CN112743665A

CN112743665A - Blank forming and cutting equipment for producing and processing perforated bricks

Info

Publication number: CN112743665A
Application number: CN202011457829.6A
Authority: CN
Inventors: 段远柏
Original assignee: Chongqing Jintano New Materials Technology Co ltd
Current assignee: Chongqing Jintano New Materials Technology Co ltd
Priority date: 2020-12-11
Filing date: 2020-12-11
Publication date: 2021-05-04

Abstract

The invention discloses a blank forming and cutting device for producing and processing porous bricks, which comprises a conveying mechanism, wherein the conveying mechanism is arranged on one side of the discharge end of a vacuum brick making machine, a supporting plate is movably arranged on a transmission belt of the conveying mechanism, a long-strip-shaped blank pressed and formed by the vacuum brick making machine is placed on the supporting plate, a blank cutting mechanism is arranged on the conveying mechanism, an automatic discharging mechanism is arranged at one end of the conveying mechanism, a blank cutting mechanism is arranged at the upper part of the conveying mechanism, the long-strip-shaped blank pressed and formed by the vacuum brick making machine is positioned and cut in the vertical direction by utilizing the blank cutting mechanism, the cut brick blank enters the automatic discharging mechanism under the driving action of the conveying mechanism, the discharging direction can be adjusted by the automatic discharging mechanism, the supporting plate and the brick blank are synchronously transferred to the next station, and the whole forming and cutting operation is automatically completed, simple structure, high degree of automation and high operating efficiency.

Description

Blank forming and cutting equipment for producing and processing perforated bricks

Technical Field

The invention relates to the technical field of production of perforated bricks, in particular to blank forming and cutting equipment for producing and processing the perforated bricks.

Background

The building blocks are necessary building materials for traditional buildings and are used for building walls or building structures. The early sintered clay bricks are gradually eliminated due to small volume, low strength and poor heat insulation effect, and are gradually replaced by heat insulation bricks, hollow bricks, perforated bricks and the like in urban buildings, the sintered perforated bricks are prepared by processing, forming and sintering clay, shale and the like serving as main raw materials, compared with solid bricks, the sintered perforated bricks can save a large amount of soil for land and brick burning fuel, reduce the transportation weight, reduce the labor intensity during brick making and building, accelerate the construction progress, reduce the dead weight of buildings, increase the number of building layers and reduce the manufacturing cost, the blank cutting part of the existing perforated brick production equipment is not ideal, more waste materials can be generated in the cutting process, the production cost is increased, the production efficiency can be reduced, the discharging direction is fixed, and the adjustment of the discharging direction cannot be carried out according to the use requirement, therefore, the problems are deeply researched, the method is used for generating the same.

Disclosure of Invention

The invention aims to solve the problems, designs a blank forming and cutting device for producing and processing perforated bricks, and solves the problems that in the prior art, the blank cutting part of the traditional perforated brick production device is not ideal, more waste materials are generated in the cutting process, the production cost is increased, the production efficiency is reduced, the discharging direction is fixed, and the discharging direction cannot be adjusted according to the use requirement.

The technical scheme of the invention for realizing the aim is as follows: a blank forming and cutting device for producing and processing porous bricks comprises a conveying mechanism, wherein the conveying mechanism is arranged on one side of the discharge end of a vacuum brick making machine, a supporting plate is movably arranged on a transmission belt of the conveying mechanism, a long-strip-shaped blank pressed and formed by the vacuum brick making machine is placed on the supporting plate, a blank cutting mechanism is arranged on the conveying mechanism, and an automatic discharging mechanism is arranged at one end of the conveying mechanism;

the blank cutting mechanism comprises: the device comprises a portal frame, a vertical adjusting structure, a pressure cutting structure and an auxiliary tool retracting structure, wherein the portal frame is arranged on a conveying mechanism, the vertical adjusting structure is arranged in the portal frame, the pressure cutting structure is arranged at the lower end of the vertical adjusting structure, and the auxiliary tool retracting structure is arranged on the outer side of the pressure cutting structure and is connected with the vertical adjusting structure;

the automatic discharging mechanism comprises: the rotary control structure is arranged on one side of the discharge end of the conveying mechanism, and the auxiliary material pushing structure is arranged on one end of the rotary control structure and is right opposite to the discharge end of the conveying mechanism.

The vertical adjustment structure includes: vertical pneumatic cylinder, sliding connection subassembly and movable plate, vertical pneumatic cylinder sets up on the crossbeam lower extreme terminal surface of door type frame, sliding connection subassembly symmetry sets up on the wall surface of door type frame internal side, the movable plate sets up on sliding connection subassembly and is connected with the piston end of vertical pneumatic cylinder.

The sliding connection assembly includes: the four guide rails are symmetrically arranged on the inner side wall surface of the door-shaped frame, and the four sliding blocks are respectively sleeved on the four guide rails in a sliding mode and connected with the side wall of the moving plate.

The pressure cutting structure includes: the cutting device comprises a plurality of first cutters and a plurality of second cutters, wherein the first cutters are sequentially arranged on the lower end face of a movable plate along the horizontal direction, the second cutters are respectively arranged between the first cutters, and the first cutters are arranged between the second cutters in a cross shape.

The auxiliary tool retracting structure comprises: the four compression springs are respectively arranged at the four corners of the lower end face of the movable plate, the four telescopic columns are respectively sleeved in the four compression springs and are fixedly connected with the movable plate, and the four contact plates are respectively arranged at the lower ends of the four compression springs and are connected with the telescopic columns.

The swing control structure includes: the automatic conveying device comprises a base, a box body, a drive control assembly and a rotary table, wherein the base is arranged on one side of a discharging end of the conveying mechanism, the box body is arranged on the base, the drive control assembly is arranged in the box body, one end of the drive control assembly extends out of the box body, and the rotary table is arranged on an exposed end of the drive control assembly.

The drive control assembly includes: servo motor, reduction gear, output shaft and rotation support piece, servo motor sets up in the box, the input of reduction gear is linked together with servo motor's output, the one end of output shaft is linked together with the output of reduction gear, the other end stretches out outside the box, and is connected with the revolving platform, rotation support piece sets up on the box, and is connected with the revolving platform.

The rotation support includes: the four arc-shaped movable blocks are sleeved on the annular slide rail in a sliding mode along the annular array and connected with the rotary table.

The supplementary material pushing assembly comprises: the rolling support piece is arranged on the rotary table, the fixing seat is arranged on the side wall of the rotary table, the material pushing cylinder is arranged on the fixing seat along the horizontal direction, and the push plate is arranged on the piston end of the material pushing cylinder.

The rolling support includes: the mounting grooves are arranged on the rotary table along the annular array, a plurality of ball-shaped grooves are formed in the mounting grooves, and a plurality of supporting balls are movably arranged in the ball-shaped grooves respectively.

The blank forming and cutting equipment for producing and processing the porous bricks, which is manufactured by the technical scheme of the invention, transfers the long-strip-shaped blanks pressed and formed by a vacuum brick making machine to a conveying mechanism, the upper part of the conveying mechanism is provided with a blank cutting mechanism, the blank cutting mechanism is used for positioning and cutting the long-strip-shaped blanks pressed and formed by the vacuum brick making machine in the vertical direction, the cut green bricks enter an automatic discharging mechanism under the driving action of the conveying mechanism, the discharging direction can be adjusted through the automatic discharging mechanism, a supporting plate and the green bricks are synchronously transferred to the next station, the whole forming and cutting operation is automatically completed, the structure is simple, the automation degree is high, the operation efficiency is high, the problems that in the prior art, the blank cutting part of the traditional porous brick production equipment is not ideal, more waste materials are generated in the cutting process, the production cost is increased, but also can reduce the production efficiency, and the direction of unloading is fixed simultaneously, can not adjust the problem of ejection of compact direction as required.

Drawings

Fig. 1 is a schematic structural view of a blank forming and cutting device for producing and processing a perforated brick according to the present invention.

Fig. 2 is a schematic top sectional structure view of the blank forming and cutting device for producing and processing the perforated brick of the present invention.

FIG. 3 is a schematic side view of the A-A position of the blank forming and cutting apparatus for manufacturing porous bricks according to the present invention.

Fig. 4 is a partially enlarged structural schematic view of a blank forming and cutting apparatus for manufacturing and processing perforated bricks according to the present invention shown in fig. 1.

Fig. 5 is a schematic structural diagram of a position a of the blank forming and cutting device for the production and processing of the perforated brick.

Fig. 6 is a schematic structural diagram of a position b of the blank forming and cutting device for the production and processing of the perforated brick.

Fig. 7 is a schematic structural diagram of a position c of the blank forming and cutting device for the production and processing of the perforated brick.

In the figure: 1-a transport mechanism; 2-a gantry; 3-a vertical hydraulic cylinder; 4, moving the plate; 5-a guide rail; 6-a slide block; 7-a first cutter; 8-a second cutter; 9-compression spring; 10-a telescopic column; 11-a contact plate; 12-a base; 13-a box body; 14-a turntable; 15-a servo motor; 16-a reducer; 17-an output shaft; 18-an annular slide rail; 19-an arc-shaped movable block; 20-a fixed seat; 21-a material pushing cylinder; 22-a push plate; 23-mounting grooves; 24-support ball.

Detailed Description

The present invention is described in detail below with reference to the accompanying drawings, as shown in fig. 1 to 7, by those skilled in the art, all electrical components in the present application are connected to their adapted power supplies through wires, and an appropriate controller should be selected according to actual conditions to meet control requirements, and specific connection and control sequence should be implemented by referring to the following working principle, in which the electrical connection between the electrical components is implemented in sequence, and the detailed connection means thereof is known in the art, and the following description mainly describes the working principle and process, and does not describe the electrical control.

Example (b): as can be seen from the attached figures 1-7 of the specification, the scheme comprises a conveying mechanism 1, wherein the conveying mechanism 1 is arranged on one side of the discharge end of a vacuum brick making machine, a supporting plate is movably arranged on a transmission belt of the conveying mechanism 1, a long-strip-shaped blank pressed and formed by the vacuum brick making machine is placed on the supporting plate, a blank cutting mechanism is arranged on the conveying mechanism 1, and an automatic discharging mechanism is arranged at one end of the conveying mechanism 1; the above-mentioned blank cutting mechanism includes: the gantry type frame 2 is arranged on the conveying mechanism 1, the vertical adjusting structure is arranged in the gantry type frame 2, the pressure cutting structure is arranged on the lower end of the vertical adjusting structure, and the auxiliary retracting structure is arranged on the outer side of the pressure cutting structure and connected with the vertical adjusting structure; above-mentioned automatic discharge mechanism includes: the rotary control structure is arranged on one side of the discharge end of the conveying mechanism 1, the auxiliary material pushing structure is arranged on one end of the rotary control structure and is opposite to the discharge end of the conveying mechanism 1, long-strip-shaped blanks pressed and formed by the vacuum brick making machine are transferred to the conveying mechanism 1, a blank cutting mechanism is arranged on the upper portion of the conveying mechanism 1, the long-strip-shaped blanks pressed and formed by the vacuum brick making machine are subjected to positioning cutting in the vertical direction by the blank cutting mechanism, the cut green bricks enter the automatic discharging mechanism under the driving action of the conveying mechanism 1, the discharging direction can be adjusted through the automatic discharging mechanism, the supporting plate and the green bricks are synchronously transferred to the next station, the whole forming and cutting operation is automatically completed, the structure is simple, the automation degree is high, and the operation efficiency is high.

As can be seen from the accompanying FIGS. 1-7, in the implementation process, the vertical adjustment structure comprises: vertical pneumatic cylinder 3, sliding connection subassembly and moving plate 4, vertical pneumatic cylinder 3 sets up on the terminal surface under the crossbeam of door type frame 2, and the sliding connection subassembly symmetry sets up on the wall surface of the interior side of door type frame 2, and moving plate 4 sets up on sliding connection subassembly, and is connected with the piston end of vertical pneumatic cylinder 3 mutually, and wherein sliding connection subassembly includes: four guide rails 5 and four sliders 6, four guide rails 5 symmetry set up on the inside wall face of door type frame 2, four sliders 6 slide respectively the suit on four guide rails 5, and be connected with the lateral wall of movable plate 4, above-mentioned pressure cutting structure includes: a plurality of first cutters 7 and a plurality of second cutters 8, a plurality of first cutters 7 set gradually on the lower terminal surface of movable plate 4 along the horizontal direction, and a plurality of second cutters 8 set up respectively between first cutters 7, and first cutters 7 are the cross between second cutters 8 and arrange, and wherein supplementary tool retracting structure includes: four compression springs 9, four telescopic columns 10 and four contact plates 11, wherein the four compression springs 9 are respectively arranged at four corners of the lower end surface of the movable plate 4, the four telescopic columns 10 are respectively sleeved in the four compression springs 9 and fixedly connected with the movable plate 4, the four contact plates 11 are respectively arranged at the lower ends of the four compression springs 9 and connected with the telescopic columns 10, when in use, a blank enters the lower part of the portal frame, the conveying mechanism 1 is controlled to stop feeding, the piston end of the vertical hydraulic cylinder 3 in the portal frame 2 is controlled to expand, the piston end of the vertical hydraulic cylinder 3 expands, and the movable plate 4 is further pushed to slide along the guide rail 5 under the connecting action of the sliding blocks 6 at two sides, so that the first cutter 7 and the second cutter 8 at the lower end of the movable block synchronously downwards cut the blank on the movable plate, and the contact plates 11 at the lower ends of the compression springs 9 at the four corners of the movable block 4 are attached to the, along with the movable plate 4 pushes down for compression spring 9 atress shrink protects the cutter, avoids knocking over the cutter, and after the cutting was accomplished, the piston end of control vertical pneumatic cylinder 3 contracts to lift the cutter, lift the in-process, compression spring 9 of cutter both sides upwards expands at the elastic force effect, thereby improves the efficiency that the cutter lifted.

As can be seen from fig. 1-2 and fig. 5 of the specification, in the implementation process, the rotation control structure includes: base 12, box 13, drive control subassembly and revolving platform 14, base 12 sets up in transport mechanism 1's discharge end one side, and box 13 sets up on base 12, and the drive control subassembly sets up in box 13, and outside box 13 was stretched out to one end, revolving platform 14 sets up on the exposure of drive control subassembly holds, and above-mentioned drive control subassembly includes: servo motor 15, reduction gear 16, output shaft 17 and rotation support piece, servo motor 15 sets up in box 13, and the input of reduction gear 16 is linked together with servo motor 15's output, and output shaft 17's one end is linked together with reduction gear 16's output, the other end stretches out outside box 13, and is connected with revolving platform 14, rotates support piece and sets up on box 13, and is connected with revolving platform 14, and above-mentioned rotation support piece includes: annular slide rail 18 and four arc movable blocks 19, annular slide rail 18 set up on box 13, and the suit in the output shaft 17 outside, and four arc movable blocks 19 slide the suit along annular array on annular slide rail 18, and be connected with revolving platform 14, and wherein supplementary material pushing component includes: roll support piece, fixing base 20, push away material cylinder 21 and push pedal 22, roll support piece sets up on revolving platform 14, and fixing base 20 sets up on the lateral wall of revolving platform 14, pushes away material cylinder 21 and sets up on fixing base 20 along the horizontal direction, and push pedal 22 sets up on the piston end that pushes away material cylinder 21, and above-mentioned roll support piece includes: a plurality of mounting grooves 23 and a plurality of supporting balls 24, the mounting grooves 23 are arranged on the rotary table 14 along an annular array, ball-shaped grooves are respectively arranged in the mounting grooves 23, the supporting balls 24 are respectively and movably arranged in the ball-shaped grooves, when in use, the cut green bricks are driven by the supporting plate to continuously advance on the conveying mechanism 1 and enter the rotary table 14, the supporting plate can smoothly slide onto the rotary table 14 under the supporting action of the supporting balls 24 in the mounting grooves 23 on the rotary table, the driving end of the servo motor 15 in the box body 13 can be controlled to rotate according to the actual discharging direction requirement, so as to drive the output shaft 17 on the output end of the speed reducer 16 to rotate, so that the rotary table 14 rotates by a required angle in the horizontal direction, and after rotating in place, the piston end of the pushing cylinder 21 on the fixing seat 20 is controlled to expand, so as to push the pushing plate 22, the supporting plate and the green bricks on the supporting plate are pushed out synchronously, and then automatic blanking operation is realized.

In conclusion, the blank forming and cutting equipment for producing and processing the porous bricks transfers the long-strip-shaped blanks pressed and formed by the vacuum brick making machine to the conveying mechanism 1, the blank cutting mechanism is arranged at the upper part of the conveying mechanism 1, the long-strip-shaped blanks pressed and formed by the vacuum brick making machine are positioned and cut in the vertical direction by utilizing the blank cutting mechanism, the cut green bricks enter the automatic discharging mechanism under the driving action of the conveying mechanism 1, the discharging direction can be adjusted through the automatic discharging mechanism, the supporting plate and the green bricks are synchronously transferred to the next station, the whole forming and cutting operation is automatically completed, the structure is simple, the automation degree is high, the operation efficiency is high, the problems that in the prior art, the blank cutting part of the traditional porous brick production equipment is not ideal, more waste materials can be generated in the cutting process, the production cost is increased, and the production efficiency is reduced are solved, meanwhile, the discharging direction is fixed, and the discharging direction can not be adjusted according to the use requirement.

The technical solutions described above only represent the preferred technical solutions of the present invention, and some possible modifications to some parts of the technical solutions by those skilled in the art all represent the principles of the present invention, and fall within the protection scope of the present invention.

Claims

1. The blank forming and cutting equipment for the production and processing of the porous bricks comprises a conveying mechanism (1), and is characterized in that the conveying mechanism (1) is arranged on one side of the discharge end of a vacuum brick making machine, a supporting plate is movably arranged on a transmission belt of the conveying mechanism (1), a long-strip-shaped blank pressed and formed by the vacuum brick making machine is placed on the supporting plate, a blank cutting mechanism is arranged on the conveying mechanism (1), and an automatic discharging mechanism is arranged at one end of the conveying mechanism (1);

the blank cutting mechanism comprises: the device comprises a portal frame (2), a vertical adjusting structure, a pressure cutting structure and an auxiliary tool retracting structure, wherein the portal frame (2) is arranged on a conveying mechanism (1), the vertical adjusting structure is arranged in the portal frame (2), the pressure cutting structure is arranged at the lower end of the vertical adjusting structure, and the auxiliary tool retracting structure is arranged on the outer side of the pressure cutting structure and is connected with the vertical adjusting structure;

the automatic discharging mechanism comprises: the device comprises a rotation control structure and an auxiliary material pushing structure, wherein the rotation control structure is arranged on one side of a discharging end of a conveying mechanism (1), and the auxiliary material pushing structure is arranged on one end of the rotation control structure and is just opposite to the discharging end of the conveying mechanism (1).

2. The apparatus of claim 1, wherein the vertical adjustment structure comprises: vertical pneumatic cylinder (3), sliding connection subassembly and movable plate (4), vertical pneumatic cylinder (3) set up on the crossbeam lower extreme terminal surface of door type frame (2), sliding connection subassembly symmetry sets up on door type frame (2) inside wall face, movable plate (4) set up on sliding connection subassembly and be connected with the piston end of vertical pneumatic cylinder (3).

3. A perforated brick making and processing blank forming and cutting apparatus as claimed in claim 2 wherein said slide connection assembly comprises: the four guide rails (5) and the four sliding blocks (6), the four guide rails (5) are symmetrically arranged on the inner side wall surface of the door-shaped frame (2), and the four sliding blocks (6) are respectively sleeved on the four guide rails (5) in a sliding mode and are connected with the side wall of the moving plate (4).

4. The apparatus of claim 3, wherein the press cutting structure comprises: the cutting device comprises a plurality of first cutters (7) and a plurality of second cutters (8), wherein the first cutters (7) are sequentially arranged on the lower end face of the movable plate (4) along the horizontal direction, the second cutters (8) are respectively arranged between the first cutters (7), and the first cutters (7) are arranged between the second cutters (8) in a cross mode.

5. The apparatus as claimed in claim 4, wherein the auxiliary retracting structure comprises: the four-point contact type movable plate comprises four compression springs (9), four telescopic columns (10) and four contact plates (11), wherein the four compression springs (9) are respectively arranged at four corners of the lower end face of the movable plate (4), the four telescopic columns (10) are respectively sleeved in the four compression springs (9) and fixedly connected with the movable plate (4), and the four contact plates (11) are respectively arranged at the lower ends of the four compression springs (9) and connected with the telescopic columns (10).

6. The apparatus as claimed in any one of claims 1 to 5, wherein the rotation control structure comprises: base (12), box (13), drive control subassembly and revolving platform (14), base (12) set up in transport mechanism (1) discharge end one side, box (13) set up on base (12), the drive control subassembly sets up in box (13), and outside one end stretches out box (13), revolving platform (14) set up on the end that exposes of drive control subassembly.

7. The apparatus of claim 6, wherein the drive control assembly comprises: servo motor (15), reduction gear (16), output shaft (17) and rotation support piece, servo motor (15) set up in box (13), the input of reduction gear (16) is linked together with servo motor (15)'s output, the one end of output shaft (17) is linked together with the output of reduction gear (16), the other end stretches out outside box (13), and is connected with revolving platform (14), rotation support piece sets up on box (13), and is connected with revolving platform (14).

8. A blank-forming cutting apparatus for use in the manufacture of perforated bricks according to claim 7 wherein said rotary support comprises: the rotary table comprises an annular slide rail (18) and four arc-shaped movable blocks (19), wherein the annular slide rail (18) is arranged on the box body (13) and sleeved on the outer side of the output shaft (17), and the four arc-shaped movable blocks (19) are sleeved on the annular slide rail (18) in a sliding mode along an annular array and connected with the rotary table (14).

9. The apparatus of claim 8, wherein the auxiliary pushing assembly comprises: roll support piece, fixing base (20), material pushing cylinder (21) and push pedal (22), roll support piece sets up on revolving platform (14), fixing base (20) set up on the lateral wall of revolving platform (14), material pushing cylinder (21) set up on fixing base (20) along the horizontal direction, push pedal (22) set up on the piston end of material pushing cylinder (21).

10. A blank-forming cutting apparatus for use in the manufacture of perforated bricks according to claim 9, wherein said rolling support comprises: the mounting structure comprises a plurality of mounting grooves (23) and a plurality of supporting balls (24), wherein the mounting grooves (23) are arranged on a rotary table (14) along an annular array, a plurality of spherical grooves are formed in the mounting grooves (23), and the supporting balls (24) are movably arranged in the spherical grooves respectively.