阅读说明：本技术 一种预制式商用混凝土构件成型装置 (Commercial concrete member forming device of prefabricated formula ) 是由 张婕妤 宋广伟 李汉宇 孟坤 于 2021-09-29 设计创作，主要内容包括：本发明公开了一种预制式商用混凝土构件成型装置,属于建筑材料技术领域。本发明包括三组传输带,三组所述传输带上设置有识别电路和振捣机构,三组传输带的一边设置有混凝土浇注机构,三组传输带下方设置有传输带支架和阻尼减震器,所述识别电路对模具的型号进行识别,混凝土浇注机构往模具内填充混凝土,振捣机构使混凝土内的气泡排出,本发明对不同型号模具进行识别以及生产装置无法进行多样化生产,利用虹吸原理对混凝土进行搅拌,使混凝土的质以及浇注密度地更加均匀,使用多个振捣棒同时工作,提高混凝土构件的强度,提高工作效率,节省振捣时间,使用橡胶囊的弹性与非牛顿流体的物理性质对传输带进行减震,达到缓冲吸振的作用。(The invention discloses a prefabricated commercial concrete member forming device, and belongs to the technical field of building materials. The invention comprises three groups of transmission belts, wherein the three groups of transmission belts are provided with an identification circuit and a vibrating mechanism, one side of each group of transmission belts is provided with a concrete pouring mechanism, a transmission belt bracket and a damping shock absorber are arranged below the three groups of transmission belts, the identification circuit identifies the model of the mould, the concrete pouring mechanism fills the concrete into the mould, and the vibrating mechanism discharges air bubbles in the concrete.)

1. The utility model provides a commercial concrete member forming device of prefabricated formula which characterized in that: including three groups of transmission bands, three groups be provided with identification circuit and vibration mechanism on the transmission band, one side of three groups of transmission bands is provided with concrete placement mechanism, and three groups of transmission bands below are provided with transmission band support (1) and damping bumper shock absorber, identification circuit discerns the model of mould, and concrete placement mechanism fills the concrete toward the mould, and the mechanism that vibrates makes the bubble in the concrete discharge.

2. The apparatus as claimed in claim 1, wherein: the three groups the transmission band includes first transmission band (201), install on transmission band support (1) first transmission band (201), the identification circuit includes conductive roller (3), conductive roller (3) set up the middle part at first transmission band (201), and conductive roller (3) department is provided with silk support (5) to the top of first transmission band (201) correspondence, it has conductive wire (4), every to gather on silk support (5) the one end and the contact of conductive roller (3) of conductive wire (4), every conductive wire (4) and conductive roller (3) form a circuit, every the circuit is connected with control system.

3. A prefabricated commercial concrete member forming apparatus as claimed in claim 2, wherein: the three groups of the conveying belts comprise second conveying belts (202), the second conveying belts (202) are arranged on conveying belt supports (1), the concrete pouring mechanism comprises a stirring barrel (6), a stirring assembly and a pouring assembly, the stirring barrel (6) is arranged on one side of the second conveying belts (202), the stirring assembly is arranged in the stirring barrel (6), and the pouring assembly is arranged outside the stirring barrel (6).

4. A prefabricated commercial concrete member forming apparatus as claimed in claim 3, wherein: the stirring assembly comprises a water pump (10), the water pump (10) is installed at the top of the stirring barrel (6), a water pumping pipe (111) is installed at the position of a water pump opening of the water pump (10), a water discharging pipe (112) is installed at the position of a water discharging opening of the water pump (10), and a siphon pipe (113) is connected to the middle of the water discharging pipe (112).

5. A prefabricated commercial concrete member forming apparatus as claimed in claim 3, wherein: the pouring assembly comprises a pouring nozzle (7), the pouring nozzle (7) is arranged at a position close to the bottom in the outer side of the stirring barrel (6), a rotary brake core (8) is installed in the pouring nozzle (7) in a rotating mode, a servo motor (9) is arranged on the outer side of the pouring nozzle (7), the servo motor (9) is connected with the rotary brake core (8) in a shaft mode, the servo motor (9) is connected with a control system, and the servo motor (9) drives the rotary brake core (8) to rotate to block a mouth of the pouring nozzle.

6. A prefabricated commercial concrete member forming apparatus as claimed in claim 2, wherein: the transmission band still includes third transmission band (203), third transmission band (203) below is provided with four at least group damping shock absorbers, the mechanism that vibrates includes curb plate (12), the excellent subassembly that vibrates and crank assembly, curb plate (12) set up the one side in third transmission band (203), crank assembly sets up on curb plate (12), be equipped with the dead slot on curb plate (12), the excellent subassembly that vibrates slides in the dead slot, crank assembly adjusts the position of the excellent subassembly that vibrates on curb plate (12), the bubble in the excellent subassembly discharge concrete that vibrates.

7. The apparatus as claimed in claim 6, wherein: the vibrating rod assembly comprises a bottom plate (13), a groove plate (16) and a groove plate motor (17), wherein the bottom plate (13) is slidably mounted on a side plate (12), a vibrating rod (15) is fixedly mounted below the bottom plate (13), at least one sliding groove is formed in the bottom plate (13), a sliding block (14) is arranged in each sliding groove, a vibrating rod is mounted below the sliding block (14), a protruding short column is arranged above the sliding block (14), the groove plate (16) is rotatably mounted on the bottom plate (13), a groove is formed in the groove plate (16), the protruding short column is embedded into the groove, the groove plate motor (17) is mounted on the bottom plate (13), the groove plate motor (17) is connected with the groove plate (16) through a shaft, and the groove plate motor (17) is connected with a control system circuit.

8. A prefabricated commercial concrete element forming apparatus as claimed in claim 7, wherein: the crank mechanism comprises a crank motor (20) and a connecting rod (19), the crank motor (20) is installed on the side plate (12), the crank motor (20) is connected with a control system circuit, a crank (18) is connected with the crank motor (20) through a shaft, one end of the connecting rod (19) is rotatably connected with the crank (18), and the other end of the connecting rod (19) is rotatably connected with the bottom plate (13).

9. The apparatus as claimed in claim 6, wherein: the damping bumper shock absorber includes pneumatic cylinder (21), rubber bag (22), the cylinder body of pneumatic cylinder (21) is installed on the support, and the piston rod and third transmission band (203) of pneumatic cylinder (21) are connected, rubber bag (22) are installed in the cylinder body bottom, and rubber bag (22) and pneumatic cylinder (21) intercommunication fill non-Newton's fluid in pneumatic cylinder (21).

Technical Field

The invention relates to the technical field of building materials, in particular to a prefabricated commercial concrete member forming device.

Background

The prefabricated concrete member is a common material in modern building construction, the concrete members used in different construction environments are different, the factors for distinguishing the concrete members in different grades comprise surface quality and strength, and the concrete member prefabricating device used at home and abroad at present has some problems.

For example, the model of the precast concrete member produced by one set of device is single, and diversified production of the concrete member cannot be realized; after concrete is kept still, stones can be deposited downwards, and the uppermost layer is slurried, so that no matter the concrete is properly stirred in the concrete transportation or use process, the existing concrete stirring device mostly adopts a flat-layer paddle board to stir the concrete, the stones deposited at the bottom cannot be turned to the upper layer, and the consistency of the successively poured concrete members cannot be ensured; the cast concrete member has air bubbles or cavities, the air bubbles or cavities become weak points of the concrete member and affect the strength of the member, the air bubbles must be discharged by using a vibrating device, the operation is often manually completed, and the production efficiency is reduced.

Disclosure of Invention

The present invention is directed to a prefabricated commercial concrete member forming device to solve the above problems.

In order to solve the technical problems, the invention provides the following technical scheme:

the utility model provides a commercial concrete member forming device of prefabricated formula, includes three groups of transmission bands, three groups be provided with identification circuit and vibration mechanism on the transmission band, one side of three groups of transmission bands is provided with concrete placement mechanism, and three groups of transmission band below are provided with transmission band support and damping bumper shock absorber, identification circuit discerns the model of mould, and concrete placement mechanism fills the concrete toward the mould, and the vibration mechanism makes the bubble in the concrete discharge.

Further, three groups the transmission band includes first transmission band, first transmission band installs on the transmission band support, identification circuit includes conductive roller, conductive roller sets up at the middle part in first transmission band, and the top in first transmission band corresponds conductive roller department and is provided with the silk support, it has conductive wire, every to gather on the silk support conductive wire's one end and conductive roller contact, every conductive wire and conductive roller form a circuit, every the circuit is connected with control system.

The conductive wires are hung on the conductive wire support, the conductive wires are not in contact with each other, the concrete mold flows through the first conveying belt and penetrates through the curtain formed by the conductive wires, the conductive wires are jacked up by the mold and are separated from the contact with the conductive rollers, the circuit is blocked, the conductive wires fall down after passing through the curtain of the conductive wires and are in contact with the conductive rollers again, the circuit is switched on, the control system judges the outline shape of the mold by analyzing the on-off condition and the interval time of the circuit of each conductive wire, the more dense the conductive wires are, the more accurate the analysis result of the control system is, the mold model information is provided for the subsequent pouring and vibrating links, the identification of different models of molds is realized by utilizing the on-off condition of the circuit, and the problem that a production device cannot carry out diversified production is solved.

Further, three groups the transmission band includes the second transmission band, the second transmission band sets up on the transmission band support, concrete placement mechanism includes agitator, stirring subassembly and pouring subassembly, the agitator sets up in one side of second transmission band, is provided with infrared sensor on the second transmission band, the stirring subassembly sets up in the agitator, the pouring subassembly sets up outside the agitator, and infrared sensor is connected with control system, and infrared sensor detects the mould and flows through, stops the second transmission band, toward the interior pouring concrete of mould.

Further, the stirring subassembly includes the water pump, the water pump is installed at the top of agitator, and the pump outlet department of water pump installs the drinking-water pipe, and the drain outlet department of water pump installs the drain pipe, the middle part of drain pipe is connected with the siphon.

The stone can down deposit can appear in the concrete after stewing, the phenomenon of the pulp of the superiors, so no matter all need carry out appropriate stirring with the concrete in concrete transportation or use, the drinking-water pipe stretches down and becomes the pulp layer in to the agitator, pulp layer mobility is better, the water pump inhales the concrete on pulp layer and discharges from the drain pipe, the lower extreme of siphon extends to the position of stone deposit, the velocity of flow on siphon and the drainage pipe connection department pulp layer is fast, form local negative pressure, up-suction bottom sedimentary stone, make the cement of stone and pulp mix fast, rethread drain pipe discharge, utilize the siphon principle to stir the concrete, make the texture of concrete more even, pouring density keeps unanimous, also improve the problem of concrete layering simultaneously.

Further, the pouring subassembly includes the pouring nozzle, the pouring nozzle sets up the position that is close to the bottom in the outside of agitator, and pouring nozzle internal rotation installs the rotary brake core, and the outside of pouring nozzle is provided with servo motor, servo motor and rotary brake spindle connection, servo motor and control system are connected, servo motor drives the rotary brake core and rotates the mouth of pouring nozzle and carry out the shutoff, and the mould volume of every model is different, and control system utilizes identification circuit's recognition result, controls servo motor, and servo motor drives the rotation of rotary brake core, adjusts the degree of opening of pouring nozzle, realizes the control to concrete pouring flow.

Further, three groups the transmission band still includes the third transmission band, third transmission band below is provided with four at least group damping shock absorbers, is provided with infrared sensor on the third transmission band, infrared sensor detects the mould that flows through, makes the third transmission band stop, vibrates the concrete in the mould, the mechanism that vibrates includes the curb plate, vibrates excellent subassembly and crank assembly, the curb plate sets up the one side at the third transmission band, crank assembly sets up on the curb plate, be equipped with the dead slot on the curb plate, vibrate excellent subassembly and slide in the dead slot, crank assembly adjusts the position of vibrating excellent subassembly on the curb plate, vibrate the bubble in the excellent subassembly discharge concrete.

Further, the vibrating rod assembly comprises a bottom plate, a groove plate and a groove plate motor, the bottom plate is slidably mounted on the side plate, a vibrating rod is fixedly mounted below the bottom plate, at least one sliding groove and each sliding block are formed in the bottom plate, a vibrating rod is mounted below each sliding block, a protruding short column is arranged above each sliding block, the groove plate is rotatably mounted on the bottom plate, a groove is formed in the groove plate, the protruding short columns are embedded into the grooves, the groove plate motor is mounted on the bottom plate and connected with the groove plate shaft, and the groove plate motor is connected with a control system circuit.

The vibrating rod extends into a concrete mould, cavities or bubbles in the concrete are discharged by utilizing high-frequency vibration, preset steel bars exist in the mould of the concrete member, the shapes of mould steel bar preset pieces of different models are different, the vibrating rod cannot contact the steel bars and the mould in the vibrating process by utilizing the vibrating rod, otherwise, the preset steel bar displacement is caused, and the pouring quality is influenced; the frid motor drives the recess board and rotates, and the short column on the slider is stirred to the recess on the recess board, promotes the slider and drives the stick that shakes and remove, and control system utilizes identification circuit to judge the information control frid motor that obtains to the mould model and rotates, and mould and reinforcing bar are avoided touchhing in the position of the stick that shakes in the adjustment, and a plurality of stick simultaneous workings that shake improve work efficiency, save the time of vibrating, and the bubble in the discharge concrete improves the intensity of concrete member.

Further, crank mechanism includes crank motor, connecting rod, crank motor installs on the curb plate, crank motor and control system circuit connection, and crank motor shaft is connected with the crank, the one end and the crank rotation of connecting rod are connected, and the other end and the bottom plate of connecting rod rotate to be connected, and the speed should be suitably blockked when the vibrating rod inserts the concrete, and the speed should be slow when extracting the concrete, and crank, connecting rod and bottom plate constitute slider-crank mechanism for the time that the vibrating rod inserted the concrete utilizes the scram characteristic of non-centering slider-crank mechanism, realizes the process of vibrating.

Furthermore, the damping shock absorber comprises a hydraulic cylinder and a rubber bag, wherein a cylinder body of the hydraulic cylinder is arranged on a support, a piston rod of the hydraulic cylinder is connected with a third transmission belt, the rubber bag is arranged at the bottom of the cylinder body and is communicated with the hydraulic cylinder, the hydraulic cylinder is filled with non-Newtonian fluid to enable the third transmission belt to absorb shock, the damping shock absorber arranged below the third transmission belt absorbs shock by using the elasticity of the rubber bag and the physical properties of the non-Newtonian fluid, the flowability of the non-Newtonian fluid is deteriorated when the non-Newtonian fluid meets external force, the impact or the vibration received by the third transmission is transmitted to the piston rod, the non-Newtonian fluid in the cylinder body is extruded by the piston rod to enter the rubber bag, the rubber bag generates certain elastic deformation, the non-Newtonian fluid is slowly extruded back into the cylinder body when the rubber bag is restored to the original state, the effect of buffering and shock absorption is achieved, and the damping effect of the rubber bag is enhanced along with the enlargement of the impact vibration, avoid the influence of vibration mechanism to whole device, the concrete mould is at the transmission course after the pouring, and the vibration can lead to the concrete deposit, and the damping bumper shock absorber falls to minimumly with the concrete influence in the mould.

Compared with the prior art, the invention has the following beneficial effects:

the on-off of the circuit is utilized to realize the identification of different models of moulds and the diversification of production devices; the concrete is stirred by the siphon principle in production, and stones deposited at the bottom are sucked upwards, so that the stones and pulpy cement are quickly mixed, the texture of the concrete is more uniform, the pouring density is kept consistent, and the problem of concrete layering is solved; the plurality of vibrating rods work simultaneously to discharge air bubbles in the concrete, so that the strength of the concrete member is improved, the working efficiency is improved, and the vibrating time is saved; the elasticity of the rubber bag and the physical property of the non-Newtonian fluid are used for damping the transmission belt, so that the effects of buffering and absorbing vibration are achieved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention. In the drawings:

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

fig. 2 is a schematic diagram of a third transmission chain according to the present invention;

fig. 3 is an exploded view of the construction of the tamper mechanism of the present invention;

fig. 4 is an exploded view of the construction of the tamper mechanism of the present invention;

FIG. 5 is a schematic view of the internal structure of the mixing tank of the present invention;

FIG. 6 is a schematic view of the internal structure of the pouring gate of the present invention;

FIG. 7 is a schematic structural diagram of a damping cylinder according to the present invention;

in the figure: 1. a conveyor belt support; 201. a first conveyor belt; 202. a second conveyor belt; 203. a third conveyor belt; 3. a conductive roller; 4. a conductive filament; 5. a wire support; 6. a stirring barrel; 7. a pouring nozzle; 8. a brake core is rotated; 9. a servo motor; 10. a water pump; 111. a water pumping pipe; 112. a drain pipe; 113. a siphon tube; 12. a side plate; 13. a base plate; 14. a slider; 15. vibrating a tamper; 16. a groove plate; 17. a slot plate motor; 18. a crank; 19. a connecting rod; 20. a crank motor; 21. a hydraulic cylinder; 22. a rubber bag.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the present invention provides the following technical solutions:

the utility model provides a commercial concrete member forming device of prefabricated formula, including three groups of transmission bands, be provided with identification circuit and vibration mechanism on three groups of transmission bands, one side of three groups of transmission bands is provided with concrete pouring mechanism, three groups of transmission bands include first transmission band 201, second transmission band 202, third transmission band 203, first transmission band 201 is installed on transmission band support 1 with second transmission band 202, third transmission band 203 below is provided with four groups of damping shock absorbers, identification circuit discerns the model of mould, concrete pouring mechanism packs the concrete toward the mould, vibration mechanism makes the bubble in the concrete discharge.

The identification circuit comprises conductive rollers 3, the conductive rollers 3 are arranged in the middle of a first transmission belt 201, an electric wire support 5 is arranged above the first transmission belt 201 corresponding to the conductive rollers 3, conductive wires 4 are densely distributed on the electric wire support 5, one end of each conductive wire 4 is in contact with the conductive rollers 3, each conductive wire 4 and the conductive rollers 3 form a circuit, each circuit is connected with a control system, the conductive wires 4 are hung on the electric wire support 5 and are not in contact with each other, a concrete mold flows through a curtain formed by the conductive wires 4 from the first transmission belt 201, the conductive wires 4 are jacked up by the mold, the conductive wires 4 are separated from the contact with the conductive rollers 3, the circuit is interrupted, the concrete mold falls down after passing through the curtain of the conductive wires 4 and is in contact with the conductive rollers 3 again, the circuit is switched on, and the control system analyzes the on-off condition and the interval time of the circuit formed by each conductive wire 4 and the conductive rollers 3, the more dense the conductive wires 4 are, the more accurate the analysis result of the control system is, the more accurate the contour shape of the mold is judged, the mold model information is provided for the subsequent mold pouring and vibrating links, and the diversified production of the production device is realized.

The concrete pouring mechanism comprises a stirring barrel 6, a stirring component and a pouring component, wherein the stirring barrel 6 is arranged on one side of a second conveying belt 202, an infrared sensor (not shown) is arranged on the second conveying belt 202, the stirring component is arranged in the stirring barrel 6, the pouring component is arranged outside the stirring barrel 6 and comprises a water pump 10, the water pump 10 is arranged at the top of the stirring barrel 6, a water pumping pipe 111 is arranged at a water pumping hole of the water pump 10, a water draining pipe 112 is arranged at a water draining hole of the water pump 10, a siphon pipe 113 is connected to the middle part of the water draining pipe 112, the pouring component comprises a pouring nozzle 7, the pouring nozzle 7 is arranged at a position close to the bottom outside of the stirring barrel 6, stones can be deposited downwards after the concrete is placed still, the phenomenon of upmost layer slurrying occurs, no matter the concrete needs to be properly stirred in the concrete transportation or use process, the water pumping pipe 111 extends downwards into the stirring barrel 6 to form a slurrying layer, the slurry layer has good fluidity, the water pump 10 sucks the concrete in the slurry layer and discharges the concrete from the drain pipe 112, the lower end of the siphon 113 extends to the position of stone deposition, the flow speed of the slurry layer at the joint of the siphon 113 and the drain pipe 112 is high, local negative pressure is formed, the stone deposited at the bottom is sucked upwards, the stone and the cement in the slurry layer are quickly mixed and then discharged through the drain pipe 112, the concrete is stirred by utilizing the siphon principle, the texture of the concrete is more uniform, the pouring density is kept consistent, meanwhile, the problem of concrete layering is also solved, the rotary brake core 8 is rotatably arranged inside the pouring nozzle 7, the servo motor 9 is arranged on the outer side of the pouring nozzle 7, the servo motor 9 is connected with the rotary brake core 8 through a shaft, the servo motor 9 drives the rotary brake core 8 to rotate to seal the opening of the pouring nozzle 7, the volumes of moulds of different models are different, the control system controls the servo motor 9 by utilizing the identification result of the identification circuit, the servo motor 9 drives the rotary brake core 8 to rotate, the opening degree of the pouring nozzle 7 is adjusted, and the control of the concrete pouring flow is realized.

The vibrating mechanism comprises a side plate 12, a vibrating rod assembly and a crank assembly, wherein the side plate 12 is arranged on one side of a third conveying belt 203, an infrared sensor (not shown) is arranged on the third conveying belt 203, the crank assembly is arranged on the side plate 12, a hollow groove is formed in the side plate 12, the vibrating rod assembly slides in the hollow groove, the crank assembly adjusts the position of the vibrating rod assembly on the side plate 12, the vibrating rod assembly discharges bubbles in concrete, the vibrating rod assembly comprises a bottom plate 13, a groove plate 16 and a groove plate motor 17, the bottom plate 13 is slidably arranged on the side plate 12, a vibrating rod 15 is fixedly arranged below the bottom plate 13, at least one sliding groove is formed in the bottom plate 13, a sliding block 14 is arranged in each sliding groove, a vibrating rod 15 is arranged below the sliding block 14, a protruding short column is arranged above the sliding block 14, the groove plate 16 is rotatably arranged on the bottom plate 13, a groove is formed in the groove plate 16, the protruding short column is embedded into the groove, the groove plate motor 17 is installed on the bottom plate 13, the groove plate motor 17 is connected with the groove plate 16 through a shaft, the groove plate motor 17 is connected with a control system circuit, the vibrating rod 15 extends into a concrete mold, cavities or bubbles in the concrete are discharged through high-frequency vibration, preset steel bars exist in the mold of a concrete member, the shapes of mold steel bar preset pieces of different types are different, in the vibrating process of using the vibrating rod 15, the vibrating rod 15 cannot contact the steel bars and the mold, otherwise, the preset steel bar displacement is caused, and the pouring quality is influenced; the groove plate motor 17 drives the groove plate 16 to rotate, the groove in the groove plate 16 stirs the short column in the sliding block 14 to push the sliding block 14 to drive the vibrating rod 15 to move, the control system utilizes the information obtained by judging the model of the mould by the identification circuit to control the groove plate motor 17 to rotate, the position of the vibrating rod 15 is adjusted to avoid touching the mould and the reinforcing steel bars, the plurality of vibrating rods 15 work simultaneously, the working efficiency is improved, the vibrating time is saved, air bubbles in concrete are discharged, and the strength of concrete components is improved;

the crank mechanism comprises a crank motor 20 and a connecting rod 19, the crank motor 20 is installed on the side plate 12, the crank motor 20 is in circuit connection with the control system, a crank 18 is connected with the crank motor 20 in a shaft mode, one end of the connecting rod 19 is in rotary connection with the crank 18, the other end of the connecting rod 19 is in rotary connection with the bottom plate 13, the speed of the vibrating rod 15 when the vibrating rod 15 is inserted into concrete is proper, the speed of the vibrating rod 15 when the concrete is pulled out is proper to be slow, the crank 18, the connecting rod 19 and the bottom plate 13 form a crank slider mechanism, and the time of the vibrating rod 15 when the concrete is inserted into the vibrating rod is shortened by utilizing the quick return characteristic of the non-centering crank slider mechanism, so that the vibrating process is achieved.

The damping shock absorber comprises a hydraulic cylinder 21 and a rubber bag 22, wherein the cylinder body of the hydraulic cylinder 21 is arranged on a support, a piston rod of the hydraulic cylinder 21 is connected with a third transmission belt 203, the rubber bag 22 is arranged at the bottom of the cylinder body, the rubber bag 22 is communicated with the hydraulic cylinder 21, the hydraulic cylinder 21 is filled with non-Newtonian fluid to enable the third transmission belt 203 to absorb shock, the damping shock absorber arranged below the third transmission belt 203 absorbs shock by using the elasticity of the rubber bag 22 and the physical properties of the non-Newtonian fluid, the flowability of the non-Newtonian fluid is poor when external force is applied, the third transmission belt 203 transmits the received shock or vibration to the piston rod, the non-Newtonian fluid in the cylinder body is extruded by the piston rod to enter the rubber bag 22, the rubber bag 22 generates certain elastic deformation, the non-Newtonian fluid is slowly extruded back into the cylinder body when the rubber bag 22 recovers to the original shape, the effect of buffering and shock absorption is achieved, the damping effect of the rubber bag 22 is enhanced along with the increase of the shock vibration, avoid the influence of vibration mechanism to whole device, the concrete mould is at the transmission course after the pouring, and the vibration can lead to the concrete deposit, and the damping bumper shock absorber falls to minimumly with the concrete influence in the mould.

The working principle of the invention is as follows:

when the device starts to work, the concrete member mould is conveyed along the first conveying belt 201, the conductive wires 4 on the conductive wire support 5 are all contacted with the conductive rollers 3, a circuit formed by each conductive wire 4 and the conductive rollers 3 is in a connection state, when the concrete mould passes through a curtain formed by the conductive wires 4, the conductive wires 4 in the outline range of the mould are jacked up, the conductive wires 4 are separated from the contact with the conductive rollers 3, the circuit of the conductive wires 4 is disconnected, when the mould flows through the curtain formed by the conductive wires 4, the conductive wires 4 sequentially fall down to be contacted with the conductive rollers 3, the circuit of the conductive wires 4 is reconnected, and the control system generates the outline shape of the mould by analyzing the circuit connection and disconnection condition and the short-circuit time of each conductive wire 4, judges the model of the mould which flows currently and preprocesses the next pouring and vibrating link.

The water pump 10 on the stirring barrel 6 is periodically started to stir the concrete in the stirring barrel 6, the water pumping pipe 111 extends downwards into the stirring barrel 6 to form a concrete slurried layer, the concrete slurried layer has good fluidity, the water pump 10 sucks the concrete in the slurried layer through the water pumping pipe 111 and discharges the concrete from the water discharging pipe 112, the lower end of the siphon pipe 113 extends to the position where stones are deposited, the flow speed of the slurried layer at the joint of the siphon pipe 113 and the water discharging pipe 112 is high to form local negative pressure, the stones deposited at the bottom are sucked upwards to enable the stones to be quickly mixed with the slurried cement, then the stones are discharged through the water discharging pipe 112, and the concrete is stirred through the siphon principle;

install infrared sensor on second transmission band 202, the mould passes through infrared sensor when flowing along second transmission band 202, the ray of infrared sensor transmission is blockked by the mould, infrared ray can not be received to the infrared sensor receiving terminal, the pouring position has been reachd to the mould, control system stops second transmission band 202, control system starts servo motor 9 and drives the commentaries on classics brake core 8 and rotates, open pouring nozzle 7, the concrete is poured the mould through pouring nozzle 7, time through controlling commentaries on classics brake core 8 and opening, calculate the flow of concrete placement, satisfy the volume of this mould model.

After pouring, the control system controls the second conveyor belt 202 to continue to operate, an infrared sensor is installed on the third conveyor belt 203, when a mold flows along the third conveyor belt 203, the mold passes through the infrared sensor, rays emitted by the infrared sensor are blocked by the mold, infrared rays cannot be received by a receiving end of the infrared sensor, the mold reaches a vibrating position, the control system stops the third conveyor belt 203, the shape and the position of a steel bar preset in the mold are obtained according to the model of the mold, when the position of the vibrating bar 15 needs to be adjusted, the control system controls the groove plate motor 17 to drive the groove plate 16 to rotate, the groove on the groove plate 16 stirs the short column on the sliding block 14, the sliding block 14 is pushed to drive the vibrating bar 15 to move, the position of the vibrating bar 15 is adjusted, the mold and the preset steel bar are prevented from being touched, the crank 18, the connecting rod 19 and the bottom plate 13 form a crank sliding block mechanism, the control system drives the crank 18 to rotate by using the crank motor 20, the crank 18 drives the bottom plate 13 to slide up and down by using the connecting rod 19, and the time for inserting the vibrating rod 15 into the concrete is shortened by using the quick return characteristic of the non-centering crank slide block mechanism, so that the uniform slow speed is kept when the vibrating rod 15 extracts the concrete, and air bubbles or cavities in the concrete are discharged out of the concrete. After the vibrating process is finished, the control system starts the third conveyor 203 to convey the mold, and a precast concrete component is prepared.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the invention. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.