CN114102835B - Automatic demolding device for autoclaved aerated concrete blocks and using method - Google Patents

Abstract

The invention relates to the technical field of autoclaved aerated concrete, in particular to an automatic demoulding device for autoclaved aerated concrete blocks and a using method thereof, wherein the automatic demoulding device comprises a rack, an aerated brick module, a demoulding device, a first conveyor belt and a second conveyor belt; the demoulding device and the first and second conveyor belts work in a matched manner, so that the device finishes the continuous demoulding process of the aerated brick module, the clamping device can clamp and demould the next aerated brick module without resetting, and the demoulding efficiency is improved; according to the aerated brick module, the side plate is provided with the hook groove, the buckle structure is arranged in the hook groove, the buckle structure is triggered through the separating hook to unlock the side plate and the mould, the work flow is simplified, the demoulding efficiency is improved, compared with the prior art, a plurality of driving assemblies are reduced, the demoulding operation can be completed only through the matching of a few driving assemblies, and the production cost of demoulding equipment is reduced.

Description

Automatic demolding device for autoclaved aerated concrete blocks and using method

Technical Field

The invention relates to the technical field of autoclaved aerated concrete, in particular to an automatic demoulding device for autoclaved aerated concrete blocks and a using method thereof.

Background

The aerated brick is an aerated concrete block produced by a high-temperature autoclaved equipment process. "aerated brick" is to be understood as a simplified or generic term. The range of products covered by the brick is a little larger, namely, the brick products produced by other various processes including autoclaving. In the production process of the aerated brick, after the aerated concrete is poured and statically stopped for forming, the whole mould needs to be lifted and turned over to complete demoulding.

The positioning mode adopted by the prior art is manual positioning or positioning by a positioning mechanism, the manual positioning is generally carried out by manually controlling the mold to move to an approximate position and then gradually finely adjusting, so that the mold filled with a finished blank can be lifted, turned over and demoulded. However, the staff fixes a position manually, and this trend can cause the location in the location not accurate enough, moreover great increase staff's work load, waste time and energy. The other positioning mode is positioning of a positioning mechanism, a driving assembly is generally adopted to drive the positioning mechanism, a clamping assembly of a conveying mold is locked, the driving assembly is controlled to release the clamping assembly after demolding is finished, energy is consumed due to the fact that the driving assembly is adopted to drive, and the driving assembly is used to enable the manufacturing cost of the device to be high.

The prior art adopts a carrying trolley clamp to get the inside mould that is equipped with the building block, then take it to the drawing of patterns point and use drive assembly to overturn and separate building block and mould, then the carrying trolley transports the mould to the mould recovery point again, a carrying trolley only can carry out the drawing of patterns to the module of an air entrainment brick once on the track, the carrying trolley need return the starting point after having carried out drawing of patterns once and can carry out the clamp of the module of next air entrainment brick and get and the drawing of patterns process, the efficiency of this kind of drawing of patterns mode is not high, the loaded down with trivial details more time waste of whole working process of drawing of patterns, the urgent need is improved.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides an automatic demoulding device for an autoclaved aerated concrete block and a using method thereof.

In order to achieve the purpose, the invention adopts the following technical scheme:

an automatic autoclaved aerated concrete block demoulding device comprises a rack, an aerated brick module, a demoulding device, a first conveyor belt and a second conveyor belt; the top of the frame is rotationally connected with the demoulding device through a motor;

the second conveyor belt and the first conveyor belt are respectively arranged on the left side and the right side of the demolding device;

the aerated brick module is transported on the first conveyor belt and the second conveyor belt; the aerated brick module comprises a mould and a side plate; the die is a cuboid shell, a detachable side plate is arranged on one long side face of the die, and clamping areas are fixedly arranged on the outer sides of two opposite short side faces of the die;

the demolding device comprises a rotating disc, a clamping arm and a telescopic cylinder; the two disc surfaces of the rotating disc are respectively and uniformly provided with four telescopic cylinders, the extending ends of the telescopic cylinders are vertically and fixedly provided with clamping arms, and the outward ends of the clamping arms are provided with rectangular clamping openings matched with clamping areas; a plurality of separating hooks and heightening pads are fixedly arranged on the conveying surface of the second conveying belt; and the side plate is provided with a hook groove matched with the separating hook.

The demoulding device provided by the invention is matched with the first conveying belt and the second conveying belt to work, so that the device can complete the continuous demoulding process of the aerated brick module, the clamping device can clamp and demould the next aerated brick module without resetting, and the demoulding efficiency is improved.

According to the aerated brick module, the hook groove is formed in the side plate, the buckle structure is arranged in the hook groove, the buckle structure is triggered through the separating hook to unlock the side plate and the mold, the side plate and the mold are automatically unlocked through the separating hook while the aerated brick module is transported and turned, the aerated brick module is transported, turned and unlocked through the second conveyor belt and the demolding device, the work flow is simplified, the demolding efficiency is improved, compared with the prior art, a plurality of driving assemblies are reduced, demolding work can be completed only through the cooperation of a few driving assemblies, and the production cost of demolding equipment is reduced.

The improvement is made on the basis of the embodiment: the horizontal height of the second conveyor belt is higher than that of the first conveyor belt.

The improvement is made on the basis of the embodiment: the middle part of the rotating disc is coaxially and fixedly provided with a rotating shaft, the rotating shaft is rotatably arranged between the two upright posts of the rack, and one end of the rotating shaft is fixedly connected with the output end of the motor.

The improvement is made on the basis of the embodiment: the separation hook and the heightening pad are arranged at a certain interval, and the heightening pad is used for bearing the die.

The improvement is made on the basis of the embodiment: and the second conveyor belt and the first conveyor belt both rotate anticlockwise.

The improvement is made on the basis of the embodiment: the speed of the second conveyor belt is greater than that of the first conveyor belt, and the second conveyor belt and the first conveyor belt are driven at a constant speed.

The use method of the automatic demoulding device for the autoclaved aerated concrete block comprises the following steps:

s1: starting a motor, starting the first conveyor belt and the second conveyor belt simultaneously, and transporting the aerated brick modules to the demoulding device along with the conveyor belts from right to left;

s2: when the aerated brick module moves to the position of the clamping opening and the clamping area, two telescopic cylinders corresponding to the clamping arms corresponding to the aerated brick module contract inwards, and the two clamping openings correspond to the clamping area of the aerated brick module at the leftmost end of the clamping conveyor belt;

s3: after clamping is finished, the motor rotates anticlockwise for 90 degrees to feed, meanwhile, the clamping arm clamping the aerated brick module rotates to the position right above the demoulding device, the aerated brick module is conveyed to the position right above the demoulding device, and meanwhile, the aerated brick module is turned over for 90 degrees, so that the side plate faces downwards; the speed of the second conveyor belt is higher, so that the separating hook is already inserted into the hook groove of the side plate in the process that the aerated brick module rotates to be right above the demoulding device;

s4: when the separating hook is inserted into the hook groove of the side plate, the buckle structure in the hook groove is triggered, the triggered buckle structure unlocks the side plate and the mold, and the separating hook separates the power-assisted side plate and the building block from the mold to complete demolding due to the fact that the mold is limited by the clamping arm to stop right above the demolding device;

s5: after the side plates and the building blocks are separated from the mold, the heightening pad moves to the position right below the mold, the two telescopic cylinders above the demolding device release the mold, the heightening pad bears the mold to move leftwards, and in the period of stopping of the demolding device, the two clamping arms at the rightmost end finish clamping the next aerated brick module;

s6: and repeating the process of S3-S5 to ensure that the device completes the continuous demoulding process of the aerated brick module.

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

1. the demoulding device provided by the invention is matched with the first conveying belt and the second conveying belt to work, so that the device can complete the continuous demoulding process of the aerated brick module, the clamping device can clamp and demould the next aerated brick module without resetting, and the demoulding efficiency is improved.

2. According to the aerated brick module, the side plate is provided with the hook groove, the buckle structure is arranged in the hook groove, the buckle structure is triggered through the separating hook to unlock the side plate and the mould, the aerated brick module is automatically unlocked through the separating hook while being transported and turned, the aerated brick module is transported, turned and unlocked through the second conveyor belt and the demoulding device, the working process is simplified, the demoulding efficiency is improved, a plurality of driving assemblies are reduced compared with the prior art, demoulding operation can be completed only through the cooperation of a few driving assemblies, and the production cost of demoulding equipment is reduced.

3. The rectangular clamping opening matched with parameters of the clamping area is formed in one end, facing outwards, of the clamping arm, the outermost end of the clamping opening is opened, the length of the clamping opening is longer than that of the clamping area, the applicability of the device can be improved within a certain range, when the distance between each aerated brick module generates deviation within a certain range, the clamping arm can still successfully clamp the aerated brick modules, the adaptability of the device is improved, manual positioning of the device is not needed, the working process is optimized, and the working efficiency of demolding is improved.

Drawings

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

Fig. 2 is a schematic view of the aerated brick module of the invention being transported along with a conveyor belt to a demoulding device.

Fig. 3 is a schematic diagram of the conveyor belt two-auxiliary demoulding device for demoulding an aerated brick module.

Fig. 4 is a schematic view showing the detailed structure of the ejector of the present invention.

Wherein: 1. a frame; 2. an aerated brick module; 3. a demolding device; 4. a first conveyor belt; 5. a second conveyor belt; 11. a motor; 21. a mold; 22. a side plate; 23. building blocks; 211. a clamping area; 221. a hook groove; 31. rotating the disc; 32. a clamp arm; 33. a rotating shaft; 34. a telescopic cylinder; 321. a clamping port; 51. a separation hook; 52. a heightening pad.

Detailed Description

Example 1: an automatic autoclaved aerated concrete block demoulding device comprises a rack 1, an aerated brick module 2, a demoulding device 3, a first conveyor belt 4 and a second conveyor belt 5; the top of the frame 1 is rotationally connected with the demolding device 3 through a motor 11, two sides of the frame 1 are respectively provided with an upright post, the demolding device 3 is rotationally arranged between the two upright posts, one upright post is provided with the motor 11, the output end of the motor 11 is connected with the demolding device 3, the demolding device 3 is driven to rotate through the motor 11, and the motor 11 is preferably a stepping motor which can be implemented, and rotates 90 degrees anticlockwise in each feeding;

the second conveyor belt 5 and the first conveyor belt 4 are respectively arranged on the left side and the right side of the demoulding device 3;

the aerated brick module 2 is transported on the first conveyor belt 4 and the second conveyor belt 5; the aerated brick module 2 comprises a mould 21 and a side plate 22; the mold 21 is a cuboid shell, a detachable side plate 22 is arranged on one long side surface of the mold 21, clamping areas 211 are fixedly arranged on the outer sides of two opposite short side surfaces of the mold 21, the clamping areas 211 are protruded cuboid bumps, the demolding device 3 overturns and moves the aerated brick module 2 through the clamping areas 211, and hook grooves 221 are formed in the side plate 22;

the demolding device 3 comprises a rotating disc 31, a clamping arm 32 and a telescopic cylinder 34; the two disc surfaces of the rotating disc 31 are respectively and uniformly provided with four telescopic cylinders 34, the extending ends of the telescopic cylinders 34 are vertically and fixedly provided with clamping arms 32, one outward ends of the clamping arms 32 are provided with rectangular clamping ports 321 which are matched with parameters of the clamping area 211, the outermost ends of the clamping ports 321 are opened, the length of each clamping port 321 is longer than that of the clamping area 211, the middle part of the rotating disc 31 is coaxially and fixedly provided with a rotating shaft 33, the rotating shaft 33 is rotatably arranged between two upright posts of the rack 1, and one end of the rotating shaft 33 is fixedly connected with the output end of the motor 11;

a plurality of separating hooks 51 matched with the hook grooves 221 and a heightening pad 52 used for supporting the mold 21 are fixedly arranged on the conveying surface of the second conveyor belt 5.

The horizontal height of the second conveyor belt 5 is higher than that of the first conveyor belt 4, the second conveyor belt 5 is horizontally arranged at the upper end of the demolding device 3, the first conveyor belt 4 is horizontally arranged at the right end of the demolding device 3, a plurality of separating hooks 51 and heightening pads 52 are fixedly arranged on the conveying surface of the second conveyor belt 5, the separating hooks 51 and the heightening pads 52 are arranged at certain intervals, and the set distance is matched with parameters of the demolding device 3 and the aerated brick module 2 and can be obtained through parameter calculation; the separation hook 51 is fitted to the shape of the hook groove 221 of the side plate 22, and the separation hook 51 can be inserted into the hook groove 221 and then apply a pushing force to the side plate 22; the heightening pad 52 is used for bearing the mold 21 separated from the side plate 22 and the building block 23; the aerated brick module 2 is transported to the demoulding device 3 from right to left along with the conveyor belt I4; the distance between each aerated brick module 2 is basically equal; the side plate 22 is located in the advancing direction of the aerated brick module 2.

In specific implementation, the motor 11 is started, the first conveyor belt 4 and the second conveyor belt 5 are started simultaneously, and the aerated brick modules 2 are conveyed to the demolding device 3 from right to left along with the first conveyor belt 4; the two telescopic cylinders 34 corresponding to the rightmost clamping arm 32 contract inwards, and the two clamping openings 321 correspond to the clamping areas 211 of the aerated brick module 2 at the leftmost end of the clamping conveyor belt I4; after clamping is finished, the motor 11 starts to rotate anticlockwise for 90 degrees to feed, meanwhile, the clamping arm 32 clamping the aerated brick module 2 rotates to be right above the demoulding device 3, the aerated brick module 2 is conveyed to be right above the demoulding device 3, and meanwhile, the aerated brick module 2 is turned over for 90 degrees, so that the side plate 22 faces downwards; due to the fact that the speed of the second conveyor belt 5 is high, in the process that the aerated brick module 2 rotates to the position right above the demoulding device 3, the separating hook 51 is already inserted into the hook groove 221 of the side plate 22; when the separating hook 51 is inserted into the hook groove 221 of the side plate 22, the snap structure in the hook groove 221 is triggered (the snap structure is not shown in the figures because the snap structure is the prior art), the triggered snap structure unlocks the side plate 22 and the mold 21, and the mold 21 is limited by the clamping arm 32 to stop right above the demolding device 3, so that the separating hook 51 separates the assisted side plate 22 and the building block 23 from the mold 21, and demolding is completed; when the side plate 22 and the building block 23 are separated from the mold 21, the heightening pad 52 moves to the position right below the mold 21, the two telescopic cylinders 34 above the demolding device 3 release the mold 21, the heightening pad 52 bears the mold 21 to move leftwards, and the two clamping arms 32 at the rightmost end finish clamping the next aerated brick module 2 in the period of stopping the demolding device 3; and repeating the process to ensure that the device finishes the continuous demoulding process of the aerated brick module 2.

Example 2: preferably, as an implementation mode, on the basis of the above embodiment, the second conveyor belt 5 and the first conveyor belt 4 both rotate counterclockwise, and the supporting component and the driving component thereof are omitted in the drawings because they are not in contact with the workpiece.

Example 3: based on the above embodiment, it is preferable as an implementation manner that the speed of the second conveyor belt 5 is greater than that of the first conveyor belt 4, both of which are driven by a constant speed, and a certain proportional relationship between the speeds of the two conveyors is 1.2-1.5:1.

example 4: the use method of the automatic demoulding device for the autoclaved aerated concrete block comprises the following steps:

s1: starting a motor 11, starting a first conveyor belt 4 and a second conveyor belt 5 at the same time, and transporting the aerated brick modules 2 from right to left to the demoulding device 3 along with the first conveyor belt 4;

s2: when the aerated brick module 2 moves to the position of the clamping opening 321 and the clamping area 211 to coincide, the two telescopic cylinders 34 corresponding to the clamping arms 32 corresponding to the aerated brick module 2 contract inwards, and the two clamping openings 321 correspond to the clamping area 211 for clamping the aerated brick module 2 at the leftmost end of the first conveyor belt 4;

s3: after clamping is finished, the motor 11 starts to rotate anticlockwise for 90 degrees to feed, meanwhile, the clamping arm 32 clamping the aerated brick module 2 rotates to be right above the demoulding device 3, the aerated brick module 2 is conveyed to be right above the demoulding device 3, and meanwhile, the aerated brick module 2 is turned over for 90 degrees, so that the side plate 22 faces downwards; due to the fact that the speed of the second conveyor belt 5 is high, the separating hooks 51 are already inserted into the hook grooves 221 of the side plates 22 in the process that the aerated brick module 2 rotates to be right above the demoulding device 3;

s4: when the separating hook 51 is inserted into the hook groove 221 of the side plate 22, the buckling structure in the hook groove 221 is triggered, the triggered buckling structure unlocks the side plate 22 and the mold 21, and the mold 21 is limited by the clamping arm 32 to stop right above the demolding device 3, so that the separating hook 51 separates the assisted side plate 22 and the building block 23 from the mold 21, and demolding is completed;

s5: after the side plate 22 and the building block 23 are separated from the mold 21, the heightening pad 52 moves to a position right below the mold 21, the two telescopic cylinders 34 above the demolding device 3 release the mold 21, the heightening pad 52 bears the mold 21 to move leftwards, and the two clamping arms 32 at the rightmost end finish clamping the next aerated brick module 2 in the period of time when the demolding device 3 stops;

s6: and repeating the process from S3 to S5 to ensure that the device completes the continuous demoulding process of the aerated brick module 2.

The above description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto. The substitution may be of partial structures, devices, method steps, or may be a complete solution. The technical solution and the inventive concept thereof according to the present invention should be equally replaced or changed within the protection scope of the present invention.

Claims (7)

1. An automatic autoclaved aerated concrete block demoulding device comprises a rack (1), an aerated brick module (2), a demoulding device (3), a first conveyor belt (4) and a second conveyor belt (5); the method is characterized in that: the top of the frame (1) is rotationally connected with the demoulding device (3) through a motor (11);

the second conveyor belt (5) and the first conveyor belt (4) are respectively arranged on the left side and the right side of the demoulding device (3);

the aerated brick module (2) is transported on the first conveyor belt (4) and the second conveyor belt (5); the aerated brick module (2) comprises a mould (21) and a side plate (22); the die (21) is a cuboid shell, one long side face of the die (21) is provided with a detachable side plate (22), and the outer sides of two opposite short side faces of the die (21) are fixedly provided with clamping areas (211);

the demolding device (3) comprises a rotating disc (31), a clamping arm (32) and a telescopic cylinder (34); the two disc surfaces of the rotating disc (31) are respectively and uniformly provided with four telescopic cylinders (34), the extending end of each telescopic cylinder (34) is vertically and fixedly provided with a clamping arm (32), and one outward end of each clamping arm (32) is provided with a rectangular clamping opening (321) suitable for the clamping area (211); a plurality of separating hooks (51) and heightening pads (52) are fixedly arranged on the conveying surface of the second conveyor belt (5); the side plate (22) is provided with a hook groove (221) matched with the separating hook (51).

2. The automatic demolding device for the autoclaved aerated concrete block as claimed in claim 1, wherein: the horizontal height of the second conveyor belt (5) is higher than that of the first conveyor belt (4).

3. The automatic demolding device for the autoclaved aerated concrete block as claimed in claim 2, wherein: the middle part of the rotating disc (31) is coaxially and fixedly provided with a rotating shaft (33), the rotating shaft (33) is rotatably arranged between two upright posts of the rack (1), and one end of the rotating shaft (33) is fixedly connected with the output end of the motor (11).

4. The automatic de-molding device for autoclaved aerated concrete blocks according to claim 3, characterized in that: the separating hook (51) and the heightening pad (52) are arranged at a certain distance, and the heightening pad (52) is used for receiving the die (21).

5. The automatic de-molding device for autoclaved aerated concrete blocks as claimed in claim 4, characterized in that: the second conveyor belt (5) and the first conveyor belt (4) both rotate anticlockwise.

6. The automatic autoclaved aerated concrete block demolding device according to claim 5, wherein: the speed of the second conveyor belt (5) is greater than that of the first conveyor belt (4), and the second conveyor belt and the first conveyor belt are driven at a constant speed.

7. The use method of the automatic autoclaved aerated concrete block demolding device as claimed in any one of claims 1 to 6 is characterized by comprising the following steps:

s1: starting a motor (11), starting the first conveyor belt (4) and the second conveyor belt (5) simultaneously, and transporting the aerated brick modules (2) to the demoulding device (3) from right to left along with the first conveyor belt (4);

s2: when the aerated brick module moves to the position overlapping of the clamping opening (321) and the clamping area (211), two telescopic cylinders (34) corresponding to the clamping arms (32) of the aerated brick module (2) contract inwards, and the two clamping openings (321) are corresponding to the clamping area (211) of the aerated brick module (2) at the leftmost end of the clamping conveyor belt I (4);

s3: after clamping is finished, the motor (11) starts to rotate anticlockwise for 90 degrees to feed, meanwhile, the clamping arm (32) clamping the aerated brick module (2) rotates to be right above the demoulding device (3), the aerated brick module (2) is conveyed to be right above the demoulding device (3), and meanwhile, the aerated brick module (2) is turned over for 90 degrees, so that the side plate (22) faces downwards; due to the fact that the speed of the second conveyor belt (5) is high, in the process that the aerated brick module (2) rotates to the position right above the demoulding device (3), the separating hook (51) is already inserted into the hook groove (221) of the side plate (22);

s4: when the separating hook (51) is inserted into the hook groove (221) of the side plate (22), the buckling structure in the hook groove (221) is triggered, the triggered buckling structure unlocks the side plate (22) and the mold (21), and the separating hook (51) separates the power-assisted side plate (22) and the building block (23) from the mold (21) to finish demolding as the mold (21) is limited by the clamping arm (32) to stop right above the demolding device (3);

s5: after the side plates (22) and the building blocks (23) are separated from the mold (21), the heightening pad (52) moves to the position right below the mold (21), two telescopic cylinders (34) above the demolding device (3) release the mold (21), the heightening pad (52) bears the mold (21) to move leftwards, and two clamping arms (32) at the rightmost end finish clamping the next aerated brick module (2) in the period of stopping the demolding device (3);

s6: and repeating the processes of S3-S5 to ensure that the device completes the continuous demoulding process of the aerated brick module (2).

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