CN221764440U - A depth measuring instrument for engineering exploration - Google Patents

Abstract

The utility model discloses an engineering exploration depth measuring instrument, which comprises a depth measuring instrument main body, wherein a supporting seat is arranged on the back surface of the depth measuring instrument main body, a quick dismounting mechanism is arranged between the supporting seat and the depth measuring instrument main body, a protection mechanism is arranged at the bottom end of the depth measuring instrument main body, and the quick dismounting mechanism comprises: the connecting component is arranged on the surface of the supporting seat and is connected with the depth measuring instrument main body; the guide assemblies are arranged at two sides between the connecting assembly and the depth measuring instrument main body; according to the utility model, through the designed connecting grooves, the guide grooves and the guide blocks, the depth measuring instrument can be quickly connected with the supporting seat, and meanwhile, the limiting grooves, the limiting blocks, the telescopic springs and the operating buttons which are designed in a matched manner can also play a role in limiting and fixing, so that the assembly, disassembly and fixing work of the depth measuring instrument is greatly facilitated compared with the prior art.

Description

A depth measuring instrument for engineering exploration

Technical Field

The utility model belongs to the technical field of engineering exploration depth measuring instruments, and in particular relates to an engineering exploration depth measuring instrument.

Background Art

Construction engineering survey refers to the activities of mapping, exploring and testing the terrain, geology, hydrology and other conditions, and providing corresponding results and data to meet the needs of engineering construction planning, design, construction, operation and comprehensive management. The survey, design, processing and monitoring activities in geotechnical engineering also belong to the scope of engineering survey. In mining exploration, a borehole depth meter is used to measure the depth of the borehole. When the borehole depth meter measures the depth of the target borehole, it is not only necessary to measure once, but also to change the measurement point to calculate multiple groups of measurement data for accurate comparison. The existing engineering exploration depth meter needs to support the instrument through a support base when in use, so as to facilitate the depth detection of the ground. However, the installation between the depth meter and the support base is more troublesome, and it needs to be fixed by screwing, which makes it more troublesome to disassemble and assemble. For this reason, we propose an engineering exploration depth meter.

Utility Model Content

The utility model aims to provide an engineering exploration depth measuring instrument to solve the problem that the depth measuring instrument is troublesome to assemble and disassemble from a support base in the above-mentioned background technology.

To achieve the above-mentioned purpose, the utility model provides the following technical solutions: an engineering exploration depth measuring instrument, comprising a depth measuring instrument body, a support seat is arranged on the back of the depth measuring instrument body, a quick disassembly mechanism is arranged between the support seat and the depth measuring instrument body, a protective mechanism is arranged at the bottom end of the depth measuring instrument body, and the quick disassembly mechanism comprises:

A connecting component, which is arranged on the surface of the support seat and connected to the depth measuring instrument body;

A guide assembly, which is arranged on both sides between the connecting assembly and the depth measuring instrument body;

A limit assembly, which is arranged on the inner side between the connecting assembly and the depth measuring instrument body;

A reset component, which is arranged inside the limit component;

A pulling assembly is arranged on the surface of the supporting seat and connected with the limiting assembly.

Preferably, the connection assembly comprises a connection groove provided on the surface of the support seat, and the depth measuring instrument body is snap-connected to the connection groove.

Preferably, the guide assembly includes guide grooves symmetrically arranged on both sides of the depth measuring instrument body and guide blocks symmetrically fixed on both sides of the inner wall of the connecting groove, and the guide blocks are engaged and connected with the guide grooves.

Preferably, the limit assembly includes limit grooves symmetrically arranged on both sides of the depth measuring instrument body and built-in grooves symmetrically arranged on both sides of the inner wall of the connecting groove, and limit blocks are arranged inside the built-in grooves, and the limit blocks are engaged and connected with the limit grooves.

Preferably, the reset assembly includes a telescopic spring disposed inside the built-in groove and fixedly connected to the limit block.

Preferably, the pulling assembly includes a groove symmetrically opened on the surface of the support seat and a through hole symmetrically opened on the inner wall of the groove and connected to the built-in groove. A connecting rod passing through the through hole and fixedly connected to the limit block is arranged inside the groove, and an operating button fixedly connected to the connecting rod is arranged inside the groove.

Preferably, the protection mechanism comprises a dust cover sleeved on the bottom end of the depth measuring instrument body and rubber blocks symmetrically fixed on both sides of the inner wall of the dust cover, and arc grooves are symmetrically formed on both sides of the dust cover.

Compared with the prior art, the beneficial effects of the utility model are:

The utility model can realize the rapid connection between the depth measuring instrument and the support seat through the designed connecting groove, guide groove and guide block, and can also play the role of limiting and fixing with the designed limit groove, limit block, telescopic spring and operating button. Compared with the existing technology, the disassembly, assembly and fixing of the depth measuring instrument are greatly facilitated.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG1 is a schematic diagram of the appearance structure of the utility model;

FIG2 is an enlarged schematic diagram of point A in FIG1 of the present invention;

FIG3 is an enlarged schematic diagram of point B in FIG1 of the present utility model;

In the figure: 1, depth measuring instrument body; 2, support seat; 100, connecting groove; 200, guide groove; 201, guide block; 300, limit groove; 301, built-in groove; 302, limit block; 400, telescopic spring; 500, groove; 501, through hole; 502, connecting rod; 503, operating button; 600, dust cover; 601, rubber block; 602, arc groove.

DETAILED DESCRIPTION

The following will be combined with the drawings in the embodiments of the utility model to clearly and completely describe the technical solutions in the embodiments of the utility model. Obviously, the described embodiments are only part of the embodiments of the utility model, not all of the embodiments. Based on the embodiments in the utility model, all other embodiments obtained by ordinary technicians in this field without creative work are within the scope of protection of the utility model.

Referring to Figures 1 to 3, the utility model provides a technical solution: an engineering exploration depth measuring instrument, comprising a depth measuring instrument body 1, a support base 2 is arranged on the back of the depth measuring instrument body 1, a quick disassembly mechanism is arranged between the support base 2 and the depth measuring instrument body 1, and a protective mechanism is arranged at the bottom end of the depth measuring instrument body 1, and the quick disassembly mechanism includes:

A connecting component, which is arranged on the surface of the support seat 2 and connected to the depth measuring instrument body 1;

A guide assembly, which is arranged on both sides between the connecting assembly and the depth measuring instrument body 1;

A limit assembly, which is arranged on the inner side between the connecting assembly and the depth measuring instrument body 1;

A reset component, which is arranged inside the limit component;

A pulling assembly is arranged on the surface of the supporting seat 2 and connected with the limiting assembly.

In this embodiment, preferably, the connection assembly includes a connection groove 100 provided on the surface of the support base 2 , and the depth measuring instrument body 1 is engaged and connected with the connection groove 100 .

In this embodiment, preferably, the guide assembly includes guide grooves 200 symmetrically arranged on both sides of the depth measuring instrument body 1 and guide blocks 201 symmetrically fixed on both sides of the inner wall of the connecting groove 100. The guide blocks 201 are engaged with the guide grooves 200 to facilitate the connection between the depth measuring instrument body 1 and the connecting groove 100.

In this embodiment, preferably, the limit assembly includes limit grooves 300 symmetrically opened on both sides of the depth measuring instrument body 1 and built-in grooves 301 symmetrically opened on both sides of the inner wall of the connecting groove 100, and a limit block 302 is arranged inside the built-in groove 301. The limit block 302 is engaged with the limit groove 300 to limit the depth measuring instrument body 1.

In this embodiment, preferably, the reset component includes a telescopic spring 400 disposed inside the built-in groove 301 and fixedly connected to the limit block 302 , which can drive the limit block 302 to reset.

In this embodiment, preferably, the pulling component includes a groove 500 symmetrically opened on the surface of the support seat 2 and a through hole 501 symmetrically penetrated through the inner wall of the groove 500 and connected to the built-in groove 301. The interior of the groove 500 is provided with a connecting rod 502 that passes through the through hole 501 and is fixedly connected to the limit block 302. The interior of the groove 500 is provided with an operating button 503 fixedly connected to the connecting rod 502, which can pull the limit block 302 to move.

In this embodiment, preferably, the protective mechanism includes a dust cover 600 mounted on the bottom end of the depth measuring instrument body 1 and rubber blocks 601 symmetrically fixed on both sides of the inner wall of the dust cover 600. Arc grooves 602 are symmetrically opened on both sides of the dust cover 600 to protect the depth measuring instrument body 1.

Working principle and use process of the utility model: When the depth measuring instrument body 1 needs to be connected to the support seat 2, the operating button 503 inside the groove 500 is first pulled to drive the connecting rod 502 to slide inside the through hole 501, and drive the limit block 302 to squeeze the telescopic spring 400 into the interior of the built-in groove 301, then the depth measuring instrument body 1 is inserted into the interior of the connecting groove 100 and connected to the support seat 2, and the guide block 201 is docked with the guide groove 200 to play a guiding role, and then the pulled operating button 503 is released, so that the limit block 302 is moved by the telescopic spring Under the action of 400, it is reset and popped out from the inside of the built-in groove 301 and stuck in the inside of the limit groove 300, so that the depth measuring instrument body 1 can be fixed, so as to support and use the depth measuring instrument body 1. When it is necessary to protect the end of the depth measuring instrument body 1, the dust cover 600 can be held through the arc groove 602, and then the dust cover 600 is put on the end of the depth measuring instrument body 1, and the rubber block 601 is squeezed, so that the rubber block 601 can be squeezed and fitted with the end of the depth measuring instrument body 1, so that the dust cover 600 can be put on the end of the depth measuring instrument body 1 for protection.

Although the embodiments of the present invention have been shown and described (see the detailed description above for details), it will be understood by those skilled in the art that various changes, modifications, substitutions and variations may be made to these embodiments without departing from the principles and spirit of the present invention, and the scope of the present invention is defined by the appended claims and their equivalents.

Claims (7)

1. The utility model provides an engineering exploration depth measuring apparatu, includes depth measuring apparatu main part (1), the back of depth measuring apparatu main part (1) is provided with supporting seat (2), its characterized in that: be provided with quick assembly disassembly mechanism between supporting seat (2) and degree of depth measuring instrument main part (1), the bottom of degree of depth measuring instrument main part (1) is provided with protection machanism, quick assembly disassembly mechanism includes:

The connecting component is arranged on the surface of the supporting seat (2) and is connected with the depth measuring instrument main body (1);

the guide assemblies are arranged at two sides between the connecting assembly and the depth measuring instrument main body (1);

The limiting component is arranged on the inner side between the connecting component and the depth measuring instrument main body (1);

The reset component is arranged in the limit component;

the pulling component is arranged on the surface of the supporting seat (2) and is connected with the limiting component.

2. An engineering survey depth gauge according to claim 1, wherein: the connecting assembly comprises a connecting groove (100) formed in the surface of the supporting seat (2), and the depth measuring instrument main body (1) is connected with the connecting groove (100) in a clamping mode.

3. An engineering survey depth gauge according to claim 1, wherein: the guide assembly comprises guide grooves (200) symmetrically formed in two sides of the depth measuring instrument main body (1) and guide blocks (201) symmetrically fixed on two sides of the inner wall of the connecting groove (100), and the guide blocks (201) are connected with the guide grooves (200) in a clamping mode.

4. An engineering survey depth gauge according to claim 1, wherein: the limiting assembly comprises limiting grooves (300) symmetrically formed in two sides of the depth measuring instrument main body (1) and built-in grooves (301) symmetrically formed in two sides of the inner wall of the connecting groove (100), limiting blocks (302) are arranged in the built-in grooves (301), and the limiting blocks (302) are connected with the limiting grooves (300) in a clamping mode.

5. An engineering survey depth gauge according to claim 1, wherein: the reset assembly comprises a telescopic spring (400) which is arranged in the built-in groove (301) and fixedly connected with the limiting block (302).

6. An engineering survey depth gauge according to claim 1, wherein: the pulling assembly comprises a groove (500) symmetrically arranged on the surface of the supporting seat (2) and a through hole (501) symmetrically penetrating through the inner wall of the groove (500) and connected with the built-in groove (301), a connecting rod (502) penetrating through the through hole (501) and fixedly connected with the limiting block (302) is arranged in the groove (500), and an operation button (503) fixedly connected with the connecting rod (502) is arranged in the groove (500).

7. An engineering survey depth gauge according to claim 1, wherein: the protection mechanism comprises a dustproof cover (600) sleeved at the bottom end of the depth measuring instrument main body (1) and rubber blocks (601) symmetrically fixed on two sides of the inner wall of the dustproof cover (600), and arc-shaped grooves (602) are symmetrically formed in two sides of the dustproof cover (600).