CN219408030U - Staggered type iron shaft conveying structure - Google Patents

Abstract

The utility model relates to a staggered iron shaft conveying structure, which comprises: the device comprises a bottom plate, a movable plate, a first toothed plate, a first tooth groove, a second toothed plate and a second tooth groove, wherein the movable plate is connected to the top of the bottom plate in a sliding mode and is arranged oppositely; the first tooth grooves and the second tooth grooves are staggered; according to the staggered type iron shaft conveying structure, the first tooth grooves and the second tooth grooves which are staggered mutually are arranged, when the lifting cylinder drives the second toothed plate to lift, the iron shafts are conveyed step by step between the first tooth grooves and the second tooth grooves, and the oppositely arranged moving plates can also meet iron shaft conveying tasks with different lengths.

Description

Staggered type iron shaft conveying structure

Technical Field

The utility model belongs to the technical field of conveying of iron shafts after gluing, and particularly relates to a staggered iron shaft conveying structure.

Background

The rubber coating process of the iron shaft is characterized in that the rubber roller product is required to uniformly coat a glue on the surface of the iron shaft of the fusion part of the iron shaft and the rubber before the rubber and the iron shaft are molded so as to improve the adhesive force between the rubber and the iron shaft, and after the iron shaft is coated with the glue at a coating machine, the iron shaft is required to be taken away from a coating area by a manipulator and then conveyed to a designated station by a conveying structure for subsequent treatment.

Because the glue is smeared on the peripheral surface of the iron shaft, the iron shaft cannot be directly transmitted by using the conveyor belt, otherwise, the glue is adhered to the conveyor belt by the iron shaft placed on the conveyor belt, so that smearing accidents are caused, corresponding jig trays are usually installed on the conveyor belt at equal intervals in the prior art, and the conveyor belt is relied on to drive the jig trays to circularly rotate, so that the conveying of the smeared iron shaft is completed.

The existing conveying structure has the following defects: firstly, in order to meet the requirement of conveying the rubberized iron shafts, a plurality of groups of jig trays are required to be installed on a conveyor belt at equal intervals, which definitely increases the production cost; moreover, the existing conveying structure can only meet the requirement of conveying the iron shafts with single length, and when facing iron shafts with different lengths, conveyor belts with different widths also need to be replaced, so that the conveying structure is poor in universality and high in cost.

Disclosure of Invention

The utility model aims to overcome the defects of high cost and poor universality of a rubberized iron shaft conveying structure in the prior art, and provides a staggered iron shaft conveying structure.

In order to achieve the above purpose, the utility model adopts the following technical scheme: an interlaced iron shaft delivery structure comprising:

the device comprises a bottom plate, a movable plate, a first toothed plate, a first tooth groove, a second toothed plate and a second tooth groove, wherein the movable plate is connected to the top of the bottom plate in a sliding mode and is arranged oppositely;

the first tooth grooves and the second tooth grooves are staggered;

when the second toothed plate rises, the second toothed groove supports the iron shaft in the first toothed groove; when the second toothed plate descends, the iron shaft in the second tooth socket falls into the other group of first tooth sockets.

Optimally, the device also comprises a horizontal sliding rail fixed on the top of the bottom plate, a horizontal sliding block slidingly mounted on the horizontal sliding rail, a first angle plate fixed on the top of the moving plate and a second angle plate arranged on the top of the moving plate in a lifting manner;

the movable plate is fixed on the horizontal sliding block, the first toothed plate is fixed on one side of the first angular plate opposite to the first toothed plate, and the second toothed plate is fixed on one side of the second angular plate opposite to the first angular plate.

Optimally, the lifting device also comprises fixing holes formed in the bottom plate at intervals, fixing pieces fixed at the bottom of the moving plate and matched with the fixing holes, an air cylinder fixing plate fixed on the moving plate, and a lifting air cylinder fixed on the air cylinder fixing plate and used for driving the second angle plate to lift.

Optimally, the first corner plate comprises a first flat corner edge fixed at the top of the movable plate, a first vertical corner edge integrally connected with one side of the first flat corner edge and an avoidance groove formed in the first flat corner edge, and the first tooth plate is fixed on the opposite side of the first vertical corner edge.

Optimally, the second angle plate comprises a second flat angle edge connected with the lifting cylinder, a second vertical angle edge integrally connected with one side of the second flat angle edge and a through groove penetrating through the second flat angle edge, and the second toothed plate is fixed on one side of the second vertical angle edge opposite to the second vertical angle edge.

Optimally, the device also comprises a vertical plate fixed at the top of the moving plate and penetrating through the through groove, a vertical sliding rail fixed on the vertical plate and a vertical sliding block connected on the vertical sliding rail in a sliding way;

the second vertical angle edge is fixed on the vertical sliding block, and the vertical plate is positioned in the avoidance groove.

Optimally, the fixing piece comprises a first fixing plate, an extending plate integrally connected to one side of the first fixing plate, a second fixing plate integrally connected to the extending plate and parallel to the first fixing plate, and a sliding groove formed in the first fixing plate and matched with the fixing hole;

the first fixing plate is fixed on the bottom plate, and the second fixing plate is fixed on the moving plate.

Due to the application of the technical scheme, compared with the prior art, the utility model has the following advantages:

according to the staggered type iron shaft conveying structure, the first tooth grooves and the second tooth grooves which are staggered with each other are arranged, when the lifting cylinder drives the second toothed plate to lift, the iron shafts are conveyed step by step between the first tooth grooves and the second tooth grooves, and the oppositely arranged moving plates can also meet iron shaft conveying tasks with different lengths;

further, the fixing piece is arranged to assist in supporting the moving plate, so that the bearing load of the horizontal sliding block is reduced, and the horizontal sliding block is prevented from being damaged;

further, the arrangement of the vertical sliding block and the vertical sliding rail effectively improves the lifting stability of the second angle plate.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is a cross-sectional view of the present utility model;

FIG. 4 is an enlarged view of the utility model at A in FIG. 1;

FIG. 5 is an enlarged view of the utility model at B in FIG. 1;

FIG. 6 is a schematic view of the first gusset of the present utility model;

FIG. 7 is a right side view of the first gusset of the present utility model;

FIG. 8 is a schematic view of the structure of a second gusset of the present utility model;

FIG. 9 is a schematic view of another angle of the second gusset of the present utility model;

FIG. 10 is a schematic view of the structure of the fixing member of the present utility model;

reference numerals illustrate:

1. a bottom plate;

2. a horizontal slide rail;

3. a horizontal slider;

4. a moving plate;

5. a fixing hole;

6. a fixing member; 601. a first fixing plate; 602. an extension plate; 603. a second fixing plate; 604. a chute;

7. a first gusset; 701. a first flat corner edge; 702. a first vertical corner edge; 703. an avoidance groove;

8. a first toothed plate;

9. a first tooth slot;

10. a second gusset; 101. a second flat corner edge; 102. a second vertical corner edge; 103. a through groove;

11. a second toothed plate;

12. a second tooth slot;

13. a vertical plate;

14. a vertical slide rail;

15. a vertical slider;

16. a cylinder fixing plate;

17. lifting cylinder.

Detailed Description

The utility model will be further described with reference to examples of embodiments shown in the drawings.

As shown in fig. 1 and 2, the structure of the staggered type iron shaft conveying structure is schematically shown, and is generally used in the field of iron shaft gluing technology for conveying iron shafts after surface gluing. The conveying structure comprises a bottom plate 1, a horizontal sliding rail 2, a horizontal sliding block 3, a moving plate 4, a fixing hole 5, a fixing piece 6, a first corner plate 7, a first toothed plate 8, a first tooth slot 9, a second corner plate 10, a second toothed plate 11, a second tooth slot 12, a vertical plate 13, a vertical sliding rail 14, a vertical sliding block 15, a cylinder fixing plate 16 and a lifting cylinder 17.

The bottom plate 1 is a rectangular metal plate and is fixed on an iron shaft processing machine table in a screw fastening mode. The horizontal sliding rail 2 is fixed at the top of the bottom plate 1 in a screw fastening mode, and the horizontal sliding block 3 is slidably arranged on the horizontal sliding rail 2. The movable plates 4 are respectively fixed on the horizontal sliding blocks 3 in two groups, the two groups of movable plates 4 are oppositely arranged, a pushing air cylinder connected with the movable plates 4 is fixed on the bottom plate 1, and the pushing air cylinder drives the movable plates 4 to synchronously move inwards or outwards, so that the iron shaft conveying work of different lengths is met.

The fixing holes 5 are formed in the bottom plate 1 at intervals, and the fixing holes 5 are used for installing the fixing pieces 6. As shown in fig. 10, the fixing member 6 is a schematic structural view of the fixing member 6, and the fixing member 6 includes a first fixing plate 601, an extension plate 602, a second fixing plate 603, and a chute 604. The extension plate 602 is integrally connected to one side of the first fixing plate 601 and is vertically disposed. The second fixing plate 603 is integrally connected to the top of the extension plate 602 and parallel to the first fixing plate 601, and the first fixing plate 601 and the second fixing plate 603 are located on the same side of the extension plate 602. The chute 604 is formed on the first fixing plate 601 and is matched with the fixing hole 5.

In the actual installation, the distance between the two groups of moving plates 4 is appropriately adjusted according to the length of the iron shaft actually conveyed, and after the adjustment is completed, the second fixing plate 603 is fixed at the bottom of the moving plate 4, and the first fixing plate 601 is fixed on the bottom plate 1. By arranging the fixing piece 6, the movable plate 4 is supported in an auxiliary mode, so that the bearing load of the horizontal sliding block 3 is reduced, and the horizontal sliding block 3 is prevented from being damaged.

As shown in fig. 6 and 7, the first corner plates 7 have two groups, which are respectively fixed on the top of the moving plate 4 and move synchronously with the moving plate 4. The first corner plate 7 includes a first flat corner edge 701, a first vertical corner edge 702, and a relief groove 703. The first flat angle side 701 is fixed at the top of the moving plate 4 by means of screw fastening, and the first vertical angle side 702 is integrally connected to the inner side of the first flat angle side 701 and is vertically arranged. Dodging grooves 703 are formed on the first flat angle side 701 at intervals for subsequently dodging the vertical plate 13.

The first toothed plate 8 is fixed on the opposite side of the first vertical corner 702, the first tooth grooves 9 are formed in the first toothed plate 8 at intervals, and the first tooth grooves 9 are used for receiving the glued iron shafts placed on the manipulator. The section of the first tooth groove 9 is V-shaped, so that the iron shaft can be conveniently transferred onto the second tooth groove 12.

As shown in fig. 8 and 9, the second angle plates 10 are two groups, are respectively arranged on the outer sides of the first angle plates 7 in a liftable manner, and drive the second toothed plates 11 to lift by arranging the lifted second angle plates 10, so that the gradual transfer of the iron shaft is completed. The second corner panel 10 includes a second flat corner edge 101, a second vertical corner edge 102, and a through slot 103. The second corner edge 101 is arranged above the first corner edge 701 in a liftable manner, the second vertical corner edge 102 is integrally connected to the inner side of the second corner edge 101 and is vertically arranged, and the second vertical corner edge 102 synchronously lifts along with the second corner edge 101. The through grooves 103 are formed on the second flat angle side 101 at intervals, correspond to the avoiding grooves 703, and are used for accommodating the vertical plates 13.

The second toothed plate 11 is fixed on one side of the second vertical corner 102, the second tooth grooves 12 are arranged on the second toothed plate 11 at intervals, and the second tooth grooves 12 are staggered with the first tooth grooves 9 in the horizontal direction. The section of the second tooth groove 12 is V-shaped, and when the second angle plate 10 ascends, the second tooth plate 11 is driven to synchronously ascend, and the second tooth groove 12 supports an iron shaft in the first tooth groove 9; when the second angle plate 10 descends, the second toothed plate 11 is driven to synchronously descend, the iron shafts in the second tooth grooves 12 fall into the other group of first tooth grooves 9, and the steps are repeated, so that the step-by-step conveying of the iron shafts can be completed.

As shown in fig. 1, the cylinder fixing plate 16 is fixed on the moving plate 4, the cylinder body of the lifting cylinder 17 is fixed on the cylinder fixing plate 16, the guide rod of the lifting cylinder 17 is connected with the second flat angle edge 101 of the second angle plate 10, and the second angle plate 10 is driven to lift under the driving of the lifting cylinder 17.

As shown in fig. 5, the vertical plate 13 is fixed to the moving plate 4 and is located in the escape groove 703, and the top of the vertical plate 13 passes through the through groove 103. The vertical slide rail 14 is fixed in the inboard of riser 13, and vertical slider 15 slidable mounting is on vertical slide rail 14, and the second perpendicular angle limit 102 of second scute 10 is fixed on vertical slider 15, and when second scute 10 goes up and down, vertical slider 15 goes up and down on vertical slide rail 14 in step, improves the stability that second scute 10 goes up and down.

The conveying principle of the staggered iron shaft conveying structure is as follows:

as shown in fig. 4, after the surface of the iron shaft is coated with glue, the external manipulator places the iron shaft in the first tooth socket 9 of the first toothed plate 8, the lifting cylinder 17 drives the second angular plate 10 to lift, the second toothed plate 11 synchronously lifts, the second tooth socket 12 supports the iron shaft in the first tooth socket 9, and the iron shaft falls on the bottom of the second tooth socket 12; then when the lifting cylinder 17 drives the second angle plate 10 to descend, the second toothed plate 11 descends synchronously, the iron shaft in the second tooth groove 12 falls into the other group of first tooth grooves 9, and the conveying work of the iron shaft can be completed by analogy.

The above embodiments are provided to illustrate the technical concept and features of the present utility model and are intended to enable those skilled in the art to understand the content of the present utility model and implement the same, and are not intended to limit the scope of the present utility model. All equivalent changes or modifications made in accordance with the spirit of the present utility model should be construed to be included in the scope of the present utility model.

Claims (7)

1. An interlaced iron shaft delivery structure, comprising:

the device comprises a bottom plate (1), a movable plate (4) which is connected to the top of the bottom plate (1) in a sliding manner and is arranged oppositely, a first toothed plate (8) which is fixed to the top of the movable plate (4), first tooth grooves (9) which are arranged on the first toothed plate (8) at intervals and are used for bearing iron shafts, a second toothed plate (11) which is arranged on the top of the movable plate (4) in a lifting manner, and second tooth grooves (12) which are arranged on the second toothed plate (11) at intervals;

the first tooth groove (9) and the second tooth groove (12) are staggered;

when the second toothed plate (11) rises, the second tooth grooves (12) support the iron shaft in the first tooth grooves (9); when the second toothed plate (11) descends, the iron shaft in the second tooth groove (12) falls into the other group of first tooth grooves (9).

2. The staggered iron shaft conveying structure according to claim 1, wherein: the movable plate also comprises a horizontal sliding rail (2) fixed at the top of the bottom plate (1), a horizontal sliding block (3) slidably mounted on the horizontal sliding rail (2), a first corner plate (7) fixed at the top of the movable plate (4) and a second corner plate (10) arranged at the top of the movable plate (4) in a lifting manner;

the movable plate (4) is fixed on the horizontal sliding block (3), the first toothed plate (8) is fixed on one side of the first angular plate (7) opposite to each other, and the second toothed plate (11) is fixed on one side of the second angular plate (10) opposite to each other.

3. The staggered iron shaft conveying structure according to claim 2, wherein: the lifting device further comprises fixing holes (5) formed in the bottom plate (1) at intervals, fixing pieces (6) fixed at the bottom of the moving plate (4) and matched with the fixing holes (5), air cylinder fixing plates (16) fixed on the moving plate (4), and lifting air cylinders (17) fixed on the air cylinder fixing plates (16) and used for driving the second corner plates (10) to lift.

4. A staggered iron shaft conveying structure as in claim 3, wherein: the first corner plate (7) comprises a first flat corner edge (701) fixed at the top of the movable plate (4), a first vertical corner edge (702) integrally connected to one side of the first flat corner edge (701) and an avoidance groove (703) formed in the first flat corner edge (701), and the first toothed plate (8) is fixed on the opposite side of the first vertical corner edge (702).

5. The staggered iron shaft conveying structure according to claim 4, wherein: the second angle plate (10) comprises a second flat angle side (101) connected with the lifting cylinder (17), a second vertical angle side (102) integrally connected with one side of the second flat angle side (101) and a through groove (103) penetrating through the second flat angle side (101), and the second toothed plate (11) is fixed on the opposite side of the second vertical angle side (102).

6. The staggered iron shaft conveying structure according to claim 5, wherein: the device also comprises a vertical plate (13) fixed at the top of the moving plate (4) and penetrating through the through groove (103), a vertical sliding rail (14) fixed on the vertical plate (13) and a vertical sliding block (15) connected on the vertical sliding rail (14) in a sliding way;

the second vertical corner edge (102) is fixed on the vertical sliding block (15), and the vertical plate (13) is positioned in the avoidance groove (703).

7. A staggered iron shaft conveying structure as in claim 3, wherein: the fixing piece (6) comprises a first fixing plate (601), an extension plate (602) integrally connected to one side of the first fixing plate (601), a second fixing plate (603) integrally connected to the extension plate (602) and parallel to the first fixing plate (601), and a sliding groove (604) formed in the first fixing plate (601) and matched with the fixing hole (5);

the first fixing plate (601) is fixed on the bottom plate (1), and the second fixing plate (603) is fixed on the moving plate (4).