CN212747841U - Concrete reinforcement detector for supervision and management of constructional engineering - Google Patents

Abstract

The utility model relates to a concrete reinforcement detector that supervision building engineering used, which comprises a base plate, be provided with the host computer that has the treater on the bottom plate, the test probe who has the sensor, realize information transmission's wire between host computer and the test probe, the test probe below is provided with useful and drives its at the uniform velocity rectilinear sliding's of same level subassembly that slides, it is provided with the centre gripping subassembly of being connected test probe and subassembly that slides to slide between subassembly and the test probe to slide, it is useful and drive the subassembly that slides at the uniform velocity rectilinear motion's of direction of height lift subassembly to slide to be provided with between subassembly and the bottom plate, this application has the effect that makes things convenient for the staff to use and guarantees the accuracy of detection data.

Description

Concrete reinforcement detector for supervision and management of constructional engineering

Technical Field

The application relates to the technical field of concrete reinforcement detectors, in particular to a concrete reinforcement detector for supervision and management of constructional engineering.

Background

The reinforced concrete detector is a multifunctional detection device which can detect the thickness of a room protective layer, the position and the trend of a steel bar, the diameter of the steel bar, the corrosion degree of the steel bar and the like.

The existing concrete reinforcement detector for supervising constructional engineering comprises a host with a processor, a detection probe with a sensor, a wire for realizing information transmission between the host and a detection head, wherein a detector holds the host with one hand and the detection head with the other hand during use, the end face of the detection head is supported on a wall, and images and data can appear on the host, so that detection is realized.

The above prior art solutions have the following drawbacks: when the concrete reinforcement detector is used, a worker is required to tightly hold the detection probe by hands to perform uniform linear motion in a wall surface range, so that data detection is completed, and in the using process, the worker is required to have certain equipment use experience to complete detection so as to ensure the accuracy of the data.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem of the scheme, the application provides a concrete reinforcement detector for supervising building engineering.

The application provides a pair of concrete reinforcement detector that supervision building engineering used adopts following technical scheme: the utility model provides a concrete reinforcement detector that supervision building engineering used, comprising a base plate, be provided with the host computer that has the treater on the bottom plate, the test probe that has the sensor, realize the wire of information transmission between host computer and the test probe, the test probe below is provided with the subassembly that slides that has and drive it at the uniform velocity rectilinear sliding of same level, be provided with the centre gripping subassembly of connecting test probe and subassembly that slides between subassembly and the test probe that slides, it has and drives the subassembly that slides at the uniform velocity rectilinear motion's of direction of height lift subassembly to be provided with between subassembly and the bottom plate that slides.

Through adopting the above-mentioned technical scheme, when using concrete reinforcement to examine the reinforcing bar in the building, at first open the host computer, carry out fixed connection with test probe and centre gripping subassembly this moment, use wire connection host computer and test probe, start the subassembly that slides after the connection is accomplished, it drives test probe and detects at same level, after the detection is accomplished, lifting unit drives test probe and detects the reinforcing bar of different levels, thereby accomplish the detection to reinforcing bar in the building, only need staff control lifting unit and the subassembly that slides this moment, just can accomplish the use of concrete reinforcement detector, do not need the staff to have long-term measurement work experience, the accuracy of detected data has been guaranteed simultaneously.

Preferably, the subassembly that slides includes the slide, the slider, the rack, the gear and rotates the motor, the slide is located the bottom plate top, slider fixed connection is at the rack lower surface, the slider inlays to be established in the slide to with slide sliding connection, the length direction of slip direction for the straight board, rotate motor fixed connection in slide upper surface length direction one end, gear and the output shaft fixed connection who rotates the motor, and the gear is connected with the meshing of rack, the slide upper surface is provided with useful and restriction draw runner sliding distance's spacing subassembly.

Through adopting above-mentioned technical scheme, when using the subassembly that slides to drive test probe and remove, the start rotation motor, it drives gear rotation to rotate the motor, thereby it slides at slide upper surface to drive the rack, the direction of sliding is the length direction of rack, it slides at slide length direction to drive test probe when the rack is gliding, thereby accomplish the detection at same level, the setting of spacing subassembly is guaranteed that the rack is connected with the slide all the time, setting up in the spacing price of group does not need the handheld test probe of staff to do uniform linear motion, the staff work load that has reduced has been reached, guarantee the effect of the accuracy of test data simultaneously.

Preferably, the centre gripping subassembly is including fixed frame, rotation bolt, splint and rotation nail, and the one end of gear is kept away from to fixed frame fixed connection at the rack upper surface, and splint are located fixed frame, rotate the bolt run through fixed frame upper surface and with fixed frame threaded connection, rotate nail fixed connection and be close to the one end of splint at the rotation bolt, and rotate the nail and inlay and establish in splint to rotate with splint and be connected, the axis of rotation that rotates the nail is the same with the axis of rotation that rotates the bolt.

Through adopting above-mentioned technical scheme, during the use, place test probe in fixed frame, guarantee simultaneously that test probe is located between splint and the fixed frame, rotate this moment and rotate the bolt, rotate and take place relative displacement between bolt and the fixed frame, rotate the nail at the splint internal rotation simultaneously to drive splint and move to one side that is close to test probe and press from both sides test probe tight.

Preferably, lifting unit includes gag lever post and pneumatic cylinder, and fixed surface is connected on gag lever post one end and the bottom plate, and remaining one end runs through the slide and with slide sliding connection, the slip direction of slide be the length direction of gag lever post, pneumatic cylinder fixed connection slide and bottom plate.

Through adopting above-mentioned technical scheme, when lifting unit drove the process that test probe removed, start the pneumatic cylinder, the pneumatic cylinder drives the slide and removes in vertical direction, produces relative slip between gag lever post and the slide simultaneously, and the slip direction of slide is the length direction of gag lever post.

Preferably, one side of the clamping plate, which is far away from the rotating bolt, is fixedly connected with an elastic wear-resistant layer.

Through adopting above-mentioned technical scheme, the elasticity wearing layer chooses for use rubber to make as the raw materials, and rubber has certain elasticity, and when centre gripping subassembly pressed from both sides tight test probe, detection device's integrality can be guaranteed in the setting of elasticity wearing layer, and protection test probe does not receive the harm.

Preferably, a connecting rod for adjusting the relative distance between the fixed frame and the rack is arranged between the fixed frame and the rack, and the connecting rod is perpendicular to the side wall of the rack in the length direction and is fixedly connected with the lower surface of the fixed frame.

Through adopting above-mentioned technical scheme, the distance between test probe and the slide can be adjusted in the setting of connecting rod, guarantees that the slide has certain distance apart from the detection wall to guarantee measured data's accuracy.

Preferably, the connecting rod comprises a sleeve, a sliding rod and a connecting bolt, the sleeve is fixedly connected with the rack, the sliding rod is sleeved in the sleeve in a sliding mode and is connected with the sleeve in a sliding mode, the sliding direction of the sliding rod in the sleeve is the length direction of the sleeve, the connecting bolt is located at one end, far away from the rack, of the sleeve and penetrates through the sleeve to be in threaded connection with the sleeve, and the connecting bolt is abutted to the sliding rod.

Through adopting above-mentioned technical scheme, the connecting rod rotates connecting bolt when using, adjusts slide bar and sheathed tube relative distance simultaneously, adjusts after accomplishing, rotates connecting bolt, and the relative position of connecting bolt fixed sleeve pipe and slide bar to accomplish the use of connecting rod, but detection probe and detection wall butt can be guaranteed to adjustable length's connecting rod, and need not remove the position of bottom plate, reached the effect that makes things convenient for the staff to use.

Preferably, the limiting assembly comprises two limiting plates and two limiting blocks, the limiting plates are fixedly connected to two ends of the length direction of the upper surface of the sliding plate and perpendicular to the side walls of the length direction of the sliding plate, the limiting blocks are fixedly connected to one ends, away from the gear, of the racks, and through holes for the racks to pass through are formed in the side walls of the limiting plates.

Through adopting above-mentioned technical scheme, when the rack slided at the slide upper surface, produced relative displacement between rack and the slide, the setting of through-hole can only guarantee that the rack passes, and the rack can be guaranteed to be located the slide upper surface all the time to the stability of concrete reinforcement detector use is guaranteed to the ability of the stopper of fixing on the rack.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the arrangement of the sliding assembly and the lifting assembly can realize that the detection probe can detect the reinforcing steel bars in the horizontal direction and the vertical direction, meanwhile, the arrangement of the sliding assembly and the lifting assembly does not require a worker to hold the detection probe to detect the reinforcing steel bars, the worker is not required to have long-time detection experience in the use process, and meanwhile, the accuracy of detection data is ensured;

2. the arrangement of the limiting assembly can ensure that the rack is always connected with the sliding plate, and the use stability of the concrete reinforcement detector is ensured;

3. the elasticity wearing layer has certain elasticity, and when splint and test probe contacted, the setting up of elasticity wearing layer can guarantee to guarantee when rubbing between splint and the test probe that test probe can not damaged by the centre gripping subassembly, and the stability that detection device used can be guaranteed in the setting up of elasticity wearing layer.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an embodiment of the present application;

FIG. 2 is a partial cross-sectional view of the components showing the glide assembly;

FIG. 3 is a partial schematic view of the clamping assembly.

In the figure, 1, a bottom plate; 2. a host; 3. detecting a probe; 4. a wire; 5. a slipping component; 51. a slide plate; 52. a slider; 53. a rack; 54. a gear; 55. rotating the motor; 6. a clamping assembly; 61. a fixing frame; 62. rotating the bolt; 63. a splint; 631. an elastic wear layer; 64. rotating the nail; 7. a lifting assembly; 71. a limiting rod; 72. a hydraulic cylinder; 8. a limiting component; 81. a limiting block; 82. a limiting plate; 821. a through hole; 9. a connecting rod; 91. a sleeve; 92. a slide bar; 93. and connecting the bolts.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses a concrete reinforcement detector for supervision and management of constructional engineering.

Referring to fig. 1 and 2, the concrete reinforcing bar detector comprises a bottom plate 1, a host machine 2 with a processor, a detection probe 3 with a sensor and a lead 4 for realizing information transmission between the host machine 2 and the detection probe 3 are arranged on the bottom plate 1, a sliding component 5 for driving the detection probe 3 to do uniform linear motion on the same horizontal plane is arranged between the detection probe 3 and the bottom plate 1, a lifting component 7 for driving the detection probe 3 to do uniform linear motion in the vertical direction is arranged between the sliding component 5 and the bottom plate 1, a clamping component 6 for clamping the detection probe 3 is arranged between the detection probe 3 and the sliding component 5, the detection probe 3 is connected with the clamping component 6 when in use, the sliding component 5 is adjusted at the moment, the sliding component 5 drives the detection probe 3 to do uniform linear motion on the same horizontal plane, and the detection on the same horizontal height of a wall surface is completed, after the detection is completed, the lifting assembly 7 is adjusted, the lifting assembly 7 drives the detection probe 3 to do uniform linear motion in the vertical direction, so that the detection of reinforcing steel bars at different heights of the wall surface is realized, the whole detection process only needs a worker to control the lifting assembly 7 and the sliding assembly 5, the worker does not need to have many years of working experience, and the accuracy of detection data can be guaranteed.

Referring to fig. 1 and 2, the sliding assembly 5 includes a sliding plate 51, a sliding block 52, a rack 53, a gear 54 and a rotating motor 55, the sliding plate 51 is located above the bottom plate 1, the sliding block 52 is fixedly connected to the lower surface of the rack 53, the sliding block 52 is embedded in the sliding plate 51 and is slidably connected to the sliding plate 51, the sliding direction of the rack 53 is the length direction thereof, the rotating motor 55 is fixedly connected to the upper surface of the sliding plate 51, the gear 54 is fixedly connected to the output shaft of the rotating motor 55, the gear 54 is engaged with the rack 53, and two ends of the length direction of the upper surface of the sliding plate 51 are fixedly connected with the limiting assemblies 8 for limiting the sliding. When the sliding assembly 5 drives the detection probe 3 to move, the rotating motor 55 is started, and the output shaft of the rotating motor 55 drives the gear 54 to rotate, so that the relative position between the adjusting rack 53 and the sliding plate 51 is realized, the sliding of the adjusting slide block 52 on the same horizontal plane is finally realized, the sliding assembly 5 can drive the detection probe 3 to move at a constant speed, and the effect of ensuring the stability of detection data is achieved.

Referring to fig. 1, limiting assembly 8 includes limiting plate 82 and limiting block 81, limiting plate 82 fixed connection is at slide 51 upper surface length direction both ends, slider 52 fixed connection is in the one end that gear 54 was kept away from to rack 53, the through-hole 821 that supplies rack 53 to pass is seted up to limiting plate 82 lateral wall, when rotating motor 55 and driving rack 53 and moving, limiting plate 82 passes and produces relative displacement between through-hole 821 and slide 51, when limiting plate 82 and limiting block 81 butt or with connecting rod 9 butt, mutual position between rack 53 and the slide 51 no longer changes, the effect of guaranteeing rack 53 and slide 51 cooperation stability in use has been reached.

Referring to fig. 1 and 3, the clamping assembly 6 includes a fixed frame 61, a rotating bolt 62, a clamping plate 63 and a rotating nail 64, a connecting rod 9 for adjusting the distance between the fixed frame 61 and the rack 53 is disposed between the fixed frame 61 and the rack 53, the connecting rod 9 includes a sliding rod 92 and a connecting bolt 93, one end of a sleeve 91 is fixedly connected with the rack 53, the sleeve 91 is parallel to the upper surface of the rack 53 and perpendicular to the side wall of the rack 53 in the length direction, the sliding rod 92 of the sleeve 91 is inserted into the sleeve 91 and slidably connected with the sleeve 91, the sliding direction is the length direction of the sleeve 91, the connecting bolt 93 is disposed at one end of the sleeve 91 far away from the connecting plate, the connecting bolt 93 penetrates through the sleeve 91 and abuts against the sliding rod 92, one end of the sliding rod 92 far away from the sleeve 91 is fixedly connected with the fixed frame 61, the rotating bolt 62 penetrates through, and rotate the nail 64 and inlay and establish in splint 63 to be connected with splint 63 rotation, the axis of rotation of rotating nail 64 is the central line of rotating bolt 62 length direction, rotates during the use and rotates bolt 62, takes place relative displacement between rotation bolt 62 and the fixed frame 61, thereby presss from both sides the test probe 3 tightly, and the distance between test probe 3 and the wall can be adjusted to the setting of connecting rod 9, does not need the staff to remove bottom plate 1, has reached the effect that makes things convenient for the staff to use.

Referring to fig. 1, lifting unit 7 includes gag lever post 71 and pneumatic cylinder 72, pneumatic cylinder 72 fixed connection bottom plate 1 and slide 51, gag lever post 71 fixed connection is at bottom plate 1 upper surface length direction both ends, and the one end that bottom plate 1 was kept away from to gag lever post 71 runs through slide 51, and with slide 51 sliding connection, slide 51's slip direction is gag lever post 71's length direction, use lifting unit 7 to drive the in-process that splint 63 rose, staff's control hydraulic cylinder 72, pneumatic cylinder 72 slide 51 removes in vertical direction, thereby realize the reinforcing bar in vertical direction detection wall.

The embodiment of the application provides a concrete reinforcement detector for supervision and management of building engineering, and the implementation principle is as follows: when using concrete reinforcement detector to detect the reinforcing bar in the building, with test probe 3 and 6 fixed connection of centre gripping subassembly, readjust connecting rod 9, guarantee test probe 3 and wall butt, after the regulation is accomplished, start subassembly 5 or lifting unit 7 that slides, the realization is to the not detection of wall co-altitude and same level different positions, whole operation process does not need the handheld test probe 3 of staff to detect, consequently, the process of detection need not necessarily have the staff of long-time work experience and just can accomplish the detection, the accuracy of detected data has been guaranteed simultaneously.

The embodiments of the present invention are preferred embodiments of the present application, and the scope of protection of the present application is not limited by the embodiments, so: all equivalent changes in the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides a concrete reinforcement detector that prises building engineering used which characterized in that: the device comprises a bottom plate (1), a host (2) with a processor is arranged on the bottom plate (1), a detection probe (3) with a sensor and a wire (4) for realizing information transmission between the host (2) and the detection probe (3), a sliding component (5) for driving the sliding component to slide linearly at the same uniform speed at the same horizontal height is arranged below the detection probe (3), a clamping component (6) for connecting the detection probe (3) with the sliding component (5) is arranged between the sliding component (5) and the detection probe (3), and a lifting component (7) for driving the sliding component (5) to move linearly at the uniform speed in the height direction is arranged between the sliding component (5) and the bottom plate (1).

2. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 1, wherein: the sliding assembly (5) comprises a sliding plate (51), a sliding block (52), a rack (53), a gear (54) and a rotating motor (55), wherein the sliding plate (51) is located above the bottom plate (1), the sliding block (52) is fixedly connected to the lower surface of the rack (53), the sliding block (52) is embedded in the sliding plate (51) and is in sliding connection with the sliding plate (51), the sliding direction is the length direction of a straight plate, the rotating motor (55) is fixedly connected to one end of the length direction of the upper surface of the sliding plate (51), the gear (54) is fixedly connected with an output shaft of the rotating motor (55), the gear (54) is meshed with the rack (53) and is connected with the limiting assembly (8) for limiting the sliding distance of the rack (53) arranged on the upper surface of the sliding plate (51).

3. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 2, wherein: centre gripping subassembly (6) are including fixed frame (61), rotation bolt (62), splint (63) and rotation nail (64), the one end of gear (54) is kept away from to fixed frame (61) fixed connection at rack (53) upper surface, splint (63) are located fixed frame (61), rotation bolt (62) run through fixed frame (61) upper surface and with fixed frame (61) threaded connection, rotation nail (64) fixed connection is in the one end that rotation bolt (62) are close to splint (63), and rotation nail (64) inlay and establish in splint (63), and rotate with splint (63) and be connected, the rotation axis that rotates nail (64) is the same with the rotation axis that rotates bolt (62).

4. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 1, wherein: lifting unit (7) include gag lever post (71) and pneumatic cylinder (72), gag lever post (71) one end and bottom plate (1) upper surface fixed connection, remaining one end run through slide (51) and with slide (51) sliding connection, the slip direction of slide (51) is the length direction of gag lever post (71), pneumatic cylinder (72) fixed connection slide (51) and bottom plate (1).

5. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 3, wherein: and one side of the clamping plate (63) far away from the rotating bolt (62) is fixedly connected with an elastic wear-resistant layer (631).

6. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 3, wherein: a connecting rod (9) for adjusting the relative distance between the fixed frame (61) and the rack (53) is arranged between the fixed frame (61) and the rack (53), and the connecting rod (9) is vertical to the side wall of the rack (53) in the length direction and is fixedly connected with the lower surface of the fixed frame (61).

7. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 6, wherein: the connecting rod (9) comprises a sleeve (91), a sliding rod (92) and a connecting bolt (93), the sliding rod (92) is fixedly connected with the rack (53), the sliding rod (92) is slidably sleeved in the sleeve (91) and is slidably connected with the sleeve (91), the sliding direction of the sliding rod (92) in the sleeve is the length direction of the sleeve (91), the connecting bolt (93) is located at one end, far away from the rack (53), of the sleeve (91) and penetrates through the sleeve (91) to be in threaded connection with the sleeve (91), and the connecting bolt (93) is abutted to the sliding rod (92).

8. A concrete reinforcing bar detecting instrument for supervising constructional engineering according to claim 2, wherein: spacing subassembly (8) are provided with two including limiting plate (82) and limiting block (81), limiting plate (82) fixed connection at slide (51) upper surface length direction both ends, and perpendicular with slide (51) upper surface and slide (51) length direction lateral wall, and limiting block (81) fixed connection keeps away from the one end of gear (54) in rack (53), and through-hole (821) that supply rack (53) to pass are seted up to limiting plate (82) lateral wall.

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