CN219951938U - Connecting device for vibrating hammer and piling ship - Google Patents

Abstract

The connecting device for the vibrating hammer and the piling ship comprises a supporting main body and sliding components fixedly arranged at corners of two opposite sides of the supporting main body, wherein the sliding components extend outwards along the corners of the supporting main body; a vertically arranged chute is formed in the sliding component, and chute openings of the sliding components on two sides of the supporting main body are oppositely arranged; a plurality of connecting holes are formed on the surface of the supporting main body; compared with the prior art, link to each other the vibratory hammer with the support main part through support main part and the slip subassembly that sets up on the support main part, pile driving boat is connected with the slip subassembly through the spout in the slip subassembly for the vibratory hammer is under the spout effect in the use, and the vibratory hammer leads and stably goes up and down, realizes the combination between pile driving boat and the vibratory hammer through support main part and slip subassembly, thereby makes the noise littleer under the circumstances of guaranteeing installation accuracy when guaranteeing to install the steel protection tube.

Description

Connecting device for vibrating hammer and piling ship

Technical Field

The utility model relates to the technical field of building construction, in particular to a connecting device for a vibrating hammer and a piling ship.

Background

In the construction of facilities such as a water surface bridge and the like, a steel pile casing is usually required to be installed at the water bottom and used for pile foundations of the facilities such as the bridge and the like, at present, the installation of the steel pile casing is usually realized by a pile driving ship, equipment for driving the steel pile casing by the pile driving ship in the prior art is usually an impact hammer, the steel pile casing is driven by the pile driving ship, the precision is higher, the verticality is better, but the impact hammer has larger noise, and the impact hammer cannot be used in a region with strict noise control. In the pile sinking process of the vibrating hammer with low noise, large hoisting equipment such as a floating crane is usually used for hoisting the vibrating hammer and matched with a guide frame to carry out pile sinking on the steel pile casing, and compared with a pile driving ship, the pile driving process has poor precision. For the project that the pile driving technique is needed to use the pile-protecting technique and the platform technique is needed, and the requirements on precision and noise control are high, the pile sinking technique of the impact hammer and the vibration hammer of the pile driving boat cannot be used.

Disclosure of Invention

The utility model aims to overcome the defects in the prior art, and provides the connecting device for the vibrating hammer and the piling ship, which has the advantages of simple structure, convenience in installation and high structural strength.

In order to achieve the above object, the present utility model adopts the following technical scheme: the connecting device for the vibrating hammer and the piling ship comprises a supporting main body and sliding components fixedly arranged at corners of two opposite sides of the supporting main body, wherein the sliding components extend outwards along the corners of the supporting main body; a vertically arranged chute is formed in the sliding component, and chute openings of the sliding components on two sides of the supporting main body are oppositely arranged; the surface of the supporting main body is provided with a plurality of connecting holes.

As a preferred solution of the present utility model, the supporting body includes a first connecting plate vertically disposed and a plurality of supporting plates connected to the first connecting plate, and the plurality of supporting plates are horizontally connected to different levels of the first connecting plate.

As a preferable scheme of the utility model, the support main body further comprises a second connecting plate connected with the plurality of support plates, the first connecting plate and the second connecting plate are arranged on two opposite sides of the support plates, and the sliding assembly is arranged at the joint of the second connecting plate and the support plates.

As a preferred embodiment of the present utility model, a plurality of the support plates are arranged at equal intervals from top to bottom.

As a preferable scheme of the utility model, the sliding component comprises a reinforcing plate and a limiting block which are connected, the sliding groove is formed in the limiting block, and the reinforcing plate and the limiting block are respectively connected with two adjacent sides of the supporting plate.

As a preferable scheme of the utility model, the limiting block is abutted with the second connecting plate.

As a preferred embodiment of the present utility model, a plurality of the connection holes are formed on a surface of the first connection plate.

As a preferable scheme of the utility model, a plurality of hollowed-out grooves for reducing weight are formed on each supporting plate.

As a preferable mode of the present utility model, the support body is welded to the sliding assembly.

As a preferable mode of the utility model, the first connecting plate and the second connecting plate are both arranged perpendicular to the supporting plate.

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

1. the vibrating hammer is connected with the supporting body through the connecting hole on the surface of the supporting body and the sliding component is arranged on the supporting body, and the piling ship is connected with the sliding component through the sliding groove in the sliding component, so that the vibrating hammer is guided and stably lifted under the action of the sliding groove in the using process, the combination between the piling ship and the vibrating hammer is realized through the supporting body and the sliding component, and the noise is smaller under the condition of ensuring the installation precision when the steel casing is installed;

2. the supporting plates which are arranged from top to bottom at equal intervals are surrounded with the first connecting plate and the second connecting plate to form a whole, so that the structural strength of the connecting device is increased, and meanwhile, the vibrating hammer is slidably connected with the pile frame of the piling ship through the sliding assemblies arranged at the corners of the two sides of the supporting body, so that the vibrating hammer can move on the pile frame of the piling ship more smoothly in the working process, and the construction precision is further ensured.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic view of the structure of the connecting hole of the present utility model

Reference numerals: the support body 1, the first connecting plate 101, the support plate 102, the second connecting plate 103, the hollowed-out groove 104, the connecting hole 105, the sliding component 2, the sliding groove 201, the reinforcing plate 202 and the limiting block 203.

Detailed Description

Embodiments of the present utility model will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1-2, a connecting device for a vibratory hammer and a piling ship comprises a supporting main body 1 and sliding components 2 fixedly arranged at corners of two opposite sides of the supporting main body 1, wherein the sliding components 2 extend outwards along the corners of the supporting main body 1; a chute 201 which is vertically arranged is formed in the sliding component 2, and the openings of the chute 201 of the sliding component 2 on two sides of the supporting main body 1 are oppositely arranged; the support body 1 is formed on a surface thereof with a plurality of connection holes 105.

Both ends of the sliding component 2 extend outwards along corners of the supporting body 1, the extending lengths of both ends of the sliding component 2 are the same, the sliding groove 201 is arranged along the length direction of the sliding component 2, the opening direction of the sliding groove 201 points to the sliding component 2 on the opposite side of the supporting body 1, and the opening direction of the sliding groove 201 is perpendicular to the sliding component 2.

The support body 1 comprises a first connecting plate 101 and a plurality of support plates 102, wherein the first connecting plate 101 is vertically arranged, the support plates 102 are connected to the first connecting plate, the support plates 102 are horizontally connected to different levels of the first connecting plate 101, the first connecting plate 101 is arranged at the end part of the support plate 102, and the width of the first connecting plate 101 is the same as that of the support plate 102.

The support body 1 further comprises a second connecting plate 103 connected with the plurality of support plates 102, the first connecting plate 101 and the second connecting plate 103 are arranged on two opposite sides of the support plates 102, and the sliding assembly 2 is arranged at the joint of the second connecting plate 103 and the support plates 102.

The second connecting plate 103 is arranged parallel to the first connecting plate 101, and the second connecting plate 103 is arranged perpendicular to the plurality of supporting plates 102.

The plurality of support plates 102 are arranged from top to bottom at equal intervals, the plurality of support plates 102 are surrounded by the first connecting plate 101 and the second connecting plate 103, so that the structural strength of the connecting device is increased, and meanwhile, the stress of the connecting device can be more uniformly distributed on the whole device through the plurality of support plates 102 arranged from top to bottom at equal intervals, so that the condition of stress concentration of the connecting device is avoided.

The sliding assembly 2 comprises a reinforcing plate 202 and a limiting block 203 which are connected, a sliding groove 201 is formed in the limiting block 203, the reinforcing plate 202 and the limiting block 203 are respectively connected to two adjacent sides of the supporting plate 102, the reinforcing plate 202 is fixedly connected with the limiting block 203, the reinforcing plate 202 is arranged on the surface of the supporting body 1, the reinforcing plate 202 is fixedly connected with a plurality of supporting plates 102, the sliding groove 201 is formed on one side, opposite to the two limiting blocks 203, of the sliding groove 201, the connecting device is in sliding connection with a pile frame of a piling ship, and the groove wall of the sliding groove 201 is in butt joint with the pile frame of the piling ship.

The stopper 203 and the butt of second connecting plate 103, stopper 203 weld on second connecting plate 103, and the width of the spout 201 of stopper 203 is close to the spout 201 of one side of second connecting plate 103 and is greater than the spout 201 and keep away from the spout 201 of one side of second connecting plate 103, through setting up the reinforcing plate 202 with stopper 203 fixed connection, increased the structural strength of stopper 203 and supporting body 1, ensure at actual course of working that stopper 203 and supporting body 1 firmly fasten together, the circumstances that stopper 203 breaks away from supporting body 1 can not appear.

The plurality of connecting holes 105 are formed in the surface of the first connecting plate 101, the plurality of connecting holes 105 are uniformly distributed on the surface of the first connecting plate 101, and the connecting device is connected with the vibrating hammer through the plurality of connecting holes 105 by bolts, so that the connecting device is ensured not to shake on the vibrating hammer, and the construction precision is ensured.

The hollowed-out grooves 104 for weight reduction are formed in the supporting plates 102, the hollowed-out grooves 104 are formed in the middle of the supporting plates 102, and the structural weight of the supporting plates 102 is reduced while the structural strength of the supporting plates 102 is guaranteed, so that the whole connecting device is more stable in the use process.

The support body 1 and the sliding component 2 are welded and fixed, and the support body 1 and the sliding component 2 are firmly fastened together through welding, so that the whole connecting device cannot be damaged in the using process.

The first connecting plate 101 and the second connecting plate 103 are perpendicular to the supporting plates 102, and the vertical arrangement of the first connecting plate 101 and the second connecting plate 103 and the supporting plates 102 ensures that the vibrating hammer mounted on the first connecting plate 101 of the supporting body 1 can vertically move up and down in the actual use process, so that the vibrating hammer can vertically mount the steel casing.

In the actual use process, the specific installation steps are as follows:

firstly, connecting a connecting device with a vibrating hammer through a bolt;

and secondly, installing the connecting device on a pile frame of the piling ship, specifically lifting a vibrating hammer by a crane hook of the piling ship, tilting the pile frame, placing the vibrating hammer below the bottom end of the pile frame, adjusting the perpendicularity of the pile frame, lifting the vibrating hammer into a tap hole, sleeving a sliding groove 201 of a limiting block 203 on the sliding component 2 with a sliding rail on the pile frame, and thus, completing the installation of the connecting device, the vibrating hammer and the piling ship.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present utility model. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the utility model; thus, the present utility model is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Although the reference numerals in the figures are used more herein: the terms of the support body 1, the first connection plate 101, the support plate 102, the second connection plate 103, the hollowed-out groove 104, the connection hole 105, the sliding component 2, the sliding groove 201, the reinforcing plate 202, the limiting block 203 and the like are not excluded from the possibility of using other terms. These terms are used merely for convenience in describing and explaining the nature of the utility model; they are to be interpreted as any additional limitation that is not inconsistent with the spirit of the present utility model.

Claims (8)

1. The connecting device for the vibrating hammer and the piling ship is characterized by comprising a supporting main body (1) and sliding components (2) fixedly arranged at the corners of two opposite sides of the supporting main body (1), wherein the sliding components (2) extend outwards along the corners of the supporting main body (1); a chute (201) which is vertically arranged is formed in the sliding component (2), and openings of the chute (201) of the sliding component (2) at two sides of the supporting main body (1) are oppositely arranged; a plurality of connecting holes (105) are formed on the surface of the supporting main body (1); the support main body (1) comprises a first connecting plate (101) which is vertically arranged and a plurality of support plates (102) which are connected to the first connecting plate, and the plurality of support plates (102) are horizontally connected to different horizontal heights of the first connecting plate (101); the sliding assembly (2) comprises a reinforcing plate (202) and a limiting block (203) which are connected, the sliding groove (201) is formed in the limiting block (203), and the reinforcing plate (202) and the limiting block (203) are respectively connected to two adjacent side edges of the supporting plate (102).

2. A connection device for use between a vibratory hammer and a piling vessel according to claim 1, wherein the support body (1) further comprises a second connection plate (103) connected to a plurality of support plates (102), the first connection plate (101) and the second connection plate (103) being provided on opposite sides of the support plates (102), and the sliding assembly (2) being provided at the connection of the second connection plate (103) and the support plates (102).

3. A connection device for use between a vibratory hammer and a piling vessel according to claim 1, wherein several of the support plates (102) are equally spaced from top to bottom.

4. A connection device for use between a vibratory hammer and a piling vessel according to claim 2, wherein the stopper (203) abuts the second connection plate (103).

5. A connection device for use between a vibratory hammer and a piling vessel according to claim 1, wherein a plurality of the connection holes (105) are formed in a surface of the first connection plate (101).

6. A connection device for a vibratory hammer and a piling vessel according to claim 1, wherein a plurality of the support plates (102) are each formed with hollowed-out grooves (104) for weight reduction.

7. A connection device for a vibratory hammer to a piling vessel according to claim 1, wherein the support body (1) is welded to the sliding assembly (2).

8. A connection device for use between a vibratory hammer and a piling vessel according to claim 2, wherein the first (101) and second (103) connection plates are each arranged perpendicular to the support plate (102).