SUMMERY OF THE UTILITY MODEL
In order to overcome the defects in the prior art, the component hoisting equipment for the pipe shaft is provided so as to solve the problems that the traditional manual carrying is time-consuming and labor-consuming and the efficiency is low in the transportation, hoisting and installation operations of the components of the super-high floors.
To achieve the above object, there is provided a component lifting device for use in a pipe well, comprising:
the loading vehicle comprises a supporting beam, wherein auxiliary rollers are respectively installed at two ends of the supporting beam in the length direction, the supporting beam is detachably connected with a first clamping arm and a second clamping arm which are used for clamping two ends of a tubular component, the first clamping arm and the second clamping arm are positioned between the two auxiliary rollers, two sides of the supporting beam in the width direction are respectively connected with a limiting rod, and the limiting rods are connected with guide rings;
the guide ring is movably sleeved in the guide cable; and
and the lifting device is used for lifting the loading vehicle and is connected to the loading vehicle.
Further, the support beam comprises a first beam body and a second beam body detachably connected to the first beam body, the first clamping arm is detachably connected to the first beam body, and the second clamping arm is detachably connected to the second beam body.
Furthermore, a plurality of fastening holes are formed in the first beam body and the second beam body respectively, the fastening holes are arranged in the vertical direction, the first beam body is overlapped on the second beam body in a staggered mode, and fastening pieces are inserted into at least two corresponding fastening holes of the first beam body and the second beam body respectively to fix the length of the supporting beam.
Furthermore, first flange plates are respectively formed on two sides of the first beam body, and the second flange plates are respectively detachably connected with first clamping arms.
Further, the first end bending type of first centre gripping arm forms first mousing-hook, first flange plate be formed with first bar hole and communicate in the second bar hole in first bar hole, first bar hole with the second bar hole is the angle setting, the length in first bar hole with first mousing-hook width looks adaptation, first centre gripping arm is inserted and is located in the second bar hole, first mousing-hook support in keeping away from of first flange plate one side of the second end of first centre gripping arm.
Furthermore, the two ends of the supporting beam in the length direction are respectively connected with a supporting rod, and the end parts of the supporting beams, far away from the supporting beams, are provided with the auxiliary rollers.
Furthermore, the lifting device comprises a winch arranged at the upper opening of the pipe shaft, and a sling is wound on the winch and connected to the supporting beam.
Furthermore, two first clamping parts are formed on the first clamping arm, and a first clamping space for embedding the pipe wall of the tubular component is formed between the two first clamping parts.
Furthermore, two second clamping parts are formed on the second clamping arm, and a second clamping space for embedding the pipe wall of the tubular member is formed between the two second clamping parts.
The beneficial effects of the utility model reside in that, the utility model discloses a component lifting equipment for in the pipe shaft loads the tubulose component centre gripping on the supporting beam through first centre gripping arm and second centre gripping arm, utilizes the lift to load in the pipe shaft in the transportation that goes up and down, utilizes the smooth gag lever post of locating the direction cable to be used for controlling the walking route of load wagon, prevents the emergence of uncontrollable phenomena such as heeling, off normal, collision structure of load wagon, and direction cable and supplementary gyro wheel can make the load wagon go stably in addition.
Detailed Description
The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention.
Fig. 1 is the utility model discloses a structural schematic diagram, fig. 2 for component lifting device in the conduit shaft are the partial enlarged view of A department in fig. 1, fig. 3 is the utility model discloses a structural schematic diagram, fig. 4 of load wagon do the utility model discloses a load wagon load pipeline backplate's schematic diagram, fig. 5 do the utility model discloses a load wagon load the sheathed tube of small-bore sketch map, fig. 6 are the utility model discloses a load wagon load the sheathed tube of large-bore sketch map.
Referring to fig. 1 to 6, the present invention provides a component lifting apparatus for use in a pipe well, including: a loading vehicle 1, a guide rope 2 and a lifting device 3.
The loader vehicle 1 is intended to be arranged in a pipe shaft 4. Specifically, the loader 1 includes a first clamp arm 12, a second clamp arm 13, and a stopper rod 14. In the pipe shaft, the support beams 11 are arranged vertically. Auxiliary rollers 13 and 16 are mounted on both ends of the longitudinal fan of the support beam 11. The support beam 11 is detachably connected with a first clamp arm 12 and a second clamp arm 13. The first clamping arm and the second clamping arm are positioned between the two auxiliary rollers. The first and second clamp arms are for clamping both ends of the tubular member. The support beam 11 is connected to a stopper rod 14 on each of the widthwise sides thereof. The end of the stop lever 14 remote from the support beam is connected to a guide ring.
The number of the guide cables 2 is at least two. In this embodiment, the number of the guide cables is two, and the two guide cables are symmetrically arranged on both sides of the loading vehicle. The guide rope 2 is installed in the pipe shaft 4 in a vertical direction. The guide ring is movably sleeved on the guide rope 2.
The lifting device 3 is mounted above the pipe shaft 4. The lifting device 3 is used for vertically lifting the loading vehicle 1 in the pipe shaft.
The utility model discloses a component lifting equipment for in tubing is loading the tubulose component centre gripping on the supporting beam through first centre gripping arm and second centre gripping arm, utilizes the lift to load in the tubing lift transportation, utilizes the smooth gag lever post of locating the direction cable to be used for controlling the walking route of load wagon, prevents the emergence of uncontrollable phenomena such as heeling, off normal, collision structure of load wagon, and direction cable and supplementary gyro wheel can make the load wagon go stably in addition.
The utility model discloses a component lifting device for in piping shaft is that an installation is simple and easy, convenient operation, dismouting labour saving and time saving to can play the repeatedly usable's of effective direction guard action hoist and mount direction protection fixed system, the construction of supporting facilities such as follow-up component sleeve pipe, mounting is taken into account comprehensively, forms a whole set of construction flow with electromechanical system's tubulose component installation, and a dragon accomplishes targetting in place, improves the success rate 100% of checking acceptance once.
The utility model discloses a work flow for component lifting device in tubing:
firstly, fixing the component on a loading vehicle, manually pushing the loading vehicle to enable the component to be transported to a pipe shaft (hoisting position) from a storage yard to be ready for hoisting;
connecting a lifting device arranged at the top layer of the pipe shaft to a loading vehicle, fixing firmly, and hoisting the loading vehicle loaded with the components by the lifting device;
after the loading vehicle loaded with the components is lifted to the designated position, the positions of the components are adjusted according to the reference positioning line, and the whole process is started to be fixed and completed.
In the present embodiment, the first gripper arm is formed with two first gripper portions 121. A first clamping space for embedding the pipe wall of the tubular component is formed between the two first clamping parts.
Likewise, the second gripper 13 arm is formed with two second gripper portions 131. A second clamping space for embedding the pipe wall of the tubular component is formed between the two second clamping parts.
As a preferred embodiment, the support beam 11 includes a first beam body 111 and a second beam body 112 detachably connected to the first beam body 111. The first clamp arm 12 is detachably connected to the first beam 111. The second clamping arm 13 is detachably connected to the second beam 112. The first beam 111 is detachably connected to the second beam 112 to facilitate unloading of the tubular member.
Specifically, the first beam body 111 and the second beam body 112 are respectively formed with a plurality of fastening holes. The plurality of fastening holes are arranged in a vertical direction. The first beam 111 is overlapped with the second beam 112 in a staggered manner. Fasteners are inserted into the corresponding at least two fastening holes of the first and second beam bodies 111 and 112, respectively, to fix the length of the support beam 11.
In a preferred embodiment, the first beam 111 has first flange plates 113 formed on both sides thereof. The first flange plates 113 on both sides of the first beam body are detachably connected with first clamping arms 12, respectively. In this embodiment, the first beam body is a T-shaped steel, and the second beam body includes two angles. The angle has a second flange plate 112 and a third flange plate. The second flanges 112 of the two angles are respectively overlapped with the first flanges 113 on the two sides of the first beam body.
In this embodiment, the first end of the first holding arm 12 is bent to form a first anti-slip hook. The first flange plate 113 is formed with a first bar-shaped hole and a second bar-shaped hole communicated with the first bar-shaped hole. The first strip-shaped hole and the second strip-shaped hole are arranged at an angle. The length of the first strip-shaped hole is matched with the width of the first mousing-hook. The first clamp arm 12 is inserted into the second strip-shaped hole. The first anti-unhooking mechanism abuts against a first side of the first flange plate 113, which is far away from the second end of the first clamping arm 12. When the first clamping arm is installed, the first anti-drop hook is inserted into the first strip-shaped hole, so that the first anti-drop hook extends to the first side of the first flange plate. After the first anti-unhooking hook extends to the first side of the first flange plate, the first clamping arm slides to the second strip-shaped hole along the first strip-shaped hole, so that the first anti-unhooking hook abuts against the first side of the first flange plate. After the first clamp arm loads the tubular member, the first anti-drop hook is tightly abutted against the first side of the first flange plate by the gravity of the tubular member located at the second side of the first flange plate.
In this embodiment, the first end of the second holding arm 13 is bent to form a second anti-slip hook. The second flange plate is formed with third bar hole and communicates in the fourth bar hole in third bar hole. The third strip-shaped hole and the fourth strip-shaped hole are arranged at an angle. The length of the third strip-shaped hole is matched with the width of the second mousing-hook. The second clamp arm 13 is inserted in the fourth hole. The second anti-slip hook abuts against a first side of the second flange plate 112 away from the second end of the second clamping arm. When the second centre gripping arm installation, insert the income with second mousing-hook via in the third bar hole for second mousing-hook extends to the first side of second flange board. After the second mousing-hook extends to the first side of the second flange plate, the second clamping arm slides to the fourth hole along the third strip-shaped hole, so that the second mousing-hook abuts against the first side of the second flange plate. After the second clamp arm loads the tubular member, the second anti-drop hook is tightened against the first side of the second flange plate using the weight of the tubular member on the second side of the second flange plate.
In the present embodiment, support rods 15 are connected to both ends of the support beam 11 in the longitudinal direction. The end of the support bar 15 remote from the support beam is fitted with an auxiliary roller 16. In the hoisting process, the auxiliary roller is abutted against the side wall of the pipe shaft for the stability of the movement of the loading vehicle, and the loading vehicle stably moves along the side wall of the pipe shaft in the lifting process.
In this embodiment, the support rod is located on the same side of the support beam as the first and second clamp arms, the support rod is supported on the side wall of the pipe shaft, so that a protection space is formed between the support beam and the side wall of the pipe shaft, and the first and second clamp arms are located in the protection space to protect the loaded tubular member.
In a preferred embodiment, the end of the stop lever 14 remote from the support beam 11 is bent to form a collar. The guide rope 2 is arranged in the collar in a sliding way. The stopper rod 14 is detachably mounted on the support beam.
Specifically, the supporting beam is provided with a threaded hole, and one end of the limiting rod, which is close to the supporting beam, is provided with an external thread matched with the internal thread of the threaded hole. The limiting rod is connected with the supporting beam in a threaded manner.
The lifting device 3 includes a hoist 31 and a hoist rope 32. The winch 31 is installed at the upper opening of the pipe shaft 4. The hoist 31 is wound with a hoist rope 32. The slings 32 are attached to the support beam 11.
Specifically, a beam is placed on an upper opening of the pipe shaft, and the winch is installed on the beam. The upper end of the guide cable is arranged at the upper part of the pipe shaft, and the lower end of the guide cable is arranged on the floor slab at the bottom layer.
It should be noted that the structure, ratio, size and the like shown in the drawings attached to the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by those skilled in the art, and are not used for limiting the limit conditions that the present invention can be implemented, so that the present invention has no technical essential meaning, and any structure modification, ratio relationship change or size adjustment should still fall within the scope that the technical content disclosed in the present invention can cover without affecting the efficacy and the achievable purpose of the present invention. Meanwhile, the terms such as "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for convenience of description, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof may be made without substantial technical changes, and the present invention is also regarded as the scope of the present invention.
The present invention has been described in detail with reference to the embodiments shown in the drawings, and those skilled in the art can make various modifications to the present invention based on the above description. Therefore, certain details of the embodiments should not be construed as limitations of the present invention, which are intended to be limited only by the scope of the appended claims.