CN114888927A - Forming equipment for producing autoclaved lightweight aerated concrete blocks - Google Patents

Abstract

The invention discloses forming equipment for producing autoclaved lightweight aerated concrete blocks, and relates to the field of concrete processing. When the building block is discharged, the motor drives the insertion rod to rotate in the upper module, the insertion rod drives the rotating fan blades to rotate through the plurality of groups of magnets on the inner wall, the rotating fan blades drive air to flow in the upper module, so that the air suction port forms negative pressure, then the building block is discharged, the building block is pushed to move below the rotating scraper blade, the rotating scraper blade scrapes the residual materials above the building block, the scraped residual materials are adsorbed by the negative pressure of the air suction port, and after the building block is moved to the position above a raw material box, the motor stops running, and the residual materials fall into the raw material box along the side face of the rotating scraper blade under the action of gravity.

Description

Evaporate and press former for production of light aerated concrete block

Technical Field

The invention relates to the field of concrete processing, in particular to a forming device for producing an autoclaved lightweight aerated concrete block.

Background

The aerated concrete block is a novel building material which is light, porous, heat-insulating, good in fireproof performance, nailable, sawable, planeable and has certain shock resistance, can be customized according to different local raw materials and different conditions, the raw materials can be river sand, fly ash, ore sand and the like, are suitable according to local conditions, can be utilized as wastes, are beneficial to environmental protection, and really change wastes into valuables.

But current former is in the use, can extrude the raw materials through the multiunit pneumatic cylinder usually, and insert the mould through promoting the inserted bar, form the through-hole in making the product, but the building block solidifies the back, cause the building block damage when taking the inserted bar out very easily, influence production quality, and the top of mould and product can all pile up unfixed raw materials after the drawing of patterns, the operation that is current to remaining raw materials is brushing the raw materials through the brush hair when transporting the building block, can not be convenient retrieve the raw materials, and cause the raise dust among the clearance process, cause environmental pollution.

Disclosure of Invention

Based on the above, the invention aims to provide the molding equipment for producing the autoclaved lightweight aerated concrete block, so as to solve the technical problems that the inserted rod is inconvenient to draw out and the residual raw materials are inconvenient to clean and recycle.

In order to achieve the purpose, the invention provides the following technical scheme: a molding device for producing autoclaved lightweight aerated concrete blocks comprises a protective shell, a conveyor belt and blocks, wherein a stirring tank is installed on a top plate of the protective shell, a raw material conveying mechanism is movably installed in the protective shell, a molding mechanism is installed in the protective shell and positioned on one side of the raw material conveying mechanism, a plurality of groups of first hydraulic cylinders are installed in the protective shell and positioned right above the molding mechanism, the output end of each first hydraulic cylinder is connected with an upper module, third hydraulic cylinders are installed at the top end of the upper module and positioned on two sides of the output end of the first hydraulic cylinder, a motor is installed at the output end of each third hydraulic cylinder, an insertion rod is connected with the output end of the motor and penetrates through the upper module, rotating blades are arranged in the upper module and positioned on the outer side of the insertion rod, the insertion rod is in transmission connection with the rotating blades, and the upper module is respectively provided with an exhaust groove and an air suction port for the rotating blades to be in contact with the outside air, the rotary scraper is installed below the air suction port and located on one side of the bottom end of the upper module, the bottom end of the rotary scraper is aligned with the top end of the upper module, and the rotary scraper is not in contact with the forming mechanism.

Through adopting above-mentioned technical scheme, can be convenient carry out extrusion to the building block, and take out in the building block of inserted bar can be convenient after the shaping, reduce the damage to the building block, at the unloading in-process, collect piling up the defective material in the building block top through rotating the scraper blade, drive through the inserted bar and rotate the flabellum and rotate, make the air current carry out further collection to the defective material, after on last module removes the raw material tank, make the defective material fall into the raw material tank in, the convenience is retrieved the raw materials.

The raw material conveying mechanism is further provided with a raw material box and an air cylinder, the raw material box is positioned below the stirring tank, the air cylinder is installed on the side surface of the raw material box, the air cylinder is fixed on the inner wall of the protective shell, and the raw material box moves in the protective shell through the air cylinder.

Through adopting above-mentioned technical scheme, conveniently remove the raw materials case.

The middle part of the raw material box is of a hollow structure, the bottom end of the raw material box is provided with a feed opening, and the feed opening is aligned with the forming mechanism.

Through adopting above-mentioned technical scheme, conveniently transport the raw materials to make the raw materials enter into the shaping intracavity through the feed opening.

The invention is further arranged in that the forming mechanism comprises a forming cavity and a second hydraulic cylinder, the forming cavity is fixed at the bottom end of the protective shell, the second hydraulic cylinder is positioned below the forming cavity, a plurality of groups of lower modules extending into the forming cavity are mounted at the output end of the second hydraulic cylinder, and the upper module is positioned right above the forming cavity.

Through adopting above-mentioned technical scheme, can conveniently carry out the shaping to the raw materials, the lower module can conveniently promote the building block to the drawing of patterns carries out.

The invention is further provided that the third hydraulic cylinder is fixedly connected with the output end of the first hydraulic cylinder, and the third hydraulic cylinder is communicated with an external hydraulic source through a hose.

Through adopting above-mentioned technical scheme, make things convenient for the third pneumatic cylinder to remove.

The invention is further provided that a plurality of groups of magnets are arranged on the inner wall of the inserted rod, the inside of the rotating fan blade is connected with an adsorption ring, and the inserted rod is in transmission connection with the rotating fan blade through the magnetic force between the magnets and the adsorption ring.

By adopting the technical scheme, the inserted bar drives the rotating fan blades to rotate synchronously.

The invention is further arranged in such a way that the side surface of the raw material box is aligned with the side surface of the building block, a plurality of groups of limiting plates are arranged on the outer side of the raw material box, and each group of building blocks are positioned in the interval between the limiting plates.

Through adopting above-mentioned technical scheme, make things convenient for the head tank to promote the building block and remove, carry on spacingly to the building block through the limiting plate, the building block can not take place the skew when guaranteeing to promote.

In summary, the invention mainly has the following beneficial effects:

1. according to the invention, through the third hydraulic cylinder, the motor and the inserted rod, when the inserted rod is pulled out, the motor is started, and the inserted rod is driven by the motor to rotate in the building block, so that the inserted rod can be separated from the building block in a rotating manner, the damage to the building block is reduced, the forming effect is improved, and the problem that the inserted rod is inconvenient to pull out is effectively solved.

2. Through the motor, the inserted link, the rotating fan blades and the upper module, when the building block is blanked, the inserted bar is driven by the motor to rotate in the upper module, the inserted bar drives the rotating fan blades to rotate through the plurality of groups of magnets on the inner wall, the rotating fan blades drive air to flow in the upper module, so that the air suction port forms negative pressure, then the building blocks are discharged to push the building blocks to move below the rotating scraper blade, the rotating scraper blade scrapes off the residual materials above the building blocks, and the negative pressure of the air suction port adsorbs the scraped residual material, so that the residual material is accumulated on the outer side of the air suction port and the side surface of the rotating scraper, when the material is moved to the upper part of the raw material box, the motor stops running, the residual material falls into the raw material box along the side surface of the rotating scraper under the action of gravity, thereby retrieve the residue, improve the availability factor, effectively solved the problem of the inconvenient recovery of clearing up remaining raw materials.

Drawings

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

FIG. 2 is a schematic cross-sectional view of the present invention;

FIG. 3 is a schematic diagram of a stopper plate structure according to the present invention;

FIG. 4 is a schematic view of the feed bin of the present invention positioned above the forming chamber;

FIG. 5 is a schematic view of the motor structure of the present invention;

FIG. 6 is a schematic cross-sectional view of an upper module according to the present invention;

FIG. 7 is a schematic top view of the upper module of the present invention;

fig. 8 is a schematic view of the internal structure of the insert rod of the present invention.

In the figure: 1. a protective shell; 2. a stirring tank; 3. a first hydraulic cylinder; 301. a support plate; 4. an upper module; 401. a connection box; 402. rotating the scraper plate; 403. an exhaust groove; 404. an air suction port; 5. a second hydraulic cylinder; 501. a lower module; 6. a molding cavity; 7. a raw material tank; 701. a feeding port; 8. a limiting plate; 9. a cylinder; 10. a conveyor belt; 11. a third hydraulic cylinder; 12. building blocks; 13. a motor; 1301. an output shaft; 14. inserting a rod; 1401. a connecting rod; 1402. a magnet; 15. rotating the fan blades; 1501. an adsorption ring.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described below with reference to the accompanying drawings are illustrative only for the purpose of explaining the present invention and are not to be construed as limiting the present invention.

The following describes an embodiment of the present invention based on its overall structure.

The utility model provides an evaporate and press former for production of light aerated concrete block, as shown in fig. 1 to 8, including protective housing 1, conveyer belt 10 and building block 12, agitator tank 2 is installed to protective housing 1 roof, the inside movable mounting of protective housing 1 has raw materials conveying mechanism, raw materials conveying mechanism comprises raw material tank 7 and cylinder 9, raw material tank 7 is located agitator tank 2's below, the side-mounting of raw material tank 7 has cylinder 9, cylinder 9 fixes the inner wall at protective housing 1, and raw material tank 7 passes through cylinder 9 and removes in protective housing 1's inside, when the material loading, pour into raw materials into agitator tank 2 in, open the valve of agitator tank 2 bottom, make the raw materials enter into raw material tank 7 in, start cylinder 9 and promote raw material tank 7 and remove.

The forming mechanism is installed to one side that the inside of protective housing 1 is located raw materials conveying mechanism, and forming mechanism includes one-tenth die cavity 6 and second pneumatic cylinder 5, and one-tenth die cavity 6 is fixed in the bottom of protective housing 1, and second pneumatic cylinder 5 is located the below that becomes die cavity 6, and the output of second pneumatic cylinder 5 is installed the multiunit and is extended to the lower module 501 that becomes die cavity 6 inside, and raw materials case 7 moves into one-tenth die cavity 6 top, makes the raw materials enter into in the one-tenth die cavity 6.

The inside of the protective shell 1 is located right above each group of forming cavities 6 and is provided with a first hydraulic cylinder 3, the output end of the first hydraulic cylinder 3 is connected with an upper module 4, after the feeding is finished, the first hydraulic cylinder 3 is started, the output end of the first hydraulic cylinder 3 pushes the upper module 4 to move downwards, so that the upper module 4 is inserted into the forming cavities 6 to extrude and form raw materials, the top end of the upper module 4 is located at the outer side of the output end of the first hydraulic cylinder 3 and is provided with a support plate 301, the two sides of the support plate 301 are provided with third hydraulic cylinders 11, the output end of the third hydraulic cylinder 11 is provided with a motor 13, the output end of the motor 13 is connected with an inserted rod 14, the inserted rod 14 penetrates through the upper module 4, after the raw materials are extruded, the third hydraulic cylinder 11 is started, the output end of the third hydraulic cylinder 11 pushes the motor 13 to move, the output rotating shaft 1301 of the motor 13 drives the inserted rod 14 to move downwards, so that the inserted rod 14 is inserted into the raw materials, the raw materials are internally provided with through holes, the outer side of an inserted link 14 is positioned in an upper module 4 and is provided with a rotating fan blade 15, the inner wall of the inserted link 14 is provided with a plurality of groups of magnets 1402, the inside of the rotating fan blade 15 is connected with an adsorption ring 1501, the inserted link 14 is in transmission connection with the rotating fan blade 15 through magnetic force between the magnets 1402 and the adsorption ring 1501, the upper module 4 is respectively provided with an exhaust groove 403 and an air suction port 404, the rotating fan blade 15 is in contact with the outside air, the side surface of the upper module 4 is provided with a connecting box 401, the air suction port 404 is positioned at the bottom end of the connecting box 401, a rotating scraper 402 is arranged below the air suction port 404, the rotating scraper 402 is positioned at one side of the bottom end of the upper module 4, the bottom end of the rotating scraper 402 is aligned with the top end of a building block 12, after the building block 12 is processed, a first hydraulic cylinder 3 and a second hydraulic cylinder 5 are started to push the building block 12 out from a forming cavity 6, a motor 13 is started to run at a low speed, the motor 13 drives the inserted link 14 to slowly rotate in the building block 12 through an output rotating shaft 1301, therefore, the inserted link 14 can be effectively separated from the inner wall of the building block, then the third hydraulic cylinder 11 is started, the output end of the third hydraulic cylinder 11 drives the motor 13 and the rotary inserted link 14 to synchronously move upwards, the inserted link 14 is quickly separated from the building block 12, the probability of damage to the building block 12 caused by the fact that the inserted link 14 is pulled during separation is reduced, the quality of the building block 12 is improved until the inserted link 14 is separated from the building block 12 and enters the upper module 4, at the moment, the magnet 1402 on the inner wall of the inserted link 14 is aligned with the adsorption ring 1501 on the inner wall of the rotating fan blade 15, the rotating fan blade 15 can synchronously rotate along with the inserted link 14 through magnetic force, at the moment, the motor 13 is started at a high speed to drive the inserted link 14 and the rotating fan blade 15 to rotate at a high speed, so that outside air can be sucked from the air suction port 404 and discharged from the air discharge channel 403, negative pressure is formed on the side surface of the rotating scraper blade 402, then the first hydraulic cylinder 3 is started, and the upper module 4 is slightly away from the building block 12, the bottom end of the rotating scraper 402 can be aligned with the top end of the building block 12, the cylinder 9 is started again, the output end of the cylinder 9 pushes the raw material box 7 to move, the raw material box 7 contacts with the side surface of the building block 12 and pushes the building block 12 to move, the raw material box 7 limits the building block 12 through a limiting plate 8 on the outer side to ensure that the building block 12 does not shift in the moving process, the rotating scraper 402 is positioned above the building block 12 in the moving process of the building block 12, so that residual raw materials above the building block can be scraped, the residual raw materials are sucked into the air suction port 404 through negative pressure, the raw materials are intercepted through the filter screen until the rotating scraper 402 reaches the upper part of the raw material box 7 through the limiting plate 8, at the moment, the motor 13 stops running, the inserted link 14 and the rotating fan blade 15 do not rotate, the residual materials adsorbed on the air suction port 404 and accumulated outside the rotating scraper 402 fall into the raw material box 7 under the action of gravity, so that the outer side of the building block 12 can be conveniently cleaned, and the residual materials are sent back to the raw material box 7.

Referring to fig. 2 and 4, the middle portion of the raw material tank 7 is a hollow structure, the bottom end of the raw material tank 7 is provided with a feed opening 701, the feed opening 701 is aligned with the forming mechanism, and the side surface of the feed opening 701 is an inclined scraper, so that the raw material in the raw material tank 7 can be conveniently fed into the forming cavity 6, and the raw material can be scraped by the scraper, thereby avoiding the raw material from being accumulated on the inner wall of the protective shell 1.

Referring to fig. 2, the third hydraulic cylinder 11 is fixedly connected to the output end of the first hydraulic cylinder 3, and the third hydraulic cylinder 11 is connected to an external hydraulic source through a hose, so that the third hydraulic cylinder 11 can move conveniently.

Referring to fig. 2 and 3, the side of the raw material tank 7 is aligned with the side of the block 12, a plurality of sets of limiting plates 8 are disposed outside the raw material tank 7, each set of block 12 is disposed in the space between the limiting plates 8, so that the block 12 is conveniently pushed by the raw material tank 7 to move, the limiting plates 8 limit the block 12, and the block 12 is prevented from shifting when pushed.

The working principle of the invention is as follows: firstly, each group of hydraulic cylinders is connected with an external hydraulic source, the third hydraulic cylinder 11 is connected with the external hydraulic source through a hose, the equipment is connected with an external power supply, so that the equipment can normally operate, when the equipment is used, raw materials are firstly injected into the stirring tank 2, a valve at the bottom end of the stirring tank 2 is opened, the raw materials enter the raw material box 7, the starting cylinder 9 pushes the raw material box 7 to move, a feed opening 701 at the bottom end of the raw material box 7 moves to the upper part of the forming cavity 6, at the moment, the raw materials enter the forming cavity 6 through the feed opening 701, then the starting cylinder 9 drives the raw material box 7 to return, the first hydraulic cylinder 3 is started, the output end of the first hydraulic cylinder 3 pushes the upper module 4 to move downwards, the upper module 4 is inserted into the forming cavity 6 to extrude the raw materials, then, the third hydraulic cylinder 11 is started, the output end of the third hydraulic cylinder 11 pushes the motor 13 to move, an output rotating shaft 1301 of a motor 13 drives an insertion rod 14 to move downwards, so that the insertion rod 14 is inserted into the raw material, a through hole is formed in the raw material, after the raw material is molded into a building block 12, a first hydraulic cylinder 3 and a second hydraulic cylinder 5 are started simultaneously, the building block 12 is pushed out of a molding cavity 6 until the top end of a lower module 501 is aligned with the top end of the molding cavity 6, then the motor 13 runs at a low speed, the motor 13 drives the insertion rod 14 to rotate slowly in the building block 12 through the output rotating shaft 1301, so that the insertion rod 14 can be effectively separated from the inner wall of the building block, then a third hydraulic cylinder 11 is started, the output end of the third hydraulic cylinder 11 drives the motor 13 and the rotating insertion rod 14 to move upwards synchronously, the insertion rod 14 is separated from the building block 12 quickly, the probability of damage to the building block 12 caused by the pulling of the insertion rod 14 during separation is reduced, the quality of the building block 12 is improved, and the insertion rod 14 is separated from the building block 12 and enters an upper module 4, at the moment, the magnet 1402 on the inner wall of the inserted link 14 is aligned with the absorption ring 1501 on the inner wall of the rotating fan blade 15, the rotating fan blade 15 can synchronously rotate along with the inserted link 14 through magnetic force, at the moment, the motor 13 is started at a high speed to drive the inserted link 14 and the rotating fan blade 15 to rotate at a high speed, so that outside air can be sucked from the air suction port 404 and exhausted from the exhaust groove 403, negative pressure is formed on the side surface of the rotating scraper blade 402, then the first hydraulic cylinder 3 is started to enable the upper module 4 to be slightly away from the building block 12, the bottom end of the rotating scraper blade 402 can be aligned with the top end of the building block 12, the cylinder 9 is started again, the output end of the cylinder 9 pushes the raw material box 7 to move, the raw material box 7 is in contact with the side surface of the building block 12 and pushes the building block 12 to move, the raw material box 7 limits the building block 12 through the limiting plate 8 on the outer side, so that the building block 12 cannot be shifted in the moving process, the building block 12 is positioned above the rotating scraper blade 402 in the moving process, so that the raw material remained above the building block can be scraped, and the residual material is sucked to the air suction port 404 by negative pressure, the raw materials are intercepted by the filter screen until the rotating scraper blade 402 passes through the position above the limit plate 8 and reaches the position above the raw material box 7, at the moment, the motor 13 stops running, the inserted link 14 and the rotating fan blade 15 do not rotate, the residual materials adsorbed on the air suction port 404 and accumulated on the outer side of the rotating scraper blade 402 fall into the raw material box 7 under the action of gravity, thereby being capable of conveniently cleaning the outer side of the building block 12 and sending the residual materials back to the raw material box 7, improving the use efficiency and the raw material utilization rate, at the moment, the building block 12 moves to the conveyor belt 10, the building block 12 is transported by the conveyor belt 10, then the second hydraulic cylinder 5 is started to make the lower module 501 move downwards, the raw material enters the forming cavity 6 again, and the process is repeated to process the subsequent building block 12.

Although embodiments of the present invention have been shown and described, it is intended that the present invention should not be limited thereto, that the particular features, structures, materials or characteristics described may be combined in any suitable manner in any one or more embodiments or examples, and that modifications, substitutions, variations or the like, which are not inventive and may be made by those skilled in the art without departing from the principle and spirit of the present invention and without departing from the scope of the claims.

Claims (7)

1. The utility model provides an evaporate and press former for aerated concrete block production, includes protective housing (1), conveyer belt (10) and building block (12), its characterized in that: the stirring tank (2) is installed on the top plate of the protective shell (1), a raw material conveying mechanism is movably installed inside the protective shell (1), a forming mechanism is installed on one side, located on the raw material conveying mechanism, of the protective shell (1), a plurality of groups of first hydraulic cylinders (3) are installed right above the forming mechanism, the output ends of the first hydraulic cylinders (3) are connected with an upper module (4), the top end of the upper module (4) is located on two sides of the output end of the first hydraulic cylinders (3) and is provided with third hydraulic cylinders (11), a motor (13) is installed at the output end of the third hydraulic cylinders (11), the output end of the motor (13) is connected with an inserted bar (14), the inserted bar (14) penetrates through the upper module (4), and rotating fan blades (15) are arranged inside, located on the outer side of the inserted bar (14), of the upper module (4), and inserted bar (14) are connected with rotation flabellum (15) transmission, go up module (4) and seted up rotation flabellum (15) and exhaust duct (403) and induction port (404) that external air contacted respectively, rotation scraper blade (402) is installed to the below of induction port (404), and rotates scraper blade (402) and be located the one side of module (4) bottom, the bottom of rotating scraper blade (402) aligns with the top of building block (12), and rotates scraper blade (402) not contact with forming mechanism.

2. The molding equipment for producing the autoclaved lightweight aerated concrete block according to claim 1, which is characterized in that: raw materials conveying mechanism comprises raw material tank (7) and cylinder (9), raw material tank (7) are located the below of agitator tank (2), the side-mounting of raw material tank (7) has cylinder (9), and inner wall at protective housing (1) is fixed in cylinder (9), and raw material tank (7) pass through cylinder (9) and move in the inside of protective housing (1).

3. The molding equipment for producing the autoclaved lightweight aerated concrete block according to claim 2, characterized in that: the middle part of raw material tank (7) is hollow structure, feed opening (701) have been seted up to the bottom of raw material tank (7), feed opening (701) align with forming mechanism.

4. The molding equipment for producing the autoclaved lightweight aerated concrete block according to claim 1, which is characterized in that: forming mechanism includes one-tenth die cavity (6) and second pneumatic cylinder (5), become die cavity (6) and fix the bottom in protective housing (1), and second pneumatic cylinder (5) are located the below that becomes die cavity (6), the output of second pneumatic cylinder (5) is installed the multiunit and is extended to die cavity (6) inside lower module (501), and goes up module (4) and be located become die cavity (6) directly over.

5. The forming equipment for producing the autoclaved lightweight aerated concrete block according to claim 1, wherein the forming equipment comprises: the third hydraulic cylinder (11) is fixedly connected with the output end of the first hydraulic cylinder (3), and the third hydraulic cylinder (11) is communicated with an external hydraulic source through a hose.

6. The molding equipment for producing the autoclaved lightweight aerated concrete block according to claim 1, which is characterized in that: the inner wall of inserted bar (14) is installed multiunit magnet (1402), the internal connection of rotating flabellum (15) has adsorption ring (1501), inserted bar (14) pass through magnet (1402), adsorb magnetic force between ring (1501) and rotate flabellum (15) transmission and be connected.

7. The molding equipment for producing the autoclaved lightweight aerated concrete block according to claim 1, which is characterized in that: the side of raw materials case (7) aligns with the side of building block (12), multiunit limiting plate (8) have been seted up in the outside of raw materials case (7), and every group building block (12) all are arranged in the interval between limiting plate (8).

Images