CN217765552U - Geotechnical engineering detects sampling device - Google Patents

Abstract

The utility model discloses a geotechnical engineering detects sampling device, including fixed pipe and roll-over stand, roll-over stand fixed mounting is at fixed pipe top, fixed pipe top is supported through three group's bracing pieces and is installed the mounting panel, fixed intraductal internally mounted has the hydraulic stem that runs through the mounting panel, the A belt pulley is installed through rotating the race ring in the mounting panel top, it is fixed through the latch mechanism joint between hydraulic stem and the A belt pulley, drive A belt pulley pivoted actuating mechanism is installed to mounting panel top one side, the hydraulic stem bottom is connected and is installed the thief rod, install spiral silo on the thief rod. The utility model discloses a driving motor drives the hydraulic stem and rotates, makes its bottom connect the thief rod of installation when rotating the sample, through the spiral silo of its outside round installation, stores not the earth of co-altitude, is convenient for carry out the multiunit sample to same region, guarantees the accuracy that detects earth.

Description

Geotechnical engineering detects sampling device

Technical Field

The utility model relates to a geotechnical engineering detects technical field, especially relates to a geotechnical engineering detects sampling device.

Background

Geotechnical engineering is to solve rock and soil engineering problems including foundation and foundation, slope and underground engineering and the like, and is a research object of the geotechnical engineering, and various engineering on the ground, underground and in water are collectively called civil engineering. The civil engineering refers to rock, soil, underground and underwater parts as geotechnical engineering.

When the existing sampling device is used, because the sampled soil has a certain property change after being sampled, the existing sampling device is inconvenient for carrying out multi-group sampling comparison on the soil in a certain area at one time, and the detection effect of the soil is influenced; meanwhile, the stability of more soil is easily influenced during sampling, and the stabilizing effect of soil quality is influenced.

SUMMERY OF THE UTILITY MODEL

The utility model provides a geotechnical engineering detection sampling device, which solves the problem that when the existing sampling device is used, because the sampled soil has a certain property change after sampling, the soil in a certain area is inconvenient to be sampled and compared in multiple groups at one time, and the detection effect of the soil is influenced; simultaneously, the stability of more soil is easily influenced during sampling, and the stability effect of soil quality is influenced.

In order to realize the purpose, the utility model adopts the following technical scheme: the utility model provides a geotechnical engineering detects sampling device, includes fixed pipe and roll-over stand, roll-over stand fixed mounting is at fixed pipe top, the upset pole is installed through the upset of three A upset pieces of group to the outside round of roll-over stand, the upset pole bottom is connected through B upset piece and is installed supporting mechanism, fixed pipe top is supported through three spinal branch vaulting poles and is installed the mounting panel, fixed intraductal internally mounted has the hydraulic stem that runs through the mounting panel, the A belt pulley is installed through rotating the bearing circle in the mounting panel top, it is fixed through the latch mechanism joint between hydraulic stem and the A belt pulley, drive A belt pulley pivoted actuating mechanism is installed to mounting panel top one side, the hydraulic stem bottom is connected and is installed the thief rod, install spiral silo on the thief rod.

Preferably, the supporting mechanism comprises supporting plates and soil inserting pipes, the soil inserting pipes are four groups and are respectively installed on two sides of the bottom of the supporting plates, and fixing nail plates are installed on the top of the supporting plates through the soil inserting pipes.

Preferably, three groups of auxiliary blocks are arranged in a circle outside the bottom of the fixed pipe, and two sides of the turnover rod are connected with the auxiliary blocks through connecting rods.

Preferably, clamping mechanism includes fixed plate and joint piece, fixed plate fixed mounting is at the top of hydraulic stem, and the joint piece is three array distributions of group and installs in the fixed plate bottom, four group's joint grooves have been seted up at A belt pulley top, the joint piece is fixed with joint groove joint.

Preferably, actuating mechanism includes install bin and driving motor, install bin fixed mounting is at A belt pulley side-mounting board top, driving motor fixed mounting is inside the install bin, and installs the B belt pulley in its bottom, driving motor passes through the B belt pulley and drives the A belt pulley rotation.

Preferably, the opening has been seted up on the mounting panel of hydraulic stem position department, the awl point is installed to the sample rod bottom, the awl point top is connected the installation through four groups connecting strip with the hydraulic stem bottom.

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

1. drive the hydraulic stem through driving motor and rotate, make its bottom connect the thief rod of installation when rotating the sample, through the spiral silo of its outside round installation, store not the earth of co-altitude, be convenient for carry out the multiunit sample to same region, guarantee the accuracy that detects earth.

2. Drive the sample rod of hydraulic stem and bottom through driving motor and reach the sample effect, and the perpendicular sample, reduce the horizontal face and dig the destruction of getting the cause to earth, the earth scope of influence when reducing the sample simultaneously avoids destroying a large amount of soil property, guarantees the stable effect that earth made at geotechnical engineering.

Drawings

Fig. 1 is a schematic view of a three-dimensional structure of a geotechnical engineering detection sampling device of the present invention;

fig. 2 is a schematic view of a sectional three-dimensional structure of the geotechnical engineering detection sampling device of the present invention;

FIG. 3 is an enlarged perspective view of the drive motor of FIG. 2;

FIG. 4 is an enlarged perspective view of the sampling rod of FIG. 2;

fig. 5 is an enlarged perspective view of the support mechanism of fig. 1.

In the figure: 100. a fixed tube; 101. a roll-over stand; 102. a, turning over a block; 103. a turning rod; 104. a connecting rod; 105. an auxiliary block; 106. a support plate; 107. b, turning over the block; 108. inserting a soil pipe; 109. fixing the nail plate; 110. a support bar; 111. mounting a plate; 112. a belt pulley; 113. a clamping block; 114. a belt pulley B; 115. installing a box; 116. a drive motor; 117. a fixing plate; 118. a clamping groove; 119. a hydraulic lever; 120. a conical tip; 121. a sampling rod; 122. a connecting strip; 123. spiral trough.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

In the description of the present invention, it should be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Referring to fig. 1-5, a geotechnical engineering detection sampling device comprises a fixed pipe 100 and a roll-over stand 101, wherein the roll-over stand 101 is fixedly arranged at the top of the fixed pipe 100, a circle outside the roll-over stand 101 is provided with a roll-over rod 103 through three groups of A roll-over blocks 102 in a roll-over mode, three groups of auxiliary blocks 105 are arranged at a circle outside the bottom of the fixed pipe 100, two sides of the roll-over rod 103 are connected and arranged with the auxiliary blocks 105 through connecting rods 104, the bottom of the roll-over rod 103 is provided with a supporting mechanism through a B roll-over block 107 in a connecting mode, the supporting mechanism comprises a supporting plate 106 and soil inserting pipes 108, the soil inserting pipes 108 are arranged at two sides of the bottom of the supporting plate 106 in four groups respectively, the top of the supporting plate 106 is provided with a fixed nail plate 109 through the soil inserting pipes 108, the top of the fixed pipe 100 is provided with a mounting plate 111 through three groups of supporting rods 110 in a supporting mode, a hydraulic rod 119 penetrating through the mounting plate 111 is arranged inside the fixed pipe 100, the top of the mounting plate 111 is provided with an A belt pulley 112 through a rotating bearing ring, the hydraulic rod 119 and the A belt pulley 112 are clamped and fixed through a clamping mechanism, the clamping mechanism comprises a fixing plate 117 and clamping blocks 113, the fixing plate 117 is fixedly mounted at the top of the hydraulic rod 119, the clamping blocks 113 are distributed at the bottom of the fixing plate 117 in three groups of arrays, four groups of clamping grooves 118 are formed in the top of the A belt pulley 112, the clamping blocks 113 are clamped and fixed with the clamping grooves 118, one side of the top of the mounting plate 111 is provided with a driving mechanism for driving the A belt pulley 112 to rotate, the driving mechanism comprises a mounting box 115 and a driving motor 116, the hydraulic rod 119 and a sampling rod 121 at the bottom of the hydraulic rod 119 are driven by the driving motor 116 to achieve a sampling effect, vertical sampling is achieved, damage to soil excavation caused by a transverse surface is reduced, meanwhile, the range of soil influenced during sampling is reduced, damage to a large amount of soil is avoided, and the stabilizing effect of the soil in geotechnical engineering is ensured;

installation box 115 fixed mounting is at A belt pulley 112 one side mounting panel 111 top, driving motor 116 fixed mounting is inside installation box 115, and install B belt pulley 114 in its bottom, driving motor 116 drives A belt pulley 112 through B belt pulley 114 and rotates, hydraulic stem 119 bottom is connected and is installed sampling rod 121, install spiral silo 123 on the sampling rod 121, the opening has been seted up on hydraulic stem 119 position department mounting panel 111, awl point 120 is installed to sampling rod 121 bottom, awl point 120 top is connected the installation through four groups of connecting strip 122 with hydraulic stem 119 bottom, drive hydraulic stem 119 through driving motor 116 and rotate, make its bottom connect the sampling rod 121 of installation when rotating the sample, spiral silo 123 through its outside round of installation, store the earth of different heights, be convenient for carry out the multiunit sample to same region, guarantee the accuracy that detects earth.

The utility model discloses when using, at first, three upset poles 103 of group through this roll-over stand 101 round of upset, make its stable support on the soil, insert into soil through running through backup pad 106 with staple board 109 and inserting soil pipe 108, insert into soil through passing through exogenic action with hydraulic stem 119, insert into soil through hydraulic stem 119 messenger its bottom, and it is fixed with four group's joint piece 113 of four group's joint piece and the four group's joint groove 118 joint at A belt pulley 112 top of hydraulic stem 119 top fixed plate 117 bottom, drive through driving motor 116, thereby drive hydraulic stem 119 and the sample rod 121 of its bottom and rotate, gather earth through spiral silo 123.

The above, only be the embodiment of the preferred of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, which are designed to be replaced or changed equally, all should be covered within the protection scope of the present invention.

Claims (6)

1. The utility model provides a geotechnical engineering detects sampling device, includes fixed pipe (100) and roll-over stand (101), a serial communication port, roll-over stand (101) fixed mounting is at fixed pipe (100) top, roll-over stand (101) outside round is installed upset pole (103) through three A turning block (102) of group, roll-over pole (103) bottom is connected through B turning block (107) and is installed supporting mechanism, fixed pipe (100) top is supported through three bracing pieces of group (110) and is installed mounting panel (111), fixed pipe (100) internally mounted has hydraulic stem (119) that run through mounting panel (111), A belt pulley (112) are installed through rotating the bearing ring in mounting panel (111) top, it is fixed through the latch mechanism joint between hydraulic stem (119) and A belt pulley (112), drive A belt pulley (112) pivoted actuating mechanism is installed to mounting panel (111) top one side, connect in hydraulic stem (119) bottom and install sampling rod (121), install spiral silo (123) on sampling rod (121).

2. The geotechnical engineering detection sampling device according to claim 1, wherein the supporting mechanism comprises supporting plates (106) and soil inserting pipes (108), the soil inserting pipes (108) are arranged in four groups and are respectively arranged on two sides of the bottom of the supporting plates (106), and fixing nail plates (109) are arranged on the tops of the supporting plates (106) in a penetrating mode through the soil inserting pipes (108).

3. The geotechnical engineering detection sampling device according to claim 1, wherein three sets of auxiliary blocks (105) are installed on the outer circle of the bottom of the fixed pipe (100), and two sides of the turnover rod (103) are connected with the auxiliary blocks (105) through connecting rods (104).

4. The geotechnical engineering detection sampling device according to claim 1, wherein the clamping mechanism comprises a fixing plate (117) and clamping blocks (113), the fixing plate (117) is fixedly installed at the top of the hydraulic rod (119), the clamping blocks (113) are distributed at the bottom of the fixing plate (117) in three groups of arrays, four groups of clamping grooves (118) are formed in the top of the A belt pulley (112), and the clamping blocks (113) are clamped and fixed with the clamping grooves (118).

5. The geotechnical engineering detection sampling device according to claim 1, wherein the driving mechanism comprises an installation box (115) and a driving motor (116), the installation box (115) is fixedly installed at the top of a side installation plate (111) of the A belt pulley (112), the driving motor (116) is fixedly installed inside the installation box (115), the bottom of the driving motor is provided with the B belt pulley (114), and the driving motor (116) drives the A belt pulley (112) to rotate through the B belt pulley (114).

6. The geotechnical engineering detection sampling device according to claim 1, wherein the mounting plate (111) at the position of the hydraulic rod (119) is provided with a through opening, the bottom of the sampling rod (121) is provided with a conical tip (120), and the top of the conical tip (120) and the bottom of the hydraulic rod (119) are connected and mounted through four groups of connecting strips (122).

Images