CN220767641U - Topography flatness measuring device - Google Patents

Abstract

The utility model discloses a topographic flatness measuring device, and relates to the technical field of flatness measurement. The road surface broken stone cleaning device comprises a measuring assembly, wherein a supporting frame is fixedly arranged at the top of the measuring assembly, a broken stone cleaning assembly for treating road surface broken stone is arranged at the front section of the supporting frame, a spreading assembly for filling a pit is arranged at the middle section of the supporting frame, a sand sweeping assembly for sweeping redundant sand is arranged at the rear section of the supporting frame, and a sand recycling assembly for recycling redundant sand is arranged at the top of the spreading assembly. According to the utility model, the first fan drives air to flow, crushed stones, fallen leaves and the like scooped by the guide plate are collected into the recovery box, sundries on the road surface are sucked and cleaned so as to prevent the sundries from affecting subsequent measurement work, the monitoring camera is used for detecting the road surface on the front side of the device, the valve is used for controlling the discharge chute to spill sand grains into the discharge chute, the pit is filled, so that the detected data of the measuring part at the pit is prevented from being changed abnormally, and the difficulty of subsequent data processing is reduced.

Description

Topography flatness measuring device

Technical Field

The utility model relates to the technical field of flatness measurement, in particular to a topographic flatness measuring device.

Background

In the use process of the highway, the flatness of the surface of the highway needs to reach a certain standard, the ground is not flat enough and needs to be maintained and treated, hidden dangers such as subsidence of the road surface are prevented from occurring, so that the safety and stability of the running of the vehicle are ensured, and the accident of the vehicle on the road surface at the place in the future is avoided.

The existing topographic flatness measuring instrument consists of a bearing vehicle and a detection part capable of swinging on the bearing vehicle to attach to the ground, when the instrument is used, the instrument is pulled by the vehicle to move on a highway, and the corresponding flatness is obtained by swinging data of the detection part, but the surface of the highway is used for a long time, a large amount of broken stones, partial pits and the like exist, pit positions on the moving path of equipment cannot be completely avoided, data abnormality is easy to cause, and the instrument is inconvenient to use.

Disclosure of Invention

In order to solve the problems, the utility model provides a topographic flatness measuring device.

The utility model adopts the following technical scheme for realizing the purposes: the utility model provides a topography roughness measuring device, includes measurement assembly, measurement assembly's top fixed mounting has the support frame, the anterior segment of support frame is provided with the rubble clearance subassembly of handling road surface rubble, the middle section of support frame is provided with the shop material subassembly of filling the pit, the rear segment of support frame is provided with the sand grain cleaning subassembly of sweeping unnecessary sand grain, the top of shop material subassembly is provided with the sand grain recovery subassembly of retrieving unnecessary sand grain.

The measuring assembly comprises a bearing car body, the bottom of the bearing car body is rotationally provided with a moving wheel, the surface of the bearing car body is rotationally provided with a swinging rod, one end of the swinging rod is rotationally provided with an auxiliary wheel, the other end of the swinging rod is rotationally provided with a supporting plate, the surface of the bearing car body is provided with a detection probe, and the detection end of the detection probe is opposite to the supporting plate.

The stone breaking and cleaning assembly comprises a recovery box, a recovery box is fixedly arranged on the surface of the support frame, a storage box is arranged in the recovery box in a sliding mode, a first fan is arranged at the top of the recovery box, the input end of the first fan is communicated with the top of the recovery box through a pipeline, a filter screen is arranged at the pipeline, a feeding cover is fixedly arranged on the front side of the recovery box through a pipeline, a guide plate is hinged to the bottom of the feeding cover, and the guide plate is trapezoid.

The stone cleaning assembly comprises a supporting frame, wherein the stone cleaning assembly comprises a stone discharging assembly, the stone discharging assembly is arranged on the bottom of the stone discharging assembly, the stone discharging assembly comprises a stone discharging box, the stone discharging box is fixedly arranged on the surface of the supporting frame, a discharging groove is formed in the bottom of the stone discharging box, a valve is arranged at the discharging groove, and a monitoring camera is arranged at the bottom of the stone cleaning assembly.

The sand sweeping assembly comprises a sliding sleeve, a sliding sleeve is fixedly arranged on the surface of the supporting frame, a servo motor is arranged at one end of the sliding sleeve, a rotating shaft is fixedly connected with the output end of the servo motor, a transmission gear is fixedly sleeved at one end of the rotating shaft, a rotating plate is fixedly arranged on the surface of the rotating shaft, and a sweeping brush is fixedly connected with the bottom end of the rotating plate.

The number of the rotating shafts and the transmission gears is two, the two groups of rotating shafts are arranged in the sliding sleeve in a staggered mode, and the two groups of transmission gears are in meshed connection.

The sand recycling assembly comprises a suction pipe, the suction pipe is fixedly arranged on the surface of the support frame and is U-shaped, the suction pipe is located on two sides of the sand sweeping assembly, a receiving box is fixedly arranged on the top of the spreading assembly, the top of the suction pipe is communicated with the top of the receiving box through a pipeline, a second fan is arranged on the top of the receiving box, the input end of the second fan is communicated with the top of the receiving box through a pipeline, a filter screen is arranged at the pipeline, the suction pipe is communicated with the spreading assembly, and a partition plate is slidably arranged at the communicating position.

The beneficial effects of the utility model are as follows:

according to the utility model, the first fan drives air to flow, crushed stones, fallen leaves and the like scooped up by the guide plate are collected into the recovery box, sundries on the pavement are sucked and cleaned so as to prevent the sundries from affecting subsequent measurement work, the monitoring camera is used for detecting the pavement at the front side of the device, when pits are found, the valve is used for controlling the discharge chute to spill sand grains into the discharge chute, the pits are filled up so as to prevent detection data of the measuring component at the pits from changing abnormally, the difficulty of subsequent data processing is reduced, the servo motor is used for driving the cleaning brush to sweep the ground, the redundant sand grains filling the pits are cleaned and cleaned, so that the pits are kept level, the second fan is used for driving the air to flow, and the redundant sand grains at the suction pipe are sucked and recovered into the spreading component for subsequent work.

Drawings

FIG. 1 is a schematic view of a first perspective of the present utility model;

FIG. 2 is a schematic view of a second perspective of the present utility model;

FIG. 3 is a schematic view in partial cross-section of the present utility model;

fig. 4 is an enlarged schematic view of a portion a in fig. 3.

Reference numerals: 1. a measurement assembly; 101. a load-bearing vehicle body; 102. a moving wheel; 103. a swinging rod; 104. a detection probe; 2. a support frame; 3. a macadam cleaning assembly; 301. a recovery box; 302. a storage box; 303. a first fan; 304. a feed hood; 305. a guide plate; 4. a paving assembly; 401. discharging boxes; 402. a discharge chute; 403. a valve; 404. monitoring a camera; 5. a sand cleaning assembly; 501. a sliding sleeve; 502. a servo motor; 503. a rotating shaft; 504. a transmission gear; 505. a rotating plate; 506. cleaning a brush; 6. a sand recycling assembly; 601. a suction pipe; 602. a material receiving box; 603. a second fan; 604. a partition board.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model.

As shown in fig. 1-4, a topography flatness measuring device comprises a measuring component 1, wherein a supporting frame 2 is fixedly arranged at the top of the measuring component 1, a stone cleaning component 3 for processing pavement stones is arranged at the front section of the supporting frame 2, a spreading component 4 for filling pits is arranged at the middle section of the supporting frame 2, a sand cleaning component 5 for cleaning redundant sand is arranged at the rear section of the supporting frame 2, and a sand recycling component 6 for recycling redundant sand is arranged at the top of the spreading component 4. The traction support frame 2 moves on a road so as to accurately detect the topographic flatness of the road section to obtain required data, the broken stone cleaning component 3 is used for shoveling and sucking sundries such as broken stone, fallen leaves and the like on the road surface at the front side of the device to clean the road surface so as to prevent the sundries from affecting the subsequent measurement work, the spreading component 4 is used for detecting the road surface at the front side of the device, sand grains are sprayed into the road surface when pits are found, the pits are filled up, so that the detected data of the measuring part at the pits are prevented from being changed abnormally, the difficulty of subsequent data processing is reduced, the pits are marked as abnormal, the excessive sand filling the pits is cleaned and swept through the sand cleaning assembly 5, the pits are kept flush, the excessive sand is sucked and recovered into the spreading assembly 4 through the sand recovering assembly 6, and resources are fully utilized for the next use.

The measuring assembly 1 comprises a bearing vehicle body 101, a moving wheel 102 is rotatably arranged at the bottom of the bearing vehicle body 101, a swinging rod 103 is rotatably arranged on the surface of the bearing vehicle body 101, an auxiliary wheel is rotatably arranged at one end of the swinging rod 103, a supporting plate is rotatably arranged at the other end of the swinging rod 103, a detection probe 104 is arranged on the surface of the bearing vehicle body 101, and the detection end of the detection probe 104 is opposite to the supporting plate. The auxiliary wheels are contacted with the ground under the action of gravity, the supporting plate is tilted upwards to be contacted with the detection probe 104, and flatness data of the road surface are obtained by pulling the bearing vehicle body 101 to move.

The rubble clearance subassembly 3 includes recovery tank 301, and support frame 2's fixed surface installs recovery tank 301, and recovery tank 301's inside slidable mounting has storage box 302, and recovery tank 301's top is provided with first fan 303, and first fan 303's input is linked together with recovery tank 301's top through the pipeline, and pipeline department is provided with the filter screen, and recovery tank 301's front side has feeding cover 304 through pipeline fixed mounting, and feeding cover 304's bottom articulates installs guide board 305, and guide board 305 is trapezoidal. The broken stone, fallen leaves and the like on the road surface are scooped up through the guide plate 305, slide into the feeding cover 304, drive air to flow through the first fan 303, pump sundries at the feeding cover 304 into the recovery box 301, and the sundries fall into the storage box 302 to be stored for unified treatment.

The spreading component 4 comprises a discharging box 401, the surface of the supporting frame 2 is fixedly provided with the discharging box 401, the bottom of the discharging box 401 is provided with a discharging groove 402, a valve 403 is arranged at the discharging groove 402, and the bottom of the broken stone cleaning component 3 is provided with a monitoring camera 404. The opening and closing of the discharge chute 402 are controlled through the valve 403, sand grains are discharged from the discharge chute 402 according to the size of the pit monitored by the monitoring camera 404, and the pit is filled.

The sand sweeping assembly 5 comprises a sliding sleeve 501, a sliding sleeve 501 is fixedly arranged on the surface of a supporting frame 2, a servo motor 502 is arranged at one end of the sliding sleeve 501, a rotating shaft 503 is fixedly connected with the output end of the servo motor 502, the rotating shaft 503 is rotatably arranged on the sliding sleeve 501, a transmission gear 504 is fixedly sleeved at one end of the rotating shaft 503, a rotating plate 505 is fixedly arranged on the surface of the rotating shaft 503, and a sweeping brush 506 is fixedly connected with the bottom end of the rotating plate 505. The rotating shaft 503 is driven to rotate reciprocally through the servo motor 502, and the rotating shaft 503 drives the sweeping brush 506 on the rotating plate 505 to sweep the ground, so that redundant sand grains on the pit surface are swept away.

The number of the rotating shafts 503 and the transmission gears 504 is two, and the two groups of rotating shafts 503 are staggered in the sliding sleeve 501, and the two groups of transmission gears 504 are in meshed connection. The two sets of rotating shafts 503 are driven by the meshed driving gears 504 to rotate reversely.

Sand grain recovery subassembly 6 includes and inhales material pipe 601, the fixed surface of support frame 2 installs and inhales material pipe 601, inhale material pipe 601 and be the U-shaped, and inhale the both sides that material pipe 601 was located sand grain cleaning subassembly 5, the top fixed mounting of spreading component 4 has receipts workbin 602, and inhale the top of material pipe 601 and be linked together through the top of pipeline with receipts workbin 602, the top of receipts workbin 602 is provided with second fan 603, the input of second fan 603 is linked together through the top of pipeline with receipts workbin 602, and pipeline department is provided with the filter screen, inhale material pipe 601 and spreading component 4 and intercommunication department slidable mounting has baffle 604. The second fan 603 drives air to flow, redundant sand grains at the suction pipe 601 are sucked and removed, the sand grains are conveyed into the material receiving box 602 to be recovered, and the recovered sand grains are discharged into the paving material assembly 4 through the pumping separation plate 604 to be used next time.

To sum up: when the road flatness measuring device is used, a worker needs to measure the flatness of a road, the device is connected with the rear end of a trailer, control equipment is communicated with the device, the measuring assembly 1 is dragged to move on the road, broken stones, fallen leaves and the like on the road are shoveled up by virtue of the guide plate 305, the broken stones and fallen leaves on the road are slid into the feeding cover 304, the first fan 303 is started to drive air to flow, sundries at the feeding cover 304 are pumped into the recovery box 301 and fall into the storage box 302, the size of pits on the road are monitored by virtue of the monitoring camera 404, sand particles are controlled to be discharged from the blanking box 401 through the valve 403, the pits are filled, the device is continuously moved, the servo motor 502 is started to drive the rotating shaft 503 to rotate, the transmission gear 504 is adopted, two groups of cleaning brushes 506 are enabled to alternately sweep the ground, redundant sand particles on the surfaces of the pits are swept to the suction pipes 601 on the two sides, the second fan 603 is started to drive air to flow, the redundant sand particles at the suction pipes 601 are sucked up, the redundant sand particles are conveyed into the recovery box 602, the auxiliary wheels of the swing rod 103 are attached to the ground and continuously move along with the ground, the sand particles are pumped out of the detection box 401 and continuously, the data are enabled to be discharged from the corresponding storage box 401 after the flatness is enabled to be in contact with the corresponding detection box, and the flatness is recovered, and the data is discharged from the storage box 401, and the corresponding sand particles are enabled to be discharged to be subjected to the flatness to be in contact with the corresponding to the flatness.

Claims (7)

1. The utility model provides a topography roughness measuring device, its characterized in that, including measuring subassembly (1), the top fixed mounting of measuring subassembly (1) has support frame (2), the anterior segment of support frame (2) is provided with rubble clearance subassembly (3) of handling road surface rubble, the middle section of support frame (2) is provided with the shop material subassembly (4) of filling the pit, the rear segment of support frame (2) is provided with sand grain cleaning subassembly (5) of sweeping unnecessary sand grain, the top of shop material subassembly (4) is provided with sand grain recovery subassembly (6) of retrieving unnecessary sand grain.

2. The terrain flatness measurement apparatus according to claim 1, wherein the measurement assembly (1) includes a carrier body (101), a moving wheel (102) is rotatably mounted at the bottom of the carrier body (101), a swinging rod (103) is rotatably mounted on the surface of the carrier body (101), an auxiliary wheel is rotatably mounted at one end of the swinging rod (103), a pallet is rotatably mounted at the other end of the swinging rod (103), a detection probe (104) is provided on the surface of the carrier body (101), and a detection end of the detection probe (104) is disposed opposite to the pallet.

3. The terrain flatness measurement device according to claim 1, characterized in that the crushed stone cleaning assembly (3) comprises a recovery box (301), the recovery box (301) is fixedly mounted on the surface of the supporting frame (2), a storage box (302) is slidably mounted in the recovery box (301), a first fan (303) is arranged at the top of the recovery box (301), the input end of the first fan (303) is communicated with the top of the recovery box (301) through a pipeline, a filter screen is arranged at the pipeline, a feeding cover (304) is fixedly mounted on the front side of the recovery box (301) through a pipeline, a guide plate (305) is hinged to the bottom of the feeding cover (304), and the guide plate (305) is trapezoid.

4. The terrain flatness measuring device according to claim 1, characterized in that the spreading component (4) comprises a blanking box (401), the surface of the supporting frame (2) is fixedly provided with the blanking box (401), a discharging groove (402) is formed in the bottom of the blanking box (401), a valve (403) is arranged at the discharging groove (402), and a monitoring camera (404) is arranged at the bottom of the crushed stone cleaning component (3).

5. The terrain flatness measurement apparatus according to claim 1, characterized in that the sand sweeping component (5) comprises a sliding sleeve (501), a sliding sleeve (501) is fixedly mounted on the surface of the supporting frame (2), a servo motor (502) is arranged at one end of the sliding sleeve (501), a rotating shaft (503) is fixedly connected with an output end of the servo motor (502) penetrating through the surface of the sliding sleeve (501), a transmission gear (504) is fixedly sleeved at one end of the rotating shaft (503), a rotating plate (505) is fixedly mounted on the surface of the rotating shaft (503), and a sweeping brush (506) is fixedly connected with the bottom end of the rotating plate (505).

6. The terrain flatness measuring device according to claim 5, characterized in that the number of the rotating shafts (503) and the transmission gears (504) is two, and the two rotating shafts (503) are staggered in the sliding sleeve (501), and the two transmission gears (504) are in meshed connection.

7. The terrain flatness measurement device according to claim 1, characterized in that the sand recycling component (6) comprises a suction pipe (601), the suction pipe (601) is fixedly arranged on the surface of the supporting frame (2), the suction pipe (601) is in a U shape, the suction pipe (601) is positioned on two sides of the sand sweeping component (5), the top of the spreading component (4) is fixedly provided with a receiving bin (602), the top of the suction pipe (601) is communicated with the top of the receiving bin (602) through a pipeline, the top of the receiving bin (602) is provided with a second fan (603), the input end of the second fan (603) is communicated with the top of the receiving bin (602) through a pipeline, a filter screen is arranged at the pipeline, the suction pipe (601) is communicated with the spreading component (4), and a partition plate (604) is slidably arranged at the communicating position.