CN212031189U - Concrete pressure detection device for hydraulic engineering - Google Patents

Abstract

The utility model belongs to the technical field of hydraulic engineering, in particular to a concrete pressure detection device for hydraulic engineering, which comprises a concrete resiliometer body, a bottom plate and a top plate, wherein four connecting columns which are distributed in a diagonal manner are vertically connected between the bottom plate and the top plate; a movable connecting plate is distributed between the bottom plate and the top plate, and a mounting assembly is arranged on the bottom surface of the movable connecting plate; a control component is arranged on the top plate; four corners of the bottom surface of the bottom plate are respectively provided with a sucker; the utility model discloses a concrete pressure detection device for hydraulic engineering utilizes the sucking disc to stabilize the device on hydraulic structure surface, promotes the concrete resiliometer body through control assembly and removes and detect with extrusion hydraulic structure, can guarantee the stability of concrete resiliometer body, reduces the intensity of labour who detects, simultaneously, utilizes control assembly can guarantee the stability that concrete resiliometer body extrudees hydraulic structure, is favorable to accurate reading, has promoted the precision that detects.

Description

Concrete pressure detection device for hydraulic engineering

Technical Field

The utility model belongs to the technical field of hydraulic engineering, concretely relates to concrete pressure detection device for hydraulic engineering.

Background

Hydraulic engineering is an engineering built for controlling and allocating surface water and underground water in the nature to achieve the purposes of removing harm and benefiting, and is also called water engineering; water is a valuable resource essential for human production and life, but the naturally existing state of the water is not completely in accordance with the needs of human, hydraulic engineering needs to construct various types of hydraulic buildings such as dams, dikes, spillways, sluice gates, water inlets, channels, transit troughs, rafts, fishways and the like so as to achieve the targets of the hydraulic engineering, when the hydraulic engineering constructs the hydraulic buildings, concrete is an essential material, because of the complexity and the stability of the use environment of the hydraulic engineering hydraulic buildings, the concrete rebound tester is a commonly used tester, the concrete rebound tester is a tester and is suitable for testing the strength of common building components, bridges and various concrete components, and the main technical index has an impact function; the rigidity of the tension spring is flicked; a percussion hammer stroke; the maximum static friction and the rate of penetration of the pointer system are averaged.

When the original concrete resiliometer is used, a plurality of persons are required to cooperate, meanwhile, a detector needs to tightly hold the concrete resiliometer body by hands, a detection head of the concrete resiliometer body needs to vertically contact the surface of concrete to be detected, and the concrete resiliometer body is sequentially pushed to extrude the surface of the concrete to be detected, on one hand, the manual holding is inconvenient, and the detector can feel tired due to the fact that a plurality of groups of data need to be detected, so that the smooth detection is influenced; on the other hand, the application of force size is difficult to control, and manual concrete resiliometer body that is difficult to stabilize, at the reading in-process, the data easily produces constantly changing, influences accurate reading.

SUMMERY OF THE UTILITY MODEL

For solving the above-mentioned problem that exists among the prior art, the utility model provides a concrete pressure detection device for hydraulic engineering has convenient to use, easily dismouting, application of force are stable and detect accurate characteristics.

In order to achieve the above object, the utility model provides a following technical scheme: a concrete pressure detection device for hydraulic engineering comprises a concrete resiliometer body, a bottom plate and a top plate, wherein four connecting columns which are distributed in a diagonal manner are vertically connected between the bottom plate and the top plate; a movable connecting plate is distributed between the bottom plate and the top plate, and the bottom surface of the movable connecting plate is provided with an installation component for installing the concrete resiliometer body; a control assembly for controlling the movable connecting plate to move is arranged on the top plate; a through hole for the concrete resiliometer body to penetrate through is formed in the bottom plate; and four corners of the bottom surface of the bottom plate are respectively provided with a sucking disc.

As a preferred technical scheme of the utility model, the control component comprises a first threaded rod, a first screw hole for the first threaded rod to pass through is arranged in the top plate, and the first threaded rod is screwed and connected with the top plate through the first screw hole; the bottom end of the first threaded rod penetrates through the first screw hole and then is connected with the movable connecting plate through a bearing, and the top end of the first threaded rod is provided with a rotary rod.

As an optimal technical scheme of the utility model, the bottom plate with still be connected with a guide bar between the roof the confession has been seted up in the swing joint board a guiding hole that a guide bar runs through.

As a preferred technical solution of the present invention, the mounting assembly includes a movable clamping piece and a fixed clamping piece, the movable clamping piece is movably distributed on the bottom surface of the movable connecting plate, and the fixed clamping piece is fixed on the bottom surface of the movable connecting plate; the movable connecting plate is characterized by further comprising a second threaded rod, a supporting plate is further fixed to the bottom surface of the movable connecting plate, a second screw hole for the second threaded rod to penetrate through is formed in the supporting plate, and the second threaded rod is connected with the supporting plate in a threaded screwing mode through the second screw hole; one end of the second threaded rod penetrates through the second screw hole and then is connected with the movable clamping piece through a bearing, and the other end of the second threaded rod is provided with a second rotating rod.

As a preferred technical solution of the present invention, the movable clamping piece and the fixed clamping piece are symmetrically distributed in a semicircular structure, and flexible pads are bonded and fixed to inner walls of the movable clamping piece and the fixed clamping piece; the flexible pad is a rubber pad.

As the utility model discloses a preferred technical scheme, the activity presss from both sides tight piece with the tip of the tight piece of fixed clamp is fixed with corresponding connecting block and No. two connecting blocks respectively the tip vertical fixation of a connecting block has No. two guide bars No. two the confession has been seted up in the connecting block No. two the guiding hole that No. two guide bars run through.

Compared with the prior art, the beneficial effects of the utility model are that: the utility model discloses a concrete pressure detection device for hydraulic engineering, concrete resiliometer body cooperation bottom plate, the roof, installation component and control assembly use, utilize the sucking disc to stabilize the device on hydraulic structure surface, promote concrete resiliometer body through control assembly and remove and detect with extrusion hydraulic structure, can guarantee the stability of concrete resiliometer body, reduce the intensity of labour who detects, and simultaneously, utilize control assembly can guarantee the stability that concrete resiliometer body extrudes hydraulic structure, be favorable to accurate reading, the precision of detection has been promoted.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic top cross-sectional view of the mounting assembly of the present invention;

in the figure: 1. a concrete resiliometer body; 2. a base plate; 3. a top plate; 4. connecting columns; 5. a first rotary rod; 6. a first threaded rod; 7. a first screw hole; 8. a movable connecting plate; 9. a first guide rod; 10. a first guide hole; 11. mounting the component; 12. perforating; 13. a suction cup; 14. a movable clamping piece; 15. fixing the clamping sheet; 16. a flexible pad; 17. a first connecting block; 18. a second connecting block; 19. a second guide rod; 20. a second guide hole; 21. a support plate; 22. a second threaded rod; 23. a second rotary rod; 24. and a second screw hole.

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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-2, the present invention provides the following technical solutions: a concrete pressure detection device for hydraulic engineering comprises a concrete resiliometer body 1, a bottom plate 2 and a top plate 3, wherein four connecting columns 4 which are distributed in a diagonal manner are vertically connected between the bottom plate 2 and the top plate 3; a movable connecting plate 8 is distributed between the bottom plate 2 and the top plate 3, and the bottom surface of the movable connecting plate 8 is provided with a mounting component 11 for mounting the concrete resiliometer body 1; a control component for controlling the movable connecting plate 8 to move is arranged on the top plate 3; a through hole 12 for the concrete resiliometer body 1 to penetrate through is formed in the bottom plate 2; suction cups 13 are installed respectively in bottom surface four corners of bottom plate 2, during the use, the tail end with concrete resiliometer body 1 passes perforation 12, and utilize installation component 11 and swing joint board 8 stable connection with the tail end of concrete resiliometer body 1, utilize suction cups 13 to adsorb on the hydraulic structure surface, for further guaranteeing stably, when detecting the vertical plane, the testing personnel can also hold roof 3 with the hand, later make swing joint board 8 drive concrete resiliometer body 1 towards hydraulic structure surface removal through the control assembly, utilize the detection head of concrete resiliometer body 1 to detect, and the reading of concrete resiliometer body 1 is once taken notes to the control assembly once per operation.

Specifically, according to fig. 1, in the embodiment, the control assembly includes a first threaded rod 6, a first threaded hole 7 is formed in the top plate 3 for the first threaded rod 6 to pass through, and the first threaded rod 6 is connected with the top plate 3 in a threaded manner through the first threaded hole 7; the bottom of threaded rod 6 runs through behind screw 7 and is connected with swing joint board 8 through the bearing, and a swing joint 5 is installed on the top of threaded rod 6, and when control swing joint board 8 drove concrete resiliometer body 1 and removed, rotate a swing joint 5, utilize a swing joint 5 to drive a threaded rod 6 rotatory, because a threaded rod 6 closes continuously for the screw soon with roof 3, can drive swing joint board 8 through a threaded rod 6 and remove.

Specifically, according to fig. 1, in this embodiment, a first guide rod 9 is further connected between the bottom plate 2 and the top plate 3, a first guide hole 10 for the first guide rod 9 to penetrate is formed in the movable connecting plate 8, and when the movable connecting plate 8 moves, the movable connecting plate 8 can move along the first guide rod 9, so that the movable connecting plate 8 moves more stably.

Specifically, according to fig. 1 and fig. 2, in the present embodiment, the mounting assembly 11 includes a movable clamping piece 14 and a fixed clamping piece 15, the movable clamping piece 14 is movably distributed on the bottom surface of the movable connecting plate 8, and the fixed clamping piece 15 is fixed on the bottom surface of the movable connecting plate 8; the screw rod mechanism further comprises a second threaded rod 22, a supporting plate 21 is fixed on the bottom surface of the movable connecting plate 8, a second screw hole 24 for the second threaded rod 22 to penetrate through is formed in the supporting plate 21, and the second threaded rod 22 is connected with the supporting plate 21 in a threaded manner through the second screw hole 24; one end of the second threaded rod 22 penetrates through the second screw hole 24 and then is connected with the movable clamping piece 14 through a bearing, the other end of the second threaded rod 22 is provided with a second rotary rod 23, when the concrete resiliometer body 1 is installed, the second rotary rod 23 is rotated firstly, the second rotary rod 23 drives the second threaded rod 22 to rotate, under the condition of screwing the threads, the second threaded rod 22 can be used for driving the movable clamping piece 14 to move, firstly, the movable clamping piece 14 is far away from the fixed clamping piece 15, stop rotating No. two swing arms 23 after can penetrating into concrete resiliometer body 1 tail end between fixed clamp piece 15 and the activity clamp piece 14, put into the inboard space of activity clamp piece 14 and fixed clamp piece 15 with the tail end of concrete resiliometer body 1, No. two swing arms 23 of reverse rotation make activity clamp piece 14 move towards fixed clamp piece 15, utilize activity clamp piece 14 and fixed clamp piece 15 to clip concrete resiliometer body 1.

Specifically, according to fig. 1 and fig. 2, in this embodiment, the movable clamping pieces 14 and the fixed clamping pieces 15 are symmetrically distributed in a semicircular ring structure, so as to adapt to the shape of the concrete rebound apparatus body 1, ensure stable installation of the concrete rebound apparatus body 1, and flexible pads 16 are bonded and fixed on inner walls of the movable clamping pieces 14 and the fixed clamping pieces 15; the flexible pad 16 is a rubber pad, so that the concrete resiliometer body 1 is prevented from being worn.

Specifically, according to fig. 1 and fig. 2, in this embodiment, a first connecting block 17 and a second connecting block 18 are respectively fixed at the end portions of the movable clamping piece 14 and the fixed clamping piece 15, a second guide rod 19 is vertically fixed at the end portion of the first connecting block 17, a second guide hole 20 for the second guide rod 19 to penetrate through is formed in the second connecting block 18, when the movable clamping piece 14 displaces relative to the fixed clamping piece 15, the second guide rod 19 can ensure the stability of the movement of the movable clamping piece 14, and at the same time, the movable clamping piece 14 and the fixed clamping piece 15 are always distributed oppositely, so that the movable clamping piece 14 and the fixed clamping piece 15 are prevented from deviating and affecting the clamping of the concrete rebound tester body 1.

The utility model discloses a theory of operation and use flow: the utility model discloses a concrete pressure detection device for hydraulic engineering, during the use, pass perforation 12 with concrete resiliometer body 1's tail end, and utilize the tail end of concrete resiliometer body 1 to carry out the centre gripping with the tight piece of the movable clamp 14 of the clamp of activity and the tight piece of fixed clamp 15, make concrete resiliometer body 1 connect in swing joint board 8 bottom surfaces, afterwards, utilize sucking disc 13 to adsorb hydraulic structure surface, for further guaranteeing stably, when detecting the vertical plane, the measurement personnel can also hold roof 3 with the hand, later make swing joint board 8 drive concrete resiliometer body 1 towards hydraulic structure surface removal through control assembly, utilize the measuring head of concrete resiliometer body 1 to detect, and the reading of concrete resiliometer body 1 is once taken notes to the control assembly once every operation.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. The utility model provides a concrete pressure detection device for hydraulic engineering, includes concrete resiliometer body (1), its characterized in that: the device is characterized by also comprising a bottom plate (2) and a top plate (3), wherein four connecting columns (4) which are distributed in a diagonal manner are vertically connected between the bottom plate (2) and the top plate (3); a movable connecting plate (8) is distributed between the bottom plate (2) and the top plate (3), and a mounting assembly (11) for mounting the concrete rebound apparatus body (1) is arranged on the bottom surface of the movable connecting plate (8); a control component for controlling the movable connecting plate (8) to move is arranged on the top plate (3); a through hole (12) for the concrete resiliometer body (1) to penetrate through is formed in the bottom plate (2); and four corners of the bottom surface of the bottom plate (2) are respectively provided with a sucker (13).

2. The concrete pressure detection device for hydraulic engineering of claim 1, characterized in that: the control assembly comprises a first threaded rod (6), a first screw hole (7) for the first threaded rod (6) to penetrate through is formed in the top plate (3), and the first threaded rod (6) is connected with the top plate (3) in a threaded manner through the first screw hole (7); the bottom of a threaded rod (6) penetrates through a screw hole (7) and then is connected with the movable connecting plate (8) through a bearing, and a rotating rod (5) is installed at the top end of the threaded rod (6).

3. The concrete pressure detection device for hydraulic engineering of claim 1, characterized in that: a first guide rod (9) is further connected between the bottom plate (2) and the top plate (3), and a first guide hole (10) for the first guide rod (9) to penetrate through is formed in the movable connecting plate (8).

4. The concrete pressure detection device for hydraulic engineering of claim 1, characterized in that: the mounting assembly (11) comprises movable clamping pieces (14) and fixed clamping pieces (15), the movable clamping pieces (14) are movably distributed on the bottom surface of the movable connecting plate (8), and the fixed clamping pieces (15) are fixed on the bottom surface of the movable connecting plate (8); the screw rod fixing device is characterized by further comprising a second threaded rod (22), a supporting plate (21) is further fixed on the bottom surface of the movable connecting plate (8), a second screw hole (24) for the second threaded rod (22) to penetrate through is formed in the supporting plate (21), and the second threaded rod (22) is connected with the supporting plate (21) in a threaded screwing mode through the second screw hole (24); one end of the second threaded rod (22) penetrates through the second screw hole (24) and then is connected with the movable clamping piece (14) through a bearing, and the other end of the second threaded rod (22) is provided with a second rotating rod (23).

5. The concrete pressure detection device for hydraulic engineering of claim 4, characterized in that: the movable clamping piece (14) and the fixed clamping piece (15) are in symmetrical semicircular annular structures, and flexible pads (16) are bonded and fixed on the inner walls of the movable clamping piece (14) and the fixed clamping piece (15); the flexible pad (16) is a rubber pad.

6. The concrete pressure detection device for hydraulic engineering of claim 5, characterized in that: the end parts of the movable clamping piece (14) and the fixed clamping piece (15) are respectively fixed with a first connecting block (17) and a second connecting block (18) which correspond to each other, a second guide rod (19) is vertically fixed at the end part of the first connecting block (17), and a second guide hole (20) for the second guide rod (19) to penetrate through is formed in the second connecting block (18).

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