CN221191472U - Portable mobile device of large-scale equipment - Google Patents

Abstract

The utility model discloses a convenient moving device for large-scale equipment, relates to the technical field of mechanical equipment installation, and aims to improve efficiency of moving the large-scale equipment. The main technical scheme of the utility model is as follows: portable mobile device of large-scale equipment includes: one end of the first sliding rail is connected to the upper end of the lifting mechanism, the lower end of the lifting mechanism is connected to the moving wheel, an axial rack is arranged on the upper surface of the first sliding rail, and wing plates are arranged on the opposite sides of the first sliding rail; the bearing part comprises a bearing frame, a plurality of rail holding parts and a plurality of hydraulic rods, wherein the lower end face of the bearing frame is rotationally connected with the roller group, the roller group is arranged on the upper surface of the first sliding rail in a rolling way, the upper ends of the rail holding parts are fixedly connected with the bearing frame, the lower ends of the rail holding parts are hooked on the lower surface of the wing plate, the upper ends of the hydraulic rods are respectively connected with the opposite side edges of the bearing frame, and the lower end faces the ground; the driving mechanism is fixedly connected to the bearing frame, the output end of the driving mechanism is connected to the driving gear, and the driving gear is meshed with the axial rack.

Description

Portable mobile device of large-scale equipment

Technical Field

The utility model relates to the technical field of mechanical equipment installation, in particular to a convenient moving device of large equipment.

Background

Along with the expansion of production scale and the improvement of technological equipment level in various industries, various large-scale and ultra-large mechanical equipment production lines are continuously applied, and the building units reduce the height of a factory building and the bearing capacity of a shop crown block through optimizing investment, so that the installation of large-scale equipment becomes a technical problem of installation and construction.

The patent application with the application number 202310612583.2 comprises a base, a hydraulic push rod and a pushing head, wherein the hydraulic push rod repeatedly pushes the moving frame to further move the large-sized equipment, the hydraulic push rod repeatedly pushes the moving frame to drive the large-sized equipment to move, the single moving distance is short, the time required for moving the large-sized equipment in place is long, the efficiency is low, and the improvement is needed.

Disclosure of utility model

In view of this, the present utility model provides a convenient moving device for large-scale equipment, and the main purpose is to improve the efficiency of moving the large-scale equipment.

In order to achieve the above purpose, the present utility model mainly provides the following technical solutions:

The utility model provides a convenient moving device of large-scale equipment, which comprises: the first slide rail, the bearing part and the driving mechanism;

One end of the first sliding rail is connected to the upper end of the lifting mechanism, the lower end of the lifting mechanism is connected to the moving wheel, an axial rack is arranged on the upper surface of the first sliding rail, and wing plates are arranged on the opposite sides of the first sliding rail;

The bearing part comprises a bearing frame, a plurality of rail holding parts and a plurality of hydraulic rods, wherein the lower end face of the bearing frame is rotationally connected with a roller group, the roller group is arranged on the upper surface of the first sliding rail in a rolling way, the upper ends of the rail holding parts are fixedly connected with the bearing frame, the lower ends of the rail holding parts are hooked on the lower surfaces of the wing plates, the upper ends of the hydraulic rods are respectively connected with the opposite side edges of the bearing frame, and the lower end faces the ground and is used for jacking the bearing frame;

The driving mechanism is fixedly connected to the bearing frame, the output end of the driving mechanism is connected to a driving gear, and the driving gear is meshed with the axial rack.

The aim and the technical problems of the utility model can be further realized by adopting the following technical measures.

Optionally, the rail clamping device further comprises a plurality of bearing wheels, wherein each bearing wheel is rotatably connected to the lower end of one rail clamping component, and the hub edge of the bearing wheel is propped against the lower surface of the wing plate.

Optionally, the driving mechanism is a hydraulic motor, the hydraulic motor is fixedly installed on the side surface of the bearing frame, and an output shaft of the hydraulic motor is coaxially connected with the driving gear.

Optionally, the actuating mechanism includes driving motor, action wheel and follow driving wheel, driving motor fixed mounting in the side of carrying the frame, driving motor's output shaft coaxial link in the action wheel, follow driving wheel coaxial coupling in drive gear, the action wheel transmission connect in follow the driving wheel.

Optionally, the driving wheel and the driven wheel are respectively chain wheels.

Optionally, the elevating system is the pneumatic cylinder, the lower extreme fixed connection of pneumatic cylinder is in the bearing sleeve, the shaft of removal wheel pass through the bearing install in the bearing sleeve.

Optionally, the novel pin shaft structure further comprises a plurality of second sliding rails, slots are respectively arranged at the other end of the first sliding rail and one end of the second sliding rail, a socket block is arranged at the other end of the second sliding rail and is anastomosed with the slots, first pin holes are formed in the side faces of the socket block, second pin holes are formed in the side walls of the slots and correspond to the first pin holes, and the pin shafts are inserted into the second pin holes.

By means of the technical scheme, the utility model has at least the following advantages:

Correspondingly placing the bearing frame at the other end of the first sliding rail, simultaneously, keeping the driving gear meshed with the axial rack, placing large equipment to be moved on the bearing frame, then supplying oil to a plurality of hydraulic rods through a hydraulic control system, extending the hydraulic rods, gradually landing the lower ends of the hydraulic rods, synchronously lifting the bearing frame by the hydraulic rods, and applying force to the lower surface of the wing plate by the lower end of the rail holding part to drive the middle section of the first sliding rail to rise; simultaneously, the lifting mechanism is started, and one end of the first sliding rail is lifted synchronously by the lifting mechanism, so that the whole first sliding rail is kept horizontal and separated from the ground by a certain distance.

At this time, the drive gear is positively started, and the drive gear drives the axial rack and the first slide rail to positively move, so that one end of the first slide rail is gradually close to the bearing frame.

When one end of the first sliding rail reaches the bearing frame, the driving gear is stopped, then the hydraulic rods shrink synchronously, the lower ends of the hydraulic rods are separated from the ground, the lifting mechanism lowers one end of the first sliding rail, and the first sliding rail is integrally grounded. At this time, the driving gear is reversely started, and the first sliding rail and the axial rack are fixed relative to the ground, so that the driving gear rolls towards the other end of the first sliding rail, and the bearing frame is driven to move towards the other end of the first sliding rail.

By using the device, the large equipment moves in place along with the bearing frame at one time, and compared with the prior art, the device has higher efficiency of moving the large equipment and can not damage the ground.

Drawings

Fig. 1 is a state diagram of a large-scale device when a portable moving device moves a slide rail according to an embodiment of the present utility model;

Fig. 2 is a state diagram of a carrier frame of a portable mobile device for large-scale equipment according to an embodiment of the present utility model;

fig. 3 is a state diagram of a large-scale apparatus according to another embodiment of the present utility model when a portable moving device moves a slide rail;

Fig. 4 is a state diagram of a carrier frame of another portable mobile device for large-scale equipment according to an embodiment of the present utility model;

fig. 5 is a perspective view of a first view angle of a portable mobile device for large-scale equipment according to an embodiment of the present utility model;

Fig. 6 is a second perspective view of a portable mobile device for large-scale equipment according to an embodiment of the present utility model.

Reference numerals in the drawings of the specification include: the lifting mechanism comprises a first sliding rail 1, a lifting mechanism 2, a movable wheel 3, an axial rack 4, a wing plate 5, a bearing frame 6, a rail holding part 7, a hydraulic rod 8, a roller group 9, a driving gear 10, a bearing wheel 11, a hydraulic motor 12, a driving motor 13, a driving wheel 14, a driven wheel 15, a bearing sleeve 16, a second sliding rail 17, a slot 18, a socket block 19, a first pin hole 20, a second pin hole 21 and a bearing beam 22.

Detailed Description

In order to further describe the technical means and effects adopted for achieving the preset aim of the utility model, the following detailed description refers to the specific implementation, structure, characteristics and effects according to the application of the utility model with reference to the accompanying drawings and preferred embodiments. In the following description, different "an embodiment" or "an embodiment" do not necessarily refer to the same embodiment. Furthermore, the particular features, structures, or characteristics of one or more embodiments may be combined in any suitable manner.

The utility model is described in further detail below with reference to the drawings and examples.

As shown in fig. 1 to 4, one embodiment of the present utility model provides a portable mobile device for a large-scale apparatus, which includes: the first slide rail 1, the bearing part and the driving mechanism;

One end of the first sliding rail 1 is connected to the upper end of the lifting mechanism 2, the lower end of the lifting mechanism 2 is connected to the moving wheel 3, an axial rack 4 is arranged on the upper surface of the first sliding rail 1, and wing plates 5 are arranged on the opposite sides of the first sliding rail 1;

the bearing part comprises a bearing frame 6, a plurality of rail holding parts 7 and a plurality of hydraulic rods 8, wherein the lower end face of the bearing frame 6 is rotationally connected with a roller set 9, the roller set 9 is arranged on the upper surface of the first sliding rail 1 in a rolling way, the upper ends of the rail holding parts 7 are fixedly connected with the bearing frame 6, the lower ends of the rail holding parts 7 are hooked on the lower surface of the wing plates 5, the upper ends of the hydraulic rods 8 are respectively connected with the opposite side edges of the bearing frame 6, and the lower end face of the hydraulic rods 8 faces the ground and is used for jacking the bearing frame 6;

The driving mechanism is fixedly connected to the bearing frame 6, the output end of the driving mechanism is connected to the driving gear 10, and the driving gear 10 is meshed with the axial rack 4.

The working process of the portable mobile device of the large-scale equipment is as follows:

The bearing frame 6 is correspondingly arranged at the other end of the first sliding rail 1, meanwhile, the driving gear 10 is meshed with the axial rack 4, large equipment to be moved is arranged on the bearing frame 6, then oil is supplied to the hydraulic rods 8 through the hydraulic control system, the hydraulic rods 8 stretch, the lower ends of the hydraulic rods 8 are gradually grounded, the hydraulic rods 8 synchronously lift the bearing frame 6, the lower end of the rail holding part 7 applies force to the lower surface of the wing plate 5, and the middle section of the first sliding rail 1 is driven to rise; simultaneously, the lifting mechanism 2 is started, and one end of the first sliding rail 1 is lifted synchronously by the lifting mechanism 2, so that the whole first sliding rail 1 is kept horizontal and is separated from the ground by a certain distance.

At this time, the driving gear 10 is started in the forward direction, and the driving gear 10 drives the axial rack 4 and the first sliding rail 1 to move in the forward direction, so that one end of the first sliding rail 1 is gradually close to the bearing frame 6.

When one end of the first sliding rail 1 reaches the bearing frame 6, the driving gear 10 is stopped, then the hydraulic rods 8 shrink synchronously, the lower ends of the hydraulic rods 8 are separated from the ground, the lifting mechanism 2 lowers one end of the first sliding rail 1, and the first sliding rail 1 is integrally grounded. At this time, the driving gear 10 is reversely started, and the first slide rail 1 and the axial rack 4 are fixed relative to the ground, so that the driving gear 10 rolls towards the other end of the first slide rail 1, and the bearing frame 6 is driven to move towards the other end of the first slide rail 1.

In the technical scheme of the utility model, the device is used, the large equipment moves in place along with the bearing frame 6 at one time, and compared with the prior art, the device has higher efficiency of moving the large equipment and can not damage the ground.

Specifically, the roller set 9 includes two rows of rollers, and the axles of the two rows of rollers are rotatably connected to the lower end surface of the bearing frame 6.

Specifically, the rail holding component 7 is L-shaped, one end of the rail holding component 7 is welded to the lower end face of the bearing frame 6, and the other end of the rail holding component 7 is bent and extends to the lower surface of the wing plate 5.

In the embodiment shown in fig. 6, the device further comprises a plurality of carrying wheels 11, wherein each carrying wheel 11 is rotatably connected to the lower end of one of the rail holding parts 7, and the hub edge of the carrying wheel 11 is abutted against the lower surface of the wing plate 5.

In this embodiment, specifically, the plurality of hydraulic rods 8 lift up the bearing frame 6, after the whole first sliding rail 1 is lifted up and separated from the ground, the lower surface of the wing plate 5 of the first sliding rail 1 contacts with the edges of the hubs of the plurality of bearing wheels 11, so when the driving gear 10 drives the axial rack 4 to move, rolling friction is generated between the bearing wheels 11 and the wing plate 5 of the first sliding rail 1, the friction coefficient is smaller, and sliding friction is avoided between the wing plate 5 of the first sliding rail 1 and the lower end of the rail holding part 7.

As shown in fig. 3 and 4, in the specific embodiment, the driving mechanism is a hydraulic motor 12, the hydraulic motor 12 is fixedly mounted on the side surface of the carrying frame 6, and an output shaft of the hydraulic motor 12 is coaxially connected to the driving gear 10.

In this embodiment, specifically, the hydraulic motor 12 may rotate forward or reverse, so that the driving gear 10 may be driven to rotate forward or reverse, and at the same time, the hydraulic motor 12 outputs a large torque, which is suitable for heavy duty working conditions.

As shown in fig. 1 and 2, in a specific embodiment, the driving mechanism includes a driving motor 13, a driving wheel 14, and a driven wheel 15, where the driving motor 13 is fixedly installed on a side surface of the carrying frame 6, an output shaft of the driving motor 13 is coaxially linked to the driving wheel 14, the driven wheel 15 is coaxially connected to the driving gear 10, and the driving wheel 14 is in transmission connection with the driven wheel 15.

In this embodiment, specifically, the driving motor 13 is a stepper motor, the driving motor 13 drives the driving wheel 14 to rotate, the driving wheel 14 drives the driven wheel 15 to rotate, and the driven wheel 15 drives the driving gear 10 to rotate. The operator can control the rotation number of the driving gear 10 by only controlling the stepping angle of the stepping motor through the controller, thereby controlling the moving distance of the bearing frame 6 relative to the first sliding rail 1.

Specifically, the driven wheel 15 and the wheel shaft of the drive gear 10 are rotatably connected to the side of the carrier frame 6.

In a specific embodiment, the driving wheel 14 and the driven wheel 15 are respectively sprockets.

In the present embodiment, specifically, the driving pulley 14 and the driven pulley 15 are driven by a chain, and the linear speeds of rotation of each other are uniform.

Specifically, the diameter of the driving wheel 14 is smaller than that of the driven wheel 15, so that the rotation speed of the driving gear 10 is smaller than that of the driving motor 13, and the moving speed of the bearing frame 6 is prevented from being too high, and accidents caused by the too high moving speed of the bearing frame 6 are avoided.

As shown in fig. 1 to 6, in a specific embodiment, the lifting mechanism 2 is a hydraulic cylinder, the lower end of the hydraulic cylinder is fixedly connected to the bearing sleeve 16, and the wheel axle of the moving wheel 3 is mounted on the bearing sleeve 16 through a bearing.

In this embodiment, specifically, the cylinder body flange of the hydraulic cylinder is connected to the bearing beam 22 at one end of the first sliding rail 1, the piston rod flange of the hydraulic cylinder is connected to the wall of the bearing sleeve 16, and the piston rod of the hydraulic cylinder stretches and contracts to drive one end of the first sliding rail 1 to lift.

When the hydraulic rod 8 and the piston rod of the hydraulic cylinder are extended, the first slide rail 1 is lifted, the weight of the first slide rail 1 is applied to the moving wheel 3, and when the first slide rail 1 horizontally slides, the moving wheel 3 rolls to assist the first slide rail 1 to move relative to the ground.

As shown in fig. 1 to 6, in a specific embodiment, the sliding device further includes a plurality of second sliding rails 17, the other end of the first sliding rail 1 and one end of the second sliding rail 17 are respectively provided with a slot 18, the other end of the second sliding rail 17 is provided with a socket block 19, the socket block 19 is anastomosed to the slot 18, a first pin hole 20 is provided on a side surface of the socket block 19, a second pin hole 21 is provided on a side wall of the slot 18, and the second pin hole 21 corresponds to the first pin hole 20 and is used for inserting a pin shaft.

In this embodiment, specifically, after the socket block 19 and the slot 18 are mutually matched, the first pin hole 20 and the second pin hole 21 correspond to each other, and the pin shaft is sequentially inserted into the first pin hole 20 and the second pin hole 21, so that the connection relationship between the first slide rail 1 and the plurality of second slide rails 17 is fixed, and the distance that the large-scale equipment can move is conveniently prolonged.

For example, the first rail 1 is only fifty meters, but after the second rail 17 is connected to the first rail of fifty meters, the large-sized device can be moved by one hundred meters.

The foregoing is merely illustrative of the present utility model, and the present utility model is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present utility model. Therefore, the protection scope of the present utility model shall be subject to the protection scope of the claims.

Claims (7)

1. A portable mobile device for a large facility, comprising:

The lifting mechanism comprises a first sliding rail, wherein one end of the first sliding rail is connected to the upper end of the lifting mechanism, the lower end of the lifting mechanism is connected to the moving wheel, an axial rack is arranged on the upper surface of the first sliding rail, and wing plates are arranged on the opposite sides of the first sliding rail;

The bearing part comprises a bearing frame, a plurality of rail holding parts and a plurality of hydraulic rods, wherein the lower end face of the bearing frame is rotationally connected with a roller set, the roller set is arranged on the upper surface of the first sliding rail in a rolling way, the upper ends of the rail holding parts are fixedly connected with the bearing frame, the lower ends of the rail holding parts are hooked on the lower surfaces of the wing plates, the upper ends of the hydraulic rods are respectively connected with the opposite side edges of the bearing frame, and the lower end faces the ground and is used for jacking the bearing frame;

The driving mechanism is fixedly connected to the bearing frame, the output end of the driving mechanism is connected to a driving gear, and the driving gear is meshed with the axial rack.

2. The portable mobile device of claim 1 wherein,

The rail clamping device further comprises a plurality of bearing wheels, each bearing wheel is rotatably connected to the lower end of one rail clamping component, and the hub edge of each bearing wheel is propped against the lower surface of each wing plate.

3. The portable mobile device of claim 1 wherein,

The driving mechanism is a hydraulic motor, the hydraulic motor is fixedly arranged on the side face of the bearing frame, and an output shaft of the hydraulic motor is coaxially connected with the driving gear.

4. The portable mobile device of claim 1 wherein,

The driving mechanism comprises a driving motor, a driving wheel and a driven wheel, wherein the driving motor is fixedly arranged on the side face of the bearing frame, an output shaft of the driving motor is coaxially linked with the driving wheel, the driven wheel is coaxially connected with the driving gear, and the driving wheel is in transmission connection with the driven wheel.

5. The portable mobile device of claim 4 wherein,

The driving wheel and the driven wheel are respectively chain wheels.

6. The portable mobile device of claim 1 wherein,

The lifting mechanism is a hydraulic cylinder, the lower end of the hydraulic cylinder is fixedly connected with a bearing sleeve, and an axle of the movable wheel is mounted on the bearing sleeve through a bearing.

7. The portable large-scale equipment moving apparatus according to any one of claims 1 to 6, wherein,

The novel sliding rail comprises a plurality of first sliding rails, and is characterized by further comprising a plurality of second sliding rails, wherein slots are respectively arranged at the other end of the first sliding rail and one end of the second sliding rail, a socket block is arranged at the other end of the second sliding rail and is anastomotic with the slots, first pin holes are formed in the side faces of the socket block, second pin holes are formed in the side walls of the slots and correspond to the first pin holes, and pin shafts are inserted into the second pin holes.