CN109024590B

CN109024590B - Sliding support seat for rotary transposition of hydraulic hammer

Info

Publication number: CN109024590B
Application number: CN201810804063.0A
Authority: CN
Inventors: 徐亚维
Original assignee: Zhu Damiao
Current assignee: Zhu Damiao
Priority date: 2018-07-20
Filing date: 2018-07-20
Publication date: 2020-04-07
Anticipated expiration: 2038-07-20
Also published as: CN109024590A

Abstract

The invention discloses a sliding support seat for the rotary transposition of a hydraulic hammer, which comprises a main support plate and an auxiliary support plate, wherein the front end surface of the main support plate is formed into a cuboid shape with an arc surface; the rear end surface of the auxiliary supporting plate and the front end surface of the main supporting plate are coaxially arranged in the same diameter; a plurality of arc-shaped sliding grooves which are distributed up and down and penetrate left and right are formed on the front end surface of the main supporting plate; the sliding groove is coaxially arranged with the rear end surface of the main supporting plate; a plurality of sliding guide rails which are distributed up and down and matched with the sliding grooves are formed on the rear end surface of the auxiliary supporting plate; a rotary hydraulic cylinder is fixed on the upper end surface of the main supporting plate; a driving plate is fixed on an output shaft of the rotary hydraulic cylinder; a driving sliding groove in a long hole shape is formed on the driving plate; a cylindrical driving column matched with the driving sliding groove is formed at the left end of the upper end face of the auxiliary supporting plate; the driving column is inserted in the driving sliding groove. The hydraulic hammer is time-saving and labor-saving, avoids frequently disassembling the hydraulic hammer, and has simple structure and convenient use.

Description

Sliding support seat for rotary transposition of hydraulic hammer

Technical Field

The invention relates to the technical field of hydraulic hammers, in particular to a sliding support seat for rotary transposition of a hydraulic hammer.

Background

The pile driver slides up and down in the guide rail through the hydraulic hammer to complete the pile driving work. The hydraulic hammer is heavier, and when the pile driver moved for a long distance, in order to reduce fuselage width and organism weight, just need tear down the hydraulic hammer and transport alone, during the use again with the hydraulic hammer assembly to the organism, the process is complicated and time-consuming, and the human labor is very big.

Disclosure of Invention

The invention aims to overcome the defects in the prior art and provides a slide support seat for the rotary transposition of a hydraulic hammer, which comprises a main support plate and a secondary support plate, wherein the front end surface of the main support plate is formed into a cuboid shape with an arc surface; a pair of sliding plates which are symmetrically arranged left and right are vertically welded on the rear end surface of the main supporting plate; the rear end surface of the auxiliary supporting plate and the front end surface of the main supporting plate are coaxially arranged in the same diameter; a pair of mounting plates which are arranged symmetrically left and right are formed on the front end surface of the auxiliary supporting plate; a plurality of arc-shaped sliding grooves which are distributed up and down and penetrate left and right are formed on the front end surface of the main supporting plate; the sliding groove is coaxially arranged with the rear end surface of the main supporting plate; a plurality of sliding guide rails which are distributed up and down and matched with the sliding grooves are formed on the rear end surface of the auxiliary supporting plate; a rotary hydraulic cylinder is fixed on the upper end surface of the main supporting plate; a driving plate is fixed on an output shaft of the rotary hydraulic cylinder; a driving sliding groove in a long hole shape is formed on the driving plate; a cylindrical driving column matched with the driving sliding groove is formed at the left end of the upper end face of the auxiliary supporting plate; the driving column is inserted in the driving sliding groove; when the auxiliary supporting plate is positioned on the right side of the main supporting plate, the left end of the sliding guide rail is still inserted into the corresponding sliding groove.

Preferably, the sliding groove has a radial cross section in a T shape with a narrow outer portion and a wide inner portion.

Preferably, the pair of mounting plates has a plurality of vertically distributed left and right penetrating mounting holes formed therein.

Preferably, a pair of sliding support plates symmetrically arranged in front and back are vertically welded to the end surfaces of the pair of sliding plates away from each other.

Preferably, the pair of sliding plates has hinge holes formed at upper ends thereof.

Preferably, an auxiliary limiting hole penetrating through the front and the back is formed in the left upper part of the front end face of the auxiliary supporting plate; an auxiliary supporting block is formed at the right upper part of the rear end surface of the main supporting plate; the auxiliary supporting block is provided with an auxiliary supporting through hole which penetrates left and right; when the auxiliary supporting plate is positioned on the right side of the main supporting plate, the auxiliary supporting through hole of the auxiliary supporting block is opposite to the auxiliary limiting hole.

The invention has the beneficial effects that: time and labor are saved, frequent disassembly of the hydraulic hammer is avoided, and the hydraulic hammer is simple in structure and convenient to use.

Drawings

FIG. 1 is a front view of the working state of the present invention;

FIG. 2 is a schematic top view of the structure of FIG. 1 in accordance with the present invention;

FIG. 3 is a schematic front view of the present invention during transport;

fig. 4 is a schematic top view of fig. 3 according to the present invention.

In the figure, 10, a main supporting plate; 100. a sliding groove; 11. an auxiliary support block; 12. a slide plate; 120. a hinge hole; 13. a sliding support plate; 20. a sub-support plate; 21. a drive column; 22. a sliding guide rail; 23. mounting a plate; 230. mounting a through hole; 30. a rotary hydraulic cylinder; 31. a drive plate; 310. the sliding groove is driven.

Detailed Description

As shown in fig. 1 to 4, a slide support base for the rotary transposition of a hydraulic hammer comprises a main support plate 10 with a cuboid shape and a secondary support plate 20 with a circular arc-shaped front end surface; a pair of sliding plates 12 which are arranged symmetrically left and right are vertically welded on the rear end surface of the main supporting plate 10; the rear end surface of the auxiliary supporting plate 20 and the front end surface of the main supporting plate 10 are coaxially arranged in the same diameter; a pair of mounting plates 23 which are arranged in bilateral symmetry are formed on the front end surface of the auxiliary supporting plate 20; a plurality of arc-shaped sliding grooves 100 which are distributed up and down and penetrate left and right are formed on the front end surface of the main supporting plate 10; the sliding slot 100 is coaxially arranged with the rear end surface of the main supporting plate 10; a plurality of sliding guide rails 22 which are distributed up and down and matched with the sliding grooves 100 are formed on the rear end surface of the auxiliary supporting plate 20; a rotary hydraulic cylinder 30 is fixed on the upper end surface of the main supporting plate 10; a drive plate 31 is fixed to an output shaft of the rotary hydraulic cylinder 30; a long-hole-shaped driving sliding groove 310 is formed on the driving plate 31; a cylindrical driving column 21 matched with the driving sliding groove 310 is formed at the left end of the upper end surface of the auxiliary supporting plate 20; the driving column 21 is inserted in the driving sliding slot 310; when the sub-support plate 20 is positioned at the right side of the main support plate 10, the left end of the slide rail 22 is still inserted into the corresponding slide groove 100.

As shown in fig. 3 and 4, the sliding groove 100 has a T-shaped radial cross section with a narrow outer portion and a wide inner portion.

As shown in fig. 3, the pair of mounting plates 23 is formed with a plurality of vertically distributed left and right penetrating mounting through holes 230.

As shown in fig. 1 to 4, a pair of sliding support plates 13, which are symmetrically arranged in front and rear, are vertically welded to the end surfaces of the pair of sliding plates 12 that are away from each other.

As shown in fig. 1 to 4, hinge holes 120 are formed at upper ends of the pair of sliding plates 12.

As shown in fig. 1 to 4, an auxiliary limiting hole 200 penetrating through the front and rear is formed at the left upper part of the front end surface of the auxiliary supporting plate 20; an auxiliary supporting block 11 is formed at the right upper part of the rear end surface of the main supporting plate 10; the auxiliary supporting block 11 is formed with an auxiliary supporting through hole which penetrates left and right; when the sub-support plate 20 is positioned at the right side of the main support plate 10, the auxiliary support penetration hole of the auxiliary support block 11 faces the auxiliary stopper hole 200.

The working principle of the sliding support seat with the hydraulic hammer rotating and changing positions is as follows:

a hydraulic hammer (not shown) is fixed to the pair of mounting plates 23 of the sub-support plate 20 by bolts;

an initial state; the auxiliary supporting plate 20 is positioned right in front of the main supporting plate 10, and the driving plate 31 points to the left front;

then the rotary hydraulic cylinder 30 is actuated so that the sub support plate 20 is rotated counterclockwise by 90 degrees along the front end surface of the main support plate 10 by the driving plate 31; at this time, the left end of the sliding guide rail 22 is still inserted into the corresponding sliding groove 100, so that the hydraulic hammer (not shown) is positioned at the right side of the sliding support seat, and the width of the machine body can be reduced without detaching the hydraulic hammer (not shown) for convenient transportation; then, the bolts are passed through the auxiliary stopper holes 200 and the auxiliary support through holes of the auxiliary support blocks 11 and fastened with nuts, thus restraining the sub-support plate 20 and preventing the left end of the slide rail 22 from being damaged by vibration of the sub-support plate 20 during transportation.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, the present invention should not be limited by the description herein, since various changes and modifications can be made in the details of the embodiment and the application range according to the spirit of the present invention.

Claims

1. The utility model provides a sliding support seat of hydraulic hammer rotation transposition which characterized in that: comprises a main support plate (10) with the front end surface shaped into a cuboid of an arc surface and an auxiliary support plate (20) with the rear end surface shaped into an arc surface; a pair of sliding plates (12) which are symmetrically arranged left and right are vertically welded on the rear end surface of the main supporting plate (10); the rear end surface of the auxiliary supporting plate (20) and the front end surface of the main supporting plate (10) are coaxially arranged in the same diameter; a pair of mounting plates (23) which are arranged in a left-right symmetrical mode are formed on the front end face of the auxiliary supporting plate (20); a plurality of arc-shaped sliding grooves (100) which are distributed up and down and penetrate left and right are formed on the front end surface of the main supporting plate (10); the sliding groove (100) is coaxially arranged with the rear end surface of the main supporting plate (10); a plurality of sliding guide rails (22) which are distributed up and down and matched with the sliding grooves (100) are formed on the rear end surface of the auxiliary supporting plate (20); a rotary hydraulic cylinder (30) is fixed on the upper end surface of the main supporting plate (10); a driving plate (31) is fixed on an output shaft of the rotary hydraulic cylinder (30); a driving sliding groove (310) in a long hole shape is formed on the driving plate (31); a cylindrical driving column (21) matched with the driving sliding groove (310) is formed at the left end of the upper end surface of the auxiliary supporting plate (20); the driving column (21) is inserted in the driving sliding groove (310); when the auxiliary support plate (20) is positioned at the right side of the main support plate (10), the left end of the sliding guide rail (22) is still inserted into the corresponding sliding groove (100).

2. A slide bearing with rotary indexing of a hydraulic hammer as claimed in claim 1, wherein: the radial cross section of the sliding groove (100) is in a T shape with a narrow outside and a wide inside.

3. A slide bearing with rotary indexing of a hydraulic hammer as claimed in claim 1, wherein: a plurality of mounting through holes (230) which are distributed up and down and penetrate through the pair of mounting plates (23) from left to right are formed.

4. A slide bearing with rotary indexing of a hydraulic hammer as claimed in claim 1, wherein: the end surfaces far away from the pair of sliding plates (12) are respectively and vertically welded with a pair of sliding support plates (13) which are symmetrically arranged front and back.

5. A slide bearing with rotary indexing of a hydraulic hammer as claimed in claim 1 or claim 4, wherein: hinge holes (120) are formed at the upper ends of the pair of sliding plates (12).

6. A slide bearing with rotary indexing of a hydraulic hammer as claimed in claim 1, wherein: an auxiliary limiting hole (200) which penetrates through the front and the back is formed in the left upper part of the front end face of the auxiliary supporting plate (20); an auxiliary supporting block (11) is formed at the upper right part of the rear end surface of the main supporting plate (10); the auxiliary supporting block (11) is formed with an auxiliary supporting through hole which penetrates left and right; when the auxiliary supporting plate (20) is positioned at the right side of the main supporting plate (10), the auxiliary supporting through hole of the auxiliary supporting block (11) is opposite to the auxiliary limiting hole (200).