CN220148495U - Inbound shunting device of hanging assembly line - Google Patents

Abstract

The utility model discloses an inbound shunting device of a hanging assembly line, which comprises a first shunting seat and a second shunting seat which are fixedly connected with a main rail beam, and is characterized in that: the first shunt seat is provided with a shunt swinging head capable of rotating up and down and an inbound swinging head capable of rotating left and right. According to the station entering shunting device, the shunting swinging head and the station entering swinging head are matched to work, so that stable rail transfer of hanging is realized, and the rail matching precision and the service life of a hanging assembly line are improved.

Description

Inbound shunting device of hanging assembly line

Technical Field

The utility model relates to the technical field of hanging systems, in particular to an inbound shunting device of a hanging assembly line.

Background

The hanging assembly line is widely used for production enterprises such as clothing, home textile, and the like, and comprises a main rail and a support rail, wherein a plurality of rail changing modes of a hanger entering the support rail from the main rail are adopted, but most of the hanger adopts a rail changing mode of a support rail switching mode, a swing rail on a rail changing device is fixed on the support rail, and then the connection and the separation of the swing rail and the main rail are controlled by a control device. However, the operation efficiency of the mode is low, and the clothes hangers are easy to fall from the joint of the main rail and the transition rail; the swing rail can be deformed slowly after being used for a long time, so that the swing rail and the main rail cannot be tightly attached, the material rack cannot enter the support rail, and the rail matching precision is low.

Disclosure of Invention

Aiming at the technical problem that rail matching precision is low due to slow deformation of a swing rail after long-term use, the utility model provides an inbound shunting device of a hanging assembly line, which realizes stable rail change of hanging by cooperation of shunting swing heads and inbound swing heads.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides a hang incoming station diverging device of assembly line, includes first reposition of redundant personnel seat, second reposition of redundant personnel seat, characterized by with main rail crossbeam fixed connection: the first shunt seat is provided with a shunt swinging head capable of rotating up and down and an inbound swinging head capable of rotating left and right.

In order to optimize the technical scheme, the utility model further comprises the following improved technical scheme.

The lower part of the first split-flow seat is provided with a split-flow swing head mounting part; an input track part which is in butt joint with the first travelling track is arranged on the upper end surface of the split swing head mounting part; the second flow dividing seat is provided with an output track part which is in butt joint with the second walking track.

One end of the shunt swing is rotationally connected with the shunt swing mounting part; the middle part system of reposition of redundant personnel pendulum head installation department has a cavity, is equipped with reposition of redundant personnel cylinder mount pad in the cavity, installs the reposition of redundant personnel cylinder on the reposition of redundant personnel cylinder mount pad, the piston rod of reposition of redundant personnel cylinder with reposition of redundant personnel pendulum head is connected.

A sliding block is arranged on a piston rod of the shunt cylinder; the front end of the split-flow air cylinder mounting seat is provided with a sliding seat, the sliding seat is provided with a sliding groove, and the sliding block is slidably arranged in the sliding groove; the slider is rotatably connected with one end of the shunt connecting rod, and the other end of the shunt connecting rod is rotatably connected with the middle part of the lower end face of the shunt swing.

One side of the split-flow swing head installation part is provided with a downward inclined part; the two sides of the split-flow swinging head are provided with extension parts which can be abutted against the inclined parts. The sliding block is pulled to slide rightwards along the sliding groove through the split air cylinder, the split connecting rod drives the split swing head to rotate downwards, the split swing head is abutted on the inclined plane, and no-difference butt joint between the input track part and the connecting track is realized.

A connecting seat is arranged on the cavity bottom plate close to the inclined part and is connected with the rear part of the first diversion seat through a connecting block; the upper surface of the connecting seat is provided with a connecting track for guiding the movement of the material rack.

The first split-flow seat is provided with a swing cylinder mounting seat, and a swing cylinder is rotatably arranged on the swing cylinder mounting seat; the piston rod of the head swing cylinder is rotatably connected with one end of the entering connecting rod, and the other end of the entering connecting rod is rotatably connected with the middle part of the lower end face of the entering swing head.

Compared with the prior art, the inbound distribution device has the advantages that the first distribution seat is provided with the distribution swing head capable of rotating up and down and the inbound swing head capable of rotating left and right, and the distribution swing head and the inbound swing head are matched for working, so that stable rail transfer of hanging is realized, and the rail matching precision and the service life of a hanging assembly line are improved.

Drawings

Fig. 1 is a diagram showing a split pendulum according to an embodiment of the present utility model in a pendulum up state.

Fig. 2 is a diagram showing the split pendulum according to an embodiment of the present utility model in a lowered state.

Fig. 3 is an exploded schematic view of an inbound diverting device.

Description of the embodiments

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings.

Fig. 1 to 3 are schematic structural views of the present utility model.

Wherein the reference numerals are as follows: the main rail beam 1, the first traveling rail 2, the second traveling rail 3, the first split seat 4, the split swing head mounting portion 4a, the input rail portion 4b, the inclined portion 4c, the second split seat 5, the output rail portion 5a, the track rail beam 6, the split swing head 8, the split cylinder mounting seat 9, the split cylinder 10, the slide seat 11, the slide block 12, the slide groove 13, the split connecting rod 14, the swing head cylinder 15, the inbound connecting rod 16, the inbound swing head 17, the connecting seat 18, the connecting block 18a, the connecting rail 19, the inbound rail 20, the cavity 21, the material frame 22, and the inbound mounting seat 23.

The hanging assembly line comprises a main rail beam 1 and a plurality of branch rail beams 6 arranged on the main rail beam 1, wherein a walking main rail is arranged below the main rail beam 1, and an inbound rail 20 is arranged below each branch rail beam 6. An inbound diverting device is arranged at the diverting position of the walking main rail, is connected between the first walking rail 2 and the second walking rail 3 of the walking main rail, and can divert a material frame 22 conveyed on the walking main rail onto the inbound rail 20.

The inbound shunting device comprises a first shunting seat 4 and a second shunting seat 5 which are fixedly connected with the main rail beam 1 in sequence. The lower portion of the first diverting seat 4 has a diverting swing mounting portion 4a. The upper end surface of the split swing head mounting portion 4a is provided with an input rail portion 4b which is abutted against the first travel rail 2. The second flow dividing seat 5 is provided with an output rail portion 5a, and the output rail portion 5a is abutted against the second travel rail 3.

A split-flow swinging head 8 which can rotate up and down is provided between the input rail portion 4b and the output rail portion 5a. One end of the split swing head 8 is rotatably connected with the split swing head mounting portion 4a, and the other end is detachably abutted with the output rail portion 5a. The middle part of the split swing head installation part 4a is provided with a cavity 21, a split cylinder installation seat 9 is arranged in the cavity 21, a split cylinder 10 is arranged on the split cylinder installation seat 9, and a sliding block 12 is arranged on a piston rod of the split cylinder 10. The front end of the split-flow air cylinder mounting seat 9 is provided with a sliding seat 11, the sliding seat 11 is provided with a sliding groove 13, and a sliding block 12 is slidably arranged in the sliding groove 13 to play a role in guiding the sliding block 12. The slide block 12 is rotatably connected with one end of a shunt connecting rod 14, and the other end of the shunt connecting rod 14 is rotatably connected with the middle part of the lower end face of the shunt swinging head 8. The split air cylinder 10 can drive the split swing head 8 to rotate up and down, and when the material frame 22 does not need split on the running main rail, the split swing head 8 rotates to be limited at the upper limit, so that the input track part 4b, the split swing head 8 and the output track part 5a form a conveying channel. When the material frame 22 needs to be split, the splitting swing head 8 rotates to be limited at the lower limit, and the material frame 22 is conveyed to the direction of the entering track 20 through the input track part 4b and the splitting swing head 8.

One side of the split swing head mounting portion 4a has an inclined portion 4c inclined downward. Extension parts are arranged on two sides of the shunt swing head 8, and the extension parts of the shunt swing head 8 can be propped against the inclined part 4c during shunt to play a supporting role.

The bottom plate of the cavity 21 near the inclined part 4c is provided with a connecting seat 18, and the connecting seat 18 is connected with the rear part of the first split-flow seat 4 through a connecting block 18a, so that rigidity is increased, and the connecting seat 18 is prevented from deforming. A connecting rail 19 for guiding the movement of the material frame 22 is arranged on the upper surface of the connecting seat 18, and the output end of the split pendulum 8 is detachably butted with the connecting rail 19.

The connecting seat 18 is provided with a standing swing head 17 which can rotate left and right. The entering swing head 17 is arc-shaped, the right end of the entering swing head 17 is detachably abutted with the entering track 20, and the material rack 22 changes the conveying direction through the entering swing head 17 so as to move to the entering track 20. The entrance rocker 17 is arranged to tilt downward at an angle from the connection track 19 to the entrance track 20, ensuring that the material rack 22 has sufficient power to enter the entrance track 20 through the entrance rocker 17.

The first split-flow seat 4 is provided with a swing cylinder mounting seat, and a swing cylinder 15 is rotatably arranged on the swing cylinder mounting seat. The piston rod of the head swing cylinder 15 is rotatably connected with one end of the inbound connecting rod 16, the other end of the inbound connecting rod 16 is rotatably connected with the middle part of the lower end face of the inbound swing head 17, and the head swing cylinder 15 can drive the inbound swing head 17 to rotate left and right so as to be in butt joint with or separated from the inbound track 20.

When detecting that the material rack 22 needs to enter the station, the piston rod of the shunting cylinder 10 is retracted, and the shunting swing head 8 rotates downwards to abut against the inclined part 4c, so that the shunting swing head 8 is matched and butted with the connecting track 19 to realize track change; and meanwhile, a piston rod of the swing head cylinder 15 extends out to enable the docking swing head 17 to be matched and docked with the docking track 20. When the material rack 22 moves to the shunt swing 8, it slides down from the shunt swing 8 and then enters the inbound track 20 along the connecting track 19 and the inbound swing 17. When the working node does not need to enter the station for shunting, the piston rod of the shunting cylinder 10 stretches out to enable the shunting swing head 8 to be matched and butted with the output track part 5a, and the material rack 22 moves to the output track part 5a through the shunting swing head 8. The piston rod of the head-swing cylinder 15 is retracted, separating the head-swing 17 from the head-swing track 20, so as to avoid interference of the head-swing 17 with the carriage 22 running on the main track.

The preferred embodiments of this utility model have been described so far that various changes or modifications may be made by one of ordinary skill in the art without departing from the scope of this utility model.

Claims (5)

1. The utility model provides a hang incoming station diverging device of assembly line, includes first reposition of redundant personnel seat (4), second reposition of redundant personnel seat (5) with main rail crossbeam (1) fixed connection, characterized by: the first diversion seat (4) is provided with a diversion swinging head (8) capable of rotating up and down and a station entering swinging head (17) capable of rotating left and right; the lower part of the first diversion seat (4) is provided with a diversion swing head mounting part (4 a); an input track part (4 b) which is in butt joint with the first travelling track (2) is arranged on the upper end surface of the split swing head mounting part (4 a); the second flow dividing seat (5) is provided with an output track part (5 a) which is in butt joint with the second walking track (3); one end of the shunt swing (8) is rotationally connected with the shunt swing mounting part (4 a); the middle part of the split swing head installation part (4 a) is provided with a cavity (21), a split air cylinder installation seat (9) is arranged in the cavity (21), a split air cylinder (10) is arranged on the split air cylinder installation seat (9), and a piston rod of the split air cylinder (10) is connected with the split swing head (8).

2. The inbound distribution device of claim 1, wherein: a sliding block (12) is arranged on a piston rod of the split-flow cylinder (10); the front end of the split-flow air cylinder mounting seat (9) is provided with a sliding seat (11), the sliding seat (11) is provided with a sliding groove (13), and the sliding block (12) is slidably arranged in the sliding groove (13); the sliding block (12) is rotatably connected with one end of the shunt connecting rod (14), and the other end of the shunt connecting rod (14) is rotatably connected with the middle part of the lower end face of the shunt swing (8).

3. The inbound distribution device of claim 2, wherein: one side of the split-flow swing head mounting part (4 a) is provided with a downward-inclined part (4 c); the two sides of the split-flow swinging head (8) are provided with extension parts which can be abutted against the inclined parts (4 c).

4. A docking and splitting device as in claim 3, wherein: a connecting seat (18) is arranged on the bottom plate of the cavity (21) close to the inclined part (4 c), and the connecting seat (18) is connected with the rear part of the first diversion seat (4) through a connecting block (18 a); a connecting track (19) for guiding the movement of the material rack (22) is arranged on the upper surface of the connecting seat (18).

5. The inbound distribution device of claim 4, wherein: the first split-flow seat (4) is provided with a head-swing cylinder mounting seat, and a head-swing cylinder (15) is rotatably arranged on the head-swing cylinder mounting seat; the piston rod of the swinging head cylinder (15) is rotatably connected with one end of an entering connecting rod (16), and the other end of the entering connecting rod (16) is rotatably connected with the middle part of the lower end surface of the entering swinging head (17).