CN211738548U - Shock attenuation platform is used in geotechnical engineering reconnaissance - Google Patents

Abstract

The utility model discloses a damping platform for geotechnical engineering investigation, which comprises a rectangular base, wherein a rectangular box body is arranged on the rectangular base, a supporting structure is arranged on the rectangular box body, and a damping structure is arranged on the lower wall surface of the rectangular base; the support structure includes: a pair of rectangular plates, a coverless collection box and a pair of strip-shaped slideways; a pair of rectangle recess has been seted up to rectangle box left and right sides wall face upper end, every equal cartridge has a pair of pillar in the rectangle recess, the utility model relates to a geotechnical engineering technical field, through the shock-absorbing structure of this device, be convenient for in rock engineering, use workstation can improve life through the buffering, reduce and lead to colliding with the loss between the ground rock, and it is more convenient to use, can increase the use area.

Description

Shock attenuation platform is used in geotechnical engineering reconnaissance

Technical Field

The utility model relates to a geotechnical engineering technical field specifically is a shock attenuation platform is used in geotechnical engineering investigation.

Background

Geotechnical engineering is a new technical system established in civil engineering practice in 60's of the 20 th century in the countries of the Europe and the America. Geotechnical engineering is to solve the problems of rock and soil engineering, including foundation and foundation, slope, underground engineering and the like, and is used as a research object of the geotechnical engineering.

When carrying out geotechnical engineering exploration, need carry out reasonable use workstation, but geotechnical engineering mostly carries out the employment outdoors, so traditional workstation need keep flat subaerial, owing to do not have reasonable shock attenuation effect, leads to traditional workstation, often takes place to collide with ground or with subaerial rock, leads to the workstation to collide with and lose, in view of this, study to above-mentioned problem, design this device.

SUMMERY OF THE UTILITY MODEL

The not enough to prior art, the utility model provides a shock attenuation platform is used in geotechnical engineering investigation has solved current when carrying out geotechnical engineering exploration, need carry out reasonable use workstation, but carries out carelessness outdoors when geotechnical engineering majority, so traditional workstation need keep flat subaerial, owing to there is not reasonable shock attenuation effect.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the damping device comprises a rectangular base, wherein a rectangular box body is arranged on the rectangular base, a supporting structure is arranged on the rectangular box body, and a damping structure is arranged on the lower wall surface of the rectangular base;

the support structure includes: a pair of rectangular plates, a coverless collection box and a pair of strip-shaped slideways;

the upper ends of the left side wall face and the right side wall face of the rectangular box body are provided with a pair of rectangular grooves, a pair of supporting columns are inserted into each rectangular groove, a pair of circular grooves are formed in the side wall faces of the rectangular plates, the pair of rectangular plates are inserted into the supporting columns through the circular grooves, rectangular through holes are formed in the side wall faces of the rectangular box body, a pair of first strip-shaped grooves are formed in the left side wall face and the right side wall face of the rectangular box body, the interiors of the pair of strip-shaped slideways are arranged in the pair of first strip-shaped grooves, the pair of strip-shaped slideways are provided with movable wheels, and the.

Preferably, the shock-absorbing structure includes: support column, spring and bush;

the support column is arranged on the lower wall surface of the rectangular base and is close to four corners, the sleeve is sleeved on each support column, the spring is sleeved on the support column, the upper end of the spring is connected with the rectangular base, the lower end of the spring is connected with the sleeve, and the lower wall surface of the sleeve is provided with the roller.

Preferably, third strip-shaped grooves are formed in the inner wall surface and the lower wall surface of the rectangular groove, and ejector rods inserted into the third strip-shaped grooves are installed on the lower wall surface of the rectangular plate.

Preferably, the front wall surface of the rectangular box body is connected with a stop door matched with the rectangular through hole through a hinge.

Preferably, a support rod penetrating through the moving wheel is installed in the first strip-shaped groove.

Preferably, a cross column is fixed between the sleeves, and handles are mounted on the side wall surfaces of the rectangular plates.

Advantageous effects

The utility model provides a shock attenuation platform is used in geotechnical engineering reconnaissance. The method has the following beneficial effects: through the shock-absorbing structure of this device, be convenient for in rock engineering, use the workstation can improve life through the buffering, reduce and lead to colliding with between the ground rock and lose the loss, it is more convenient to use, can increase the use area.

Drawings

Figure 1 is the utility model relates to a geotechnical engineering reconnaissance is with shock attenuation platform's structural schematic.

Figure 2 is the utility model relates to a geotechnical engineering reconnaissance is with shock attenuation platform's side view.

Figure 3 is the utility model relates to a geotechnical engineering reconnaissance is with shock attenuation platform's uncovered collection box side view.

In the figure: 1-a rectangular base; 2-a rectangular box body; 3-a rectangular plate; 4-a strip-shaped slideway; 5-a pillar; 6-moving wheels; 7-a support column; 8-a spring; 9-a sleeve; 10-a roller; 11-a top rod; 12-a stop gate; 13-a strut; 14-a lidless collection box; 15-horizontal column.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying 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. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a damping platform for geotechnical engineering investigation comprises a rectangular base 1, wherein a rectangular box body 2 is arranged on the rectangular base 1, a supporting structure is arranged on the rectangular box body 2, and a damping structure is arranged on the lower wall surface of the rectangular base 1;

the support structure includes: a pair of rectangular plates 3, a coverless collection box 14, and a pair of strip-shaped slideways 4;

a pair of rectangular grooves are formed in the upper ends of the left side wall surface and the right side wall surface of the rectangular box body 2, a pair of supporting columns 5 is inserted into each rectangular groove, a pair of circular grooves are formed in the side wall surfaces of the pair of rectangular plates 3, the pair of rectangular plates 3 are inserted into the supporting columns 5 through the circular grooves, a rectangular through hole is formed in the side wall surface of the rectangular box body 2, a pair of first strip-shaped grooves are formed in the left side wall surface and the right side wall surface of the rectangular box body 2, the pair of strip-shaped slideways 4 are arranged inside the pair of first strip-shaped grooves, the pair of strip-shaped slideways 4 are provided with moving wheels 6, and the uncovered collecting box.

It should be noted that: rectangle base 1 plays the supporting role, be used for supporting rectangle box 2, it inserts inside the circular recess on the rectangular plate 3 to install pillar 5 in the rectangle recess on rectangle box 2, the rectangular plate 3 of being convenient for can stimulate, stretch out through the rectangle recess, the rectangular plate 3 of being convenient for to use, increase the usable floor area, and removal wheel 6 on bar slide 4 can remove, the uncovered collection box 14 that drives on the removal wheel 6 removes, be convenient for stretch out through the rectangle through-hole, be convenient for to uncovered collection box 14 inside placing object article, be convenient for collect.

The shock-absorbing structure includes: a support post 7, a spring 8 and a sleeve 9;

the supporting columns 7 are arranged on the lower wall surface of the rectangular base 1 and close to four corners, the sleeve 9 is sleeved on each supporting column 7, the spring 8 is sleeved on each supporting column 7, the upper end of each spring is connected with the rectangular base 1, the lower end of each spring is connected with the sleeve 9, and the lower wall surface of each sleeve 9 is provided with a roller 10;

it should be noted that: support column 7 plays the supporting role, the sleeve 9 cartridge of being convenient for is on support column 7, spring 8 suit is on support column 7, and on upper end and rectangle base 1, the lower extreme is connected with sleeve 9, when letting gyro wheel 10 on the sleeve 9 and ground overlap joint, play the cushioning effect through spring 8, sleeve 9 and ground contact, later rectangle box 2 is because self gravity, lead to rocking the collision loss, so elasticity through spring 8 self forms the buffering, can not lose the body.

As a preferable technical scheme, furthermore, third strip-shaped grooves are formed in the inner lower wall surfaces of the rectangular grooves, and ejector rods 11 inserted into the third strip-shaped grooves are installed on the lower wall surfaces of the rectangular plates 3; the ejector rod 11 is inserted into the third strip-shaped groove, so that the rectangular plate 3 does not separate from the rectangular groove when the rectangular plate 3 is pulled.

As a preferable technical solution, further, the front wall of the rectangular box 2 is connected with a shutter 12 matched with the rectangular through hole through a hinge; the shutter 12 is used to block the rectangular through hole.

As a preferable technical solution, furthermore, a supporting rod 13 penetrating through the moving wheel 6 is installed in the first strip-shaped groove; the supporting rod 13 penetrates through the moving wheel 6, and the moving wheel 6 cannot be separated from the strip-shaped slideway 4.

As a preferable technical scheme, furthermore, cross columns 15 are fixed between the sleeves 9, and handles are mounted on the side wall surfaces of the rectangular plate 3; pulling of the rectangular plate 3 is facilitated by a handle.

Claims (6)

1. The shock absorption platform for geotechnical engineering investigation comprises a rectangular base (1), and is characterized in that a rectangular box body (2) is arranged on the rectangular base (1), a supporting structure is arranged on the rectangular box body (2), and a shock absorption structure is arranged on the lower wall surface of the rectangular base (1);

the support structure includes: a pair of rectangular plates (3), a coverless collection box (14) and a pair of strip-shaped slideways (4);

a pair of rectangular grooves is formed in the upper ends of the left side wall face and the right side wall face of the rectangular box body (2), a pair of supporting columns (5) is inserted into each rectangular groove, a pair of circular grooves are formed in the side wall faces of the rectangular plates (3), the rectangular plates (3) are inserted into the supporting columns (5) through the circular grooves, rectangular through holes are formed in the side wall faces of the rectangular box body (2), a pair of first strip-shaped grooves are formed in the left side wall face and the right side wall face of the rectangular box body (2), the pair of strip-shaped slideways (4) are arranged inside the pair of first strip-shaped grooves, moving wheels (6) are arranged on the pair of strip-shaped slideways (4), and the uncovered collecting box (14) is arranged on the pair of moving wheels (.

2. The shock absorbing platform for geotechnical engineering investigation of claim 1, wherein, said shock absorbing structure includes: a support column (7), a spring (8) and a sleeve (9);

the supporting columns (7) are arranged on the lower wall face of the rectangular base (1) and close to four corners, the sleeves (9) are sleeved on each supporting column (7), the springs (8) are sleeved on the supporting columns (7), the upper ends of the springs are connected with the rectangular base (1), the lower ends of the springs are connected with the sleeves (9), and the rollers (10) are installed on the lower wall face of the sleeves (9).

3. The shock absorption platform for geotechnical engineering investigation of claim 1, wherein the rectangular groove is provided with third strip-shaped grooves on the inner and lower wall surfaces, and the lower wall surface of the rectangular plate (3) is provided with a top rod (11) inserted into the third strip-shaped grooves.

4. The shock absorption platform for geotechnical engineering investigation of claim 1, wherein the front wall of the rectangular box body (2) is hinged with a stop door (12) matched with the rectangular through hole.

5. The shock absorbing platform for geotechnical engineering investigation of claim 1, characterized in that, the first bar-shaped groove is internally provided with a support rod (13) penetrating through the movable wheel (6).

6. The shock absorption platform for geotechnical engineering investigation of claim 2, wherein, a transverse column (15) is fixed between the sleeves (9), and handles are installed on the side wall surfaces of the rectangular plates (3).

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