CN212608105U - Brick body steering equipment for ceramic large plate production - Google Patents

Abstract

The utility model relates to a brick body turns to equipment for production of ceramic large plate. The brick body steering device comprises a rack, a conveying mechanism, a lifting mechanism and a steering mechanism; the top of the frame is fixedly provided with a conveying mechanism, the conveying mechanism is used for connecting conveying equipment at the front end and the rear end of the equipment, receiving the ceramic large-plate bricks conveyed by the conveying equipment at the front end to a middle steering position, and conveying the ceramic large-plate bricks to the next procedure after the steering is finished; the bottom of the conveying mechanism is provided with a steering mechanism which is used for steering the brick body after lifting; the inner side of the frame at the bottom of the steering mechanism is provided with a plurality of lifting mechanisms which are used for lifting the ceramic large-plate brick body and the steering mechanism together. This equipment is through setting up the whole lifting rotary platform of lifting mechanism, with ceramic big board steadily lifting to leaving the roller platform, the ceramic big board can not produce displacement, friction in rotary platform's grid holds in the palm the net to avoided turning to the damage problem of equipment to the adobe when having realized turning to the brick body.

Description

Brick body steering equipment for ceramic large plate production

Technical Field

The utility model belongs to the technical field of pottery, in particular to brick body steering equipment for big board of pottery.

Background

In the production process of large ceramic plates, in order to improve the stability of equipment, the mold cavity of an automatic hydraulic brick press with a large length-width ratio is often designed to have a long edge at the front and back sides and a narrow edge at the left and right sides, so that the position of a brick blank on a conveying line when the brick blank is conveyed from a pressing machine process to a subsequent process is also the front and back positions of the long edge and the narrow edge at the left and right positions; in the processes of drying, glazing, firing and subsequent edging and polishing of the green body, in order to reduce the manufacturing cost and the floor area of a drying kiln, a glazing line device, a firing kiln and other devices, the brick body is often conveyed and processed by taking a long side as a side edge and a narrow side as a front side and a rear side, so that the next process can be carried out only by adjusting the edge of the pressed green body.

In the existing production of ceramic tiles, because the blank area is small and the weight is light, a cone rod type turning machine, a riding wheel type turning machine and a riding groove type turning machine are often used, the turning machines all adopt a mode of side-to-side speed difference to realize the turning of a tile body, but when the ceramic tile is applied to the production of large ceramic boards, because the area of the large ceramic boards is large and the overall weight is large, under the condition of low green body strength, if the side adjustment is carried out in a speed difference mode to enable the turning of the tile body, firstly, because the area of the large ceramic boards is large, the side adjustment turning can be realized only by the large speed difference, the cone rods, adhesive tapes and the like generate sliding friction with the tile blanks in the process, the large ceramic boards are easily influenced by friction force to generate surface damage and internal stress in the turning process, and then the tile blanks have corner breakage or middle dark crack phenomenon and can generate the defect when the subsequent firing is carried out. Secondly, because the ceramic large plate has a large area, the mode of adjusting the speed difference and turning simultaneously needs a large field to realize the change of the speed difference, therefore, a turning device suitable for the production of the ceramic large plate is needed, and the green brick is not abraded and deformed due to the friction of the turning device while the turning function is realized.

In addition, in the existing ceramic tile production, there is also a right-angle turning machine, for example, the right-angle turning mechanism in the ceramic tile conveying line right-angle turning device of application No. 201720826269.4, although such a turning machine protects the tile body well in the turning process and has less friction, the right-angle turning is realized for the whole conveying direction of the conveying line after the turning, the orientation of the tile body in space is not changed, when the whole arrangement direction of the assembly line is consistent with that of the press, a direct turning machine with the same function needs to be added to the subsequent conveying line to turn the conveying line again, the original conveying direction is recovered, the body turning function of the green tile is not realized after the two turns, the long and wide sides of the green tile come out from the press are turned and then enter the subsequent production line, and therefore, the turning machine cannot solve the turning requirement functionally.

In the existing ceramic tile production process, another steering device is provided, for example, a ceramic tile steering device of application number 201821187795.1, the device adopts a mode of steering the whole rotation of a steering roller table, the steering mode not only has large steering inertia and is easy to cause the loss of a driving device, but also has large energy consumption in the whole steering.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a setting is at big board production line of pottery, especially can set up after the shaping press to the conveying line before advancing the drying kiln on, has solved the big board production process of pottery of length width ratio, avoids turning to the brick body of the friction damage problem of equipment to the adobe when realizing that the brick body turns to and turns to equipment. Another object of the utility model is to provide a realize that the big board of pottery is stable, high quality, high efficiency, low energy consumption production are used for the brick body of the big board production of pottery to turn to equipment.

The technical proposal of the utility model is that the brick steering device for ceramic large plate production is characterized in that the brick steering device comprises a frame, a conveying mechanism, a lifting mechanism and a steering mechanism; the top of the rack is fixedly provided with a conveying mechanism, the conveying mechanism is used for connecting conveying equipment at the front end and the rear end of the equipment, receiving the ceramic large-plate brick bodies conveyed by the conveying equipment at the front end to a middle steering position, and conveying the ceramic large-plate brick bodies to the next procedure after the steering is finished; the bottom of the conveying mechanism is provided with a steering mechanism, and the steering mechanism is used for steering the brick body after lifting; the inner side of the rack positioned at the bottom of the steering mechanism is provided with a plurality of lifting mechanisms, and the lifting mechanisms are used for lifting the ceramic large-plate brick body and the steering mechanism together.

Preferably, the method comprises the following steps: the rack is formed by splicing two or more rack components; the frame is provided with a plurality of longitudinal beams which are arranged in parallel, hoisting mounting holes and guide holes for hoisting the lifting mechanism are arranged on part of the longitudinal beams in pairs, each pair of hoisting mounting holes is arranged at two ends of the corresponding longitudinal beam, and the guide direction is vertical; each pair of guide holes are also arranged at two ends of the corresponding longitudinal beam in the vertical direction; the hoisting mounting hole on the same side is arranged adjacent to the guide hole.

Preferably, the method comprises the following steps: the conveying mechanism comprises conveying carrier rollers, a synchronous belt wheel set, a synchronous belt, a first motor and a first speed reducer which are arranged in an array manner; the conveying carrier roller consists of a hollow circular tube, support sleeve rings arranged on the hollow circular tube in an array manner, driven shaft sleeves and driving shaft sleeves which are fixed at the head end and the tail end of the hollow circular tube, and driving synchronous belt pulleys are arranged on the driving shaft sleeves;

preferably, the method comprises the following steps: the conveying mechanism also comprises a section bar bracket and bearing blocks which are arranged at the two ends of the conveying carrier roller and used for fixing the conveying carrier roller on the upper surface of the section bar bracket; the synchronous pulley group consists of a driving wheel arranged on the output shaft of the speed reducer, idler wheels arranged on two sides of the driving wheel to increase the synchronous belt action area of the driving wheel and a tension wheel; when the first motor works, the output shaft of the first speed reducer rotates along with the driving wheel and the synchronous belt to drive the driving wheel and the synchronous belt to act, and then a plurality of groups of conveying carrier rollers are driven to rotate; the conveying mechanism can be integrally split into the conveying assemblies which are consistent with the machine frame in number according to the splitting condition of the machine frame, and each group of conveying assemblies are driven by an independent driving motor.

Preferably, the method comprises the following steps: the lifting mechanism comprises a lifting platform, a cam assembly and a driving assembly; the lifting platform is used for bearing the steering mechanism and integrally reciprocates in the vertical direction; the drive assembly is used for outputting epicyclic motion; the cam assembly is used for converting the rotary motion output by the driving assembly into linear motion of the lifting platform.

Preferably, the method comprises the following steps: the lifting platform comprises a lifting rack, the lifting rack is welded by a plurality of rectangular section steels, adhesive tapes arranged in parallel arrays are arranged above the lifting rack, and the adhesive tapes are fixed on the section steels and are fixed on the lifting rack through bolts; guide posts are arranged below the lifting support and correspond to the guide holes in the longitudinal beams of the rack one by one; a bearing is arranged below the guide post; the rubber strips and the profiles which are arranged in parallel with the conveying carrier rollers of the conveying mechanism, each combined rubber strip and each combined profile is arranged between two adjacent groups of conveying carrier rollers, and the whole conveying carrier rollers and the conveying carrier rollers are alternately arranged.

Preferably, the method comprises the following steps: the cam component comprises a hoisting bolt, the hoisting bolt is arranged corresponding to a hoisting mounting hole on a longitudinal beam of the rack, the hoisting bolt is mounted on the longitudinal beam by arranging nuts on the upper and lower surfaces of the rack, a suspension bearing is mounted below the hoisting bolt, a cam rotating shaft is arranged below the corresponding longitudinal beam, and two ends of the cam rotating shaft respectively penetrate through the suspension bearings at corresponding positions, so that the cam rotating shaft can rotate on the suspension bearings; the cam rotating shaft is sleeved with cams which are arranged in pairs and respectively correspond to the bearings of the lifting platform one by one, grooves are formed in the cylindrical surfaces of the cams, the outer diameter surfaces of the bearings are in line contact with the bottom surfaces of the grooves of the cams, when the cam rotating shaft rotates, the cams rotate along with the cam, and the highest points of the bottom surfaces of the grooves in the vertical direction change along with the cam when the cam rotates, so that the upper position and the lower position of the bearings change simultaneously along with the rotation of the cam, and the lifting platform moves up and down; the cam rotating shafts are connected in series through the first connecting rod, the second connecting rod and the first rotating shaft which are paired, and when one cam rotating shaft rotates, the other cam rotating shafts can be driven to synchronously rotate.

Preferably, the method comprises the following steps: the driving assembly comprises a second motor, a second speed reducer, a first cam divider and an induction sheet arranged on an output shaft of the first cam divider, the outer contour of the induction sheet is a cylinder with a sector flange, and a photoelectric sensor is arranged on the side edge of the output shaft; the cam component is provided with a third connecting rod, a fourth connecting rod, a second rotating shaft and a crank; the second motor and the second speed reducer are arranged on one side of the input shaft of the first cam divider, one end of the crank is arranged on the output shaft of the first cam divider of the cam assembly, the other end of the crank is provided with a mounting groove with an adjustable mounting position, the crank is connected with the fourth connecting rod through the second rotating shaft, when the output shaft of the first cam divider rotates, the crank does circular motion, then the third connecting rod is pushed to swing forwards and backwards through the second rotating shaft and the fourth connecting rod, then the cam rotating shaft rotates, when the induction sheet rotates along with the output shaft, the photoelectric sensor can sense a position signal of the fan-shaped flange, so that the initial position and the stop position of the output shaft are controlled, and then the position of the lifting rack during up-and-down action is finally.

Preferably, the method comprises the following steps: the steering mechanism comprises a third motor, a third speed reducer, a second cam divider, a grid supporting net, a photoelectric sensor and a sensing piece; the second cam divider is fixedly arranged with the lifting platform, and the cam divider can synchronously move up and down when the lifting platform moves up and down; the grid supporting net is a steel plate with regularly-arranged rectangular holes cut, and is borne on the adhesive tape above the lifting platform, the supporting lantern ring of the conveying mechanism is positioned at the position of the rectangular holes of the grid supporting net, the center of the lower surface of the grid supporting net is connected with the output shaft of the second cam divider, and when the second cam divider acts, the grid supporting net rotates along with the rotation of the output shaft and is always in contact with the adhesive tape; when the lifting machine frame is positioned at a low position, the highest point of the supporting lantern ring is higher than the upper surface of the grid supporting net, and when the lifting machine frame is positioned at a high position, the highest point of the supporting lantern ring is lower than the upper surface of the grid supporting net; the second sensing piece is arranged on the output shaft of the second cam divider, and the shape of the second sensing piece is the same as that of the first sensing piece; the photoelectric sensor is arranged on the side edge of the output shaft and used for receiving a signal of the first sensing piece so as to control the initial action position and the stop working position of the second cam divider.

Preferably, the method comprises the following steps: the side that conveying mechanism is connected with preceding, back end transfer chain still is equipped with into brick detection sensor and goes out brick detection sensor.

Compared with the prior art, the beneficial effects of the utility model are that:

the utility model discloses a this equipment can be with the ceramic big board steadily the lifting to leaving the roller platform through setting up the whole lifting rotary platform of lifting mechanism, the rotatory in-process of rotary platform, the ceramic big board can not produce displacement, friction on rotary platform's grid holds in the palm the net, avoided adopting traditional speed difference to realize that the brick body turns to easily cause the product to break the angle or the middle risk that causes the dark fracture because of the speed difference to avoided turning to the damage problem to the adobe because of will turning to when the brick body turns to, satisfied the stable production of product.

Do a matter the utility model discloses a this equipment is through setting up the whole lifting rotary platform of lifting mechanism, and rotary platform mainly is the grid and holds in the palm the net, and equipment is light and handy, and it is rotatory to hold in the palm the net by the grid when the brick body turns to and bear the weight of the brick body, does not have the problem that causes the drive arrangement loss greatly easily to turn to inertia, and wholly turns to the power consumption low.

The utility model discloses a this equipment sets up on the production conveying line, directly accomplishes the demand that turns to at the straight line production in-process, has saved the production place space greatly.

Drawings

FIG. 1 is a perspective view of the whole device of the present invention;

FIG. 2 is a top view of FIG. 1;

FIG. 3 is a view from one side of FIG. 1;

FIG. 4 is a sectional view taken along line B-B of FIG. 3;

FIG. 5 is a view from the other side of FIG. 1;

FIG. 6 is a sectional view taken along line F-F of FIG. 5;

FIG. 7 is a front view of the grid support net of the present invention in a lowered position;

FIG. 8 is a front view of the grid support net of the present invention in a raised position;

fig. 9 is a schematic perspective view of the conveying mechanism of the present invention;

fig. 10 is a schematic perspective view of the conveying idler of the present invention;

fig. 11 is a schematic structural diagram of the lifting mechanism of the present invention;

fig. 12 is a schematic perspective view of the driving assembly of the present invention;

fig. 13 is a schematic perspective view of the steering mechanism of the present invention;

fig. 14 is a rear view of the steering mechanism of the present invention;

fig. 15 is a control flow chart of the present invention.

Description of the main component symbols:

guide hole 112 of longitudinal beam 110 hoisting mounting hole 111 of rack 100

Hollow round tube 211 of conveying idler 210 of conveying mechanism 200 supports collar 212

Driven shaft sleeve 214 driving shaft sleeve 215 driving synchronizing wheel 216 synchronizing wheel set 220

Drive pulley 221 idler pulley 222 tension pulley 223 timing belt 230

First motor 240 first speed reducer 250 section bar support 260 advances brick detection sensor 261

Brick discharge detection sensor 262 bearing seat 270 lifting mechanism 300 lifting platform 310

Lifting frame 311 bolt 312 section bar 313 adhesive tape 314

Guide post 315 bearing 316 nut 32 cam assembly 320

Hoisting bolt 321 suspension type bearing 322 cam rotating shaft 323 cam 324

Groove 3241 first link 325 third link 3251 second link 326

Fourth link 3261 first shaft 327 and second shaft 3271 crank 328

Mount-slot 3281 nut 329 drive assembly 330 second motor 331

Second reducer 332 cam divider 333 first sensing piece 334 photoelectric sensor 335

Steering mechanism 400 third motor 401 third reducer 402 cam divider 403

Grid supporting net 404 photoelectric sensor 405 and second sensing piece 406

Detailed Description

The utility model discloses the following will make further detail with the accompanying drawing:

referring to fig. 1, the brick turning apparatus for ceramic large plate production includes a frame 100, a conveying mechanism 200, a lifting mechanism 300, and a turning mechanism 400; the top of the rack 100 is fixedly provided with a conveying mechanism 200, the conveying mechanism 200 is used for connecting conveying equipment at the front end and the rear end of the equipment, receiving ceramic large-plate bricks conveyed by the conveying equipment at the front end to a middle turning position, and conveying the ceramic large-plate bricks to the next procedure after turning is finished; the bottom of the conveying mechanism 200 is provided with a steering mechanism 400, and the steering mechanism 400 is used for steering the brick body after lifting; the inner side of the frame 100 at the bottom of the steering mechanism 400 is provided with a plurality of lifting mechanisms 300, and the lifting mechanisms 300 are used for lifting the ceramic large-plate brick body and the steering mechanism together.

Because the area of the large ceramic plate is large, in order to improve the convenience of processing, transportation and field assembly of the steering device, the frame 100 can be formed by splicing two or more frame components; referring to fig. 6, the embodiment is a three-segment split rack 100; the rack 100 is provided with a plurality of longitudinal beams 110 arranged in parallel, hoisting mounting holes 111 and guide holes 112 for hoisting the lifting mechanism 300 are arranged on some of the longitudinal beams 110 in pairs, each pair of hoisting mounting holes 111 is arranged at two ends of the corresponding longitudinal beam 110, and the guide direction is vertical; each pair of guide holes 112 is also arranged at two ends of the corresponding longitudinal beam, and the direction is vertical; the hoisting installation hole 111 on the same side is arranged adjacent to the guide hole 112.

Referring to fig. 9 and 10, the conveying mechanism 200 includes conveying rollers 210, a synchronous pulley set 220, a synchronous belt 230, a first motor 240 and a first speed reducer 250 arranged in an array; the conveying carrier roller 210 comprises a hollow circular tube 211, support lantern rings 212 arranged on the hollow circular tube 211 in an array mode, driven shaft sleeves 214 and driving shaft sleeves 215 fixed to the head end and the tail end of the hollow circular tube 211, and driving synchronizing wheels 216 are arranged on the driving shaft sleeves 215; the conveying mechanism 200 further comprises a profile bracket 260 and bearing blocks 270 which are arranged at two ends of the conveying idler 210 and fix the idler 210 on the upper surface of the profile bracket 260. The synchronous pulley set 220 comprises a driving pulley 221 mounted on the output shaft of the reducer, an idle pulley 222 and a tension pulley 223 mounted on both sides of the driving pulley 221 to increase the action area of the driving pulley 221 and the synchronous pulley 230, and a plurality of tension pulleys 223 arranged on the side of the aluminum profile 260 and between the driving synchronous pulleys of each conveying carrier roller 210, for pressing the tooth surface of the synchronous pulley 230 against the driving synchronous pulley 216; when the first motor 240 works, the output shaft of the first speed reducer 250 rotates along with the first motor, so as to drive the driving wheel 221 and the synchronous belt 230 to act, and further drive the plurality of groups of conveying carrier rollers 210 to rotate; the conveying mechanism 200 can be integrally separated into three groups of conveying assemblies, which are respectively mounted on three groups of single machine frames 100, and the conveying assemblies of each group are driven by an independent first motor 240, according to the separation condition of the machine frames 100, and the number of the conveying assemblies is consistent with that of the machine frames 100.

Referring to fig. 11, the lifting mechanism 300 includes a lifting platform 310, a cam assembly 320, and a driving assembly 330; the lifting platform 310 is used for bearing the steering mechanism 400 and integrally reciprocates in the vertical direction; the drive assembly 33 is for outputting an epicyclic motion; the cam assembly 320 is used to convert the rotational motion output by the drive assembly into linear motion of the lift platform.

Referring to fig. 11, the lifting platform 310 includes a lifting frame 311, the lifting frame 311 is welded by a plurality of rectangular section steels, adhesive tapes 314 arranged in parallel are disposed above the lifting frame 311, the adhesive tapes 314 are fixed on the section steels 313 and fixed on the lifting frame 311 by bolts 312; guide posts 315 are arranged below the lifting frame 311 and correspond to the guide holes 112 on the longitudinal beams 110 of the frame 100 one by one; a bearing 316 is arranged below the guide column 315; the adhesive strips 314, the profiles 313 arranged in parallel arrays are arranged parallel to the conveying idlers 210 of the conveying mechanism 100, and each combined adhesive strip 314, profile 313 is arranged between two adjacent sets of conveying idlers 110, the whole being arranged alternately with the conveying idlers 210.

Referring to fig. 11, the cam assembly 320 includes a hoisting bolt 321, the hoisting bolt 321 is disposed corresponding to the hoisting mounting hole 111 on the longitudinal beam 110 of the rack 100, the hoisting bolt 321 is mounted on the longitudinal beam 110 by disposing nuts 329 on the upper and lower surfaces of the rack 100, a suspension bearing 322 is mounted below the hoisting bolt 321, a cam rotating shaft 323 is disposed below the corresponding longitudinal beam 110, and two ends of the cam rotating shaft 323 respectively pass through the suspension bearings 322 at corresponding positions, so that the suspension bearings 322 can rotate; the cam rotating shaft 323 is also sleeved with cams 324 which are arranged in pairs and respectively correspond to the bearings 316 of the lifting platform 310 one by one, a groove 3241 is formed in the cylindrical surface of the cam 324, the outer diameter surface of the bearing 316 is in line contact with the bottom surface of the groove of the cam 324, when the cam rotating shaft 323 rotates, the cam 324 rotates along with the cam, and the highest point of the bottom surface of the groove in the vertical direction changes along with the rotation of the cam 324, so that the upper position and the lower position of the bearing 316 change along with the rotation of the cam 324 at the same time, and the lifting platform 310 moves up and down; the plurality of sets of cam rotating shafts 323 are connected in series through a pair of a first connecting rod 325, a second connecting rod 326 and a first rotating shaft 327, and when one set of cam rotating shafts 323 rotates, the other set of cam rotating shafts 323 are driven to rotate synchronously.

Referring to fig. 7 and 12, the cam assembly 320 further includes a driving assembly 330, and the driving assembly 330 includes a second motor 331, a second reducer 332, and a first cam divider 333; the cam assembly 320 includes a set of a third long link 3251, a fourth long link 3261, a second shaft 3271, and a crank 328. The second motor 331 and the second reducer 332 are disposed on the input shaft side of the first cam divider 333, one end of the crank 328 is mounted on the output shaft of the first cam divider 333 of the cam assembly 320, the other end is provided with a mounting groove 3281 whose mounting position can be adjusted, the crank is connected with the fourth connecting rod 3261 through the second rotating shaft 3271, when the second motor 331 operates, the output shaft of the first cam divider 333 is driven to rotate through the second reducer 332, the crank 328 makes a circular motion, and then the third connecting rod 3251 is pushed to swing back and forth through the second rotating shaft 3271 and the fourth connecting rod 3261, so that the cam rotating shaft 323 rotates. The driving assembly 330 further includes a sensing piece 334 disposed on the output shaft of the first cam divider 333, the outer contour of the sensing piece 334 is a cylinder with a sector flange, a photoelectric sensor 335 is disposed on the side of the output shaft, when the sensing piece 333 rotates along with the output shaft, the photoelectric sensor 335 can sense a position signal of the sector flange, so as to control the start position and stop position of the output shaft, and finally control the position of the lifting frame 311 during the up-and-down motion.

Referring to fig. 13, the steering mechanism 400 includes a third motor 401, a third reducer 402, a second cam divider 403, a grid support net 404, a photoelectric sensor 405, and a sensor sheet 406. The second cam divider 403 is fixedly mounted on the lifting platform 310, and when the lifting platform 310 moves up and down, the cam divider 403 moves up and down synchronously. The grid supporting net 404 is a steel plate with regularly arranged rectangular holes, and is borne on the adhesive tape 314 above the lifting platform 310, the supporting lantern ring 212 of the conveying mechanism 100 is positioned at the position of the rectangular holes of the grid supporting net 404, the center of the lower surface of the grid supporting net 404 is connected with an output shaft of the second cam divider 403, and when the second cam divider 403 acts, the grid supporting net 404 rotates along with the rotation of the output shaft and is always in contact with the adhesive tape 314; when the lifting frame 311 is located at a low position, the highest point of the supporting lantern ring 212 is higher than the upper surface of the grid supporting net 404, and when the lifting frame 311 is located at a high position, the highest point of the supporting lantern ring 212 is lower than the upper surface of the grid supporting net 404. A sensing piece 406 is provided on the output shaft of the second cam divider 403, and has the same shape as the sensing piece 333; the photoelectric sensor 405 is disposed on the side of the output shaft for receiving the signal from the sensing piece 333 to control the initial operation position and the stop operation position of the second cam divider 403.

Referring to fig. 14, a brick feeding detection sensor 261 and a brick discharging detection sensor 262 are further provided at the side where the conveying mechanism 200 is connected to the front and rear conveyor lines.

Referring to fig. 15, the control flow of the apparatus is as follows:

a) the equipment is in a standby state, the conveying mechanism 200 is in a pause state, the output shaft of the first cam divider 333 of the lifting mechanism 300 is in an initial position, and the lifting platform 310 is in a low position;

b) the brick entering detection sensor 261 detects that the brick enters, the first motor 240 of the conveying mechanism 200 starts to act, the conveying carrier roller 210 rotates, and the support collar 212 rotates to convey the brick to the preset position.

c) After the brick body is conveyed to the preset position, the second motor 331 of the lifting mechanism 300 acts, the first cam divider 333 acts through the second speed reducer 332, the output shaft of the first cam divider 333 rotates to the stop position, the lifting platform 310 is lifted to the high position state through the action of the cam assembly 320, and the grid supporting net 404 of the steering mechanism 400 supports the brick body;

d) the motor 401 of the steering mechanism 400 operates to rotate the output shaft of the second cam divider 403 by 90 degrees, and the grid supporting net 404 supports the brick bodies by 90 degrees;

e) after the rotation, the second motor 331 of the lifting mechanism 300 operates, the first cam divider 333 is operated by the second speed reducer 332, the output shaft of the first cam divider 333 is rotated to the initial position, the lifting platform 310 is lowered to the low position by the operation of the cam assembly 320, the brick is lowered by the grid supporting net 404 of the steering mechanism 400, and the brick is supported by the supporting collar 212.

f) When the first motor 240 of the conveying mechanism 200 is operated, the conveying carrier roller 210 rotates, the support collar 212 rotates to convey the brick bodies to the lower section conveying line, and when the brick discharge detection sensor 262 detects that the conveying is completed, the first motor 240 stops, and the equipment returns to the standby state.

The above description is only a preferred embodiment of the present invention, and all equivalent changes and modifications made according to the scope of the claims of the present invention should be covered by the claims of the present invention.

Claims (10)

1. A brick body steering device for ceramic large plate production is characterized by comprising a rack, a conveying mechanism, a lifting mechanism and a steering mechanism; the top of the rack is fixedly provided with a conveying mechanism, the conveying mechanism is used for connecting conveying equipment at the front end and the rear end of the equipment, receiving the ceramic large-plate brick bodies conveyed by the conveying equipment at the front end to a middle steering position, and conveying the ceramic large-plate brick bodies to the next procedure after the steering is finished; the bottom of the conveying mechanism is provided with a steering mechanism, and the steering mechanism is used for steering the brick body after lifting; the inner side of the rack positioned at the bottom of the steering mechanism is provided with a plurality of lifting mechanisms, and the lifting mechanisms are used for lifting the ceramic large-plate brick body and the steering mechanism together.

2. The brick turning device for ceramic large plate production according to claim 1, wherein the frame is formed by splicing two or more frame components; the frame is provided with a plurality of longitudinal beams which are arranged in parallel, hoisting mounting holes and guide holes for hoisting the lifting mechanism are arranged on part of the longitudinal beams in pairs, each pair of hoisting mounting holes is arranged at two ends of the corresponding longitudinal beam, and the guide direction is vertical; each pair of guide holes are also arranged at two ends of the corresponding longitudinal beam in the vertical direction; the hoisting mounting hole on the same side is arranged adjacent to the guide hole.

3. The brick body steering device for ceramic large-plate production according to claim 1, wherein the conveying mechanism comprises conveying carrier rollers, a synchronous belt wheel set, a synchronous belt, a first motor and a first speed reducer which are arranged in an array; the conveying carrier roller comprises a hollow circular tube, supporting sleeve rings arranged on the hollow circular tube in an array mode, driven shaft sleeves and driving shaft sleeves, wherein the driven shaft sleeves and the driving shaft sleeves are fixed at the head end and the tail end of the hollow circular tube, and driving synchronizing wheels are arranged on the driving shaft sleeves.

4. The brick turning device for ceramic large plate production according to claim 3, wherein the conveying mechanism further comprises a section bar bracket and bearing blocks arranged at two ends of the conveying carrier roller for fixing the conveying carrier roller on the upper surface of the section bar bracket; the synchronous pulley group consists of a driving wheel arranged on the output shaft of the speed reducer, idler wheels arranged on two sides of the driving wheel to increase the synchronous belt action area of the driving wheel and a tension wheel; the system comprises a profile support, a plurality of driving synchronous wheels, a plurality of first speed reducers, a plurality of second speed reducers, a plurality of tension pulleys, a plurality of second speed reducers and a plurality of conveying carrier rollers, wherein the plurality of tension pulleys are arranged on the side part of the profile support and between the driving synchronous wheels of each conveying carrier roller and are used for pressing the tooth surfaces of the synchronous belts on the driving synchronous wheels; the conveying mechanism can be integrally split into the conveying assemblies which are consistent with the machine frame in number according to the splitting condition of the machine frame, and each group of conveying assemblies are driven by an independent first motor.

5. The brick turning apparatus for ceramic large plate production as claimed in claim 1, wherein the lifting mechanism comprises a lifting platform, a cam assembly and a driving assembly; the lifting platform is used for bearing the steering mechanism and integrally reciprocates in the vertical direction; the drive assembly is used for outputting epicyclic motion; the cam assembly is used for converting the rotary motion output by the driving assembly into linear motion of the lifting platform.

6. The brick turning device for ceramic large plate production according to claim 5, wherein the lifting platform comprises a lifting frame, the lifting frame is welded by a plurality of rectangular section steels, adhesive tapes arranged in parallel array are arranged above the lifting frame, and the adhesive tapes are fixed on the section steels and fixed on the lifting frame through bolts; guide posts are arranged below the lifting support and correspond to the guide holes in the longitudinal beams of the rack one by one; a bearing is arranged below the guide post; the rubber strips and the profiles which are arranged in parallel with the conveying carrier rollers of the conveying mechanism, each combined rubber strip and each combined profile is arranged between two adjacent groups of conveying carrier rollers, and the whole conveying carrier rollers and the conveying carrier rollers are alternately arranged.

7. The brick steering device for ceramic large-plate production according to claim 5, wherein the cam assembly comprises a hoisting bolt, the hoisting bolt is arranged corresponding to a hoisting mounting hole on a longitudinal beam of the frame, the hoisting bolt is arranged on the longitudinal beam by arranging nuts on the upper and lower surfaces of the frame, a suspension bearing is arranged below the hoisting bolt, a cam rotating shaft is arranged below the corresponding longitudinal beam, and two ends of the cam rotating shaft respectively penetrate through the suspension bearings at corresponding positions, so that the cam rotating shaft can rotate on the suspension bearings; the cam rotating shaft is also sleeved with cams which are arranged in pairs and respectively correspond to the bearings of the lifting platform one by one, grooves are processed on the cylindrical surfaces of the cams, and the outer diameter surfaces of the bearings are in line contact with the bottom surfaces of the grooves of the cams; when the cam rotating shaft rotates, the cam rotates along with the cam, and the highest point of the bottom surface of the groove in the vertical direction changes along with the cam when the cam rotates, so that the upper position and the lower position of the bearing change along with the rotation of the cam, and the lifting platform moves up and down; the cam rotating shafts are connected in series through the first connecting rod, the second connecting rod and the first rotating shaft which are paired, and when one cam rotating shaft rotates, the other cam rotating shafts can be driven to synchronously rotate.

8. The brick turning device for ceramic large plate production according to claim 7, wherein the driving assembly comprises a second motor, a second speed reducer, a first cam divider and a sensing piece arranged on an output shaft of the first cam divider, the sensing piece is a cylinder with a sector flange in the outer contour, and a photoelectric sensor is arranged on the side edge of the output shaft; the cam component is provided with a third connecting rod, a fourth connecting rod, a second rotating shaft and a crank; the second motor and the second speed reducer are arranged on one side of the input shaft of the first cam divider, one end of the crank is arranged on the output shaft of the first cam divider of the cam assembly, the other end of the crank is provided with a mounting groove with an adjustable mounting position, the crank is connected with the fourth connecting rod through the second rotating shaft, when the output shaft of the first cam divider rotates, the crank does circular motion, then the third connecting rod is pushed to swing forwards and backwards through the second rotating shaft and the fourth connecting rod, then the cam rotating shaft rotates, when the induction sheet rotates along with the output shaft, the photoelectric sensor can sense a position signal of the fan-shaped flange, so that the initial position and the stop position of the output shaft are controlled, and then the position of the lifting rack during up-and-down action is finally.

9. The brick turning device for ceramic large plate production according to claim 1, wherein the turning mechanism comprises a third motor, a third reducer, a second cam divider, a grid support net, a photoelectric sensor and a sensing piece; the second cam divider is fixedly arranged with the lifting platform, and the cam divider can synchronously move up and down when the lifting platform moves up and down; the grid supporting net is a steel plate with regularly arranged rectangular holes and is borne on the adhesive tape above the lifting platform, the supporting lantern ring of the conveying mechanism is positioned at the position of the rectangular holes of the grid supporting net, and the center of the lower surface of the grid supporting net is connected with the output shaft of the second cam divider; when the second cam divider acts, the grid supporting net rotates along with the rotation of the output shaft and is always in a contact state with the rubber strip; when the lifting machine frame is positioned at a low position, the highest point of the supporting lantern ring is higher than the upper surface of the grid supporting net, and when the lifting machine frame is positioned at a high position, the highest point of the supporting lantern ring is lower than the upper surface of the grid supporting net; the second sensing piece is arranged on the output shaft of the second cam divider, and the shape of the second sensing piece is the same as that of the first sensing piece; the photoelectric sensor is arranged on the side edge of the output shaft and used for receiving a signal of the first sensing piece so as to control the initial action position and the stop working position of the second cam divider.

10. The brick turning device for ceramic large plate production according to claim 1, wherein the side of the conveying mechanism connected with the front and rear section conveying lines is further provided with a brick feeding detection sensor and a brick discharging detection sensor.

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