阅读说明：本技术 一种土木建筑智能成型设备 (Civil construction intelligence former ) 是由 王彩芹 于 2020-11-27 设计创作，主要内容包括：为解决上述技术问题,一种土木建筑智能成型设备,包括安装板、给料装置、动力传递装置、物料传送装置、脱模装置、挤压成型装置,通过给料装置持续的向上述提供需要加工的混合材料,动力传递装置提供设备工作时的动力,物料传送装置将需要成型的材料推到指定的位置,脱模装置和挤压成型装置将材料成型后并脱模等功能,其特征在于：给料装置安装固定在安装板上,动力传递装置安装固定在安装板上,物料传送装置安装固定在动力传递装置上,物料传送装置滑动安装在脱模装置上,脱模装置安装固定在安装板上,挤压成型装置安装固定在安装板上。(For solving above-mentioned technical problem, a building intelligent molding equipment, including mounting panel, feeder, power transmission device, material conveyer, shedder, extrusion device, last to provide the combined material that needs processing to the aforesaid through feeder, power transmission device provides the power of equipment during operation, and material conveyer pushes away the fashioned material that needs to the appointed position, and functions such as drawing of patterns after shedder and the extrusion device with the material shaping, its characterized in that: the feeding device is fixedly installed on the installation plate, the power transmission device is fixedly installed on the installation plate, the material conveying device is fixedly installed on the power transmission device, the material conveying device is slidably installed on the demolding device, the demolding device is fixedly installed on the installation plate, and the extrusion forming device is fixedly installed on the installation plate.)

1. The utility model provides a civil construction intelligence former, includes mounting panel (1), feeder (2), power transmission device (3), material conveyer (4), shedder (5), extrusion device (6), its characterized in that: the feeding device (2) is fixedly installed on the installation plate (1), the power transmission device (3) is fixedly installed on the installation plate (1), the material conveying device (4) is fixedly installed on the power transmission device (3), the material conveying device (4) is slidably installed on the demolding device (5), the demolding device (5) is fixedly installed on the installation plate (1), and the extrusion molding device (6) is fixedly installed on the installation plate (1).

2. The civil construction intelligent molding equipment of claim 1, wherein: the feeding device (2) comprises supporting legs (2-1) and discharge nozzles (2-2), wherein the supporting legs (2-1) are fixedly arranged on the mounting plate (1), and the discharge nozzles (2-2) are fixedly arranged on the supporting legs (2-1).

3. The civil construction intelligent molding equipment of claim 1, wherein: the power transmission device (3) comprises an installation frame (3-1), a sliding column (3-2), a sliding block (3-3), a fixed shaft (3-4), an installation rod (3-5), a driving shaft (3-6), an output belt wheel (3-7), a pushing sliding rod (3-8), a transmission belt (3-9), an installation seat (3-10), a transmission shaft (3-11), a receiving belt wheel (3-12), a gear (3-13), an installation seat I (3-14), a transmission shaft I (3-15), a transmission gear (3-16) and a gear I (3-17), wherein the sliding column (3-2) is slidably installed on the installation frame (3-1), and the sliding block (3-3) is slidably installed inside the sliding column (3-2), a fixed shaft (3-4) is fixedly arranged on a sliding block (3-3), a mounting rod (3-5) is fixedly arranged on a mounting plate (1), a driving shaft (3-6) is rotatably arranged on the mounting rod (3-5), an output belt wheel (3-7) is fixedly arranged on the driving shaft (3-6), a push sliding rod (3-8) is fixedly arranged on the driving shaft (3-6), a transmission belt (3-9) is arranged on the output belt wheel (3-7) and a receiving belt wheel (3-12), a mounting seat (3-10) is fixedly arranged on the mounting plate (1), a transmission shaft (3-11) is rotatably arranged on the mounting seat (3-10), the receiving belt wheel (3-12) is fixedly arranged on the transmission shaft (3-11), a gear (3-13) is fixedly arranged on the transmission shaft (3-11), the mounting base I (3-14) is fixedly arranged on the sliding column (3-2), the transmission shaft I (3-15) is rotatably arranged on the mounting base I (3-14), the transmission gear (3-16) is meshed with the gear (3-13), the transmission gear (3-16) is fixedly arranged on the transmission shaft I (3-15), and the gear I (3-17) is fixedly arranged on the transmission shaft I (3-15).

4. The civil construction intelligent molding equipment of claim 2, wherein: the material conveying device (4) comprises a mold box (4-1), a baffle (4-2), a connecting rod (4-3), a matched slotted hole (4-4), a fixing rod (4-5), a fixing plate (4-6), a spring (4-7), a movable rack plate (4-8), a rack top plate (4-9), a connecting plate I (4-10), a limiting rod (4-11) and a spring I (4-12), wherein the mold box (4-1) is fixedly arranged on the connecting rod (4-3), the baffle (4-2) is fixedly arranged on the mold box (4-1), the connecting rod (4-3) is fixedly arranged on a sliding column (3-2), the matched slotted hole (4-4) is arranged on the mold box (4-1), the fixing rod (4-5) is fixedly arranged inside the mold box (4-1), the fixed plate (4-6) is fixedly arranged on the fixed rod (4-5), the spring (4-7) is arranged inside the movable rack plate (4-8), the movable rack plate (4-8) is slidably arranged on the fixed plate (4-6), the rack top plate (4-9) is fixedly arranged on the connecting plate I (4-10), the connecting plate I (4-10) is slidably arranged on the limiting rod (4-11), the limiting rod (4-11) is fixedly arranged inside the die box (4-1), and the spring I (4-12) is sleeved on the limiting rod (4-11).

5. The civil construction intelligent molding equipment of claim 1, wherein: the demolding device (5) comprises a supporting plate (5-1), a matching groove plate (5-2), a limiting hole (5-3), a matching hole cylinder (5-4), a spring II (5-5), a sliding plate II (5-6), a connecting square column (5-7), a supporting plate (5-8), a spring III (5-9), a sliding plate II (5-10), a pushing rod II (5-11), a limiting inclined plane block (5-12) and a matching inclined plane groove (5-13), wherein the supporting plate (5-1) is fixedly arranged on the mounting plate (1), the matching groove plate (5-2) is fixedly arranged on the supporting plate (5-1), the limiting hole (5-3) is arranged on the matching groove plate (5-2), and the matching hole cylinder (5-4) is fixedly arranged on the mounting plate (1), the spring II (5-5) is installed inside the matching hole cylinder (5-4), the sliding plate II (5-6) is installed inside the matching hole cylinder (5-4) in a sliding mode, the connecting square column (5-7) is installed and fixed on the sliding plate II (5-6), the supporting plate (5-8) is installed and fixed on the connecting square column (5-7), the spring III (5-9) is installed inside the supporting plate (5-8), the sliding plate II (5-10) is installed inside the supporting plate (5-8) in a sliding mode, the pushing rod II (5-11) is installed and fixed on the sliding plate II (5-10), the limiting inclined plane block (5-12) is installed and fixed on the pushing rod II (5-11), and the matching inclined plane groove (5-13) is formed in the limiting inclined plane block (5-12).

6. The civil construction intelligent molding equipment of claim 1, wherein: the extrusion forming device (6) comprises a mounting frame II (6-1), a transmission shaft II (6-2), a belt wheel I (6-3), a transmission belt I (6-4), a receiving belt wheel (6-5), a reciprocating direction changing device (6-6), an output gear (6-7), a pushing gear (6-8), a fixed sliding block (6-9), a sliding rack (6-10), a connecting plate II (6-11), a pushing rod II (6-12), a transmission gear barrel (6-13), a transmission gear barrel I (6-14), a pushing gear plate I (6-15), a connecting plate II (6-16), a spring II (6-17) and an extrusion plate (6-18), wherein the mounting frame II (6-1) is fixedly arranged on the mounting plate (1), and the transmission shaft II (6-2) is rotatably arranged on the mounting frame II (6-1), a first belt wheel (6-3) is fixedly arranged on a second transmission shaft (6-2), a first transmission belt (6-4) is arranged on the first belt wheel (6-3) and a first receiving belt wheel (6-5), the first receiving belt wheel (6-5) is fixedly arranged on a reciprocating direction changing device (6-6), the reciprocating direction changing device (6-6) is fixedly arranged on a mounting plate (1), an output gear (6-7) is fixedly arranged on the reciprocating direction changing device (6-6), the output gear (6-7) is meshed with the first gear (3-17), a pushing gear (6-8) is fixedly arranged on the second transmission shaft (6-2), a fixed sliding block (6-9) is fixedly arranged on the second mounting frame (6-1), a sliding rack (6-10) is slidably arranged on the fixed sliding block (6-9), a second connecting plate (6-11) is fixedly arranged on a sliding rack (6-10), a second push rod (6-12) is fixedly arranged on the second connecting plate (6-11), a first transmission gear barrel (6-13) is rotatably arranged in the second push rod (6-12), a first transmission gear barrel (6-14) is respectively meshed with the first transmission gear barrel (6-13) and the first push toothed plate (6-15), the first push toothed plate (6-15) is fixedly arranged on the second connecting plate (6-16), the second connecting plate (6-16) is slidably arranged in the second push rod (6-12), a sixth spring (6-17) is fixedly arranged on the second connecting plate (6-16) and in the second push rod (6-12), the extrusion plates (6-18) are installed and fixed on the sliding racks (6-10).

7. The civil construction intelligent molding equipment of claim 2, wherein: and a feeding device is arranged at the upper end of a discharging nozzle (2-2) of the feeding device (2).

8. The civil construction intelligent molding equipment of claim 3, characterized in that: the driving shaft (3-6) of the power transmission device (3) is provided with a matched motor.

9. The civil construction intelligent molding equipment of claim 3, characterized in that: the reciprocating direction changing device (6-6) of the extrusion forming device (6) is a reciprocating direction changing device which is regulated and controlled and published on the market.

Technical Field

The invention relates to intelligent forming equipment, in particular to intelligent forming equipment for civil buildings.

Background

In recent years, civil engineering and construction own home is in great interest, but along with development, a large amount of construction waste is also generated, and the construction waste is specially treated and briquetted in order to reduce pollution caused by the waste and utilize energy as much as possible, so that the intelligent forming equipment for the civil construction is invented.

Disclosure of Invention

The invention relates to intelligent forming equipment for a civil construction, in particular to the intelligent forming equipment for the civil construction, which continuously provides mixed materials to be processed for the civil construction through a feeding device, provides power for the equipment during working through a power transmission device, pushes the materials to be formed to a specified position through a material conveying device, and has the functions of forming the materials and demoulding through a demoulding device and an extrusion forming device.

For solving above-mentioned technical problem, a building intelligent molding equipment, including mounting panel, feeder, power transmission device, material conveyer, shedder, extrusion device, last to provide the combined material that needs processing to the aforesaid through feeder, power transmission device provides the power of equipment during operation, and material conveyer pushes away the fashioned material that needs to the appointed position, and functions such as drawing of patterns after shedder and the extrusion device with the material shaping, its characterized in that: the feeding device is fixedly installed on the installation plate, the power transmission device is fixedly installed on the installation plate, the material conveying device is fixedly installed on the power transmission device, the material conveying device is slidably installed on the demolding device, the demolding device is fixedly installed on the installation plate, and the extrusion forming device is fixedly installed on the installation plate.

As a further optimization of the technical scheme, the feeding device of the intelligent civil building forming equipment comprises supporting legs and discharge nozzles, wherein the supporting legs are fixedly arranged on an installation plate, and the discharge nozzles are fixedly arranged on the supporting legs.

As a further optimization of the technical scheme, the power transmission device of the intelligent forming equipment for civil construction comprises a mounting frame, a sliding column, a sliding block, a fixed shaft, a mounting rod, a driving shaft, an output belt wheel, a pushing sliding rod, a transmission belt, a mounting seat, a transmission shaft, a receiving belt wheel, a gear, a mounting seat I, a transmission shaft I, a transmission gear and a gear I, wherein the sliding column is slidably mounted on the mounting frame, the sliding block is slidably mounted inside the sliding column, the fixed shaft is fixedly mounted on the sliding block, the mounting rod is fixedly mounted on the mounting plate, the driving shaft is rotatably mounted on the mounting rod, the output belt wheel is fixedly mounted on the driving shaft, the pushing sliding rod is fixedly mounted on the driving shaft, the transmission belt is mounted on the output belt wheel and the receiving belt wheel, the mounting seat is fixedly mounted on the mounting plate, the gear is fixedly installed on the transmission shaft, the first installation base is fixedly installed on the sliding column, the first transmission shaft is rotatably installed on the first installation base, the transmission gear is meshed with the gear, the transmission gear is fixedly installed on the first transmission shaft, and the first gear is fixedly installed on the first transmission shaft.

As a further optimization of the technical scheme, the material conveying device of the intelligent molding equipment for civil buildings comprises a mold box, a baffle, a connecting rod, a matching slotted hole, a fixing rod, a fixing plate, a spring, a movable rack plate, a rack top plate, a first connecting plate, a limiting rod and a first spring, wherein the mold box is fixedly installed on the connecting rod, the baffle is fixedly installed on the mold box, the connecting rod is fixedly installed on a sliding column, the matching slotted hole is formed in the mold box, the fixing rod is fixedly installed in the mold box, the fixing plate is fixedly installed on the fixing rod, the spring is arranged in the movable rack plate, the movable rack plate is slidably installed on the fixing plate, the rack top plate is fixedly installed on the first connecting plate, the first connecting plate is slidably installed on the limiting rod, the limiting rod is fixedly installed in the mold box, and the.

As a further optimization of the technical scheme, the demolding device comprises a supporting plate, a matching groove plate, a limiting hole, a matching hole cylinder, a spring II, a sliding plate II, a connecting square column, a supporting plate, a spring III, a sliding plate II, a pushing rod II, a limiting inclined plane block and a matching inclined plane groove, wherein the supporting plate is fixedly installed on a mounting plate, the matching groove plate is fixedly installed on the supporting plate, the limiting hole is formed in the matching groove plate, the matching hole cylinder is fixedly installed on the mounting plate, the spring II is installed in the matching hole cylinder, the sliding plate II is slidably installed in the matching hole cylinder, the connecting square column is fixedly installed on the sliding plate II, the supporting plate is fixedly installed on the connecting square column, the spring III is installed in the supporting plate, the sliding plate II is slidably installed in the supporting plate, the pushing rod II is fixedly installed on the sliding plate II, and the limiting inclined plane block is fixedly installed, the matching inclined plane groove is arranged on the limiting inclined plane block.

As a further optimization of the technical scheme, the extrusion molding device of the intelligent molding equipment for civil construction comprises a mounting frame II, a transmission shaft II, a belt wheel I, a transmission belt I, a receiving belt wheel, a reciprocating direction changing device, an output gear, a pushing gear, a fixed sliding block, a sliding rack, a connecting plate II, a pushing rod II, a transmission gear barrel I, a pushing toothed plate I, a connecting plate II, a spring VI and a squeezing plate, wherein the mounting frame II is fixedly arranged on the mounting plate, the transmission shaft II is rotatably arranged on the mounting frame II, the belt wheel I is fixedly arranged on the transmission shaft II, the transmission belt I is arranged on the belt wheel I and the receiving belt wheel, the receiving belt wheel is fixedly arranged on the reciprocating direction changing device, the reciprocating device is fixedly arranged on the mounting plate, the output gear is fixedly arranged on the reciprocating direction changing device, the output gear is meshed with, the fixed sliding block is fixedly installed on the second mounting frame, the sliding rack is slidably installed on the fixed sliding block, the second connecting plate is fixedly installed on the sliding rack, the second push rod is fixedly installed on the second connecting plate, the first transmission gear barrel is rotatably installed inside the second push rod, the first transmission gear barrel is respectively meshed with the first push gear plate, the first push gear plate is fixedly installed on the second connecting plate, the second connecting plate is slidably installed inside the second push rod, the six springs are fixedly installed on the second connecting plate and inside the second push rod, and the extrusion plate is fixedly installed on the sliding rack.

As a further optimization of the technical scheme, the feeding device is arranged at the upper end of the discharging nozzle of the feeding device of the intelligent civil construction forming equipment.

As a further optimization of the technical scheme, the driving shaft of the power transmission device of the intelligent civil construction molding equipment is provided with a matched motor.

As a further optimization of the technical scheme, the reciprocating direction changing device of the extrusion forming device of the intelligent civil construction forming equipment is a reciprocating direction changing device for regulating and controlling the direction of the civil construction.

The intelligent civil building forming equipment has the beneficial effects that:

the invention relates to intelligent forming equipment for a civil construction, in particular to intelligent forming equipment for the civil construction, which realizes the functions of continuously providing mixed materials to be processed for the civil construction through a feeding device, providing power for the equipment during working through a power transmission device, pushing the materials to be formed to a specified position through a material conveying device, forming the materials through a demoulding device and an extrusion forming device, demoulding and the like.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a third schematic view of the overall structure of the present invention.

Fig. 4 is a first structural schematic diagram of the feeding device of the present invention.

Fig. 5 is a schematic structural diagram of a feeding device of the present invention.

Fig. 6 is a third schematic structural diagram of the feeding device of the present invention.

Fig. 7 is a first structural schematic diagram of the power transmission device of the present invention.

Fig. 8 is a second schematic structural view of the power transmission device of the present invention.

Fig. 9 is a third schematic structural view of the power transmission device of the present invention.

Fig. 10 is a fourth schematic structural view of the power transmission device of the present invention.

Fig. 11 is a first structural diagram of the material conveying device according to the present invention.

Fig. 12 is a schematic structural diagram of a second material conveying device according to the present invention.

Fig. 13 is a third schematic structural view of the material conveying device of the present invention.

Fig. 14 is a schematic structural diagram of an extrusion molding apparatus according to the present invention.

FIG. 15 is a schematic view of the second embodiment of the extrusion molding apparatus of the present invention.

FIG. 16 is a third schematic view of the extrusion molding apparatus of the present invention.

Fig. 17 is a fourth schematic view of the extrusion molding apparatus of the present invention.

In the figure: a mounting plate 1; support legs 2-1; 2-2 of a discharge nozzle; a feeding device 2; a power transmission device 3; a mounting frame 3-1; a sliding column 3-2; 3-3 of a sliding block; 3-4 parts of a fixed shaft; 3-5 of a mounting rod; 3-6 parts of a driving shaft; an output belt wheel 3-7; pushing the sliding rod 3-8; 3-9 parts of a transmission belt; 3-10 of a mounting seat; 3-11 parts of a transmission shaft; receiving pulleys 3-12; 3-13 parts of gear; mounting seats I3-14; 3-15 parts of a first transmission shaft; transmission gears 3-16; 3-17 parts of a first gear; a material conveying device 4; a mold box 4-1; a baffle 4-2; 4-3 of a connecting rod; matching with the slotted hole 4-4; 4-5 of a fixed rod; fixing plates 4-6; 4-7 of a spring; moving the rack plate 4-8; 4-9 of a rack top plate; 4-10 of a first connecting plate; 4-11 parts of a limiting rod; 4-12 parts of a first spring; a demolding device 5; a support plate 5-1; matching with the groove plate 5-2; 5-3 of a limiting hole; 5-4 of a matching hole cylinder; 5-5 parts of a second spring; a second sliding plate 5-6; connecting the square columns 5-7; 5-8 of a supporting plate; 5-9 parts of a spring; 5-10 parts of a second sliding plate; 5-11 parts of a push rod II; 5-12 parts of a limiting inclined plane block; 5-13 of a matching inclined plane groove; an extrusion molding device 6; a second mounting frame 6-1; a second transmission shaft 6-2; a belt wheel I6-3 drives a belt I6-4; a receiving belt wheel 6-5; a reciprocating direction changing device 6-6; output gears 6-7; 6-8 parts of a pushing gear; 6-9 parts of a fixed slide block; 6-10 of a sliding rack; 6-11 parts of a second connecting plate; 6-12 parts of a second push rod; 6-13 parts of a transmission gear barrel; 6-14 parts of a transmission gear barrel I; 6-15 of a pushing toothed plate; 6-16 parts of a second connecting plate; six springs 6-17; and 6-18 of the pressing plate.

Detailed Description

The first embodiment is as follows:

in order to solve the above technical problems, an intelligent molding apparatus for civil construction includes a mounting plate 1, a feeding device 2, a power transmission device 3, a material conveying device 4, a demolding device 5, and an extrusion molding device 6, wherein the feeding device continuously provides a mixed material to be processed, the power transmission device provides power for the apparatus during operation, the material conveying device pushes the material to be molded to a specified position, and the demolding device and the extrusion molding device mold and demold the material, and is characterized in that: the feeding device 2 is fixedly installed on the mounting plate 1, the power transmission device 3 is fixedly installed on the mounting plate 1, the material conveying device 4 is fixedly installed on the power transmission device 3, the material conveying device 4 is slidably installed on the demolding device 5, the demolding device 5 is fixedly installed on the mounting plate 1, and the extrusion molding device 6 is fixedly installed on the mounting plate 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and the embodiment further describes the first embodiment, in which the feeding device 2 includes a support leg 2-1 and a discharge nozzle 2-2, the support leg 2-1 is fixed on a mounting plate 1, and the discharge nozzle 2-2 is fixed on the support leg 2-1.

The third concrete implementation mode:

the present embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and is further described in the present embodiment, where the power transmission device 3 includes a mounting frame 3-1, a sliding column 3-2, a sliding block 3-3, a fixed shaft 3-4, a mounting rod 3-5, a driving shaft 3-6, an output pulley 3-7, a pushing sliding rod 3-8, a driving belt 3-9, a mounting seat 3-10, a driving shaft 3-11, a receiving pulley 3-12, a gear 3-13, a mounting seat 3-14, a driving shaft 3-15, a driving gear 3-16, and a gear 3-17, and a feeding device is provided at an upper end of a discharging nozzle 2-2 of the device 2 and is capable of continuously discharging a material to be processed through the discharging nozzle 2-2, when the mold box 4-1 of the material conveying device 4 is positioned below the discharge nozzle 2-2, the mold box 4-1 receives the mixed material, then the driving shaft 3-6 of the power transmission device 3 drives the output belt wheel 3-7 and the sliding rod 3-8 to rotate, the output belt wheel 3-7 drives the receiving belt wheel 3-12 to rotate through the transmission belt 3-9, the receiving belt wheel 3-12 drives the gear 3-13 to rotate through the transmission shaft 3-11, the sliding rod 3-8 is pushed to be matched through the fixed shaft 3-4, and the sliding block 3-3 can slide in the sliding column 3-2, so that the sliding column 3-2 can move on the mounting frame 3-1 in a reciprocating manner, and the sliding column 3-2 can stop for a period of time when moving to the two ends of the mounting frame 3-1, when the mold box 4-1 is positioned below the discharging nozzle 2-2, the mold box 4-1 moves and enables the sliding column 3-2 to stay at one end of the mounting frame 3-1 and then stay at one end for a period of time so that sufficient materials can be added into the mold box 4-1, then the sliding column 3-2 drives the mold box 4-1 to slide forwards to push off a finished product formed on the demolding device 5, then the mold box reaches the other end to stop, at the moment, the sliding column 3-2 drives the transmission shaft I3-15 and the transmission gear 3-16 and the gear I3-17 on the transmission shaft I3-15 to move through the mounting seat I3-14 so that the transmission gear 3-16 is meshed with the gear 3-13, then the gear 3-13 drives the gear 3-13 to rotate, and drives the gear I3-17 to rotate through the transmission shaft, a sliding column 3-2 is slidably arranged on a mounting frame 3-1, a sliding block 3-3 is slidably arranged inside the sliding column 3-2, a fixed shaft 3-4 is fixedly arranged on the sliding block 3-3, a mounting rod 3-5 is fixedly arranged on the mounting plate 1, a driving shaft 3-6 is rotatably arranged on the mounting rod 3-5, an output belt wheel 3-7 is fixedly arranged on the driving shaft 3-6, a pushing sliding rod 3-8 is fixedly arranged on the driving shaft 3-6, a transmission belt 3-9 is arranged on the output belt wheel 3-7 and a receiving belt wheel 3-12, a mounting seat 3-10 is fixedly arranged on the mounting plate 1, a transmission shaft 3-11 is rotatably arranged on the mounting seat 3-10, the receiving belt wheel 3-12 is fixedly arranged on the transmission shaft 3-11, the gear 3-13 is fixedly arranged on the transmission shaft 3-11, the mounting seat I3-14 is fixedly arranged on the sliding column 3-2, the transmission shaft I3-15 is rotatably arranged on the mounting seat I3-14, the transmission gear 3-16 is meshed with the gear 3-13, the transmission gear 3-16 is fixedly arranged on the transmission shaft I3-15, and the gear I3-17 is fixedly arranged on the transmission shaft I3-15.

The fourth concrete implementation mode:

the second embodiment is further described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17. the second embodiment is further described, wherein the material conveying device 4 comprises a mold box 4-1, a baffle plate 4-2, a connecting rod 4-3, a matching slotted hole 4-4, a fixing rod 4-5, a fixing plate 4-6, a spring 4-7, a moving rack plate 4-8, a rack top plate 4-9, a connecting plate one 4-10, a limiting rod 4-11, a spring one 4-12, a protruding pushing toothed plate one 6-15 downwards pushes out the rack top plate 4-9, the rack top plate 4-9 compresses the spring one 4-12 through the connecting plate one 4-10, and the rack top plate 4-9 continues to firstly place the limiting inclined plane block 5-12 of the demolding device 5 in the matching slot 5-13 Pushing towards the center of a supporting plate 5-8 under the action, a mold box 4-1 is fixedly arranged on a connecting rod 4-3, a baffle plate 4-2 is fixedly arranged on the mold box 4-1, the connecting rod 4-3 is fixedly arranged on a sliding column 3-2, a matched slotted hole 4-4 is arranged on the mold box 4-1, a fixed rod 4-5 is fixedly arranged inside the mold box 4-1, a fixed plate 4-6 is fixedly arranged on the fixed rod 4-5, a spring 4-7 is arranged inside a movable rack plate 4-8, the movable rack plate 4-8 is slidably arranged on the fixed plate 4-6, a rack top plate 4-9 is fixedly arranged on a connecting plate 4-10, the connecting plate one 4-10 is slidably arranged on a limiting rod 4-11, and the limiting rod 4-11 is fixedly arranged inside the mold box 4-1, the first spring 4-12 is sleeved on the limiting rod 4-11.

The fifth concrete implementation mode:

referring to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, which further illustrates the first embodiment, the demolding device 5 includes a support plate 5-1, a matching groove plate 5-2, a limiting hole 5-3, a matching hole cylinder 5-4, a spring II 5-5, a sliding plate II 5-6, a connecting square column 5-7, a support plate 5-8, a spring III 5-9, a sliding plate II 5-10, a pushing rod II 5-11, a limiting bevel block 5-12, a matching bevel groove 5-13, and then the limiting bevel block 5-12 and the limiting hole 5-3 are separated, then the ejecting top plate rack 4-9 continues to push the support plate 5-8 downwards and the extrusion plate 6-18 and the support plate 5-8 do not act on the molded article with force, when the supporting plate 5-8 moves downwards, the supporting plate 5-8 pushes the sliding plate II 5-6 in the matching hole cylinder 5-4 through the connecting square column 5-7, the spring II 5-5 is compressed, and air in the matching hole cylinder 5-4 is pushed out, when the supporting plate 5-8 pushes the formed material to completely leak out of the die box 4-1, the supporting plate moves downwards by the distance of one end, then the pushing gear 6-8 of the extrusion forming device 6 moves rapidly in the direction under the action of the reciprocating direction changing device 6-6 and rapidly returns to the state, at the moment, the power transmission device 3 starts to pull the die box 4-1 to move back, the gear 3-13 and the transmission gear 3-16 are not meshed, the gear I3-17 is meshed with the output gear 6-7, and the extrusion forming device 6 stops working without power input, due to the matching hole cylinders 5-4, the speed of resetting the sliding plates 5-6, the connecting square columns 5-7 and the supporting plates 5-8 by the springs 5-5 is far less than the resetting speed of other devices, so that the resetting is proper, the die box 4-1 is reset after moving one end of the lower end of the discharging nozzle 2-2, then the die box 4-1 moves towards the lower part of the extrusion forming device 6, the process is repeated, the supporting plate 5-1 is fixedly arranged on the mounting plate 1, the matching groove plate 5-2 is fixedly arranged on the supporting plate 5-1, the limiting holes 5-3 are arranged on the matching groove plate 5-2, the matching hole cylinders 5-4 are fixedly arranged on the mounting plate 1, the springs 5-5 are arranged inside the matching hole cylinders 5-4, the sliding plates 5-6 are slidably arranged inside the matching hole cylinders 5-4, the connecting square column 5-7 is fixedly arranged on the sliding plate II 5-6, the supporting plate 5-8 is fixedly arranged on the connecting square column 5-7, the spring III 5-9 is arranged in the supporting plate 5-8, the sliding plate II 5-10 is slidably arranged in the supporting plate 5-8, the pushing rod II 5-11 is fixedly arranged on the sliding plate II 5-10, the limiting inclined plane block 5-12 is fixedly arranged on the pushing rod II 5-11, and the matched inclined plane groove 5-13 is arranged on the limiting inclined plane block 5-12.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, and the embodiment further describes the embodiment, where the extrusion molding device 6 includes a mounting frame two 6-1, a transmission shaft two 6-2, a pulley one 6-3, a transmission belt one 6-4, a receiving pulley 6-5, a reciprocating direction changing device 6-6, an output gear 6-7, a pushing gear 6-8, a fixed slider 6-9, a sliding rack 6-10, a connecting plate two 6-11, a pushing rod two 6-12, a transmission gear barrel 6-13, a transmission gear barrel one 6-14, a pushing gear plate one 6-15, a connecting plate two 6-16, a spring six 6-17, and a squeezing plate 6-18, the first gear 3-17 drives an output gear 6-7 of the extrusion forming device 6 to rotate, the output gear 6-7 drives a receiving belt wheel 6-5 to rotate in a reciprocating mode through a reciprocating direction changing device 6-6, the receiving belt wheel 6-5 drives a belt wheel 6-3 to rotate in a reciprocating mode through a movable belt I6-4, the belt wheel I6-3 drives a transmission shaft II 6-2 to rotate in a reciprocating mode, the transmission shaft II 6-2 drives a pushing gear 6-8 to rotate in a reciprocating mode, the extrusion forming device 6 starts to operate just when the position of a mold box 4-1 reaches the lower end of an extrusion plate 6-18, the pushing gear 6-8 pushes a sliding rack 6-10 to move downwards first, and the sliding rack 6-10 drives a connecting plate II 6-11, a pushing rod II 6-12, a transmission gear barrel 6-13, a driving gear barrel, The first transmission gear barrel 6-14, the first pushing toothed plate 6-15, the second connecting plate 6-16, the sixth spring 6-17 and the squeezing plate 6-18 move downwards, the squeezing plate 6-18 moving downwards firstly squeezes materials in the die box 4-1, the pushing rod 6-12 enters the matching slotted hole 4-4 after squeezing to a certain distance to push the moving rack plate 4-8 towards the inner side of the die box 4-1, then the moving rack plate 4-8 and the moving rack plate 4-8 are separated, the transmission gear barrel 6-13 is meshed with the inner wall of the matching slotted hole 4-4, the transmission gear barrel 6-13 drives the first pushing toothed plate 6-15 to move downwards rapidly through the first transmission gear barrel 6-14 along with the downward movement of the pushing rod 6-12 and the squeezing plate 6-18, and then the sixth spring 6-17 is compressed, so that the stroke of the push rod II 6-12 and the push toothed plate I6-15 is far larger than that of the extrusion plate 6-18, the mounting frame II 6-1 is fixedly arranged on the mounting plate 1, the transmission shaft II 6-2 is rotatably arranged on the mounting frame II 6-1, the belt wheel I6-3 is fixedly arranged on the transmission shaft II 6-2, the transmission belt I6-4 is arranged on the belt wheel I6-3 and the receiving belt wheel 6-5, the receiving belt wheel 6-5 is fixedly arranged on the reciprocating direction changing device 6-6, the reciprocating direction changing device 6-6 is fixedly arranged on the mounting plate 1, the output gear 6-7 is fixedly arranged on the reciprocating direction changing device 6-6, the output gear 6-7 is meshed with the gear I3-17, the push gear 6-8 is fixedly arranged on the transmission shaft II 6-2, the fixed sliding block 6-9 is fixedly arranged on the mounting frame II 6-1, the sliding rack 6-10 is slidably arranged on the fixed sliding block 6-9, the connecting plate II 6-11 is fixedly arranged on the sliding rack 6-10, the push rod II 6-12 is fixedly arranged on the connecting plate II 6-11, the transmission gear barrel 6-13 is rotatably arranged inside the push rod II 6-12, the transmission gear barrel I6-14 is respectively meshed with the transmission gear barrel 6-13 and the push gear plate I6-15, the push gear plate I6-15 is fixedly arranged on the connecting plate II 6-16, the connecting plate II 6-16 is slidably arranged inside the push rod II 6-12, and the spring six 6-17 is fixedly arranged on the connecting plate II 6-16 and inside the push rod II 6-12, the extrusion plates 6-18 are fixed on the sliding racks 6-10.

The seventh embodiment:

the present embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and the second embodiment is further described, in which a feeding device is provided at an upper end of the discharging nozzle 2-2 of the feeding device 2.

The specific implementation mode is eight:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and the second embodiment will be further described, in which the driving shafts 3 to 6 of the power transmission device 3 are provided with associated motors.

The specific implementation method nine:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, and 17, and the second embodiment will be further described, in which the direction changing device 6-6 of the extrusion molding device 6 is a commercially available adjustable reciprocating direction changing device.

The working principle of the invention is as follows:

the intelligent forming equipment for the civil construction has the working principle that whether the connection condition between the devices meets the requirements is checked before the intelligent forming equipment is used, firstly, a feeding device is arranged at the upper end of a discharging nozzle 2-2 of a feeding device 2 and can continuously discharge materials to be processed through the discharging nozzle 2-2, when a mould box 4-1 of a material conveying device 4 is positioned below the discharging nozzle 2-2, the mould box 4-1 receives mixed materials, then a driving shaft 3-6 of a power transmission device 3 drives an output belt wheel 3-7 and a sliding rod 3-8 to rotate, the output belt wheel 3-7 drives a receiving belt wheel 3-12 to rotate through a transmission belt 3-9, the receiving belt wheel 3-12 drives a gear 3-13 to rotate through a transmission shaft 3-11, and the sliding rod 3-8 is pushed to be matched through a fixed shaft 3-4, and the sliding block 3-3 can slide in the sliding column 3-2 to enable the sliding column 3-2 to move on the mounting frame 3-1 in a reciprocating manner and enable the sliding column 3-2 to stay for a period of time when moving to two ends of the mounting frame 3-1, when the die box 4-1 is positioned below the discharging nozzle 2-2, the sliding column 3-2 stays at one end of the mounting frame 3-1 and then stays at one end for a period of time to enable sufficient materials to be added into the die box 4-1, then the sliding column 3-2 drives the die box 4-1 to slide forwards to push off finished products formed on the demolding device 5, then the finished products reach the other end to stop, and at the moment, the sliding column 3-2 drives the transmission shaft one 3-15 and the transmission gear 3-16 and the gear one 3-17 on the transmission shaft one 3-15 to move through the mounting seat one 3-14, the transmission gears 3-16 are meshed with the gears 3-13, then the gears 3-13 drive the gears 3-13 to rotate, the transmission shafts 3-15 drive the gears 3-17 to rotate, the gears 3-17 drive the output gears 6-7 of the extrusion molding device 6 to rotate, the output gears 6-7 drive the receiving belt wheels 6-5 to rotate in a reciprocating manner through the reciprocating direction changing devices 6-6, the receiving belt wheels 6-5 drive the belt wheels 6-3 to rotate in a reciprocating manner through the moving belts 6-4, the belt wheels 6-3 drive the transmission shafts 6-2 to rotate in a reciprocating manner, the transmission shafts 6-2 drive the pushing gears 6-8 to rotate in a reciprocating manner, and the extrusion molding device 6 starts to operate just when the position of the mold box 4-1 reaches the lower end of the extrusion plates 6-18, the gear 6-8 is pushed to enable the sliding rack 6-10 to move downwards firstly, the sliding rack 6-10 drives the connecting plate II 6-11, the pushing rod II 6-12, the transmission gear barrel 6-13, the transmission gear barrel I6-14, the pushing toothed plate I6-15, the connecting plate II 6-16, the spring six 6-17 and the extrusion plate 6-18 to move downwards, the extrusion plate 6-18 moving downwards extrudes materials in the die box 4-1 firstly, after the materials are extruded to a certain distance, the pushing rod II 6-12 enters the matched slotted hole 4-4 to push the moving rack plate 4-8 towards the inner side of the die box 4-1, then the moving rack plate 4-8 and the moving rack plate 4-8 are separated, and the transmission gear barrel 6-13 is meshed with the inner wall of the matched slotted hole 4-4, with the downward movement of the pushing rods 6-12 and the extrusion plates 6-18, the transmission gear barrels 6-13 drive the pushing toothed plate I6-15 to rapidly move downwards through the transmission gear barrels 6-14 and then compress the springs six 6-17, so that the stroke of the pushing toothed plate I6-15 and the pushing toothed plate II 6-12 is far larger than that of the extrusion plates 6-18, then the extended pushing toothed plate I6-15 pushes the rack top plate 4-9 downwards, the rack top plate 4-9 compresses the springs I4-12 through the connecting plates I4-10, the rack top plate 4-9 continuously pushes the limiting inclined plane blocks 5-12 of the demoulding device 5 to the center of the supporting plate 5-8 under the action of the matching inclined plane grooves 5-13, and then the limiting inclined plane blocks 5-12 are separated from the limiting holes 5-3, then the ejection rack top plate 4-9 continues to push the supporting plate 5-8 downwards, the extrusion plate 6-18 and the supporting plate 5-8 do not act on the formed object under the action of force, the supporting plate 5-8 pushes the sliding plate two 5-6 in the matching hole cylinder 5-4 through the connecting square column 5-7 in the downward movement process of the supporting plate 5-8, the spring two 5-5 is compressed, and air in the matching hole cylinder 5-4 is pushed out, when the supporting plate 5-8 pushes the formed material to completely leak out of the mold box 4-1 and moves downwards for a certain distance at one end, then the pushing gear 6-8 of the extrusion forming device 6 moves in the rapid direction under the action of the reciprocating direction changing device 6-6 and rapidly restores to the state, and then the power transmission device 3 starts to pull the mold box 4-1 to move back, the gears 3-13 and the transmission gears 3-16 are not meshed, the gears 3-17 are meshed with the output gears 6-7, the extrusion forming device 6 stops working without power input, the speed of resetting the sliding plate 5-6, the connecting square column 5-7 and the supporting plate 5-8 through the spring second 5-5 is far lower than the resetting speed of other devices due to the matching hole cylinder 5-4, the mould box 4-1 is reset after moving one end of the lower end of the discharging nozzle 2-2, and then the mould box 4-1 moves towards the lower part of the extrusion forming device 6 to repeat the process.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.