CN116675012A - Environment-friendly non-clay brick production conveying device - Google Patents

Abstract

The application relates to the technical field of non-clay brick production and conveying, and in particular provides an environment-friendly non-clay brick production and conveying device, which comprises: two fixed brackets, a bearing plate and a limiting bearing mechanism. When the supporting plate is placed, the position of the supporting plate is limited through the limiting supporting mechanism, shaking is prevented from being generated when the supporting plate moves after supporting the porous bricks, the stability of porous brick conveying is affected, the problem of porous brick deformation caused by shaking of the supporting plate is solved, the main supporting rod and the auxiliary supporting rod are arranged at the bottom of the supporting plate, and the supporting plate is provided with the matched stepped counter bore holes, so that the bottom of the supporting plate can be supported, the middle part of the supporting plate cannot be concavely deformed under the action of the gravity of the porous bricks when the supporting plate is stacked later, meanwhile, the supporting plate is also subjected to plug connection and limiting, and the porous bricks are prevented from being deformed or cracked when the middle part of the supporting plate is concavely deformed or moved when the supporting plate is conveyed.

Description

Environment-friendly non-clay brick production conveying device

Technical Field

The application relates to the technical field of non-clay brick production and conveying, and particularly provides an environment-friendly non-clay brick production and conveying device.

Background

The environment-friendly non-clay brick refers to a brick which does not use clay as a raw material, such as a smooth brick, a porous brick, an energy-saving sound-insulating brick and the like which are made of materials such as cement, lime and the like, does not need to be fired at high temperature, does not pollute air, and takes the porous brick as an example, when the porous brick is manufactured, the formed porous brick is required to be carried and conveyed, then the porous brick is conveyed into a drying kiln for drying treatment, and in the process, the panel carrying the porous brick is required to be conveyed and piled up, so that the porous brick can enter the drying kiln in batches.

But the following problems are easy to occur when the porous bricks are produced and transported: 1. the panel for carrying the porous bricks is easy to concave under the action of the gravity of the porous bricks after carrying the porous bricks, the porous bricks on the panel are easy to move towards the concave of the panel when moving and stacking and placing, so that the porous bricks which are not dried and shaped are deformed and used after being influenced, and in order to facilitate taking and placing the panel for carrying the porous bricks when stacking, the panel for carrying the porous bricks is not limited, the panel is easy to shake when moving, friction is easily generated between the porous bricks and the panel when shaking, and the bottom of the porous bricks which are not dried and shaped are cracked is caused; 2. when carrying the panel that has accepted the perforated brick and remove, the panel is liable to produce on conveying equipment and remove to the stationarity when having reduced the perforated brick on the panel and carrying, the perforated brick that easily leads to takes place to warp.

Disclosure of Invention

In view of the above problems, the embodiments of the present application provide an environment-friendly non-clay brick production and conveying device, so as to solve the technical problems that in the related art, a panel for receiving porous bricks deforms under the action of gravity pressing of porous bricks, which affects the quality of porous bricks, and when stacking porous bricks, the panel for receiving porous bricks is not subjected to limiting treatment for easy taking and placing, so that shaking occurs when the stacked porous bricks move, which causes damage to the porous bricks.

In order to achieve the above object, the embodiment of the present application provides the following technical solutions: an environmental protection non-clay brick production conveyor, includes: the two fixing brackets and the bearing plate are rotatably connected with a rotating shaft, opposite faces of the two fixing brackets are rotatably connected with a mounting shaft, the mounting shaft is connected with the rotating shaft through a main chain wheel and a chain in a transmission manner, and the two chains are provided with limiting bearing mechanisms which limit the bearing plate placed on the chains.

The bottom rotation of the bearing plate is installed four main vaulting poles and a plurality of auxiliary vaulting poles that are the rectangle and arrange, and a plurality of auxiliary vaulting poles are located between four main vaulting poles, and the face expanding plate is all installed to the bottom of main vaulting pole and auxiliary vaulting pole, and the toper projection is installed to the bottom of face expanding plate, and the ladder counter bore with main vaulting pole, auxiliary vaulting pole position one-to-one is seted up at the top of bearing plate, and the vertical section of downside of ladder counter bore is with toper projection complex inclined plane, ladder counter bore and face expanding plate, toper projection grafting cooperation.

One end of each fixed support, which is close to the installation shaft, is an inserting and placing station, one side, which is close to the inserting and placing station, of each fixed support is a porous brick forming and discharging station, one end, which is far away from the installation shaft, of each fixed support is a hoisting and discharging station, and the existing porous brick forming equipment is positioned above the porous brick forming and discharging station.

The bearing driving mechanism is arranged at one end of the two fixed brackets, which is close to the rotating shaft, and is used for supporting the bearing plates bearing the porous bricks so as to facilitate stacking of the bearing plates; one side of one of the fixed brackets is provided with a hoisting driving mechanism, and the hoisting driving mechanism is used for moving the bearing plate bearing the porous bricks from the chain to the bearing driving mechanism.

The limiting bearing mechanism comprises a plurality of groups of bearing groups, each group of bearing groups consists of an L-shaped bearing seat, a limiting seat and a plurality of middle bearing plates, wherein the L-shaped bearing seats are hinged to the chain, the limiting seat, the middle bearing plates and the L-shaped bearing seats are sequentially distributed along the direction from an installation shaft to a rotation shaft when being positioned above the chain, the middle bearing plates are rotationally connected with antifriction rollers which are uniformly distributed, the limiting seats are provided with accommodating grooves, the accommodating grooves are provided with extension limiting blocks through supporting springs, one sides of the tops of the extension limiting blocks, far away from the L-shaped bearing seats, are of arc structures, the L-shaped bearing seats and the limiting seats are provided with side baffle plates, and one sides of the side baffle plates on the limiting seats, far away from the L-shaped bearing seats, are of arc structures.

In a possible implementation manner, the hoisting driving mechanism comprises a fixed guide rail, the fixed guide rail is connected with a supporting vertical plate sliding along the length direction of the supporting vertical plate in a sliding manner, an up-down sliding lifting plate is connected to the supporting vertical plate, an adjusting and mounting box with a cavity structure is mounted at the bottom of the lifting plate, a first sliding plate is mounted on two side walls of the adjusting and mounting box, which are distributed along the length direction of the fixed support, a L-shaped clamping plate is mounted at one end of the first sliding plate, which is far away from the adjusting and mounting box, a second sliding plate is mounted on two side walls of the adjusting and mounting box, which are distributed along the axial direction of a rotating shaft, an inverted U-shaped frame is mounted at one end of the second sliding plate, an inserting and supporting plate is mounted on two vertical sections of the inverted U-shaped frame, a clamping driving group for clamping the receiving plate is mounted in the adjusting and mounting box in a synchronous movement manner, and a limiting group for limiting downward movement of the L-shaped clamping plate is mounted on one fixed support.

In one possible implementation mode, the clamping driving group comprises a driving rotating shaft which is rotationally connected to the middle of the adjusting and mounting box, driving gears which are arranged symmetrically up and down are arranged on the driving rotating shaft, racks are arranged on the first sliding plate and the second sliding plate, two racks on the first sliding plate are staggered, are positioned on two sides of the driving gear on the upper side and are meshed with the driving gear for transmission, and two racks on the second sliding plate are staggered, are positioned on two sides of the driving gear on the lower side and are meshed with the driving gear for transmission.

In one possible implementation mode, two the fixed bolster is kept away from the one end of rotation axis and is installed jointly and insert and move the direction group, inserts and moves the sector plate that the direction group was installed through the support bar on the fixed bolster, and the arc lateral wall of two sector plates is located the opposite face of two sector plates, and the sector plate is close to one side of chain and all installs supplementary arc strip, and two supplementary arc strips all are located between two main chain wheel.

In one possible implementation mode, the limiting group comprises two fixing plates which are arranged on one fixing support along the length direction of the fixing plates, the top of each fixing plate is provided with a limiting baffle disc through a supporting column, the top of each limiting baffle disc is provided with a plug post, the L-shaped clamping plate is provided with a waist-shaped sleeve, the waist-shaped sleeve is in plug connection with the plug post, and the limiting baffle disc limits the waist-shaped sleeve when moving downwards.

In one possible implementation mode, a discharging hole penetrating through the bearing plate, the main supporting rod/auxiliary supporting rod, the surface expanding disc and the conical convex column is formed in the stepped counter bore at the top of the bearing plate.

In one possible implementation mode, the bearing driving mechanism comprises a movable plate vehicle, two groups of step counter bores are formed in the top of the movable plate vehicle, and the structure and the position distribution of the step counter bores on each group of movable plate vehicle are identical to those of the step counter bores on the bearing plate except that the depth of the step counter bores on the movable plate vehicle is larger than that of the step counter bores on the bearing plate.

In one possible implementation mode, the fixing frames are arranged on the two fixing frames, the opposite faces of the two fixing frames are rotationally connected with bearing shafts which are uniformly distributed, auxiliary chain wheels are fixedly sleeved on the bearing shafts, and the auxiliary chain wheels are in meshed transmission with the middle part of the upper horizontal section of the chain.

In one possible embodiment, the opposite faces of both said fixed brackets are provided with a protective cover for isolating the horizontal section of the underside of the chain.

The above technical solutions in the embodiments of the present application have at least one of the following technical effects: 1. according to the environment-friendly non-clay brick production conveying device, when the bearing plate is placed, the position of the bearing plate is limited through the limiting bearing mechanism, so that shaking is prevented when the bearing plate moves after bearing the porous bricks, the stability of porous brick conveying is affected or the porous bricks are deformed, the bottom of the bearing plate is provided with the main supporting rod and the auxiliary supporting rod, the bearing plate is provided with the matched stepped counter bore, the middle part of the bearing plate is prevented from being concavely deformed under the action of the gravity of the porous bricks when the porous bricks are piled later, meanwhile, the bearing plate can be subjected to plug connection and limiting, and the porous bricks are prevented from being deformed or cracked when the middle part of the bearing plate is concavely deformed or moved when the bearing plate is conveyed, so that the quality of the porous bricks is affected.

2. The L-shaped abutting seat and the extending limiting block limit the bearing plate, and meanwhile, the placement position of the bearing plate is positioned, so that the stability of the bearing plate in the placement and movement process is improved, and the bearing plate bearing the perforated bricks is conveniently subjected to splicing and stacking afterwards.

3. When the conical convex column is inserted into the step counter bore, the conical structure of the conical convex column can improve the convenience of the insertion into the step counter bore, and the surface expansion disc can increase the contact area between the main stay rod/auxiliary stay rod and the step counter bore and improve the stability of the insertion connection between the main stay rod/auxiliary stay rod and the step counter bore.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings that are required to be used in the embodiments or the description of the prior art will be briefly described below, and it is obvious that the drawings in the following description are only embodiments of the present application, and that other drawings can be obtained according to the provided drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic view of a main perspective structure of the present application.

Fig. 2 is a partial cross-sectional view of the present application.

Fig. 3 is an enlarged view of the application at a in fig. 2.

FIG. 4 is a schematic view of the structure of the receiving plate and the parts thereon according to the present application.

Fig. 5 is a cross-sectional view of the part of fig. 4 in accordance with the present application.

FIG. 6 is a schematic view of the structure of the limiting base, the accommodating groove, the extending limiting block and the supporting spring.

Fig. 7 is a top cross-sectional view of the hoist drive mechanism of the present application.

Fig. 8 is a schematic view of a partial perspective structure of the hoist driving mechanism of the present application.

Reference numerals: 1. a fixed bracket; 2. a receiving plate; 3. a rotation shaft; 4. a mounting shaft; 5. a limit bearing mechanism; 6. a supporting driving mechanism; 7. hoisting the driving mechanism; 8. a porous brick; 10. a sector plate; 11. supplementing an arc bar; 12. a fixing frame; 13. an auxiliary sprocket; 14. a protective cover; 20. a main stay bar; 21. an auxiliary stay bar; 22. a spread-surface plate; 23. conical convex columns; 24. step counter bore; 240. a discharge hole; 50. an L-shaped base; 51. a limit seat; 52. a middle bearing plate; 53. a receiving groove; 54. extending a limiting block; 55. side baffles; 60. a movable plate vehicle; 70. a fixed guide rail; 71. a supporting vertical plate; 72. a lifting plate; 73. adjusting the mounting box; 74. a first sliding plate; 75. an L-shaped clamping plate; 76. a second sliding plate; 77. an inverted U-shaped frame; 78. inserting and supporting plates; 79. clamping the driving group; 790. driving the rotating shaft; 791. a drive gear; 780. a fixing plate; 781. a support column; 782. a limiting baffle disc; 783. inserting a column; 784. a waist-shaped sleeve.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In order that those skilled in the art will better understand the present application, the following description will be given in detail with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1 and 2, an environment-friendly non-clay brick production and conveying device comprises: the two fixing brackets 1 and the bearing plate 2 are rotatably connected with a rotating shaft 3, opposite surfaces of the two fixing brackets 1 are rotatably connected with a mounting shaft 4, the mounting shaft 4 is connected with the rotating shaft 3 through a main chain wheel and a chain in a transmission manner, and the two chains are provided with limiting bearing mechanisms 5 which limit the bearing plate 2 placed on the chains.

Referring to fig. 4 and 5, four main supporting rods 20 and a plurality of auxiliary supporting rods 21 which are arranged in a rectangular manner are rotatably installed at the bottom of the bearing plate 2, the auxiliary supporting rods 21 are located among the four main supporting rods 20, a surface expanding disc 22 is installed at the bottoms of the main supporting rods 20 and the auxiliary supporting rods 21, conical convex columns 23 are installed at the bottoms of the surface expanding discs 22, stepped counter bores 24 corresponding to the positions of the main supporting rods 20 and the auxiliary supporting rods 21 one by one are formed in the top of the bearing plate 2, inclined surfaces matched with the conical convex columns 23 are formed in the vertical sections of the lower sides of the stepped counter bores 24, and the stepped counter bores 24 are in plug-in fit with the surface expanding disc 22 and the conical convex columns 23.

One end of each fixed support 1, which is close to the mounting shaft 4, is a plugging and placing station, one side, which is close to the plugging and placing station, of each fixed support 1 is a porous brick 8 forming and blanking station, one end, which is far away from the mounting shaft 4, of each fixed support 1 is a hoisting and discharging station, and when the device is specifically working, the existing porous brick 8 forming equipment is positioned above the porous brick 8 forming and blanking station.

Referring to fig. 5, a discharging hole 240 penetrating the receiving plate 2, the main stay bar 20/auxiliary stay bar 21, the surface expansion plate 22 and the conical convex column 23 is formed in the stepped counter bore 24 at the top of the receiving plate 2, so that the problem that the receiving plate 2 is used after being affected due to the fact that dust falls down from the porous bricks 8 on the receiving plate 2 to block the stepped counter bore 24 after drying is avoided.

Referring to fig. 1, a bearing driving mechanism 6 is disposed at one end of two fixing brackets 1 near the rotating shaft 3, and is used for supporting the bearing plates 2 with porous bricks 8, so as to facilitate stacking of a plurality of bearing plates 2; one side of one of the fixed brackets 1 is provided with a hoisting driving mechanism 7, and the hoisting driving mechanism 7 is used for moving the bearing plate 2 bearing the perforated bricks 8 from the chain to the bearing driving mechanism 6.

When the supporting plate 2 is stacked after supporting the perforated bricks 8, the lifting driving mechanism 7 drives the lifted supporting plate 2 to move downwards, so that the expansion surface plate 22 and the conical convex column 23 at the bottom of the lifted supporting plate 2 are inserted into the stepped counter bore 24 on the supporting plate 2 which is already stacked on the supporting driving mechanism 6, the stepped counter bore 24 on the supporting plate 2 which is already stacked on the supporting driving mechanism 6 supports the expansion surface plate 22 and the conical convex column 23 which are placed downwards above the supporting plate 2, the bottom of the supporting plate 2 is supported and limited by the main supporting rod 20 and the auxiliary supporting rod 21, the situation that the middle part of the supporting plate 2 is deformed downwards due to the weight factor of the perforated bricks 8 at the top of the supporting plate 2, the perforated bricks 8 on the supporting plate 2 below the supporting plate are damaged is avoided, and when the supporting driving mechanism 6 drives the supporting plate 2 to move towards the existing perforated bricks 8, the conical convex column 23 shakes when being inserted into the stepped counter bore 24, the conical structure can improve the convenience of insertion, and the contact area between the expansion surface plate 22 and the counter bore 24 can be increased.

Referring to fig. 2, 3 and 6, the spacing receiving mechanism 5 includes a plurality of groups of receiving groups, each group of receiving groups is composed of an L-shaped base 50 hinged on a chain, a spacing base 51 and a plurality of middle bearing plates 52, the spacing base 51, the middle bearing plates 52 and the L-shaped base 50 are sequentially arranged along the direction from the mounting shaft 4 to the rotating shaft 3 when being positioned above the chain, grinding reduction rollers which are uniformly arranged are rotationally connected on the middle bearing plates 52, a containing groove 53 is formed on the spacing base 51, an extending limiting block 54 is mounted on the containing groove 53 through a supporting spring, one side of the top of the extending limiting block 54 far from the L-shaped base 50 is in an arc structure, side baffles 55 are mounted on the L-shaped base 50 and the spacing base 51, one side of the side baffles 55 on the spacing base 51 far from the L-shaped base 50 is in an arc structure, and two ends of the lower side of the receiving plate 2, which are close to the spacing base 51 and the L-shaped base 50, are in arc structures.

The supporting plate 2 is pushed from the end parts of the two fixed brackets 1 to the limiting seat 51 of the inserting station, the arc-shaped part of the supporting plate 2 extrudes the arc-shaped part of the extending limiting block 54 in the moving process, so that the extending limiting block 54 moves into the accommodating groove 53, then the supporting plate 2 moves towards the L-shaped supporting seat 50 under the guiding limiting action of the side baffles 55 on the two sides of the limiting seat 51 until the end part of the supporting plate 2 abuts against the vertical section of the L-shaped supporting seat 50, at the moment, the supporting plate 2 is positioned between the L-shaped supporting seat 50 and the extending limiting block 54, the extending limiting block 54 resets under the elastic action of the supporting spring, the supporting plate 2 is limited, the placing position of the supporting plate 2 is positioned, the stability of the supporting plate 2 in the moving process is improved, and the supporting plate 2 with the porous bricks 8 is convenient to be inserted and piled afterwards.

Referring to fig. 2, two opposite surfaces of the fixing support 1 are respectively provided with a protection cover 14 for isolating the horizontal section of the lower side of the chain, and the protection covers 14 are used for protecting the limit bearing mechanism 5 on the chain.

Referring to fig. 3, two fixing frames 12 are mounted on the fixing frames 1, opposite faces of the two fixing frames 12 are respectively and rotatably connected with bearing shafts which are uniformly distributed, auxiliary chain wheels 13 are fixedly sleeved on the bearing shafts, the auxiliary chain wheels 13 are in meshed transmission with the middle of the upper horizontal section of the chain, and the auxiliary chain wheels 13 are used for supporting the middle of the chain, so that the moving stability of the bearing plate 2 is improved.

Referring to fig. 2, 7 and 8, the lifting driving mechanism 7 includes a fixed rail 70, a supporting vertical plate 71 sliding along the length direction of the fixed rail 70 is slidingly connected to the fixed rail 70, a lifting plate 72 sliding up and down is connected to the supporting vertical plate 71, an adjusting and mounting box 73 with a cavity structure is mounted at the bottom of the lifting plate 72, a first sliding plate 74 is slidingly connected to two side walls of the adjusting and mounting box 73, an L-shaped clamping plate 75 is mounted at one end of the first sliding plate 74 far from the adjusting and mounting box 73, a second sliding plate 76 is slidingly connected to two side walls of the adjusting and mounting box 73 which are axially arranged along the rotating shaft 3, an inverted-u-shaped frame 77 is mounted at one end of the second sliding plate 76 far from the adjusting and mounting box 73, an inserting and supporting plate 78 is mounted at two vertical sections of the inverted-u-shaped frame 77, a clamping driving set 79 for driving the two first sliding plates 74 and the two second sliding plates 76 to synchronously move to clamp the receiving plate 2 is mounted in the adjusting and mounting box 73, and a limiting set of limiting the downward movement of the L-shaped clamping plate 75 is mounted on one fixed bracket 1.

Referring to fig. 7, the clamping driving set 79 includes a driving shaft 790 rotatably connected to the middle of the adjusting mounting box 73, driving gears 791 symmetrically arranged up and down are mounted on the driving shaft 790, racks are mounted on the first sliding plate 74 and the second sliding plate 76, two racks on the first sliding plate 74 are staggered, and are located on two sides of the driving gear 791 on the upper side and are engaged with the driving gear 791 for transmission, and two racks on the second sliding plate 76 are staggered, are located on two sides of the driving gear 791 on the lower side and are engaged with the driving gear 791 for transmission.

When the bearing plate 2 bearing the perforated bricks 8 moves to the lifting and unloading station, an external electric slide block connected with the lifting plate 72 drives the lifting plate 72, the adjusting and mounting box 73, the L-shaped clamping plate 75, the inverted U-shaped frame 77 and the inserting and supporting plate 78 to move downwards until the limiting group limits the movement of the L-shaped clamping plate 75, at the moment, the horizontal section of the L-shaped clamping plate 75 and the inserting and supporting plate 78 are all positioned below the bearing plate 2, then the driving rotating shaft 790 is driven to rotate by external electric work connected with the driving rotating shaft 790 and driving the driving rotating shaft 790 to rotate, the driving gear 791 drives the two L-shaped clamping plates 75 to move towards the bearing plate 2 through meshing with racks in the rotating process, the two inverted U-shaped frames 77 move towards the bearing plate 2 until the L-shaped clamping plate 75 and the inverted U-shaped frames 77 are tightly attached to the bearing plate 2, at the moment, the horizontal section of the L-shaped clamping plate 75 and the inserting and supporting plate 78 are all moved to the bottom of the bearing plate 2, the bottom of the bearing plate 2 is prevented from moving, the bearing plate 2 is prevented from falling down to the bearing plate 78 in the bearing plate 52 and being arranged in the lifting and supporting plate 2, and the bearing plate 78 is prevented from being arranged at the lifting and supporting plate 52 and unloading station in the process.

Referring to fig. 2 and 3, two ends of the fixing support 1 far away from the rotating shaft 3 are provided with a moving guiding group, the moving guiding group comprises a sector plate 10 installed on the fixing support 1 through a supporting bar, the arc side walls of the two sector plates 10 are located on opposite faces of the two sector plates 10, one side of the sector plate 10 close to a chain is provided with a complementary arc strip 11, and the two complementary arc strips 11 are located between two main chain wheels.

The bearing plate 2 is placed on the two sector plates 10, and then the bearing plate 2 is pushed to move towards the limit seat 51 of the inserting and placing work position, at the moment, the main stay bar 20 at the bottom of the bearing plate 2 is in rolling contact with the arc-shaped side wall of the sector plate 10 and the side wall of the supplementary arc strip 11 so as to guide the movement of the bearing plate 2, and the bearing plate 2 is convenient to enter between the two opposite side baffle plates 55, so that the convenience of movement and adjustment of the bearing plate 2 is improved.

Referring to fig. 2 and 7, the limiting set includes two fixing plates 780 mounted on one fixing support 1 and disposed along a length direction of the fixing plates 780, a limiting stop plate 782 is mounted on a top portion of each fixing plate 780 through a supporting column 781, a plug 783 is mounted on a top portion of each limiting stop plate 782, a waist-shaped sleeve 784 is mounted on each L-shaped clamping plate 75, each waist-shaped sleeve 784 is in plug-in fit with each plug-in column 783, each limiting stop plate 782 limits when each waist-shaped sleeve 784 moves downwards, each plug-in column 783 is inserted into each waist-shaped sleeve 784 when each L-shaped clamping plate 75 drives each waist-shaped sleeve 784 to move downwards until each waist-shaped sleeve 784 abuts against each limiting stop plate 782, each L-shaped clamping plate 75 is prevented from moving downwards, the whole working efficiency is affected, or the downward moving distance is too short, and accordingly the bearing of the bearing plate 2 cannot be carried out.

Referring to fig. 1, the bearing driving mechanism 6 includes a movable plate car 60, two sets of stepped counter bores 24 are provided at the top of the movable plate car 60, except that the depth of the stepped counter bores 24 on the movable plate car 60 is greater than the depth of the stepped counter bores 24 on the receiving plate 2, the rest structure and position distribution of the stepped counter bores 24 on each set of movable plate car 60 are identical to those of the stepped counter bores 24 on the receiving plate 2, rollers are mounted at the bottom of the movable plate car 60, and the stepped counter bores 24 on the movable plate car 60 are used for performing plug-in connection with the main stay bars 20/auxiliary stay bars 21 on the receiving plate 2 at the lowest side during stacking, so as to stably support the receiving plate 2.

During operation, the bearing plate 2 is pushed from between the end parts of the two fixed brackets 1 to the limiting seat 51 of the inserting station until the end part of the bearing plate 2 is abutted against the vertical section of the L-shaped abutment 50, the L-shaped abutment 50 and the extending limiting block 54 limit the bearing plate 2, and meanwhile, the placing position of the bearing plate 2 is positioned, so that the stability of the bearing plate 2 in the placing and moving process is improved, and the bearing plate 2 with the porous bricks 8 is conveniently inserted and stacked later.

The rotary shaft 3 is driven by an external driving motor to intermittently rotate, so that the main chain wheel and the chain are matched to drive the bearing plate 2 to move, when the bearing plate 2 moves to the porous brick 8 forming and blanking station, the porous brick 8 is placed on the bearing plate 2 through the existing porous brick forming equipment, then the bearing plate 2 continues to move, when the bearing plate 2 moves to the lifting and discharging station to intermittently stop, the lifting driving mechanism 7 clamps the bearing plate 2 and drives the bearing plate 2 to move to the bearing driving mechanism 6, and the bearing plate 2 bearing the porous brick 8 is piled up.

When the bearing plate 2 is piled up, the lifting driving mechanism 7 drives the lifted bearing plate 2 to move downwards, so that the main supporting rod 20 at the bottom of the lifted bearing plate 2 and the expansion surface plate 22 and the conical convex column 23 at the bottom of the auxiliary supporting rod 21 are inserted into the stepped counter bores 24 on the piled up bearing plate 2 on the bearing driving mechanism 6, the stepped counter bores 24 on the piled up bearing plate 2 on the bearing driving mechanism 6 bear the expansion surface plate 22 and the conical convex column 23 on the bottom of the bearing plate 2 which are placed downwards above the stepped counter bores, and the problem that the porous bricks 8 on the bearing plate 2 are damaged due to the fact that the middle of the bearing plate 2 is deformed and concave due to the weight factor of the porous bricks 8 at the top of the bearing plate 2, and the bearing driving mechanism 6 drives the piled up bearing plate 2 to move towards the existing drying kiln is avoided.

In the description of the present application, it should be understood that the terms "center", "longitudinal", "transverse", "length", "width", "thickness", "upper", "lower", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the description of the present application, it should also be noted that, unless explicitly specified and limited otherwise, the terms "disposed," "connected," "mounted," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

The embodiments of the present application are all preferred embodiments of the present application, and are not limited in scope by the present application, so that all equivalent changes according to the structure, shape and principle of the present application are covered in the scope of the present application.

Claims (9)

1. An environmental protection non-clay brick production conveyor, characterized by comprising:

the two fixing brackets (1) and the bearing plate (2) are rotationally connected with a rotating shaft (3), opposite surfaces of the two fixing brackets (1) are rotationally connected with a mounting shaft (4), the mounting shaft (4) is in transmission connection with the rotating shaft (3) through a main chain wheel, and two chains are jointly provided with a limiting bearing mechanism (5) for limiting the bearing plate (2) placed on the chains;

four main supporting rods (20) and a plurality of auxiliary supporting rods (21) which are arranged in a rectangular manner are rotatably arranged at the bottom of the bearing plate (2), the auxiliary supporting rods (21) are positioned between the four main supporting rods (20), a surface expanding disc (22) is arranged at the bottoms of the main supporting rods (20) and the auxiliary supporting rods (21), conical convex columns (23) are arranged at the bottoms of the surface expanding discs (22), stepped counter bores (24) which are in one-to-one correspondence with the positions of the main supporting rods (20) and the auxiliary supporting rods (21) are arranged at the top of the bearing plate (2), inclined surfaces matched with the conical convex columns (23) are arranged on the vertical sections of the lower sides of the stepped counter bores (24), and the stepped counter bores (24) are in plug-in fit with the surface expanding discs (22) and the conical convex columns (23);

the bearing driving mechanism (6) is arranged at one end of the two fixed brackets (1) close to the rotating shaft (3) and is used for supporting the bearing plates (2) bearing the porous bricks (8) so as to facilitate stacking of the plurality of bearing plates (2); one side of one fixed bracket (1) is provided with a hoisting driving mechanism (7), and the hoisting driving mechanism (7) is used for moving the bearing plate (2) bearing the porous bricks (8) from the chain to the bearing driving mechanism (6);

the limiting and bearing mechanism (5) comprises a plurality of groups of bearing groups, each group of bearing groups consists of an L-shaped bearing seat (50), a limiting seat (51) and a plurality of middle bearing plates (52), wherein the L-shaped bearing seats (50) and the limiting seat (51) are hinged to a chain, the limiting seats (51), the middle bearing plates (52) and the L-shaped bearing seats (50) are sequentially arranged along the direction from an installation shaft (4) to a rotating shaft (3) when being positioned above the chain, an accommodating groove (53) is formed in the limiting seat (51), an extending limiting block (54) is installed on the accommodating groove (53) through a supporting spring, one side, far away from the L-shaped bearing seat (50), of the top of the extending limiting block (54) is of an arc-shaped structure, side baffles (55) are installed on the L-shaped bearing seat (50) and the limiting seat (51), and one side, far away from the L-shaped bearing seat (50), of the side baffles (55) on the limiting seat (51) is of an arc-shaped structure.

2. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: hoist and mount actuating mechanism (7) including fixed rail (70), sliding connection has on fixed rail (70) along its length direction gliding support riser (71), be connected with on support riser (71) about gliding lifter plate (72), adjust mounting box (73) for cavity structure are installed to the bottom of lifter plate (72), adjust two lateral walls that mounting box (73) were arranged along fixed bolster (1) length direction and equal sliding connection have a sliding plate (74), L type splint (75) are installed to one end that adjusting mounting box (73) was kept away from to sliding plate (74), two lateral walls that adjusting mounting box (73) were arranged along rotation axis (3) axial equal sliding connection have No. two sliding plates (76), one end that adjusting mounting box (73) was kept away from to No. two sliding plates (76) is installed and is reversed U type frame (77), two vertical sections of reverse U type frame (77) are all installed and are inserted supporting plate (78), install in adjusting mounting box (73) and drive two No. one sliding plate (74) and two No. two sliding plates (76) and two synchronous removal plates (76) carry out clamping group (75) and carry out clamping type to carry out clamping and limiting group (75) on the fixed support (1) that carries out clamping and carries out clamping group downward.

3. An environmentally friendly non-clay brick production and conveying device according to claim 2, wherein: the clamping driving group (79) comprises a driving rotating shaft (790) which is rotationally connected to the middle part of the adjusting mounting box (73), driving gears (791) which are arranged symmetrically up and down are arranged on the driving rotating shaft (790), racks are arranged on the first sliding plate (74) and the second sliding plate (76), two racks on the first sliding plate (74) are staggered, are positioned on two sides of the driving gears (791) on the upper side and are in meshed transmission with the driving gears (791), and two racks on the second sliding plate (76) are staggered, are positioned on two sides of the driving gears (791) on the lower side and are in meshed transmission with the driving gears (791).

4. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: two the one end that rotation axis (3) was kept away from to fixed bolster (1) is installed jointly and is inserted and move the direction group, inserts and moves sector plate (10) that the direction group was installed through the support bar on fixed bolster (1), and the arc lateral wall of two sector plates (10) is located the opposite face of two sector plates (10), and supplementary arc strip (11) are all installed to one side that sector plate (10) is close to the chain, and two supplementary arc strips (11) all are located between two main chain wheel.

5. An environmentally friendly non-clay brick production and conveying device according to claim 2, wherein: the limiting group comprises two fixing plates (780) which are arranged on one fixing support (1) along the length direction of the fixing plates, limiting baffle plates (782) are arranged at the tops of the fixing plates (780) through supporting columns (781), inserting columns (783) are arranged at the tops of the limiting baffle plates (782), waist-shaped sleeves (784) are arranged on L-shaped clamping plates (75), the waist-shaped sleeves (784) are in inserting fit with the inserting columns (783), and the limiting baffle plates (782) limit the waist-shaped sleeves (784) when moving downwards.

6. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: a discharging hole (240) penetrating through the bearing plate (2), the main stay bar (20)/the auxiliary stay bar (21), the surface expansion disc (22) and the conical convex column (23) is formed in the stepped counter bore (24) at the top of the bearing plate (2).

7. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: the bearing driving mechanism (6) comprises a movable plate vehicle (60), two groups of stepped counter bores (24) are formed in the top of the movable plate vehicle (60), and other structures and position distribution of the stepped counter bores (24) on each group of movable plate vehicle (60) are identical to those of the stepped counter bores (24) on the bearing plate (2) except that the depth of the stepped counter bores (24) on the movable plate vehicle (60) is larger than that of the stepped counter bores (24) on the bearing plate (2).

8. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: the two fixing brackets (1) are provided with fixing frames (12), opposite faces of the two fixing frames (12) are rotationally connected with bearing shafts which are uniformly distributed, auxiliary chain wheels (13) are fixedly sleeved on the bearing shafts, and the auxiliary chain wheels (13) are in meshed transmission with the middle part of the upper horizontal section of the chain.

9. The environmentally friendly non-clay brick production and conveying device according to claim 1, wherein: the opposite surfaces of the two fixing brackets (1) are respectively provided with a protective cover (14) for isolating the horizontal section at the lower side of the chain.