CN214653309U - Efficient electromechanical component mounting and lifting equipment - Google Patents

Abstract

The utility model discloses a high-efficiency electromechanical component mounting lifting device, which comprises a device underframe, a lifting frame body, a device upper frame body, a sliding assembly, a winch motor group, a lifting fixed pulley block and a top fixed pulley block; an equipment upper frame body is fixedly connected to the equipment underframe along the vertical direction, a lifting frame body and a hoisting motor set are respectively arranged on the equipment underframe and positioned on two sides of the equipment upper frame body, the lifting frame body is fixedly connected with the side face of a sliding assembly, the sliding assembly is slidably connected with the equipment upper frame body, a lifting fixed pulley block is fixedly connected to the lifting frame body, and a top fixed pulley block is fixedly connected to the bottom of a top square steel pipe; the hoisting motor set is provided with a steel wire rope, the steel wire rope penetrates through the lifting fixed pulley block and the top fixed pulley block, and the lifting frame body and the sliding assembly are driven to integrally move through the steel wire rope. The utility model discloses an equipment is showing and has promoted the efficiency of construction, has strengthened the stability of support body, and this patent technology is an exquisite construction and the green construction technique in the building engineering field.

Description

Efficient electromechanical component mounting and lifting equipment

Technical Field

The utility model relates to a job site electromechanical installation technical field especially is about a high-efficient electromechanical component installation jacking equipment.

Background

In the electromechanical installation operation process of a construction site, the lifting operation of components such as pipelines, air pipes and the like is completed by workers with the help of simple tools. Due to the large size and weight of the large installation components, multiple workers are required to complete the lifting process. Because the whole lifting operation is manually operated by manpower, the cooperative construction of workers is caused, and the efficiency is lower, thereby restricting the construction progress of the installation operation and increasing the installation cost of the project.

In the prior art, the lifting operation process of the electromechanical installation component mainly has the following problems: firstly, in electromechanical installation, the sizes and the masses of a pipeline and an air pipe are large, a large amount of manpower is consumed for cooperation, the working efficiency is low, and the implementation cost is high; secondly, in the lifting operation process of the pipeline and the air pipe, after the pipeline and the air pipe are lifted to a certain height, the stability of the component is difficult to maintain through manual operation, construction errors are caused, and the construction quality is influenced; thirdly, lifting operation is completed by means of automatic equipment, so that the cost is high and the cost performance is insufficient; fourthly, the manual lifting operation efficiency is low, the construction period is easily delayed, and therefore the construction cost of the project is increased.

The information disclosed in this background section is only for enhancement of understanding of the general background of the invention and should not be taken as an acknowledgement or any form of suggestion that this information constitutes prior art already known to a person skilled in the art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient electromechanical component installation jacking equipment, it can solve prior art's above-mentioned problem.

In order to achieve the purpose, the utility model provides a high-efficiency electromechanical component mounting lifting device, which comprises a device underframe, a lifting frame body, a device upper frame body, a sliding component, a hoisting motor group, a lifting fixed pulley block and a top fixed pulley block; the lifting fixed pulley block is fixedly connected to the lifting frame body, and the top fixed pulley block is fixedly connected to the bottom of a top square steel pipe of the upper frame body of the equipment; and when the hoisting motor set is started, the lifting frame body and the sliding assembly are driven to integrally move through the steel wire rope.

In one or more embodiments, the equipment chassis is formed by welding five square steel pipes, wherein three transversely-arranged square steel pipes are welded between two longitudinally-arranged square steel pipes, three longitudinally-arranged angle steel supports are arranged on one side of the equipment chassis between the two transversely-arranged square steel pipes, and a hoisting motor set is fixedly connected to each angle steel support.

In one or more embodiments, the lifting frame body comprises two horizontal square steel tubes, two inclined strut square steel tubes and one transverse support angle steel, the bottom of each horizontal square steel tube is provided with one inclined strut square steel tube, and the inner sides of the ends of the two horizontal square steel tubes are connected through the transverse support angle steel in a welded mode.

In one or more embodiments, the upper frame body of the equipment further comprises two vertical square steel tubes, the two vertical square steel tubes are welded on the middle horizontal square steel tube of the equipment underframe, and two ends of the top square steel tube are welded on the two vertical square steel tubes.

In one or more embodiments, the slip subassembly is two sets of, two sets of slip subassemblies and two vertical square steel pipe sliding connection, every slip subassembly of group includes the pulley link, fixing bearing, the gyro wheel, clamping screw, the set bolt group, wherein clamping screw passes clamping bearing, clamping screw's both ends welding is in the inboard of pulley link, the gyro wheel passes through the set bolt group to be fixed on the pulley link, fixing bearing and gyro wheel set up respectively in the both sides of vertical square steel pipe and laminate vertical square steel pipe, so that the slip subassembly slides from top to bottom along vertical square steel pipe.

In one or more embodiments, the lifting crown block assembly includes a pulley mount, a pulley fixing shaft, and a pulley, the pulley mount being welded to the lateral support angle.

In one or more embodiments, the structure of the top set of pulleys is the same as the structure of the lifting set of pulleys.

In one or more embodiments, the hoisting motor set further comprises a hoisting motor and a motor base, wherein the hoisting motor is fixed on the motor base, and the motor base is welded on an angle iron support of the equipment chassis.

In one or more embodiments, the bottom of the equipment chassis is provided with four sets of universal wheels, which are arranged at the four corners of the bottom of the equipment chassis.

Compared with the prior art, according to the utility model discloses a high-efficient electromechanical component installation jacking equipment has following advantage: the utility model discloses a high-efficient electromechanical component installation jacking equipment is through setting up equipment chassis, the lift support body, equipment upper portion support body, sliding component, hoist engine group, promotion fixed pulley group and top fixed pulley group, and hoist engine group is provided with wire rope, and wire rope passes promotion fixed pulley group and top fixed pulley group, when hoist engine group, during the start-up, drives lift support body and sliding component along equipment upper portion support body moving as a whole through wire rope to realize the lifting function of equipment. The lifting frame body forms a triangular stable structure through the horizontal square steel pipe and the inclined strut square steel pipe, so that the stability of the whole lifting frame body is enhanced. The utility model discloses a high-efficient electromechanical component installation jacking equipment has improved the operating efficiency, has reduced engineering construction cost.

Drawings

Fig. 1 is a schematic perspective view of a high-efficiency electromechanical component mounting lifting device according to an embodiment of the present invention.

Fig. 2 is a schematic structural diagram of an equipment chassis according to an embodiment of the present invention.

Fig. 3 is a schematic structural view of a lifting frame body according to an embodiment of the present invention.

Fig. 4 is a schematic structural view of an upper frame of an apparatus according to an embodiment of the present invention.

Fig. 5 is a schematic structural diagram of a sliding assembly according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a hoisting motor set according to an embodiment of the present invention.

Fig. 7 is a schematic view of a lifting crown block assembly according to an embodiment of the present invention.

Description of reference numerals:

1-universal wheel, 2-equipment underframe, 3-lifting frame body, 4-equipment upper frame body, 5-sliding assembly, 6-hoisting motor group, 7-hoisting fixed pulley group, 8-top fixed pulley group, 9-steel wire rope, 21-square steel pipe, 22-angle steel support, 31-horizontal square steel pipe, 32-diagonal square steel pipe, 33-transverse support angle steel, 41-top square steel pipe, 42-vertical square steel pipe, 51-pulley connecting frame, 52-fixed bearing, 53-roller, 54-fixed screw, 55-fixed bolt group, 61-hoisting motor, 62-motor base, 71-pulley fixed frame, 72-pulley fixed shaft and 73-pulley.

Detailed Description

The following detailed description of the present invention is provided in conjunction with the accompanying drawings, but it should be understood that the scope of the present invention is not limited by the following detailed description.

Throughout the specification and claims, unless explicitly stated otherwise, the word "comprise", or variations such as "comprises" or "comprising", will be understood to imply the inclusion of a stated element or component but not the exclusion of any other element or component.

As shown in fig. 1 to 7, according to the utility model discloses a high-efficient electromechanical component installation jacking equipment of embodiment, including equipment chassis 2, lifting frame body 3, equipment upper portion support body 4, sliding assembly 5, hoisting motor group 6, promotion fixed pulley group 7 and top fixed pulley group 8. The equipment chassis 2 sets up along the horizontal direction, along vertical direction fixedly connected with equipment upper portion support body 4 on the equipment chassis 2, the both sides of equipment upper portion support body 4 fixedly connected with lifting frame body 3 and hoist generator group 6 respectively, and hoist generator group 6 is fixed to be set up on equipment chassis 2. The side fixed connection of the lifting frame body 3 and the sliding assembly 5, the sliding assembly 5 and the upper frame body 4 of the equipment are connected in a sliding mode, and therefore the sliding assembly 5 can slide up and down along the upper frame body 4 of the equipment. The lifting fixed pulley block 7 is fixedly connected to the lifting frame body 3, and the top fixed pulley block 8 is fixedly connected to the bottom of the top square steel pipe 41 of the upper frame body 4 of the device. The hoisting motor group 6 is provided with a steel wire rope 9, the steel wire rope 9 penetrates through the lifting fixed pulley block 7 and the top fixed pulley block 8, and when the hoisting motor group 6 is started, the lifting frame body 3 and the sliding assembly 5 are driven to integrally move through the steel wire rope 9, so that the lifting function of the equipment is realized.

Further, the equipment chassis 2 is formed by welding five square steel pipes 21, wherein three transversely-arranged square steel pipes 21 are welded between two longitudinally-arranged square steel pipes 21, three longitudinally-arranged angle steel supports 22 are arranged on one side of the equipment chassis 2 between the two transversely-arranged square steel pipes 21, and a hoisting motor group 6 is fixedly connected to each angle steel support 22. The angle iron support 22 is used for supporting the transverse loading force of the reinforcing frame body and fixing the hoisting motor set.

Further, the lifting frame body 3 comprises two horizontal square steel tubes 31, two inclined strut square steel tubes 32 and a transverse support angle steel 33, the bottom of each horizontal square steel tube 31 is provided with one inclined strut square steel tube 32, and the inner sides of the ends of the two horizontal square steel tubes 31 are connected through the transverse support angle steel 33 in a welding mode.

Further, the upper frame body 4 of the equipment further comprises two vertical square steel tubes 42, the two vertical square steel tubes 42 are welded on the middle horizontal square steel tube 21 of the equipment chassis 2, and two ends of the top square steel tube 41 are welded on the two vertical square steel tubes 42 to form a whole with the equipment chassis 2.

Further, the sliding assembly 5 is two sets of, two sets of sliding assemblies 5 and two vertical square steel tube 42 sliding connection, every sliding assembly 5 of group includes pulley link 51, fixing bearing 52, gyro wheel 53, clamping screw 54, clamping screw 55, wherein clamping screw 54 passes clamping bearing 52, clamping screw 54's both ends welding is in pulley link 51's inboard, gyro wheel 53 passes clamping screw 55 and fixes on pulley link 51, clamping bearing 52 and gyro wheel 53 set up respectively in the both sides of vertical square steel tube 42 and laminate vertical square steel tube 42, thereby realized that sliding assembly 5 slides from top to bottom along vertical square steel tube 42.

Further, the lifting fixed pulley group 7 comprises a pulley fixing frame 71, a pulley fixing shaft 72 and a pulley 73, and the pulley fixing frame 71 is welded and connected to the middle position of the transverse support angle steel 33.

Further, the structure of the top crown block 8 is the same as that of the lifting crown block 7, and the top crown block 8 and the lifting crown block 7 are fixed at the middle position of the bottom of the top square steel tube 41 in the same connecting mode, and are arranged in the same vertical plane.

Further, the hoisting motor unit 6 further comprises a hoisting motor 61 and a motor base 62, wherein the hoisting motor 61 is fixed on the motor base 62, and the motor base 62 is welded on the angle iron support 22 of the equipment chassis 2.

Further, four sets of universal wheels 1 are arranged at the bottom of the equipment chassis 2, and the four sets of universal wheels 1 are arranged at four corners of the bottom of the equipment chassis 2. The universal wheel 1 can realize the removal of equipment arbitrary direction and distance, moves to the assigned position when equipment, steps on the piece of stopping on the universal wheel 1, can realize that equipment fixes at the assigned position temporarily.

The foregoing descriptions of specific exemplary embodiments of the present invention have been presented for purposes of illustration and description. It is not intended to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. The exemplary embodiments were chosen and described in order to explain certain principles of the invention and its practical application to enable one skilled in the art to make and use various exemplary embodiments of the invention and various alternatives and modifications as are suited to the particular use contemplated. It is intended that the scope of the invention be defined by the claims and their equivalents.

Claims (9)

1. The efficient electromechanical component mounting and lifting equipment is characterized by comprising an equipment underframe (2), a lifting frame body (3), an equipment upper frame body (4), a sliding assembly (5), a hoisting motor set (6), a lifting fixed pulley block (7) and a top fixed pulley block (8);

wherein the equipment underframe (2) is arranged along the horizontal direction, the equipment underframe (2) is fixedly connected with the upper frame body (4) of the equipment along the vertical direction, the two sides of the upper frame body (4) of the device are respectively provided with the lifting frame body (3) and the hoisting motor group (6), the hoisting motor group (6) is fixedly arranged on the equipment chassis (2), the lifting frame body (3) is fixedly connected with the side surface of the sliding component (5), the sliding component (5) is connected with the upper frame body (4) of the equipment in a sliding way, so that the sliding component (5) can slide up and down along the upper frame body (4) of the equipment, the lifting fixed pulley block (7) is fixedly connected on the lifting frame body (3), the top fixed pulley block (8) is fixedly connected to the bottom of a top square steel pipe (41) of the upper frame body (4) of the equipment;

and the hoisting motor group (6) is provided with a steel wire rope (9), the steel wire rope (9) penetrates through the lifting fixed pulley block (7) and the top fixed pulley block (8), and when the hoisting motor group (6) is started, the lifting frame body (3) and the sliding assembly (5) are driven to integrally move through the steel wire rope (9).

2. The efficient electromechanical component mounting lifting device as recited in claim 1, wherein the device chassis (2) is formed by welding five square steel tubes (21), wherein three horizontally arranged square steel tubes (21) are welded between two vertically arranged square steel tubes (21), three vertically arranged angle steel supports (22) are arranged on one side of the device chassis (2) between the two horizontally arranged square steel tubes (21), and the hoisting motor group (6) is fixedly connected to the angle steel supports (22).

3. The efficient electromechanical component mounting lifting device according to claim 2, wherein the lifting frame body (3) comprises two horizontal square steel tubes (31), two inclined strut square steel tubes (32) and a transverse support angle steel (33), one inclined strut square steel tube (32) is arranged at the bottom of each horizontal square steel tube (31), and the inner sides of the ends of the two horizontal square steel tubes (31) are welded and connected through the transverse support angle steel (33).

4. The efficient electromechanical component installation lifting device according to claim 3, wherein the device upper frame (4) further comprises two vertical square steel tubes (42), the two vertical square steel tubes (42) are welded to the middle horizontally arranged square steel tube (21) of the device underframe (2), and two ends of the top square steel tube (41) are welded to the two vertical square steel tubes (42).

5. The efficient electromechanical component mounting lifting device according to claim 4, wherein said sliding assemblies (5) are divided into two groups, two groups of said sliding assemblies (5) are slidably connected with two vertical square steel tubes (42), each group of said sliding assemblies (5) comprises a pulley connecting frame (51), a fixed bearing (52), a roller (53), a fixed screw (54) and a fixed bolt group (55), wherein the fixed screw (54) passes through the fixed bearing (52), two ends of the fixed screw (54) are welded at the inner side of the pulley connecting frame (51), the roller (53) is fixed on the pulley connecting frame (51) through the fixed bolt group (55), the fixed bearing (52) and the roller (53) are respectively arranged at two sides of the vertical square steel pipe (42) and are attached to the vertical square steel pipe (42), so that the sliding assembly (5) can slide up and down along the vertical square steel pipe (42).

6. The high efficiency electromechanical component mounting lifting device of claim 5, wherein said set of lifting tackle blocks (7) comprises a tackle fixing bracket (71), a tackle fixing shaft (72) and a tackle (73), said tackle fixing bracket (71) being welded on the transverse support angle (33).

7. A high efficiency electromechanical component mounting lifting device according to claim 6, characterised in that the structure of said top set of pulleys (8) is identical to the structure of said lifting set of pulleys (7).

8. The high efficiency electromechanical component mounting lifting device of claim 7, wherein the hoist motor assembly (6) further comprises a hoist motor (61) and a motor base (62), wherein the hoist motor (61) is fixed to the motor base (62), and the motor base (62) is welded to the angle iron support (22) of the device chassis (2).

9. A high efficiency electromechanical component mounting lifting device according to claim 1, c h a r a c t e r i z e d in that the bottom of said device chassis (2) is provided with four sets of universal wheels (1), four sets of universal wheels (1) being arranged at four corners of the bottom of said device chassis (2).

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