CN214983459U - Viscous material die-stamping forming block manufacturing equipment - Google Patents

Abstract

The utility model discloses a viscous material die-stamping forming block manufacturing device, which comprises a material extruding device, a conveying device, a cutter device, a die-stamping device and a balance device; the extruding device is provided with a shape discharging nozzle; the conveying device comprises a first belt conveying section and a second belt conveying section, wherein the input end of the first belt conveying section is arranged below the discharge nozzle in a shape corresponding to the input end of the first belt conveying section, and the input end of the second belt conveying section is in connection conveying with the output end of the first belt conveying section; the cutter device comprises a cutter which is correspondingly arranged above the first belt conveying section; the stamping device comprises a mould, a lifting driving mechanism and a demoulding mechanism, wherein the mould is correspondingly arranged above the second belt conveying section; the tray placing device comprises a tray shifting mechanism and a fermentation tray placed on the tray shifting mechanism, the fermentation tray is arranged below the output end of the second belt conveying section correspondingly, the equipment and the manufacturing process thereof can achieve the purposes of improving the weight stability of the traditional Chinese medicine forming block, saving labor and reducing enterprise cost.

Description

Viscous material die-stamping forming block manufacturing equipment

Technical Field

The utility model relates to a massive preparation equipment of viscidity material shaping and manufacturing process's technical field.

Background

In traditional Chinese medicine products, a lot of traditional Chinese medicines are prepared into rectangular blocks by material distribution after materials are mixed to be in a viscous state, and then fermentation and other processes are carried out, the traditional Chinese medicine blocks not only require uniform density, but also have high requirements on the weight consistency of each block, so that the control on the dosage and the drug effect can be better achieved, however, the incoming materials of the viscous traditional Chinese medicines are generally lumpy materials with uneven density, irregular shape and various shapes during material distribution, and the incoming materials are characterized by the difficulty of forming traditional Chinese medicine forming blocks with uniform density and uniform size.

The existing manufacturing process steps of the viscous traditional Chinese medicine forming block are that feeding, pressing materials into a die, scraping off excess materials, demoulding and pressing out the forming block, and by adopting the traditional Chinese medicine forming process, the appearance of the traditional Chinese medicine forming block has more burrs, cracks are easy to occur, the weight of each forming block is unstable, the fermentation of the subsequent working procedures of the traditional Chinese medicine forming block is influenced, and the medicine property or the qualification rate of medicines is influenced; in addition, the traditional Chinese medicine forming process is easy to influence the preparation of the traditional Chinese medicine forming block by factors such as manual manipulation, manual state and the like, which also influences the yield of the traditional Chinese medicine. In addition, the current traditional Chinese medicine molding process adopts manual or semi-automatic process for production, has low production efficiency, low molding rate and large manual quantity, and the control of labor cost is especially important under the background that the labor cost is continuously increased.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a viscidity material stamp becomes piece preparation equipment that can reach the automated production preparation.

Another object of the utility model is to provide a manufacturing process of viscidity material stamp shaping piece, this manufacturing process be new shaping process, can improve the production efficiency of viscidity material shaping piece and the stability of weight, and can practice thrift the manual work, reduce the cost in business.

In order to achieve the above purpose, the technical scheme of the utility model is that: a viscous material die-stamping forming block manufacturing device comprises a material extruding device, a conveying device, a cutter device, a die-stamping device and a swinging disc device; the extruding device is provided with a shape discharging nozzle; the conveying device comprises a first belt conveying section and a second belt conveying section, wherein the input end of the first belt conveying section is correspondingly arranged below the discharging nozzle, and the input end of the second belt conveying section is in connection conveying with the output end of the first belt conveying section; the cutter device comprises a cutter which is correspondingly arranged above the first belt conveying section; the stamping device comprises a mould corresponding to the upper part of the second belt conveying section, a lifting driving mechanism for driving the mould to lift and a demoulding mechanism for forming and demoulding the mould; the tray swinging device comprises a tray shifting mechanism and a fermentation tray placed on the tray shifting mechanism, and the fermentation tray is arranged below the output end of the second belt conveying section correspondingly.

The mould includes outer module and interior module, be formed with the die cavity in the outer module, the lower surface that the die cavity leads to outer module is relative with second belt conveyor section, the embedding that interior module can move about from top to bottom is established on die cavity upper portion, and the lower surface of interior module constitutes the shaping space of material die mark shaping piece with the die cavity inner wall of its below, thereby demoulding mechanism reaches the drawing of patterns for the relative motion that the lift drive mechanism connects the lift activity of drive outer module lift activity and interior module respectively and reach between outer module and the interior module.

And a cavity depth adjusting structure for adjusting the position of the inner module in the outer module is arranged between the inner module and the outer module.

The demoulding mechanism further comprises a blowing mechanism, the output end of the blowing mechanism is connected to the inner module, and an air channel structure capable of leading gas output by the output end of the blowing mechanism to the forming space to achieve demoulding is arranged on the inner module.

And the second belt conveying section is provided with an action sensor on one side of the input direction of the mould towards the conveying direction for controlling the action of the printing device.

The material extruding device comprises a material box with a feeding opening and an extruding opening and a feeding roller mechanism arranged in the material box and used for stirring and extruding materials from the extruding opening, and the shape discharging nozzle is detachably and replaceably arranged on the extruding opening.

The second belt conveying section is provided with a telescopic moving mechanism which can enable the output end of the second belt conveying section to move back and forth along the conveying front and back direction, and the telescopic moving mechanism is provided with a material in-place sensor corresponding to the output end of the second belt conveying section; the grid plate shifting mechanism is used for driving the fermentation grid plate to move in the direction perpendicular to the conveying direction of the second belt conveying section, and an initial position sensor used for sensing the initial position of the fermentation grid plate to be placed is arranged on the grid plate shifting mechanism.

A material in-place sensor is arranged on the second belt conveying section corresponding to the output end of the second belt conveying section; the grating disc shifting mechanism is used for driving the fermentation grating disc to move along the front-back direction conveyed by the second belt conveying section and the direction vertical to the front-back direction, and an initial position sensor used for sensing the initial position of the fermentation grating disc is arranged on the grating disc shifting mechanism.

The manufacturing process of the viscous material die-stamping forming block comprises the following manufacturing process steps:

step one, a discharging nozzle with a required shape is arranged on an extruding device, a fermentation grating disc is placed on a grating disc shifting mechanism and corresponds to an initial position sensor, and the output end of a second belt conveying section corresponds to the first position of the first row of a blanking swing disc of the fermentation grating disc;

adding a viscous material into an extruding device, stirring the viscous material by the extruding device, extruding material shape strips from a shape discharging nozzle on a first belt conveying section, and arranging a cutter above the material shape strips correspondingly;

step two, when the material shape strips are conveyed forwards on the first belt conveying section, the cutter device works according to a preset action frequency, so that the cutter descends to cut the material shape strips, and the ascending reset is completed after the cutting, so that the material sections are cut from the material shape strips;

step three, the cut material sections are sequentially output from the first belt conveying section to the second belt conveying section, and as the second belt conveying section is a differential separation section, the conveying speed of the second belt conveying section is higher than that of the first belt conveying section, the material sections entering the second belt conveying section form a spacing distance to be separated and conveyed forwards continuously, and the mold corresponds to the position above the material sections;

in the conveying process of the second belt conveying section, the stamping device works according to a preset dynamic frequency, and the lifting driving mechanism drives the die to descend to buckle the corresponding material section and stamp the material section into a material block consistent with the cavity;

step five, the lifting driving mechanism drives the mold to ascend, meanwhile, the demolding mechanism works to enable the material block to be separated from the cavity of the mold, the material block is conveyed to the output end of the second belt conveying section after being separated from the cavity, and the stamping device is reset to wait for the next stamping action;

sixthly, the material in-place sensor keeps sensing the material block at the output end of the second belt conveying section in real time;

seventhly, placing the material blocks output by the output end of the second belt conveying section to a first position of a first row of a blanking placing plate of the fermentation grating plate, and then entering a row of placing actions; the course of the line putting action is as follows: when the material in-place sensor senses that the next material block is in place, the telescopic moving mechanism drives the output end of the second belt conveying section to move and retreat to the position of a material block discharging swinging plate, the speed of the telescopic moving mechanism driving the second belt conveying section to move and retreat is consistent with the conveying speed of the second belt conveying section, the material block output by the output end of the second belt conveying section is placed to the second position of the discharging swinging plate of the fermentation grating plate after the position of the material block discharging swinging plate is retreated, and the steps are sequentially circulated to one row for placing and entering a discharging and line changing action; the process of the blanking line-changing action is as follows: after one line of placement is finished, the grating disc shifting mechanism drives the fermentation grating disc to move to a position corresponding to a second line of blanking grating discs in a direction vertical to the conveying direction of the second belt conveying section, meanwhile, the telescopic moving mechanism drives the output end of the second belt conveying section to move and extend to a first position of the second line, and material blocks output by the output end of the second belt conveying section are blanked and placed to the first position of the second line and then enter the one line of placement action; and the steps are sequentially circulated to the discharging and placing plate of the fermentation grating plate to finish.

Or, in the seventh step, the material blocks output by the output end of the second belt conveying section are placed to the first position of the first row of the blanking placing plate of the fermentation grating plate, and then the placing action is carried out in one row; the course of the line putting action is as follows: when the material in-place sensor senses that the next material block is in place, the grating disc shifting mechanism drives the fermentation grating disc to move the position of a material block discharging swinging disc along the direction of the conveying direction of the second belt conveying section, and after the position of the material block discharging swinging disc is moved, the material block output by the output end of the second belt conveying section is placed at the second position of the fermentation grating disc discharging swinging disc, and the steps are sequentially circulated until one row of material block is placed, and then the material block enters the material discharging line changing action; the process of the blanking line-changing action is as follows: after one line of placement is finished, the grating disc shifting mechanism drives the fermentation grating disc to move to a position corresponding to a second line of blanking grating discs in a direction vertical to the conveying direction of the second belt conveying section, and drives the fermentation grating disc to move to a first position of the second line in the direction opposite to the conveying direction of the second belt conveying section, and material blocks output by the output end of the second belt conveying section are blanked and placed to the first position of the second line, and then enter the one line of placement action; and the steps are sequentially circulated to the discharging and placing plate of the fermentation grating plate to finish.

By adopting the technical scheme, the beneficial effects of the utility model are that: come even extrusion viscidity material and can adopt the shape ejection of compact mouth to extrude the material shape strip of specific shape as required through crowded material device, the material that will extrude through conveyor is carried forward, the material section of the quality of every shaping piece that the segmentation formed the material shape strip cutting segmentation in the transportation process through cutting the device, carry to the second belt conveying section behind the cutting segmentation and carry out the moulding shaping material piece, carry to the balance device behind the shaping material piece and carry out the even interval unloading balance of polylith multirow, can automize and go on, the artificial operation that can significantly reduce. The viscous traditional Chinese medicine forming blocks which are processed by adopting the equipment and the manufacturing process have the advantages that 1, the surfaces of the forming blocks are flat, have no cracks or burrs, the weight of each forming block is stable, the fermentation of the later process of the traditional Chinese medicine is ensured, the drug effect of the traditional Chinese medicine is not influenced, and the product percent of pass of the traditional Chinese medicine forming blocks is ensured; 2. from feeding to fermentation, the formed blocks are not affected by manual intervention, manual manipulation, worker state and the like, and the yield of the traditional Chinese medicine is proved; 3. the production efficiency of the traditional Chinese medicine forming block is improved, the weight stability of the traditional Chinese medicine forming block is improved, the labor is saved, and the enterprise cost is reduced.

Drawings

FIG. 1 is a block diagram of a process of a device for manufacturing a viscous material molding block;

fig. 2 is a schematic view of the extrusion process of the extrusion device according to the present invention;

fig. 3 is a schematic structural view of a cutting process of the cutter device according to the present invention;

fig. 4 is a schematic diagram of a stamping device process according to the present invention;

fig. 5 is a schematic structural view of the blanking process of the balance device of the present invention.

In the figure:

a material extruding device 1; a work bin 11; a feed roller mechanism 12; a shape discharging nozzle 13;

a conveying device 2; a first belt conveying section 21; a second belt conveying section 22; a material-in-place sensor 23;

a cutter device 3; a cutter 31; a stamping device 4; a mold 41;

an outer module 411; an inner module 412; a mold cavity 413; a motion sensor 42;

a wobble plate device 5; a fermentation tray 51;

a material shape strip 10; a piece of material 20; a material section 30.

Detailed Description

In order to further explain the technical solution of the present invention, the present invention is explained in detail by the following embodiments.

Example one

The process flow of the viscous material die-stamping forming block manufacturing equipment disclosed by the embodiment can be divided into the processes of feeding, extruding, conveying, cutting, conveying, die stamping, demolding, conveying and swinging in sequence as shown in fig. 1, and the equipment comprises a material extruding device 1, a conveying device 2, a cutter device 3, a die stamping device 4 and a swinging disk device 5; the connection relationship of the structural positions of the parts is described in detail below with reference to the accompanying drawings.

The material extruding device 1, as shown in fig. 2, includes a material box 11 having a feeding port and an extruding port, a feeding roller mechanism 12 disposed in the material box 11 for stirring and extruding the material from the extruding port, and a shape discharging nozzle 13 disposed on the extruding port, wherein the shape discharging nozzle 13 is detachably and replaceably disposed on the extruding port, so that the corresponding shape discharging nozzle 13 can be selected according to the shape of the block to be produced, and extrusion with different shapes and thicknesses can be achieved.

The conveying device 2, as shown in fig. 2, 3, 4 and 5, includes a first belt conveying section 21 and a second belt conveying section 22, an input end of the first belt conveying section 21 corresponds to a lower portion of the shape discharging nozzle 13 to correspondingly receive the material shape strip 10 extruded from the shape discharging nozzle 13, the second belt conveying section 22 is a differential speed separation section, that is, the second belt conveying section 22 has a different rotation speed from the first belt conveying section 21, and an input end thereof is connected with an output end of the first belt conveying section 21 for conveying; the second belt conveying section 22 is provided with a telescopic moving mechanism (not visible in the figure, the structure of the mechanism can be realized by the existing mechanical telescopic technology, the structure can be realized in various ways, the structure is not specifically disclosed and limited in the embodiment, and the clear understanding of the technical personnel in the field is influenced) which can enable the output end of the second belt conveying section to reciprocate along the front-back direction of the conveying, the telescopic moving mechanism is provided with a material in-place sensor 23 corresponding to the output end of the second belt conveying section 22, and the sensor is used for sensing whether the material is in place at the output end of the second belt conveying section 22, so that the second belt conveying section is arranged on the telescopic moving mechanism, and the material can be sensed accurately in place during telescopic operation.

The cutter device 3 comprises a cutter 31 which is correspondingly arranged above the first belt conveying section, and the cutter device 3 can drive the cutter 31 to descend, cut and ascend to reset.

The stamping device 4 comprises a mold 41 correspondingly above the second belt conveying section 22, a lifting driving mechanism (not shown in the figure) for driving the mold 41 to lift and lower, and a demolding mechanism (not shown in the figure) for mold forming and demolding; the structure of the mold 41 disclosed in this embodiment includes an outer mold block 411 and an inner mold block 412, a cavity 413 is formed in the outer mold block 411, the cavity 413 is opened to the lower surface of the outer mold block 411 and is opposite to the second belt conveying section 22, so as to buckle the material block 20 formed by the material section 30 when the mold 41 descends, in this embodiment, the inner mold block 412 is movably embedded in the upper part of the cavity 413 up and down, and a cavity depth adjusting structure (not shown in the figure) for adjusting the position of the inner mold block 412 in the outer mold block 411 is further provided between the inner mold block 412 and the outer mold block 411, the initial position of the inner mold block 412 in the outer mold block 411 can be changed by adjusting the cavity depth adjusting structure according to the quality of the formed material block, so as to change the thickness of the material block 20 formed by molding, the entire mold 41 can be replaced as needed, and thus, the lower surface of the inner mold block 412 and the inner wall 413 below the inner mold block form a molding space of the material mold block.

In the demolding mechanism disclosed in this embodiment, the lifting driving mechanism is respectively connected with and drives the outer module 411 to move up and down and the inner module 412 to move up and down, so that the relative movement between the outer module 411 and the inner module 412 is achieved to achieve demolding, that is, when the mold descends, the relative position of the inner module 412 and the outer module 411 is an initial position, a molding space in the mold is a cavity of a molding block, after impression molding, when the lifting driving mechanism starts to demold and drive the mold to ascend, an action that the outer module 411 ascends before the inner module 412 is also achieved, and under the action, the inner module 412 pushes out a molded material block out of the cavity, so that demolding action is achieved.

In this embodiment, the demolding mechanism further includes a blowing mechanism (not shown in the figure), an output end of the blowing mechanism is connected to the inner module 412, and the inner module 412 is provided with an air passage structure capable of leading the gas output by the output end of the blowing mechanism to the forming space to achieve demolding, so as to further assist in rapid demolding.

In addition, in order to better control the action of the stamping device, the second belt conveying section 22 is provided with a motion sensor 42 on one side of the input direction of the mold 41 towards the conveying direction for controlling the action of the stamping device, so that the stamping device 4 can act only when the motion sensor 42 senses that the material section 30 is in place, and the control of the action time and the conveying speed is facilitated, so that the stamping process can be better corresponding.

The tray swinging device 5, as shown in fig. 5, includes a tray shifting mechanism (not shown in the figure) and a fermentation tray 51 placed on the tray shifting mechanism, the fermentation tray 51 is correspondingly arranged below the output end of the second belt conveying section 22, and the output end of the second belt conveying section 22 keeps its output material corresponding to the fermentation tray 51 during the telescopic movement; the tray shifting mechanism is used for driving the fermentation trays 51 to move in the direction perpendicular to the conveying direction of the second belt conveying section 22, and an initial position sensor (not shown in the figure) for sensing the initial position of the fermentation trays 51 is arranged on the tray shifting mechanism.

The manufacturing process of the viscous material die-stamping forming block comprises the following manufacturing process steps:

step one, a discharging nozzle 13 with a required shape is arranged on an extruding device 1, a fermentation grating disc 51 is placed on a grating disc displacement mechanism and corresponds to an initial position sensor, and the output end of a second belt conveying section 22 corresponds to the first position of the first row of a blanking swing disc of the fermentation grating disc 51;

adding a viscous material into an extruding device 1, stirring the viscous material through the extruding device 1, extruding a material shape strip 10 from a shape discharging nozzle 13 on a first belt conveying section 11, and correspondingly arranging a cutter 41 above the material shape strip 10;

step two, when the material shape strip 10 is conveyed forwards on the first belt conveying section 22, the cutter device 3 works according to a preset action frequency, so that the cutter 31 descends to cut the material shape strip 10, and the ascending reset is completed after the cutting, so that the material section 30 is cut from the material shape strip 10;

step three, the cut-out material sections 30 are sequentially output from the first belt conveying section 21 to the second belt conveying section 22, and as the second belt conveying section 22 is a differential separation section and the conveying speed of the second belt conveying section is higher than that of the first belt conveying section 21, a separation distance is formed between the material sections entering the second belt conveying section 22, the material sections are separated and conveyed continuously forwards, and the mold 41 corresponds to the upper part of the material sections;

step four, in the process of conveying 22 by the second belt conveying section, the stamping device 4 works according to a preset dynamic frequency, and the lifting driving mechanism drives the mould 41 to descend to buckle the corresponding material section 30 and stamp the material section 30 into the material block 20 consistent with the cavity;

fifthly, the lifting driving mechanism drives the mold 41 to ascend, meanwhile, the demolding mechanism works to remove the material block 20 from the cavity 413 of the mold 41, the material block 41 is conveyed to the output end of the second belt conveying section 22 after being separated from the cavity 413, and the stamping device 4 is reset to wait for the next stamping action;

sixthly, the material in-place sensor 23 keeps sensing the material blocks 20 at the output end of the second belt conveying section 22 in real time;

seventhly, the material blocks 20 output by the output end of the second belt conveying section 22 are placed to the first position of the first row of the blanking placing plate of the fermentation grating plate 51, and then a row of placing actions are carried out; the course of the line putting action is as follows: when the material in-place sensor 23 senses that the next material block 20 is in place, the telescopic moving mechanism drives the output end of the second belt conveying section 22 to move and retreat to the position of the material block 20 blanking swinging plate, the speed of the telescopic moving mechanism driving the second belt conveying section 22 to move and retreat is consistent with the conveying speed of the second belt conveying section 22, the material blocks output by the output end of the second belt conveying section 22 are placed to the second position of the material blanking swinging plate of the fermentation grating disc 51 after the position of the material block 20 blanking swinging plate is retreated, and the process is sequentially circulated until one row of material blocks are placed, and the material blanking line changing action is performed; the process of the blanking line-changing action is as follows: after one line of placement is finished, the grating disc shifting mechanism drives the fermentation grating disc 51 to move to a position corresponding to a second line of blanking grating disc in a direction vertical to the conveying direction of the second belt conveying section 22, meanwhile, the telescopic moving mechanism drives the output end of the second belt conveying section to move and extend to a first position of the second line, material blocks output by the output end of the second belt conveying section 22 are blanked and placed to the first position of the second line, and then the one line of placement action is carried out; and then the process is sequentially circulated to the fermentation grating disc 51 for blanking and disc swinging.

Example two

The difference between the embodiment and the first embodiment is that the second belt conveying section is not provided with a telescopic moving mechanism, that is, the output end of the second belt conveying section cannot move telescopically, but the second belt conveying section is also provided with a material in-place sensor corresponding to the output end of the second belt conveying section; the grating disc shifting mechanism can be used for driving the fermentation grating disc to move along the front-back direction of the second belt conveying section and the direction perpendicular to the front-back direction of the second belt conveying section, the moving realization structure can be realized through the existing mechanical telescopic technology, the structure capable of being realized is various, the structure in the embodiment is not specifically disclosed and limited, and the clear understanding of the technical personnel in the field is influenced, and the same grating disc shifting mechanism is provided with an initial position sensor for sensing the initial position of the fermentation grating disc to be placed.

The difference between the manufacturing process steps of the device of the embodiment and the manufacturing process steps of the device of the embodiment one is step four, in the embodiment, in the step seven, the material blocks output by the output end of the second belt conveying section are placed to the first position of the first row of the blanking placing plate of the fermentation grating plate, and then a row placing action is performed; the course of the line putting action is as follows: when the material in-place sensor senses that the next material block is in place, the grating disc shifting mechanism drives the fermentation grating disc to move the position of a material block discharging swinging disc along the direction of the conveying direction of the second belt conveying section, and after the position of the material block discharging swinging disc is moved, the material block output by the output end of the second belt conveying section is placed at the second position of the fermentation grating disc discharging swinging disc, and the steps are sequentially circulated until one row of material block is placed, and then the material block enters the material discharging line changing action; the process of the blanking line-changing action is as follows: after one line of placement is finished, the grating disc shifting mechanism drives the fermentation grating disc to move to a position corresponding to a second line of blanking grating discs in a direction vertical to the conveying direction of the second belt conveying section, and drives the fermentation grating disc to move to a first position of the second line in the direction opposite to the conveying direction of the second belt conveying section, and material blocks output by the output end of the second belt conveying section are blanked and placed to the first position of the second line, and then enter the one line of placement action; and the steps are sequentially circulated to the discharging and placing plate of the fermentation grating plate to finish.

The viscous traditional Chinese medicine forming block prepared by adopting the equipment and the preparation process has the following advantages.

1. The molding blocks have smooth surfaces, no cracks and no burrs, and each molding block has stable weight, thereby ensuring the fermentation of the later process of the traditional Chinese medicine, not influencing the efficacy of the traditional Chinese medicine and ensuring the qualification rate of the products of the traditional Chinese medicine molding blocks.

2. From feeding to fermentation, the formed blocks are not affected by manual intervention, manual manipulation, worker state and the like, and the yield of the traditional Chinese medicine is ensured.

3. The production efficiency of the traditional Chinese medicine forming block is improved, the weight stability of the traditional Chinese medicine forming block is improved, the labor is saved, and the enterprise cost is reduced.

The above embodiments and drawings are not intended to limit the form and style of the present invention, and any suitable changes or modifications made by those skilled in the art should not be construed as departing from the scope of the present invention.

Claims (8)

1. The utility model provides a viscidity material stamp shaping piece preparation equipment which characterized in that: comprises a material extruding device, a conveying device, a cutter device, a die printing device and a swinging disc device; the extruding device is provided with a shape discharging nozzle; the conveying device comprises a first belt conveying section and a second belt conveying section, wherein the input end of the first belt conveying section is correspondingly arranged below the discharging nozzle, and the input end of the second belt conveying section is in connection conveying with the output end of the first belt conveying section; the cutter device comprises a cutter which is correspondingly arranged above the first belt conveying section; the stamping device comprises a mould corresponding to the upper part of the second belt conveying section, a lifting driving mechanism for driving the mould to lift and a demoulding mechanism for forming and demoulding the mould; the tray swinging device comprises a tray shifting mechanism and a fermentation tray placed on the tray shifting mechanism, and the fermentation tray is arranged below the output end of the second belt conveying section correspondingly.

2. The apparatus for making a viscous material die-cast molding block of claim 1, wherein: the mould includes outer module and interior module, be formed with the die cavity in the outer module, the lower surface that the die cavity leads to outer module is relative with second belt conveyor section, the embedding that interior module can move about from top to bottom is established on die cavity upper portion, and the lower surface of interior module constitutes the shaping space of material die mark shaping piece with the die cavity inner wall of its below, thereby demoulding mechanism reaches the drawing of patterns for the relative motion that the lift drive mechanism connects the lift activity of drive outer module lift activity and interior module respectively and reach between outer module and the interior module.

3. The apparatus for making a viscous material die-cast block of claim 2, wherein: and a cavity depth adjusting structure for adjusting the position of the inner module in the outer module is arranged between the inner module and the outer module.

4. The apparatus for making a viscous material die-cast block of claim 2, wherein: the demoulding mechanism further comprises a blowing mechanism, the output end of the blowing mechanism is connected to the inner module, and an air channel structure capable of leading gas output by the output end of the blowing mechanism to the forming space to achieve demoulding is arranged on the inner module.

5. The apparatus for making a viscous material stamp-formed block according to any one of claims 1 to 4, wherein: and the second belt conveying section is provided with an action sensor on one side of the input direction of the mould towards the conveying direction for controlling the action of the printing device.

6. The apparatus for making a viscous material stamp-formed block according to any one of claims 1 to 4, wherein: the material extruding device comprises a material box with a feeding opening and an extruding opening and a feeding roller mechanism arranged in the material box and used for stirring and extruding materials from the extruding opening, and the shape discharging nozzle is detachably and replaceably arranged on the extruding opening.

7. The apparatus for making a viscous material stamp-formed block according to any one of claims 1 to 4, wherein: the second belt conveying section is provided with a telescopic moving mechanism which can enable the output end of the second belt conveying section to move back and forth along the conveying front and back direction, and the telescopic moving mechanism is provided with a material in-place sensor corresponding to the output end of the second belt conveying section; the grid plate shifting mechanism is used for driving the fermentation grid plate to move in the direction perpendicular to the conveying direction of the second belt conveying section, and an initial position sensor used for sensing the initial position of the fermentation grid plate to be placed is arranged on the grid plate shifting mechanism.

8. The apparatus for making a viscous material stamp-formed block according to any one of claims 1 to 4, wherein: a material in-place sensor is arranged on the second belt conveying section corresponding to the output end of the second belt conveying section; the grating disc shifting mechanism is used for driving the fermentation grating disc to move along the front-back direction conveyed by the second belt conveying section and the direction vertical to the front-back direction, and an initial position sensor used for sensing the initial position of the fermentation grating disc is arranged on the grating disc shifting mechanism.

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