RU2102210C1 - Car body assembling and welding automatic transfer line - Google Patents

Abstract

FIELD: automotive industry; assembling and welding of automobile bodies, vans and microbuses. SUBSTANCE: line has mechanized section 15 arranged at beginning of line for assembling and welding of base with windshield frame and jigs for sides 16 arranged in tandem in pairs relative to technological axis line 1-1 in which tailgate aperture is formed, and sections for welding up body 17 with simultaneously welding-to of roof. Transport for pallets 18 is made in form of rotary-roll out tables 19 arranged at both sides relative to line 1-1. Loading and unloading devices belonging to section 15 are made in form of multicarriage portal manipulators 46, 51 and 56. Chain conveyor 70 for transportation of base with welded-to windshield frame and chain conveyor 71 for transportation of assembled body are arranged on one axis. Roof transportation chain conveyor 72 is arranged in parallel with this axis. Chain conveyor 71 encloses in width chain conveyor 70 at loading position 73. EFFECT: enlarged operating capabilities. 6 cl, 15 dwg

Description

 The invention relates to welding, and in particular to the design of an automated line for the assembly and welding of car bodies, in particular bodies of vans and vans.

 Known production line for the assembly and welding of bodies and body units of vehicles by AS N 1524984, containing assembly and welding posts, including a body assembly section with a device for loading a pre-assembled base made in the form of a telescopic reloader, and body assembly stores, a body frill section with a main conductor equipped with automatic welding groups and manual welding tongs, with with the help of which a preformed body is grasped, and a welding section with welding robots, on which the final welding of the body and welding of individual nodal nodes (sidewalls and bases). The indicated sections are sequentially interconnected by a horizontally-closed non-synchronous transport, made in the form of chain conveyor drives with lifting tables and roller tables with an electromechanical drive, along which two types of satellites for the body and sidewalls (universal satellites for the base and body) are moved. Sidewalls are loaded into their respective satellites manually. The body is assembled by installing on the satellite with the assembled base of the sidewalls, the roof and the windshield frame and fixing them with staples, also manually. After the welding section, the finished body is unloaded with a device similar to the boot one.

 The advantage of this line is its versatility, since it is possible to simultaneously assemble and weld several units of the body and the body itself and, as a result, save production space at a sufficiently high productivity due to the reduction of interoperation time.

 However, this line has a number of significant drawbacks, expressed primarily in its low technological capabilities, due to the limited range of body types that can be assembled on this line, a low degree of automation and the consequent high labor intensity, inconvenience of service and low safety standards. In addition, the line is distinguished by the complexity of the design, and therefore its cost increases significantly, which means the cost of assembled cars.

 The above disadvantages are determined by the fact that this line is mainly intended for the assembly and welding of car bodies (for example, Oka cars), which have relatively small dimensions, low weight and the corresponding assembly-welding technology, which allows the entire formation of the body geometry using staples, then grabbing it in the main conductor and final welding in the welding area by welding robots. Both the general layout of the line and the non-synchronous transport linking its sections, providing for the sequential movement of satellites one after another from section to section, are subordinated to these features. This makes the formation of the body unsafe, since it is performed by operators entering vehicles, which is quite large satellites and, therefore, significant traction sharply reduces the level of safety of assembly and welding operations. In addition, the loading of the roof and sidewalls is done manually by operators, which is not only safe, but laborious and non-technological with sequentially moving non-synchronous transport. For the same reasons, it is much more difficult for operators to manually form the rear doorway, as well as for tacking and control of the body’s internal seams made in the main conductor. In addition, with this layout of the line, when welding robots cannot be located on the back side of the body, but are located only on both sides of the body moving on the satellite, it becomes impossible to completely weld the most labor-intensive seams connecting the sidewalls with their help with a reason, as a result of which this operation the operators have to partially carry out manually in the main conductor, which, as mentioned above, is not technologically advanced and time-consuming. The use in this case of robots with a seventh axis, allowing to carry out the specified operation, would significantly complicate the line and increase its cost. Another drawback that significantly affects the complexity of the line design and increase its cost is the large number of satellites required for assembly-welding of car bodies (there are about 10 in the known line), not counting the individual satellites for the base and sidewalls. In such lines, satellites account for 20-30% of its total cost, since this is a complex mechanism with high requirements for manufacturing accuracy. Such requirements are determined by ensuring the constancy of the geometry of the body, in connection with which each satellite, despite the long dimensional chain, should clearly stand up relative to the stationary forming and welding equipment of the sidewall tack conductor (main conductor), as well as regarding welding robots in the body welding section. It should also be said that the design complexity inherent in the well-known line, high laboriousness, low level of safety equipment are complemented by the inability to use it for assembly and welding of vans and minibuses, since the body shaping technology in this case involves the sequential assembly and welding of body parts, since the next part covers part of the welds of the previous one. Thus, as already mentioned above, the technology used to form the body on “clips” used in this line, along with other disadvantages, significantly reduces its technological capabilities.

 The objective of the invention is to eliminate these drawbacks, namely to expand the technological capabilities of the line, simplify its design, increase the degree of automation, ease of maintenance, safety standards, reduce costs and obtain a technical result, which consists in expanding the range of products to be welded, in particular the ability to assemble -Welding bodies of vans and vans, as well as a significant reduction in the number of satellites due to the creation of an optimal trajectory their movements, while ensuring the most rational positioning of satellites relative to the welding equipment.

To solve the above problems and obtain the specified technical result in a well-known line for assembling and welding car bodies containing assembly and welding posts, vehicles for satellites, welding equipment including welding robots, automatic welding groups and manual welding tools, devices for loading and unloading and chain conveyors for moving body units and bodies to the aforementioned devices, assembly and welding posts are a mechanized section of assembly-welding of innovations with a windshield frame and conduits for tacking the sidewalls and forming an aperture of the rear doors and areas for welding the body with simultaneous welding of the roof, sequentially arranged behind it in pairs with respect to the technological axis of the line. The transport for satellites is made in the form of rotary-roll tables located on both sides relative to the technological axis, on each of which there are two satellites with the possibility of their reciprocal rotation with the table and tangential roll-out in opposite directions to the sidewall tack conductor and to the section body welding in extreme positions of the table. The devices for loading and unloading are made in the form of multi-gantry portal manipulators, the first of which, corresponding to the mechanized section of the base assembly-welding with the windshield frame, is located along the technological axis of the line, and the other two, corresponding to the swing-out tables and the sections of the body welding, are perpendicular to this axis, while the gantry manipulator related to the body finishing section is equipped with a roof forming conductor. The chain conveyors for moving the base with the welded-on windshield frame and the finished body are located on one axis corresponding to the technological axis of the line parallel to which the chain conveyor for moving the roof is located, and the chain conveyor for moving the finished body covers the width of the chain conveyor for moving the base with the welded frame of the windshield at the position loading and unloading, respectively, of the body and base with a gantry manipulator corresponding to the swing-out tables. In addition, the mechanized assembly-welding section of the base with the windshield frame includes a stationary conductor with a pivot arm, on which the forming equipment of the windshield frame is located, and a roll-out table with a base conductor installed with the ability to move perpendicular to the technological axis of the line by hiding the portal carriage the manipulator, designed to capture the base with a welded frame of the wind edema from the conductor roll-out table, made with the possibility of rotation of 90 ^o . At the same time, the sidewall tack conductor is equipped with an automatic side feed and installation device made in the form of drain sections of the monorail, and the chain conveyors for moving the finished body and the base with a welded windshield frame are each equipped with two groups of lodges mounted on slots in mutually opposite positions relative to the horizontal plane of symmetry of the conveyors and installed with the possibility of alternating admission to the loading and unloading position, respectively, to and the call or the base of each group lodgements one conveyor or lodgements groups relating to equal conveyors. It should also be said that the mold-forming roof conductor of the multi-gantry portal manipulator corresponding to the body verification section includes self-aligning clamps made in the form of pneumatic cylinders, the rod of each of which is connected via an articulated lever mechanism with an axis mounted with the possibility of rotation in the carriage frame, with which the lower clamping cam is rigidly connected and relative to which the pneumatic cylinder body supporting the upper clamping cam is pivotally mounted, in this case Neno hole, wherein a gap is fixed in the frame of the carriage stop angular position of the pneumatic cylinder.

Performing assembly and welding posts in the form of a mechanized assembly-welding base section located at the beginning of the line with a windshield frame and successively arranged behind it in pairs relative to the technological axis of the conductor tack line of the sidewalls and forming the opening of the rear doors and the body welding section with the roof welded together with Moreover, automatic loading devices, made in the form of multi-gantry portal manipulators, allows with a high degree of automation Assembly-welding of a car body, in particular a van body and a minibus, providing for the sequential assembly of body parts. The difference between the van and the minibus is only in the presence of the through openings for windows and additional elements for fastening the seats and seat belts on the base. In addition, the use as a transport for satellites of swing-out tables, on each of which there are two satellites with the possibility of their reciprocating motion together with the table and tangential roll-out in opposite directions to the sidewall tack conductor and to the body welding section in extreme positions table, allows you to equip the line with only four satellites (provided that both branches of the line work), which greatly simplifies the design of the line and reduces its cost. It should be noted that the tangential roll-out of satellites from the turntable allows the most favorable way to place welding equipment relative to the body being welded, the longitudinal axis of which coincides with the direction of the tangential roll-out, since it becomes possible to arrange welding robots and manual welding equipment not only on both sides of the body, but and from the side of its rear doorway. Moreover, both in the sidewall tack conductor and in the finishing section, the selected body units from the turntable are rolled up with the rear opening forward, which creates the possibility for operators with a high degree of safety and convenience to form the rear door opening, and in the second case eliminates the use of expensive welding robots with the seventh axis, since the assembled body rolls itself onto the standard welding robot with an extended arm located on the side of the rear opening of the body, which at the same time is boiled It has the longest and most laborious seams connecting the sidewalls with the base. Another advantage of using the swing-out tables as a transport for satellites is the ability to supply energy to the satellites (air, power, water) using one-piece sleeves and cables (energy circuits), which is provided by a 180 ^° rotary table rotation, which ultimately also simplifies the design of the line and makes it less expensive. It should also be noted that the supply of the sidewall tack conductor with an automatic side feed and installation device, made in the form of lowering sections of the monorail, also helps to increase the degree of automation of the line, which is especially necessary when assembling vans and minibuses, whose body units have large dimensions and weight.

Another significant difference of the claimed line is the loading and welding of the roof directly on the body welding section, which reduces the number of assembly and welding positions, and for the implementation of the above operation, the multi-rail portal manipulator is equipped with a forming roof conductor with self-adjusting clamps made in the form of swinging pneumatic cylinders with clamping cams. In addition, the implementation of the chain transport for moving the finished body and the base with a welded-on windshield frame in the form of separate chain conveyors, each of which is equipped with two groups of lodgements mounted on chains in mutually opposite positions relative to the horizontal plane of symmetry of the conveyors and installed with the possibility of alternating flow to the loading and unloading position, respectively, of the body and base of either each lodgement group of one conveyor or lodgement group c, relating to different conveyors, the first conveyor extending across the width of the second conveyor at the aforementioned position, eliminating the influence of chain drawing, providing accurate aiming of the mounting lodges on the loading and unloading positions, and eliminating the need for a gantry manipulator carriage designed to load the finished conveyor body swivel 180 ^o , and also allows for non-synchronous operation of the line. All this makes the line more technological and convenient for maintenance. The compactness of the line and the convenience of its maintenance are also achieved by rolling out the table with the base conductor on the mechanized section of the base assembly-welding with the windshield frame perpendicular to the technological axis of the line, as a result of which the operator can freely access the stationary conductor with a rotary lever for the windshield frame, with with which the movable base conductor is paired, and the windshield frame is conveniently loaded and welded. In this case, the execution of the carriage of the portal manipulator, designed to capture the base with a welded windshield frame from the roll-out table conductor, rotatable by 90 ^° , subsequently allows the assembled body to be rolled out from the rotary-roll tables to the assembly and welding posts with the rear opening forward, which, as indicated above, it also provides convenience of line maintenance, a high degree of safety of manual welding and control operations, as well as cheaper line through the use of standard robots.

 In FIG. 1 shows a perspective view of a car body, in this case a van, with characteristic welds; in FIG. 2, section AA in FIG. one; in FIG. 3 perspective view of the body parts of the van; in FIG. 4 general view of the lines in plan; in FIG. 5 view B in FIG. 4 mechanized section of the assembly-welding of the base with the windshield frame and the corresponding portal manipulator; in FIG. 6, view B in FIG. 4 conductor tack sidewalls and the formation of the opening of the rear doors; in FIG. 7 section GG in FIG. 4 - a swing-out table with a corresponding portal manipulator and chain conveyors for moving the finished body and base with a windshield frame welded to it; in FIG. 8 is a section DD in FIG. 4 section of the body welding and roof welding simultaneously with the corresponding portal manipulator, as well as the chain conveyor for moving the finished body and the lifting section of the roofs; in FIG. 9 section EE in FIG. 4 chain conveyors for moving the finished body and the base with a welded windshield frame with a tilt-up trolley, a lift and a mounted conveyor of the finished body; in FIG. 10, an external element G in FIG. 4 site for welding the body and simultaneously welding the roof in plan; in FIG. 11 remote element And in FIG. 8, a gantry manipulator carriage with grips and a forming roof conductor; FIG. 12 is a view of K in FIG. eleven; in FIG. 13 the remote moment A in FIG. 11 self-aligning clip forming roof conductor; in FIG. 14 is a section MM in FIG. 13; in FIG. 15 is a section HH in FIG. 14.

 In FIG. 1, 2 and 3 show a car body 1, in this case a van body consisting of a base 2, a windshield frame 3, side walls 4, arch parts 5 and a lower lining 6 of the rear door opening, as well as the roof 7.

 The most typical welding seams connecting the specified body units: seams 8 of the welding of the windshield frame to the base; seams 9 of the sidewall welding to the windshield frame; seams 10 outer seams of sidewall welding to the base; seams 11 inner seams of sidewall welding to the base; seams 12 for welding parts of the arch of the aperture of the rear doors; seams 13 for welding the lower lining of the aperture of the rear doors; seams 14 welding the roof to the body.

 An automated line for assembling and welding car bodies, in particular vans and minibuses, includes a mechanized section 15 for assembling and welding the base 2 with a windshield frame 3 located at the beginning of the line and conductors 16 arranged in series behind it in pairs relative to the technological axis of line 1-1 tacking the sidewalls 4 to the base 2 with the windshield frame 3, in which the rear door opening is also formed by welding the parts of the arch 5 and the lower lining 6, and sections 17 of the welding body 1 with simultaneous welding th roof 7. Between the sidewall tack conductor 16 and the body finishing section 17, there is a satellite transport 18, made in the form of rotary-roll tables 19 also located on both sides relative to the technological axis of the line 1-1, each of which has two satellites with the possibility of their reciprocating movement together with the table and tangential roll out in opposite directions to the conductor tack conductor 16 and to the body welding section 17 in the extreme positions of the table 19.

 The mechanized section 15 of the assembly-welding of the base with the frame of the windshield includes a stationary conductor 20 with a pivoting arm 21, on which the forming tooling 22 for the frame of the windshield 3 is placed, and a roll-out table 23 with the conductor 24 for the base 2, mounted for movement perpendicular technological axis of the line 1-1. The site is also equipped with a latch 25 of the roll-out table 23, a hanging hand-held welding tool 26 and a drive 27 of the windshield frames.

 In the conductor 16 tacking the sidewalls and the formation of the opening of the rear doors there is a stationary receiving section 28 of the turntable 19 with guides 29, along which the satellite 18 is rolled out from the rotary using a reciprocating drive located in the receiving section 28 (not shown) table 19 in the conductor 16. The drive can be mounted on the satellite itself. At the receiving section 28, the latches 30 of the satellites 18 and the forming equipment of the conductor 16 are mounted, made in the form of two discarded trusses 31, into which the sidewalls 4 are laid using the drain sections 32 of the monorail 33 of the side line 4. The conductor is also equipped with automatic welding groups 34 mounted on the discarded farms 31, and hanging hand welding tool 35 located on the side of the free end of the receiving section 28.

 The rotating part of the turntable 19 (the rotation drive is not shown) consists of a base 36, relative to which a turntable 39 rotates on a support 37 and on rollers 38 mounted on the base 36, on which there are separate sections of the guides 29, along which the satellites 18 make a reciprocating movement from the turntable 39 to the stationary receiving section 28 and back. On the turntable 39, the latches 40 of the satellites 18 are mounted, and the satellites themselves are equipped with a forming tool 41. On the rotary-roll table 19, energy circuits 42 are also mounted, made in the form of integral sleeves and cables connected to the satellites 18.

 A similar stationary receiving section 28 of the swing-out table 19 with guides 29 is placed on the body welding section 17 with simultaneous roof welding, as well as in the sidewall tack conductor 16. The satellite clamps 43 are installed on the receiving section, robots are located along its longitudinal sides 44 with an ordinary hand, and from its free end mounted robot 45 with an elongated hand.

The portal manipulator 46, corresponding to the mechanized section 15 for assembling and welding the base with the windshield frame, contains a carriage 47 with a gripper 48, designed to load the base 2 into the conductor 24 of the roll-out table 23, and a carriage 49 with a gripper 50, designed to unload the base with welded to him a frame of the windshield after their assembly-welding, and the last carriage is made to rotate 90 ^o . The portal manipulator 51, corresponding to the swing-out tables 19, includes two carriages of the same type 52 with grippers 53 and a carriage 54 with a gripper 55. The first two carriages are designed for unloading the finished body 1 from the swing-out tables 19, and the carriage 54 for loading onto these base tables 2 with a windshield frame 3 welded to it. The gantry manipulator 56, corresponding to the body welding sections 17 and designed to load the roof 7 onto the assembled body 1, includes two similar carriages 57, on the frame 58 of which each the grippers 59 of the roof 7, vacuum suction cups 60 and the shape-forming roof conductor including self-aligning clamps made in the form of pneumatic cylinders 61, the rod 62 of each of which is connected via the articulated lever mechanism 63 with the axis 64 mounted for rotation in the carriage frame, are mounted which is rigidly connected to the lower clamping cam 65 and relative to which the housing 66 of the pneumatic cylinder 61 supporting the upper clamping cam 67 is pivotally mounted. In the latter, an opening 68 is made, in which it is secured with a clearance The limiter 69 of the angular position of the pneumatic cylinder 61, which is mounted in the carriage frame.

The chain conveyor 70 for moving the base 2 with the windshield frame 3 (inlet) welded to it and the chain conveyor 71 for moving the finished body 1 (outlet) are located on one axis corresponding to the technological axis of line 1-1, parallel to which there is a chain conveyor 72 for moving the roof 7. At the same time, the chain conveyor 71 covers the width of the chain conveyor 70 at position 73 of loading the finished body onto the conveyor 71 with carriages 52 and unloading from the base conveyor 70 with the windshield frame by the carriage 54 of the portal mani puller 51. The chain conveyor 70 for moving the base with a welded windshield frame and the chain conveyor 71 for moving the finished body are equipped with two groups of lodges 74 and 75, respectively, while the groups of lodges of each conveyor are mounted on chains in mutually opposite positions relative to the horizontal plane of symmetry of the conveyors 11- 11, and along the length of the last group of lodges related to both one and different chain conveyors are installed relative to each other with the possibility of alternating in the optimal time mode, both to the extreme loading (unloading) positions of the conveyors 70 and 71, and to their common position 73. At the end of the chain conveyor 71 there is a reciprocating lifting and swiveling carriage 76, designed to be removed, turned on 90 and the installation ^o the body 77 on the lift forks 78 which serves to transmit the finished body on overhead conveyor 79. Chain conveyor 72 is provided with a movement of the roof portal manipulator 80 the carriage 81 intended for loading on the roof Hubsysteme Lifting section 82, which delivers them to the carriages 57 of the manipulator gantry 56.

 An automated line for the assembly and welding of car bodies, in particular vans and vans, operates as follows.

From the assembly-welding line of the base 2, the latter using the carriage 47 with the capture 48 of the portal manipulator 46 is moved to the mechanized section 15 of the assembly-welding of the base 2 with the windshield frame 3 and loaded into the jig 24 of the roll-out table 23. The base is fixed and clamped in the jig 24 and then the roll-out table 23, moving perpendicular to the technological axis of line 1-1, rolls out the base 2 to the stationary conductor 20. By this time, the operator sets the operator from the drive 27 into the mold tooling 22 of the swing arm 21 I frame of the windscreen 3. After vykata table 23 is fixed a clamp 25, the operator is instructed to rotate the lever 21, whereby the base frame 2 mates with the windscreen 3. Thereafter, manual welding tool 26 penetrates the seams 8 which connect the aforementioned body sites. Then, at the command of the operator, the pivot arm 21 of the stationary conductor 20 returns to its original position, and the roll-out table 23 in automatic mode after unlocking moves back under the manipulator 46. Next, the carriage 49 with a gripper 50, which takes the place of the carriage 47, which has moved beyond the next base, unloads the last welded thereto with the frame of the windshield 24 of the conductor draw-out section 23 and by expanding the base 90 ^o, moves it forward to the front of the loading station, located at the beginning of the chain conveyor 70. If k then this position came lodgements group 74 of the chain conveyor 70, the grip 50 of the carriage 49, sinking, sets the base to the frame of the windshield to these lodgements. The command to turn on the chain conveyor 70 and further move the base with the welded windshield frame to position 73, which is the common position of the chain conveyors 70 and 71, from which the base is unloaded, and then loaded into the satellite of the swing-out table and onto which the finished body is loaded , is given in the presence of a free satellite on one of the swing-out tables and in the absence of a finished body at the aforementioned position.

 It should be said that both branches of the line, located after the mechanized section of the assembly-welding base with the windshield frame and including the conductors for tacking the sides and forming the opening of the rear doors, swing-out tables and sections of the body welding with simultaneous welding of the roof, work in non-synchronous mode, involving many options for the mutual passage of body parts through these areas in the process of assembly-welding.

Therefore, suppose that on the right branch of the line, satellites 18 with assembled body units roll out along the guides 29 from the turntable 39 of the turntable 19 in opposite directions to the stationary receiving sections 28 of this table located in the sidewall tack conductor 16 and on the body welding section 17 and the finished body, unloaded before this from the right satellite of the right swing-out table 19 with the carriage 52 with the capture of the 53 portal manipulator 51, was loaded after the satellites were rolled out by the same carriage to position 73 with finding I’m on it with a group of lodges 75 of the chain conveyor 71. If there is a finished body at position 73, the chain conveyor 71 is turned on and takes the body to the unloading position on the tilt-up carriage 76 and then by the lift 78 to the overhead conveyor 79. By this time, on the left branch of the line after the end of the process in the jig 16 of the sidewall tack and on the body welding section 17, the satellites 18, respectively, with the assembled and finished body are rolled out from the stationary receiving sections 28 along the guides 28 onto the turntable 39 ykatnogo table 19 and fixed on it clamps 40. The finished body is discharged via the carriage 52 to the left gripper 53 of the manipulator gantry 51 and quickly removed to the left. Then the turntable 39 on the support 37 and the rollers 38 of the base 36 is rotated 180 ^o , after which the unlocked satellite 18 with a picked up body (without a roof) is rolled out from the turntable 39 to the receiving section 28 of the body welding section 17. Thus, the right-hand satellite 18 of the left swing-out table 19 at this point in time appears to be free, as well as the common position 73 of the chain conveyors 70 and 71, with which, as mentioned above, the chain conveyor 71 was assigned to the unloading position body 1, welded on the right branch of the line. The absence at the position 73 of the finished body and the presence of a free satellite on the left swing-out table gives the command to turn on the chain conveyor 70, which moves the base with the windshield frame welded to it to position 73.

After the grip 55 of the carriage 54 of the portal manipulator 51 removes the base with the windshield frame from this position of the chain conveyor 70, the command is given to turn on this conveyor again, as a result of which one group of lodges 74 leaves position 73 and the other is aimed at the loading position of the base with a windshield frame from the mechanized section 15 to the chain conveyor 70, where the capture of the carriage 49 carries out the next installation of this sub-assembly. At the same time, the base with the windshield frame, taken from position 73 of the conveyor 70, is loaded into the free right satellite 18 of the left rotary-roll table 19 and fixed in it using the forming tool 41, after which the satellite along the guides 29 is rolled out from the turntable 39 swivel-roll table 19 to its stationary receiving section 28, located in the conductor 16 tacking sidewalls and the formation of the opening of the rear doors. If at this point in time on the right branch of the line in the conductor tack 16 of the sidewalls and on the body welding section 17, the technological process has not yet completed, and after unloading the finished carriage 52 to the right with the carriage 52 and turning the circle 39 by 180 ^{o, it has} not formed free satellite, then immediately after the start of moving the left carriage 52 with the finished body 1 and the carriage 56 to the right, the chain conveyor 71 is turned on and a group of lodges 75 comes to position 73.

 In this case, the carriage 55 moving to the right runs across the longitudinal axis of the chain conveyors 70 and 71, which coincides with the technological axis of the line 1-1, (position 73), and the grab 53 of the carriage 52 lowers the finished body from the left swing-out table onto the lodges 75 of the chain conveyor 71 If, however, by the time the finished body was loaded from the left swing-out table onto the chain conveyor 71 on the right branch of the line, the process had already completed and a free satellite appeared on the swing-out table 19 of this branch, requiring priority loading on a base frame with a windshield from the position 73, the chain conveyor 70 is activated, by which the above-mentioned position fed a regular basis with the frame of the windscreen. Moving to the right together with the carriage 52 with the finished body, the carriage 55 captures along the way with its grab 54 the base with the windshield frame from position 73 of the chain conveyor 70 and loads it into the free satellite of the right swing-out table 19, which then rolls out into the junction box conductor 16 and the formation of the opening of the rear doors. Immediately after capturing from position 73 of the aforementioned sub-assembly, both chain conveyors 70 and 71 are turned off and the group of lodgements 74 of the chain conveyor 70 located at position 73 is replaced in the optimal time mode by the group of lodgements 75 of the chain conveyor 71, to which the left carriage 52 portal manipulator 51 is loaded ready-made body 1 from the left swing-out table 19.

 After that, the chain conveyor 71 is turned on, which takes the finished body to the unloading position on the swing-out cart 76 and then by the lift 78 to the overhead conveyor 79. If by this time, now on the left branch of the line, the technological process has not yet been completed (on the right branch the welded body is ready to be loaded onto the chain conveyor 71) and there is no free satellite formed on the swing-out table of this branch, then immediately after the start of moving the right carriage 52 with the finished body 1 and the carriage 55 to the left, the chain transport again turns on p 71 and the group of lodges 75 comes to position 73. At the same time, moving to the left, the carriage 55 runs over the longitudinal axis of the chain conveyors 70 and 71, and the grab 53 of the right carriage 52 lowers the finished body from the right swing table 19 to the group of lodges 75 of the chain conveyor 71, which, including, leads him to the unloading position.

 Next, one of the options for the line, described at the beginning and beginning with the fact that at position 73 there is no ready-made body, and after some time a free satellite appears on the left swing-out table, is repeated, as a result of which a command is given to turn on the chain conveyor 70, which moves to position 73 another base with a windshield frame. If, by the time the finished body is loaded from the right swing-out table onto the chain conveyor 71, the technological process on the left branch of the line has already been completed, the process of first loading the free satellite of the left swing-out table and then loading the finished body is similar to the process of loading the finished bodies from the left rotary-roll-out table, with the only difference being that the carriage 55, an exciting base along the way with the windshield frame, and the carriage 52 with the finished body move to the left.

 In conditions of non-synchronous operation of the line, in addition to the above, other options are also possible, in particular when the line is turned on when all four satellites are unloaded, or when the bases for some reason do not enter the line and rotate-roll out tables are completely unloaded. In addition, the line can temporarily or permanently operate on one branch. All operating options are provided automatically without any readjustment by the line control system, including programmable controllers (1st level of control) and computer software (2nd level of control).

 The technological process of assembly-welding of body assemblies in the conductor 16 of the sidewall tack and the formation of the rear door opening and in the body welding section 17 with the simultaneous welding of the roof is as follows.

After loading into a free satellite 18 one of the swing-out tables 19 (for example, the left) of the base 2 with a windshield frame 3 welded to it and fixing it using the forming tool 41, the base on the satellite along the guides 29 rolls out with the rear opening forward to the receiving section 28 of the turntable 19 located in the jig 16 of the sidewall tack. The satellite is fixed using latches 30, after which the trusses 31 are thrown into which the sidewalls 4 are laid in advance using the drain sections 32 of the monorail 33, the latter rotate and pair with the base 2. After visual inspection, including inside the body, where the operators there is safe and unhindered access, a command is given to trigger automatic welding groups 34 that grab the sidewalls to the base with the windshield frame at the seams 9 and 10. At the same time, operators set the waist of the arch 5 and the lower plate 6, and according to the patterns, with the help of the suspended hand-held welding tool 35, an aperture of the rear doors is formed and welded (seams 12 and 13), and placement from the side of the last operators and the hand-held welding tool, which are not intersected by satellite transport, allows a high degree of security and convenience to form the opening of the rear doors. After grabbing the sidewalls, the satellite is unlocked and it returns to the turntable 39 of the turntable 19 with the selected body along the guides 29, is fixed on it by the clamps 40 and after the finished body is rolled out onto the same table from section 17, unloaded and quickly removed by the carriage 52 left turns along with turning another by 180 ^o, after which also the rear opening rolls forward on the free portion 17. In the satellite with the position 73 of the chain conveyor 70 carriage 54 is loaded with the following base welded thereto p my windscreen, after which the satellite rolls with rotational-withdrawable section 19 in the conductor 16 and tack sidewalls forming the opening rear doors.

 During the roll-out of the satellite 18 with the assembled body to the back-welding section 17, the front openings create favorable conditions for the optimal use of the working area of robots 45 with an elongated arm, which during intermediate stops (or synchronized with the work of the roll-out robots) begin to boil the longest and most labor-intensive internal seams 11 welding the sidewalls 4 to the base 2, while the robots 44 also weld the welds falling into their working area as the satellites roll out (9, 10). After the final roll-out of the satellite 18 with the assembled and partially boiled body (without a roof) to the receiving section 28 located on the body welding section 17 and fixing it with the latch 43, the portal manipulator 56 is fed to this section of one of the carriages 57 (in this case, the left) the roof 7, which before this the carriage 81 of the portal manipulator 80 is mounted from the roof line to the chain conveyor 72, from where it is delivered to the carriages 57 using the lifting section 82. Using the grippers 59 mounted on the frame 58 of the carriage 57, the roof is unloaded with Hubsysteme Lifting section 82 and is moved to the body portion 17 dovarki. After the roof 7 is over the body 1, the suction cups 60 are turned on, and the grips 59 are pulled to the side (the retractable clamps of the forming jig are in the retracted position), without interfering with the roof dropping onto the body 1. After installing the roof behind the body, the self-installing clamps shape-forming roof conductor, made in the form of oscillating pneumatic cylinders 61, with which the roof is finally based and pressed against the body.

 This process is as follows. Each pneumatic cylinder 61 is held in the retracted position by a stopper 69, which is in contact with the edge of the hole 68 made in the upper clamping cam 67, while the lower clamping cam 65 is also in the retracted position. After the pneumatic cylinders 61 are activated, the rod of each of them, moving downward, by means of the articulated lever mechanism 63 begins to rotate the axis 64 with the lower gripping cam 65 rigidly fixed on it, thereby leading it to the body flange 1. Having rested against it, the cam 65 stops, while the housing 66 of the pneumatic cylinder 61, which carries the upper clamping cam 67, pivots the remaining stroke of the rod 62, rotates on the axis 64, thereby pressing the mating flanges of the body and roof. In the pressed state, the roof 7 is grabbed by the robots 44 to the body 1 at the seams 14, after which the stem 62 moves upward, the cams are unclenched, the pneumatic cylinders are retracted to the sides and the carriage 57 returns to its original position, thereby preventing further roof welding and body welding in general (seams 9, 10, 11 and 14).

After the technological process in the conductor 16 and in section 17, the satellites, respectively, with the assembled and the finished body are rolled out onto the swing-out table, from which the finished body is unloaded by one of the carriages 52 and quickly retracted to the side (in this case to the left), after which the turntable 33, turning 180 ^o , returns to its original position. The following base with a windshield frame is installed on a free satellite, and after the satellites are rolled out into the sidewall tacking conductor 16 and on the body welding section 17, the finished carriage with the carriage 52 is loaded onto the lodges 75 of the chain conveyor 71 that have approached position 73. Next, using a tilt-up trolley 76 the finished body is removed from the conveyor 71, rotated 90 ^° and in this position, which is the most convenient for transportation, it is mounted on the shafts 77 of the elevator 78, which then automatically places the finished body on a suspension th conveyor 79.

 The operation of the right branch of the line, partially described earlier, is similar to the operation of its left branch, both vans and minibuses can be welded on both. In addition, the presence of two branches allows you to switch to a new model of the body to be welded without stopping the line, for this purpose, mainly, the readjustment of one of the most labor-intensive conductor 16 tack sidewalls. In addition, the reliability of the line increases significantly, since the body finishing section 17 and the most complex conductor 16 of the sidewall tacking of one swing-out table are always duplicated by the same section and the conductor of the second table. It should also be said that in conditions of non-synchronous operation of the line, the presence of separate chain conveyors for moving the finished body and base with a windshield frame welded to it allows increasing the load factor of the equipment, which increases the line productivity by 6-8%

Claims (6)

 1. Automated line for assembly and welding of car bodies, containing technological satellites transport, welding equipment, including welding work, automatic welding groups and manual welding tools and devices for loading and unloading, interconnected by chain conveyors for moving body units and bodies, characterized in that it is equipped with a mechanized section of the assembly-welding base with a windshield frame and sequentially located behind it in pairs relative to the technological axis of the line by two conductors for tacking the sides and forming an aperture of the rear doors and two sections of body welding with simultaneous welding of the roof, the satellite transport is made in the form of rotary-sliding tables placed on both sides relative to the technological axis of the line, each of which is located between the sidewall tack conductor and the rear door opening formation and the body weld and roof weld area and each of which is diametrically opposite about two satellites with the possibility of reciprocating movement in opposite directions and rolling out the tack of the sidewalls and the body welding section into the conductor, the loading and unloading devices are made in the form of multi-gantry portal manipulators, the first of which is installed on the mechanized assembly-welding section of the base with frame the windshield and is located along the technological axis of the line, and the other two are installed respectively in the area of the location of the swivel tables and sections of the weld body and are arranged perpendicular to this axis, while the multi-gantry portal manipulator of the lid welding sections additionally contains a forming roof conductor, and the chain conveyors for moving the base with the welded frame of the windshield and the finished body are located one after the other on the technological axis of the line parallel to which the chain conveyor for moving the roof is located, the end of the chain conveyor for moving the base with the welded-on windshield frame is located inside the end of the chain conveyor displacements of the finished body in the loading position and the unloading, respectively, of the body and the base of the portal manipulator corresponding tilt-and-roll-out tables.  2. The line according to claim 1, characterized in that the mechanized section of the assembly-welding of the base with the windshield frame includes a stationary conductor with a pivot arm and a forming tool on the windshield frame and a draw-out table with a conductor for the base mounted with the possibility displacement perpendicular to the technological axis of the line. 3. The line according to claims 1 and 2, characterized in that the carriage of the portal manipulator for gripping the base with a welded-on windshield frame from the roll-out table conductor is mounted rotatably by 90 ^° .  4. The line according to claim 1, characterized in that the sidewall tack conductor is equipped with an automatic side feed and installation device made in the form of monorail sections mounted for movement.  5. The line according to claim 1, characterized in that the chain conveyors for moving the finished body and the base with a welded windshield frame are each equipped with two groups of lodges mounted on chains in mutually opposite positions relative to the horizontal plane of symmetry of the conveyors and mounted with the possibility of alternating movement to the position loading and unloading, respectively, of the body and base, or of each group of lodges of the same conveyor, or of the group of lodges related to different conveyor m.  6. The line according to claim 1, characterized in that the forming roof conductor consists of self-adjusting clamps, each of which is made in the form of pneumatic cylinders, a linkage mechanism, lower and upper clamping cams and a limiter for the angular position of the pneumatic cylinder, and each carriage of the portal manipulator section body welding and roof welding contains a frame with an axis, while the rod of each pneumatic cylinder is kinematically connected by a pivot-lever mechanism with the axis of the frame, the lower clamping cam is rigidly connected with th frame and the body of the pneumatic cylinder is articulated on this axis, the upper clamping jaw is mounted on the pneumatic cylinder body and an opening therein, wherein the limiter is located with a gap of the angular position of the pneumatic cylinder, which is fixed in the frame of the carriage.

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