CN115892860A - Concrete construction engineering loading attachment - Google Patents

Abstract

The invention relates to the technical field of feeding machines, in particular to a feeding device for concrete construction engineering. A concrete construction engineering loading attachment, includes feed mechanism, first actuating mechanism, feed mechanism, adjustment mechanism, discharge mechanism and two second actuating mechanism. The feeding mechanism comprises a first support frame, a feeding box, a first conveying belt, a second conveying belt and a sieve plate. The adjusting mechanism is used for conveying the materials scattered from the hopper to the first conveying belt. The discharging mechanism is used for discharging outwards. The invention provides a concrete construction engineering feeding device, which aims to solve the problems that a feeding machine used in the existing construction engineering needs manual cleaning, the existing feeding device is difficult to clean due to a complex structure, a large amount of manpower is wasted, and in construction, time is often spent on adjustment and the working efficiency is reduced in the face of different feeding height requirements under different construction conditions.

Description

Concrete construction engineering loading attachment

Technical Field

The invention relates to the technical field of feeding machines, in particular to a feeding device for concrete construction engineering.

Background

The feeding machine is a feeding machine, is accurate in transportation, reliable in quality, firm and durable, does not damp raw materials in the feeding process, does not have foreign matters or leak, achieves feeding process automation, reduces labor intensity, improves production efficiency, and is one of the necessities of modern enterprise civilized production. Concrete is not strange to people, sand and stone play a role of a skeleton and are called aggregate, after cement slurry is hardened, the aggregate is cemented into a solid whole, and after the concrete is hardened, reinforcing steel bars can be fixed and limited to form an important component of a building.

If the chinese patent with the publication number CN113401598B provides a feeding machine for concrete processing, the feeding machine is abutted to two surfaces of the spiral blade which are deviated from each other through the scraping piece, at the moment, the rotating shaft is driven to rotate through the driving motor, so that the rotating shaft drives the spiral blade to drive, meanwhile, the moving rod is driven to move along the length direction of the rod body through the moving device, so that the scraping piece can move along the length direction of the spiral blade along with the spiral blade in a rotating state of a user, the scraping piece can scrape impurities which are paid off from the length of the spiral blade, the whole spiral blade is cleaned, the adhered impurities are not required to be cleaned manually, the cleaning effect on the spiral blade is improved, and the manpower is saved; when scraping the material piece and removing along helical blade's length direction, scrape the material piece and can drive the dead lever and be located the elasticity that the sleeve resisted the spring and remove to make and scrape the helical blade that the material piece adapts to different positions, improved and scraped the removal effect that the material piece removed far away helical blade length direction.

However, in the end of construction, the time is often spent for adjustment in the face of different loading height requirements under different construction conditions, and the work efficiency is reduced. In addition, after the construction is finished, a feeding mechanism used in construction engineering also needs to be cleaned manually, and the feeding mechanism is difficult to clean due to the complex structure, so that a large amount of manpower is wasted.

Disclosure of Invention

The invention provides a concrete construction engineering feeding device, which solves the problems that a feeding machine used in the existing construction engineering needs manual cleaning, the feeding device is difficult to clean due to a complex structure, a large amount of manpower is wasted, and in construction, the feeding machine often needs to spend time for adjustment and reduces the working efficiency in the face of different feeding height requirements under different construction conditions.

The invention relates to a concrete construction engineering feeding device, which adopts the following technical scheme: a concrete construction engineering loading attachment, includes feed mechanism, first actuating mechanism, feed mechanism, adjustment mechanism, discharge mechanism and two second actuating mechanism.

The feeding mechanism comprises a first support frame, a feeding box, a first conveying belt, a second conveying belt and a sieve plate. The feeding box is fixedly arranged on the first support frame, and the lower end of the feeding box is provided with a discharging port. The first conveying belt and the second conveying belt are horizontally arranged, the first conveying belt and the second conveying belt can be rotatably arranged on the first support frame, and the feeding box, the first conveying belt and the second conveying belt are sequentially arranged from top to bottom. The sieve sets up on first support frame, and the upper end of sieve is in discharge gate department, and the lower extreme of sieve is in the top of second conveyer belt, has seted up the sieve mesh on the sieve. The first driving mechanism is used for driving the first conveying belt and the second conveying belt to rotate.

Feed mechanism includes that flitch is gone up to second support frame, a plurality of shutoff subassembly, two sets of conveyor components, a plurality of first flitch and a plurality of second. A plurality of bin outlets are formed in the second supporting frame in the vertical direction, and the blocking assembly is used for blocking the bin outlets. Each set of conveying components comprises a third conveying belt and two belt wheels. The belt wheel rotates and is arranged on the second supporting frame, the third conveying belt is vertically arranged, and the upper end and the lower end of the third conveying belt are respectively connected with a belt wheel. The second driving mechanism is used for driving the belt wheel to rotate. The first feeding plates are uniformly distributed on one third conveying belt, and the second feeding plates are uniformly distributed on the other third conveying belt. The first feeding plate and the adjacent second feeding plate can be in mutual contact, and the first feeding plate and the adjacent second feeding plate are in contact and then form a hopper for containing materials with the side end surface of the second support frame. Flitch homoenergetic is gone up to first flitch and second and is dismantled.

The adjusting mechanism is used for conveying the materials scattered from the hopper to the first conveying belt. The discharging mechanism is used for discharging outwards.

Further, the discharging mechanism comprises a sliding rail and a discharging plate. The sliding track is vertically arranged on one side, far away from the feeding mechanism, of the second support frame. The spout has been seted up to one side of the play flitch, and the opposite side of the play flitch is provided with the swash plate that is used for drawing the material. The discharging plate is arranged on the sliding rail in a sliding mode through the sliding groove, friction exists between the discharging plate and the sliding rail, and the discharging plate and the sliding rail are static relatively in an initial state. The discharging plate is horizontally provided with a friction block, and the friction block is used for being in contact with the second supporting frame.

Further, the plugging assembly comprises a blocking plate and a rotating block. The barrier plate is installed in discharge opening department, has seted up the mounting groove on the barrier plate. The rotating block comprises a rotating block and a blocking rod, the rotating block is rotatably arranged in the mounting groove, and the rotating block and the blocking plate can synchronously move along the horizontal direction. The blocking rod is fixedly connected with the rotating block, and in the initial state, the blocking rod is in contact with the sliding track.

Further, the adjusting mechanism comprises a recovery tank, a screw conveyor and a first motor. The recovery tank is arranged on the second support frame and is positioned under the hopper. The spiral conveyor is arranged on the first support frame, the lower end of the spiral conveyor is located at the recycling groove, and the upper end of the spiral conveyor is located above the first conveying belt. The first motor is fixedly arranged on the screw conveyer and used for driving the screw conveyer to rotate.

Further, the feeding mechanism also comprises two first transmission shafts and two second transmission shafts. The first transmission shaft is rotationally arranged on the first support frame, and two ends of the first conveying belt are respectively connected with the first transmission shaft. The second transmission shaft is rotatably arranged on the first support frame, and two ends of the second conveying belt are respectively connected with one second transmission shaft. The first drive mechanism includes a second motor and a drive belt. The second motor is fixedly installed on the first support frame, and the transmission belt is sleeved on the outer sides of the first transmission shaft, the second transmission shaft and the output shaft of the second motor.

Further, every second actuating mechanism includes the third motor, installs the backup pad on the second support frame, and the third motor is fixed to be set up in the backup pad, and the output shaft of third motor is connected on the band pulley.

Further, the first feeding plate and the second feeding plate are arranged oppositely. The first feeding plate is gradually close to the center line of the second support frame along the direction from top to bottom. The second feeding plate is gradually close to the center line of the second support frame along the direction from top to bottom.

Furthermore, the side of the first feeding plate adjacent to the second feeding plate has magnetism, and the side of the second feeding plate adjacent to the first feeding plate has magnetism.

Furthermore, the first support frame is further provided with two material guiding plates, and the two material guiding plates are respectively arranged at one ends, close to the second support frame, of the first conveying belt and the second conveying belt. Gaps are reserved between the material guiding plate and the first conveying belt and between the material guiding plate and the second conveying belt. And a channel for the hopper to pass through is arranged on the material guiding plate.

Furthermore, the length of the first conveying belt is shorter than that of the second conveying belt, the sieve plate is obliquely arranged, small-particle materials fall onto the first conveying belt from the sieve holes, and large-particle materials fall onto the second conveying belt through the obliquely arranged sieve plate.

The beneficial effects of the invention are: according to the feeding device for the concrete construction engineering, the first feeding plate is in contact with the adjacent second feeding plate and then forms a hopper for containing materials with the side end face of the second support frame, so that the first feeding plate and the second feeding plate are simple in structure. Flitch all slopes to set up on first flitch and the second, and first flitch and second material loading drop contact back of going up, the material is difficult for piling up on flitch and second are gone up to first flitch, and flitch homoenergetic is dismantled on first flitch and the second, makes things convenient for the clearance after the work.

In the face of the demand of lifting different heights of materials in the working process, the discharging mechanism and the plugging assembly can be simply adjusted, and the working efficiency is improved.

The hopper adopts magnetic force adsorption's mode to through the setting of sieve and first conveyer belt, second conveyer belt, make the large granule material arrange down, the tiny particle material is arranged last, has reduced the unrestrained of transportation. And the spiral conveyor is used for recovering the scattered small particles and conveying the small particles back to the first conveying belt, so that the waste of materials is reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a concrete construction project feeding device according to an embodiment of the present invention;

FIG. 2 is a right side view of an embodiment of a concrete construction work feeding apparatus of the present invention;

FIG. 3 is a front view of an embodiment of a concrete construction work feeding device of the present invention;

FIG. 4 is a top view of an embodiment of a concrete construction work feeding device of the present invention;

FIG. 5 is an enlarged view taken at A in FIG. 4;

FIG. 6 is a left side view of an embodiment of a concrete work project loading apparatus of the present invention;

FIG. 7 is an enlarged view at B in FIG. 6;

FIG. 8 is a front view of a loading mechanism of an embodiment of a concrete work project loading apparatus of the present invention;

FIG. 9 is an isometric view of a charging mechanism of an embodiment of a charging apparatus for a concrete work project according to the present invention;

fig. 10 is a schematic structural diagram of a discharging plate of an embodiment of the feeding device for the concrete construction project.

In the figure: 101. a feeding box; 102. a sieve plate; 103. a first conveyor belt; 104. a second conveyor belt; 105. a first support frame; 106. a second motor; 107. a screw conveyor; 108. a first motor; 201. a second support frame; 202. a recovery tank; 203. a first feeding plate; 204. a pulley; 205. a third conveyor belt; 206. a support plate; 207. a third motor; 208. a second feeding plate; 300. a discharging mechanism; 301. a blocking plate; 302. rotating the block; 303. a sliding track; 304. a discharge plate; 305. a chute.

Detailed Description

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

An embodiment of a concrete construction engineering feeding device according to the present invention is shown in fig. 1 to 10, and includes a feeding mechanism, a first driving mechanism, a feeding mechanism, an adjusting mechanism, a discharging mechanism 300, and two second driving mechanisms.

The feeding mechanism comprises a first support frame 105, a feeding box 101, a first conveyor belt 103, a second conveyor belt 104 and a screening deck 102. The feeding box 101 is fixedly arranged on the first supporting frame 105, and a discharge hole is formed in the lower end of the feeding box 101. The first conveying belt 103 and the second conveying belt 104 are horizontally arranged, the first conveying belt 103 and the second conveying belt 104 are both rotatably arranged on the first support frame 105, and the feeding box 101, the first conveying belt 103 and the second conveying belt 104 are sequentially arranged from top to bottom. The sieve plate 102 is arranged on the first support frame 105, the upper end of the sieve plate 102 is arranged at the discharge port, the lower end of the sieve plate 102 is arranged above the second conveyor belt 104, and sieve holes are formed in the sieve plate 102. The first driving mechanism is used for driving the first conveying belt 103 and the second conveying belt 104 to rotate.

The feeding mechanism comprises a second supporting frame 201, a plurality of plugging assemblies, two groups of conveying assemblies, a plurality of first feeding plates 203 and a plurality of second feeding plates 208. A plurality of bin outlets are formed in the second supporting frame 201 along the vertical direction, and the blocking assembly is used for blocking the bin outlets. Each set of conveyor assemblies comprises a third conveyor belt 205 and two pulleys 204. The belt wheel 204 rotates and is arranged on the second supporting frame 201, the third conveying belt 205 is vertically arranged, and the upper end and the lower end of the third conveying belt 205 are respectively connected with one belt wheel 204. The second drive mechanism is used to drive the pulley 204 in rotation. A plurality of first feeding plates 203 are uniformly distributed on one third conveyor belt 205, and a plurality of second feeding plates 208 are uniformly distributed on the other third conveyor belt 205. The first feeding plate 203 and the adjacent second feeding plate 208 can contact with each other, and the first feeding plate 203 and the adjacent second feeding plate 208 contact with each other and then form a hopper for containing materials with the side end surface of the second supporting frame 201. The first feeding plate 203 and the second feeding plate 208 can be detached.

The adjusting mechanism is used for conveying the materials scattered from the hopper to the first conveying belt 103. The discharging mechanism 300 is used for discharging outwards.

In this embodiment, the outfeed mechanism 300 comprises a sliding rail 303 and an outfeed plate 304. The sliding rail 303 is vertically arranged on one side of the second supporting frame 201 far away from the feeding mechanism. A chute 305 is arranged on one side of the discharge plate 304, and an inclined plate for guiding materials is arranged on the other side of the discharge plate 304. The discharge plate 304 is slidably disposed on the sliding rail 303 through the chute 305, and there is friction between the discharge plate 304 and the sliding rail 303, and in an initial state, the discharge plate 304 and the sliding rail 303 are relatively stationary. The discharging plate 304 is horizontally provided with a friction block, and the friction block is used for contacting with the second supporting frame 201. The discharge plate 304 may be slid into place according to the height at which the material is to be lifted. When there is not the material on the play flitch 304, the friction of play flitch 304 and slip track 303 makes a flitch 304 can not landing downwards, and when having the material on a flitch 304, the material gives the swash plate certain pressure, and the swash plate slope makes the clutch blocks contact second support frame 201 to make a flitch 304 can not landing downwards.

In this embodiment, the blocking assembly includes a blocking plate 301 and a turning block 302. The barrier plate 301 is installed in discharge opening department, has seted up the mounting groove on the barrier plate 301. The rotating block 302 comprises a rotating block and a blocking rod, the rotating block is rotatably arranged in the mounting groove, and the rotating block and the blocking plate 301 can synchronously move along the horizontal direction. The blocking rod is fixedly connected to the rotary block, and in an initial state, the blocking rod is in contact with the sliding rail 303. When the discharge opening at the position needs to be opened, the blocking rod is rotated to make the blocking rod fall off and contact with the sliding rail 303, and then the blocking plate 301 and the rotating block 302 are moved out together.

In the present embodiment, the adjustment mechanism includes the recovery tank 202, the screw conveyor 107, and the first motor 108. The recovery tank 202 is mounted on the second support frame 201 and is located right below the hopper. The screw conveyor 107 is disposed on the first support frame 105, a lower end of the screw conveyor 107 is located at the recovery tank 202, and an upper end of the screw conveyor 107 is located above the first conveyor belt 103. The first motor 108 is fixedly arranged on the screw conveyor 107, and the first motor 108 is used for driving the screw conveyor 107 to rotate. Due to vibration and the like generated during transportation, a part of the upper hopper falls down to the lower hopper and the bottom, and is finally accumulated in the recovery tank 202. The first motor 108 is driven, the first motor 108 enables the spiral conveyor 107 to work, the spiral conveyor 107 conveys the materials in the recovery tank 202 to the first conveying belt 103, and the materials are conveyed into the hopper again.

In this embodiment, the feeding mechanism further comprises two first transmission shafts and two second transmission shafts. The first transmission shaft is rotatably disposed on the first support frame 105, and two ends of the first conveyor belt 103 are respectively connected to one first transmission shaft. The second transmission shaft is rotatably disposed on the first support frame 105, and two ends of the second conveyor belt 104 are respectively connected to a second transmission shaft. The first drive mechanism includes a second motor 106 and a drive belt. The second motor 106 is fixedly mounted on the first support frame 105, and the transmission belt is sleeved on the outer sides of the first transmission shaft, the second transmission shaft and the output shaft of the second motor 106. And starting the second motor 106, wherein the second motor 106 drives the first transmission shaft and the second transmission shaft to rotate through a transmission belt.

In this embodiment, each second driving mechanism includes a third motor 207, a supporting plate 206 is mounted on the second supporting frame 201, the third motor 207 is fixedly disposed on the supporting plate 206, and an output shaft of the third motor 207 is connected to the pulley 204. The third motor 207 is started, and the third motor 207 drives the pulley 204 to rotate.

In the present embodiment, the first feeding plate 203 and the second feeding plate 208 are disposed opposite to each other. The first feeding plate 203 is gradually close to the center line of the second supporting frame 201 in the up-down direction. The second upper material plate 208 gradually approaches the center line of the second supporting frame 201 in the top-to-bottom direction.

In the present embodiment, a side of the first upper material plate 203 adjacent to the second upper material plate 208 has magnetism, and a side of the second upper material plate 208 adjacent to the first upper material plate 203 has magnetism. In other embodiments, magnets are mounted on the first feeding plate 203 on a side adjacent to the second feeding plate 208, and magnets are mounted on the second feeding plate 208 on a side adjacent to the first feeding plate 203. When the first feeding plate 203 and the second feeding plate 208 move to the lowest end of the third conveyor belt 205, the first feeding plate 203 and the second feeding plate 208 start to approach slowly and are mutually adsorbed by magnetic force, and form a hopper with the side wall of the second support frame 201 to contain the material from the feeding mechanism.

In this embodiment, two material guiding plates are further disposed on the first supporting frame 105, and the two material guiding plates are respectively disposed at one ends of the first conveying belt 103 and the second conveying belt 104 close to the second supporting frame 201. Gaps are arranged between the material guiding plate and the first conveying belt 103, and gaps are arranged between the material guiding plate and the second conveying belt 104. And a channel for the hopper to pass through is arranged on the material guiding plate. The guiding plates are used for guiding materials on the first conveying belt 103 and the second conveying belt 104, and the scattering of the materials in the conveying process is reduced.

In this embodiment, the length of the first conveyor belt 103 is shorter than that of the second conveyor belt 104, the sieve plate 102 is placed obliquely, the small-sized materials fall onto the first conveyor belt 103 through the sieve holes, and the large-sized materials fall onto the second conveyor belt 104 through the obliquely placed sieve plate 102. Through the arrangement of the sieve plate 102, the first conveyer belt 103 and the second conveyer belt 104, large-particle materials are positioned below small-particle materials, and the scattering of the materials in the conveying process is reduced.

The working process comprises the following steps: the movement direction of the hopper is from bottom to top. The second motor 106 is started, and the second motor 106 drives the first transmission shaft and the second transmission shaft to rotate through the transmission belt, so as to drive the first conveying belt 103 and the second conveying belt 104 to rotate. The third motor 207 is started, the third motor 207 drives the belt pulley 204 to rotate, the belt pulley 204 drives the third conveyer belt 205 to rotate, and the third conveyer belt 205 drives the first feeding plates 203 and the second feeding plates 208 to rotate. When the first feeding plate 203 and the second feeding plate 208 move to the lowest end of the third conveyor belt 205, the first feeding plate 203 and the second feeding plate 208 start to approach slowly and are mutually adsorbed by magnetic force, and form a hopper with the side wall of the second support frame 201 to contain the material from the feeding mechanism.

When the operation begins, the material is put into from feed box 101, and the material falls into on sieve 102 from the discharge gate department, and the material that the granule is less falls into on first conveyer belt 103 through the sieve mesh, and the material that the granule is less falls into on second conveyer belt 104 through sieve 102 to be carried feed mechanism department together, and adorn in the hopper with big granule under, the mode that the tiny particle is on.

The worker opens the proper blocking plate 301 according to the height required to lift the material, rotates the blocking rod to make the blocking rod fall off and contact with the sliding rail 303, then moves the blocking plate 301 and the rotating block 302 together, opens the discharge port at the position, slides the discharge plate 304 to a proper position, and waits for the material to arrive.

Due to vibration and the like generated during transportation, a part of the upper hopper falls down to the lower hopper and the bottom, and is finally accumulated in the recovery tank 202. The first motor 108 is driven, the first motor 108 enables the spiral conveyor 107 to work, the spiral conveyor 107 conveys the materials in the recovery tank 202 to the first conveying belt 103, and the materials are conveyed into the hopper again.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (10)

1. The utility model provides a concrete construction engineering loading attachment which characterized in that:

the automatic feeding device comprises a feeding mechanism, a first driving mechanism, a feeding mechanism, an adjusting mechanism, a discharging mechanism and two second driving mechanisms;

the feeding mechanism comprises a first support frame, a feeding box, a first conveying belt, a second conveying belt and a sieve plate; the feeding box is fixedly arranged on the first support frame, and the lower end of the feeding box is provided with a discharge hole; the first conveying belt and the second conveying belt are horizontally arranged, the first conveying belt and the second conveying belt can be rotatably arranged on the first support frame, and the feeding box, the first conveying belt and the second conveying belt are sequentially arranged from top to bottom; the sieve plate is arranged on the first support frame, the upper end of the sieve plate is positioned at the discharge port, the lower end of the sieve plate is positioned above the second conveying belt, and sieve pores are formed in the sieve plate; the first driving mechanism is used for driving the first conveying belt and the second conveying belt to rotate;

the feeding mechanism comprises a second support frame, a plurality of plugging assemblies, two groups of conveying assemblies, a plurality of first feeding plates and a plurality of second feeding plates; a plurality of discharge openings are formed in the second support frame along the vertical direction, and the plugging assembly is used for plugging the discharge openings; each group of conveying components comprises a third conveying belt and two belt wheels; the belt wheel is rotatably arranged on the second support frame, the third conveying belt is vertically arranged, and the upper end and the lower end of the third conveying belt are respectively connected with one belt wheel; the second driving mechanism is used for driving the belt wheel to rotate; the first feeding plates are uniformly distributed on one third conveying belt, and the second feeding plates are uniformly distributed on the other third conveying belt; the first feeding plate and the adjacent second feeding plate can be contacted with each other, and the first feeding plate and the adjacent second feeding plate are contacted with each other and then form a hopper for containing materials with the side end surface of the second support frame; the first feeding plate and the second feeding plate can be detached;

the adjusting mechanism is used for conveying the materials scattered from the hopper onto the first conveying belt; the discharging mechanism is used for discharging outwards.

2. The concrete construction engineering loading attachment of claim 1, characterized in that:

the discharging mechanism comprises a sliding rail and a discharging plate; the sliding track is vertically arranged on one side, far away from the feeding mechanism, of the second support frame; one side of the discharge plate is provided with a chute, and the other side of the discharge plate is provided with an inclined plate for guiding materials; the discharging plate is arranged on the sliding rail in a sliding mode through the sliding groove, friction exists between the discharging plate and the sliding rail, and the discharging plate and the sliding rail are relatively static in an initial state; the discharging plate is horizontally provided with a friction block, and the friction block is used for being in contact with the second supporting frame.

3. The concrete construction engineering loading attachment of claim 2, characterized in that:

the plugging assembly comprises a blocking plate and a rotating block; the blocking plate is arranged at the discharge opening and provided with an installation groove; the rotating block comprises a rotating block and a blocking rod, the rotating block is rotatably arranged in the mounting groove, and the rotating block and the blocking plate can synchronously move along the horizontal direction; the blocking rod is fixedly connected to the rotating block, and in an initial state, the blocking rod is in contact with the sliding rail.

4. The concrete construction engineering loading attachment of claim 1, characterized in that:

the adjusting mechanism comprises a recovery tank, a spiral conveyor and a first motor; the recovery tank is arranged on the second support frame and is positioned right below the hopper; the spiral conveyor is arranged on the first support frame, the lower end of the spiral conveyor is positioned at the recycling groove, and the upper end of the spiral conveyor is positioned above the first conveying belt; the first motor is fixedly arranged on the screw conveyer and used for driving the screw conveyer to rotate.

5. The concrete construction engineering loading attachment of claim 1, characterized in that:

the feeding mechanism also comprises two first transmission shafts and two second transmission shafts; the first transmission shaft is rotationally arranged on the first support frame, and two ends of the first conveying belt are respectively connected with one first transmission shaft; the second transmission shaft is rotatably arranged on the first support frame, and two ends of the second conveying belt are respectively connected with one second transmission shaft;

the first driving mechanism comprises a second motor and a transmission belt; the second motor is fixedly arranged on the first support frame, and the transmission belt is sleeved on the outer sides of the output shafts of the first transmission shaft, the second transmission shaft and the second motor.

6. The concrete construction engineering loading attachment of claim 1, characterized in that:

every second actuating mechanism includes the third motor, installs the backup pad on the second support frame, and the third motor is fixed to be set up in the backup pad, and the output shaft of third motor is connected on the band pulley.

7. The concrete construction engineering loading attachment of claim 1, characterized in that:

the first feeding plate and the second feeding plate are arranged oppositely; the first feeding plate is gradually close to the center line of the second support frame along the direction from top to bottom; the second feeding plate is gradually close to the center line of the second support frame along the direction from top to bottom.

8. The concrete construction engineering loading attachment of claim 1, characterized in that:

the first feeding plate is provided with magnetism at one side adjacent to the second feeding plate, and the second feeding plate is provided with magnetism at one side adjacent to the first feeding plate.

9. The concrete construction engineering loading attachment of claim 1, characterized in that:

the first support frame is also provided with two material guiding plates which are respectively arranged at one ends of the first conveying belt and the second conveying belt close to the second support frame; gaps are reserved between the material guiding plate and the first conveying belt and between the material guiding plate and the second conveying belt; and a channel for the hopper to pass through is arranged on the material guiding plate.

10. The concrete construction engineering loading attachment of claim 1, characterized in that:

the length of first conveyer belt is shorter than the length of second conveyer belt, and the sieve slope is placed, and the material of tiny granule falls into on the first conveyer belt from sieve mesh department, and the sieve that the material of large granule placed through the slope falls onto the second conveyer belt.

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