CN113104560B - Gypsum board desiccator goes out board device - Google Patents

Abstract

The invention discloses a board discharging device of a gypsum board dryer, which comprises a base, wherein a board discharging conveying mechanism and a plurality of noise reduction fetching and conveying mechanisms are arranged on the base; the noise reduction taking and delivering mechanism is used for adsorbing and fixing the gypsum board on the drying mechanism and suspending the gypsum board; and the board discharging and conveying mechanism is used for butt-jointing and fixing the gypsum board suspended by the noise reduction taking and conveying mechanism and conveying the gypsum board to the next procedure. According to the invention, the gypsum board on the drying mechanism is actively adsorbed and fixed by the noise reduction taking and conveying mechanism and is suspended, and then the gypsum board suspended by the noise reduction taking and conveying mechanism is fixed in a butt joint mode by the board discharging conveying mechanism and is conveyed to the next process.

Description

Gypsum board desiccator goes out board device

Technical Field

The invention relates to the technical field of gypsum boards, in particular to a board discharging device of a gypsum board dryer.

Background

The gypsum board is a material prepared by taking building gypsum as a main raw material. The building material has the advantages of light weight, high strength, small thickness, convenient processing, sound insulation, heat insulation, fire prevention and other good performances, and is one of the currently-developed novel light boards. The production process of gypsum board mainly does, uses the system board setting to press the shaping with raw and other materials, uses drying equipment to dry the shaping gypsum board, and drying equipment delivers to warehouse through the conveyer belt after going out the board.

The play board in-process among the prior art is that drying equipment has the discharge gate of an inclined state generally for the gypsum that is dried breaks away from the discharge gate by the natural slip under self action of gravity, is provided with the conveyer belt below the discharge gate, accepts the gypsum board that drops through the conveyer belt. But through the transportation mode that the slip dropped, because the vibrations and the friction that the gypsum board dropped and arouse can cause great noise and can cause certain degree of injury to the gypsum board, though accessible set up modes such as blotter on the conveyer belt, reduce this kind of impact, nevertheless can't solve this problem fundamentally. Therefore, a low-noise transfer mechanism for automatically transferring the gypsum board on the dryer to the transfer mechanism and a transfer mechanism matched with the transfer mechanism are urgently needed.

Disclosure of Invention

The invention aims to provide a gypsum board discharging device of a gypsum board dryer, and aims to solve the technical problem that a low-noise transfer mechanism and a transfer mechanism matched with the transfer mechanism are not available in the prior art, and the low-noise transfer mechanism and the transfer mechanism are used for automatically transferring gypsum boards on the dryer to the transfer mechanism.

In order to solve the technical problems, the invention specifically provides the following technical scheme:

a board discharging device of a gypsum board dryer comprises a base, wherein a board discharging conveying mechanism and a plurality of noise reduction taking and conveying mechanisms are mounted on the base;

the noise reduction taking and delivering mechanism is used for adsorbing and fixing the gypsum board on the drying mechanism and suspending the gypsum board;

and the board discharging and conveying mechanism is used for butt-jointing and fixing the gypsum board suspended by the noise reduction taking and conveying mechanism and conveying the gypsum board to the next procedure.

As a preferable aspect of the present invention, the plate discharging conveying mechanism includes an annular conveying rail, a silent sliding block is slidably mounted on the annular conveying rail along an edge of the annular conveying rail, and a control unit for controlling sliding and locking of the silent sliding block is mounted on the annular conveying rail;

the mute sliding block is provided with a stacking rotating member which rotates and locks by taking 90 degrees as a single rotation amplitude, a third longitudinal telescopic cavity is fixedly mounted at the top end of the stacking rotating member, a transverse telescopic cavity is fixedly mounted at the top end of the third longitudinal telescopic cavity, and a second vacuum chuck for fixing a gypsum board is fixedly mounted on the transverse telescopic cavity.

In a preferred embodiment of the present invention, the endless transfer track is formed by connecting an inclined transport section and an endless sliding section end to end.

As a preferable mode of the present invention, the control assembly includes a set of driving magnets respectively fixedly installed at both ends of the circulating sliding part, and a fitting magnet block fitted with the driving magnets is fixedly installed in the mute sliding block;

the mute slide block is telescopically provided with a control clamping piece, and a clamping hole for nesting the control clamping piece is formed in the joint of the inclined transportation part and one side of the circulating sliding part.

As a preferable scheme of the present invention, the control clip includes a sliding mounting hole which is opened on the mute slide block and longitudinally penetrates through the mute slide block, a first sliding member is linearly slidably mounted at the top end of the sliding mounting hole through a first elastic member, and a second sliding member is linearly slidably mounted at the bottom end of the sliding mounting hole through a second elastic member;

the bottom end of the second sliding part is embedded on the clamping opening in a linearly sliding manner, an M-shaped traction rope used for enabling the first sliding part and the second sliding part to move in a reverse direction is installed on the first sliding part, and sliding pore channels used for being sleeved with the M-shaped traction rope are formed in the hole walls of the two sides of the sliding installation hole.

As a preferable scheme of the present invention, the stacking rotating member includes a circular groove fixedly installed on the first sliding member, a circular disc rotating in the circular groove, the third longitudinal telescopic cavity is fixedly installed on the circular disc, four positioning grooves are uniformly formed in the bottom surface of the circular disc, and a clamping member is linearly slidably installed in each positioning groove through a third elastic member;

evenly offer on the circular recess and be used for the nestification the screens recess of screens piece install in the screens recess be used for with the screens piece is extruded the second circulation extruded article of screens recess.

As a preferable scheme of the invention, the third longitudinal telescopic cavity and the transverse telescopic cavity are both composed of a slide cylinder arranged on the outer layer and an elastic air bag arranged on the inner layer.

As a preferable scheme of the invention, the noise reduction taking and delivering mechanism comprises a containing groove arranged on a container of a gypsum board on the drying mechanism, a first action piece is arranged in the containing groove, and a first vacuum suction cup is arranged at the top end of the first action piece.

As a preferable scheme of the present invention, the first operating member includes a first longitudinal telescopic cavity fixedly installed in the accommodating groove, a second longitudinal telescopic cavity is fixedly installed at a top end of the first longitudinal telescopic cavity, an L-shaped telescopic rod is fixedly installed at a top end of the second longitudinal telescopic cavity, and the first vacuum chuck is fixedly installed at a bottom end of the L-shaped telescopic rod.

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

according to the invention, the gypsum board on the drying mechanism is actively adsorbed and fixed by the noise reduction taking and conveying mechanism and is suspended, and then the gypsum board suspended by the noise reduction taking and conveying mechanism is fixed in a butt joint mode by the board discharging conveying mechanism and is conveyed to the next process.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary and that other implementation drawings may be derived from the provided drawings by those of ordinary skill in the art without inventive effort.

FIG. 1 is a schematic diagram of an overall structure of a plate discharging device according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of the plate discharging device and the drying mechanism in cooperation with each other in the embodiment of the present invention;

FIG. 3 is a top view of the drying mechanism in an embodiment of the present invention;

FIG. 4 is a schematic structural view of a transverse guiding plate in the drying mechanism according to the embodiment of the present invention;

FIG. 5 is a schematic view of an angle adjustment assembly in the drying mechanism according to an embodiment of the present invention;

FIG. 6 is a schematic structural view of a control card in the plate discharging device according to the embodiment of the present invention;

fig. 7 is a structural schematic of a pallet rotating member in the plate discharging device in an embodiment of the invention.

The reference numerals in the drawings denote the following, respectively:

1-a base; 2-a drying mechanism; 3-a plate discharging conveying mechanism; 4-noise reduction taking and delivering mechanism;

21-an annular track; 22-rigid drive ring; 23-installing a through groove; 24-connecting and guiding the transverse plate; 25-an angle adjustment assembly; 26-a locking assembly; 27-a heating element; 28-sound insulation cavity;

41-a second locking assembly; 42-a receiving groove; 43-a first action; 44-a first vacuum chuck;

251-a cylindrical inner cavity; 252-a buoyant liquid; 253-a floating plate; 254-sealing the shaft; 255-a locking bar; 256-flip assembly;

261-a mounting ring body; 262-sliding concave surface; 263-a first elastic member; 264-first locking projection; 265-first locking hole slot; 266-first endless extrusion;

411-a second locking hole slot; 412-a second endless extrusion;

431-a first longitudinally telescoping lumen; 432-a second longitudinally telescoping lumen; 433-L-shaped telescopic rods;

2561-middle dividing plate; 2562-connecting channel; 2563-liquid pump;

31-an endless transfer track; 32-a mute slide block; 33-a control assembly; 34-a pallet rotating member; 35-a third longitudinally telescoping lumen; 36-a transverse telescopic cavity; 37-a second vacuum chuck;

311-inclined transport section; 312-a cyclic slide;

331-a drive magnet; 332-a mating magnet block; 333-control cartridge; 334-a blocking hole;

3331-sliding mounting holes; 3332-a first resilient member; 3333-first sliding member; 3334-a second resilient member; 3335-second slide; 3336-M shaped hauling ropes;

341-circular groove; 342-a circular disk; 343-a positioning groove; 345-a clamping part; 346-a detent recess; 347-second endless extrusion.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, 6 and 7, the invention provides a board discharging device of a gypsum board dryer, which comprises a base 1, wherein a board discharging and conveying mechanism 3 and a plurality of noise reduction taking and conveying mechanisms 4 are mounted on the base 1; the noise reduction taking and delivering mechanism 4 is used for adsorbing and fixing the gypsum board on the drying mechanism and suspending the gypsum board; and the board discharging and conveying mechanism 3 is used for butt-jointing and fixing the gypsum board suspended by the noise reduction taking and conveying mechanism 4 and conveying the gypsum board to the next working procedure. The plate discharging conveying mechanism 3 comprises an annular conveying track 31, a mute slide block 32 is arranged on the annular conveying track 31 in a sliding way along the edge of the annular conveying track 31, and a control component 33 for controlling the sliding and locking of the mute slide block 32 is arranged on the annular conveying track 31; the mute sliding block 32 is provided with a stacking rotating member 34 which rotates and locks by taking 90 degrees as a single rotation amplitude, a third longitudinal telescopic cavity 35 is fixedly mounted at the top end of the stacking rotating member 34, a transverse telescopic cavity 36 is fixedly mounted at the top end of the third longitudinal telescopic cavity 35, and a second vacuum suction cup 37 for fixing a gypsum board is fixedly mounted on the transverse telescopic cavity 36.

Wherein, the endless conveying track 31 is formed by connecting an inclined transportation part 311 and a circulating sliding part 312 end to end. The control unit 33 includes a set of driving magnets 331 respectively fixed to both ends of the circulating sliding portion 312, and a fitting magnet block 332 fitted to the driving magnets 331 is fixed to the mute slide block 32; the mute slide block 32 is telescopically provided with a control clamping piece 333, and a clamping opening 334 for nesting the control clamping piece 333 is arranged at the connection position of the inclined transportation part 311 and one side of the circulating sliding part 312.

The control latch 333 includes a sliding mounting hole 3331 which is opened on the mute slide block 32 and longitudinally penetrates through the mute slide block 32, a first sliding piece 3333 is linearly slidably mounted on the top end of the sliding mounting hole 3331 through a first elastic piece 3332, and a second sliding piece 3335 is linearly slidably mounted on the bottom end of the sliding mounting hole 3331 through a second elastic piece 3334; the bottom end of the second sliding member 3335 is linearly slidably nested in the positioning opening 334, an M-shaped pulling rope 3336 for making the first sliding member 3333 and the second sliding member 3335 move in opposite directions is installed on the first sliding member 3333, and sliding holes for sleeving the M-shaped pulling rope 3336 are respectively formed on the wall of each of the two side walls of the sliding installation hole 3331.

The stacking rotating member 34 includes a circular groove 341 fixedly mounted on the first sliding member 3333, a circular disc 342 rotating in the circular groove 341, the third longitudinally-telescopic cavity 35 is fixedly mounted on the circular disc 342, four positioning grooves 343 are uniformly formed in the bottom surface of the circular disc 342, and a blocking member 345 is linearly slidably mounted on the positioning grooves 343 through a third elastic member 344; the circular groove 341 is uniformly provided with a blocking groove 346 for nesting the blocking member 345, and a second circulating extrusion member 347 for extruding the blocking member 345 out of the blocking groove 346 is installed in the blocking groove 346. The third longitudinal telescopic cavity 35 and the transverse telescopic cavity 36 are both composed of a slide cylinder arranged on the outer layer and an elastic air bag arranged on the inner layer.

Wherein, it draws and send mechanism 4 to fall to make an uproar is including seting up the groove 42 of accomodating on the container of stoving mechanism last gypsum board accomodate and install first action 43 in the groove 42 first vacuum chuck 44 is installed on the top of first action 43. First action 43 includes fixed mounting accomodate first vertical flexible cavity 431 in the groove 42 the top fixed mounting of first vertical flexible cavity 431 has the vertical flexible cavity 432 of second the vertical flexible cavity 432 top fixed mounting of second has L shape telescopic link 433, first vacuum chuck 44 fixed mounting be in the bottom of L shape telescopic link 433.

Through the arrangement of the special shape of the annular conveying track 31, the silent sliding block 32 can automatically slide the points for stacking the gypsum boards from the points for bearing the gypsum boards under the action of self gravity; also, the mute slide 32 is cyclically slidable to enable continuous operation of the device.

The power for sliding the mute slide block 32 is provided by the cooperation of the magnet block 332 and the driving magnet 331 on the mute slide block 32, which are mutually attracted or repelled. Specifically, the mute slide 32 passes through the left curve under the action of gravity, the magnet at the curve provides a horizontal pushing force to the mute slide 32 through the repulsive force, and when the mute slide 32 enters the right curve, the magnet 331 at the right side provides an attractive force, so that the mute slide 32 passes through the second curve.

Moreover, the control fastener 333 and the locking hole 334 cooperate with each other to automatically lock the silent sliding block 32 at the receiving point of the gypsum board, so as to provide sufficient transit time for the gypsum board.

The first sliding member 3333 is pressed by the weight of the gypsum board to trigger unlocking, and the first sliding member 3333 is moved to weaken the impact of the gypsum board during the process of receiving the gypsum board, thereby reducing the noise during the transfer to some extent.

Because, this device is the fixed transport to the gypsum board, and does not use frictional force to drive among the prior art, and the gypsum board piles up the in-process and needs 90 degrees crisscross pile up neatly of rotatoryly.

The device can utilize special fixed transfer, so that the rotary adjustment of the device can be completed only through the stacking rotating piece 34, and automatic stacking is realized.

Compared with the traditional mode that the conveying roller drives the belt through friction, the mode has the advantages that the acting surface is smooth, the generated friction is small, the vibration is small, the noise is low, and lubricating oil and the like can be added into the sliding groove to further reduce the friction and the noise.

In the invention, the first longitudinal telescopic cavity 431, the second longitudinal telescopic cavity 432 and the third longitudinal telescopic cavity 35 are all formed by nesting elastic air bags in sliding barrels, in this way, the elastic air bags of the connected structure can be communicated, and the sequence of expansion of each part can be controlled by setting different stiffness coefficients of the elastic air bags of each part, so that the automation of the device is realized.

The board discharging device mainly realizes the suspension butt joint of the conveyor belt and the gypsum board on the dryer, greatly reduces the noise in the board discharging process, and also provides an embodiment of the drying mechanism because the different drying mechanisms cause different corresponding specific conditions.

The embodiment of the drying mechanism provided by the invention is a rotary closed type drying mechanism, and the plate feeding process is that the plate is put in from the top end and is transmitted out from one side of the top end, so when the butt joint of the drying mechanism is realized, the noise reduction taking and conveying mechanism 4 is needed to suspend on the drying mechanism, so that the second vacuum suction cups 37 on the plate discharging conveying mechanism 3 enter the bottom surface of the gypsum board, and the suspension transfer of the gypsum board is realized.

As shown in fig. 2 and fig. 3, the present invention further provides a drying mechanism, which includes two annular rails 21 fixedly installed on the base 1, a rigid driving ring 22 is installed between the two annular rails 21 in a rotatable manner, installation penetrating grooves 23 are uniformly formed on the rigid driving ring 22, a connecting transverse plate 24 for bearing gypsum boards is rotatably installed in the installation penetrating grooves 23, and an angle adjusting assembly 25 for keeping the connecting transverse plate 24 in a horizontal state all the time when the connecting transverse plate 24 rotates along with the rigid driving ring 22 is arranged between the connecting transverse plate 24 and the installation penetrating grooves 23; a locking assembly 26 for locking the connecting cross plate 24 at the corresponding position to receive the formed gypsum board output from the board making device is arranged at the top end of the rigid driving ring 22; the plate-discharging conveying mechanism 3 is arranged on one side of the rigid driving ring 22, and a heating element 27 with the temperature gradually decreased towards the longitudinal top end is arranged at the bottom end of the rigid driving ring 22; the noise reduction taking and delivering mechanisms 4 are correspondingly arranged on the guiding transverse plates 24.

In the prior art, the drying mechanism 2 is usually a long and narrow channel, and by arranging a heating device in the long and narrow channel, the gypsum board is dried gradually through the long and narrow channel at a constant speed.

The above prior art has two drawbacks: firstly, because the gypsum board needs a long time for drying, a long drying channel needs to be laid, so that the occupied plant area is overlarge; secondly, the long and narrow channel is used for conveying plasterboards through a long conveyor belt, the conveyor belt is conveyed through friction force, and the friction force brings shaking, so that high noise is generated.

In the scheme, the drying mechanism widens the longitudinal space, so that plasterboards are placed in the circumferential direction and rotate on the rigid driving ring 22 in a circulating manner to control the drying time of the plasterboards, in the process, the plasterboards are driven in a rotating manner mainly by the relative rotation of the annular rail 21 and the rigid driving ring 22, the rotation between the annular rail 21 and the rigid driving ring 22 is driven by a motor, and the contact surfaces of the annular rail 21 and the rigid driving ring 22 are set to be smooth surfaces so as to reduce the friction force; furthermore, by expanding the longitudinal space, the heating device is arranged at the bottom end of the rigid driving ring 22 in the device, so that a heating area with temperature increasing from top to bottom is formed on the rigid driving ring 22.

The shaping gypsum board of system board device output in this device is placed on topmost connects and leads diaphragm 24, and the temperature of topmost is minimum to preheat the gypsum board of just coming out of the machine, in order to prevent that the gypsum board from touching high temperature suddenly, and take place the chap of certain degree.

As shown in fig. 4 and 5, the angle adjusting assembly 25 includes two cylindrical inner cavities 251 respectively opened in the installation through groove 23, a buoyant liquid 252 is disposed in the cylindrical inner cavities 251, a floating plate 253 for floating on the surface of the buoyant liquid 252 is disposed on the buoyant liquid 252, one side of the floating plate 253 is connected to a sealing shaft 254 penetrating into the installation through groove 23, the sealing shaft 254 is correspondingly installed on the guiding transverse plates 24, and the other side of the floating plate 253 is connected to a locking rod 255 penetrating through the rigid driving ring 22.

The locking assembly 26 includes a mounting ring 261, the mounting ring 261 is fixedly mounted on the annular rail 21 close to the locking rod 255, an annular sliding concave surface 262 is provided on the mounting ring 261, a first locking protrusion 264 is telescopically mounted in the locking rod 255 through a first elastic member 263, the first locking protrusion 264 slidably abuts against the sliding concave surface 262, a first locking hole 265 for nesting and fixing the first locking protrusion 264 is opened at the top end of the sliding concave surface 262, and a first circulating extrusion member 266 for abutting against the first locking protrusion 264 and extruding the first locking protrusion 264 out of the first locking hole 265 is mounted in the first locking hole 265. The heating element 27 is a first electric heating plate fixedly mounted on the base 1 opposite to the rigid driving ring 22. Connect and lead diaphragm 24 through fall make an uproar pick-and-place mechanism 4 adsorbs and takes out connect the gypsum board on the diaphragm 24 of leading and unsettled transfer extremely go out board transport mechanism 3. Noise reduction pick-and-place mechanism 4 is including being used for locking top one side connect the second locking subassembly 41 that leads diaphragm 24, wherein, two accomodate groove 42 and seted up connect the both sides that lead diaphragm 24 accomodate the inslot 42 and install first action piece 43 first vacuum chuck 44 is installed on the top of first action piece 43.

The second locking assembly 41 includes a second locking hole slot 411 opened in the concave sliding surface 262, and a second circulating pressing member 412 is installed in the second locking hole slot 411 to abut against the first locking protrusion 264 and press the first locking protrusion 264 out of the second locking hole slot 411. An overturning assembly 256 for overturning the gypsum board on the guiding transverse plate 24 when the first vacuum suction cup 44 fixes the gypsum is arranged on the cylindrical inner cavity 251; the tilting assembly 256 includes a partition plate 2561 fixedly installed on upper and lower surfaces of the floating plate 253, a communication passage 2562 fixedly installed on one side of the cylindrical inner cavity 251 for communicating a bottom end with a top end of the cylindrical inner cavity 251, and a liquid pump 2563 installed in the communication passage 2563.

In the prior art, the drying-machine is drying the gypsum board, need drop the gypsum board to the conveyer belt on, and at this in-process, the gypsum board drops on the conveyer belt and takes place the collision of certain degree to produce noise and certain degree of wearing and tearing.

And in this device, thereby it keeps the suspended state to make the gypsum board through making an uproar to fall to fetch and send mechanism 4 adsorbs the gypsum board to be convenient for by a board transport mechanism 3 butt joint.

The noise reduction taking and delivering mechanism 4 has a fixing effect on the gypsum board, and after the gypsum board is fixed, the gypsum board is turned over through the turning assembly 256, so that the gypsum board is uniformly dried.

When the gypsum board is not placed on the guiding cross plate 24, the first vacuum suction cup 44 is higher away from the guiding cross plate 24 by the simultaneous ascending of the first longitudinal telescopic cavity 431 and the second longitudinal telescopic cavity 432, so that a space is provided for placing the gypsum board.

Wherein, the circulation extruded part can be linear electric motor, also can be other regular extending structure that have.

The above embodiments are only exemplary embodiments of the present application, and are not intended to limit the present application, and the protection scope of the present application is defined by the claims. Various modifications and equivalents may be made by those skilled in the art within the spirit and scope of the present application and such modifications and equivalents should also be considered to be within the scope of the present application.

Claims (4)

1. The utility model provides a gypsum board desiccator goes out board device which characterized in that: the device comprises a base (1), wherein a plate discharging and conveying mechanism (3) and a plurality of noise reduction taking and conveying mechanisms (4) are arranged on the base (1);

the noise reduction taking and conveying mechanism (4) is used for adsorbing and fixing the gypsum board on the drying mechanism and suspending the gypsum board;

the board discharging and conveying mechanism (3) is used for butt-jointing and fixing the gypsum board suspended by the noise reduction taking and conveying mechanism (4) and conveying the gypsum board to the next working procedure,

the plate discharging conveying mechanism (3) comprises an annular conveying track (31), a mute slide block (32) is arranged on the annular conveying track (31) in a sliding mode along the edge of the annular conveying track (31), and a control assembly (33) used for controlling the sliding and locking of the mute slide block (32) is arranged on the annular conveying track (31);

a stacking rotating member (34) which rotates and locks in a single rotation range of 90 degrees is arranged on the mute sliding block (32), a third longitudinal telescopic cavity (35) is fixedly installed at the top end of the stacking rotating member (34), a transverse telescopic cavity (36) is fixedly installed at the top end of the third longitudinal telescopic cavity (35), a second vacuum suction cup (37) for fixing a gypsum board is fixedly installed on the transverse telescopic cavity (36),

the noise reduction taking and delivering mechanism (4) comprises a containing groove (42) arranged on a container of a gypsum board on the drying mechanism, a first action piece (43) is arranged in the containing groove (42), a first vacuum suction cup (44) is arranged at the top end of the first action piece (43),

the annular conveying track (31) is formed by connecting an inclined conveying part (311) and a circulating sliding part (312) end to end,

the control assembly (33) comprises a group of driving magnets (331) which are fixedly arranged at two ends of the circulating sliding part (312) respectively, and a matching magnet block (332) matched with the driving magnets (331) is fixedly arranged in the mute sliding block (32);

a control clamping piece (333) is telescopically arranged on the mute slide block (32), a clamping opening hole (334) for nesting the control clamping piece (333) is formed in the connecting position of the inclined transportation part (311) and one side of the circulating sliding part (312),

the control clamping piece (333) comprises a sliding installation hole (3331) which is arranged on the mute sliding block (32) and longitudinally penetrates through the mute sliding block (32), a first sliding piece (3333) is installed at the top end of the sliding installation hole (3331) in a linear sliding mode through a first elastic piece (3332), and a second sliding piece (3335) is installed at the bottom end of the sliding installation hole (3331) in a linear sliding mode through a second elastic piece (3334);

the bottom end of the second sliding piece (3335) can be linearly slidably nested on the clamping opening hole (334), an M-shaped traction rope (3336) used for enabling the first sliding piece (3333) and the second sliding piece (3335) to move in opposite directions is installed on the first sliding piece (3333), and sliding pore channels used for being sleeved with the M-shaped traction rope (3336) are formed in the hole walls of the two sides of the sliding installation hole (3331).

2. The board discharging device of the gypsum board dryer according to claim 1, wherein: the stacking rotating member (34) comprises a circular groove (341) fixedly mounted on the first sliding member (3333), a circular disc (342) rotating in the circular groove (341), the third longitudinally-telescopic cavity (35) is fixedly mounted on the circular disc (342), four positioning grooves (343) are uniformly formed in the bottom surface of the circular disc (342), and a blocking member (345) is linearly slidably mounted on the positioning grooves (343) through a third elastic member (344);

clamping grooves (346) used for nesting the clamping pieces (345) are uniformly formed in the circular groove (341), and second circulating extrusion pieces (347) used for extruding the clamping pieces (345) out of the clamping grooves (346) are installed in the clamping grooves (346).

3. The board discharging device of the gypsum board dryer according to claim 1, wherein: the third longitudinal telescopic cavity (35) and the transverse telescopic cavity (36) are both composed of a sliding cylinder arranged on the outer layer and an elastic air bag arranged on the inner layer.

4. A gypsum board dryer panel output apparatus as claimed in claim 3, wherein: first action piece (43) are including fixed mounting accomodate first longitudinal extension cavity (431) in groove (42) the top fixed mounting of first longitudinal extension cavity (431) has second longitudinal extension cavity (432) top fixed mounting has L shape telescopic link (433), first vacuum chuck (44) fixed mounting be in the bottom of L shape telescopic link (433).

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