CN114311234A - Ceramic rolling equipment of full-automatic production line - Google Patents

Abstract

The invention relates to the technical field of ceramic equipment, in particular to ceramic rolling equipment of a full-automatic production line, which structurally comprises: the soil conveying device is placed on a material bearing plate on the soil conveying device through the adobe columns, the feeding chain runs to drive the material bearing plate to carry the adobe columns upwards, the effect of automatically lifting the adobe columns to a high position and then turning the adobe columns to fall on the first conveyor is achieved, manual feeding is avoided, the process of manually lifting the heavy and coarse adobe columns to the higher first conveyor is replaced, and the angle plate is pulled upwards obliquely by pushing the oil cylinder, so that the rotating plate swings upwards, the rotating rod drives the transferring cylinder to rotate on the transverse plate, after the rotating rod rotates ninety degrees, the transfer cylinder is vertical to the second conveyor, and the transfer cylinder puts down the cut adobe column in the direction that the bottom surface faces the second conveyor, thereby effectively avoiding the adobe column from being cylindrical, the rolling mechanism is placed on the second conveyor in a side surface mode, so that the rolling phenomenon is easy to occur, the feeding is time-saving and labor-saving, and the feeding is safe and stable.

Description

Ceramic rolling equipment of full-automatic production line

Technical Field

The invention relates to the technical field of ceramic equipment, in particular to ceramic rolling equipment of a full-automatic production line.

Background

In ceramic molding machinery, a roll forming machine is a common ceramic production device, and with the development of the ceramic industry, an automatic ceramic production device gradually becomes a mainstream production device. The existing ceramic rolling equipment has the following defects:

1. the method is characterized in that the rough and heavy adobes need manual operation and are lifted to a higher conveyor, the working efficiency is extremely low, the labor cost is very high, the adobes on the conveyor are cut and cut off, and the cut small sections are continuously conveyed to a green compact, however, the initial adobes are generally cylindrical due to the small size and weight, and the cut small sections are also cylindrical after being longitudinally cut off, so that the cut adobes are easy to roll on the conveyor, and even the adobes roll out of a belt to fall to the ground due to the vibration of the conveyor, so that the adobes are wasted and re-fed, and time and labor are wasted;

2. the production of ceramics is a manual operation, including the following processes, at first, need to prepare the adobe, then wait for the roller to lift up, then throw into the adobe in the die cavity of the mould again, the artificial adobe on the mould compacts, and then mould pressing shaping through the roller, the ceramic adobe after shaping, send into baking equipment to dry and shape manually, take out manually finally, move to the brace, the automaticity of the ceramic production apparatus at present is low, the artificial work load is large, especially need the artificial feeding and discharging during shaping, the daily output is low, cause the cost to be high;

3. the mould on the ceramic rolling equipment is a plaster mould, and 200-300 plaster moulds are required to be configured. However, the gypsum of the mould has low strength and is easy to wear, and after a gypsum mould is used for a plurality of times, the surface of the gypsum mould begins to become rough, which seriously influences the forming quality of the ceramic body. In addition, the average life of the plaster mold is only dozens to hundreds of times, and the mold needs to be replaced frequently, so that a large amount of plaster needs to be consumed, which not only wastes resources, but also needs a large amount of manpower to process the plaster mold with large quantity. And a large amount of waste gypsum is generated by using the moulds, so that resources are wasted, the use area of a factory is wasted, human resources are wasted, and great pressure is brought to environmental protection, energy conservation and emission reduction. Therefore, the use of the plaster mold brings great burden to enterprises, influences the benefits of the enterprises, and is a problem to be solved urgently.

Disclosure of Invention

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by the practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

The invention aims to overcome the defects and provide ceramic rolling equipment of a full-automatic production line.

In order to achieve the purpose, the technical solution of the invention is as follows: the utility model provides a ceramic rolling press equipment of full-automatic production line, its structure includes: a soil feeding device, a first conveyor, a adobe column, a second conveyor, a transfer device, a moving device and a roller press, the cutting machine comprises a die, a rotary table, a third conveyor, a motor, a cutter and a cutting cylinder, wherein a soil conveying device used for conveying a adobe column is arranged on one side of the first conveyor, the first conveyor and the second conveyor are driven by the motor, a transfer device used for transferring the adobe column and adjusting the angle is arranged between the first conveyor and the second conveyor, the cutting cylinder is connected with the cutter used for cutting off the adobe column, a moving device is arranged on one side of the second conveyor, a roller press is arranged on one side of the rotary table, the third conveyor is arranged on the other side of the rotary table, the die is rotatably arranged on the rotary table, the cutting cylinder is connected with the cutter used for cutting off the adobe column, the motor adopts a servo motor, a photoelectric switch is further connected on the transfer device, and the photoelectric switch is electrically connected with the motor.

Preferably, the soil conveying device comprises two mounting frames, two conveying chains and two material bearing plates, the two conveying chains are mounted on the mounting frames, the material bearing plates used for lifting and conveying the adobe pillars are arranged on the conveying chains, and the mounting frames are arranged on the first conveyor.

Preferably, the transfer device comprises a transfer cylinder, a transverse plate, a rotating rod, an angle plate, a support frame, a pushing cylinder, a rotating plate and a rotating shaft, one side of the rotating plate is rotatably arranged on the transverse plate through being connected with the rotating rod, the other side of the rotating plate is connected with the rotating shaft, the angle plate is rotatable on the rotating plate through the rotating shaft, the pushing cylinder is rotatably connected on the support frame, the rotating rod is provided with the transfer cylinder for fixing the adobe column, the rotating rod is arranged on the transverse plate, and the rotating rod rotates to push the angle plate through the pushing cylinder in a telescopic mode.

Preferably, a suction cup for fixing the adobe column is arranged on the transferring cylinder, and the transferring cylinder is arranged above the first conveyor.

Preferably, the angle of the corner plate is ninety degrees, one of two edges of the ninety degrees is connected with the rotating shaft, the other edge of the ninety degrees is connected with the pushing oil cylinder, and the pushing oil cylinder is obliquely arranged on the supporting frame.

Preferably, the moving device comprises a control box, a lifting platform, a rotating motor, a rotating transmission arm, a steering arm, a taking and placing device, a material pressing disc and a material throwing disc, the steering arm is installed on the rotating and rotating transmission arm, the rotating motor is connected with the rotating and rotating transmission arm, the rotating motor is arranged on the lifting platform, the steering arm is provided with the taking and placing device for extracting the adobes in the molds, the lifting platform can be installed on the control box in a front-back movement mode, a transmission belt connected with the rotating motor is arranged in the rotating transmission arm, the taking and placing device, the material throwing disc and the material pressing disc are installed on the steering arm in a triangular mode, and the taking and placing device, the material throwing disc and the material pressing disc are respectively arranged clockwise.

Preferably, the taking and placing device comprises an air cylinder, a partition plate, fixing blocks, clamping blocks, filling columns, guide rails and a ventilation layer, the air cylinder penetrates through the partition plate to be connected with the filling columns, a liftable interval is arranged between the filling columns and the partition plate, the fixing blocks are fixed on the partition plate, the clamping blocks are movably installed on the partition plate, small inclined planes and large inclined planes are arranged on the filling columns, small inclined planes are arranged between every two adjacent large inclined planes, sliding grooves in clearance fit with the guide rails on the clamping blocks are arranged on the large inclined planes, sliding grooves in clearance fit with the guide rails on the fixing blocks are arranged on the small inclined planes, the filling columns are in a hexagonal frustum shape, the small inclined planes are parallel to the fixing blocks, the clamping blocks are lifted and gathered together through the filling columns, the clamping blocks are arranged between every two adjacent fixing blocks, the ventilation layer is connected to the clamping blocks and the fixing blocks, and the partition plate is installed at the lower end of a steering arm.

Preferably, the clamping block is annularly mounted on the partition plate, and the fixing block is annularly mounted on the partition plate.

Preferably, the mold comprises an inner mold, locking holes, a support ring, a filter cylinder, a bearing table, an outer cylinder, air inlet through holes and a gap seam, the inner mold is bonded in the filter cylinder, the support ring is installed at the upper end of an outer ring of the filter cylinder, the bearing table is installed at the upper end of an inner ring of the outer cylinder, the filter cylinder is hung on the outer cylinder through the support ring and the bearing table, the support ring and the bearing table are respectively provided with a plurality of locking holes, the gap seam convenient for air inlet is arranged between the filter cylinder and the outer cylinder, the air inlet through holes are provided with a plurality of filtering holes which are distributed at the cylinder bottom and the cylinder wall of the outer cylinder, the filter cylinder is provided with a plurality of uniformly distributed filtering holes for uniform air inlet, the inner mold adopts a microporous resin material layer, the bolts are inserted into the plurality of locking holes, the support ring is fixed on the bearing table through the bolts, a sealing ring for preventing air leakage is filled between the support ring and the bearing table, and the filter cylinder adopts metal material or hard material.

Preferably, the outer drum is rotatably mounted on the turntable.

By adopting the technical scheme, the invention has the beneficial effects that:

1. the soil billet post is placed on the material bearing plate on the soil conveying device, the conveying chain runs, the material bearing plate is driven to drive the soil billet post to be conveyed upwards, the effect of automatically lifting the soil billet post to a high position and then turning the soil billet post to fall on the first conveyor is achieved, manual feeding is avoided, the manual process of manually lifting and conveying heavy soil billet posts to the higher first conveyor is replaced, the angle plate is pulled upwards in an inclined mode through the pushing oil cylinder, the rotating plate swings upwards, the rotating rod drives the transfer cylinder to rotate on the transverse plate, after the rotating rod rotates ninety degrees, the transfer cylinder is perpendicular to the second conveyor, the transfer cylinder puts down cut soil billet posts in the direction that the bottom surface faces the second conveyor, the phenomenon that the soil billet posts are easy to roll due to being cylindrical is effectively avoided, the soil billet posts are placed on the second conveyor in a side surface mode, time and labor are saved, and the conveying is safe and stable.

2. The lifting platform controls the steering arm to drive the taking and placing device to be close to a die after die forming, the air cylinder starts to work and drives the filling column to move upwards, the small inclined plane is parallel to the fixed block, so that the fixed block is always kept still in the moving process of the filling column, the large inclined plane is not parallel to the clamping block and has an angle difference, the clamping block can be pulled inwards under the matching of the guide rail and the sliding groove in the moving process of the filling column, a plurality of clamping blocks can be gathered, the lifting platform drives the taking and placing device to enter a die blank after die forming after gathering, the clamping block is descended by the filling column to be propped away from the die from the blank, the clamping block is propped outwards between every two adjacent fixed blocks by descending of the filling column, the blank is more matched with two or more than two special-shaped blanks during blank taking, the blank is not easy to deform and swell, the production quality is improved, and the material disc in the lifting platform is repeatedly knocked and knocked after the blank is discharged by the die, The vibrating adobe has the advantages of trowelling, compacting and compression molding before compression molding, being more convenient for compression molding of a roller press, further avoiding manual loading and unloading, reducing the manual workload, improving the daily productivity and enhancing the automation effect of a ceramic production device.

3. The original plaster mold is replaced by the microporous resin material mold, the service life is longer, tens of thousands of products can be produced at one time, the water and air permeability is good, the requirement of ceramic forming can be completely met, the strength is high, the wear resistance is good, the cost is reduced, the product forming quality is improved, and the important environmental protection significance is achieved, furthermore, a lock hole is arranged on the support ring and the bearing table, the support ring is connected to the upper end of the outer ring of the filter cylinder, the bearing table is connected to the upper end of the inner ring of the outer cylinder, the filter cylinder is fixed on the outer cylinder by screwing the bolt into the lock hole, the inner mold is fixed on the outer cylinder, the phenomenon that the bolt is directly screwed into the inner mold to be fixed on the outer cylinder is effectively avoided, the inner mold of the microporous resin material is easy to damage or crack, the inner mold is separated from the outer cylinder by the filter cylinder, the air inlet through hole is smoother, and the introduced gas can be directly dispersed to the blank in the inner mold, thereby the even effect of body drawing of patterns can be guaranteed to guaranteed good drawing of patterns effect, more help improving the mould drawing of patterns.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

Clearly, such objects and other objects of the present invention will become more apparent from the detailed description of the preferred embodiments hereinafter set forth in the various drawings and drawings.

These and other objects, features and advantages of the present invention will become more apparent from the following detailed description of one or more preferred embodiments of the invention, as illustrated in the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings, like parts are designated with like reference numerals, and the drawings are schematic and not necessarily drawn to scale.

In order to more clearly illustrate the embodiments or technical solutions in the prior art of the present invention, the drawings used in the description of the embodiments or prior art will be briefly described below, it is obvious that the drawings in the following description are only one or several embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to such drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of a ceramic rolling apparatus of a fully automatic production line according to the present invention;

FIG. 2 is a schematic view of a partial structure of a ceramic rolling apparatus of a fully automatic production line according to the present invention;

FIG. 3 is a schematic structural view of the soil transporting device of the present invention;

FIG. 4 is an enlarged partial view of A in FIG. 2 according to the present invention;

FIG. 5 is a partial enlarged structural view of B in FIG. 4 according to the present invention;

FIG. 6 is a schematic structural diagram of a mobile device according to the present invention;

FIG. 7 is a partial enlarged view of C in FIG. 6 according to the present invention;

FIG. 8 is a schematic bottom perspective view of the pick-and-place apparatus of the present invention;

FIG. 9 is a schematic structural view of the pick-and-place device of the present invention in a bottom view;

FIG. 10 is a schematic bottom plan view of a packed column of the present invention;

FIG. 11 is a schematic structural view of a mold of the present invention;

FIG. 12 is a schematic view of an exploded structure of the inventive mold;

fig. 13 is a schematic cross-sectional view of the mold of the present invention.

Description of the main reference numerals: a soil conveying device-1, a first conveyor-2, a adobe column-3, a second conveyor-4, a transfer device-5, a moving device-6, a roller press-7, a mould-8, a turntable-9, a third conveyor-10, a motor-11, a cutter-12, a cutting cylinder-13, a mounting rack-101, a feeding chain-102, a material bearing plate-103, a transfer cylinder-501, a transverse plate-502, a rotating rod-503, an angle plate-504, a supporting frame-505, a pushing cylinder-506, a rotating plate-507, a rotating shaft-508, a control box-601, a lifting platform-602, a rotating motor-603, a rotating transmission arm-604, a steering arm-605, a taking and placing device-606, a material pressing disc-607, a material pressing disc-3, a material conveying device-501, a material conveying device-501, a material conveying device, a material, The device comprises a feeding tray-608, a cylinder-6061, a clapboard-6062, a fixed block-6063, a clamping block-6064, a filling column-6065, a guide rail-6066, a breathable layer-6067, a small inclined plane-60651, a large inclined plane-60652, a chute-60653, an inner mold-801, a lock hole-802, a support ring-803, a filter cartridge-804, a bearing table-805, an outer cylinder-806, an air inlet through hole-807 and a clearance seam-808.

Detailed Description

The following detailed description of the embodiments of the present invention will be provided with reference to the drawings and examples, so that how to apply the technical means to solve the technical problems and achieve the technical effects can be fully understood and implemented. It should be noted that, as long as there is no conflict, the embodiments and the features of the embodiments of the present invention may be combined with each other, and the technical solutions formed are within the scope of the present invention.

In the following description, for purposes of explanation, numerous specific details are set forth in order to provide a thorough understanding of the embodiments of the invention. It will be apparent, however, to one skilled in the art that the present invention may be practiced without some of these specific details or with other methods described herein.

Referring to fig. 1 and 2, the present invention provides a ceramic rolling apparatus for a full-automatic production line, which comprises: the soil cutting machine comprises a soil feeding device 1, a first conveyor 2, a adobe column 3, a second conveyor 4, a transfer device 5, a moving device 6, a roller press 7, a mold 8, a rotary table 9, a third conveyor 10, a motor 11, a cutter 12 and a cutting cylinder 13, wherein the soil feeding device 1 for conveying the adobe column 3 is arranged on one side of the first conveyor 2, the first conveyor 2 and the second conveyor 4 are both driven by the motor 11, the transfer device 5 for transferring the adobe column 3 and adjusting the angle is arranged between the first conveyor 2 and the second conveyor 4, the cutter 12 for cutting the adobe column 3 is connected on the cutting cylinder 13, the moving device 6 is arranged on one side of the second conveyor 4, the roller press 7 is arranged on one side of the rotary table 9, the third conveyor 10 is arranged on the other side of the rotary table 9, the mold 8 is provided with one or more cutters which are rotatably arranged on the rotary table 9, the cutter 12 for cutting the adobe column 3 is connected on the cutting cylinder 13, motor 11 adopts servo motor, has the belt running length of the first conveyer 2 of accurate control and second conveyer 4, and the effect that the location is also more accurate, still is connected with photoelectric switch on the transfer device 5, and photoelectric switch is connected with motor 11 electricity. The adobe column 3 is conveyed to the first conveyor 2 by the soil conveying device 1, the first conveyor 2 is conveyed forwards by the motor 11, when the adobe column 3 is conveyed to one side and extends out of the first conveyor 2 for a section, the photoelectric switch senses that the preset distance is reached to drive the motor 11 to stop rotating, the transfer device 5 sucks the adobe column 3, the cutting cylinder 13 controls the cutter 12 to cut the adobe column 3, the transfer device 5 rotates to place the cut adobe column 3 on the second conveyor 4 for transportation, the moving device 6 sucks the adobe column 3 on the second conveyor 4 into the mold 8, then the rotary table 9 controls the mould 8 to rotate to the position below the roller press 7, the roller press 7 carries out compression molding on the adobe column 3 in the mould 8, the rotary table 9 rotates the mould 8 to the original position after molding, and the moving device 6 extracts the embryo body formed by compression molding of the mould 8 to the third conveyor 10 and carries out the process.

Referring to fig. 3, the soil feeding device 1 includes a mounting frame 101, two feeding chains 102 and a material supporting plate 103, the two feeding chains 102 are mounted on the mounting frame 101, the material supporting plate 103 for lifting the adobe columns 3 is disposed on the feeding chains 102, the mounting frame 101 is disposed on the first conveyor 2, the adobe columns 3 are placed on the material supporting plate 103, the feeding chains 102 operate to drive the material supporting plate 103 to carry the adobe columns 3 upwards, and the material supporting plate has the function of automatically lifting the adobe columns to a high place and then turning the adobe columns to fall onto the first conveyor 2, so that manual feeding is avoided, and the process of manually lifting the heavy adobe columns 3 to the higher first conveyor 2 is replaced.

Referring to fig. 4 and 5, the transfer device 5 includes a transfer cylinder 501, a horizontal plate 502, a rotating rod 503, an angle plate 504, a support frame 505, a pushing cylinder 506, a rotating plate 507, and a rotating shaft 508, one side of the rotating plate 507 is rotatably mounted on the horizontal plate 502 by connecting with the rotating rod 503, the other side is connected with the rotating shaft 508, the angle plate 504 is rotatable on the rotating plate 507 by the rotating shaft 508, the pushing cylinder 506 is rotatably connected on the support frame 505, the rotating rod 503 is provided with the transfer cylinder 501 for fixing the earth blank column 3, the rotating rod 503 is mounted on the horizontal plate 502, the rotating rod 503 is rotated to telescopically push the angle plate 504 by the pushing cylinder 506, the transfer cylinder 501 is provided with a suction cup for fixing the earth blank column 3, the transfer cylinder 501 is mounted above the first conveyor 2, the angle of the angle plate 504 is ninety degrees, and two sides of the ninety degrees are connected with the rotating shaft 508 and the other is connected with the pushing cylinder 506, the pushing oil cylinder 506 is obliquely arranged on the supporting frame 505, and when the pushing oil cylinder is conveyed to one side of the adobe column 3 and extends out of the first conveyor 2 for a section, the photoelectric switch senses that the distance reaches the set distance, the motor 11 is driven to stop rotating, the first conveyor 2 stops, the transfer cylinder 501 extends out, the sucker is driven to move forwards until the sucker touches and is adsorbed on the adobe column 3, the effect of fixing the adobe column 3 is achieved, the cutting is more convenient, then the cutting cylinder 13 controls the cutter 12 to move upwards to cut off the adobe column 3, a section of the adobe column 3 extending out of the first conveyor 2 is cut off, and is fixed to the transfer cylinder 501, and then the push cylinder 506 is retracted to obliquely pull up the angle plate 504, the rotating plate 507 is swung upward by the rotating shaft 508, and the rotating rod 503 rotates with the transfer cylinder 501, and after rotating ninety degrees, the transfer cylinder 501 is perpendicular to the second conveyor 4, and the transfer cylinder 501 drops the cut adobe column 3 with the bottom surface facing the second conveyor 4.

Referring to fig. 6 and 7, the moving device 6 includes a control box 601, a lifting table 602, a rotating motor 603, a rotating transmission arm 604, a steering arm 605, a pick-and-place device 606, a material pressing disk 607, and a material feeding disk 608, the steering arm 605 is mounted on the rotating transmission arm 604, the rotating motor 603 is connected with the rotating transmission arm 604, the rotating motor 603 is disposed on the lifting table 602, the steering arm 605 is provided with a pick-and-place device 606 for picking up the earth blank in the mold 8, the lifting table 602 is mounted on the control box 601 in a forward and backward moving manner, a transmission belt connected with the rotating motor 603 is disposed in the rotating transmission arm 604, the pick-and-place device 606, the material feeding disk 608, and the material pressing disk 607 are mounted on the steering arm 605 in a triangular manner and are clockwise respectively the pick-and place device 606, the material feeding disk 608, and the material pressing disk 607, the lifting table 602 moves forward and backward in the control box 601, the rotating transmission arm 604 and the rotating motor 603 move up and down in the lifting table 602, the steering arm 605 is rotatable on the rotary transmission arm 604, and can adjust the corresponding adobe columns 3 on the mold 8 or the second conveyor 4 in multiple directions when taking materials or taking embryos, so that the accuracy of embryo taking and feeding is achieved.

Referring to fig. 8-10, the pick-and-place device 606 includes a cylinder 6061, a partition 6062, fixed blocks 6063, clamp blocks 6064, a filling column 6065, a guide rail 6066 and a permeable layer 6067, the cylinder 6061 passes through the partition 6062 to be connected with the filling column 6065, a lifting distance is provided between the filling column 6065 and the partition 6062, the fixed blocks 6063 are fixed on the partition 6062, the clamp blocks 6064 are movably mounted on the partition 6062, the filling column 6065 is provided with a small inclined plane 60651 and a large inclined plane 60652, a small inclined plane 60651 is provided between every two adjacent large inclined planes 60652, a chute 60653 which is in clearance fit with the guide rail 6066 on the clamp block 6064 is provided on the large inclined plane 60652, a chute 60653 which is in clearance fit with the guide rail 6066 on the fixed block 6063 is provided on the small inclined plane 60651, the filling column 6065 is in a hexagonal frustum shape, the small inclined plane 60651 and the fixed block 6063 are parallel, the clamp blocks 6064 are lifted and gathered by the filling column 6065, a clamp block 6064 is provided between every two adjacent fixed blocks 6063, the clamp blocks 6064 and the fixed blocks 6063 are both connected with a ventilating layer 6067, the partition plates 6062 are arranged at the lower end of the steering arm 605, the clamp blocks 6064 are arranged on the partition plates 6062 in an annular form, the fixed blocks 6063 are arranged on the partition plates 6062 in an annular form, the clamp blocks 6064 and the fixed blocks 6063 are both connected with the ventilating layer 6067, the ventilating layer 6067 is made of microporous resin or ventilating sponge or other ventilating materials and has good ventilation property, a produced blank is not easy to deform and bulge when the blank is taken out or put in, the steering arm 605 is controlled by the lifting platform 60201 to drive the taking and placing device 606 to be close to the die 8 after compression molding, the air cylinder 6061 starts working and drives the filling column 6065 to move upwards, the fixed blocks 6063 are always kept motionless in the moving process of the filling column 6065 because the small inclined planes 60651 are parallel to the fixed blocks 6063, the large inclined planes 60652 are not parallel to the clamp blocks 6064 and have an angle difference, the clamp blocks 6064 can be pulled downwards under the matching of the guide rails 6066 and the sliding grooves 6063 in the moving process of the filling column 6065, a plurality of clamp blocks 6064 will gather together, the lifting platform 60201 takes the taking and placing device 606 to enter the mould blank body after mould pressing after gathering together, the filling column 6065 falls back the clamp blocks 6064 to prop open, and then the blank body is extracted from the mould 8, so that the blank body after mould pressing in the mould 8 is extracted, wherein the pressure plate 607 repeatedly knocks and vibrates the blank body after the blank body is discharged from the mould 8, and the blank body before mould pressing has the advantages of leveling and compaction, and is more convenient for mould pressing of the roller press 7.

Referring to fig. 11-13, the mold 8 includes an inner mold 801, locking holes 802, a support ring 803, a filter cartridge 804, a receiving platform 805, an outer cylinder 806, an air inlet through hole 807, and a gap 808, the inner mold 801 is adhered in the filter cartridge 804, the support ring 803 is installed at the upper end of the outer ring of the filter cartridge 804, the receiving platform 805 is installed at the upper end of the inner ring of the outer cylinder 806, the filter cartridge 804 is hung on the outer cylinder 806 through the support ring 803 and the receiving platform 805, the support ring 803 and the receiving platform 805 are both provided with a plurality of locking holes 802, the gap 808 for facilitating air inlet is provided between the filter cartridge 804 and the outer cylinder 806, which has the function of facilitating uniform air inlet to the filter cartridge 804, the outer cylinder 806 is rotatably installed on the turntable 9, the air inlet through holes 807 are provided with a plurality of holes and distributed on the bottom and the wall of the outer cylinder 806, which has the function of layered air inlet on the outer cylinder 806, the air inlet pressure of each layer in the cylinder can be adjusted, so that the embryo is not easy to deform and bulge, the high-quality blank taking is effectively achieved, the blank forming rate is high, a plurality of uniformly distributed filter holes for uniform air inlet are installed on the filter cylinder 804, the inner mold 801 is made of a microporous resin material layer or other breathable materials, the existing gypsum mold is replaced by the microporous resin material mold, the filter cylinder has good water and air permeability, can completely meet the requirements of ceramic forming, is high in strength and better in abrasion resistance, the service life of one resin mold can reach tens of thousands of times, the service life is longer, bolts are inserted into the plurality of lock holes 802, the support ring 803 is fixed on the bearing table 805 through the bolts, a sealing ring for preventing air leakage is filled between the support ring 803 and the bearing table 805, the filter cylinder 804 is made of metal or other hard materials, and the inner mold 801 is made of the microporous resin material layer, so that the metal material has the function of facilitating bonding and has a better breathable effect, the die can bear larger pressure, materials are not easy to damage, the forming efficiency of products can be accelerated, and the die is simpler and quicker to manufacture.

The support ring 803 is attached to the outer ring upper end of the filter cartridge 804 by making locking holes 802 in the support ring 803 and the receiving table 805, the receiving table 805 is attached to the inner ring upper end of the outer cylinder 806, the support ring 803 is supported by the receiving table 805 so that the filter cartridge 804 generates a clearance gap 808 in the outer cylinder 806, which has the function of allowing air to be uniformly supplied to the filter cartridge 804 through the air supply through holes 807, and then the air is blown out from the inner mold 802 through the uniformly distributed filter holes, the clearance gap 808 uniformly disperses the air arranged inside the mold body, and the inner mold 802 made of a microporous resin material has good air permeability, thereby ensuring good demoulding effect, being more beneficial to improving the demoulding of the mould, separating the inner mould 801 from the outer cylinder 806 through the filter cylinder 804, the air inlet through holes 807 can smoothly inlet air, and the introduced air can be directly diffused to the blank in the internal mold 801, so that the uniform demolding of the blank can be ensured.

The device is single-head rolling or multi-head rolling, when an operator uses the device, firstly, the adobe columns 3 are placed on the material bearing plate 103 on the soil conveying device 1, the feeding chain 102 operates to drive the material bearing plate 103 to carry the adobe columns 3 upwards, and the device has the functions of automatically lifting the adobe columns to a high place and then turning the adobe columns to fall on the first conveyor 2.

The first conveyor 2 conveys the adobe column 3 forwards through the motor 11, when the adobe column 3 is conveyed to one side and extends out of the first conveyor 2 for a section, the photoelectric switch senses that the preset distance is reached to drive the motor 11 to stop rotating, the first conveyor 2 stops, the transfer cylinder 501 extends out to drive the sucker to move forwards until the sucker touches and is adsorbed on the adobe column 3, the adobe column 3 is fixed and is more convenient to cut, then the cutting cylinder 13 controls the cutter 12 to move upwards to cut off the adobe column 3, the section of the adobe column 3 extending out of the first conveyor 2 is cut off and is fixed on the transfer cylinder 501, then the push cylinder 506 retracts to pull the angle plate 504 upwards, the rotating plate 507 swings upwards under the action of the rotating shaft 508, the rotating rod 503 rotates along with the transfer cylinder 501, after the ninety degrees, the transfer cylinder 501 is vertical to the second conveyor 4, the transfer cylinder 501 puts down the cut adobe column 3 with the bottom surface facing to the direction of the second conveyor 4, effectively avoiding the phenomenon that the adobe column 3 is easy to roll because of being cylindrical and placed on the second conveyor 4 in a side mode.

Then the second conveyor 4 stably conveys the adobe column 3 to be close to the moving device 6, similarly, when the photoelectric switch on the second conveyor 4 senses that the preset distance is reached, the motor 11 is driven to stop rotating, the lifting platform 602 moves back and forth in the control box 601, the rotary transmission arm 604 and the rotary motor 603 move up and down in the lifting platform 602, the steering arm 605 can rotate on the rotary transmission arm 604, and the feeding tray inner mold 802608 can suck the adobe column 3 on the second conveyor 4 into the mold inner mold 8028.

Then the rotary table 9 rotates the mould 8 to the roller press 7 for compression molding, during the compression molding, the batch pan 608 places a new non-molded adobe into another mould 8, the mould 8 rotates back to the original position after molding, the other mould reaches the roller press 7, the uninterrupted compression molding effect is realized, the working efficiency is improved, then the control box 601 controls the lifting platform 60202 to adjust the position back and forth, the lifting platform 60202 controls the steering arm 605 to bring the taking and placing device 606 to be close to the mould 8 after compression molding, the air cylinder 6061 starts working, and the filling column 6065 moves upwards, because the small inclined plane 60651 is parallel to the fixed block 6063, the fixed block 803 is always kept still in the moving process of the filling column 6065, because the large inclined plane 8052 is not parallel to the clamping block 6064, the angle difference exists, the clamping block 6064 is pulled inwards under the matching of the guide rail 6066 and the chute 60653 in the moving process of the filling column 6065, and a plurality of clamping blocks 6064 are gathered together, after gathering, the lifting platform 602 drives the pick-and-place device 606 to enter the molded mold blank, and the filling column 6065 descends the clamping block 6064 to be opened, so that the blank is extracted from the mold 8, and the molded blank in the mold 8 is extracted to the third conveyor inner mold 80210 and sent out.

Wherein the mould 8 adopts a microporous resin material layer, the microporous resin material mould replaces the existing plaster mould, has the functions of good water and air permeability, can completely meet the requirements of ceramic forming, has high strength and better abrasion resistance, the service life of one resin mould can reach tens of thousands of times, the service life is longer, a lock hole 802 is punched on a support ring 803 and a bearing platform 805, the support ring 803 is connected to the upper end of the outer ring of the filter cartridge 804, the bearing platform 805 is connected to the upper end of the inner ring of the outer cylinder 806, the support ring 803 is supported by the bearing platform 805, so that the filter cartridge 804 generates a gap 808 in the outer cylinder 806, the gap 808 has the function of facilitating uniform air intake to the filter cartridge 804, then the air is flushed out from the inner mould 802 through uniformly distributed filter holes, the gap 808 uniformly disperses the air arranged in the mould body, and the inner mould 802 made of the microporous resin material has good air permeability, thereby guaranteed good drawing of patterns effect, more helped improving the mould drawing of patterns to separate centre form 1 and urceolus 806 through straining a section of thick bamboo 804, make air inlet through-hole 807 admit air more smoothly, the leading-in gas can directly disperse to the idiosome in centre form 1, thereby can guarantee the even effect of base member drawing of patterns.

It is to be understood that the disclosed embodiments of the invention are not limited to the particular process steps or materials disclosed herein, but rather, are extended to equivalents thereof as would be understood by those of ordinary skill in the relevant art. It is also to be understood that the terminology used herein is for the purpose of describing particular embodiments only, and is not intended to be limiting.

Reference in the specification to "an embodiment" means that a particular feature, or characteristic described in connection with the embodiment is included in at least one embodiment of the invention. Thus, the appearances of the phrase or "an embodiment" in various places throughout this specification are not necessarily all referring to the same embodiment.

Furthermore, the described features or characteristics may be combined in any other suitable manner in one or more embodiments. In the above description, certain specific details are provided, such as thicknesses, amounts, etc., to provide a thorough understanding of embodiments of the invention. One skilled in the relevant art will recognize, however, that the invention may be practiced without one or more of the specific details, or with other methods, components, materials, and so forth.

Claims (10)

1. The utility model provides a ceramic rolling press equipment of full-automatic production line which characterized in that, its structure includes: the soil-conveying device comprises a soil-conveying device (1), a first conveyor (2), a adobe column (3), a second conveyor (4), a transfer device (5), a moving device (6), a roller press (7), a mold (8), a rotary table (9), a third conveyor (10), a motor (11), a cutter (12) and a cutting cylinder (13), wherein the soil-conveying device (1) used for conveying the adobe column (3) is arranged on one side of the first conveyor (2), the first conveyor (2) and the second conveyor (4) are both driven by the motor (11), the transfer device (5) used for transferring the adobe column (3) and adjusting the angle is arranged between the first conveyor (2) and the second conveyor (4), the cutter (12) used for cutting off the adobe column (3) is connected onto the cutting cylinder (13), the moving device (6) is arranged on one side of the second conveyor (4), the roller press (7) is arranged on one side of the rotary table (9), A third conveyor (10) is installed on the other side, a die (8) is rotatably installed on the rotary table (9), a cutting knife (12) used for cutting off the adobe column (3) is connected to the cutting cylinder (13), the motor (11) adopts a servo motor, a photoelectric switch is further connected to the transfer device (5), and the photoelectric switch is electrically connected with the motor (11).

2. The ceramic rolling equipment of the full-automatic production line according to claim 1, characterized in that: the soil conveying device (1) comprises a mounting frame (101), two conveying chains (102) and material bearing plates (103), wherein the two conveying chains (102) are arranged on the mounting frame (101), the material bearing plates (103) used for lifting and conveying the soil billet columns (3) are arranged on the conveying chains (102), and the mounting frame (101) is arranged on the first conveyor (2).

3. The ceramic rolling equipment of the full-automatic production line according to claim 1, characterized in that: the transfer device (5) comprises a transfer cylinder (501), a transverse plate (502), a rotating rod (503), an angle plate (504), a support frame (505), a pushing cylinder (506), a rotating plate (507) and a rotating shaft (508), wherein one side of the rotating plate (507) is rotatably arranged on the transverse plate (502) through being connected with the rotating rod (503), the other side of the rotating plate is connected with the rotating shaft (508), the angle plate (504) is rotatably arranged on the rotating plate (507) through the rotating shaft (508), the pushing cylinder (506) is rotatably connected on the support frame (505), the rotating rod (503) is provided with the transfer cylinder (501) for fixing the soil billet column (3), the rotating rod (503) is arranged on the transverse plate (502), and the rotating rod (503) rotates to telescopically push the angle plate (504) through the pushing cylinder (506).

4. The ceramic rolling equipment of the full-automatic production line according to claim 3, characterized in that: a sucker for fixing the adobe column (3) is arranged on the transferring cylinder (501), and the transferring cylinder (501) is arranged above the first conveyor (2).

5. The ceramic rolling equipment of the full-automatic production line according to claim 3, characterized in that: the angle of the angle plate (504) is ninety degrees, one of two sides of the ninety degrees is connected with the rotating shaft (508), the other side of the ninety degrees is connected with the pushing oil cylinder (506), and the pushing oil cylinder (506) is obliquely arranged on the supporting frame (505).

6. The ceramic rolling equipment of the full-automatic production line according to claim 1, characterized in that: the moving device (6) comprises a control box (601), a lifting platform (602), a rotating motor (603), a rotating transmission arm (604), a steering arm (605), a taking and placing device (606), a material pressing disc (607) and a material throwing disc (608), wherein the steering arm (605) is installed on the rotating transmission arm (604), the rotating motor (603) is connected with the rotating transmission arm (604), the rotating motor (603) is arranged on the lifting platform (602), the steering arm (605) is provided with the taking and placing device (606) for extracting the soil billets in the molds (8), the lifting platform (602) can be installed on the control box (601) in a back-and-forth moving mode, a transmission belt connected with the rotating motor (603) is arranged in the rotating transmission arm (604), the taking and placing device (606), the material throwing disc (608) and the material pressing disc (607) are installed on the steering arm (605) in a triangular mode, and the taking and placing device (606) and the material pressing disc (607) are clockwise installed, A feeding tray (608) and a material pressing tray (607).

7. The ceramic rolling equipment of the full-automatic production line according to claim 6, characterized in that: the taking and placing device (606) comprises a cylinder (6061), a partition plate (6062), a fixed block (6063), a clamping block (6064), a filling column (6065), a guide rail (6066) and a breathable layer (6067), wherein the cylinder (6061) penetrates through the partition plate (6062) to be connected with the filling column (6065), a liftable interval is arranged between the filling column (6065) and the partition plate (6062), the fixed block (6063) is fixed on the partition plate (6062), the clamping block (6064) is movably arranged on the partition plate (6062), a small inclined plane (60651) and a large inclined plane (60652) are arranged on the filling column (6065), a small inclined plane (60651) is arranged between every two adjacent large inclined planes (60652), a sliding groove (60653) in clearance fit with the guide rail (6066) on the clamping block (6064) is arranged on the large inclined plane (60652), a sliding groove (60653) in clearance fit with the guide rail (6066) on the fixed block (6063) is arranged on the small inclined plane (60651), and the filling column (6065) is in a hexagonal frustum shape, small inclined plane (60651) and fixed block (6063) are parallel, clamp splice (6064) go up and down through packed column (6065) and take place to gather together, be provided with clamp splice (6064) between every two adjacent fixed block (6063), all be connected with ventilative layer (6067) on clamp splice (6064) and fixed block (6063), install at steering arm (605) lower extreme baffle (6062).

8. The ceramic rolling equipment of the full-automatic production line according to claim 7, characterized in that: the clamping block (6064) is arranged on the partition plate (6062) in an annular form, and the fixing block (6063) is arranged on the partition plate (6062) in an annular form.

9. The ceramic rolling equipment of the full-automatic production line according to claim 1, characterized in that: the mold (8) comprises an inner mold (801), locking holes (802), a supporting ring (803), a filter cylinder (804), a receiving table (805), an outer cylinder (806), an air inlet through hole (807) and a clearance gap (808), wherein the inner mold (801) is bonded in the filter cylinder (804), the supporting ring (803) is installed at the upper end of the outer ring of the filter cylinder (804), the receiving table (805) is installed at the upper end of the inner ring of the outer cylinder (806), the filter cylinder (804) is hung on the outer cylinder (806) through the supporting ring (803) and the receiving table (805), the supporting ring (803) and the receiving table (805) are both provided with a plurality of locking holes (802), the clearance gap (808) convenient for air inlet is arranged between the filter cylinder (804) and the outer cylinder (806), the air inlet through holes (807) are provided with a plurality of holes and distributed on the bottom and the wall of the outer cylinder (806), the filter cylinder (804) is provided with a plurality of uniformly distributed filter holes for uniformly inlet air, the inner mold (801) adopts a microporous resin material layer, bolts are inserted into the plurality of lock holes (802), the support ring (803) is fixed on the bearing platform (805) through the bolts, a sealing ring for preventing air leakage is filled between the support ring (803) and the bearing platform (805), and the filter cartridge (804) is made of metal or hard material.

10. The ceramic rolling equipment of the full-automatic production line according to claim 9, characterized in that: the outer cylinder (806) is rotatably mounted on the turntable (9).

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