阅读说明：本技术 振动锤一体化施工装置 (Vibration hammer integrated construction device ) 是由 张德平 蒋海峰 吴承亮 谢钦官 陈本超 于 2019-09-30 设计创作，主要内容包括：本发明公开了一种振动锤一体化施工装置,其包括振动锤、动力站和吊车,所述振动锤和动力站通过液压管相连接,所述吊车包括旋转平台、转动地连接于所述旋转平台的吊臂,所述振动锤连接于所述吊臂的顶端部,所述动力站设置于所述旋转平台上。振动锤和动力站都设置在同一个吊车上,充分利用吊车上的空间,减少施工占用的场地,能够避免液压管在施工过程中扯断,而且吊车能够同时转移振动锤和动力站,提高了施工的灵活性和效率,同时,由于动力站的自重较大,能够为吊车起到配重的作用,节省吊车的配重块。(The invention discloses a vibration hammer integrated construction device which comprises a vibration hammer, a power station and a crane, wherein the vibration hammer is connected with the power station through a hydraulic pipe, the crane comprises a rotating platform and a suspension arm which is rotationally connected with the rotating platform, the vibration hammer is connected to the top end part of the suspension arm, and the power station is arranged on the rotating platform. The vibrating hammer and the power station are arranged on the same crane, the space on the crane is fully utilized, the site occupied by construction is reduced, the hydraulic pipe can be prevented from being broken in the construction process, the crane can transfer the vibrating hammer and the power station simultaneously, the flexibility and the efficiency of construction are improved, and meanwhile, the self weight of the power station is large, so that the effect of balancing weight can be achieved for the crane, and the balancing weight of the crane is saved.)

1. The utility model provides a vibratory hammer integration construction equipment which characterized in that, includes vibratory hammer, power station and crane, vibratory hammer and power station are connected through the hydraulic pressure pipe, the crane include rotary platform, rotationally connect in rotary platform's davit, the vibratory hammer connect in the top portion of davit, the power station set up in rotary platform is last.

2. The vibro-hammer-integrated construction apparatus of claim 1, wherein the boom and power station are located on different sides of the rotary platform.

3. The vibro-hammer-integrated construction device of claim 1, wherein the rotary platform is provided with a bracket for supporting the power station, the bracket extending toward a side away from the boom.

4. A vibro-hammer-integrated working apparatus as in claim 3, wherein a reinforcing rib is provided between the bracket and the rotary platform.

5. The vibro-hammer-integrated working apparatus according to claim 3, wherein the upper surface of the bracket is provided with a plurality of limit protrusions, and the limit protrusions define a limit space for accommodating the power station.

6. The vibro-hammer-integrated working apparatus according to claim 1, wherein the rotating platform is provided with a weight block, the weight block being located on a side of the rotating platform away from the boom.

7. A vibro-hammer-integrated working apparatus as in claim 1, wherein a section of the hydraulic pipe remote from the vibro-hammer is at least partially attached to the boom.

8. The vibro-hammer-integrated working apparatus according to claim 7, wherein the boom crane is provided with a transition block, the transition block is in a natural hanging state, the hydraulic pipe is spaced from the boom arm, and a portion of the hydraulic pipe between the vibro-hammer and the boom arm is laid on the transition block.

9. The vibro-hammer integrated construction device of claim 8, wherein the upper surface of the transition block is provided with a receiving groove for receiving the hydraulic pipe.

10. The vibro-hammer integrated working apparatus according to claim 9, wherein the upper surface of the transition block is an upwardly protruding arc shape, and the receiving groove is an arc-shaped groove.

11. The vibro-hammer integrated construction apparatus of claim 7, wherein the hydraulic pipe comprises a link strapped on the boom, and the link extends in the same direction as the boom.

12. The vibro-hammer-integrated working apparatus according to claim 1, wherein the crane further comprises a crawler means provided at the bottom, the rotary platform being relatively rotatably connected to the crawler means, the crawler means being adapted to move the crane.

Technical Field

The invention relates to a vibration hammer integrated construction device.

Background

During road construction, piling is required to form a firm pavement foundation. At present, the steel pipe pile is widely used, and mainly has the advantages of good rigidity, high bearing capacity, difficult damage, convenient pile sinking and pile splicing and high construction speed because of the steel pipe pile. The vibratory hammer is a pile driving device which is commonly used, and the power station provides power for the vibratory hammer through the hydraulic pipe. The vibration hammer has high construction speed and efficiency, accurate pile sinking precision and environment-friendly construction operation.

The power station and the vibratory hammer that use on the building site at present are the distributing type and arrange, and this kind of arrangement occupies great construction space, and the flexibility ratio is relatively poor, when needs shift the vibratory hammer, still will correspondingly shift the power station, need constantly coordinate the position relation between power station and the vibratory hammer in the work progress, increased the engineering time, the construction degree of difficulty and labour, and the power station is comparatively heavy, and it is very difficult to remove, consequently influences the efficiency of construction more.

Disclosure of Invention

The invention aims to overcome the defects that in the prior art, due to the fact that a vibration hammer and a power station are arranged separately, construction difficulty is high, and a large amount of labor cost is consumed, and provides an integrated construction device for the vibration hammer.

The invention solves the technical problems through the following technical scheme:

The utility model provides a vibratory hammer integration construction equipment which characterized in that, includes vibratory hammer, power station and crane, vibratory hammer and power station are connected through the hydraulic pressure pipe, the crane include rotary platform, rotationally connect in rotary platform's davit, the vibratory hammer connect in the top portion of davit, the power station set up in rotary platform is last.

Preferably, the boom and the power station are located on different sides of the rotating platform.

In the scheme, the power station and the suspension arm are positioned on two sides of the rotating center of the rotating platform, and the moments generated by the power station and the suspension arm are balanced with each other, so that the crane is prevented from turning over.

Preferably, the rotary platform is provided with a cradle for supporting the power station, the cradle extending towards a side remote from the boom.

In the present case, the bracket plays the effect that increases rotary platform supporting area, can make the mounted position of power station have great adjustment space to satisfy the position requirement of counter weight.

Preferably, a reinforcing rib is arranged between the bracket and the rotating platform.

In the present case, the stiffening rib has improved the joint strength between bracket and the rotary platform for the bracket can stabilize and support the power station.

Preferably, the upper surface of the bracket is provided with a plurality of limiting bulges, and the limiting bulges surround a limiting space for accommodating the power station.

In the scheme, the limiting protrusions surround the periphery of the power station, so that the power station is fixed in the limiting space, and the power station is prevented from falling off from a crane.

Preferably, a balancing weight is arranged on the rotating platform and is located on one side, far away from the suspension arm, of the rotating platform.

In the present case, further balance the produced moment of davit through setting up the balancing weight, prevent that the crane from taking place the turnover accident.

Preferably, a section of the hydraulic tube remote from the vibratory hammer is at least partially connected to the boom.

In the present case, adopt above-mentioned structural style, hydraulic pressure pipe arrange comparatively neatly, can prevent that hydraulic pressure pipe from taking place the winding and prevent the safety risk that hydraulic pressure pipe mopping brought.

Preferably, the boom crane is provided with a transfer block, when the transfer block is in a natural hanging state, a distance exists between a part of the hydraulic pipe extending from the boom and the transfer block, and a section of the hydraulic pipe between the vibration hammer and the boom is partially lapped on the transfer block.

In the scheme, the adapter block can further prevent the hydraulic pipe from dragging the ground and prevent the hydraulic pipe from being damaged due to excessive bending at the position where the hydraulic pipe extends out of the suspension arm.

Preferably, the upper surface of the adapter block is provided with a receiving groove for receiving the hydraulic pipe.

In the present case, the holding tank can keep hydraulic pressure pipe and switching piece contact, further restricts the motion of hydraulic pressure pipe, avoids the motion influence construction of hydraulic pressure pipe.

Preferably, the upper surface of the adapter block is an arc protruding upwards, and the receiving groove is an arc groove.

In the present case, the holding tank can avoid the hydraulic pressure pipe to take place excessively to buckle in the part of switching piece for the arc, prevents the damage of hydraulic pressure pipe.

Preferably, the hydraulic pipe comprises a connecting section strapped on the boom, and the extending direction of the connecting section is the same as the extending direction of the boom.

In the present case, the linkage segment of hydraulic pressure pipe is connected on the davit and extends along the direction of davit for hydraulic pressure pipe arrange neatly more, avoid hydraulic pressure pipe excessively buckle or take place the winding.

Preferably, the crane further comprises a crawler device arranged at the bottom, the rotating platform is relatively and rotatably connected with the crawler device, and the crawler device is used for driving the crane to move.

the positive progress effects of the invention are as follows: the utility model discloses a vibration hammer integration construction device, including the power station, the power station is used for the power station, the vibration hammer all sets up on same crane with the power station, because the dead weight of power station is great, can play the effect of counter weight for the crane, can lift off original balancing weight on the crane, the space vacated is used for settling the power station, make full use of the space on the crane, and can not increase the load of crane, reduce the place that the power station took in the construction, can also avoid hydraulic pressure pipe to tear apart in the work progress, and the crane can shift vibration hammer and power station simultaneously, the flexibility and the efficiency of construction have been improved, make the economic benefits in this.

Drawings

Fig. 1 is a schematic structural view of a vibratory hammer construction platform according to an embodiment of the present invention.

Fig. 2 is an enlarged schematic view of fig. 1 at a portion a.

Fig. 3 is a schematic structural diagram of a power station and a bracket of the vibratory hammer construction platform according to the embodiment of the invention.

Fig. 4 is another schematic structural view of a power station and a bracket of the vibration hammer construction platform according to the embodiment of the present invention.

Description of reference numerals:

Vibration hammer 1

Power station 2

Crane 3

Rotating platform 31

Boom 32

Crawler belt device 33

Cross member 34

Steel wire 35

Hook 36

Hydraulic pipe 4

Connecting section 41

Steel pipe pile 5

bracket 6

Reinforcing ribs 61

Spacing projection 62

Counterweight block 7

Transfer block 8

Binding tape 9

Detailed Description

The invention is further illustrated by the following examples, which are not intended to limit the scope of the invention.

As shown in fig. 1 to 2, the invention discloses a vibratory hammer integrated construction device, which comprises a vibratory hammer 1, a power station 2 and a crane 3, wherein the vibratory hammer 1 and the power station 2 are connected through a hydraulic pipe 4. The crane 3 includes a rotary platform 31 and a boom 32 rotatably connected to the rotary platform 31, the vibration hammer 1 is connected to a tip end portion of the boom 32 via a hook 36, and the hook 36 is movable up and down with respect to the boom 32 to move the vibration hammer 1 up and down. The power station 2 is provided on the rotary platform 31. After the rotating platform 31 can be rotated relative to the crawler 33 of the crane 3, the crawler 33 drives the crane 3 to a designated position, the rotating platform 31 and the boom 32 are adjusted so that the steel pipe pile 5 is aligned with the piling position, and then the vibration hammer 1 is operated to drive the steel pipe pile 5 into the ground.

The vibrating hammer 1 and the power station 2 are arranged on the same crane 3, and the self weight of the power station 2 is large, so that the crane 3 can play a role in balancing weight, an original balancing weight on the crane 3 can be detached, the vacated space is used for arranging the power station 2, the space on the crane 3 is fully utilized, the occupied site for construction is reduced, and the load of the crane 3 cannot be increased. And because the maximum distance between the vibration hammer 1 and the power station 2 is a determined value, the hydraulic pipe 4 can be prevented from being pulled apart in the construction process as long as the hydraulic pipe 4 has enough length allowance, and an operator of the crane 3 can be relieved for construction. And the crane 3 can transfer the vibratory hammer 1 and the power station 2 simultaneously, compared with the prior art, the equipment and the process for transferring the power station 2 are not needed, the construction flexibility and efficiency are improved, the construction time of each bearing platform can be saved by 1 hour, the labor input is reduced by 3 names, and the economic benefit of the equipment in the whole life cycle is improved.

As shown in fig. 1, the power station 2 and the boom 32 are located at both sides of the rotation center of the rotary platform 31, and the moments generated by the power station 2 and the boom 32 are balanced with each other to prevent the crane 3 from turning over.

As shown in fig. 3, in the present embodiment, the rotary platform 31 is provided with a bracket 6 for supporting the power station 2, the power station 2 is fixedly connected to the bracket 6 by screws, and the bracket 6 is fixedly connected to the rotary platform by bolts. The bracket 6 functions to increase the supporting area of the rotary platform 31 and improve the accommodation capacity of the rotary platform 31. The extension of the bracket 6 towards the side away from the boom 32 enables a larger adjustment space for the installation position of the power station 2 to meet the position requirements of the counterweight. The installation position of the power station 2 can be far away from the suspension arm 32 as far as possible so as to generate larger moment to balance with the moment generated by the suspension arm 32, and further improve the counterweight effect of the power station 2. And the bracket 6 can also play a role of balancing the crane 3 by means of self weight. A reinforcing rib 61 is arranged between the bracket 6 and the rotating platform 31, one end of the reinforcing rib 61 is supported at the bottom of the bracket 6, and the other end of the reinforcing rib 61 is connected to the rotating platform 31, and the reinforcing rib 61 improves the connection strength between the bracket 6 and the rotating platform 31 and the supporting capacity of the bracket 6, so that the bracket 6 can stably support the power station 2.

As shown in fig. 4, in the present embodiment, the upper surface of the bracket 6 is provided with a plurality of limiting protrusions 62, and the limiting protrusions 62 enclose a limiting space for accommodating the power station. The limiting protrusion 62 surrounds the periphery of the power station, so that the power station 2 is fixed in the limiting space, the power station 2 is prevented from moving horizontally relative to the bracket 6, the power station 2 is further prevented from falling off from the crane 3, and the safety of the vibratory hammer integrated construction device is improved. Meanwhile, the limiting space enables the power station 2 to be positioned more easily when being installed, and the power station 2 can be aligned with the installation hole positions of the bracket 6 only by pressing the power station 2 into the limiting space. Specifically, the limit projection 62 is L-shaped, and four corners of the power station 2 are each covered with one limit projection 62, so that the power station 2 is completely limited in the horizontal direction.

In order to further ensure the safety of the crane 3, a counterweight 7 is arranged on the rotating platform 31, and the counterweight 7 is positioned on one side of the rotating platform 31 far away from the boom 32. In the present embodiment, the weight block 7 is disposed below the power station 2 to save space. The moment generated by the suspension arm 32 is further balanced by arranging the balancing weight 7, so that the crane 3 is prevented from being turned over.

As shown in fig. 1 and 2, in order to arrange the hydraulic pipes 4 neatly, a section of the hydraulic pipe 4 away from the vibratory hammer 1 is at least partially connected to the boom 32, and the hydraulic pipe 4 moves along with the movement of the boom 32, so that the position of the hydraulic pipe 4 can be constrained, the hydraulic pipe 4 is prevented from being wound, the safety risk caused by dragging the hydraulic pipe 4 is prevented, and the safety of the vibratory hammer construction platform is improved. In this embodiment, the hydraulic pipe 4 includes a connection section 41 bundled on the boom 32, the extension direction of the connection section 41 is the same as the extension direction of the boom 32, and the connection section 41 of the hydraulic pipe 4 is connected to the lower end of the boom 32 and extends along the direction of the boom 32, so that the arrangement of the hydraulic pipe 4 is cleaner and tidier, the hydraulic pipe 4 is prevented from being excessively bent or wound, and the potential safety hazard is further eliminated. A certain length margin is left on the part of the hydraulic pipe 4 between the suspension arm 32 and the vibration hammer 1, so that the vibration hammer 1 cannot break the hydraulic pipe 4 when moving. In this embodiment, the connecting section 41 of the hydraulic pipe 4 is fixed inside the boom 32 by the strapping 9, further preventing the hydraulic pipe 4 from being damaged.

In the present embodiment, the boom 32 is provided with a transfer block 8, specifically, the boom 32 is provided with a beam 34, the transfer block 8 is suspended on the beam 34 by a steel wire 35, and the beam 34 is located between the position where the hydraulic pipe 4 extends from the boom 32 and the top end of the boom 32. When the transfer block 8 is in a natural hanging state, a space exists between the transfer blocks 8 at the positions where the hydraulic pipes 4 extend out of the suspension arms 32, and a section of the hydraulic pipes 4 between the vibration hammer 1 and the suspension arms 32 is partially overlapped on the transfer block 8. The transition block 8 further prevents the hydraulic pipe 4 from being dragged and entangled and prevents the hydraulic pipe 4 from being damaged by excessive bending where it protrudes from the boom 32. Meanwhile, the transfer block 8 is hung on the suspension arm 32, so that a certain degree of freedom of the hydraulic pipe 4 can be ensured. The position of the cross beam 34 is determined by the length of the hydraulic pipe 4 and the height of the steel pipe pile 5, and the position of the cross beam 34 can be adjusted according to actual conditions. If the cross member 34 is positioned too far down, the extended hydraulic pipes 5 will be dragged over the ground, and if the cross member 34 is positioned too far up, the extended hydraulic pipes 5 will be less and the vibration hammer 1 will not reach the ground.

Preferably, the holding tank (not shown in the figure) that is used for holding hydraulic pressure pipe 4 is seted up to the upper surface of switching piece 8, and the holding tank can keep hydraulic pressure pipe 4 and switching piece 8 contact, further limits the motion of hydraulic pressure pipe 4, avoids the motion influence construction of hydraulic pressure pipe 4. The upper surface of switching piece 8 is the bellied arc that makes progress, and the holding tank is the arc wall, because the holding tank is the arc, consequently can avoid hydraulic pressure pipe 4 to take place excessively buckling in the part of switching piece 8, prevents the damage of hydraulic pressure pipe 4.

While specific embodiments of the invention have been described above, it will be appreciated by those skilled in the art that this is by way of example only, and that the scope of the invention is defined by the appended claims. Various changes and modifications to these embodiments may be made by those skilled in the art without departing from the spirit and scope of the invention, and these changes and modifications are within the scope of the invention.