CN220960875U

CN220960875U - Material strength detection device

Info

Publication number: CN220960875U
Application number: CN202322667765.8U
Authority: CN
Inventors: 李航
Original assignee: Individual
Current assignee: Individual
Priority date: 2023-10-07
Filing date: 2023-10-07
Publication date: 2024-05-14
Anticipated expiration: 2033-10-07

Abstract

The utility model provides a material strength detection device, which relates to the field of strength detection and aims to solve the problems that after a common strength detection device for building materials is used for multiple times, a detection sensing assembly is contacted with the building materials, residues or dirt are easy to generate at the contact position, cleaning is laborious and detection efficiency is affected. After detecting that sensing subassembly bottom is infected with the residue, directly pulling control the subassembly and drive the clean subassembly of contact and displace together, after the top side of the clean subassembly of contact and the contact of detection sensing subassembly side, automatic atress displacement compresses the spring, and the top of the clean subassembly of contact and clean groove are through detecting the bottom of sensing subassembly, will detect the convenient clear of residue of sensing subassembly bottom, improve clean efficiency.

Description

Material strength detection device

Technical Field

The utility model belongs to the technical field of strength detection, and particularly relates to a material strength detection device.

Background

Before using, building material need carry out intensity detection to it, and then whether short-term test building material accords with the use standard of setting up, avoid the potential safety hazard to appear later stage, and the common intensity detection device who is used for building material on the market detects the support position area less, if meet long strip or the great material of volume and detect afterwards, the supporting effect is weaker, lead to building material to drop or incline easily, and after detecting sensing assembly used many times, after contacting with building material, the contact position produces residue or dirt easily, it is comparatively laborious to clear away, influence detection efficiency.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a material strength detection device, which is used for solving the problems that the common strength detection device for building materials has smaller detection support position area, has weaker support effect after encountering long strip or large-volume materials for detection, and is easy to cause the falling or tilting of the building materials.

The utility model provides a material strength detection device, which comprises: an intensity detection device; the top end of the strength detection device is provided with a freely telescopic pushing component, the top end of the pushing component is spliced with a splicing component, the top end of the splicing component is matched with the adjusting component and is arranged above the splicing component to slide freely, the bottom of the adjusting component is fixedly provided with two positioning slide bars, and the top end of the strength detection device is provided with a supporting ejector rod; the top subassembly, the outside at the support ejector pin is fixed to the top subassembly, and the top subassembly is connected with the moving part that can freely reciprocate through controlling the subassembly, and the inboard of moving part is fixed with the clean subassembly of contact of flexible rubber material, and the top both sides of the clean subassembly of contact are the arc structure.

Optionally, two sides of the pushing component are respectively fixed with a supporting rod with a U-shaped structure, two round holes are formed in each supporting rod, a top groove with a rectangular structure is formed in the top end of the splicing component, an adjusting component is embedded in the top groove and is freely pulled out of the top groove, two guide grooves with arc-shaped structures at two ends are formed in the bottom end of the top groove, and positioning sliding rods are inserted into the guide grooves; the two sides of the pushing component are respectively welded and fixed with a reinforcing rod with a U-shaped structure and displace along with the pushing component, the two sides of the reinforcing rod made of metal materials are of an inclined structure, the top end of the reinforcing rod is fixedly connected with the bottom of the supporting rod, and the supporting rod is supported; the bottom of concatenation subassembly is fixed with two rectangular column structure's embedded rod, and embedded rod location is fixed to the inside location of bracing piece, and the bottom of every embedded rod is fixed with two column structure's locating component, and locating component inserts and fixes a position in the round hole inside.

Optionally, a detection sensing component is fixed at the bottom of the top component, the bottom end surface of the detection sensing component is lower than the top end surface of the contact cleaning component, and the control component is inserted into the top component for free drawing; the side of controlling the subassembly is fixed with a square board, and the inside of square board has inserted the guide bar of T shape axle construction to freely pull in the inside of square board, the outside cover of guide bar is equipped with the spring, and the bottom and the moving part fixed connection of guide bar, and drive the moving part and displace together, the clean groove of V-arrangement structure has been seted up on the top of contact clean subassembly.

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

1. After encountering large-size or long-strip building materials, directly controlling the splicing assembly and the adjusting assembly to be positioned and spliced above the pushing assembly, then controlling the building materials to be placed above the splicing assembly and the adjusting assembly for use, enlarging the supporting area, avoiding inclination or efficiency in detection, simultaneously controlling the adjusting assembly to drive the materials to slide in the top groove, and conveniently adjusting the detection position;

2. after detecting that sensing subassembly bottom is infected with the residue, directly pulling control the subassembly and drive the clean subassembly of contact and displace together, after the top side of the clean subassembly of contact and the contact of detection sensing subassembly side, automatic atress displacement compresses the spring, and the top of the clean subassembly of contact and clean groove are through detecting the bottom of sensing subassembly, will detect the convenient clear of residue of sensing subassembly bottom, improve clean efficiency.

Drawings

Fig. 1 is a schematic perspective view of the present utility model.

Fig. 2 is a schematic bottom view of the present utility model.

Fig. 3 is an exploded perspective view of the present utility model.

Fig. 4 is a schematic exploded and partially sectioned perspective view of the strength detecting apparatus of the present utility model.

Fig. 5 is an exploded perspective and partially enlarged schematic view of the top assembly of the present utility model.

In the figure, the correspondence between the component names and the drawing numbers is:

1. An intensity detection device; 101. a pushing assembly; 102. a support rod; 103. a reinforcing rod; 104. a splice assembly; 105. an embedded rod; 106. a positioning assembly; 107. a top groove; 108. an adjustment assembly;

2. a top assembly; 201. detecting a sensing component; 202. a manipulation assembly; 203. a guide rod; 204. a moving member; 205. a contact cleaning assembly; 206. and cleaning the groove.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples.

Embodiment one:

as shown in fig. 1 to 5:

the utility model provides a material strength detection device, comprising: an intensity detection device 1; the top end of the strength detection device 1 is provided with a freely telescopic pushing component 101, the top end of the pushing component 101 is spliced with a splicing component 104, the splicing component 104 is freely installed for use, the supporting area is enlarged, the stability of building materials is improved, the top end of the splicing component 104 is fittingly provided with an adjusting component 108 and is freely slid above the splicing component 104 to drive the building materials to freely adjust the detection position, the bottom of the adjusting component 108 is fixedly provided with two positioning slide bars, and the top end of the strength detection device 1 is provided with a supporting ejector rod; the top subassembly 2, the outside at the support ejector pin is fixed to the top subassembly 2, and the top subassembly 2 is connected with the moving part 204 that can freely reciprocate through controlling the subassembly 202, and the inboard of moving part 204 is fixed with the clean subassembly 205 of contact of flexible rubber material, and the top both sides of the clean subassembly 205 of contact are the arc structure, are used for with the side contact of detecting the sensing subassembly 201, atress displacement downwards, wipe the bottom of detecting the sensing subassembly 201, clear away the residue fast.

Referring to fig. 4, two sides of the pushing component 101 are respectively fixed with a supporting rod 102 with a U-shaped structure, the fixed embedded rods 105 are connected in a positioning way, two round holes are formed in each supporting rod 102, the inserting and positioning component 106 is fixed, a top groove 107 with a rectangular structure is formed in the top end of the splicing component 104, an adjusting component 108 is embedded in the top groove 107, the adjusting component is freely pulled out of the top groove 107 to drive building materials to slide in a guiding way, two guide grooves with arc-shaped structures are formed in the bottom end of the top groove 107, and positioning sliding rods are inserted in the guide grooves to prevent the building materials and the adjusting component 108 from being excessively displaced; the two sides of the pushing component 101 are respectively welded and fixed with a reinforcing rod 103 with a U-shaped structure, and the reinforcing rods are displaced along with the pushing component 101, the two sides of the reinforcing rod 103 made of metal are of an inclined structure, the top ends of the reinforcing rods 103 are fixedly connected with the bottom of the supporting rods 102, the supporting rods 102 are supported, and the supporting strength and the bearing strength are improved; the bottom of the splicing component 104 is fixed with two embedded rods 105 with strip-shaped structures, the embedded rods 105 are fixedly positioned and embedded into the supporting rods 102, the bottom of each embedded rod 105 is fixed with two positioning components 106 with cylindrical structures, and the positioning components 106 are inserted into the round holes for fixedly positioning and splicing.

Referring to fig. 5, a detection sensing component 201 is fixed at the bottom of the top component 2, the bottom end surface of the detection sensing component 201 is lower than the top end surface of the contact cleaning component 205, and the control component 202 is inserted into the top component 2 to be freely pulled and pulled for use, so that the contact cleaning component 205 is driven to move to clean the bottom of the detection sensing component 201; the side of controlling the subassembly 202 is fixed with a square board, and the inside of square board has inserted the guide bar 203 of T shape axle construction to freely pull in the inside of square board, control guide bar 203 direction displacement, the outside cover of guide bar 203 is equipped with the spring, promotes the automatic rising of guide bar 203 and resets, and the bottom and the moving member 204 fixed connection of guide bar 203 drive the moving member 204 and displace together, contact cleaning assembly 205's top and seted up V-arrangement structure's clean groove 206, clean the attachment of collecting detection sensing assembly 201 bottom.

Embodiment two: if the building material is small, the splice assembly 104 is not required to be installed, so that the abrasion of parts is reduced.

When in use, the utility model is characterized in that: according to the shape of building materials, the splicing assembly 104 is controlled to splice freely, the splicing assembly 104 drives the adjusting assembly 108 to install together, meanwhile, the embedded rod 105 is inserted into the supporting rod 102, the positioning assembly 106 is inserted into the round hole to be connected in a positioning mode, then the building materials to be detected are placed above the splicing assembly 104 and the adjusting assembly 108, then the strength detection device 1 is controlled to operate, the strength detection device 1 controls the pushing assembly 101 to drive the building materials to ascend and contact the detection sensing assembly 201, the strength of the building materials is detected rapidly, after the detection position needs to be switched, the adjusting assembly 108 is directly controlled to drive the building materials to slide, detection convenience is improved, if residues are generated at the bottom of the detection sensing assembly 201, the control assembly 202 is directly pulled to move, the contact cleaning assembly 205 is driven to pass through the bottom of the detection sensing assembly 201, and the contact cleaning assembly 205 is matched with the cleaning groove 206 to clean the attachments, and cleaning efficiency is improved.

Claims

1. A material strength detection apparatus, comprising:

An intensity detection device (1); the top end of the strength detection device (1) is provided with a freely telescopic pushing component (101), the top end of the pushing component (101) is spliced with a splicing component (104), the top end of the splicing component (104) is provided with an adjusting component (108) in a fit manner and is positioned above the splicing component (104) to slide freely, the bottom of the adjusting component (108) is fixedly provided with two positioning slide bars, and the top end of the strength detection device (1) is provided with a supporting ejector rod;

The top subassembly (2), top subassembly (2) is fixed in the outside of supporting the ejector pin, and top subassembly (2) are connected with moving part (204) that can freely reciprocate through controlling subassembly (202), and the inboard of moving part (204) is fixed with flexible rubber material's contact cleaning subassembly (205), and the top both sides of contact cleaning subassembly (205) are arc structure.

2. The material strength detection device according to claim 1, wherein two sides of the pushing component (101) are respectively fixed with a supporting rod (102) with a U-shaped structure, two round holes are formed in each supporting rod (102), a top groove (107) with a rectangular structure is formed in the top end of the splicing component (104), an adjusting component (108) is embedded in the top groove (107) and is freely pulled out in the top groove (107), two guide grooves with arc-shaped structures at two ends are formed in the bottom end of the top groove (107), and positioning sliding rods are inserted in the guide grooves.

3. A material strength detecting device according to claim 2, wherein two sides of the pushing component (101) are respectively welded and fixed with a reinforcing rod (103) with a U-shaped structure, and displace together with the pushing component (101), two sides of the reinforcing rod (103) made of metal materials are of inclined structures, and the top end of the reinforcing rod (103) is fixedly connected with the bottom of the supporting rod (102) and supports the supporting rod (102).

4. A material strength detecting device according to claim 3, wherein the bottom of the splicing component (104) is fixed with two embedded rods (105) with long strip structures, the embedded rods (105) are positioned and embedded into the supporting rods (102) for positioning and fixing, the bottom of each embedded rod (105) is fixed with two positioning components (106) with cylindrical structures, and the positioning components (106) are inserted into the round holes for positioning and fixing.

5. A material strength detecting device according to claim 1, wherein the bottom of the top component (2) is fixed with a detecting sensor component (201), the bottom end surface of the detecting sensor component (201) is lower than the top end surface of the contact cleaning component (205), and the control component (202) is inserted into the top component (2) to be freely pulled and pulled.

6. The material strength detecting device according to claim 5, wherein a square plate is fixed on the side edge of the control assembly (202), a guide rod (203) with a T-shaped shaft structure is inserted into the square plate, the guide rod (203) is freely pulled out of the square plate, a spring is sleeved outside the guide rod (203), the bottom of the guide rod (203) is fixedly connected with the moving member (204) and drives the moving member (204) to move together, and a cleaning groove (206) with a V-shaped structure is formed in the top end of the contact cleaning assembly (205).