CN115609742A

CN115609742A - Automatic production process of building materials

Info

Publication number: CN115609742A
Application number: CN202211188381.1A
Authority: CN
Inventors: 杨飞
Original assignee: Zhejiang Changxing Feiyang Construction Engineering Co ltd
Current assignee: Zhejiang Changxing Feiyang Construction Engineering Co ltd
Priority date: 2022-09-28
Filing date: 2022-09-28
Publication date: 2023-01-17

Abstract

The invention relates to an automatic production process of building materials, which comprises a transmission process, wherein a partition component and a smoothing component in a bearing mechanism are driven by a swing mechanism to be transmitted backwards; a material cavity blocking step, wherein the bearing groove is divided into a material discharging cavity a and a material discharging cavity b by a blocking assembly and a smoothing assembly; a pigment filling step, wherein a first feeding mechanism fills pigment into the discharging cavity a; a cement pouring process, namely pouring cement into the discharge cavity b by the second feeding mechanism; a material cavity opening procedure, wherein the partition assembly is opened to enable the discharging cavity a and the discharging cavity b to be communicated; a cement smoothing process, wherein a smoothing assembly scrapes and smoothes cement; a pressing step of pressing and molding cement by a pressing mechanism; a brick jacking process, namely jacking bricks out by a jacking mechanism; a transfer output process, wherein the transfer mechanism outputs the bricks; the problems of low efficiency, poor continuity of the manufacturing process, high labor cost input, low accuracy, low automation degree and the like in the manufacturing process of the conventional bionic brick are solved.

Description

Automatic production process of building materials

Technical Field

The invention relates to the technical field of building material processing, in particular to an automatic production process of building materials.

Background

In the bionic brick manufacturing process, cement pigment is poured into a mold manually and paved manually, cement paste is poured into the mold filled with the cement pigment, then the cement paste in the mold is flattened one by one manually and sent to a pressing table for pressing and manufacturing the bionic brick, and the problems of large manpower consumption, low efficiency, poor continuity in the manufacturing process, large material waste and the like exist in the bionic brick manufacturing process.

The invention discloses a Chinese invention with publication number CN111777371A, and discloses a preparation process of a stone-like PC brick, wherein colored sand, stone powder, cement, slag powder, silica fume and a powdery additive are uniformly stirred, water is added into the mixture, and the mixture is uniformly stirred to obtain a fabric; mixing cement, sand, broken stone, stone chips, stone powder, slag powder and fly ash, and uniformly stirring to obtain a bottom material; laying a bottom die, and vibrating the bottom die during laying the bottom die; after the bottom material is distributed, prepressing the bottom material by an upper die, distributing the fabric, vibrating the upper die during the fabric distribution, then pressing for forming, and demolding to obtain the stone-like PC brick.

The problems of high labor cost investment, poor continuity, low automation degree, low efficiency and the like still exist in the process of manufacturing the bionic brick.

Disclosure of Invention

The invention aims to provide an automatic production process for building materials, which aims at overcoming the defects of the prior art and solving the problems of low automation degree, low manufacturing efficiency, poor continuity of the manufacturing process and the like in the manufacturing process of the conventional bionic brick.

Aiming at the technical problems, the technical scheme adopted by the invention is as follows:

an automatic production process of building materials comprises the following production steps:

the method comprises the following steps that firstly, in the conveying process, a partition component and a smoothing component on a bearing mechanism are driven by a slewing mechanism to be conveyed backwards;

step two, a material cavity blocking process, namely dividing the bearing groove into a material discharging cavity a and a material discharging cavity b by the blocking assembly and the smoothing assembly under the action of the guide assembly a and the guide assembly b respectively in the step one;

step three, a pigment filling step, wherein when the discharging cavity a in the step two moves to the lower end of the first feeding mechanism, the first feeding mechanism fills pigment into the discharging cavity a;

step four, cement pouring, namely when the discharging cavity b in the step two moves to the lower end of the second feeding mechanism, the second feeding mechanism pours cement into the discharging cavity b;

step five, a material cavity opening procedure, wherein the closed partition assembly in the step two is opened under the action of the guide assembly a, so that the discharge cavity a is communicated with the discharge cavity b;

step six, a cement smoothing process, namely scraping and smoothing cement poured into the discharging cavity b in the step four by the smoothing assembly in the step two in the process of resetting the smoothing assembly separated from the guide assembly b;

step seven, a pressing process, namely pressing the cement which is scraped and leveled in the step six and moves to the lower end of the pressing mechanism into a brick block;

step eight, a brick jacking process, namely jacking the bricks pressed and formed in the step seven out of the bearing mechanism by a jacking mechanism under the action of a lifting guide bar;

and the step eight of the brick conveying process is that the brick which is separated from the bearing mechanism in the step eight is conveyed by the conveying mechanism.

Preferably, in the first step, the isolation assembly and the smoothing assembly are slidably arranged on the side wall of the bearing groove in the bearing mechanism, and the bearing mechanism is conveyed backwards through the chain.

Preferably, in the second step, the blocking plate in the blocking assembly slides to the inside of the bearing groove until being closed in the process of passing through the pushing-in section a in the outer guide rail and the pushing-in section b in the inner guide rail, and the smoothing plate in the smoothing assembly slides to the inside of the bearing groove until being closed in the process of passing through the side pushing section in the guide rail.

Preferably, in the third step, the cylinder a in the first feeding mechanism pushes the discharging pipe a towards the direction of the bearing groove, and after the discharging port a on the side surface of the bottom end of the discharging pipe a is communicated with the feeding port on the bearing groove, the first feeding mechanism fills the pigment into the discharging cavity a.

Preferably, in the fourth step, the air cylinder b in the second feeding mechanism pushes the discharging pipe b towards the direction of the bearing groove, and after the discharging port b on the discharging pipe b enters the discharging cavity b, the second feeding mechanism fills cement into the discharging cavity b.

Preferably, the blocking plate in the blocking assembly in the fifth step slides to two sides of the bearing groove until being completely opened in the process of passing through the withdrawing section a in the outer guide rail and the withdrawing section b in the inner guide rail.

Preferably, after the smoothing plate in the sixth smoothing assembly is separated from the guiding function of the guide rail, the smoothing plate is reset through a reset spring a, and in the resetting process, the triangular lug arranged at one end of the smoothing plate is rotated to scrape and smooth the upper surface of the cement.

Preferably, the lower pressing block in the step seven pressing mechanism presses the cement scraped and smoothed in the bearing groove into a brick under the action of the lower pressing table.

Preferably, in the eight-step jacking mechanism, the lifting rod drives the jacking disk fixedly arranged at one end of the lifting rod to jack the brick out of the bearing groove in the process of passing through the ascending section in the lifting guide bar.

Preferably, the air cylinder c in the ninth transferring mechanism pushes the bricks separated from the bearing groove onto the conveying belt through the material receiving plate, and the motor a drives the conveying belt to output the bricks.

The invention also aims to overcome the defects of the prior art and provides a bionic brick production system, wherein a bearing groove is divided into a discharging cavity a and a discharging cavity b, a bearing mechanism transmits the discharging cavity a, a first feeding mechanism fills cement pigment into the discharging cavity a, a second feeding mechanism fills cement paste into the discharging cavity b filled with the cement pigment, a smoothing component smoothes the cement paste, a partition component withdraws towards two sides before reaching a pressing mechanism, the pressing mechanism presses the cement pigment and the cement paste for forming, and a jacking mechanism lifts bricks, so that the problems of low efficiency, poor continuity of a manufacturing process, large investment of labor cost, low accuracy, low automation degree and the like in the existing bionic brick manufacturing process are solved.

a bionic brick production system comprises a transmission device, wherein the transmission device comprises a swing mechanism and a plurality of bearing mechanisms driven by the swing mechanism, a partition component and a smoothing component are arranged on the bearing mechanisms in a sliding manner, a guide component a and a guide component b are respectively arranged on moving paths of the partition component and the smoothing component, the partition component and the smoothing component are respectively pushed inwards and reset to slide out under the action of the guide component a and the guide component b, a first feeding mechanism, a second feeding mechanism and a pressing mechanism are sequentially arranged on the moving paths of the bearing mechanisms, and a jacking mechanism is further arranged in each bearing mechanism; the partition component divides the bearing mechanism into a discharging cavity a and a discharging cavity b, the first feeding mechanism is used for filling cement pigment into the discharging cavity a which moves to the bearing mechanism at the lower end of the first feeding mechanism, the second feeding mechanism is used for filling cement paste into the discharging cavity b which is filled with the cement pigment and moves to the bearing mechanism at the lower end of the second feeding mechanism, the smoothing component is used for smoothing the cement paste in the discharging cavity b, the pressing mechanism is used for pressing the cement paste which moves to the bearing mechanism at the lower end of the pressing mechanism into bricks, and the jacking mechanism is used for jacking the bricks which are formed by pressing and outputting.

Preferably, the slewing mechanism comprises a rotating base, a motor box a fixedly arranged on the rotating base and a chain driven by the motor box a; the bearing mechanism comprises a support arm, a bearing groove, guide wheels, a support guide rail, slide bars, a slide groove a, a slide groove b and a feed port, wherein one end of the support arm is fixedly arranged on the chain, the bearing groove is fixedly arranged at the other end of the support arm, the guide wheels are rotatably arranged on two sides of the support arm, the support guide rail is fixedly arranged on a moving path of the guide wheels, the slide bars are fixedly arranged on two sides of the bearing groove, the slide groove a, the slide groove b and the feed port are arranged on two sides of the bearing groove, and the slide groove c is arranged on the support arm.

Preferably, the partition assembly comprises a partition plate slidably disposed in the sliding groove a, a supporting rod a fixedly disposed at the tail end of the group partition plate, and a sliding block a fixedly disposed at the bottom end of the supporting rod a.

Preferably, the smoothing assembly comprises a smoothing plate arranged in the sliding groove b in a sliding mode, a triangular lug rotatably arranged at one end of the smoothing plate, a supporting rod b and a sliding strip fixedly arranged at the other end of the smoothing plate, a sliding block b fixedly arranged at the bottom end of the supporting rod b and a return spring a arranged on the sliding rod, and a spring b is arranged between the triangular lug and the smoothing plate.

Preferably, the guide assembly a comprises a supporting leg, and an outer rail and an inner rail which are fixedly arranged on the supporting leg, wherein the outer rail comprises an exit section a, a smooth section a, a rotary section a and a push-in section a, and the inner rail comprises an exit section b, a smooth section b, a rotary section b and a push-in section b; the guide assembly b comprises a support frame and a guide rail fixedly arranged on the support frame, and the guide rail comprises a smooth section c, a side pushing section and a smooth section d.

Preferably, the first feeding mechanism comprises a storage barrel fixedly arranged on the support seat a, an air cylinder a fixedly arranged on the lower bottom surface of the storage barrel, a push rod a driven by the air cylinder a, a discharging pipe a arranged on the storage barrel in a sliding manner, an inductor a fixedly arranged on the discharging pipe a, a discharging port a arranged on the side surface of the bottom end of the discharging pipe a and a signal receiver a fixedly arranged on the storage barrel, wherein the discharging pipe a is fixedly connected with the push rod a.

Preferably, the second feeding mechanism comprises a supporting seat b, a storage box fixedly arranged on the supporting seat b, an air cylinder b, a motor b, a signal receiver b fixedly arranged on the storage box, a screw driven by the motor b to rotate, a discharging pipe fixedly arranged at one end of the storage box, a discharging pipe b arranged in the discharging pipe in a sliding mode, an inductor b fixedly arranged on the discharging pipe b, a discharging hole b arranged on the discharging pipe b and a pushing rod b driven by the air cylinder b, wherein the discharging pipe b is fixedly connected with the pushing rod b.

Preferably, the pressing mechanism comprises a supporting seat c, a pressing platform fixedly arranged on the supporting seat c and a pressing block arranged on the pressing platform in a sliding manner, and the pressing block is connected with the pressing platform in a sliding manner through a plurality of supporting sliding rods.

Preferably, the jacking mechanism comprises a lifting rod arranged in the sliding groove c in a sliding mode, a jacking disc fixedly arranged on one end of the lifting rod, a sliding block c fixedly arranged at the other end of the lifting rod and a lifting guide strip fixedly arranged on a moving path of the sliding block c, and the lifting guide strip comprises a rotary section c, an ascending section, a horizontal pushing section a, a descending section and a horizontal pushing section b.

Preferably, a transfer mechanism is further arranged on the other side of the swing mechanism, and the transfer mechanism comprises a motor a, a transmission belt driven by the motor a, barrier strips fixedly arranged on two sides of the transmission belt, a material receiving plate fixedly arranged on one side of the transmission belt, an air cylinder c arranged at one end of the material receiving plate, and a push rod c driven by the air cylinder c.

The invention has the beneficial effects that:

1. the bionic brick manufacturing device is characterized in that a rotating mechanism is arranged to drive a bearing mechanism to transmit, a partition component divides a bearing groove on the bearing mechanism into a discharging cavity a and a discharging cavity b, a first feeding mechanism, a second feeding mechanism and a pressing mechanism are sequentially arranged on a moving path of the bearing mechanism, the first feeding mechanism fills cement pigment in the discharging cavity a moving to the lower end of the first feeding mechanism, the second feeding mechanism fills cement pigment in the discharging cavity b after filling the cement pigment and moving to the lower end of the second feeding mechanism, a leveling component slowly withdraws towards the outer side of the bearing groove under the action of a guide component b to smooth the cement paste in the bearing groove, the partition component withdraws towards the outer side of the bearing groove under the action of the guide component a before reaching the pressing mechanism to enable the cement paste to be in contact with the cement pigment, the pressing mechanism presses and forms the cement paste together, a jacking mechanism arranged in the bearing mechanism in a sliding mode lifts the formed bricks in the bearing groove under the action of a lifting guide strip, and a cylinder c in the transfer mechanism pushes the bricks to transfer the bricks to output the bricks on a transfer belt in a transfer mechanism on one side of the rotating mechanism, so that the bionic bricks are poor in the existing bionic brick manufacturing process, the problems of poor continuity, poor efficiency, low cost, high efficiency, high cost of manufacturing and the waste of the high cost of the existing bionic bricks and the high cost of the existing bionic bricks are solved.

2. In the invention, partition components are arranged on two sides of a bearing groove in a sliding manner, and when a partition plate in the partition components is in a closed state under the action of a guide component a, the bearing groove is divided into a discharging cavity a and a discharging cavity b; when being in the state of separately under the effect of direction subassembly a for blowing chamber an and blowing chamber b intercommunication on dealing with the manual work and filling cement pigment and grout one by one in to traditional mould on the basis, cut off the subassembly through setting up and divide into two with the bearing groove space, and it is ingenious to merge novel filling mode structure together again after separately filling cement pigment and grout, easily realizes, makes pigment and cement fill comparatively evenly.

3. According to the invention, the two sides of the bearing groove are also provided with the smoothing components in a sliding manner, one end of a smoothing plate in the smoothing components is rotatably provided with the triangular lug, when the smoothing plates are in contact with each other under the action of the guide component b and are in a closed state, the triangular lug effectively slows down the flow of cement paste in the discharging cavity b, and when the blocking plate is pulled out of the bearing groove, the loss and waste of the cement paste are effectively slowed down; the in-process that the flat board withdrawed from to the bearing groove outside in-process of breaking away from direction subassembly b, the grout of triangle lug in with the bearing groove smooths, and the triangle lug passes through spring b with smooth board and is connected, can not cause great scraping power to the grout at the in-process of smoothing for the grout surface is comparatively level and smooth, smooths subassembly novel structure, and is difficult for destroying the whole shape of cement when smoothing effectual to the cement surface.

4. According to the bionic brick storage device, the second feeding mechanism is arranged, the screw rod is arranged in the second feeding mechanism, the screw rod is driven by the motor b to ceaselessly stir cement paste in the storage box in the second feeding mechanism, so that the cement paste can keep good fluidity all the time, and on the basis of storage of traditional production materials, the screw rod is arranged to stir the materials, so that the hardening of the cement paste is avoided, and meanwhile, the intelligence in the production process of the bionic brick is improved.

5. According to the invention, the lifting rod is arranged in the supporting arm on the bearing mechanism in a sliding manner, the jacking disc is fixedly arranged at one end of the lifting rod, when the lifting rod passes through the ascending section in the lifting guide strip, the bricks in the bearing groove are lifted by the jacking disc and matched with the transfer mechanism to output the bricks, and in the process of manually taking out the pressed bricks one by one, the bricks in the bearing groove are not easily damaged while the bricks are taken out by the jacking disc.

6. According to the bionic brick manufacturing device, the other side of the rotary mechanism is also provided with the transfer mechanism, the air cylinder c in the transfer mechanism pushes bricks lifted by the jacking plate to the material receiving plate, when the air cylinder c pushes the next brick, the previous brick is pushed to the conveying belt, the conveying belt outputs the bricks under the driving of the motor a, and on the basis of manual conveying and transferring of the bricks, the transfer mechanism is arranged to output the bricks, so that the continuity in the bionic brick manufacturing process is improved.

In conclusion, the invention has the advantages of high manufacturing efficiency, high accuracy in the manufacturing process, labor cost investment saving, improvement of the continuity in the brick manufacturing process, high automation control degree and suitability for the technical field of building material processing.

Drawings

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

FIG. 1 is a process flow diagram of an automated building material production process;

FIG. 2 is a schematic structural diagram of a bionic brick production system;

FIG. 3 is a schematic position diagram of a guide assembly a and a guide assembly b;

FIG. 4 is an enlarged schematic view at A in FIG. 3;

FIG. 5 is a schematic position diagram of a feeding cavity a and a feeding cavity b;

FIG. 6 is a schematic structural diagram of the swing mechanism;

FIG. 7 is an enlarged schematic view of the carriage mechanism at B of FIG. 6;

FIG. 8 is an enlarged schematic view at C of FIG. 7;

FIG. 9 is a schematic view of a partition assembly;

FIG. 10 is a schematic structural view of a smoothing assembly;

FIG. 11 is a schematic structural view of the right side of the leveling assembly and a return spring a;

FIG. 12 is an enlarged schematic view at D of FIG. 11;

FIG. 13 is a schematic structural view of a guide assembly a;

FIG. 14 is a schematic view of the structure of the guide member b;

FIG. 15 is a schematic structural view of a first feeding mechanism;

FIG. 16 is an enlarged schematic view at E in FIG. 15;

FIG. 17 is a schematic structural view of a second feeding mechanism;

FIG. 18 is an enlarged schematic view at F of FIG. 17;

FIG. 19 is a schematic top view of a second feed mechanism;

FIG. 20 is a schematic view of the pressing mechanism;

FIG. 21 is a schematic view of the structure of the lifting bar;

FIG. 22 is a schematic view of the position of the jacking disk;

FIG. 23 is a schematic view of the transfer mechanism;

FIG. 24 is a schematic view of the positions of the separation plates separated from each other and the leveling plates separated from each other;

fig. 25 is a schematic view of the positions of the partition plates and the stroking plates closed to each other.

Detailed Description

The technical scheme in the embodiment of the invention is clearly and completely explained in the following by combining the drawings.

Example one

As shown in fig. 1, an automatic production process for building materials comprises the following production steps:

step one, a conveying process, namely, the partition component 2 and the smoothing component 3 on the bearing mechanism 12 are driven by the rotary mechanism 11 to be conveyed backwards;

step two, a material cavity blocking process, namely dividing the bearing groove 122 into a material discharging cavity a13 and a material discharging cavity b14 by the blocking assembly 2 and the smoothing assembly 3 in the step one under the action of the guide assembly a4 and the guide assembly b5 respectively;

step three, filling pigment, wherein when the discharging cavity a13 in the step two moves to the lower end of the first feeding mechanism 6, the first feeding mechanism 6 fills pigment into the discharging cavity a 13;

step four, cement pouring, namely when the discharging cavity b14 in the step two moves to the lower end of the second feeding mechanism 7, the second feeding mechanism 7 pours cement into the discharging cavity b14;

step five, a material cavity opening procedure, wherein the partition assembly 2 closed in the step two is opened under the action of a guide assembly a4, so that a discharging cavity a13 is communicated with a discharging cavity b14;

step six, a cement smoothing process, namely, in the step two, the smoothing component 3 scrapes and smoothes the cement poured into the discharge cavity b14 in the step four in the process of resetting the separation guide component b 5;

step seven, a pressing procedure, namely pressing the cement which is scraped and smoothed in the step six and moves to the lower end of the pressing mechanism 8 into a brick 10;

step eight, a brick jacking process, namely jacking the bricks 10 pressed and molded in the step seven out of the bearing mechanism 12 by the jacking mechanism 9 under the action of the lifting guide bars 94;

and a transfer output process, wherein the transfer mechanism 15 outputs the brick 10 which is separated from the bearing mechanism 12 in the step eight.

In step one, the partition component 2 and the smoothing component 3 are slidably arranged on the side wall of the bearing groove 122 in the bearing mechanism 12, and the bearing mechanism 12 is conveyed backwards through the chain 113.

In the second step, the blocking plate 21 in the blocking assembly 2 slides towards the inside of the bearing groove 122 until being closed in the process of passing through the pushing-in section a424 in the outer guide rail 42 and the pushing-in section b434 in the inner guide rail 43, and the smoothing plate 31 in the smoothing assembly 3 slides towards the inside of the bearing groove 122 until being closed in the process of passing through the middle side pushing section 522 in the guide rail 52.

Step three, the air cylinder a63 in the first feeding mechanism 6 pushes the discharging pipe a65 to the direction of the bearing groove 122, and after the discharging port a67 on the side surface of the bottom end of the discharging pipe a65 is communicated with the feeding port 128 on the bearing groove 122, the first feeding mechanism 6 fills pigment into the discharging cavity a 13.

Step four, the air cylinder b73 in the second feeding mechanism 7 pushes the discharging pipe b78 towards the direction of the bearing groove 122, and after the discharging port b711 on the discharging pipe b78 enters the discharging cavity b14, the second feeding mechanism 7 pours cement into the discharging cavity b 14.

Barrier plate 21 in partition assembly 2 of step five slides to both sides of load bearing slot 122 in the process of passing through exit section a421 in outer guide rail 42 and exit section b431 in inner guide rail 43 until being completely opened.

After the smoothing plate 31 in the sixth smoothing assembly 3 is separated from the guiding function of the guide rail 52, the restoring spring a36 is used for restoring, and in the process of restoring, the triangular lug 32 arranged at one end of the smoothing plate 31 is rotated to scrape and smooth the upper surface of the cement.

The pressing block 83 in the step seven pressing mechanism 8 presses the cement scraped and leveled in the bearing groove 122 into the brick 10 under the action of the pressing table 82.

In the step eight, in the process that the lifting rod 91 passes through the ascending section 96 of the lifting guide bar 94 in the lifting mechanism 9, the lifting disk 92 fixedly arranged at one end of the lifting rod 91 is driven to lift the brick 10 out of the bearing groove 122.

In addition, the air cylinder c155 in the ninth transferring mechanism 15 pushes the brick 10 out of the bearing groove 122 onto the conveying belt 152 through the material receiving plate 154, and the motor a151 drives the conveying belt 152 to output the brick 10.

Example two

As shown in fig. 2 to 25, a bionic brick production system comprises a transmission device 1, wherein the transmission device 1 comprises a swing mechanism 11 and a plurality of bearing mechanisms 12 driven by the swing mechanism 11, the bearing mechanisms 12 are provided with a partition component 2 and a smoothing component 3 in a sliding manner, moving paths of the partition component 2 and the smoothing component 3 are respectively provided with a guide component a4 and a guide component b5, the partition component 2 and the smoothing component 3 are respectively pushed inwards and reset to slide out under the action of the guide component a4 and the guide component b5, a first feeding mechanism 6, a second feeding mechanism 7 and a pressing mechanism 8 are sequentially arranged on the moving path of the bearing mechanism 12, and a jacking mechanism 9 is further arranged in the bearing mechanism 12; the partition component 2 divides the bearing mechanism 12 into a discharging cavity a13 and a discharging cavity b14, the first feeding mechanism 6 is used for filling cement pigment into the discharging cavity a13 in the bearing mechanism 12 which moves to the lower end of the first feeding mechanism, the second feeding mechanism 7 is used for filling cement paste into the discharging cavity b14 in the bearing mechanism 12 which is filled with the cement pigment and moves to the lower end of the second feeding mechanism, the smoothing component 3 is used for smoothing the cement paste in the discharging cavity b14, the pressing mechanism 8 is used for pressing the cement paste which is smoothed in the bearing mechanism 12 which moves to the lower end of the second feeding mechanism into bricks 10, and the jacking mechanism 9 is used for jacking the bricks 10 which are pressed and formed to output.

It is worth mentioning that, in this embodiment, the revolving mechanism 11 is arranged to drive the carrying mechanism 12 to transport, the partition assembly 2 is arranged to divide the carrying groove 122 on the carrying mechanism 12 into the discharging cavity a13 and the discharging cavity b14, the first feeding mechanism 6, the second feeding mechanism 7 and the pressing mechanism 8 are sequentially arranged on the moving path of the carrying mechanism 12, the first feeding mechanism 6 fills the discharging cavity a14 in the carrying mechanism 12 moving to the lower end thereof with cement pigment, the second feeding mechanism 7 fills the discharging cavity b14 in the carrying mechanism 12 moving to the lower end thereof with cement paste after filling with cement pigment, the smoothing assembly 3 is slidably arranged on both sides of the carrying groove 122, the smoothing assembly 3 slowly withdraws to the outside of the carrying groove 122 under the action of the guiding assembly b5, the smoothing in the carrying groove 122 is withdrawn to the outside of the carrying groove 122 under the action of the guiding assembly a4 before reaching the pressing mechanism 8, so that the smoothing assembly 2 is in contact with cement pigment, the pressing mechanism 8 presses the cement paste and the pigment together, the sliding arrangement in the pressing mechanism presses the cement paste and presses the brick carrying mechanism 12, the brick manufacturing process, the lifting mechanism 2 transfers the cement paste to the high efficiency of the brick manufacturing process of the lifting mechanism 15 and the brick manufacturing process of the lifting mechanism 15, and the bionic brick manufacturing process of the high lifting mechanism 10, and the bionic brick manufacturing process of the high lifting mechanism, and the bionic brick manufacturing efficiency of the bionic lifting mechanism 10.

The swing mechanism 11 comprises a rotating base 111, a motor box a112 fixedly arranged on the rotating base 111, and a chain 113 driven by the motor box a 112; the bearing mechanism 12 includes a supporting arm 121 with one end fixedly disposed on the chain 113, a bearing groove 122 fixedly disposed on the other end of the supporting arm 121, a guide wheel 123 rotatably disposed on both sides of the supporting arm 121, a supporting guide rail 124 fixedly disposed on the moving path of the guide wheel 123, a sliding rod 125 fixedly disposed on both sides of the bearing groove 122, a chute a126, a chute b127 and a feeding port 128 disposed on both sides of the bearing groove 122, and a chute c129 disposed on the supporting arm 121.

The partition assembly 2 comprises a partition plate 21 slidably disposed in the sliding groove a126, a supporting rod a22 fixedly disposed at the tail end of the group partition plate 21, and a sliding block a23 fixedly disposed at the bottom end of the supporting rod a 22.

In addition, in the embodiment, the partition assemblies 2 are slidably arranged on two sides of the bearing groove 122, and when the partition plate 21 in the partition assembly 2 is in a closed state under the action of the guide assembly a4, the bearing groove 122 is partitioned into the discharging cavity a13 and the discharging cavity b14; when being in the state of separately under the effect of direction subassembly a4 for blowing chamber a13 and blowing chamber b14 intercommunication, on dealing with artifical basis of filling cement pigment and grout one by one in to traditional mould, cut off subassembly 2 through setting up and be divided into two with the bearing groove 122 space, it is ingenious to merge the novel filling mode structure together after separately filling cement pigment and grout again, easy realization makes pigment and cement fill comparatively evenly.

The smoothing assembly 3 comprises a smoothing plate 31 arranged in a sliding groove b127 in a sliding mode, a triangular lug 32 rotatably arranged at one end of the smoothing plate 31, a supporting rod b33 and a sliding strip 34 fixedly arranged at the other end of the smoothing plate 31, a sliding block b35 fixedly arranged at the bottom end of the supporting rod b33 and a return spring a36 arranged on a sliding rod 125, wherein a spring b37 is arranged between the triangular lug 32 and the smoothing plate 31.

It should be mentioned that, in this embodiment, the leveling assemblies 3 are further slidably disposed on two sides of the bearing groove 122, one end of the leveling plate 31 in the leveling assembly 3 is rotatably disposed with the triangular protrusion 32, when the leveling plates 31 are in a closed state in mutual contact under the action of the guide assembly b5, the triangular protrusion 32 effectively slows down the flow of cement slurry in the discharge cavity b14, and when the blocking plate 21 is pulled out of the bearing groove 122, the loss and waste of cement slurry is effectively slowed down; the in-process that the flat board 31 withdraws from to the bearing groove 122 outside in the effect that breaks away from guide assembly b5, the grout of bearing groove 122 is pacified to triangle lug 32, and triangle lug 32 with pacify flat board 31 and pass through spring b37 and be connected, can not cause great scraping power to grout at the in-process of pacifying for the grout surface is comparatively level and smooth, pacifies 3 novel structure of subassembly, and is difficult for destroying the whole shape of cement when pacifying effectually to the cement surface.

The guide assembly a4 comprises a supporting leg 41, an outer rail 42 and an inner rail 43 which are fixedly arranged on the supporting leg 41, wherein the outer rail 42 comprises an exit section a421, a smooth section a422, a revolving section a423 and a push-in section a424, and the inner rail 43 comprises an exit section b431, a smooth section b432, a revolving section b433 and a push-in section b434; the guide assembly b5 comprises a support frame 51 and a guide rail 52 fixedly arranged on the support frame 51, wherein the guide rail 52 comprises a smooth section c521, a side pushing section 522 and a smooth section d523.

The first feeding mechanism 6 comprises a storage barrel 62 with a support seat a61 fixedly arranged on the support seat a61, an air cylinder a63 fixedly arranged on the lower bottom surface of the storage barrel 62, a push rod a64 driven by the air cylinder a63, a discharging pipe a65 slidably arranged on the storage barrel 62, an inductor a66 fixedly arranged on the discharging pipe a65, a discharging port a67 arranged on the bottom end side surface of the discharging pipe a65 and a signal receiver a68 fixedly arranged on the storage barrel 62, wherein the discharging pipe a65 is fixedly connected with the push rod a 64.

The second feeding mechanism 7 comprises a supporting seat b71, a storage box 72, an air cylinder b73, a motor b74, a signal receiver b75, a screw 76, a discharge pipe 77, a discharge pipe b78, an inductor b79, a discharge port b711 and a pushing rod b712, wherein the storage box 72, the air cylinder b73 and the motor b74 are fixedly arranged on the supporting seat b71, the signal receiver b75 is fixedly arranged on the storage box 72, the screw 76 is driven by the motor b74 to rotate, the discharge pipe 77 is fixedly arranged at one end of the storage box 72, the discharge pipe b78 is slidably arranged in the discharge pipe 77, the inductor b79 is fixedly arranged on the discharge pipe b78, the discharge port b711 is arranged on the discharge pipe b78, and the pushing rod b712 is driven by the air cylinder b73, and the discharge pipe b78 is fixedly connected with the pushing rod b 712.

In addition, be provided with second feed mechanism 7 in this embodiment, be provided with screw rod 76 in second feed mechanism 7, screw rod 76 stirs the grout in the stock box 72 in second feed mechanism 7 under the drive of motor b73 ceaselessly for grout keeps better mobility always, on the basis that reply traditional production material was deposited, sets up screw rod 76 and stirs the material and has avoided the intelligence in the grout hardening when having promoted bionical brick production process.

The pressing mechanism 8 comprises a supporting seat c81, a lower pressing platform 82 fixedly arranged on the supporting seat c81 and a lower pressing block 83 slidably arranged on the lower pressing platform 82, wherein the lower pressing block 83 is slidably connected with the lower pressing platform 82 through a plurality of supporting sliding rods 84.

The jacking mechanism 9 comprises a lifting rod 91 arranged in the sliding groove c129 in a sliding mode, a jacking disk 92 fixedly arranged at one end of the lifting rod 91, a sliding block c93 fixedly arranged at the other end of the lifting rod 91 and a lifting guide strip 94 fixedly arranged on the moving path of the sliding block c93, wherein the lifting guide strip 94 comprises a rotary section c95, an ascending section 96, a horizontal pushing section a97, a descending section 98 and a horizontal pushing section b99.

It should be further noted that in this embodiment, the lifting rod 91 is slidably disposed in the supporting arm 121 on the bearing mechanism 12, the lifting disc 92 is fixedly disposed at one end of the lifting rod 91, when the lifting rod 91 passes through the ascending section 96 of the lifting guide bar 94, the lifting disc 92 lifts the brick 10 in the bearing groove 122 to match the transfer mechanism 15 to output the brick 10, and in the process of manually taking out the pressed bricks 10 one by one, the lifting disc 92 is disposed to take out the bricks 10 in the bearing groove 122 while not easily damaging the bricks.

EXAMPLE III

As shown in fig. 23, in which the same or corresponding components as those in embodiment two are denoted by the same reference numerals as those in embodiment two, only the points of difference from embodiment two will be described below for the sake of convenience. The third embodiment is different from the second embodiment in that: the other side of the swing mechanism 11 is further provided with a transfer mechanism 15, and the transfer mechanism 15 includes a motor a151, a conveying belt 152 driven by the motor a151, a blocking strip 153 fixedly arranged at two sides of the conveying belt 152, a material receiving plate 154 fixedly arranged at one side of the conveying belt 152, an air cylinder c155 arranged at one end of the material receiving plate 154, and a pushing rod c156 driven by the air cylinder c 155.

In this embodiment, a transfer mechanism 15 is further disposed on the other side of the rotating mechanism 11, a cylinder c155 in the transfer mechanism 15 pushes the brick 10 lifted by the jacking tray 92 onto the material receiving plate 154, when the cylinder c155 pushes the next brick 10, the previous brick 10 is pushed onto the conveyor belt 152, the conveyor belt 152 outputs the brick 10 under the driving of the motor a151, and the transfer mechanism 15 is disposed to output the brick 10 on the basis of manual transportation and transfer of the brick 10, so that the continuity in the process of manufacturing the bionic brick is improved.

The working process is as follows:

firstly, the slewing mechanism 11 drives the bearing mechanism 12 to transmit to the first feeding mechanism 6, and before reaching the first feeding mechanism 6, the blocking plates 21 arranged at two sides of the bearing groove 122 in a sliding way are in a closed state, so that the bearing groove 122 is divided into two spaces, namely a discharging cavity a13 and a discharging cavity b14;

then, the air cylinder a63 in the first feeding mechanism 6 pushes the discharging pipe a65 to the feeding hole 128 outside the carrying groove 122 at the lower end of the first feeding mechanism 6 through the pushing rod a64, the sensor a66 transmits a signal to the signal receiver a68 on the storage cylinder 62, and then the cement pigment in the storage cylinder 62 is filled into the discharging cavity a13 through the discharging hole a at the side of the bottom end of the discharging pipe a 65;

then, the bearing groove 122 filled with cement pigment continues to move towards the second feeding mechanism 7, before reaching the second feeding mechanism 7, the leveling plates 31 slidably arranged at two sides of the bearing groove 122 are in a closed state under the action of the side pushing section 522 on the guide assembly b5, then the cutting b73 in the second feeding mechanism 7 pushes the discharging pipe b78 to the outer side of the top surface of the bearing groove 122 moved to the lower end of the second feeding mechanism 7 through the pushing rod b712, the sensor b79 sends a signal to the signal receiver b75 on the storage box 72, then cement paste in the storage box 72 is filled into the discharging cavity b14 through the discharging hole b711 on the discharging pipe b78, the bearing groove 122 filled with cement pigment continues to move backwards, and before reaching the pressing mechanism 8, the blocking plates 21 at two sides of the bearing groove 122 respectively move outwards to a separated state through the withdrawing section a421 and the withdrawing section b431 in the guide assembly a 4;

then, a complete space is formed in the bearing groove 122 separated from the blocking plate 21, after the cement paste and the cement pigment are contacted with each other, the leveling plate 31 is reset through the reset spring a36 after being separated from the action of the guide assembly b5, so that the leveling plates 31 on the two sides of the bearing groove 122 are in a separated state, and in the process, the triangular convex block 32 arranged at one end of the leveling plate 31 is rotated to scrape and smooth the cement paste in the bearing groove 122;

finally, the bearing groove 122 continues to move backwards, the pressing mechanism 8 presses and forms cement paste and cement pigment in the bearing groove 122 moving to the lower end of the pressing mechanism 8, then in the process that the bearing groove 122 continues to move, the lifting rod 91 slidably arranged in the supporting arm 121 drives the jacking disc 92 to lift the bricks 10 in the bearing groove 122 when passing through the ascending section 96 in the lifting guide strip 94, the air cylinder c155 arranged on one side of the lifted bricks 10 pushes the bricks 10 lifted by the jacking disc 92 onto the material receiving plate 154, and the bricks 10 are lowered onto the conveying belt 152 through the material receiving plate 154 to be output.

In the description of the present invention, it is to be understood that the terms "front-back", "left-right", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the referred device or component must have a specific orientation, be constructed in a specific orientation, and be operated, and thus should not be construed as limiting the invention.

Of course, in this disclosure, those skilled in the art should understand that the terms "a" and "an" should be interpreted as "at least one" or "one or more", i.e., in one embodiment, one element may be present in one number, while in another embodiment, the element may be present in multiple numbers, and the terms "a" and "an" should not be interpreted as limiting the number.

While the invention has been described with reference to specific preferred embodiments, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims

1. An automatic production process of building materials is characterized in that: the method comprises the following production steps:

the method comprises the following steps that firstly, in the conveying process, a partition component (2) and a smoothing component (3) on a bearing mechanism (12) are driven by a rotary mechanism (11) to be conveyed backwards;

step two, a material cavity blocking process, namely dividing the bearing groove (122) into a material discharging cavity a (13) and a material discharging cavity b (14) by the blocking assembly (2) and the smoothing assembly (3) in the step one under the action of the guide assembly a (4) and the guide assembly b (5) respectively;

step three, filling pigment, wherein when the discharging cavity a (13) in the step two moves to the lower end of the first feeding mechanism (6), the first feeding mechanism (6) fills pigment into the discharging cavity a (13);

step four, cement pouring, wherein when the discharging cavity b (14) in the step two moves to the lower end of the second feeding mechanism (7), the second feeding mechanism (7) pours cement into the discharging cavity b (14);

step five, a material cavity opening procedure, wherein the closed partition component (2) in the step two is opened under the action of a guide component a (4), so that the discharging cavity a (13) is communicated with the discharging cavity b (14);

step six, a cement smoothing process, namely scraping and smoothing cement poured into the discharging cavity b (14) in the step four by the smoothing component (3) in the step two in the process of resetting the separation guide component b (5);

step seven, a pressing procedure, namely pressing the cement which is scraped and leveled in the step six and moves to the lower end of the pressing mechanism (8) into a brick block (10);

and step eight, a brick jacking process, namely jacking the brick (10) pressed and molded in the step seven out of the bearing mechanism (12) by the jacking mechanism (9) under the action of the lifting guide bar (94).

2. The automated production process of building materials as claimed in claim 1, wherein in the first step, the partition component (2) and the smoothing component (3) are slidably arranged on the side wall of the bearing groove (122) in the bearing mechanism (12), and the bearing mechanism (12) is conveyed backwards through the chain (113).

3. The automated production process for building materials according to claim 1, wherein in the second step, the barrier plate (21) in the barrier assembly (2) slides towards the inside of the bearing groove (122) until being closed in the process of passing through the pushing-in section a (424) in the outer guide rail (42) and the pushing-in section b (434) in the inner guide rail (43), and the leveling plate (31) in the leveling assembly (3) slides towards the inside of the bearing groove (122) until being closed in the process of passing through the side pushing section (522) in the guide rail (52).

4. The automatic production process of building materials according to claim 1, wherein in the third step, the air cylinder a (63) in the first feeding mechanism (6) pushes the discharging pipe a (65) towards the bearing groove (122), and after the discharging port a (67) on the side surface of the bottom end of the discharging pipe a (65) is communicated with the feeding port (128) on the bearing groove (122), the first feeding mechanism (6) fills pigment into the discharging cavity a (13).

5. The automatic production process of building materials according to claim 1, wherein the cylinder b (73) in the fourth feeding mechanism (7) pushes the discharging pipe b (78) towards the bearing groove (122), and when the discharging port b (711) on the discharging pipe b (78) enters the discharging cavity b (14), the second feeding mechanism (7) pours cement into the discharging cavity b (14).

6. The automated production process of building materials as claimed in claim 1, wherein the blocking plate (21) in the blocking assembly (2) in the fifth step slides to both sides of the bearing groove (122) until being completely opened in the process of passing through the exit section a (421) in the outer guide rail (42) and the exit section b (431) in the inner guide rail (43).

7. The automated production process of building materials as claimed in claim 6, wherein the smoothing plate (31) in the sixth smoothing assembly (3) is reset by a reset spring a (36) after being separated from the guiding function of the guide rail (52), and during the resetting process, the triangular lug (32) arranged at one end of the smoothing plate (31) is rotated to scrape and smooth the upper surface of the cement.

8. The automated production process of building materials as claimed in claim 1, wherein the pressing blocks (83) in the seven-step pressing mechanism (8) press the cement in the bearing grooves (122) into the bricks (10) under the action of the pressing table (82).

9. The automated production process of building materials as claimed in claim 1, wherein the eight-step jacking mechanism (9) drives the jacking disk (92) fixedly arranged at one end of the lifting rod (91) to jack the brick (10) out of the bearing groove (122) in the process that the lifting rod (91) passes through the ascending section (96) of the lifting guide bar (94).

10. The automated production process of building materials as claimed in claim 1, wherein the cylinder c (155) in the nine-step transfer mechanism (15) pushes the bricks (10) separated from the bearing groove (122) onto the conveyor belt (152) through the receiving plate (154), and the motor a (151) drives the conveyor belt (152) to output the bricks (10).