CN115649806A - Conveyer of material for bridge construction - Google Patents

Abstract

The invention relates to the field of transportation devices, in particular to a transportation device for materials for bridge construction. The utility model provides a conveyer of material for bridge construction includes mounting bracket and conveying mechanism, and conveying mechanism sets up on the mounting bracket, and conveying mechanism includes pipeline, flood dragon mechanism, actuating mechanism and strikes off the mechanism. The conveying pipeline is vertically arranged, a feeding hole is formed in the lower end of the conveying pipeline, and a discharging hole is formed in the upper end of the conveying pipeline; when the materials are conveyed, the materials are put into the conveying pipeline from the feeding hole, and the materials are driven by the flood dragon mechanism to move to the discharging hole and are discharged from the discharging hole. Strike off the mechanism and be used for when stopping to the input material in the pipeline, upwards promote the material that the flood dragon mechanism is gone up to be detained, push away the discharge gate with the material that pipeline stayed. The screw conveyer can apply external force to the materials retained on the screw conveyer mechanism to discharge the materials retained in the conveying pipeline, so that manual operation is reduced, and the working efficiency is high.

Description

Conveyer of material for bridge construction

Technical Field

The invention relates to the field of transportation devices, in particular to a transportation device for materials for bridge construction.

Background

When a bridge is built, more sandstone materials are needed, so that a transportation device is needed. Most of current conveyer only can transport the grit on the level land, however when building the bridge, need often transport the grit toward the eminence, this just leads to traditional level land conveyer not to be suitable for, need use one kind can be to the conveyer of eminence transport, the utility model patent of No. CN216637831U provides a grit conveyer for building bridge, the form that adopts screw feed transports the grit to the eminence, but inside remaining problem can appear in this kind of mode, because building material easily agglomerates after doing, so can cause subsequent jam, influence the construction process.

Disclosure of Invention

The invention provides a transportation device for materials for bridge construction, which aims to solve the problem that the existing transportation device can effectively and completely discharge the materials in a conveying pipeline.

The invention relates to a transportation device for materials for bridge construction, which adopts the following technical scheme:

the utility model provides a conveyer of material for bridge construction includes mounting bracket and conveying mechanism, and conveying mechanism sets up on the mounting bracket, and conveying mechanism includes pipeline, flood dragon mechanism, actuating mechanism and strikes off the mechanism.

The conveying pipeline is vertically arranged, a feeding hole is formed in the lower end of the conveying pipeline, and a discharging hole is formed in the upper end of the conveying pipeline; the flood dragon mechanism is vertically arranged in the conveying pipeline; the driving mechanism is used for driving the flood dragon mechanism to rotate; when the materials are conveyed, the materials are put into the conveying pipeline from the feeding hole, and the materials are driven by the flood dragon mechanism to move to the discharging hole and are discharged from the discharging hole. Strike off the mechanism and be used for when stopping to the input material in the pipeline, upwards promote the material that is detained on the flood dragon mechanism, push away the discharge gate with the material that pipeline stayed.

Furthermore, a first annular groove, a second annular groove and a vertical groove are arranged on the inner wall of the conveying pipeline, the first annular groove is arranged below the feed inlet, and the second annular groove is arranged below the discharge outlet; the vertical groove extends along the up-down direction, and the lower end of the vertical groove is communicated with the first ring groove.

Flood dragon mechanism includes drive shaft and helical blade, and the drive shaft rotationally sets up in pipeline around a vertical axis, and helical blade installs on the drive shaft and extends around the circumference spiral of drive shaft.

The scraping mechanism comprises a scraping plate assembly and a stopping assembly; the scraper component comprises a scraper and a spiral ring strip; the scraping plate is vertically arranged in one pitch of the helical blade, and the upper end and the lower end of the scraping plate are abutted against the helical blade; the spiral ring strip extends to the upper end of the scraper from the lower end of the scraper in a spiral way, the rotating direction of the spiral ring strip is the same as that of the spiral blade, the spiral ring strip is arranged along the edge of the spiral blade in a sliding way, and the outer edge of the spiral ring strip is in contact with the inner wall surface of the conveying pipeline; the scraper extends along the radial direction of the driving shaft, and the inner end of the scraper is contacted with the driving shaft; the outer end of the scraper is provided with a sliding block, and the sliding block is positioned in the first annular groove in an initial state; when materials are put into the feeding hole in the process that the driving shaft rotates around the first circumferential direction, the stopping component is used for stopping the sliding block from entering the vertical groove, so that the scraping plate rotates along the first annular groove under the driving of the helical blade; and when the drive shaft around first circumferential direction pivoted in-process, when stopping to the feed inlet input material, backstop subassembly is used for making the slider get into in the vertical groove and rise to the second annular along vertical groove in, later makes the slider rotate along the second annular, pushes away the material of scraper blade front side to the bin outlet.

Further, a horizontal mounting groove and a vertical mounting groove are formed in the inner wall of the conveying pipeline; the horizontal mounting groove is arranged above the first ring groove, and one end of the horizontal mounting groove is communicated with the vertical groove; the vertical mounting groove and the horizontal mounting groove are respectively arranged on two sides of the vertical groove; the lower end of the vertical mounting groove is communicated with the first ring groove; the stop assembly comprises a transverse stop block, a longitudinal stop block and a driving part; the transverse stopping block is arranged in a sliding manner along the horizontal mounting groove, is positioned in the vertical groove in an initial state, and has a lower surface flush with the upper groove wall of the first ring groove to cut off the communication part between the first ring groove and the vertical groove; the longitudinal stopping block is slidably arranged along the vertical mounting groove and is positioned above the first ring groove in an initial state; the drive division is used for along first circumferential direction pivoted in-process and when stopping to the feed inlet input material at the drive shaft, impel horizontal backstop piece to withdraw from perpendicular inslot, and impel vertical backstop piece to move down to offset with the lower cell wall of first annular, make during the drive shaft rotates, the slider rotates to the intercommunication department of perpendicular groove and first annular under helical blade's drive, later the slider rises along perpendicular groove under the restriction of vertical backstop piece and helical blade, until getting into the second annular in, last slider is at first week upward along the second annular rotation under helical blade's drive.

Further, the driving part comprises a first motor, a first screw rod, a first adjusting block, a second screw rod and a second adjusting block; the first motor is arranged on the outer side of the conveying pipeline; the first screw rod is horizontally arranged, the two ends of the first screw rod are respectively a first end part and a second end part, the first end part of the first screw rod is arranged on an output shaft of the first motor, and the second end part of the first screw rod is provided with a first bevel gear; the first adjusting block is provided with a first threaded hole in screw transmission fit with the first screw rod, and the first adjusting block is connected with the transverse stop block; the first motor drives the first screw rod to rotate during working, the first screw rod drives the first adjusting block to horizontally move along the first screw rod, and the first adjusting block drives the transverse stopping block to move in the horizontal mounting groove during moving.

The second screw rod is vertically arranged, the second screw rod is rotatably arranged on the conveying pipeline around the axis of the second screw rod, and a second bevel gear meshed with the first bevel gear is arranged at the lower end of the second screw rod; a second threaded hole in screw transmission fit with the second screw is formed in the second adjusting block, and the second adjusting block is connected with the longitudinal stop block; when the first screw rod rotates, the second screw rod is driven to rotate through the first bevel gear and the second bevel gear, and when the first screw rod rotates to drive the transverse stopping block to move towards one side far away from the vertical groove, the second screw rod drives the second adjusting block to move downwards.

Further, a first sliding rod and a first spring are mounted on the transverse stop block; the first adjusting block is provided with a first through hole, the first adjusting block is sleeved on the first sliding rod through the first through hole, and one end of the first sliding rod is provided with a first end cover for preventing the first adjusting block from being separated from the first sliding rod; first slide bar is located to first spring cover, and the one end and the horizontal backstop piece of first spring are connected, and the other end and the first regulating block of first spring are connected.

The longitudinal stop block is provided with a second sliding rod and a second spring; a second through hole is formed in the second adjusting block, the second adjusting block is sleeved on the second sliding rod through the second through hole, and a second end cover for preventing the second adjusting block from being separated from the second sliding rod is installed at one end of the second sliding rod; the second sliding rod is sleeved with the second spring, one end of the second spring is connected with the longitudinal stop block, and the other end of the second spring is connected with the second adjusting block.

Furthermore, a placing groove is further formed in the conveying pipeline, the upper end of the placing groove is communicated with the second annular groove, the driving assembly further comprises a one-way stop block and a third spring, the one-way stop block is arranged in the placing groove, the lower end of the one-way stop block is connected to the lower groove wall of the placing groove through the third spring, an inclined surface extending backwards from top to bottom is arranged on the rear side of the one-way stop block in the first circumferential direction, and the sliding block can downwards extrude the one-way stop block under the action of the inclined surface when rotating along the second annular groove in the first circumferential direction; when the reset is needed, the driving shaft rotates around the axis of the driving shaft along the second circumferential direction, and when the sliding block moves to the front side of the one-way stop block, the sliding block moves downwards along the vertical groove under the action of the second stop block and the helical blade until entering the first annular groove.

Further, the driving mechanism further comprises a second motor, a third bevel gear and a fourth bevel gear; the second motor is arranged on the mounting frame, the third bevel gear is arranged on an output shaft of the second motor, and the fourth bevel gear is arranged at the lower end of the driving shaft and meshed with the third bevel gear; when materials need to be transported, the second motor drives the driving shaft to rotate around the first circumferential direction through the third bevel gear and the fourth bevel gear; when the motor is reset, the second motor drives the driving shaft to rotate around the second circumferential direction through the third bevel gear and the fourth bevel gear.

Furthermore, an installation cavity is formed inside the installation frame, and the second motor is arranged inside the installation cavity; the inside of installation cavity is provided with the residue and collects the storehouse, and the lower extreme intercommunication in storehouse and pipeline is collected to the residue is connected with between the storehouse and is used for guiding the material to the inside guide board in residue collection storehouse with the residue.

The invention has the beneficial effects that: the transportation device for the materials for bridge construction transports the materials from bottom to top during bridge construction. Due to the drawback of the flood dragon mechanism, when the flood dragon mechanism stops feeding materials into the conveying pipeline, the thrust of the upward transmission of the materials disappears, and the materials on the flood dragon mechanism are not discharged from the discharge hole any more. According to the flood dragon type automatic material discharging device, the scraping mechanism is arranged, so that external force can be applied to materials staying on the flood dragon mechanism, the materials staying in the conveying pipeline are discharged, manual operation is reduced, and the working efficiency is high.

Through setting up the spiral ring strip, prevent that the material of scraper blade upside from falling the below of scraper blade. Through setting up the residue and collecting the storehouse, can collect the residual material that the in-process that the scraper blade resets carried. After the materials in the conveying pipeline are completely discharged, the scraping assembly can be reset, and the next use is facilitated.

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 view of an embodiment of a transportation device for bridge construction materials according to the present invention;

FIG. 2 is a front view of an embodiment of the present invention of a material transportation device for bridge construction;

FIG. 3 is a cross-sectional view of a transportation device for bridge construction materials according to the present invention;

FIG. 4 is a schematic structural diagram of a scraper and a spiral ring of the transportation device for bridge construction materials of the present invention;

FIG. 5 is a schematic structural view of a flood dragon mechanism and a scraping mechanism of the transportation device for bridge construction materials of the present invention;

FIG. 6 is an enlarged view taken at A in FIG. 5;

fig. 7 is an enlarged view of fig. 5 at B.

In the figure: 100. a feed inlet; 110. a delivery conduit; 120. a discharge port; 130. a mounting frame; 140. a helical blade; 200. a second motor; 210. a fourth bevel gear; 211. a third bevel gear; 220. a drive shaft; 230. a squeegee; 231. a slider; 232. a helical loop; 240. a first motor; 250. a first screw; 251. a first bevel gear; 252. a first spring; 253. a first end cap; 260. a second screw; 261. a second bevel gear; 262. a second spring; 263. a second end cap; 270. a first regulating block; 271. a second regulating block; 280. a transverse stop block; 281. a longitudinal stop block; 282. a one-way stop block; 283. a third spring; 300. a residue collection bin; 301. a guide plate.

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.

In the embodiment of the transportation device for bridge construction materials, as shown in fig. 1 to 7, the transportation device for bridge construction materials comprises an installation frame 130 and a conveying mechanism, wherein the conveying mechanism is arranged on the installation frame 130 and comprises a conveying pipeline 110, a flood dragon mechanism, a driving mechanism and a scraping mechanism.

The conveying pipeline 110 is vertically arranged, the lower end of the conveying pipeline 110 is provided with a feeding hole 100, and the upper end is provided with a discharging hole 120; flood dragon mechanism sets up vertically in pipeline 110. The driving mechanism is used for driving the flood dragon mechanism to rotate; when materials are conveyed, the materials are put into the conveying pipeline 110 from the feeding hole 100, and the materials are driven by the flood dragon mechanism to move to the discharging hole 120 and are discharged from the discharging hole 120.

The scraping mechanism is used for pushing up the materials retained on the auger mechanism when the materials are stopped to be put into the conveying pipeline 110, so that the materials retained on the conveying pipeline 110 are pushed out of the discharge hole 120, and then the materials retained on the helical blade 140 are discharged. Specifically, when the material is stopped to be put into the conveying pipeline 110, the thrust of the upward transmission of the material is caused to disappear, and the material on the dragon mechanism is no longer discharged from the discharge hole 120. Through setting up the mechanism of striking off, can exert external force to the material that is detained on the flood dragon mechanism, will detain the material discharge in pipeline 110.

In this embodiment, the inner wall of the conveying pipe 110 is provided with a first annular groove, a second annular groove and a vertical groove (not shown in the figure), the first annular groove is arranged below the feeding hole 100, and the second annular groove is arranged below the discharging hole 120; the vertical groove extends along the up-down direction, and the lower end of the vertical groove is communicated with the first ring groove.

The flood dragon mechanism comprises a driving shaft 220 and a spiral blade 140, wherein the driving shaft 220 is rotatably arranged in the conveying pipeline 110 around a vertical axis, and the spiral blade 140 is arranged on the driving shaft 220 and extends spirally around the circumference of the driving shaft 220. The operating principle of the flood dragon mechanism is that the rotating helical blade 140 pushes the material to carry out helical conveying, so that the force of the material not rotating together with the helical blade 140 is the self weight of the material and the frictional resistance of the conveying pipeline 110 to the material.

The scraping mechanism includes a scraper assembly and a stop assembly. The squeegee assembly includes a squeegee 230 and a helical circumferential strip 232; the scraping plate 230 is vertically arranged and is positioned in one pitch of the spiral blade 140, and the upper end and the lower end of the scraping plate 230 are abutted against the spiral blade 140; the spiral ring strip 232 extends from the lower end of the scraper 230 to the upper end of the scraper 230 in a spiral manner, the spiral direction is the same as that of the spiral blade 140, the spiral ring strip 232 is slidably arranged along the edge of the spiral blade 140, and the outer edge of the spiral ring strip 232 is in contact with the inner wall surface of the conveying pipeline 110; the scrapers 230 extend in the radial direction of the driving shaft 220, and the inner ends of the scrapers 230 contact the driving shaft 220; the outer end of the scraping plate 230 is provided with a sliding block 231, and the sliding block 231 is positioned in the first annular groove in the initial state; in the process that the driving shaft 220 rotates around the first circumferential direction, when the material is fed into the feed inlet 100, the stopping assembly is used for stopping the sliding block 231 from entering the vertical groove, so that the scraping plate 230 rotates along the first annular groove in the first circumferential direction under the driving of the helical blade 140; and when the driving shaft 220 rotates around the first circumferential direction, and stops to input the material into the material inlet 100, the stopping component is used for urging the sliding block 231 to enter the vertical groove and ascend to the second annular groove along the vertical groove, and then the sliding block 231 rotates along the second annular groove to push the material on the front side to the material outlet. Specifically, the first circumferential direction is a clockwise direction as viewed from above as shown in fig. 3 and 5.

In the present embodiment, a horizontal installation groove and a vertical installation groove (not shown in the figure) are provided on the inner wall of the delivery pipe 110; the horizontal mounting groove is arranged above the first ring groove, and one end of the horizontal mounting groove is communicated with the vertical groove; the vertical mounting groove and the horizontal mounting groove are respectively arranged on two sides of the vertical groove; the lower end of the vertical mounting groove is communicated with the first ring groove; as shown in fig. 5 and 6, the stopper assembly includes a lateral stopper 280, a longitudinal stopper 281, and a driving part; the transverse stopping block 280 is slidably arranged along the horizontal mounting groove, the transverse stopping block 280 is positioned in the vertical groove in an initial state, the lower surface of the transverse stopping block 280 is flush with the upper groove wall of the first ring groove, and the communication part of the first ring groove and the vertical groove is cut off, so that the sliding block 231 can only slide along the first ring groove; the longitudinal stop block 281 is slidably arranged along the vertical installation groove, and the longitudinal stop block 281 is positioned above the first ring groove in an initial state; the driving portion is configured to, in the process that the driving shaft 220 continuously rotates, when the material feeding port 100 stops feeding the material, cause the transverse stop block 280 to exit from the vertical groove, and cause the longitudinal stop block 281 to move downward to abut against a lower groove wall of the first annular groove, and one side of the longitudinal stop block 281 is flush with one side groove wall of the vertical groove, so that when the driving shaft 220 rotates along the first circumferential direction, the slider 231 rotates to a communication position between the vertical groove and the first annular groove under the driving of the helical blade 140, and then the slider 231 ascends along the vertical groove under the restriction of the longitudinal stop block 281 and the helical blade 140 until the slider 231 enters the second annular groove, and finally rotates along the second annular groove in the first circumferential direction under the driving of the helical blade 140.

When the sliding block 231 moves upwards along the vertical slot, the scraper 230 pushes the material in front to move upwards spirally, and the inside of the conveying pipe 110 is gradually discharged from the discharge hole 120. When the sliding block 231 enters the second annular groove and drives the scraping plate 230 to rotate to the discharge hole 120 along the second annular groove in the first circumferential direction, the material on the front side of the scraping plate 230 is completely discharged.

In the present embodiment, the driving part includes a first motor 240, a first screw 250, a first adjusting block 270, a second screw 260, and a second adjusting block 271. The first motor 240 is installed at the outer side of the conveying pipe 110; the first screw 250 is horizontally disposed, two ends of the first screw 250 are respectively a first end and a second end, the first end of the first screw 250 is mounted on the output shaft of the first motor 240, and the second end of the first screw 250 is mounted with a first bevel gear 251. The first adjusting block 270 is provided with a first threaded hole in screw transmission fit with the first screw 250, and the first adjusting block 270 is connected with the transverse stop block 280; when the first motor 240 works, the first screw 250 is driven to rotate, the first screw 250 rotates to drive the first adjusting block 270 to horizontally move along the first screw 250, and when the first adjusting block 270 moves, the transverse stopping block 280 is driven to move in the horizontal mounting groove.

The second screw 260 is vertically arranged, the second screw 260 is rotatably arranged on the conveying pipeline 110 around the axis of the second screw 260, and the lower end of the second screw 260 is provided with a second bevel gear 261 engaged with the first bevel gear 251; a second threaded hole in screw driving fit with the second screw 260 is formed in the second adjusting block 271, and the second adjusting block 271 is connected with the longitudinal stop block 281; when the first screw 250 rotates, the second screw 260 is driven to rotate by the first bevel gear 251 and the second bevel gear 261, when the first screw 250 rotates to drive the transverse stopping block 280 to move towards the side far away from the vertical chute, the second screw 260 drives the second adjusting block 271 to move downwards, and when the second adjusting block 271 moves downwards, the longitudinal stopping block 281 is driven to move downwards along the vertical chute.

Further, the lateral stopper 280 is mounted with a first sliding rod and a first spring 252; a first through hole is formed in the first adjusting block 270, the first adjusting block 270 is sleeved on the first sliding rod through the first through hole, and a first end cover 253 for preventing the first adjusting block 270 from being separated from the first sliding rod is installed at one end of the first sliding rod; the first spring 252 is sleeved on the first sliding rod, one end of the first spring 252 is connected with the transverse stop block 280, and the other end of the first spring 252 is connected with the first adjusting block 270, so that the first adjusting block 270 is prevented from being damaged when stressed.

The longitudinal stopper 281 is mounted with a second slide bar and a second spring 262; a second through hole is formed in the second adjusting block 271, the second adjusting block 271 is sleeved on the second sliding rod through the second through hole, and a second end cover 263 for preventing the second adjusting block 271 from being separated from the second sliding rod is installed at one end of the second sliding rod; the second spring 262 is sleeved on the second sliding rod, one end of the second spring 262 is connected with the longitudinal stop block 281, and the other end of the second spring 262 is connected with the second adjusting block 271, so that the second adjusting block 271 is prevented from being damaged when being stressed.

In this embodiment, the delivery pipe 110 is further provided with a placement groove, an upper end of the placement groove is communicated with the second annular groove, the driving assembly further includes a one-way stop block 282 and a third spring 283, the one-way stop block 282 is disposed in the placement groove, a lower end of the one-way stop block 282 is connected to a lower groove wall of the placement groove through the third spring 283, in the first circumferential direction, a rear side of the one-way stop block 282 is provided with an inclined surface extending from top to bottom, and the slider 231 can press the one-way stop block 282 downwards under the action of the inclined surface when rotating along the second annular groove in the first circumferential direction. When the reset is required, the driving shaft 220 rotates around its axis in the second circumferential direction, and when the sliding block 231 moves to the front side of the one-way stop 282, the sliding block 231 moves downward along the vertical groove under the action of the second stop and the spiral blade 140 until entering the first annular groove.

In this embodiment, the driving mechanism further includes a second motor 200, a third bevel gear 211, and a fourth bevel gear 210; the second motor 200 is arranged on the mounting bracket 130, the third bevel gear 211 is arranged on the output shaft of the second motor 200, and the fourth bevel gear 210 is arranged at the lower end of the driving shaft 220 and meshed with the third bevel gear 211; when materials need to be transported, the second motor 200 drives the driving shaft 220 to rotate around the first circumferential direction through the third bevel gear 211 and the fourth bevel gear 210 when the materials are transported; when the motor is reset, the second motor 200 drives the driving shaft 220 to rotate around the second circumferential direction through the third bevel gear 211 and the fourth bevel gear 210.

In this embodiment, a mounting cavity is disposed inside the mounting bracket 130, and the second motor 200 is disposed inside the mounting bracket 130; the inside of installation cavity is provided with residue collection bin 300, and residue collection bin 300 communicates with the lower extreme of conveying pipeline 110, is connected with between conveying pipeline 110 and the residue collection bin 300 and is used for leading the inside guide plate 301 of material to residue collection bin 300 for scraper blade 230 is at the in-process that resets, will be in its below residue scraping off to finally push away the residue that scrapes to guide plate 301, be convenient for guide remaining material to in the residue collection bin 300.

The working principle and the working method of the transportation device for the bridge construction materials in the embodiment are as follows:

first, the second motor 200 is turned on, the second motor 200 drives the driving shaft 220 to rotate around its axis in the first circumferential direction through the first bevel gear 251 and the second bevel gear 261, and the driving shaft 220 drives the helical blade 140 to rotate when rotating. The materials are put into the feed inlet 100, are spirally driven upwards under the action of the flood dragon mechanism, and are discharged from the discharge outlet 120. In this state, the scraper 230 is rotated in the first circumferential direction along the first ring groove by the slider 231.

If the feeding of the material into the feeding hole 100 is stopped, at this time, the material inside the conveying pipeline 110 is difficult to be conveyed upwards under the influence of gravity, at this time, the first motor 240 is started, so that the first motor 240 drives the first screw 250 to rotate, the first screw 250 drives the second screw 260 to rotate through the first bevel gear 251 and the second bevel gear 261, the first screw 250 drives the first adjusting block 270 to move towards the side far away from the vertical groove along the first screw 250 when rotating, and the first adjusting block 270 drives the transverse stopping block 280 to move towards the side far away from the vertical groove in the horizontal installation groove when moving, so that the connecting channel between the vertical groove and the first ring groove is opened. Meanwhile, the second screw 260 drives the second adjusting block 271 to move downwards when rotating, the second adjusting block 271 drives the longitudinal stop block 281 to move downwards to intercept the rotation of the sliding block 231 in the first ring groove, when the sliding block 231 moves to contact with the longitudinal stop block 281 along with the rotation of the spiral blade 140, the longitudinal stop block 281 and the spiral blade 140 rise along the vertical groove under the limitation until the sliding block 231 enters the second ring groove, and finally, the sliding block rotates along the second ring groove in the first circumferential direction under the driving of the spiral blade 140. When the sliding block 231 moves upwards along the vertical slot, the scraper 230 pushes the material in front to move upwards spirally, and the inside of the conveying pipe 110 is gradually discharged from the discharge hole 120. When the sliding block 231 enters the second annular groove and drives the scraper 230 to rotate to the discharge hole 120 along the second annular groove in the first circumferential direction, the material on the front side of the scraper 230 is completely discharged.

During the ascending process of the scraper 230, the spiral ring strip 232 slides along the edge of the spiral blade 140, and the outer edge of the spiral ring strip 232 contacts with the inner wall of the conveying pipe 110, so when the scraper 230 cleans the material on the spiral blade 140, the material scraped by the scraper 230 does not fall below the scraper 230.

When the material on the spiral blade 140 is completely discharged, that is, after the scraping plate 230 completely passes through the discharging hole 120, the second motor 200 is rotated reversely, so that the driving shaft 220 and the spiral blade 140 rotate in the second circumferential direction, the spiral blade 140 rotates in the second circumferential direction, the sliding block 231 is driven to rotate in the second circumferential direction in the second ring groove, when the sliding block 231 rotates to contact with the one-way stop block 282, the sliding block cannot rotate under the action of the one-way stop block 282, and then the sliding block enters the vertical groove under the action of the spiral blade 140 and the one-way stop block 282, slides downwards along the vertical groove, and then enters the first ring groove.

When the slider 231 enters the first ring groove, the first motor 240 is reversely activated, so that the lateral and longitudinal stoppers 280 and 281 are reset. If scraper blade 230 carries the residual material in the downward movement process, scraper blade 230 pushes away the residual material to guide board 301 department along the in-process of first annular rotation, later during the material gets into residue collecting bin 300 along guide board 301, regularly clear up the residue of residue collecting bin 300 inside can.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and should not be taken as limiting the scope of the present invention, which is intended to cover any modifications, equivalents, improvements, etc. within the spirit and scope of the present invention.

Claims (8)

1. The utility model provides a conveyer of material for bridge construction which characterized in that: the conveying mechanism is arranged on the mounting frame and comprises a conveying pipeline, a flood dragon mechanism, a driving mechanism and a scraping mechanism;

the conveying pipeline is vertically arranged, a feeding hole is formed in the lower end of the conveying pipeline, and a discharging hole is formed in the upper end of the conveying pipeline; the flood dragon mechanism is vertically arranged in the conveying pipeline; the driving mechanism is used for driving the flood dragon mechanism to rotate; when materials are conveyed, the materials are put into the conveying pipeline from the feeding hole, are driven by the flood dragon mechanism to move to the discharging hole and are discharged from the discharging hole;

strike off the mechanism and be used for when stopping to the input material in the pipeline, upwards promote the material that is detained on the flood dragon mechanism, push away the discharge gate with the material that pipeline stayed.

2. The transportation device for the bridge construction material according to claim 1, characterized in that: the inner wall of the conveying pipeline is provided with a first annular groove, a second annular groove and a vertical groove, the first annular groove is arranged below the feed inlet, and the second annular groove is arranged below the discharge outlet; the vertical groove extends along the up-down direction, and the lower end of the vertical groove is communicated with the first annular groove;

the flood dragon mechanism comprises a driving shaft and a spiral blade, the driving shaft is rotatably arranged in the conveying pipeline around a vertical axis, and the spiral blade is arranged on the driving shaft and spirally extends around the circumference of the driving shaft;

the scraping mechanism comprises a scraping plate assembly and a stopping assembly; the scraper component comprises a scraper and a spiral ring strip; the scraping plate is vertically arranged in one pitch of the helical blade, and the upper end and the lower end of the scraping plate are abutted against the helical blade; the spiral ring strip extends to the upper end of the scraper from the lower end of the scraper in a spiral way, the rotating direction of the spiral ring strip is the same as that of the spiral blade, the spiral ring strip is arranged along the edge of the spiral blade in a sliding way, and the outer edge of the spiral ring strip is in contact with the inner wall surface of the conveying pipeline; the scraper extends along the radial direction of the driving shaft, and the inner end of the scraper is contacted with the driving shaft; the outer end of the scraping plate is provided with a sliding block, and the sliding block is positioned in the first ring groove in an initial state; when materials are put into the feeding hole in the process that the driving shaft rotates around the first circumferential direction, the stopping component is used for stopping the sliding block from entering the vertical groove, so that the scraping plate rotates along the first annular groove under the driving of the helical blade; and when the drive shaft around first circumferential direction pivoted in-process, when stopping to the feed inlet input material, backstop subassembly is used for making the slider get into in the vertical groove and rise to the second annular along vertical groove in, later makes the slider rotate along the second annular, pushes away the material of scraper blade front side to the bin outlet.

3. The transportation device for materials for bridge construction according to claim 2, wherein: a horizontal mounting groove and a vertical mounting groove are formed in the inner wall of the conveying pipeline; the horizontal mounting groove is arranged above the first ring groove, and one end of the horizontal mounting groove is communicated with the vertical groove; the vertical mounting groove and the horizontal mounting groove are respectively arranged on two sides of the vertical groove; the lower end of the vertical mounting groove is communicated with the first ring groove; the stop assembly comprises a transverse stop block, a longitudinal stop block and a driving part; the transverse stopping block is arranged in a sliding manner along the horizontal mounting groove, is positioned in the vertical groove in an initial state, and has a lower surface flush with the upper groove wall of the first ring groove to cut off the communication part of the first ring groove and the vertical groove; the longitudinal stopping block is slidably arranged along the vertical mounting groove and is positioned above the first ring groove in an initial state; the driving part is used for enabling the transverse stopping block to withdraw from the vertical groove when the driving shaft stops inputting materials to the feeding hole along the first circumferential rotating process, and enabling the longitudinal stopping block to move downwards to be abutted to the lower groove wall of the first annular groove, so that when the driving shaft rotates, the sliding block rotates to the communication position of the vertical groove and the first annular groove under the driving of the spiral blade, then the sliding block ascends along the vertical groove under the limitation of the longitudinal stopping block and the spiral blade until the sliding block enters the second annular groove, and finally the sliding block rotates along the second annular groove in the first circumferential direction under the driving of the spiral blade.

4. The transportation device for the bridge construction material according to claim 3, wherein: the driving part comprises a first motor, a first screw, a first adjusting block, a second screw and a second adjusting block; the first motor is arranged on the outer side of the conveying pipeline; the first screw rod is horizontally arranged, the two ends of the first screw rod are respectively a first end part and a second end part, the first end part of the first screw rod is arranged on an output shaft of the first motor, and the second end part of the first screw rod is provided with a first bevel gear; the first adjusting block is provided with a first threaded hole in screw transmission fit with the first screw rod, and the first adjusting block is connected with the transverse stop block; the first motor drives the first screw rod to rotate when working, the first screw rod drives the first adjusting block to horizontally move along the first screw rod, and the first adjusting block drives the transverse stopping block to move in the horizontal mounting groove when moving;

the second screw rod is vertically arranged, the second screw rod is rotatably arranged on the conveying pipeline around the axis of the second screw rod, and a second bevel gear meshed with the first bevel gear is arranged at the lower end of the second screw rod; a second threaded hole in screw transmission fit with the second screw is formed in the second adjusting block, and the second adjusting block is connected with the longitudinal stop block; when the first screw rod rotates, the second screw rod is driven to rotate through the first bevel gear and the second bevel gear, and when the first screw rod rotates to drive the transverse stopping block to move towards one side far away from the vertical groove, the second screw rod drives the second adjusting block to move downwards.

5. The transportation device for the bridge construction material according to claim 4, wherein: the transverse stopping block is provided with a first sliding rod and a first spring; the first adjusting block is provided with a first through hole, the first adjusting block is sleeved on the first sliding rod through the first through hole, and one end of the first sliding rod is provided with a first end cover for preventing the first adjusting block from being separated from the first sliding rod; the first spring is sleeved on the first sliding rod, one end of the first spring is connected with the transverse stopping block, and the other end of the first spring is connected with the first adjusting block;

the longitudinal stop block is provided with a second sliding rod and a second spring; a second through hole is formed in the second adjusting block, the second adjusting block is sleeved on the second sliding rod through the second through hole, and a second end cover for preventing the second adjusting block from being separated from the second sliding rod is installed at one end of the second sliding rod; the second sliding rod is sleeved with the second spring, one end of the second spring is connected with the longitudinal stop block, and the other end of the second spring is connected with the second adjusting block.

6. The transportation device for the bridge construction material according to claim 5, wherein:

the conveying pipeline is further provided with a placing groove, the upper end of the placing groove is communicated with the second annular groove, the driving assembly further comprises a one-way stop block and a third spring, the one-way stop block is arranged in the placing groove, the lower end of the one-way stop block is connected to the lower groove wall of the placing groove through the third spring, an inclined surface extending backwards from top to bottom is arranged on the rear side of the one-way stop block in the first circumferential direction, and the sliding block can downwards extrude the one-way stop block under the action of the inclined surface when rotating along the second annular groove in the first circumferential direction; when the reset is needed, the driving shaft rotates around the axis of the driving shaft along the second circumferential direction, and when the sliding block moves to the front side of the one-way stop block, the sliding block moves downwards along the vertical groove under the action of the second stop block and the helical blade until entering the first annular groove.

7. The transportation device for the bridge construction material according to claim 1, characterized in that: the driving mechanism further comprises a second motor, a third bevel gear and a fourth bevel gear; the second motor is arranged on the mounting frame, the third bevel gear is arranged on an output shaft of the second motor, and the fourth bevel gear is arranged at the lower end of the driving shaft and meshed with the third bevel gear; when materials need to be transported, the second motor drives the driving shaft to rotate around the first circumferential direction through the third bevel gear and the fourth bevel gear; when the motor is reset, the second motor drives the driving shaft to rotate around the second circumferential direction through the third bevel gear and the fourth bevel gear.

8. The transportation device for the bridge construction material according to claim 7, wherein: an installation cavity is formed inside the installation frame, and the second motor is arranged inside the installation cavity; the inside of installation cavity is provided with the residue and collects the storehouse, and the lower extreme intercommunication in storehouse and pipeline is collected to the residue is connected with between the storehouse and is used for guiding the material to the inside guide board in residue collection storehouse with the residue.

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