CN214121882U

CN214121882U - Novel concrete hardness detects device

Info

Publication number: CN214121882U
Application number: CN202022375251.1U
Authority: CN
Inventors: 刘全龙
Original assignee: Shaanxi Road And Bridge Engineering Inspection Co ltd
Current assignee: Shaanxi Road And Bridge Engineering Inspection Co ltd
Priority date: 2020-10-22
Filing date: 2020-10-22
Publication date: 2021-09-03
Anticipated expiration: 2030-10-22

Abstract

The utility model belongs to the technical field of the concrete hardness detects, especially, novel concrete hardness detects device, including workstation, supporting leg, casing, detection mechanism, guide mouth, fixture, concrete test block and collecting box, the top of supporting leg respectively with the four corners department fixed connection of workstation bottom surface, the bottom at casing both ends and the top surface fixed connection at workstation both ends, the top of detection mechanism and the top surface fixed connection of casing inner chamber, the middle part of workstation top surface is seted up to the guide mouth. This novel concrete hardness detection device, through the improvement to concrete hardness detection device, at first can carry out a plurality of positions to the concrete test block and carry out hardness detection, just so improved the work efficiency of device, then can also detect a plurality of concrete test blocks to improve the practicality of device, can also in time clear up and collect the fragment at last, just so make things convenient for more to use hardness detection device.

Description

Novel concrete hardness detects device

Technical Field

The utility model relates to a concrete hardness detects technical field, especially relates to a novel concrete hardness detects device.

Background

The existing concrete hardness detection device cannot perform continuous detection when performing hardness detection on concrete, and when a concrete slab is detected, a pressure applying device of the concrete slab needs to be adjusted again, so that a large amount of time is wasted, and the existing concrete hardness detection device is inconvenient in collecting waste materials, so that the practicability of the concrete hardness detection device is reduced.

SUMMERY OF THE UTILITY MODEL

Based on current concrete hardness detection device can not carry out continuous detection, inconvenient collection waste material, the low technical problem of practicality, the utility model provides a novel concrete hardness detection device.

The utility model provides a novel concrete hardness detects device, including workstation, supporting leg, casing, detection mechanism, guide mouth, fixture, concrete test block and collection workbin, the top of supporting leg respectively with the four corners fixed connection of workstation bottom surface, the bottom at casing both ends and the top surface fixed connection at workstation both ends, the top of detection mechanism and the top surface fixed connection at casing inner chamber, the middle part of workstation top surface is seted up in the guide mouth, the bottom at fixture both ends and the top surface fixed connection at workstation both ends, two the concrete test block respectively with fixture's top and bottom joint, the bottom surface fixed connection at the top at collection workbin both ends and workstation both ends.

Detection mechanism includes guide rail, transposition piece, guide cylinder, lift cylinder, intensity pipe, force cell sensor and detects the head, the top of guide rail and the top surface fixed connection of casing inner chamber, the top of transposition piece and the middle part joint of guide rail bottom, the right-hand member of guide cylinder and the top fixed connection of casing right side inner wall, and the left end of guide cylinder and the right flank fixed connection of transposition piece, the top of lift cylinder and the bottom surface fixed connection of transposition piece, the top of intensity pipe and the bottom fixed connection of lift cylinder, force cell sensor's top and the top surface fixed connection of intensity pipe inner chamber, the top of detecting the head is pegged graft with the inner chamber of intensity socle end.

Preferably, the clamping mechanism comprises rotary cylinders, a material guide box, a partition plate, a first support plate, a first guide hole, a first guide rod, a first clamping block, a second guide hole, a second guide rod, a second clamping block and a second support plate, wherein the bottom of one end, far away from each other, of each rotary cylinder is fixedly connected with the top surfaces of the two ends of the workbench, the middle parts of the two side surfaces of the material guide box are fixedly connected with one ends, close to each other, of the two rotary cylinders, the two ends of the partition plate are fixedly connected with the middle parts of the inner walls of the two sides of the material guide box, the end, far away from each support plate, of each support plate is fixedly connected with the top parts of the inner walls of the two sides of the material guide box, the first guide holes are arranged at the top parts of the two side surfaces of the material guide box, the end, close to each other, of the two first clamping blocks is movably inserted into the inner cavities of the two first guide holes, one surface, far away from each clamping block is fixedly connected with the end, close to each guide rod, the two guide holes II are formed in the bottoms of the two side faces of the material guide box, one ends, close to each other, of the two guide rods are movably inserted into the inner cavities of the two guide holes II, one faces, far away from each other, of the two clamping blocks are fixedly connected with one ends, close to each other, of the two guide rods, and one ends, far away from each other, of the two support plates are fixedly connected with the bottoms of the inner walls of the two sides of the material guide box.

Preferably, the groove surface at the top end of the transposition block is in sliding connection with the surface of the bottom of the guide rail.

Preferably, the surface of the top end of the detection head is connected with the inner wall of the strength tube in a sliding mode.

Preferably, the surfaces of the two first guide rods close to one end are in threaded connection with the inner walls of the two first guide holes.

Preferably, the surfaces of the two guide rods close to one end of each other are in threaded connection with the inner walls of the two guide holes.

Preferably, the load cell is of the type LCD 800.

The utility model provides a beneficial effect does:

1. through the detection mechanism who sets up, at first control the direction cylinder start, the direction cylinder starts and just can drive and move about the transposition piece, move about the transposition piece and just can drive lift cylinder and detect the head and move about simultaneously, move about through detecting the head and just can adjust the check point of concrete test block at will, then control the lift cylinder start, the lift cylinder starts just can drive the intensity tube and detect the head and move down simultaneously, after the bottom crush concrete test block that detects the head, force cell sensor just can the hardness of real-time detection concrete test block at this moment, thereby the work efficiency of device has been improved.

2. Through the improvement to concrete hardness detection device, at first can carry out a plurality of positions to the concrete test block and carry out hardness detection, just so improve the work efficiency of device, then can also detect a plurality of concrete test blocks to improve the practicality of device, can also in time clear up and collect the fragment at last, just so make things convenient for more convenient for the use of hardness detection device.

Drawings

Fig. 1 is a schematic view of a novel concrete hardness testing device provided by the utility model;

fig. 2 is the utility model provides a novel concrete hardness detects device's workstation and fixture connection structure's front cut-away view.

In the figure: 1. a work table; 2. supporting legs; 3. a housing; 4. a detection mechanism; 401. a guide rail; 402. a bit-shifting block; 403. a guide cylinder; 404. a lifting cylinder; 405. a strength tube; 406. a force sensor; 407. a detection head; 5. a material guide port; 6. a clamping mechanism; 601. a rotating cylinder; 602. a material guiding box; 603. a partition plate; 604. a first support plate; 605. a first guide hole; 606. a first guide rod; 607. a first clamping block; 608. a second guide hole; 609. a second guide rod; 610. a second clamping block; 611. a second support plate; 7. testing concrete blocks; 8. a material collecting box.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-2, a novel concrete hardness detection device, including workstation 1, supporting leg 2, casing 3, detection mechanism 4, guide opening 5, fixture 6, concrete test block 7 and collection workbin 8, the top of supporting leg 2 respectively with the four corners department fixed connection of workstation 1 bottom surface, the bottom at casing 3 both ends and the top surface fixed connection at workstation 1 both ends, the top of detection mechanism 4 and the top surface fixed connection of casing 3 inner chamber, guide opening 5 sets up the middle part at workstation 1 top surface, the bottom at fixture 6 both ends and the top surface fixed connection at workstation 1 both ends, two concrete test blocks 7 respectively with fixture 6's top and bottom joint, the top at collection workbin 8 both ends and the bottom surface fixed connection at workstation 1 both ends.

The detection mechanism 4 comprises a guide rail 401, a transposition block 402, a guide cylinder 403, a lifting cylinder 404, a strength tube 405, a load cell 406 and a detection head 407, the top of the guide rail 401 is fixedly connected with the top surface of the inner cavity of the shell 3, the top end of the transposition block 402 is clamped with the middle part of the bottom end of the guide rail 401, the groove surface of the top end of the transposition block 402 is in sliding connection with the surface of the bottom of the guide rail 401, the right end of the guide cylinder 403 is fixedly connected with the top of the inner wall of the right side of the shell 3, the left end of the guide cylinder 403 is fixedly connected with the right side face of the transposition block 402, the top of the lifting cylinder 404 is fixedly connected with the bottom face of the transposition block 402, the top of the strength tube 405 is fixedly connected with the bottom end of the lifting cylinder 404, the top of the force measuring sensor 406 is fixedly connected with the top face of the inner cavity of the strength tube 405, the force measuring sensor 406 is of the type LCD800, the top end of the detection head 407 is inserted into the inner cavity of the bottom end of the strength tube 405, and the surface of the top end of the detection head 407 is in sliding connection with the inner wall of the strength tube 405.

The clamping mechanism 6 comprises a rotary cylinder 601, a material guiding box 602, a partition plate 603, a first support plate 604, a first guide hole 605, a first guide rod 606, a first clamping block 607, a second guide hole 608, a second guide rod 609, a second clamping block 610 and a second support plate 611, wherein the bottoms of the ends, far away from each other, of the two rotary cylinders 601 are fixedly connected with the top surfaces of the two ends of the workbench 1, the middle parts of the two side surfaces of the material guiding box 602 are fixedly connected with the ends, close to each other, of the two rotary cylinders 601, the two ends of the partition plate 603 are fixedly connected with the middle parts of the inner walls of the two sides of the material guiding box 602, the ends, far away from each other, of the two support plates 604 are fixedly connected with the tops of the inner walls of the two sides of the material guiding box 602, the two first guide holes 605 are arranged on the tops of the two side surfaces of the material guiding box 602, the ends, close to each other, of the two guide rods 606 are movably inserted into the inner cavities of the two first guide holes 605, the surfaces of the ends, which are in threaded connection with the two guide rods 605, the surfaces, far away from each other, of the two clamping blocks I607 are fixedly connected with the ends, close to each other, of the two guide rods I606, the two guide holes II 608 are formed in the bottoms of the two side surfaces of the material guide box 602, the ends, close to each other, of the two guide rods II 609 are movably inserted into the inner cavities of the two guide holes II 608, the surfaces, close to each other, of the two guide rods II 609 are in threaded connection with the inner walls of the two guide holes II 608, the surfaces, far away from each other, of the two clamping blocks II 610 are fixedly connected with the ends, close to each other, of the two guide rods II 609, and the ends, far away from each other, of the two support plates II 611 are fixedly connected with the bottoms of the inner walls of the two sides of the material guide box 602.

When the concrete block positioning device is used, a first concrete block 7 is firstly placed on the top surfaces of two support plates I604, then two guide rods I606 are controlled to rotate forwards, the two clamping blocks I607 can be driven to move towards opposite directions by rotating forwards the two guide rods I606, when the surfaces, close to each other, of the two clamping blocks I607 are in full contact with the two side surfaces of the first concrete block 7, the first concrete block 7 is positioned, then the rotating cylinder 601 is controlled to start, the rotating cylinder 601 can drive the guide box 602 to turn over 180 degrees by starting, then the second concrete block 7 is placed on the top surfaces of two support plates II 611, then two guide rods II 609 are controlled to rotate forwards, the two guide rods II 609 can drive the two clamping blocks II 610 to move towards opposite directions by rotating forwards, when the surfaces, close to each other, of the two clamping blocks II 610 are in full contact with the two side surfaces of the second concrete block 7, at this time, the positioning of the second concrete test block 7 is completed, after the positioning of the concrete test block 7 is finished, the guide cylinder 403 is controlled to be started, the guide cylinder 403 is started to drive the transposition block 402 to move left and right, the transposition block 402 moves left and right to drive the lifting cylinder 404 and the detection head 407 to move left and right simultaneously, the detection point of the concrete test block 7 can be adjusted at will by moving the detection head 407 left and right, then the lifting cylinder 404 is controlled to be started, the lifting cylinder 404 is started to drive the strength tube 405 and the detection head 407 to move downwards simultaneously, when the bottom end of the detection head 407 crushes the concrete test block 7, the force measuring sensor 406 can detect the hardness of the concrete test block 7 in real time, the rotary cylinder can be controlled to be started after detecting the first concrete test block 7, the rotary cylinder 601 can drive the guide box 602 to turn over 180 degrees again by controlling the guide cylinder 403 and the lifting cylinder 404 to be started again, and the second concrete test block 7 can be quickly detected And (3) performing hardness detection, controlling the rotary cylinder 601 to start again, driving the guide box 602 to turn over by 180 degrees again by starting the rotary cylinder 601, and then quickly conveying the fragments generated in the two detections to the inside of the material collecting box 8 by the guide box 602, thus finishing the cleaning and collection of the fragments.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a novel concrete hardness detects device, includes workstation (1), supporting leg (2), casing (3), detection mechanism (4), guide mouth (5), fixture (6), concrete test block (7) and collection case (8), its characterized in that: the top ends of the supporting legs (2) are fixedly connected with four corners of the bottom surface of the workbench (1) respectively, the bottoms of two ends of the shell (3) are fixedly connected with the top surfaces of two ends of the workbench (1), the top of the detection mechanism (4) is fixedly connected with the top surface of an inner cavity of the shell (3), the material guide port (5) is formed in the middle of the top surface of the workbench (1), the bottoms of two ends of the clamping mechanism (6) are fixedly connected with the top surfaces of two ends of the workbench (1), the two concrete test blocks (7) are clamped with the top end and the bottom end of the clamping mechanism (6) respectively, and the tops of two ends of the material collecting box (8) are fixedly connected with the bottom surfaces of two ends of the workbench (1);

the detection mechanism (4) comprises a guide rail (401), a transposition block (402), a guide air cylinder (403), a lifting air cylinder (404), a strength tube (405), a force cell (406) and a detection head (407), the top of the guide rail (401) is fixedly connected with the top surface of the inner cavity of the shell (3), the top end of the transposition block (402) is clamped with the middle part of the bottom end of the guide rail (401), the right end of the guide cylinder (403) is fixedly connected with the top of the inner wall of the right side of the shell (3), and the left end of the guide cylinder (403) is fixedly connected with the right side surface of the transposition block (402), the top of the lifting cylinder (404) is fixedly connected with the bottom surface of the transposition block (402), the top of the strength tube (405) is fixedly connected with the bottom end of the lifting cylinder (404), the top of the force measuring sensor (406) is fixedly connected with the top surface of the inner cavity of the strength tube (405), the top end of the detection head (407) is inserted into the inner cavity at the bottom end of the strength tube (405).

2. The novel concrete hardness detection device according to claim 1, characterized in that: the clamping mechanism (6) comprises rotary cylinders (601), a material guide box (602), a partition plate (603), a first support plate (604), a first guide hole (605), a first guide rod (606), a first clamping block (607), a second guide hole (608), a second guide rod (609), a second clamping block (610) and a second support plate (611), wherein the bottom of one end, far away from each other, of each rotary cylinder (601) is fixedly connected with the top surfaces of the two ends of the workbench (1), the middle parts of the two side surfaces of the material guide box (602) are fixedly connected with one ends, close to each other, of the two rotary cylinders (601), the two ends of the partition plate (603) are fixedly connected with the middle parts of the inner walls of the two sides of the material guide box (602), one ends, far away from each support plate (604), of the two support plates are fixedly connected with the tops of the inner walls of the two sides of the material guide box (602), and the two first guide holes (605) are formed in the tops of the two side surfaces of the material guide box (602), two the one end that guide bar one (606) are close to each other is pegged graft with the inner chamber activity of two guiding holes one (605), two the one side that clamp splice one (607) kept away from each other and the one end fixed connection that two guide bar one (606) are close to each other, two bottom that guide hole two (608) were seted up in guide box (602) both sides face, two the one end that guide bar two (609) are close to each other is pegged graft with the inner chamber activity of two guide hole two (608), two the one side that clamp splice two (610) are kept away from each other and the one end fixed connection that two guide bar two (609) are close to each other, two the one end that backup pad two (611) are kept away from each other and the bottom fixed connection of guide box (602) both sides inner wall.

3. The novel concrete hardness detection device according to claim 1, characterized in that: the groove surface at the top end of the transposition block (402) is in sliding connection with the surface at the bottom of the guide rail (401).

4. The novel concrete hardness detection device according to claim 1, characterized in that: the surface of the top end of the detection head (407) is in sliding connection with the inner wall of the strength tube (405).

5. The novel concrete hardness detection device according to claim 2, characterized in that: the surfaces of one end, close to each other, of the two guide rods I (606) are in threaded connection with the inner walls of the two guide holes I (605).

6. The novel concrete hardness detection device according to claim 2, characterized in that: the surfaces of the two second guide rods (609) close to one end are in threaded connection with the inner walls of the two second guide holes (608).

7. The novel concrete hardness detection device according to claim 1, characterized in that: the load cell (406) is of the type LCD 800.