CN115106665A - Seat core supporting component aeroelastic tube sleeve outer sleeve gasket welding system - Google Patents

Abstract

A seat core support assembly aero-elastic tube-in-tube outer sleeve gasket welding system comprising: the conveying belt is used for orderly conveying the outer sleeves; the overturning assembly is used for realizing vertical overturning of the outer sleeve; the moving assembly is used for realizing the linear movement of the overturned outer sleeve in a state of keeping the overturned outer sleeve vertical; set up in removal subassembly one side for realize outer tube and annular gasket automatic weld's welding Assembly, welding Assembly is including the weldment work platform, and the weldment work platform can go up and down the action, is provided with swivel work head on the weldment work platform, is provided with on swivel work head to be used for inserting in the outer tube and can be with the ejector pin of outer tube jack-up, is provided with automatic welding machine in the top of ejector pin. The automatic welding device can convey, position and transfer the outer sleeve in order and perform automatic mechanical welding, improves the working efficiency of the welding operation of the outer sleeve and the annular gasket, and effectively ensures the welding quality of each product.

Description

Seat core supporting component aeroelastic tube sleeve outer sleeve gasket welding system

Technical Field

The invention belongs to the technical field of lifting sleeve assembling production equipment, and particularly relates to a seat core support assembly aeroelastic sleeve outer sleeve gasket welding system.

Background

In the lifting seat structure, the balloon sleeve pipe arranged in the middle of the seat is used as a supporting component structure, and the lifting seat structure has high structural strength and use reliability. The gas bomb tube sleeve comprises an outer sleeve, an annular gasket is arranged at one end of the outer sleeve and positioned inside the outer sleeve, and the annular gasket is in welded connection with the outer sleeve.

In the prior art, the welding between the annular gasket and the outer sleeve is usually completed by manual operation, and the manual welding mode has the following problems: 1. the workload is large, and the working efficiency is low; 2. the requirement on the welding skill of a welding worker is high, and the skilled worker is required to be competent for work; 3. the manual welding quality has large fluctuation and uneven welding quality.

Disclosure of Invention

Technical problem (I)

In summary, how to improve the working efficiency and the welding quality of the annular gasket and the outer sleeve becomes a problem to be solved by those skilled in the art.

(II) technical scheme

The invention provides a seat core support assembly aeroelastic pipe sleeve outer pipe gasket welding system which is used for realizing mechanical automatic welding of an annular gasket in an outer sleeve.

The welding system for the gasket of the sleeve outside the tube of the gas elastic tube of the core support component of the seat comprises the following steps in the production process sequence:

the conveying belt is used for orderly conveying the outer sleeves;

the overturning assembly is used for realizing vertical overturning of the outer sleeve;

the moving assembly is used for realizing the linear movement of the overturned outer sleeve in a vertical state;

set up in remove subassembly one side for realize outer tube and annular gasket automatic weld's welding subassembly, the welding subassembly is including the weldment work platform, the weldment work platform can go up and down the action, in be provided with swivel work head on the weldment work platform, in be provided with on the swivel work head and be used for inserting in the outer tube and can be with the ejector pin of outer tube jack-up, in the top of ejector pin is provided with automatic welding machine.

Preferably, in the seat core support assembly aero-elastic tube sleeve outer tube gasket welding system provided by the invention, the conveying belt comprises a conveying belt, partition plates are arranged on the outer surface of the conveying belt, and the partition plates are arranged on the conveying belt at equal intervals and form accommodating spaces for accommodating an outer tube.

Preferably, in the welding system for the gasket of the sleeve outside the tube of the gas spring tube of the seat core support assembly provided by the invention, the overturning assembly comprises a pushing workbench and an overturning platform, a pushing device for pushing the outer sleeve is arranged at the front end of the pushing workbench along the pushing direction of the outer sleeve, the overturning platform is arranged at the rear end of the pushing workbench, and the overturning platform can be overturned by 90 degrees and is used for realizing the verticality of the outer sleeve when the outer sleeve is loaded; the pushing workbench is connected with the conveying belt in a process mode.

Preferably, in the welding system for the gasket of the sleeve outside the tube of the gas spring tube of the core support assembly of the seat provided by the invention, a plurality of pushing grooves for accommodating the outer tube are arranged on the pushing workbench, all the pushing grooves are arranged at intervals in the pushing direction perpendicular to the outer tube, a slope surface is arranged between every two adjacent pushing grooves, an ejection device for ejecting the outer tube upwards is arranged in each pushing groove, and the ejection device is matched with the slope surface and used for realizing the ordered movement of the outer tube on the pushing workbench.

Preferably, in the welding system for the gasket of the outer sleeve of the gas spring sleeve of the seat core support assembly provided by the invention, a positioning rod coaxially arranged with the ejector rod is arranged at the top end of the ejector rod, and the positioning rod is used for being inserted into a central hole of the annular gasket in the outer sleeve and used for realizing positioning after jacking the outer sleeve.

Preferably, in the welding system for the gasket of the sleeve pipe of the gas spring pipe sleeve of the seat core support assembly provided by the invention, at least two sets of welding assemblies are arranged, at least two sets of rotating tables are arranged, and the rotating tables and the welding assemblies are arranged in a one-to-one correspondence manner.

Preferably, in the system for welding gasket of sleeve outside of tube of air elastic tube for core support assembly of seat provided by the present invention, the moving assembly includes a linear track, a moving slider is disposed on the linear track, and a mounting block is disposed on the moving slider, and the mounting block can perform linear reciprocating motion in a direction perpendicular to the linear track; and a clamping hand for clamping the outer sleeve in a vertical state is arranged on the mounting block.

Preferably, in the welding system for gasket of sleeve pipe outside of gas spring pipe sleeve of seat core supporting component provided by the invention, the clamping hand is a controllable mechanical hand; the clamping hands are provided with a plurality of clamping hands, and the intervals between the clamping hands are the same as the intervals between the welding assemblies.

Preferably, in the welding system for the gasket of the outer sleeve of the gas spring sleeve of the seat core support assembly, a blocking plate for blocking and separating the outer sleeve from the clamping hand is fixedly arranged relative to the linear rail, and the setting height of the blocking plate is higher than that of the clamping hand and lower than the top end of the outer sleeve in a vertical state.

Preferably, in the welding system for the gasket of the outer sleeve of the aeroelastic tube sleeve of the seat core support assembly, a containing box is arranged at the starting end of the conveying belt, and the width of the containing box is 2-4cm greater than the length of the outer sleeve; the inner side bottom surface of the containing box is a slope surface, an output window for leaking the outer sleeve is formed in one side of the containing box, corresponding to the lower end of the inner side bottom surface of the containing box, and the output window is connected with the conveying belt.

(III) advantageous effects

The invention provides a seat core support assembly aeroelastic pipe sleeve outer pipe gasket welding system which is used for realizing mechanical automatic welding of an annular gasket in an outer sleeve. According to the production process sequence, the welding system for the gasket of the sleeve pipe outside the gas spring pipe of the seat core supporting assembly comprises the following steps: the conveying belt is used for orderly conveying the outer sleeves; the overturning assembly is used for realizing vertical overturning of the outer sleeve; the moving assembly is used for realizing the linear movement of the overturned outer sleeve in a vertical state; set up in removal subassembly one side for realize outer tube and annular gasket automatic weld's welding Assembly, welding Assembly is including weldment work platform, and weldment work platform can go up and down the action, is provided with swivel work platform on weldment work platform, is provided with on swivel work platform to be arranged in inserting the outer tube and can be with the ejector pin of outer tube jack-up, is provided with automatic welding machine in the top of ejector pin.

Through the structural design, the welding system for the gasket of the sleeve pipe outside the gas spring pipe of the seat core support assembly can convey, position and transfer the outer sleeve in order and perform automatic mechanical welding.

Drawings

FIG. 1 is a schematic structural diagram of a gasket welding system for an outer sleeve of a gas spring tube of a seat core support assembly according to an embodiment of the invention.

In fig. 1, the correspondence between the component names and the reference numerals is:

a conveyer belt 1, a welding workbench 2, a rotary workbench 3, a mandril 4, an automatic welding machine 5,

The device comprises a pushing workbench 6, a turnover table 7, a linear track 8 and a controllable manipulator 9.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In addition, in the description of the present invention, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of describing the present invention but do not require that the present invention must be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. The terms "connected" and "connected" used herein should be interpreted broadly, and may include, for example, a fixed connection or a detachable connection; they may be directly connected or indirectly connected through intermediate members, and specific meanings of the above terms will be understood by those skilled in the art as appropriate.

Referring to fig. 1, fig. 1 is a schematic structural diagram of a gasket welding system for an outer sleeve of a bellows of a seat core support assembly according to an embodiment of the present invention.

The invention provides a seat core support assembly aeroelastic pipe sleeve outer pipe gasket welding system which is used for realizing mechanical automatic welding of an annular gasket in an outer sleeve. In the prior art, the outer sleeve is of a circular tube structure, an annular gasket is arranged at one end of the outer sleeve and at a position 1-1.5cm inside the outer sleeve, the outer edge of the annular gasket needs to be welded and fixed with the inner side wall of the outer sleeve, and a circular hole structure is arranged at the center of the annular gasket.

According to the production process sequence, the welding system for the gasket of the sleeve pipe outside the gas spring pipe of the seat core supporting component comprises the following components:

a first part: a conveyor belt 1 for orderly conveying the outer sleeves.

The outer sleeve is a long straight round pipe (general structure), so the conveyer belt 1 used in the invention should firstly meet the conveying requirements of the bars or pipes, secondly should be capable of dispersing the bars or pipes one by one, and finally should be capable of arranging and orderly conveying the dispersed bars or pipes.

In order to meet the three conditions, the conveying belt 1 used in the invention is a belt type conveying device, the conveying belt 1 comprises a conveying belt, the outer surface of the conveying belt is provided with a partition board, and the partition board is arranged on the conveying belt at equal intervals and is provided with an accommodating space for accommodating an outer sleeve.

Specifically, the conveying belt 1 comprises a conveying belt steel frame, belt wheels are mounted on the conveying belt steel frame, and belts are mounted on the conveying belt steel frame through the belt wheels, metal armors can be further arranged on the belts, partition plates are arranged according to the diameter size of the outer sleeve, the partition plates are arranged on the belts at equal intervals, and the interval distance between every two adjacent partition plates is larger than the diameter of the outer sleeve and smaller than 1.5 times of the diameter of the outer sleeve. Meanwhile, one end (the starting end) of the conveying belt steel frame is shorter, and the other end (the tail end) of the conveying belt steel frame is higher, so that the belt forms an uphill conveying structure. The above-mentioned structural design of conveyer belt 1 can realize the transport of outer tube promptly, can realize the orderly arrangement of outer tube again, provides the guarantee for safety in production.

The second part is a turnover assembly used for realizing vertical turnover of the outer sleeve.

The welding system for the gasket of the outer sleeve of the gas spring sleeve of the seat core support assembly mainly realizes the welding of the annular gasket in the outer sleeve, and the outer sleeve needs to be kept in a vertical arrangement state in order to facilitate the automatic welding of a welding machine. The conveyor belt 1 provided by the invention conveys the outer sleeve in a horizontal laying state (which can be understood as a flat lying state), so that the invention provides a turnover assembly, and the outer sleeve in the horizontal state is erected through the turnover assembly.

In the invention, the overturning assembly comprises a pushing workbench 6 and an overturning platform 7, wherein the overturning platform 7 is an overturning vertical structure for realizing the change of the outer sleeves from a horizontal state to a vertical state, and the pushing workbench 6 is connected with the conveying belt 1 and is used for pushing the outer sleeves to the overturning platform 7 one by one. The end of the conveyer belt 1 arranged on the pushing workbench 6 is pushed along the pushing direction of the outer sleeve (the pushing direction is vertical to the conveying direction of the outer sleeve on the conveyer belt 1), so that after the outer sleeve is separated from the conveyer belt 1 (a connecting plate with a downhill structure can be arranged, when the outer sleeve runs to the end of the conveyer belt 1 through the conveyer belt 1, the conveyer belt 1 rotates, the outer sleeve can be separated from the accommodating space and then is connected by the connecting plate to roll onto the pushing workbench 6), the pushing device for pushing the outer sleeve is arranged at the front end of the pushing workbench 6 (in the invention, the pushing device is preferably an air cylinder, the hydraulic cylinder can be a hydraulic cylinder, when the air cylinder is adopted, the pushing stroke of the pushing device can be adjusted, the air cylinder is rapid in reaction, the production efficiency can be improved), the overturning platform 7 is arranged at the rear end of the pushing workbench 6, and the overturning platform 7 can perform 90-degree overturning, For achieving the verticality of the outer casing when loaded with the outer casing.

Specifically, the overturning platform 7 comprises a platform surface, an arc-shaped linear groove (the cross section of the linear groove is arc-shaped) is arranged on the platform surface, the overturning platform 7 is hinged on the overturning platform frame, the overturning platform can limit the overturning of the overturning platform 7 (the lower limit is kept horizontal, and the upper limit is kept vertical) by arranging a limiting structure, meanwhile, the overturning power device is also provided, the overturning power device can be an air cylinder or a hydraulic cylinder, an air cylinder shaft of the air cylinder or a hydraulic cylinder shaft of the hydraulic cylinder is hinged with the bottom surface of the overturning platform 7, and the cylinder body is hinged on the overturning platform frame, so that the overturning action of the overturning platform 7 can be realized through the extension and retraction of the air cylinder shaft or the hydraulic cylinder shaft. Furthermore, a baffle plate is arranged on one side, away from the pushing workbench 6, of the turnover table 7, and is used for limiting pushing of the outer sleeve, so that the outer sleeve is prevented from falling off due to excessive pushing. Meanwhile, the baffle plate is further provided with the overturning limiting plate, the overturning limiting plate and the table board of the overturning platform 7 are arranged at an interval, the overturning limiting plate can be arranged to avoid the situation that the outer sleeve falls off when the outer sleeve overturns along with the overturning platform 7, and meanwhile, the overturning limiting plate and the table board of the overturning platform 7 are arranged at an interval to ensure that the outer sleeve can move on two sides.

In the present invention, the pushing workbench 6 is technically connected with the conveying belt 1, specifically, a transition structure, such as the above-mentioned connecting plate, is arranged according to the actual situation of equipment installation, so that the outer sleeve on the conveying belt 1 can be stably conveyed (specifically, rolled) onto the pushing workbench 6.

Step by step, be provided with the propelling movement recess that is used for holding the outer tube on the propelling movement workstation 6, each propelling movement recess can both stably hold an outer tube. In the present invention, the depth of the pushing groove is not more than 1/3 of the diameter of the outer sleeve, and the depth of the pushing groove is preferably one fifth of the diameter of the outer sleeve. In order to improve the production efficiency, the vertical overturning operation needs to be carried out on a plurality of outer sleeves at one time, so that a plurality of pushing grooves are arranged on the pushing workbench 6, and all the pushing grooves are arranged at intervals along the pushing direction perpendicular to the outer sleeves. In order to realize that the outer sleeve rolls between two adjacent pushing grooves, the connecting surface between two adjacent pushing grooves is designed into a slope surface (the slope surface is a downhill surface structure in the direction that the last pushing groove points to the next pushing groove), an ejection device for ejecting the outer sleeve upwards is arranged in the pushing groove (the ejection device can be a small air cylinder or a small hydraulic cylinder, or other small reciprocating mechanisms), the ejection device is arranged on the pushing workbench 6 and can eject the outer sleeve entering the pushing groove, and the ejected outer sleeve can roll down to the next pushing groove on the slope surface, so that the outer sleeve can move on the pushing workbench 6 orderly through the matching of the ejection device and the slope surface.

And the third part is a moving assembly used for realizing the linear movement of the overturned outer sleeve in the vertical state.

The main function of the moving assembly is to move the outer sleeve from the overturning platform 7 to the welding assembly for mechanical welding in a state that the outer sleeve is kept vertical.

In order to realize the operation, the moving assembly is provided with a linear track 8, and a moving slide block is arranged on the linear track 8 and can reciprocate along a straight line. In the invention, the linear track 8 can adopt an air cylinder, and the movable sliding block is arranged at the shaft end of an air cylinder shaft, so that the air cylinder drives the movable sliding block to do linear reciprocating motion. The cylinder is adopted to drive the movable sliding block to move, and the moving response speed is high.

According to the invention, the mounting block is arranged on the movable sliding block, the mounting block is of a structure for realizing movement in the horizontal direction, the mounting block can perform linear reciprocating movement in the direction perpendicular to the linear track 8, the movement track of the mounting block is similar to a rectangle, and the mounting block is provided with the clamping hand for clamping the outer sleeve in the vertical state, so that the mounting block can drive the clamping hand to perform controllable movement on a rectangular movement track.

Furthermore, the clamping hand is a controllable mechanical hand 9, and comprises two openable 'fingers', and the outer sleeve in the vertical state is firmly clamped and fixed by the fingers. The clamping hands are arranged in a plurality of numbers, and the intervals between the clamping hands are the same as the intervals between the welding assemblies.

In the structural design, the outer sleeve is turned over and erected by the turning table 7 and then is kept still, the clamping hand is aligned with the outer sleeve and then moves towards the outer sleeve (specifically, the movable sliding block is fixed, and the mounting block moves linearly) through the matching of the movable sliding block and the mounting block, at the moment, the clamping hand is in an open state, after the clamping hand moves in place, the clamping hand is closed to clamp the outer sleeve, then the mounting block is fixed, the sliding block is moved to move linearly, thereby the outer sleeve is transferred to the welding assembly from the overturning platform 7, the outer sleeve is received by the welding assembly, the clamping hand is loosened, the outer sleeve is rotated and welded, after welding is finished, the clamping hand clamps the outer sleeve to continuously move and remove the outer sleeve from the welding assembly, after the clamping hand is loosened, the movable sliding block is fixed, the mounting block returns, the outer sleeve is separated from the clamping hand, and the movable sliding block moves to reset to grab the outer sleeve next time.

Furthermore, a blocking plate for blocking and separating the outer sleeve from the clamping hand is fixedly arranged relative to the linear rail 8, and the setting height of the blocking plate is higher than that of the clamping hand and lower than the top end of the outer sleeve in a vertical state. Through setting up the interception board, can intercept the outer tube to make the outer tube break away from smoothly from the tong.

And a fourth part for welding the assembly.

The welding assembly for automatically welding the outer sleeve and the annular gasket is arranged on one side of the moving assembly, the welding assembly comprises a welding workbench 2, the welding workbench 2 can move up and down, a rotary workbench 3 is arranged on the welding workbench 2, the rotary workbench 3 works independently relative to the welding workbench 2, and the rotary workbench 3 is arranged on the welding workbench 2 and can move up and down along with the welding workbench 2. Be provided with on swivel work head 3 and be used for inserting in the outer tube and can be with ejector pin 4 of outer tube jack-up, just can drive the outer tube and rotate after jacking the outer tube through ejector pin 4, realize the circumferential weld of the interior annular gasket outer fringe of outer tube in the rotatory in-process of outer tube.

An automatic welding machine 5 is arranged above the ejector rod 4, the automatic welding machine 5 is fixed in the welding process, and the outer sleeve rotates under the action of the ejector rod 4 (the ejector rod 4 is driven to rotate by the rotary workbench 3).

In order to improve the welding operation precision, the top end of the ejector rod 4 is provided with a positioning rod which is coaxially arranged with the ejector rod, and the positioning rod is used for being inserted into a central hole of an annular gasket in the outer sleeve and used for realizing the positioning after jacking the outer sleeve.

Furthermore, the welding assemblies are provided with at least two sets, the rotary workbench 3 is provided with at least two sets, and the rotary workbench 3 and the welding assemblies are arranged in a one-to-one correspondence mode. The welding assembly is provided with a plurality of sets, can realize that a plurality of outer sleeves weld simultaneously, can improve welding efficiency like this.

In order to improve the safety of a production plant area, the outer side of the welding assembly is provided with a protective cover (a window structure is arranged on the protective cover according to the actual equipment structure, so that a moving structure can be avoided), and the protective cover is preferably of a metal cover body structure.

The invention also arranges a containing box at the starting end of the conveyer belt 1, the width of the containing box is 2-4cm larger than the length of the outer sleeve, the bottom surface of the inner side of the containing box is a slope surface, an output window for the outer sleeve to leak is arranged at one side of the lower end of the bottom surface of the inner side of the containing box, and the output window is connected with the conveyer belt 1.

Therefore, the invention provides a seat core support assembly aeroelastic pipe sleeve outer sleeve gasket welding system which is used for realizing mechanical automatic welding of an annular gasket in an outer sleeve. According to the production process sequence, the welding system for the gasket of the sleeve pipe outside the gas spring pipe of the seat core supporting assembly comprises the following steps: a conveying belt 1 for orderly conveying the outer sleeves; the overturning assembly is used for realizing vertical overturning of the outer sleeve; the moving assembly is used for realizing the linear movement of the overturned outer sleeve in a vertical state; set up in removal subassembly one side for realize outer tube and annular gasket automatic weld's welding assembly, welding assembly is including weldment work platform 2, and weldment work platform 2 can go up and down to move, is provided with swivel work head 3 on weldment work platform 2, is provided with on swivel work head 3 to be used for inserting in the outer tube and can be with ejector pin 4 of outer tube jack-up, is provided with automatic welding machine 5 in the top of ejector pin 4.

Through the structural design, the welding system for the gasket of the sleeve pipe outside the gas spring pipe of the seat core support assembly can convey, position and transfer the outer sleeve in order and perform automatic mechanical welding.

It will be appreciated by those skilled in the art that the invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The embodiments disclosed above are therefore to be considered in all respects as illustrative and not restrictive. All changes which come within the scope of or equivalence to the invention are intended to be embraced therein.

Claims (10)

1. The utility model provides a seat core supporting component aeroelastic tube sleeve outside of tubes sleeve pipe gasket welding system for realize the mechanized automatic weld of the interior annular gasket of overcoat pipe, its characterized in that includes according to production technology order:

the conveying belt (1) is used for orderly conveying the outer sleeves;

the overturning assembly is used for realizing vertical overturning of the outer sleeve;

the moving assembly is used for realizing the linear movement of the overturned outer sleeve in a vertical state;

set up in remove subassembly one side for realize outer tube and annular gasket automatic weld's welding subassembly, the welding subassembly is including weldment work platform (2), the weldment work platform can go up and down the action, in be provided with swivel work head (3) on the weldment work platform, in be provided with on the swivel work head and be used for inserting in the outer tube and can be with ejector pin (4) of outer tube jack-up, in the top of ejector pin is provided with automatic welding machine (5).

2. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 1,

the conveyer belt including conveyor belt, in conveyor belt's surface is provided with the baffle, the baffle is in conveyor belt equidistantly sets up and is formed with the accommodation space that is used for holding an outer tube.

3. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 1,

the overturning assembly comprises a pushing workbench (6) and an overturning platform (7), a pushing device for pushing the outer sleeve is arranged at the front end of the pushing workbench along the pushing direction of the outer sleeve, the overturning platform is arranged at the rear end of the pushing workbench, and the overturning platform can be overturned by 90 degrees and is used for realizing the verticality of the outer sleeve when the outer sleeve is loaded;

the pushing workbench is connected with the conveying belt in a process mode.

4. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 3,

the outer sleeve pushing device is characterized in that a plurality of pushing grooves used for containing the outer sleeve are formed in the pushing workbench, all the pushing grooves are arranged at intervals in the pushing direction perpendicular to the outer sleeve, a slope is formed between every two adjacent pushing grooves, an ejection device used for ejecting the outer sleeve upwards is arranged in each pushing groove, and the ejection device is matched with the slope and used for achieving ordered movement of the outer sleeve on the pushing workbench.

5. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 1,

and a positioning rod which is coaxial with the ejector rod is arranged at the top end of the ejector rod and is used for being inserted into a central hole of the annular gasket in the outer sleeve and positioning the outer sleeve after jacking.

6. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 5,

the welding assembly is provided with at least two sets, the rotary workbench is provided with at least two sets, and the rotary workbench and the welding assembly are arranged in a one-to-one correspondence mode.

7. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 6,

the moving assembly comprises a linear track (8), a moving slide block is arranged on the linear track, and an installation block is arranged on the moving slide block and can perform linear reciprocating motion in a direction perpendicular to the linear track;

and a clamping hand for clamping the outer sleeve in a vertical state is arranged on the mounting block.

8. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 7,

the clamping hand is a controllable mechanical hand (9);

the clamping hands are arranged in a plurality of numbers, and the intervals between the clamping hands are the same as the intervals between the welding assemblies.

9. The seat core support assembly balloon sleeve outer tube gasket welding system of claim 7,

and an interception plate for intercepting and separating the outer sleeve from the clamping hand is fixedly arranged relative to the linear track, and the arrangement height of the interception plate is higher than that of the clamping hand and lower than the top end of the outer sleeve in a vertical state.

10. The seat core support assembly balloon sleeve outer sleeve gasket welding system of any one of claims 1 to 9,

an accommodating box is arranged at the starting end of the conveying belt, and the width of the accommodating box is 2-4cm greater than the length of the outer sleeve;

the inner side bottom surface of the containing box is a slope surface, an output window for leaking the outer sleeve is arranged on one side of the containing box, which corresponds to the lower end of the inner side bottom surface of the containing box, and the output window is connected with the conveying belt.

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