526 kept away from the inner wall of through-hole 525 is in helical groove 522, and the one end that fixed block 526 kept away from the inner wall of through-hole 525 is smooth, reduces the coefficient of friction that fixed block 526 kept away from the one end of inner wall of through-hole 525.

Referring to fig. 3, 4 and 5, driven bevel gears 527 are engaged with and connected to the two drive bevel gears 524, and the axial directions of the two driven bevel gears 527 are perpendicular to the plane of the driving frame 31, and the driven bevel gears 527 are connected to the air blowing assembly 51. The two driven bevel gears 527 are arranged in a central symmetry in the axial direction of the slide bar 521, i.e., the two driven bevel gears 527 are respectively arranged at two sides of the axis of the slide bar 521.

Referring to fig. 1, 2 and 3, the air supply assembly 51 includes two impellers 512, each of the two impellers 512 is rotatably mounted on the base 1, and the impellers 512 are rotatably mounted on a fixed shaft fixedly mounted on the base 1, and rotatably mounted on the base 1. The two impellers 512 are symmetrically arranged about the conveyor belt 21. The impeller 512 is coaxially and fixedly connected with a first air supply gear 511, and the first air supply gear 511 is coaxially sleeved and rotatably mounted on the fixed shaft. The first air supply gear 511 is sleeved with and engaged with an air supply toothed belt 513, one end, far away from the first air supply gear 511, of the air supply toothed belt 513 is sleeved with and engaged with a second air supply gear 514, the second air supply gear 514 is rotatably mounted on the driving bracket 31, the second air supply gear 514 is rotatably mounted on another fixed shaft, the other fixed shaft is fixedly mounted on the driving bracket 31, and the second air supply gear 514 is coaxially and fixedly connected with the driven bevel gear 527.

When the air cooling mechanism 5 works, the double-sided rack 37 moves back and forth on the driving bracket 31, the double-sided rack 37 moves to drive the two slide bars 521 to slide in the fixed sleeve 523, the fixed block 526 slides in the spiral groove 522 while the slide bars 521 slide, the fixed block 526 rotates around the axis of the spiral groove 522, the fixed block 526 rotates to drive the drive bevel gear 524 to rotate around the axis of the fixed sleeve 523, the drive bevel gear 524 rotates to drive the driven bevel gear 527 to rotate, the driven bevel gear 527 rotates to drive the second air supply gear 514 to rotate, the second air supply gear 514 rotates to drive the air supply toothed belt 513 to work, the air supply toothed belt 513 works to drive the first air supply gear 511 to rotate, the first air supply gear 511 rotates to drive the impeller 512 to rotate to accelerate the air flow rate, the quick air cooling is performed on the plasterboard, the setting time of the plasterboard is reduced, the strength of the plasterboard is improved, deformation of the plasterboard in the transportation process is avoided, and the production quality of the plasterboard is improved.

The implementation principle of the gypsum board forming belt conveyor provided by the embodiment of the application is as follows: the gypsum board is placed on the conveying mechanism 2, the conveying mechanism 2 works and conveys the gypsum board, the conveying mechanism 2 drives the driving mechanism 3 to work while conveying the gypsum board, meanwhile, the conveying mechanism 2 drives the cutting mechanism 4 to synchronously move with the gypsum board, the driving mechanism 3 works to further drive the cutting mechanism 4 and the air cooling mechanism 5 to work, the division and air cooling of the gypsum board are synchronously realized while conveying the gypsum board, and the finished product quality and the finished product efficiency of the gypsum board belt conveyor on the gypsum board are improved.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims

1. The utility model provides a gypsum board shaping belt feeder which characterized in that: the gypsum board cutting device comprises a base (1), wherein a conveying mechanism (2) is arranged on the base (1), the conveying mechanism (2) is used for conveying gypsum boards, a driving mechanism (3) is connected to the conveying mechanism (2), the driving mechanism (3) is arranged on the base (1), a cutting mechanism (4) is arranged on the driving mechanism (3), and the cutting mechanism (4) is used for cutting gypsum boards;

wherein the driving mechanism (3) comprises:

the driving bracket (31), the said driving bracket (31) is fixedly mounted on said base (1);

the sliding plate (38), the sliding plate (38) is installed on the driving bracket (31) in a sliding way, the sliding plate (38) is connected with the cutting mechanism (4), and the double-sided rack (37) is fixedly installed on the sliding plate (38);

the two driven half gears (36), two driven half gears (36) are symmetrically arranged on two sides of the double-sided rack (37), the two driven half gears (36) can be meshed with the double-sided rack (37), and the two driven half gears (36) are rotatably arranged on the driving support (31).

2. The plasterboard forming belt conveyor as claimed in claim 1, characterized in that the drive mechanism (3) further comprises:

a first drive spur gear (33), the first drive spur gear (33) being rotatably mounted on the drive bracket (31);

the two driven straight gears (35), the two driven straight gears (35) are symmetrically and meshed and connected to two sides of the first driving straight gear (33), the two driven straight gears (35) are rotatably mounted on the driving support (31), and the two driven half gears (36) are coaxially and fixedly mounted on the two driven straight gears (35) respectively.

3. The plasterboard forming belt conveyor as claimed in claim 2, characterized in that the transport mechanism (2) comprises:

two transporting spur gears (22), wherein the two transporting spur gears (22) are symmetrically and rotatably arranged on the base (1);

the two ends of the conveying toothed belt (21) are respectively sleeved on the two conveying spur gears (22), and the conveying toothed belt (21) is in meshed connection with the conveying spur gears (22);

the conveying motor (23), conveying motor (23) stiff end fixed mounting is in on base (1), conveying motor (23) output with one of them conveying spur gear (22) coaxial and fixed connection.

4. A plasterboard forming belt conveyor as claimed in claim 3, characterized in that the drive mechanism (3) further comprises:

the second driving straight gear (34), the second driving straight gear (34) is rotatably installed on the driving bracket (31), and the second driving straight gear (34) is coaxial with and fixedly connected with the first driving straight gear (33);

the driving toothed belt (32), one end of the driving toothed belt (32) is sleeved on the second driving straight gear (34) and is in meshed connection with the second driving straight gear (34), and the other end of the driving toothed belt (32) is in meshed connection and is sleeved on one of the transporting straight gears (22).

5. The gypsum board forming belt conveyor of claim 1, wherein: the cutting mechanism (4) comprises a first telescopic rod (41), the fixed end of the first telescopic rod (41) is fixedly arranged on the sliding plate (38), and the movable end of the first telescopic rod (41) is fixedly provided with a cutter (43).

6. The gypsum board forming belt conveyor of claim 5, wherein: the cutting mechanism (4) further comprises a second telescopic rod (42), the fixed end of the second telescopic rod (42) is fixedly arranged on the driving bracket (31), and the movable end of the second telescopic rod (42) is fixedly connected with the sliding plate (38);

the fixed end of the second telescopic rod (42) is communicated with a corrugated pipe (44), and one end, away from the second telescopic rod (42), of the corrugated pipe (44) is communicated with the fixed end of the first telescopic rod (41).

7. The gypsum board forming belt machine according to claim 1, further comprising an air cooling mechanism (5), the air cooling mechanism (5) comprising a transmission assembly (52) and an air supply assembly (51), the transmission assembly (52) being configured to drive the air supply assembly (51);

wherein the air supply assembly (51) comprises:

two impellers (512), two said impellers (512) are rotatably mounted on said base (1);

a first air supply gear (511), wherein the first air supply gear (511) is coaxially and fixedly arranged on the impeller (512);

the second air supply gear (514) is rotatably arranged on the driving bracket (31), and the second air supply gear (514) is connected with the transmission assembly (52);

and the air supply toothed belt (513) is sleeved at one end of the air supply toothed belt (513) and is rotatably mounted on the first air supply gear (511), and the other end of the air supply toothed belt (513) is sleeved at the other end of the air supply toothed belt and is rotatably mounted on the second air supply gear (514).

8. The gypsum board forming belt conveyor of claim 7, wherein: the transmission assembly (52) includes:

the two sliding rods (521), the two sliding rods (521) are fixedly arranged at two ends of the double-sided rack (37), and spiral grooves (522) are formed in the two sliding rods (521);

the two fixing sleeves (523) are symmetrically and fixedly arranged on the driving bracket (31), and the two sliding rods (521) are respectively penetrated and slidably arranged in the two fixing sleeves (523);

the two drive bevel gears (524) are respectively rotatably arranged at one ends of the two fixed sleeves (523) which are far away from each other, and through holes (525) are formed in the drive bevel gears (524) in a penetrating manner;

the fixed block (526), one end of the fixed block (526) is fixedly arranged on the inner wall of the through hole (525), and the other end of the fixed block (526) is slidably arranged in the spiral groove (522);

and the driven bevel gear (527) is in meshed connection with the driving bevel gear (524), and the driven bevel gear (527) is coaxially and fixedly arranged on the second air supply gear (514).

9. The gypsum board forming belt conveyor of claim 8, wherein: the two driven bevel gears (527) are arranged in a central symmetry mode;

the spiral grooves (522) on the two slide bars (521) are in the same rotation direction.

10. The gypsum board forming belt conveyor of claim 8, wherein: the walls of the spiral grooves (522) are smoothed;

one end of the fixed block (526) far away from the inner wall of the through hole (525) is subjected to smoothing treatment.