CN215511606U - Evaporate and press aerated concrete body cutting clout adsorption equipment - Google Patents

Abstract

An adsorption device for cutting excess materials of autoclaved aerated concrete blanks comprises an adsorption device top frame, a top adsorption device and end adsorption devices, wherein the top adsorption device is arranged below the adsorption device top frame and is fixedly connected with the adsorption device top frame; one end in top adsorption equipment length direction is provided with sealed belt reel subassembly, and the end that stretches out of sealed belt in the sealed belt reel subassembly can remove along top adsorption equipment length direction under sealed belt slide mechanism's drive to can seal the part that the top adsorbs the wire net and does not contact the body in the top adsorption equipment when cutting the clout and adsorbing to shorter body. The cutting excess materials of the blanks with different specifications can be removed at one time, the production efficiency is high, the production cost is low, and the popularization and application values are high.

Description

Evaporate and press aerated concrete body cutting clout adsorption equipment

Technical Field

The utility model belongs to the technical field of production of autoclaved aerated concrete products, and particularly relates to an autoclaved aerated concrete blank cutting excess material adsorption device.

Background

In the production process of autoclaved aerated concrete products, a rectangular blank body discharged from a casting mould needs to be cut by a cutting machine when advancing forwards in the length direction, cutting excess materials are formed at the periphery and the top in the cutting process of the blank body, end excess materials are formed on two end faces vertical to the length direction, side excess materials are formed on two side faces parallel to the length direction, top excess materials are formed on the top face, and the side excess materials can be removed in the moving process of the blank body. The top and end remainders move with the green body and cannot be removed in the moving process, and need to be moved into a waste slurry pit through a cutting remainder adsorption device.

With the rapid development of the fabricated building, a large amount of autoclaved aerated concrete plates with different lengths are required by the market, so that rectangular blanks with different lengths need to be cut. In the prior art, the length of a top suction cavity body of a cutting excess material adsorption device is fixed, and the distance between a front end part adsorption cavity body and a rear end part adsorption cavity body is also fixed, when a shorter plate needs to be produced, because the length of a blank body is smaller than the distance between the two end part adsorption devices, the two end part adsorption devices cannot simultaneously contact the excess materials at the front end part and the rear end part of the blank body, the excess materials at the two end parts cannot be simultaneously removed at the same station, the excess materials at the two end parts need to be respectively removed at the two stations, and therefore, the production cost is high, and the working efficiency is low; in addition, in the prior art, when the excess material at the end part of the blank body is adsorbed, the part of the top suction cavity body, which is in contact with the blank body, can be completely attached, and the part, which is not in contact with the blank body, is connected with the atmosphere, so that the vacuum cannot be formed in the top suction cavity body, manual intervention is needed to assist in forming the vacuum, the process is complex, and the labor cost is high.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an adsorption device for cutting excess materials of an autoclaved aerated concrete blank.

In order to achieve the purpose, the utility model adopts the technical scheme that: an adsorption device for cutting excess materials of autoclaved aerated concrete blanks comprises an adsorption device top frame, a top adsorption device and end adsorption devices, wherein the top adsorption device is arranged below the adsorption device top frame and is fixedly connected with the adsorption device top frame; one end in top adsorption equipment length direction is provided with sealed belt reel subassembly, and the end that stretches out of sealed belt in the sealed belt reel subassembly can remove along top adsorption equipment length direction under sealed belt slide mechanism's drive to can seal the part that the top adsorbs the wire net and does not contact the body in the top adsorption equipment when cutting the clout and adsorbing to shorter body.

Furthermore, the end adsorption devices are hinged with the respective sliding blocks, air springs capable of being inflated and deflated are arranged between the end adsorption devices and the sliding blocks, and the end adsorption devices can rotate around the hinged points for a certain angle to adjust the contact relation between the end adsorption devices and the green body in the inflation and deflation processes of the air springs.

As an optional implementation mode, tip adsorb slide mechanism including setting up the tip that adsorbs slip driving motor at adsorption equipment roof-rack length direction one end, adsorb the drive shaft with the tip that the drive motor transmission of tip is connected and set up the tip that adsorbs the drive shaft both ends at the tip and adsorb the slip action wheel, still be equipped with on the adsorption equipment roof-rack with corresponding tip adsorb the slip action wheel cooperation work the tip adsorb slip from the driving wheel, adsorb slip action wheel and tip and be equipped with tip and adsorb slip hold-in range between the driving wheel at the tip, tip adsorption equipment and tip adsorb slip hold-in range fixed connection.

As an optional implementation mode, sealing belt sliding mechanism include sealing belt slip driving motor, with sealing belt slip driving shaft that sealing belt slip driving motor transmission is connected, establish sealing belt slip action wheel at sealing belt slip driving shaft both ends and with sealing belt slip action wheel cooperation work's sealing belt slip from the driving wheel, slide at sealing belt slip action wheel and corresponding sealing belt and be equipped with sealing belt slip hold-in range between the driving wheel, sealing belt's the end that stretches out and sealing belt slip hold-in range fixed connection, sealing belt slip driving motor establish the one end opposite with sealing belt reel subassembly on top adsorption equipment.

Preferably, a sealing plate is arranged at the extending end of the sealing belt and penetrates through the width direction of the top adsorption device, and two ends of the sealing plate are fixedly connected with the sealing belt sliding synchronous belt arranged on the corresponding side of the width direction of the top adsorption device respectively.

Further, the pressing block and the guide block are arranged on one side, facing the inner side, of the sealing belt sliding synchronous belt and correspond to the sealing plate, the pressing block, the sealing belt sliding synchronous belt and the sealing plate are fixedly connected together, the guide block and the pressing block are fixedly connected through the L-shaped plate, the height of the guide block is equal to the distance between the upper portion and the lower portion of the inner side of the ring of the sealing belt sliding synchronous belt, a guide rail used for guiding the sealing belt sliding synchronous belt is further arranged on the top adsorption device, and the guide rail is provided with a guide groove used for limiting the width of the sealing belt sliding synchronous belt.

As an optional embodiment the top adsorption equipment include the top inhale the cavity, set up and inhale the wire net fixed frame of cavity lower extreme and fix the top absorption wire net in wire net fixed frame lower part in the top, adsorb the wire net at the top and be provided with the sealing member all around, be provided with the top on the top inhale the cavity and adsorb the trachea connector.

As an optional implementation mode, the sealing belt winding drum assembly is arranged on the outer side of the top suction cavity, the extending end of the sealing belt is arranged below the top suction steel wire mesh, and the parts, close to the two ends in the width direction, in the steel wire mesh fixing frame are connected with the sealing belt sliding mechanism.

Furthermore, the top adsorption device is fixed on the adsorption device top frame through a screw shaft, a spring is sleeved at one end, extending out of the adsorption device top frame, of the screw shaft, and the upper position and the lower position of the top adsorption device are adjusted through adjusting the compression degree of a nut arranged at the top end of the screw shaft on the spring.

As an optional implementation manner, the end adsorption device includes that the tip adsorbs the cavity, the tip adsorbs mount and the tip adsorbs the wire net, the tip adsorbs cavity and tip adsorb mount fixed connection, the tip adsorbs the wire net and the wire net fixed plate fixed connection that sets up on the cavity is adsorbed to the tip, be equipped with tip on the cavity is adsorbed to the tip and adsorb the trachea interface.

Has the advantages that:

according to the utility model, by arranging the end adsorption sliding mechanism, the sealing belt reel assembly and the sealing belt sliding mechanism, the position of the end adsorption device can be adjusted according to the autoclaved aerated concrete products with different specifications required by the market, and the exposed part of the top adsorption cavity can be sealed by the sealing belt under the condition that the position of the end adsorption device is adjusted to be suitable for a shorter blank body, so that the cutting excess materials of the blank bodies with various specifications can be removed integrally by one-time adsorption, the production efficiency is high, the production cost is low, and the sealing belt reel assembly has remarkable beneficial effects and great popularization and application values.

Drawings

Fig. 1 is a schematic diagram of the three-dimensional structure profile of the present invention.

FIG. 2 is a front view showing the state of the present invention in which the cutting residue is adsorbed to the long die blank.

FIG. 3 is a front view showing the state of the present invention in which the cutting residue is adsorbed to the short die blank.

Fig. 4 is a schematic diagram of the three-dimensional configuration of the end suction device.

Fig. 5 is a cross-sectional view of the end suction device.

FIG. 6 is a front view of the top adsorption unit.

Fig. 7 is a bottom view of the top suction device in an operating state for the short die.

Fig. 8 is a schematic three-dimensional appearance of the top suction device in an operating state for a short die.

Fig. 9 is a half sectional view in the longitudinal direction of the top suction device.

Fig. 10 is a cross-sectional view taken along the line B-B in fig. 9 (fig. 10 is a transverse full-section).

Fig. 11 is a sectional view taken at a in fig. 6.

Fig. 12 is an enlarged view at C in fig. 10.

In the figure, 1, an adsorption device top frame, 11, an end adsorption sliding mechanism, 111, an end adsorption sliding driving motor, 112, an end adsorption driving shaft, 113, an end adsorption sliding driving wheel, 114, an end adsorption sliding synchronous belt, 115, an end adsorption sliding driven wheel, 2, an end adsorption device, 21, an air spring, 22, a guide shaft, 23, a rotation fulcrum, 24, an end adsorption cavity, 241, an end adsorption air pipe interface, 25, an end adsorption fixing frame, 26, end adsorption sealing cotton, 27, an end adsorption steel wire mesh, 28, a connecting piece, 29, a steel wire mesh fixing plate, 30, a sliding block, 3, a top adsorption device, 31, a screw shaft, 32, a spring, 33, a sealing belt reel assembly, 34, a sealing belt sliding mechanism, 341, a guide rail, 342, a sealing belt, 343, a pressing block, 344, a guide block, 345, a sealing plate, 346 and a belt sliding driving motor, 347. sealing belt slip action wheel, 348, sealing belt slip hold-in range, 349, sealing belt slip drive shaft, 350, sealing belt slip action wheel, 35, the top suction cavity, 351, cavity baffle, 352, top suction gas pipe connector, 36, top adsorption steel wire net, 37, sealed plastic skin, 38, steel wire net mount, 381, hollow tube portion, 39, top adsorption sealing cotton, 4, slide rail.

Detailed Description

The present invention will be described in further detail with reference to the following drawings and examples, but the utility model is not limited thereto.

As shown in fig. 1, 2, 3 and 6, the residual material adsorption device for cutting the autoclaved aerated concrete blank comprises an adsorption device top frame 1, a top adsorption device 3 and an end adsorption device 2, wherein the top adsorption device 3 is arranged below the adsorption device top frame 1 and is fixedly connected with the adsorption device top frame 1.

The adsorption device top frame 1 can be fixed on the lower part of the crane through a cable.

The lower parts of the two ends of the width direction of the adsorption device top frame 1 are respectively provided with a slide rail 4 along the length direction of the adsorption device top frame 1, and the two end adsorption devices 2 are installed on the slide rails 4 through respective slide blocks 30 and can move along the slide rails 4 under the driving of respective end adsorption sliding mechanisms 11.

Be provided with sealed belt reel subassembly 33 in top adsorption equipment length direction's one end, the end that stretches out of sealed belt 342 in sealed belt reel subassembly 33 can remove along 3 length direction of top adsorption equipment under the drive of sealed belt slide mechanism 34 to can seal the part that the top adsorption steel mesh does not contact the body in the top adsorption equipment when cutting the clout and adsorbing to shorter body.

Specifically, the end adsorption devices 2 are hinged to respective sliders, an air spring 21 capable of being inflated and deflated is arranged between the end adsorption device 2 and the sliders, and in the inflation and deflation processes of the air spring 21, the end adsorption device 2 can rotate around a hinge point for a certain angle to adjust the contact relation between the end adsorption device 2 and the green body.

In order to limit the offset amplitude of the end adsorption device 2 in the width direction of the adsorption device top frame 1 during the rotation process around the hinge point, a guide shaft 22 is arranged at the lower end of the slide block 30, the guide shaft 22 is matched with a guide hole arranged on the end adsorption device, the diameter of the guide hole is larger than that of the guide shaft, and the guide hole is preferably a long hole extending along the length direction of the adsorption device top frame 1. The guide shaft 22 can be fixed on the lower end face of the sliding block 30 by bolts, specifically, a connecting plate can be welded above the guide shaft 22, and the connecting plate is fixed on the sliding block 30 by bolts; alternatively, the guide shaft 22 may be threaded and fixed to the slider 30 by a nut. In this embodiment, the sliding block 30 is a long-strip groove shape, and a protrusion portion installed in cooperation with the i-shaped sliding rail is disposed inside the long-strip groove shape.

As shown in fig. 1, in this embodiment, the end adsorption sliding mechanism 11 includes an end adsorption sliding driving motor 111 disposed at one end of the adsorption device top frame 1 in the length direction, an end adsorption driving shaft 112 in transmission connection with the end adsorption sliding driving motor 111, and end adsorption sliding driving wheels 113 disposed at two ends of the end adsorption driving shaft 112, an end adsorption sliding driven wheel 115 cooperating with the corresponding end adsorption sliding driving wheel 113 is further disposed on the adsorption device top frame 1, an end adsorption sliding timing belt 114 is disposed between the end adsorption sliding driving wheel 113 and the end adsorption sliding driven wheel 115, and the end adsorption device 2 is fixedly connected to the end adsorption sliding timing belt 114.

As shown in fig. 4 and 5, the end adsorption device 2 includes an end adsorption cavity 24, an end adsorption fixing frame 25 and an end adsorption steel wire mesh 27, the end adsorption cavity 24 and the end adsorption fixing frame 25 are fixedly connected, the end adsorption steel wire mesh 27 and the end adsorption cavity 24 are fixedly connected with a steel wire mesh fixing plate 29, and an end adsorption air pipe connector 241 is arranged on the end adsorption cavity 24.

Specifically, tip adsorbs cavity 24 to be a welded structure's cavity, opens at one side of tip adsorption cavity 24 and has the inlet port, and wire net fixed plate 29 is established around the one side that tip adsorption cavity 24 set up the inlet port, and tip adsorbs wire net 27 and wire net fixed plate 29 accessible bolted connection. The end suction chamber 24 may be detachably connected to the end suction holder 25 by means of a connecting piece 28 or welded, preferably detachably connected. The end part adsorption sealing cotton 26 is arranged around the end part adsorption steel wire mesh 2, and the end part adsorption sealing cotton 26 can be bonded around the end part adsorption cavity 24.

The end adsorption air pipe interface 241 is used for connecting a vacuum blower to make the end adsorption cavity 24 form vacuum in a working state.

As shown in fig. 6, 7, 8, 9 and 10, in this embodiment, the top adsorption device 3 includes a top adsorption cavity 35, a steel wire mesh fixing frame 38 disposed at a lower end of the top adsorption cavity 35, and a top adsorption steel wire mesh 36 fixed at a lower portion of the steel wire mesh fixing frame 38, sealing members are disposed around the top adsorption steel wire mesh 36, and a top adsorption air pipe connection port 352 is disposed on the top adsorption cavity 35.

In this embodiment, the top suction cavity 35 is a cavity with a welded structure, and a plurality of cavity partitions 351 are disposed inside the cavity. The sealing element around the top adsorption steel wire mesh 36 comprises top adsorption sealing cotton 39 directly adhered to the periphery of the top adsorption cavity 35, and a circle of sealing plastic skin 37 is adhered to the outer side of the frame of the adhering part of the top adsorption sealing cotton 39. The top suction air pipe connection 352 is used to connect a corresponding vacuum blower, and is used to form a vacuum in the top suction cavity 35 during operation.

In this embodiment, the top adsorption device 3 is fixed on the adsorption device top frame 1 through the screw shaft 31, one end of the screw shaft 31 extending out of the adsorption device top frame 1 is sleeved with a spring 32, and the top and bottom positions of the top adsorption device 3 are adjusted by adjusting the compression degree of the spring 32 by the nut arranged at the top end of the screw shaft.

In this embodiment, the sealing belt reel assembly 33 is disposed outside the top suction cavity 35, and may be specifically fixed outside the top suction cavity 35 by bolts. The extending end of the sealing belt 342 is disposed below the top adsorption steel wire mesh 36, and is connected to the sealing belt sliding mechanism 34 in the hollow pipe portion 381 at the two ends of the steel wire mesh fixing frame 38 in the width direction (i.e., the two sides of the top adsorption cavity 35 in the width direction).

As shown in fig. 6, 9, 10, 11 and 12, in this embodiment, the sealing belt sliding mechanism 34 includes a sealing belt sliding driving motor 346, a sealing belt sliding driving shaft 349 in transmission connection with the sealing belt sliding driving motor 346, sealing belt sliding driving wheels 347 disposed at two ends of the sealing belt sliding driving shaft 349 and sealing belt sliding driven wheels 350 cooperating with the sealing belt sliding driving wheels 347, a sealing belt sliding timing belt 348 is disposed between the sealing belt sliding driving wheels 347 and the corresponding sealing belt sliding driven wheels 350, an extending end of the sealing belt 342 is fixedly connected with the sealing belt sliding timing belt 348, and the sealing belt sliding driving motor 346 is disposed at an end of the top adsorption device 3 opposite to the sealing belt reel assembly 33.

In a preferred embodiment, a sealing plate 345 is provided at the end of the sealing belt 342 extending in the width direction of the top suction device 3, and both ends of the sealing plate 345 are fixedly connected to sealing belt sliding timing belts 348 provided on the corresponding sides in the width direction of the top suction device 3.

A pressing block 343 and a guide block 344 are arranged on one surface, facing the inner side, of the sealing belt sliding synchronous belt 348 and correspond to the sealing plate 345, the pressing block 343, the sealing belt sliding synchronous belt 348 and the sealing plate 345 are fixedly connected together, the guide block 344 and the pressing block 343 are fixedly connected through an L-shaped plate through bolts, the height of the guide block 344 is equal to the distance between the upper side and the lower side of the annular inner side of the sealing belt sliding synchronous belt 348, a guide rail 341 for guiding the sealing belt sliding synchronous belt 348 is further arranged on the top adsorption device 3, and the guide rail 341 is provided with a guide groove for limiting the width of the sealing belt sliding synchronous belt 348. The guide block 344 guides the advancing direction of the sealing belt sliding timing belt 348 together with the guide rail 341, and ensures that the sealing belt sliding timing belt 348 smoothly advances in a predetermined direction.

In this embodiment, the guide rail 341 is disposed at the top of the hollow tube 381 by a bolt, and is disposed along the direction parallel to the length of the top suction chamber 35.

The working process of the autoclaved aerated concrete blank cutting excess material adsorption device is as follows:

1) when producing the whole die (namely a longer blank) autoclaved aerated concrete blank:

the positions of the end adsorption device 2 and the top adsorption device 3 are shown in fig. 2, the end adsorption sliding mechanism 11 and the belt sliding mechanism 34 are not started, and the positions of the adsorption devices are adjusted by a crane, so that the end adsorption device 2 and the top adsorption device 3 are in contact with the autoclaved aerated concrete green body.

In this process, the air spring 21 is deflated, and the end face of the end suction device 3 is at a vertical position with respect to the ground. Through the centrifugal fan effect that is used for the evacuation, the top of top adsorption equipment 3 is inhaled cavity 35 and is contacted with the top clout, and the sealed plastic skin 37 and the top that the top was inhaled cavity 35 all around adsorb sealed cotton 39 and hug closely with the top clout, inhale cavity 35 inside formation vacuum in the top, adsorb the top clout on top adsorbs steel wire net 36.

Then, the end adsorption device 3 contacts with the end remainder, the end adsorption cavity 24 contacts with the end remainder, the end remainder and the end adsorption sealing cotton 26 are tightly attached, the corresponding vacuum-pumping fan enables the inside of the end adsorption cavity 24 to form vacuum, and the end remainder is adsorbed on the end adsorption steel wire mesh 27. Then the air spring 21 is inflated to enable the end adsorption device 3 and the end residual materials adsorbed together with the end adsorption device to incline for a certain angle and separate from the blank body, and then the end adsorption device moves to the upper part of the waste slurry pit along with the adsorption device top frame 1 under the action of a crane to break vacuum, and the cut residual materials are discarded.

2) When autoclaved aerated concrete blanks of other specifications (namely shorter blanks) are produced, the positions of the end adsorption device 2 and the top adsorption device 3 are shown in figure 3, and the end adsorption sliding mechanism 11 and the sealing belt sliding mechanism 34 are started. According to the specification of the autoclaved aerated concrete blank to be produced, the end adsorption sliding driving motor 111 drives the end adsorption sliding mechanism 11 to move the end adsorption device 2 to a proper position, and the sealing belt sliding driving motor 346 drives the sealing belt sliding mechanism 34 to move the sealing belt 342 to a proper position.

And then, adjusting the position of the adsorption device by a crane to enable the end adsorption device 2 and the top adsorption device 3 to be in contact with the autoclaved aerated concrete body. In this process, the air spring 21 is deflated, and the end face of the end suction device 3 is at a vertical position with respect to the ground. The top suction cavity 35 of the top suction device 3 is in contact with the top remainder, the sealing plastic skin 37 and the top suction sealing cotton 39 around the top suction cavity 35 are tightly attached to the top remainder, and the inside of the top suction cavity 35 is vacuumized to suck the top remainder under the action of the centrifugal fan.

Then, the end adsorption device 3 contacts with the end remainder, the end adsorption cavity 24 contacts with the end remainder, the end remainder is tightly attached to the end adsorption sealing cotton 26, vacuum is formed inside through the action of a centrifugal fan for vacuumizing, then the air spring 21 is inflated to enable the end adsorption device 3 and the end remainder adsorbed together with the end adsorption device 3 to incline for a certain angle and be separated from the original blank, then the end adsorption device moves to the upper part of the waste slurry pit along with the adsorption device top frame 1 under the action of a crane, vacuum is broken, and the cutting remainder is discarded.

In this embodiment, the two end suction devices are both provided with the end suction sliding mechanisms 11, so as to avoid collision with the green body in the process that the suction devices move downwards to the periphery of the green body. In actual work, in the descending process, the distance between the two end adsorption devices 2 is large, and after the end adsorption devices descend to the right position, the end adsorption devices are moved to the right position through the end adsorption sliding mechanisms 11, so that the method is suitable for whole die production and short die production. During short-die production, the end adsorption device at one end of the sealing belt reel assembly 33 can be moved for a certain distance, and then is descended to the right position, and then fine adjustment is carried out, so that the two end adsorption devices are in contact with the two ends of the blank body.

The detailed parts of the present invention are the same as the prior art.

The above embodiments are only intended to illustrate the technical solution of the present invention and not to limit the same, and it should be understood by those skilled in the art that the specific embodiments of the present invention can be modified or substituted with equivalents with reference to the above embodiments, and any modifications or equivalents without departing from the spirit and scope of the present invention are within the scope of the claims of the present invention.

Claims (10)

1. The utility model provides an evaporate and press aerated concrete blank cutting clout adsorption equipment, includes adsorption equipment roof-rack (1), top adsorption equipment (3) and tip adsorption equipment (2), its characterized in that: the top adsorption device (3) is arranged below the adsorption device top frame (1) and is fixedly connected with the adsorption device top frame (1), slide rails (4) are arranged on the lower portions of the two ends of the adsorption device top frame (1) in the width direction along the length direction of the adsorption device top frame (1), and the two end adsorption devices (2) are arranged on the slide rails (4) through respective slide blocks (30) and can move along the slide rails (4) under the driving of respective end adsorption sliding mechanisms (11); one end in the length direction of the top adsorption device is provided with a sealing belt reel assembly (33), the extending end of a sealing belt (342) in the sealing belt reel assembly (33) can move along the length direction of the top adsorption device (3) under the driving of a sealing belt sliding mechanism (34), and therefore the part, which is not in contact with the green body, of the top adsorption steel wire mesh in the top adsorption device can be sealed when the short green body is cut and the excess material is adsorbed.

2. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: the end adsorption devices (2) are hinged with the respective sliding blocks, air springs (21) capable of being inflated and deflated are arranged between the end adsorption devices (2) and the sliding blocks, and in the inflation and deflation processes of the air springs (21), the end adsorption devices (2) can rotate around hinged points for a certain angle to adjust the contact relation between the end adsorption devices (2) and the green bodies.

3. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: tip adsorb slide mechanism (11) including setting up tip absorption slip driving motor (111) in adsorption equipment roof-rack (1) length direction one end, adsorb drive shaft (112) with tip absorption slip driving motor (111) transmission connection, and set up tip absorption slip driving wheel (113) at tip absorption drive shaft (112) both ends, still be equipped with on adsorption equipment roof-rack (1) with corresponding tip absorption slip driving wheel (113) cooperation work's tip absorption slip from driving wheel (115), be equipped with tip absorption slip hold-in range (114) between tip absorption slip driving wheel (113) and tip absorption slip from driving wheel (115), tip adsorption equipment (2) and tip absorption slip hold-in range (114) fixed connection.

4. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: the sealing belt sliding mechanism (34) comprises a sealing belt sliding driving motor (346), a sealing belt sliding driving shaft (349) in transmission connection with the sealing belt sliding driving motor (346), sealing belt sliding driving wheels (347) arranged at two ends of the sealing belt sliding driving shaft (349) and sealing belt sliding driven wheels (350) in matched work with the sealing belt sliding driving wheels (347), a sealing belt sliding synchronous belt (348) is arranged between each sealing belt sliding driving wheel (347) and the corresponding sealing belt sliding driven wheel (350), the extending end of each sealing belt (342) is fixedly connected with the sealing belt sliding synchronous belt (348), and the sealing belt sliding driving motor (346) is arranged at one end, opposite to the sealing belt winding drum assembly (33), of the top adsorption device (3).

5. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 4, characterized in that: a sealing plate (345) is arranged at the extending end of the sealing belt (342) in the width direction of the top adsorption device (3), and two ends of the sealing plate (345) are respectively fixedly connected with a sealing belt sliding synchronous belt (348) arranged on the corresponding side of the top adsorption device (3) in the width direction.

6. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 5, characterized in that: the sealing belt sliding synchronous belt (348) is provided with a pressing block (343) and a guide block (344) on the surface facing the inner side and corresponding to a sealing plate (345), the pressing block (343), the sealing belt sliding synchronous belt (348) and the sealing plate (345) are fixedly connected together, the guide block (344) and the pressing block (343) are fixedly connected through an L-shaped plate through bolts, the height of the guide block (344) is equal to the distance between the upper portion and the lower portion of the inner side of the ring of the sealing belt sliding synchronous belt (348), a guide rail (341) used for guiding the sealing belt sliding synchronous belt (348) is further arranged on the top adsorption device (3), and the guide rail (341) is provided with a guide groove used for limiting the width of the sealing belt sliding synchronous belt (348).

7. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: the top adsorption device (3) comprises a top adsorption cavity (35), a steel wire mesh fixing frame (38) arranged at the lower end of the top adsorption cavity (35) and a top adsorption steel wire mesh (36) fixed on the lower portion of the steel wire mesh fixing frame (38), sealing parts are arranged around the top adsorption steel wire mesh, and a top adsorption air pipe connector (352) is arranged on the top adsorption cavity (35).

8. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 7, characterized in that: the sealing belt winding drum assembly (33) is arranged on the outer side of the top suction cavity (35), the extending end of the sealing belt (342) is arranged below the top suction steel wire mesh (36), and the parts, close to the two ends in the width direction, in the steel wire mesh fixing frame (38) are connected with the sealing belt sliding mechanism (34).

9. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: the top adsorption device (3) is fixed on the adsorption device top frame (1) through a screw shaft (31), a spring (32) is sleeved at one end of the screw shaft (31) extending out of the adsorption device top frame (1), and the upper position and the lower position of the top adsorption device (3) are adjusted through adjusting the compression degree of a nut arranged at the top end of the screw shaft on the spring (32).

10. The autoclaved aerated concrete body cutting excess material adsorption device according to claim 1, characterized in that: tip adsorption equipment (2) adsorb mount (25) and tip and adsorb wire net (27) including tip adsorption cavity (24), tip adsorption cavity (24) and tip adsorb mount (25) fixed connection, tip adsorption wire net (27) and the wire net fixed plate (29) fixed connection that set up on tip adsorption cavity (24) are equipped with tip adsorption trachea interface (241) on tip adsorption cavity (24).

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