CN219391602U - Steel intensity detection device for building detection - Google Patents

Abstract

The utility model discloses a steel intensity detection device for building detection, which comprises a detection box and further comprises: the support plate is provided with a guide rail on one side, a plurality of support blocks are slidably arranged on the guide rail, a support rod is arranged on the support blocks, a plurality of fixing plates are arranged on the support rod, a placing groove is formed in each fixing plate, and springs are arranged among the support blocks; the detection box is internally provided with a lifting frame, the lifting frame is internally provided with a mounting plate, a plurality of movable blocks are slidably arranged on the mounting plate, the center of each movable block is slidably provided with a detection rod, one end of each detection rod is provided with a pressing plate, and the lifting frame is internally provided with a pressure sensor; a plurality of steels are placed between two standing grooves respectively, and the fixed plate is fixed to the steels, conveniently fixes the steels of different sizes, has realized the detection of a plurality of steels.

Description

Steel intensity detection device for building detection

Technical Field

The utility model relates to the technical field of steel detection, in particular to a steel strength detection device for building detection.

Background

The steel is a material with certain shape, size and performance, which is made of steel ingots or billets through pressure processing, a large amount of steel is needed to be used for building a frame of a building during construction, the strength of the building steel refers to the fracture resistance of the material under the action of external force, and in order to ensure the use safety of the steel, a strength detection device is needed to measure the strength of the steel.

The existing steel strength detection device is used for placing steel on a workbench generally, the steel is measured through a pressure sensor and a pressure head, the device cannot measure a plurality of steel simultaneously, the use efficiency of the detection device is low, the detection device cannot be suitable for detecting large-batch steel, and normal building detection is not facilitated.

Disclosure of Invention

The utility model aims to provide a steel strength detection device for building detection, which aims to solve the problems in the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a steel intensity detection device for building detects, includes the detection case, still includes:

the steel support device comprises a support plate, wherein one side of the support plate is provided with a guide rail, a plurality of support blocks are arranged on the guide rail in a sliding manner, a support rod is arranged on the support blocks, a plurality of fixing plates are arranged on the support rod, a placing groove for placing steel is formed in each fixing plate, and springs are arranged among the support blocks;

the detection box is internally provided with a lifting frame, the lifting frame is internally provided with a mounting plate, a plurality of movable blocks are slidably arranged on the mounting plate, the center of each movable block is slidably provided with a detection rod, one end of each detection rod is provided with a pressing plate, and the lifting frame is internally provided with a pressure sensor;

the fixing mechanism is arranged in the supporting plate and is used for extruding and fixing steel materials in a mode of driving the fixing plates to be close to each other;

and the detection mechanism is connected with the lifting frame and detects the strength of the steel by driving the detection rod to extrude the steel.

Based on the technical scheme, the utility model also provides the following optional technical schemes:

in one alternative: the fixed establishment includes dwang, driving block, nut and motor, the dwang rotates and sets up inside the backup pad, the supporting shoe bottom is provided with the driving block, driving block one end penetrates inside the backup pad and the cover is established on the dwang, fixedly on the driving block be provided with the nut, the dwang outside is provided with the external screw thread with nut matched with, motor rotation end and dwang fixed connection.

In one alternative: the detection mechanism comprises a threaded sleeve, a screw rod, lifting plates and a power assembly for driving the threaded sleeve to rotate, the threaded sleeve is arranged at the top of the detection box in a rotating mode, the screw rod is arranged inside the threaded sleeve, the lifting plates are fixedly arranged on two sides of the lifting frame, and one end of the screw rod is fixedly connected with the lifting plates.

In one alternative: the power assembly comprises a transmission motor and a transmission belt, belt pulleys are arranged outside the two threaded sleeves, the transmission belt is arranged between the two belt pulleys, and the motor rotating end is connected with the threaded sleeves through the transmission belt.

In one alternative: the square groove is formed in the center of the mounting plate, the movable block is slidably arranged in the square groove, and bolts are arranged outside the mounting plate.

Compared with the prior art, the utility model has the following beneficial effects:

the steel intensity detection device for building detection is used for measuring steel by downwards extruding the detection rod, the pressure sensor is upwards extruded by the pressing plate at the top of the detection rod, the pressure applied by the detection rod can be obtained through the display screen, a plurality of steels are respectively placed between two placing grooves, the supporting blocks drive the fixing plates to be close to each other through the supporting rods arranged at the top, the fixing plates fix the steels, the steels with different sizes are convenient to fix, and simultaneous detection of a plurality of steels is realized.

Drawings

FIG. 1 is a schematic view of a construction of a steel strength detecting device for building detection.

Fig. 2 is a cross-sectional view of the steel strength detecting device for building detection.

Fig. 3 is a cross-sectional view of the lifting frame in the steel strength detecting device for building detection.

Reference numerals annotate: 1-detection box, 2-backup pad, 3-supporting shoe, 4-bracing piece, 5-fixed plate, 501-standing groove, 6-guide rail, 7-spring, 8-dwang, 9-nut, 10-driving block, 11-motor, 12-cushion, 13-lifter plate, 14-lifting frame, 15-mounting panel, 151-square groove, 16-detecting rod, 17-pressure sensor, 18-clamp plate, 19-movable block, 20-reset spring, 21-lead screw, 22-driving belt, 23-threaded sleeve, 24-belt pulley, 25-stopper, 26-driving motor, 27-display screen, 28-bolt.

Description of the embodiments

In order to make the objects, technical solutions and advantages of the present utility model more apparent, the present utility model will be described in further detail with reference to the accompanying drawings and examples; in the drawings or description, similar or identical parts are provided with the same reference numerals, and in practical applications, the shape, thickness or height of each part may be enlarged or reduced. The examples set forth herein are intended to be illustrative of the utility model and are not intended to limit the scope of the utility model. Any obvious modifications or alterations to the utility model, as would be apparent, are made without departing from the spirit and scope of the present utility model.

In one embodiment, as shown in fig. 1 to 3, a steel strength detection device for building detection includes a detection box 1, and further includes:

the support plate 2 is installed inside the detection box 1 through a cushion block 12 arranged at the bottom, a U-shaped guide rail 6 is fixedly arranged on one side of the support plate 2, a plurality of support blocks 3 are slidably arranged on the guide rail 6, a support rod 4 is fixedly arranged on the support blocks 3, a plurality of fixing plates 5 are fixedly arranged on the support rod 4, placing grooves 501 for placing steel are formed in two sides of the fixing plates 5, springs 7 are arranged between the support blocks 3, and the springs 7 are sleeved on the guide rail 6;

the detection box 1 is internally provided with a lifting frame 14, the lifting frame 14 is internally fixedly provided with a mounting plate 15, the mounting plate 15 is provided with a plurality of movable blocks 19 in a sliding manner, the center of each movable block 19 is provided with a detection rod 16 in a sliding manner, one end of each detection rod 16 is provided with a pressing plate 18, the outside of each detection rod 16 is sleeved with a reset spring 20, the lifting frame 14 is internally provided with a pressure sensor 17, the pressure sensor 17 is positioned right above the pressing plate 18, and the pressure sensor 17 is electrically connected with a display screen 27 outside the detection box 1;

the fixing mechanism is arranged in the supporting plate 2 and is used for extruding and fixing steel materials in a way of driving the fixing plates 5 to approach each other;

and the detection mechanism is connected with the lifting frame 14 and detects the strength of the steel by driving the detection rod 16 to extrude the steel.

The steel intensity detection device for building detection drives the fixed plate 5 to be close to each other through the fixed mechanism, steel is placed between two standing grooves 501, the fixed plate 5 is used for fixing and clamping the steel, the detection mechanism drives the detection rod 16 to descend, the bottom of the detection rod 16 is used for extruding the steel, the pressing plate 18 at the top of the detection rod 16 is upwards used for extruding the pressure sensor 17, the pressure applied by the detection rod 16 can be obtained through the display screen 27, after detection is completed, the intensity of the steel can be obtained according to the deformation quantity of the surface of the steel, simultaneous detection of a plurality of steels is realized, the left, right, upper and lower positions of all components in the drawing are only one arrangement mode, and specific positions are set according to specific requirements.

In one embodiment, as shown in fig. 2, the fixing mechanism comprises a rotating rod 8, a driving block 10, a nut 9 and a motor 11, the rotating rod 8 is rotatably arranged inside the supporting plate 2, a plurality of driving blocks 10 are arranged at the bottoms of the supporting blocks 3, one end of each driving block 10 penetrates into the supporting plate 2 and is sleeved on the corresponding rotating rod 8, the nut 9 is fixedly arranged on the driving block 10, external threads matched with the nut 9 are arranged on the outer portion of the rotating rod 8, the rotating end of the motor 11 is fixedly connected with the rotating rod 8, the motor 11 drives the rotating rod 8 to rotate, the rotating rod 8 drives the driving blocks 10 to be close to each other, the supporting blocks 3 at two ends of the guide rail 6 are close to each other and squeeze the supporting blocks 3 at the central position, the supporting blocks 3 drive the fixing plates 5 to be close to each other through supporting rods 4 arranged at the top, and the fixing plates 5 fix steel.

In one embodiment, as shown in fig. 2, the detection mechanism includes a threaded sleeve 23, a screw 21, a lifting plate 13 and a power assembly for driving the threaded sleeve 23 to rotate, the threaded sleeve 23 is rotatably disposed at the top of the detection box 1, the screw 21 is disposed inside the threaded sleeve 23, the screw 21 is a ball screw and is matched with a threaded groove inside the threaded sleeve 23, the lifting plate 13 is fixedly disposed on two sides of the lifting frame 14, one end of the screw 21 is fixedly connected with the lifting plate 13, a limiting block 25 is disposed on the other end of the screw 23, and since the screw 21 is fixedly disposed, the threaded sleeve 23 rotates and drives the screw 21 to move up and down, and the screw 21 drives the lifting plate 13 and the lifting frame 14 to move up and down.

In one embodiment, as shown in fig. 2, the power assembly includes a transmission motor 26 and a transmission belt 22, two belt pulleys 24 are disposed outside the threaded sleeves 23, a transmission belt 22 is disposed between the two belt pulleys 24, a rotating end of the motor 26 is connected with the threaded sleeves 23 through the transmission belt 22, and the transmission motor 26 drives the two threaded sleeves 23 to rotate through the transmission belt 22.

In one embodiment, as shown in fig. 3, a square groove 151 is formed in the center of the mounting plate 15, the movable block 19 is slidably disposed inside the square groove 151, a bolt 28 is disposed outside the mounting plate 15, and the slide block 19 can drive the detection rod 16 to move left and right, so that the pressing plate 18 on the top of the detection rod 16 is aligned with the pressure sensor 17, and the slide block 19 is fixed by the bolt 28.

In the above embodiment of the present utility model, a plurality of steels are respectively placed between two placing grooves 501, a motor 11 drives a rotating rod 8 to rotate, the rotating rod 8 drives a driving block 1 and a supporting block 3 to approach each other, the supporting block 3 drives a fixing plate 5 to approach each other through a supporting rod 4 arranged at the top, the fixing plate 5 fixes steels with different sizes, the lifting frame 14 drives a detecting rod 16 to descend, the detecting rod 16 extrudes the steels, a pressing plate 18 at the top of the detecting rod 16 extrudes a pressure sensor 17 upwards, and the pressure applied by the detecting rod 16 can be obtained through a display screen 27, so that the strength of the steels can be obtained.

The foregoing is merely specific embodiments of the disclosure, but the protection scope of the disclosure is not limited thereto, and any person skilled in the art can easily think about changes or substitutions within the technical scope of the disclosure, and it is intended to cover the scope of the disclosure. Therefore, the protection scope of the present disclosure shall be subject to the protection scope of the claims.

Claims (5)

1. The utility model provides a steel intensity detection device for building detects, includes the detection case, its characterized in that still includes:

the steel support device comprises a support plate, wherein one side of the support plate is provided with a guide rail, a plurality of support blocks are arranged on the guide rail in a sliding manner, a support rod is arranged on the support blocks, a plurality of fixing plates are arranged on the support rod, a placing groove for placing steel is formed in each fixing plate, and springs are arranged among the support blocks;

the detection box is internally provided with a lifting frame, the lifting frame is internally provided with a mounting plate, a plurality of movable blocks are slidably arranged on the mounting plate, the center of each movable block is slidably provided with a detection rod, one end of each detection rod is provided with a pressing plate, and the lifting frame is internally provided with a pressure sensor;

the fixing mechanism is arranged in the supporting plate and is used for extruding and fixing steel materials in a mode of driving the fixing plates to be close to each other;

and the detection mechanism is connected with the lifting frame and detects the strength of the steel by driving the detection rod to extrude the steel.

2. The steel strength detection device for building detection according to claim 1, wherein the fixing mechanism comprises a rotating rod, a driving block, a nut and a motor, the rotating rod is rotatably arranged inside the supporting plate, the driving block is arranged at the bottom of the supporting block, one end of the driving block penetrates into the supporting plate and is sleeved on the rotating rod, the nut is fixedly arranged on the driving block, an external thread matched with the nut is arranged outside the rotating rod, and the rotating end of the motor is fixedly connected with the rotating rod.

3. The steel strength detection device for building detection according to claim 2, wherein the detection mechanism comprises a threaded sleeve, a screw rod, a lifting plate and a power assembly for driving the threaded sleeve to rotate, the threaded sleeve is rotatably arranged at the top of the detection box, the screw rod is arranged in the threaded sleeve, the lifting plate is fixedly arranged on two sides of the lifting frame, and one end of the screw rod is fixedly connected with the lifting plate.

4. The steel strength detection device for building detection according to claim 3, wherein the power assembly comprises a transmission motor and a transmission belt, belt pulleys are arranged outside the two threaded sleeves, the transmission belt is arranged between the two belt pulleys, and the motor rotating end is connected with the threaded sleeves through the transmission belt.

5. The steel strength detection device for building detection according to claim 1, wherein the square groove is formed in the center of the mounting plate, the movable block is slidably arranged in the square groove, and a bolt is arranged outside the mounting plate.