CN113415733A

CN113415733A - Large-scale storage tank jack-up lifting device of industry

Info

Publication number: CN113415733A
Application number: CN202110971156.4A
Authority: CN
Inventors: 于卫新; 贾蒙; 王广龙; 曹鋆汇; 郝艺萌; 李悦
Original assignee: Xinxiang University
Current assignee: Xinxiang University
Priority date: 2021-08-24
Filing date: 2021-08-24
Publication date: 2021-09-21
Anticipated expiration: 2041-08-24
Also published as: CN113415733B

Abstract

The invention relates to the field of hoisting, in particular to a hoisting device for a large industrial storage tank. The technical problem of the invention is that: in the hoisting process of the large glass fiber reinforced plastic storage tank, the large glass fiber reinforced plastic storage tank is difficult to be quickly positioned and hoisted. An industrial large-scale storage tank hoisting device comprises a portal crane system, a fiber separation system, a guide normal position system and a positioning lowering system; a fiber separation system is arranged on the left side in the portal crane system; and a guide righting system is arranged on the right side of the gantry crane system. The invention realizes the effects of automatically hoisting the glass fiber reinforced plastic storage tank, automatically guiding and conveying the glass fiber reinforced plastic storage tank to the position right above the installation position, realizing small-angle rotation of the glass fiber reinforced plastic storage tank to enable the glass fiber reinforced plastic storage tank to be aligned with the installation position, temporarily positioning and lowering the two sides of the glass fiber reinforced plastic storage tank, and enabling the glass fiber reinforced plastic storage tank to be hoisted in a normal position and lowered to the position to be installed.

Description

Large-scale storage tank jack-up lifting device of industry

Technical Field

The invention relates to the field of hoisting, in particular to a hoisting device for a large industrial storage tank.

Background

At present, in the process of hoisting a large glass fiber reinforced plastic storage tank in the prior art, the large glass fiber reinforced plastic storage tank needs to be hoisted by a crane and is upwards pulled away from the outer side of a fixed inner cylinder, then the crane needs to adjust the position for many times after hoisting the glass fiber reinforced plastic storage tank, so that the tank body can move right above the installation position, the operation is complicated, the consumed time is long, when the tank body is placed down, the glass fiber reinforced plastic tank body needs a plurality of operators to surround the periphery of the glass fiber reinforced plastic storage tank to assist in making the glass fiber reinforced plastic storage tank be in the right position, the glass fiber reinforced plastic storage tank can be placed down successfully after the angles and the positions are adjusted for many times, and more than ten hours are consumed; in addition, a large amount of glass fibers exist at the bottom of the glass fiber reinforced plastic storage tank, the glass fibers at the bottom of the glass fiber reinforced plastic storage tank need to be manually removed, and the operation is complex.

In order to solve the problems, the hoisting equipment for the industrial large storage tank is provided.

Disclosure of Invention

The technical problem of the invention is that: in order to overcome the defects that in the prior art, a crane needs to adjust the position for many times after lifting the glass fiber reinforced plastic storage tank, so that the tank body can move right above the installation position, the operation is complicated, the consumed time is long, when the tank body is lowered, the glass fiber reinforced plastic tank body needs a plurality of operators to surround the periphery of the glass fiber reinforced plastic storage tank to assist in righting the glass fiber reinforced plastic storage tank, the glass fiber reinforced plastic storage tank can be successfully lowered after the angles and the positions are adjusted for many times, and more than ten hours are consumed; in addition, a large amount of glass fibers exist at the bottom of the glass fiber reinforced plastic storage tank, and the glass fibers at the bottom of the glass fiber reinforced plastic storage tank need to be manually cleaned.

An industrial large-scale storage tank hoisting device comprises a portal crane system for hoisting and transferring a glass fiber reinforced plastic storage tank, wherein the portal crane system comprises a first movable support steel rail; the fiber separation device also comprises a fiber separation system, a guiding and righting system and a positioning and lowering system; a fiber separation system for performing glass fiber separation on the glass fiber storage tank is arranged on the middle left side between the two first movable supporting steel rails; a guide righting system for movably guiding the glass fiber reinforced plastic storage tank is arranged on the right side of the two first movable supporting steel rails; a set of location system of transferring the location is supplementary is transferred to glass steel storage tank respectively to direction normal position system right front side and right back side is installed.

Further explaining, the guiding and righting system comprises a mounting frame, a mounting portal frame, a first guiding roller group, a second electric sliding assembly, a fourth electric sliding seat, a third electric sliding assembly, a third electric sliding seat and an adjusting contact plate; the right sides of the two first movable supporting steel rails are provided with installation racks; the front side of the top of the mounting frame and the rear side of the top are respectively fixedly connected with a mounting portal frame; the upper parts of the two installation portal frames are respectively provided with a first guide roller group; the middle upper parts of the two installation portal frames are respectively provided with a second guide roller group; the upper sides of the two installation portal frames are respectively provided with a second electric sliding assembly; the two second electric sliding assemblies are respectively connected with a fourth electric sliding seat in a sliding manner; a third electric sliding assembly is arranged between the two fourth electric sliding seats; the left side of the third electric sliding assembly is connected with a third electric sliding seat in a sliding manner; an adjusting contact plate is arranged on the left side of the third electric sliding seat; a group of positioning and lowering systems are respectively installed on the upper sides of the two installation portal frames.

Further explaining, the positioning and lowering system comprises a fourth electric sliding assembly, a fifth electric sliding seat, a sixth electric sliding seat, an installation bottom frame, a connecting vertical frame plate, a connecting transverse plate, a first control insertion rod, an L-shaped connecting rod, a second control insertion rod, an electric telescopic assembly, a pushing clamping plate, a connecting side column, a stabilizing clamping rod, a second reset elastic piece and a sliding sleeve frame; the upper sides of the two installation portal frames are respectively provided with a fourth electric sliding assembly; the two fourth electric sliding assemblies are respectively connected with a fifth electric sliding seat in a sliding manner; the two fourth electric sliding assemblies are respectively connected with a sixth electric sliding seat in a sliding manner; the top parts of the fifth electric sliding seat and the sixth electric sliding seat on each fourth electric sliding assembly are connected with an installation underframe; the right sides of the tops of the two mounting bottom frames are respectively fixedly connected with a connecting vertical frame; the left sides of the tops of the two mounting bottom frames are respectively fixedly connected with a connecting vertical frame plate; a connecting transverse plate is fixedly connected to the top between the adjacent connecting vertical frames and the connecting vertical frame plates; the top parts of the two connecting transverse plates are respectively fixedly inserted with a first control insertion rod; the upper part of the outer surface of the first control inserted rod is respectively connected with an L-shaped connecting rod in a rotating way; the two vertical connecting frame plates are respectively connected with a sliding sleeve frame in a sliding way; the inner sides of the two sliding sleeve frames are respectively connected with a connecting side column in a sliding way; the tops of the two connecting side columns are fixedly inserted with a second control inserted rod respectively; the two L-shaped connecting rods are respectively connected with a second control inserted rod in a transmission way; the two connecting vertical frame plates are respectively provided with an electric telescopic component; the tops of the two connecting side columns are respectively fixedly connected with a pushing clamping plate; the bottoms of the two connecting vertical frame plates are respectively fixedly connected with a second reset elastic piece; the tops of the two second reset elastic pieces are fixedly connected with a sliding sleeve frame; two connecting side columns are respectively and fixedly connected with a stable clamping rod.

Further described, the fiber separation system includes an organic base plate, an alarm, a protective enclosure, a separation assembly, and a position adjustment assembly; a bottom plate is arranged on the middle left side between the two first movable supporting steel rails; four corners of the top of the bottom plate of the machine are respectively provided with an alarm; four edges of the top of the bottom plate of the machine are provided with continuous protective fences; the top of the bottom plate of the machine is provided with a separation component; the top of the bottom plate of the machine is provided with a position adjusting component.

Further explaining, the position adjusting assembly comprises a mounting frame seat, a first electric sliding assembly, a first electric sliding seat, a mounting connecting frame, an outer ring, an annular sliding assembly and an outward turning assembly; the front side of the top of the bottom plate and the rear side of the top of the bottom plate are respectively provided with an installation frame seat; two first electric sliding assemblies are respectively arranged at the tops of the two mounting frame seats; two adjacent first electric sliding assemblies are connected with a first electric sliding seat in a sliding manner; the two first electric sliding seats are respectively fixedly connected with an installation connecting frame; the upper parts of the two mounting connecting frames are provided with outer rings; the upper parts of the inner sides of the two mounting connecting frames are provided with annular sliding components; the inner side of the annular sliding component is connected with a fixing component in a sliding way.

Further, the outward turning assembly comprises a second electric sliding seat, a first electric rotating shaft seat, a first mounting connecting rod, a first fixing rod, a rotating shaft rod, a second mounting connecting rod, a first reset elastic element, a second fixing rod, a third mounting connecting rod, a first bearing frame strip, a fourth mounting connecting rod, a second bearing frame strip, a second electric rotating shaft seat, a fifth mounting connecting rod and a first pressing strip; the inner side of the annular sliding assembly is connected with a second electric sliding seat in a sliding manner; a first electric rotating shaft seat is arranged at the rear part of the second electric sliding seat; the rotating ends at two sides of the first electric rotating shaft seat are respectively provided with a first mounting connecting rod; the lower parts of the two first mounting connecting rods are fixedly connected with first fixing rods; the middle parts of the two first mounting connecting rods are fixedly connected with a rotating shaft lever; two sides of the outer surface of the rotating shaft lever are respectively and rotatably connected with a second mounting connecting rod; the middle parts of the two second mounting connecting rods are respectively provided with a first reset elastic piece; the tops of the two first resetting elastic pieces are respectively connected with a first mounting connecting rod; the lower parts of the two second mounting connecting rods are fixedly connected with second fixing rods; a third mounting connecting rod is fixedly connected to each of two sides of the second fixing rod; a first bearing frame strip is fixedly connected to the rear sides of the two third mounting connecting rods; a fourth mounting connecting rod is fixedly connected to each of two sides of the first fixing rod; the middle parts of the tops of the two fourth mounting connecting rods are fixedly connected with second bearing frame strips; the middle parts of the front sides of the two fourth mounting connecting rods are respectively provided with a second electric rotating shaft seat; the middle parts of the rear sides of the two fourth mounting connecting rods are respectively provided with a second electric rotating shaft seat; the rotating ends of the four second electric rotating shaft seats are fixedly connected with a fifth mounting connecting rod respectively; the top parts of two fifth mounting connecting rods positioned at the front sides of the two fourth mounting connecting rods are fixedly connected with a first pressing strip; and a first pressing strip is fixedly connected to the tops of the two fifth mounting connecting rods positioned at the rear sides of the two fourth mounting connecting rods.

Further, the bottom of the first pressing strip is provided with a plurality of trapezoidal slots.

Further explaining, the separating component comprises a power motor, a first rotating shaft rod, a bearing seat, a first bevel gear, a bearing seat plate, a mounting top plate, a second rotating shaft rod, a first transmission wheel, a second bevel gear, a second transmission wheel, a third rotating shaft rod, a third transmission wheel, a first flat gear, a mounting disc, a fourth rotating shaft rod, a fourth transmission wheel, a second flat gear, a first conical rod, a second conical rod and a rotating sleeve seat; a power motor is fixedly connected to the left rear side of the top of the bottom plate of the machine; a first rotating shaft rod is fixedly connected with an output shaft of the power motor; a bearing seat is fixedly connected to the left side of the top of the bottom plate of the machine; the bearing seat is rotationally connected with the first rotating shaft rod; a first bevel gear is fixedly sleeved on the front side of the outer surface of the first rotating shaft rod; a bearing frame plate is fixedly connected to the left front side of the top of the bottom plate of the machine; the bearing frame plate is rotationally connected with the first rotating shaft rod; the top of the bottom plate of the machine is fixedly connected with a mounting top plate; the upper part of the rear side of the bearing frame plate is rotatably connected with a second rotating shaft rod; a first driving wheel and a second bevel gear are fixedly connected to the outer surface of the second rotating shaft rod in sequence; the second bevel gear is meshed with the first bevel gear; the middle part of the top of the base plate of the machine is fixedly connected with an installation plate; the top of the mounting disc is connected with a mounting top plate; the top of the mounting disc is rotatably connected with a third rotating shaft rod; a second driving wheel, a third driving wheel and a first flat gear are fixedly connected to the outer surface of the third rotating shaft rod in sequence; the outer ring surface of the second driving wheel is in transmission connection with the first driving wheel through a belt; the mounting top plate is rotatably connected with a third rotating shaft rod; the middle part of the top of the mounting disc is rotatably connected with a fourth rotating shaft rod; a fourth driving wheel is fixedly connected to the outer surface of the fourth rotating shaft rod; the front side of the mounting top plate is rotationally connected with a rotating sleeve seat; a second flat gear is fixedly sleeved on the lower side of the outer surface of the rotary sleeve seat; the second spur gear is meshed with the first spur gear; the inner side of the rotary sleeve seat is rotatably connected with a fourth rotating shaft rod; the upper side of the outer surface of the fourth rotating shaft rod is symmetrically and fixedly inserted with a first conical prick rod; the upper side of the outer surface of the rotary sleeve seat is symmetrically and fixedly inserted with a second taper rod.

Further, the pricks on the two sides of the outer surface of the first prick rod are inclined downwards, and the pricks on the two sides of the outer surface of the second prick rod are inclined upwards.

The invention has the beneficial effects that: in order to solve the problems that in the prior art, a crane is needed to lift the large glass fiber reinforced plastic storage tank and pull the large glass fiber reinforced plastic storage tank upwards from the outer side of the fixed inner cylinder, and then the crane needs to adjust the position for many times after lifting the glass fiber reinforced plastic storage tank, so that the tank body can move right above the installation position, the operation is complicated, the consumed time is long, when the tank body is placed down, the glass fiber reinforced plastic tank body needs a plurality of operators to surround the glass fiber reinforced plastic storage tank to assist in keeping the glass fiber reinforced plastic storage tank in the right position, the glass fiber reinforced plastic storage tank body can be placed down successfully after the angles and the positions are adjusted for many times, and the consumption is often over ten hours; in addition, a large amount of glass fibers exist at the bottom of the glass fiber reinforced plastic storage tank, and the glass fibers at the bottom of the glass fiber reinforced plastic storage tank need to be manually removed, so that the operation is complicated;

a portal crane system is designed, so that the automatic hoisting of the glass fiber reinforced plastic storage tank is realized;

a fiber separation system is designed, and glass fibers at the bottom of the glass fiber reinforced plastic storage tank are separated in the automatic hoisting and transferring process of the glass fiber reinforced plastic storage tank;

the guide positioning system is designed to automatically guide and convey the glass fiber reinforced plastic storage tank, so that the problem that the position needs to be adjusted for multiple times to be matched with the installation in the conventional hoisting process is solved, the glass fiber reinforced plastic storage tank is automatically guided and conveyed to the position right above the installation position, and small-angle rotation of the glass fiber reinforced plastic storage tank is realized, so that the glass fiber reinforced plastic storage tank is aligned to the installation position;

the location is transferred the system, carries out the temporary location to glass steel storage tank both sides and transfers for glass steel storage tank can just hoist and mount and transfer to the effect that will carry out the position of installing.

Drawings

FIG. 1 is a schematic front, upper left perspective view of the present invention;

FIG. 2 is a right upper right perspective view of the present invention;

FIG. 3 is a schematic perspective view of a gantry crane system according to the present invention;

FIG. 4 is a schematic perspective view of a fiber separation system of the present invention;

FIG. 5 is a perspective view of the position adjustment assembly of the present invention;

figure 6 is a schematic view of a first three-dimensional configuration of the valgus module according to the invention;

figure 7 is a schematic view of a second perspective configuration of the valgus module according to the invention;

figure 8 is a schematic partial perspective view of the valgus module of the present invention;

FIG. 9 is a schematic perspective view of a first embodiment of the separator assembly of the present invention;

FIG. 10 is a schematic view of a second perspective view of the separator assembly of the present invention;

FIG. 11 is a perspective view of the guiding and aligning system of the present invention;

FIG. 12 is a schematic view of a first perspective of the positioning lowering system of the present invention;

FIG. 13 is a schematic view of a second embodiment of the positioning lowering system of the present invention;

FIG. 14 is a schematic view of the front upper assembled perspective structure of the guiding righting system and the positioning lowering system of the present invention;

fig. 15 is a schematic view of the front upper combined space structure of the guiding righting system and the positioning lowering system of the present invention.

In the above drawings: 1-gantry crane system, 2-fiber separation system, 3-guide righting system, 4-position lowering system, 101-first movable support rail, 102-movable support assembly, 103-lifting beam, 104-transverse movable assembly, 105-hook assembly mount, 201-machine base plate, 202-alarm, 203-guard fence, 204-motor power, 205-first rotating shaft rod, 206-bearing base, 207-first bevel gear, 208-bearing frame plate, 209-mounting top plate, 2010-second rotating shaft rod, 2011-first driving wheel, 2012-second bevel gear, 2013-second driving wheel, 2014-third rotating shaft rod, 2015-third driving wheel, 2016-first flat gear, 2017-mounting plate, 2018-a fourth rotating shaft rod, 2019-a fourth transmission wheel, 2020-a second flat gear, 2021-a first prick bar, 2022-a second prick bar, 2023-a mounting frame seat, 2024-a first electric sliding component, 2025-a first electric sliding seat, 2026-a mounting connecting frame, 2027-an outer ring, 2028-a ring sliding component, 2029-a second electric sliding seat, 2030-a first electric rotating shaft seat, 2031-a first mounting connecting rod, 2032-a first fixing rod, 2033-a rotating shaft rod, 2034-a second mounting connecting rod, 2035-a first restoring elastic component, 2036-a second fixing rod, 2037-a third mounting connecting rod, 2038-a first receiving frame strip, 2039-a fourth mounting connecting rod, 2040-a second receiving frame strip, 2041-a second electric rotating shaft seat, 2042-a fifth mounting connecting rod, 2043-a first pressing strip, 2044-a rotating sleeve seat, 301-an installation frame, 302-an installation portal frame, 303-a first guide roller group, 304-a second guide roller group, 305-a second electric sliding component, 306-a fourth electric sliding seat, 307-a third electric sliding component, 308-a third electric sliding seat, 309-an adjustment contact plate, 401-a fourth electric sliding component, 402-a fifth electric sliding seat, 403-a sixth electric sliding seat, 404-an installation underframe, 405-a connecting vertical frame, 406-a connecting vertical frame plate, 407-a connecting transverse plate, 408-a first control inserted bar, 409-L-shaped connecting rods, 4010-a second control inserted bar, 4011-an electric telescopic component, 4012-a pushing clamping plate and 4013-a connecting side column, 4014-stabilizing clamping bar, 4015-second restoring spring, 4016-sliding sleeve.

Detailed Description

The present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which presently preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided for completeness and fully convey the scope of the invention to the skilled person.

Example 1

According to the drawings of fig. 1-2, the lifting device for the industrial large-scale storage tank comprises a portal crane system 1, a fiber separation system 2, a guiding normal position system 3 and a positioning lowering system 4; the fiber separation system 2 is arranged at the left part in the portal crane system 1; the right part of the gantry crane system 1 is provided with a guide righting system 3; and a group of positioning lowering systems 4 are respectively arranged on the front side and the rear side of the guiding righting system 3.

When using, at first with the fixed position to carrying out the storage tank installation of the equipment of the large-scale storage tank jack-up lifting device of industry, make two sets of location transfer system 4 be located the both sides of storage tank mounted position respectively, with lifting hook group installation to gantry crane system 1, then the staff starts the vehicle and stops large-scale glass steel storage tank normal position in gantry crane system 1 below, then control gantry crane system 1 upwards mentions the glass steel storage tank, the glass steel storage tank upwards moves and breaks away from fixed inner tube, then control gantry crane system 1 drives the glass steel storage tank and moves to fibre piece-rate system 2 top, and then fibre piece-rate system 2 separates the glass fibre of glass steel storage tank bottom, guarantee the clean and tidy of its bottom.

Then continue control portal crane system 1 and drive glass steel storage tank motion to direction normal position system 3, the normal position system 3 of direction leads glass steel storage tank this moment promptly, makes it can not incline, after waiting to move to the top of mounted position, the normal position system 3 of direction is controlled again and is rotated the accent to it, waits to rotate to suitable angle, and portal crane system 1 is controlled again and transfers glass steel storage tank, and the system 4 is transferred in the location to glass steel storage tank location simultaneously and transfers.

Realized the automatic hoist and mount to glass steel storage tank, the glass fiber separation of its bottom in the automatic transfer process that lifts up of glass steel storage tank, carry out the automatic direction conveying to glass steel storage tank, the problem of the adjustment position of many times cooperation installation has been solved in the conventional hoist and mount process, convey to the mounted position directly over to glass steel storage tank automatic direction, and realize glass steel storage tank small-angle and rotate, make it aim at the mounted position, and carry out the temporary location to glass steel storage tank both sides and transfer, make glass steel storage tank can transfer the effect of the position that will carry out the installation by normal hoist and mount.

Example 2

On the basis of the embodiment 1, as shown in fig. 3, the gantry crane system 1 includes a first movable support rail 101, a movable support assembly 102, a lifting beam 103, a transverse moving assembly 104 and a hook assembly mount 105; a movable support component 102 is movably arranged on the left side of the top of each of the two first movable support steel rails 101; the top parts of the two movable supporting components 102 are provided with hoisting beams 103; the middle part of the bottom of the hoisting beam 103 is provided with a transverse moving assembly 104; the bottom of the transverse moving assembly 104 is slidably connected with a hook assembly mounting seat 105; a fiber separation system 2 is arranged on the middle left side between the two first movable supporting steel rails 101; the right sides of the two first movable support rails 101 are provided with a guide righting system 3.

Firstly, the hook assembly is arranged on the hook assembly mounting seat 105, the transverse moving assembly 104 is controlled to drive the hook assembly mounting seat 105 to move to a proper position, then a power mechanism in the lifting hook component mounting seat 105 is controlled to drive the lifting hook group to move downwards to hook the steel wire rope group fixed at the top of the glass fiber reinforced plastic storage tank, then the power mechanism in the mounting seat 105 of the hook component is controlled to drive the hook to move upwards, then the glass fiber reinforced plastic storage tank is lifted upwards, the glass fiber reinforced plastic storage tank moves upwards to be separated from the fixed inner cylinder, then the two movable support assemblies 102 are controlled to drive the lifting cross beam 103 to move, namely, the two movable supporting components 102 move towards the fiber separating system 2 at the tops of the two first movable supporting rails 101 respectively, and then the lifting hook below the lifting hook component mounting seat 105 drives the glass fiber reinforced plastic storage tank to move to the upper part of the fiber separation system 2, and the preliminary lifting of the glass fiber reinforced plastic storage tank is completed.

Example 3

On the basis of example 2, according to fig. 4-10, the defibration system 2 comprises an organic base plate 201, an alarm 202, a guard fence 203, a separation assembly and a position adjustment assembly; a bottom plate 201 is arranged at the middle left side between the two first movable supporting steel rails 101; four corners of the top of the bottom plate 201 are respectively provided with an alarm 202; four edges at the top of the bottom plate 201 are provided with continuous protective fences 203; the top of the bottom plate 201 is provided with a separating component; the top of the base plate 201 is provided with a position adjusting assembly.

Glass steel storage tank is shifted to 2 tops of fibre separation system, the unnecessary glass fibre of glass steel storage tank bottom can fall into position adjustment subassembly downwards, the position adjustment subassembly adjusts the location to the glass fibre of glass steel storage tank bottom promptly, then control the glass fibre separation of separation subassembly with glass steel storage tank bottom, siren 202 sends the light suggestion site operation personnel and will not be close to in the separation, protect rail 203 to surround the protection in its work outside simultaneously, avoid taking place the accident.

The position adjusting component comprises a mounting frame seat 2023, a first electric sliding component 2024, a first electric sliding seat 2025, a mounting connecting frame 2026, an outer ring 2027, an annular sliding component 2028 and an outward turning component; the front side of the top part and the rear side of the top part of the bottom plate 201 are respectively provided with an installation frame base 2023; two first electric sliding assemblies 2024 are respectively arranged at the tops of the two mounting frame seats 2023; two adjacent first electric sliding assemblies 2024 are connected with first electric sliding seats 2025 in a sliding manner; the two first electric sliding seats 2025 are respectively fixedly connected with an installation connecting frame 2026; the upper parts of the two mounting connecting frames 2026 are provided with outer rings 2027; the upper parts of the inner sides of the two mounting connecting frames 2026 are provided with annular sliding assemblies 2028; the inner side of the annular sliding component 2028 is slidably connected with a fixing component.

The glass fiber reinforced plastic storage tank is transferred to the upper part of the fiber separating system 2, at this time, the first electric sliding assemblies 2024 are controlled to drive the first electric sliding seats 2025 to move upwards, and then the two first electric sliding seats 2025 drive the mounting connecting frame 2026, the outer ring 2027, the annular sliding assemblies 2028 and the outward turning assemblies to move upwards, at this time, due to the existence of natural wind, the glass fibers at the bottom of the glass fiber reinforced plastic storage tank can tilt and flap, then a part of the glass fibers are far away from the circle center of the outer ring 2027, and the other part of the glass fibers are close to the circle center of the outer ring 2027, and when the outer ring 2027 and the annular sliding assemblies 2028 move upwards, namely, the glass fibers far away from the circle center of the outer ring 2027 move to the gap between the outer ring 2027 and the annular sliding assemblies 2028, and then the other part of the glass fibers close to the circle center of the outer ring 2027 fall into the circular area in the middle of the annular sliding assemblies 2028, and at this time, the outward turning assemblies are controlled to fall to the outside of the glass fibers in the circular area in the middle of the annular sliding assemblies 2028 Turned into the gap between the outer ring 2027 and the annular slide assembly 2028.

The outward turning component comprises a second electric sliding seat 2029, a first electric rotating shaft seat 2030, a first mounting connecting rod 2031, a first fixing rod 2032, a rotating shaft rod 2033, a second mounting connecting rod 2034, a first reset elastic element 2035, a second fixing rod 2036, a third mounting connecting rod 2037, a first bearing frame strip 2038, a fourth mounting connecting rod 2039, a second bearing frame strip 2040, a second electric rotating shaft seat 2041, a fifth mounting connecting rod 2042 and a first pressing strip 2043; a second electric sliding seat 2029 is connected to the inner side of the annular sliding assembly 2028 in a sliding manner; the rear part of the second electric sliding seat 2029 is provided with a first electric rotating shaft seat 2030; the rotating ends at the two sides of the first electric rotating shaft seat 2030 are respectively provided with a first mounting connecting rod 2031; the lower parts of the two first mounting connecting rods 2031 are fixedly connected with first fixing rods 2032; a rotating shaft rod 2033 is fixedly connected to the middle parts of the two first mounting connecting rods 2031; two sides of the outer surface of the rotating shaft rod 2033 are respectively connected with a second mounting connecting rod 2034 in a rotating way; a first reset elastic piece 2035 is respectively arranged in the middle of each of the two second mounting connecting rods 2034; the tops of the two first return elastic members 2035 are respectively connected with a first mounting link 2031; the lower parts of the two second mounting connecting rods 2034 are fixedly connected with second fixing rods 2036; a third mounting connecting rod 2037 is fixedly connected to each of the two sides of the second fixing rod 2036; a first bearing frame strip 2038 is fixedly connected to the rear side of the two third mounting connecting rods 2037; a fourth mounting connecting rod 2039 is fixedly connected to each of the two sides of the first fixing rod 2032; a second bearing frame strip 2040 is fixedly connected to the middle of the tops of the two fourth mounting connecting rods 2039; a second electric rotating shaft seat 2041 is respectively arranged in the middle of the front side and the middle of the rear side of each of the two fourth mounting connecting rods 2039; the rotating ends of the four second electric rotating shaft seats 2041 are respectively and fixedly connected with a fifth mounting connecting rod 2042; the top of each of the four fifth mounting links 2042 is fixedly connected to a first pressing bar 2043.

After the glass fiber near the center of the outer ring 2027 falls to the circular area in the middle of the annular sliding assembly 2028, the annular sliding assembly 2028 is controlled to drive the second electric sliding seat 2029 to move, that is, the second electric sliding seat 2029 drives the entire outward turning assembly to move to the position of the glass fiber, at this time, the glass fiber is located above the outward turning assembly, the first pressing bar 2043 is in a state of being opened to both sides in the initial state, then the glass fiber drops on the top of the second receiving frame strip 2040 and one side of the first receiving frame strip 2038, the second electric spindle seat 2041 is controlled to drive the fifth mounting link 2042 and the first pressing bar 2043 to move, that is, the two first pressing bars 2043 are combined, then the glass fiber is simply clamped, the glass fiber is fixed to the inner side of the second receiving frame strip 2040, then the first electric spindle seat 2030 is controlled to rotate upward, and further the first electric spindle seat drives the

first mounting link

2031, 2030, A first fixing rod 2032, a rotating shaft rod 2033, a second mounting link 2034, a first elastic restoring element 2035, a second fixing rod 2036, a third mounting link 2037, a first receiving frame strip 2038, a fourth mounting link 2039, a second receiving frame strip 2040, a second electric spindle seat 2041, a fifth mounting link 2042 and a first pressing strip 2043 are turned upwards integrally, so that the glass fiber is turned upwards and is turned outside the annular sliding assembly 2028, at this time, the second electric spindle seat 2041 is controlled to drive the fifth mounting link 2042 and the first pressing strip 2043 to be opened, namely, the glass fiber is not bound any more, and then the glass fiber is thrown out to a gap between the annular sliding assembly 2028 and the outer ring 2027, when the first electric spindle seat 2030 is controlled to stop rotating, the two first mounting links 1 stop rotating, at this time, the two first elastic restoring elements 2035 are compressed, so as to realize the second mounting link 2034, The rotation of the first elastic reset member 2035, the second fixing rod 2036, the third mounting link 2037 and the first receiving frame strip 2038 stops buffering, so that the first receiving frame strip 2038 shakes to shake and separate the glass fibers downwards, and then the glass fibers all fall into the annular region between the outer ring 2027 and the annular sliding assembly 2028.

A plurality of trapezoidal slots are formed in the bottom of the first compressing strip 2043.

So that the first pressing strip 2043 can clamp the glass fibers at the bottom thereof.

The separating assembly comprises a power motor 204, a first rotating shaft rod 205, a bearing seat 206, a first bevel gear 207, a bearing frame plate 208, a mounting top plate 209, a second rotating shaft rod 2010, a first driving wheel 2011, a second bevel gear 2012, a second driving wheel 2013, a third rotating shaft rod 2014, a third driving wheel 2015, a first flat gear 2016, a mounting plate 2017, a fourth rotating shaft rod 2018, a fourth driving wheel 2019, a second flat gear 2020, a first awl rod 2021, a second awl rod 2022 and a rotating sleeve seat 2044; the left rear side bolt at the top of the bottom plate 201 is connected with a power motor 204; a first rotating shaft rod 205 is fixedly connected with an output shaft of the power motor 204; a bearing seat 206 is connected to the left side of the top of the bottom plate 201 through a bolt; the bearing housing 206 is rotatably connected to the first spindle shaft 205; a first bevel gear 207 is fixedly sleeved on the front side of the outer surface of the first rotating shaft rod 205; a bearing frame plate 208 is connected to the left front side bolt at the top of the bottom plate 201; the bearing frame plate 208 is rotatably connected with the first rotating shaft rod 205; a mounting top plate 209 is fixedly connected to the top of the bottom plate 201; a second rotating shaft rod 2010 is rotatably connected to the upper part of the rear side of the bearing frame plate 208; a first driving wheel 2011 and a second bevel gear 2012 are fixedly connected to the outer surface of the second rotating shaft rod 2010 in sequence; second bevel gear 2012 engages first bevel gear 207; a mounting plate 2017 is welded in the middle of the top of the bottom plate 201; the top of the mounting plate 2017 is connected with a mounting top plate 209; the top of the mounting plate 2017 is rotatably connected with a third rotating shaft 2014; a second driving wheel 2013, a third driving wheel 2015 and a first flat gear 2016 are fixedly connected to the outer surface of the third rotating shaft 2014 in sequence; the outer ring surface of the second driving wheel 2013 is in transmission connection with a first driving wheel 2011 through a belt; the mounting top plate 209 is rotatably connected to the third shaft 2014; the middle of the top of the mounting plate 2017 is rotatably connected with a fourth rotating shaft rod 2018; a fourth driving wheel 2019 is fixedly connected to the outer surface of the fourth rotating shaft rod 2018; a rotary sleeve seat 2044 is rotatably connected to the front side of the mounting top plate 209; a second flat gear 2020 is fixedly sleeved on the lower side of the outer surface of the rotating sleeve seat 2044; the second spur gear 2020 engages the first spur gear 2016; the inner side of the rotating sleeve seat 2044 is rotatably connected with a fourth rotating shaft rod 2018; a first prick rod 2021 is symmetrically and fixedly inserted on the upper side of the outer surface of the fourth rotating shaft rod 2018; a second taper rod 2022 is symmetrically fixed and inserted on the upper side of the outer surface of the rotating sleeve seat 2044.

When the glass fibers all fall into the annular area between the outer ring 2027 and the annular sliding assembly 2028, the power of the joint power motor 204 is controlled, that is, the power motor 204 drives the first rotating shaft rod 205 to rotate, then the first rotating shaft rod 205 drives the first bevel gear 207 to rotate, further the first bevel gear 207 drives the second bevel gear 2012 to rotate, then the second bevel gear 2012 drives the second rotating shaft rod 2010 to rotate, then the second rotating shaft rod 2010 drives the first driving wheel 2011 to rotate, then the first driving wheel 2011 drives the second driving wheel 2013 to rotate, further the second driving wheel 2013 drives the third rotating shaft rod 2014 to rotate, then the third rotating shaft 2014 drives the third driving wheel 2015 and the first flat gear 2016 to rotate, further the first flat gear 2016 drives the second flat gear 2020 to rotate, further the second flat gear 2020 drives the rotating sleeve seat 2044 to rotate, then, the sleeve seat 2044 is rotated to drive the two second taper bars 2022 to rotate, and at the same time, the third driving wheel 2015 drives the fourth driving wheel 2019 to rotate, that is, the fourth driving wheel 2019 drives the fourth rotating shaft 2018 to rotate, and further, the fourth rotating shaft 2018 drives the two first taper bars 2021 to rotate, that is, at this time, the first taper bars 2021 and the second taper bars 2022 move in opposite directions, that is, the first taper bars 2021 and the second taper bars 2022 rotate in opposite directions to stir and tear and separate the glass fibers falling downward from the annular region between the outer ring 2027 and the annular sliding assembly 2028.

The stabs on the two sides of the outer surface of the first stabbing rod 2021 are inclined downwards, and the stabs on the two sides of the outer surface of the second stabbing rod 2022 are inclined upwards.

The first and

second barbed rods

2021 and 2022 move in opposite directions, and the glass fibers can be hooked and torn apart by the opposite barbs of the first and

second barbed rods

2021 and 2022.

Example 4

On the basis of embodiment 3, as shown in fig. 11, the guiding and aligning system 3 includes a mounting frame 301, a mounting gantry 302, a first guiding roller set 303, a second guiding roller set 304, a second electric sliding assembly 305, a fourth electric sliding seat 306, a third electric sliding assembly 307, a third electric sliding seat 308, and an adjusting contact plate 309; the installation frame 301 is arranged on the right sides of the two first movable supporting steel rails 101; the front side of the top of the installation frame 301 and the rear side of the top are respectively connected with an installation portal frame 302 through bolts; the upper parts of the two mounting portal frames 302 are respectively provided with a first guide roller group 303; the middle upper parts of the two mounting portal frames 302 are respectively provided with a second guide roller group 304; the upper sides of the two mounting portal frames 302 are respectively provided with a second electric sliding assembly 305; each of the two second electric sliding assemblies 305 is slidably connected with a fourth electric sliding seat 306; a third electric sliding assembly 307 is arranged between the two fourth electric sliding seats 306; a third electric sliding seat 308 is connected to the left side of the third electric sliding assembly 307 in a sliding manner; an adjusting contact plate 309 is arranged at the left side of the third electric sliding seat 308; and a group of positioning lowering systems 4 are respectively arranged on the upper sides of the two installation portal frames 302.

After the fiber separation system 2 separates the glass fiber, the gantry crane system 1 is controlled to drive the glass fiber reinforced plastic storage tank to move to the guiding and righting system 3, the glass fiber reinforced plastic storage tank can contact with the adjusting contact plate 309 at first, then the glass fiber reinforced plastic storage tank continues to move, the adjusting contact plate 309 contacts with the glass fiber reinforced plastic storage tank to keep stable at the moment, then the two second electric sliding assemblies 305 are controlled to drive the two fourth electric sliding seats 306 to move synchronously, then the two fourth electric sliding seats 306 drive the third electric sliding assembly 307 between the two fourth electric sliding seats to move, the third electric sliding assembly 307 drives the third electric sliding seat 308 and the adjusting contact plate 309 to move, namely, the adjusting contact plate 309 and the glass fiber reinforced plastic storage tank are kept to move synchronously, at the moment, the glass fiber reinforced plastic storage tank moves to one side of the first guiding roller group 303 and the second guiding roller group 304, namely, the first guiding roller group 303 and the second guiding roller group 304 at the two sides of the glass fiber reinforced plastic storage tank are respectively guided and moved To, treat that glass steel storage tank moves to two location and transfer between the system 4, control third electric sliding subassembly 307 this moment and drive third electric sliding seat 308 and move, third electric sliding seat 308 drives adjustment contact plate 309 and moves promptly, because there is enough frictional force adjustment contact plate 309 and glass steel storage tank contact, then adjustment contact plate 309 short distance removes the small-angle rotation that can drive the realization glass steel storage tank, can rotate the adjustment to glass steel storage tank, make it can aim at the position that the below will carry out the installation.

Example 5

Based on embodiment 4, as shown in fig. 12 to 13, the positioning and lowering system 4 includes a fourth electric sliding assembly 401, a fifth electric sliding seat 402, a sixth electric sliding seat 403, an installation base frame 404, a connection vertical frame 405, a connection vertical frame plate 406, a connection horizontal plate 407, a first control insertion rod 408, an L-shaped connecting rod 409, a second control insertion rod 4010, an electric telescopic assembly 4011, a push catch plate 4012, a connection side column 4013, a stabilization clamping rod 4014, a second return elastic member 4015, and a sliding sleeve frame 4016; the upper sides of the two installation portal frames 302 are respectively provided with a fourth electric sliding assembly 401; each of the two fourth electric sliding assemblies 401 is slidably connected with a fifth electric sliding seat 402; each of the two fourth electric sliding assemblies 401 is slidably connected with a sixth electric sliding seat 403; a mounting chassis 404 is connected to the top of the adjacent fifth electric sliding seat 402 and sixth electric sliding seat 403 on each fourth electric sliding assembly 401; the tops of the two mounting bottom frames 404 are respectively fixedly connected with a connecting vertical frame 405; the tops of the two mounting underframe 404 are respectively fixedly connected with a connecting vertical frame plate 406; a connecting transverse plate 407 is fixedly connected to the top between the adjacent connecting vertical frame 405 and the connecting vertical frame plate 406; the top of each of the two connecting transverse plates 407 is fixedly inserted with a first control insertion rod 408; the upper part of the outer surface of the first control inserted rod 408 is respectively connected with an L-shaped connecting rod 409 in a rotating way; each of the two vertical connecting frame plates 406 is slidably connected with a sliding sleeve frame 4016; the inner sides of the two sliding sleeve frames 4016 are respectively connected with a connecting side post 4013 in a sliding way; the tops of the two connecting side columns 4013 are fixedly inserted with a second control inserted rod 4010 respectively; the two L-shaped connecting rods 409 are respectively connected with a second control inserted rod 4010 in a transmission way; the two vertical connecting frame plates 406 are respectively provided with an electric telescopic assembly 4011; the tops of the two connecting side columns 4013 are respectively welded with a pushing clamping plate 4012; the bottom parts in the two connecting vertical frame plates 406 are fixedly connected with a second reset elastic part 4015 respectively; the tops of the two second reset elastic pieces 4015 are fixedly connected with a sliding sleeve frame 4016; each of the two connecting side columns 4013 is fixedly connected with a stabilizing clamping rod 4014.

Firstly, the fourth electric sliding assembly 401 is controlled to drive the fifth electric sliding seat 402 and the sixth electric sliding seat 403 to move, that is, the fifth electric sliding seat 402 and the sixth electric sliding seat 403 drive the positioning lowering system 4 to move, so that the stabilizing clamping rods 4014 move to two sides of the installation position of the glass fiber reinforced plastic storage tank, then when the guiding righting system 3 guides and conveys the glass fiber reinforced plastic storage tank, when the glass fiber reinforced plastic storage tank moves to the position right above the installation position, the fourth electric sliding seat 306 just moves to the inner side of the bending part of the L-shaped connecting rod 409, after the fourth electric sliding seat 306 continues to move, the bending part of the L-shaped connecting rod 409 is driven to move, at this time, the fourth electric sliding seat 306 drives the third electric sliding assembly 307, the third electric sliding seat 308 and the adjusting contact plate 309 to move to the rightmost side of the bending part of the L-shaped connecting rod 409, that is, at this time, the third electric sliding assembly 307, The third electric sliding seat 308 and the adjusting contact plate 309 are not located in the area between the two stabilizing clamping bars 4014, the glass fiber reinforced plastic storage tank is located in the area between the two stabilizing clamping bars 4014 at this time, that is, the fourth electric sliding seat 306 can drive the L-shaped connecting rod 409 to rotate around the first control inserting rod 408, then the other side of the L-shaped connecting rod 409 drives the second control inserting rod 4010 to move, that is, the second control inserting rod 4010 drives the connecting side post 4013 to slide inside the sliding sleeve frame 4016, that is, the connecting side post 4013 drives the stabilizing clamping rod 4014 to move in the direction close to the glass fiber reinforced plastic storage tank, and at the same time, the other positioning lowering system 4 performs the same operation, that is, the two stabilizing clamping bars 4014 clamp the two sides of the glass fiber reinforced plastic storage tank, then the glass fiber reinforced plastic storage tank is slowly lowered by the portal crane system 1, and simultaneously the two stabilizing clamping bars 4014 move synchronously downward along with the glass fiber reinforced plastic storage tank, that is the second control inserting rod 4010, 4014, The push clamp plate 4012, the connecting side column 4013, the stabilizing clamping rods 4014 and the sliding sleeve frame 4016 synchronously move downwards, namely the connecting side column 4013 drives the sliding sleeve frame 4016 to move downwards in the connecting vertical frame plate 406, namely the sliding sleeve frame 4016 drives the second resetting elastic piece 4015 to compress, then after the glass fiber reinforced plastic storage tank is placed at a specified installation position, the portal crane system 1 is controlled to loosen, the portal crane system 1 is controlled to reset, then the fourth electric sliding seat 306 is controlled to reset to leave the bending part of the L-shaped connecting rod 409, the bending part of the L-shaped connecting rod 409 is not limited by the fourth electric sliding seat 306 any more, namely the two stabilizing clamping rods 4014 loosen the clamping on the glass fiber reinforced plastic storage tank, namely the second resetting elastic piece 4015 starts to release elastic force to extend to move upwards to drive the sliding sleeve frame 4016 and the connecting side column 4013 to reset, after the connecting side column 4013 moves upwards to reset, promote cardboard 4012 this moment relative with electronic flexible subassembly 4011, electronic flexible subassembly 4011 extension of control again, electronic flexible subassembly 4011's flexible end promotes cardboard 4012 promptly, then promotes cardboard 4012 and drives and connect side post 4013 and slide in slip cover frame 4016 inboard and reset, connect side post 4013 and drive a stable clamping bar 4014 motion and reset, stabilize clamping bar 4014 promptly and keep away from the glass steel storage tank, accomplish the hoist and mount to the glass steel storage tank.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. An industrial large-scale storage tank hoisting device comprises a portal crane system (1) for hoisting and transferring a glass fiber reinforced plastic storage tank, wherein the portal crane system (1) comprises a first movable supporting steel rail (101); the method is characterized in that: the fiber separation device also comprises a fiber separation system (2), a guiding and righting system (3) and a positioning and lowering system (4); a fiber separation system (2) for performing glass fiber separation on the glass fiber storage tank is arranged on the middle left side between the two first movable supporting steel rails (101); a guide righting system (3) for movably guiding the glass fiber reinforced plastic storage tank is arranged on the right side of the two first movable supporting steel rails (101); and a group of positioning lowering systems (4) for assisting the lowering and positioning of the glass fiber reinforced plastic storage tank are respectively arranged on the front right side and the rear right side of the guide righting system (3).

2. The industrial large-scale storage tank hoisting equipment as claimed in claim 1, wherein: the guiding and righting system (3) comprises an installation rack (301), an installation portal frame (302), a first guiding roller group (303), a second guiding roller group (304), a second electric sliding assembly (305), a fourth electric sliding seat (306), a third electric sliding assembly (307), a third electric sliding seat (308) and an adjusting contact plate (309); the right sides of the two first movable supporting steel rails (101) are provided with installation racks (301); the front side and the rear side of the top of the installation rack (301) are respectively fixedly connected with an installation portal frame (302); the upper parts of the two mounting portal frames (302) are respectively provided with a first guide roller group (303); the middle upper parts of the two mounting portal frames (302) are respectively provided with a second guide roller group (304); the upper sides of the two mounting portal frames (302) are respectively provided with a second electric sliding assembly (305); each of the two second electric sliding assemblies (305) is connected with a fourth electric sliding seat (306) in a sliding way; a third electric sliding assembly (307) is arranged between the two fourth electric sliding seats (306); a third electric sliding seat (308) is connected to the left side of the third electric sliding assembly (307) in a sliding manner; an adjusting contact plate (309) is arranged at the left side of the third electric sliding seat (308); the upper sides of the two installation portal frames (302) are respectively provided with a group of positioning and lowering systems (4).

3. The hoisting equipment for the large industrial storage tank as claimed in claim 2, wherein: the positioning lowering system (4) comprises a fourth electric sliding assembly (401), a fifth electric sliding seat (402), a sixth electric sliding seat (403), an installation underframe (404), a connection vertical frame (405), a connection vertical frame plate (406), a connection transverse plate (407), a first control inserted rod (408), an L-shaped connecting rod (409), a second control inserted rod (4010), an electric telescopic assembly (4011), a pushing clamping plate (4012), a connection side column (4013), a stabilizing clamping rod (4014), a second reset elastic piece (4015) and a sliding sleeve frame (4016); the upper sides of the two mounting portal frames (302) are respectively provided with a fourth electric sliding assembly (401); the two fourth electric sliding assemblies (401) are respectively connected with a fifth electric sliding seat (402) in a sliding way; each of the two fourth electric sliding assemblies (401) is connected with a sixth electric sliding seat (403) in a sliding manner; the top of a fifth electric sliding seat (402) and a sixth electric sliding seat (403) on each fourth electric sliding assembly (401) is connected with a mounting chassis (404); a connecting vertical frame (405) is fixedly connected to the right side of the top of each of the two mounting underframe (404); the left sides of the tops of the two mounting underframe (404) are respectively fixedly connected with a connecting vertical frame plate (406); a connecting transverse plate (407) is fixedly connected to the top between the adjacent connecting vertical frame (405) and the connecting vertical frame plate (406); the tops of the two connecting transverse plates (407) are respectively fixedly inserted with a first control insertion rod (408); the upper part of the outer surface of the first control inserted rod (408) is respectively connected with an L-shaped connecting rod (409) in a rotating way; the two vertical connecting frame plates (406) are respectively connected with a sliding sleeve frame (4016) in a sliding way; the inner sides of the two sliding sleeve frames (4016) are respectively connected with a connecting side post (4013) in a sliding way; the tops of the two connecting side columns (4013) are fixedly inserted with a second control inserted rod (4010) respectively; the two L-shaped connecting rods (409) are respectively connected with a second control inserted bar (4010) in a transmission way; two vertical connecting frame plates (406) are respectively provided with an electric telescopic assembly (4011); the tops of the two connecting side columns (4013) are fixedly connected with a pushing clamping plate (4012) respectively; the inner bottoms of the two vertical connecting frame plates (406) are respectively fixedly connected with a second reset elastic piece (4015); the tops of the two second reset elastic pieces (4015) are fixedly connected with a sliding sleeve frame (4016); two connecting side columns (4013) are respectively fixedly connected with a stabilizing clamping rod (4014).

4. The industrial large-scale storage tank hoisting equipment as claimed in claim 3, wherein: the fiber separation system (2) comprises an organic bottom plate (201), an alarm (202), a protective fence (203), a separation component and a position adjusting component; a bottom plate (201) is arranged on the middle left side between the two first movable supporting steel rails (101); four corners of the top of the bottom plate (201) are respectively provided with an alarm (202); four edges at the top of the bottom plate (201) are provided with continuous protective fences (203); the top of the machine bottom plate (201) is provided with a separating component; the top of the machine bottom plate (201) is provided with a position adjusting component.

5. The industrial large-scale storage tank hoisting equipment as claimed in claim 4, wherein: the position adjusting component comprises an installation frame seat (2023), a first electric sliding component (2024), a first electric sliding seat (2025), an installation connecting frame (2026), an outer ring (2027), an annular sliding component (2028) and an outward turning component; the front side and the rear side of the top of the bottom plate (201) are respectively provided with an installation frame seat (2023); two first electric sliding assemblies (2024) are respectively arranged at the tops of the two mounting frame seats (2023); two adjacent first electric sliding assemblies (2024) are connected with a first electric sliding seat (2025) in a sliding way; two first electric sliding seats (2025) are respectively fixedly connected with an installation connecting frame (2026); the upper parts of the two mounting connecting frames (2026) are provided with outer rings (2027); the upper parts of the inner sides of the two installation connecting frames (2026) are provided with annular sliding components (2028); the inner side of the annular sliding component (2028) is connected with a fixing component in a sliding way.

6. The industrial large-scale storage tank hoisting equipment as claimed in claim 5, wherein: the outward turning component comprises a second electric sliding seat (2029), a first electric rotating shaft seat (2030), a first mounting connecting rod (2031), a first fixing rod (2032), a rotating shaft rod (2033), a second mounting connecting rod (2034), a first resetting elastic part (2035), a second fixing rod (2036), a third mounting connecting rod (2037), a first bearing frame strip (2038), a fourth mounting connecting rod (2039), a second bearing frame strip (2040), a second electric rotating shaft seat (2041), a fifth mounting connecting rod (2042) and a first pressing strip (2043); a second electric sliding seat (2029) is connected to the inner side of the annular sliding component (2028) in a sliding way; a first electric rotating shaft seat (2030) is arranged at the rear part of the second electric sliding seat (2029); the rotating ends at two sides of the first electric rotating shaft seat (2030) are respectively provided with a first mounting connecting rod (2031); the lower parts of the two first mounting connecting rods (2031) are fixedly connected with a first fixing rod (2032); a rotating shaft lever (2033) is fixedly connected to the middle parts of the two first mounting connecting rods (2031); two sides of the outer surface of the rotating shaft rod (2033) are respectively connected with a second mounting connecting rod (2034) in a rotating way; the middle parts of the two second mounting connecting rods (2034) are respectively provided with a first reset elastic piece (2035); the tops of the two first resetting elastic pieces (2035) are respectively connected with a first mounting connecting rod (2031); the lower parts of the two second mounting connecting rods (2034) are fixedly connected with a second fixing rod (2036); a third mounting connecting rod (2037) is fixedly connected to each of the two sides of the second fixing rod (2036); a first bearing frame strip (2038) is fixedly connected to the rear sides of the two third mounting connecting rods (2037); a fourth mounting connecting rod (2039) is fixedly connected to each of two sides of the first fixing rod (2032); a second bearing frame strip (2040) is fixedly connected to the middle of the tops of the two fourth mounting connecting rods (2039); the middle parts of the front sides of the two fourth mounting connecting rods (2039) are respectively provided with a second electric rotating shaft seat (2041); the middle parts of the rear sides of the two fourth mounting connecting rods (2039) are respectively provided with a second electric rotating shaft seat (2041); the rotating ends of the four second electric rotating shaft seats (2041) are fixedly connected with a fifth mounting connecting rod (2042) respectively; a first pressing strip (2043) is fixedly connected to the tops of two fifth mounting connecting rods (2042) positioned at the front sides of the two fourth mounting connecting rods (2039); and a first pressing strip (2043) is fixedly connected to the tops of the two fifth mounting connecting rods (2042) positioned at the rear sides of the two fourth mounting connecting rods (2039).

7. The industrial large-scale storage tank hoisting equipment as claimed in claim 6, wherein: the bottom of the first pressing strip (2043) is provided with a plurality of trapezoidal grooves.

8. The industrial large-scale storage tank hoisting device as claimed in claim 7, wherein: the separating assembly comprises a power motor (204), a first rotating shaft rod (205), a bearing seat (206), a first bevel gear (207), a bearing frame plate (208), a mounting top plate (209), a second rotating shaft rod (2010), a first transmission wheel (2011), a second bevel gear (2012), a second transmission wheel (2013), a third rotating shaft rod (2014), a third transmission wheel (2015), a first flat gear (2016), a mounting disc (2017), a fourth rotating shaft rod (2018), a fourth transmission wheel (2019), a second flat gear (2020), a first conical barbed rod (2021), a second conical barbed rod (2022) and a rotating sleeve seat (2044); a power motor (204) is fixedly connected to the left rear side of the top of the bottom plate (201); a first rotating shaft rod (205) is fixedly connected to an output shaft of the power motor (204); a bearing seat (206) is fixedly connected to the left side of the top of the bottom plate (201); the bearing seat (206) is rotationally connected with the first rotating shaft rod (205); a first bevel gear (207) is fixedly sleeved on the middle front side of the outer surface of the first rotating shaft rod (205); a bearing frame plate (208) is fixedly connected to the left front side of the top of the bottom plate (201); the bearing frame plate (208) is rotationally connected with the first rotating shaft rod (205); a mounting top plate (209) is fixedly connected to the top of the bottom plate (201); the upper part of the rear side of the bearing frame plate (208) is rotatably connected with a second rotating shaft rod (2010); a first transmission wheel (2011) and a second bevel gear (2012) are fixedly connected to the outer surface of the second rotating shaft rod (2010) in sequence; the second bevel gear (2012) engages the first bevel gear (207); a mounting disc (2017) is fixedly connected to the middle of the top of the bottom plate (201); the top of the mounting disc (2017) is connected with a mounting top plate (209); the top of the mounting disc (2017) is rotatably connected with a third rotating shaft rod (2014); a second driving wheel (2013), a third driving wheel (2015) and a first flat gear (2016) are fixedly connected to the outer surface of the third rotating shaft rod (2014) in sequence; the outer ring surface of the second transmission wheel (2013) is in transmission connection with the first transmission wheel (2011) through a belt; the mounting top plate (209) is rotatably connected with a third rotating shaft rod (2014); the middle of the top of the mounting disc (2017) is rotatably connected with a fourth rotating shaft rod (2018); a fourth driving wheel (2019) is fixedly connected to the outer surface of the fourth rotating shaft rod (2018); the front side of the mounting top plate (209) is rotatably connected with a rotating sleeve seat (2044); a second flat gear (2020) is fixedly sleeved on the lower side of the outer surface of the rotary sleeve seat (2044); the second spur gear (2020) engages the first spur gear (2016); the inner side of the rotary sleeve seat (2044) is rotatably connected with a fourth rotating shaft rod (2018); a first pricker rod (2021) is symmetrically and fixedly inserted on the upper side of the outer surface of the fourth rotating shaft rod (2018); a second taper rod (2022) is symmetrically and fixedly inserted on the upper side of the outer surface of the rotating sleeve seat (2044).

9. The industrial large-scale storage tank hoisting device as claimed in claim 8, wherein: the pricks on the two sides of the outer surface of the first prick rod (2021) are inclined downwards, and the pricks on the two sides of the outer surface of the second prick rod (2022) are inclined upwards.