CN221959943U - A concrete slab hardness testing device - Google Patents

Abstract

A concrete slab hardness testing device includes a first support rod and a second support rod, a rotating screw is arranged between the first support rod and the second support rod, a plurality of sliders are arranged on the rotating screw, an isolation plate is fixedly arranged below the slider, a sliding through hole is arranged on the isolation plate, a vertical bracket is arranged above the isolation plate, a sliding test piece is arranged on the vertical bracket, and the sliding test piece is arranged in coordination with the sliding through hole. The present application adopts a rotating screw to actively drive the slider, and then uses the slider to drive the isolation plate, and the isolation plate drives the vertical bracket, and the sliding test piece on the vertical bracket can slide with equal pressure, thereby ensuring the reproducibility of the results.

Description

A concrete slab hardness testing device

Technical Field

The present application relates to a concrete slab hardness testing device.

Background Art

Whether it is a public building, a private building, a warehouse, etc., the ground, roof, top surface, etc. need to be set with a hardened plate, which is generally made of concrete as the main structure. For different types of ground, the specific requirements for ground hardness are different, so it is necessary to continuously test the ground hardness. At present, the ground hardness is generally measured by a handheld hardness tester. The biggest problem with this measurement method is that the measurement results of different people may be different. Even the same person may get different results at different times due to different grip strength, and the reproducibility is very poor.

Utility Model Content

In order to solve the above problems, the present application proposes a concrete slab hardness testing device, including a first support rod and a second support rod, a rotating screw rod is arranged between the first support rod and the second support rod, a plurality of sliders are arranged on the rotating screw rod, an isolation plate is fixedly arranged below the slider, a sliding through hole is arranged on the isolation plate, a vertical bracket is arranged above the isolation plate, a sliding test piece is arranged on the vertical bracket, and the sliding test piece is arranged in coordination with the sliding through hole. The present application adopts a rotating screw rod to actively drive the slider, and then uses the slider to drive the isolation plate, and the isolation plate drives the vertical bracket, and the sliding test piece on the vertical bracket can slide with equal pressure, thereby ensuring the reproducibility of the results.

Preferably, a plurality of guide slide bars are arranged between the first support bar and the second support bar, and a plurality of sliding sleeve blocks are arranged on the guide slide bars, and the bottom of the sliding sleeve blocks is fixedly connected to the isolation plate. The present application drives the isolation plate by rotating the screw and the slider, and then guides the sliding sleeve blocks by using the guide slide bars and the sliding sleeve blocks, thereby ensuring the reliability of the entire driving process.

Preferably, the number of the guide sliding rods is two, and the rotating screw is arranged on one side of the guide sliding rod.

Preferably, the vertical bracket includes a vertical rod, an inclined plate is arranged on the vertical rod, a sliding hole is arranged on the inclined plate, and the sliding test piece is slidably arranged in the sliding hole.

Preferably, the sliding test piece includes a test rod, a sliding collar is arranged on the test rod, the sliding collar is slidably arranged in the sliding hole, a plurality of counterweights are arranged on the test rod above the sliding collar, and a test needle is arranged below the test rod. The present application can test the size of the downward pressure on the needle by configuring the counterweight, ensuring that the downward pressure of the needle is well adjustable during use.

Preferably, a middle mounting hole is provided at the bottom of the test rod, a test needle is provided in the middle mounting hole, a positioning hole is provided at the position of the middle mounting hole corresponding to the test rod, a positioning screw is passed through the positioning hole and abuts against the test needle.

Preferably, a rotary motor is dynamically connected to the rotary screw.

Preferably, the rotating motor is arranged on the first supporting rod.

Preferably, a stabilizing spring is provided between the vertical support and the first supporting rod.

This application can bring the following beneficial effects:

1. This application uses a rotating screw to actively drive a slider, and then uses the slider to drive an isolation plate, and the isolation plate drives a vertical bracket. The sliding test piece on the vertical bracket can slide with equal pressure, thereby ensuring the reproducibility of the results.

2. The present application uses a rotating screw and a slider to drive the isolation plate, and then uses a guide slide rod and a sliding sleeve to guide the sliding sleeve, thereby ensuring the reliability of the entire driving process.

3. The present application can test the size of the downward pressure applied on the needle by configuring the counterweight block, thereby ensuring that the downward pressure applied by the needle is well adjustable during use.

BRIEF DESCRIPTION OF THE DRAWINGS

The drawings described herein are used to provide a further understanding of the present application and constitute a part of the present application. The illustrative embodiments of the present application and their descriptions are used to explain the present application and do not constitute an improper limitation on the present application. In the drawings:

FIG1 is a schematic diagram of the structure of the present application;

FIG2 is a schematic diagram of the side structure of the present application;

FIG. 3 is a schematic diagram of the structure of the sliding test piece.

DETAILED DESCRIPTION

In order to clearly illustrate the technical features of the present solution, the present application is described in detail below through specific implementation methods and in conjunction with the accompanying drawings.

In the first embodiment, as shown in FIG1 , a concrete slab hardness testing device includes a first support rod 1 and a second support rod 2, a rotating screw rod 3 is arranged between the first support rod 1 and the second support rod 2, a plurality of sliders 4 are arranged on the rotating screw rod 3, an isolation plate 5 is fixedly arranged below the sliders 4, a sliding through hole 6 is arranged on the isolation plate 5, a vertical bracket 7 is arranged above the isolation plate 5, a sliding test piece 8 is arranged on the vertical bracket 7, and the sliding test piece 8 is arranged in cooperation with the sliding through hole 6.

When in use, the present application is set on the surface to be measured, the sliding through hole 6 is set in coordination with the measuring surface, and then the rotating screw 3 is used to actively drive the slider 4, and then the slider 4 is used to drive the isolation plate 5, and the isolation plate 5 drives the vertical bracket 7, and the sliding test piece 8 on the vertical bracket 7 can perform equal pressure sliding.

In the second embodiment, as shown in Fig. 1-3, a concrete slab hardness testing device comprises a first support rod 1 and a second support rod 2, a rotating screw rod 3 is arranged between the first support rod 1 and the second support rod 2, a plurality of sliders 4 are arranged on the rotating screw rod 3, an isolation plate 5 is fixedly arranged below the slider 4, a sliding through hole 6 is arranged on the isolation plate 5, a vertical bracket 7 is arranged above the isolation plate 5, a sliding test piece 8 is arranged on the vertical bracket 7, and the sliding test piece 8 is arranged in cooperation with the sliding through hole 6. A plurality of guide slide rods 9 are arranged between the first support rod 1 and the second support rod 2, a plurality of sliding sleeves 10 are arranged on the guide slide rods 9, and the bottom of the sliding sleeves 10 is fixedly connected with the isolation plate 5. The number of the guide slide rods 9 is two, and the rotating screw rod 3 is arranged on one side of the guide slide rod 9. The vertical bracket 7 comprises a vertical rod 11, an inclined plate 12 is arranged on the vertical rod 11, a sliding hole is arranged on the inclined plate 12, and the sliding test piece 8 is slidably arranged in the sliding hole. The sliding test piece 8 includes a test rod 13, a sliding collar 14 is arranged on the test rod 13, the sliding collar 14 is slidably arranged in the sliding hole, a plurality of counterweights 15 are arranged on the test rod 13 above the sliding collar 14, and a test pin 16 is arranged below the test rod 13. A middle mounting hole (not shown in the figure) is arranged at the bottom of the test rod 13, a test pin 16 is arranged in the middle mounting hole, a positioning hole is arranged at the position of the middle mounting hole corresponding to the test rod 13, and a positioning screw 17 is passed through the positioning hole and abutted against the test pin 16. A rotating motor 18 is connected to the rotating screw 3. The rotating motor 18 is arranged on the first support rod 1. A stabilizing spring (not shown in the figure) is arranged between the vertical bracket 7 and the first support rod 1.

When in use, the present application is set on the surface to be measured, the sliding through hole 6 is set in coordination with the measuring surface, and then the rotating screw 3 is used to actively drive the slider 4, and then the slider 4 is used to drive the isolation plate 5, and the isolation plate 5 drives the vertical bracket 7. The sliding test piece 8 on the vertical bracket 7 can slide with equal pressure. When the pressure needs to be adjusted, the corresponding effect can be achieved by increasing or decreasing the number of counterweights.

The above are only embodiments of the present application and are not intended to limit the present application. For those skilled in the art, the present application may have various changes and variations. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included within the scope of the claims of the present application.

Claims (9)

1. A concrete slab hardness testing device is characterized in that: including first bracing piece and second bracing piece, be provided with a rotatory screw rod between first bracing piece and second bracing piece, be provided with a plurality of sliders on rotatory screw rod, set up a division board at the fixed below of slider, set up a sliding through hole on the division board, set up a vertical support in the top of division board, set up a slip test piece on the vertical support, slip test piece sets up with the sliding through hole cooperation.

2. A concrete slab hardness testing apparatus according to claim 1, wherein: a plurality of guide sliding rods are arranged between the first supporting rods and the second supporting rods, a plurality of sliding sleeve blocks are arranged on the guide sliding rods, and the bottoms of the sliding sleeve blocks are fixedly connected with the isolation plates.

3. A concrete slab hardness testing apparatus according to claim 2, wherein: the number of the guide slide bars is two, and the rotary screw is arranged on one side of the guide slide bars.

4. A concrete slab hardness testing apparatus according to claim 1, wherein: the vertical support comprises a vertical rod, an inclined plate is arranged on the vertical rod, a sliding hole is formed in the inclined plate, and the sliding test piece is arranged in the sliding hole in a sliding mode.

5. The concrete slab hardness testing apparatus according to claim 4, wherein: the sliding test piece comprises a test rod, a sliding sleeve ring is arranged on the test rod, the sliding sleeve ring is arranged in a sliding hole in a sliding mode, a plurality of balancing weights are arranged on the test rod above the sliding sleeve ring, and a test needle is arranged below the test rod.

6. The concrete slab hardness testing apparatus according to claim 5, wherein: the bottom of the test rod is provided with a middle mounting hole, a test needle is arranged in the middle mounting hole, a positioning hole is formed in the position, corresponding to the test rod, of the middle mounting hole, and a positioning screw rod is arranged in the positioning hole in a penetrating mode and is in butt joint with the test needle.

7. A concrete slab hardness testing apparatus according to claim 1, wherein: a rotary motor is in power connection with the rotary screw.

8. A concrete slab hardness testing apparatus according to claim 7, wherein: the rotating motor is arranged on the first supporting rod.

9. A concrete slab hardness testing apparatus according to claim 1, wherein: a stabilizing spring is arranged between the vertical support and the first support rod.