JPS62105626A - Positioning device for cord joining - Google Patents

Abstract

PURPOSE:To enable the titled device to join angular cut cords with each other without generating a step deviation by making an acute-angled part and obtuse-angled part of the angular cut cords coincide with each other, by providing a linear magnet which is contactable with the side edge in the vicinity of the acute-angled part of the angular cut cord and a driving device driving this magnet. CONSTITUTION:Linear magnets 43, 60 which are contactable with side edges in the vicinities 5b, 6b of acute-angled parts of angular cut cords 5, 6 and a driving device driving them are provided, in a cord joining device 11 joining the end fringes of the angular cut cords 5, 6, which are obtained by cutting off bias rubberized cord cloth 1 having a cord 2 made of a ferromagnetic substance such as a steel cord, in order mutually. After deformations in the vicinity 5b, 6b of the acute-angled parts of the angular cut cords 5, 6 have been corrected by bringing the linear magnets 43, 60 into contact with the side edges in the vicinity of the acute-angled parts of the angular cut cords 5, 6 in the cord joining device 11, the cord joining device 11 and driving device are actuated. With this construction, the angular cut cords 5, 6 can be joined with each other without generating a step deviation by making the acute-angled parts of the angular cut cords 5, 6 and obtuse-angled parts 5d, 6d of the angular cut cords 5, 6, which are facing one another, coincide with one another.

Description

[Detailed Description of the Invention] It takes 2 hours x 1 job.The present invention is a rubber tire. ! In connection with construction, when forming a tie V belt material by integrally joining the edges of a parallelogram cord made of rubberized cord cloth with a predetermined width and a predetermined bias angle, The present invention relates to a cord joining positioning device that can accurately align and join the end of a parallelogram cord to be newly joined to the end of a ribbon-like joined cord.

[1 and 1] Conventionally, the cord joining apparatus shown in FIGS. 1 to 4 has been used to sequentially join diagonally formed cords.

The rubberized cord cloth 1 is made by adhering rubber to cords 2 arranged in a wide U pattern in the width direction, and is fed obliquely to a bias cutting machine 4 on a conveyor 3, and is cut at a bias angle by the cutting machine 4. The entry side diagonal cord 5 is cut at α and has a parallelogram shape.

The inlet diagonal cord 5 having a constant IIIW is transferred to the inlet joining conveyor 8 by the inlet conveyor 7 along its joining edge, and is conveyed from the inlet joining conveyor 8 to the cord splicing machine 11 to form the inlet diagonal cord. After the end edge 5a of the cord 5 and the end edge 6a of the outlet diagonal cord 6 are joined, the cord is carried out to the carry-out conveyor 10 by the outlet joint conveyor 9.

This inlet joining conveyor8. The output joining conveyor 9 is divided into several narrow belts and has a variable conveyance length, and is a cord joining machine that rotates around a vertical axis and changes its inclination angle as the bias angle α changes. 11, the input side coupling conveyor 8. Output joint conveyor 9
The length of the conveyance is adjusted.

In addition, the input side joining conveyor 8. Along the side edge of the exit coupling conveyor 9 is an entry guide 12 . An exit guide 13 is provided.

Furthermore, as shown in FIG. 4, the cord splicing machine 11 has locking pawls 14 and 15 that are formed in planar shapes so as to mesh with each other alternately and are swingably connected to each other. 14
．． 15, elastic pressing pieces 18 and 19 that elastically press the f11 locking claws 14 and 15, and a drive means 20 that moves the support member 1B up and down. The locking pawl 14.15 is placed in the open state by the elasticity of the piece 18.19, and the support member 16 is lowered by the operation of the drive means 20, and the locking pawl 14 is brought into contact with the end edge 5a of the entry side diagonal cord 5 and the exit side. When the end edge 6a of the side diagonal cord 6 is contacted and the elastic suppressing piece 18.19 is contracted by the reduction blade of the driving means 20, the locking claws 14.15 are swung and their tips are brought close to each other. , the end edge 5a of the entry side diagonal cord 5 and the end edge 6a of the exit side diagonal cord 6, which are locked by the locking claws 14.15, are drawn together, the edges 5a and 6a are brought into contact, and the entry side is Side oblique code 5. Due to the viscosity of the rubber in the outlet diagonal cord 6, the end edges 5a, 6a of the inlet diagonal cord 5 and the outlet diagonal cord 6 are joined together.

Then, as shown in FIG. 5, the distance X between the entrance guide 12 and the exit guide 13 is set to a constant value, and the entrance diagonal cord 5. Mutual offset of exit side diagonal cord 6 1~ms=
Keep x-w constant and enter diagonal cord5. The entry side diagonal cord 5. The distance P between the end edges 5a, 5a of the exit side diagonal cord 6 is kept constant, and the end edges 5a, 6a are moved in the straight direction to form the entry side diagonal cord 5. The outlet diagonal cord 6 can be joined in a straight line.

However, the entrance diagonal cord5. As shown in FIG. 6 or FIG. 7, the exit side oblique cord 6 is prone to deformation near the acute angle portion, and moreover, the entrance side guide 12 and the exit side guide 13 are easily deformed.
cannot be extended near the cord splicing machine 11 in order to ensure workability in the vicinity of the cord splicing machine 11. 5. Entrance side diagonal cord on the bellow board 22 near and adjacent thereto; The end edge 5a of the outlet diagonal cord 6.

6a is out of place and the entrance diagonal cord 5. Exit diagonal code 6
The deformation in the vicinity of the edges 5a, 5a is not corrected when they are joined, resulting in a step shift as shown in FIG. 8 or 9.

-' TANO-~ The present invention relates to an invention of a device attached to a cord joining device that overcomes such difficulties, and is a device that is obtained by diagonally cutting a rubberized cord cloth having a ferromagnetic cord such as a steel cord. A cord joining device for sequentially joining the ends of a diagonal cord to each other, comprising: a linear magnet capable of contacting the side edge of the diagonal cord in the vicinity of an acute corner; and a driving means for driving the magnet; The linear magnet is brought into contact with the side edge of the oblique cord near the acute corner in the cord joining device to correct the deformation of the oblique cord near the acute corner, and then the cord joining device and the driving means are operated. Accordingly, the oblique cords can be joined without causing a step shift by aligning the acute angle part of the diagonal rubber with the obtuse angle part of the diagonal cord opposite thereto.

1Jl An embodiment of the present invention illustrated in FIGS. 10 to 14 will be described below.

The cord 2 in the rubberized cord cloth 1 with a thickness of about 1 to 3IIIR is made of steel and has a diameter of 0.6 to 1.5#I.
This embodiment is applied to the cord splicing machine 11 shown in FIGS. 1 to 4.

On the entry side of the cord splicing machine 11, as shown in FIGS. 11 and 12, the bracket 31 of the entry side positioning device 30 on the entry side machine frame 23 is removably attached to the thumbscrew 32, and the bracket 31 A base plate 34 is pivotally supported by a stay 33 integrally extending horizontally to the left and right about a pivot @35, and its swing angle relationship is maintained constant by an adjusting screw 36.

Further, an inlet air cylinder 37 is installed on the base plate 34, and a drive piece 39 is integrally fixed to the tip of its piston rod 38.
A 9-shaped support piece 42 is integrally attached to the plate 40, and a thin rectangular permanent magnet 43 with a thickness of 105 Il or less is integrally attached to the lower end of the support piece 42. If has been.

Further, on the exit side of the cord splicing machine 11, as shown in FIGS. 13 and 14, a bracket 51 of the exit side positioning device 50 is detachably attached to the exit side machine frame 24 of the cord splicing machine 11 with a bolt nut 52. The board 54 is attached to the stay 53 that is mounted and integrated with the bracket 51, and the board 54 is attached to the stay 53 that is integrated with the bracket 51.
A thumbscrew 56 is screwed into the stay 53 through the elongated hole 55 of the base plate 54, so that the position of the base plate 54 can be adjusted relative to the stay 53.

Furthermore, an outlet air cylinder 57 is installed on the base plate 54, and a permanent magnet 60 is integrally attached to the tip of the piston rod 58 via a mounting piece 59.

Since the embodiment shown in FIGS. 10 to 14 is configured as described above, the entry side diagonal cord 5 formed by the combination word 1fi4 is conveyed by the carry-in conveyor 7 and the input side combination conveyor 8. between, the end edge 5a of the entry side diagonal cord 5
Even if the sharp corner 5b deforms along the cord 2 as shown in FIG. 15 or 16,
After the entry side diagonal cord 5 is conveyed and stopped at a predetermined position with respect to the cord splicing machine 11, in the case of FIG. Then, the permanent magnet 43 comes into contact with the cutting edge 5c near the acute angle portion 5b of the entry side diagonal cord 5, and the extrusion force of the entry side air cylinder 37 corrects the acute angle portion 5b of the entry side diagonal cord 5. In the case of FIG. 16, the piston rod 38 protrudes by a predetermined stroke due to the operation of the inlet air cylinder 37, and the permanent magnet 43 stopped at a predetermined position is caused to form an inlet oblique shape by this magnetic force. The protruding edge 5c of the cord 5 near the acute angle part 5b is attracted, and due to this suction force, the acute angle part 5b of the inlet diagonal cord 5 is corrected, and the cut edge 5c of the cord 5 becomes straight.

Also, in the exit positioning device 50, the deformation of the acute angle portion 6b of the oblique tapping cord 6 is corrected by the same action as described above, and the al! The cutting edge 6C becomes straight.

Therefore, as shown in FIG.
The acute angle portions 5b, 6b of the exit side diagonal cord 6 are connected to the input side diagonal cord 5. The obtuse angle portions 5d and 6d of the outlet diagonal cord 6 are set at complementary angles, and the positional relationship is perpendicular to the edges 5a and 6a.
A ribbon-like carcass material without step shift can be obtained.

Also permanent magnet 43. Since the permanent tit & stone 60 can be made thinner than the thickness of the rubberized cord cloth 1, the exit diagonal cord 6 and the cut edges 5c, 6c of the exit diagonal cord 6 can be made thinner. Permanent magnet 43. When the permanent magnet 60 is attracted to the center in the thickness direction, the entrance diagonal cord 5. i of outlet diagonal code 6! Li Dangreen 5G.

The upward deformation 1 of 6C becomes slight, and this adverse effect can be almost eliminated.

As described above, according to the present invention, it is possible to join the diagonal cords without causing a step shift by aligning the acute angle portion of the diagonal cord with the obtuse angle portion of the diagonal cord opposite thereto. Therefore, it is possible to obtain - straight-extended bell 1 - material and manufacture high quality tires.

[Brief explanation of drawings]

FIG. 1 is a plan view of a conventional cord joining device to which the cord joining positioning device of the present invention is applied, and FIGS. 2 and 3 are sectional views taken along line II-II in FIG. , FIG. 2 shows the cord joining rock before its operation, FIG. 3 shows it after its operation, FIG. 4 is an enlarged plan view of the locking pawl, and FIG. 5 is an explanatory diagram showing the cord joining state. , FIGS. 6 and 7 are plan views showing the deformed state of the diagonal cord before the cords are joined, and FIGS. 8 and 9 are the plan views showing the deformed state of the diagonal cord before the cords are joined. FIG. 10 is a plan view showing an embodiment of the cord joining positioning device of the present invention, FIG. 11 is a plan view of the entry side positioning device, and FIG. Fig. 13 is a plan view of the exit positioning device, Fig. 14 is a cross-sectional view of Fig. 13.
rV-XTV arrow views and FIGS. 15 to 18 are explanatory diagrams illustrating the state in which the cord is corrected according to the embodiment. 1... Cord cloth with rubber, 2... Cord, 3...
Transfer conveyor, 4... Compiling machine, 5... Entrance side diagonal code, 6... Output side diagonal code, 7... Carrying conveyor,
8... Entry side combined conveyor, 9... Output side combined conveyor, 10... Export conveyor, 11... Cord splicing machine,
12... Inlet guide, 13... Outlet guide, 14.
15...Latching claw, 16.17...Support member, 18.
19... Elastic pressing piece, 20... Drive means, 21.2
2...Blank plate, 23...Enter side machine frame, 24...Outlet side machine frame, 30...Enter side positioning device, 31...Bracket, 32...Thumb screw, 33...・Stay, 34...
・Platform board, 35... Pivot, 36... Adjustment screw, 37.
...Inlet air cylinder, 38...Piston rod, 39.
...Drive piece, 40...Mounting plate, 41...Thumb screw,
42...branch. Holding piece, 43... Permanent magnet, 50... Exit side positioning device, 51... Bracket,
52... Bolt nut, 53... Stay, 54...
・Board, 55... Long hole, 56... Thumb screw, 51...
・Outlet air cylinder, 58...Piston rod, 59...
・Installation is single piece, 60...permanent magnet. Representative Patent Attorney Nozomu Ehara and 2 other names 6 illustrations
Figure 8 Figure 10 Figure 11 Figure 3b Figure 12 Figure 13 Figure 14 Figure 15 Figure 17 d

Claims (1)

[Claims] In a cord joining device that sequentially joins together the edges of a diagonal cord obtained by diagonally cutting a rubberized cord cloth having a ferromagnetic cord such as a steel cord, a side near an acute corner of the diagonal cord is used. A cord splicing positioning device characterized by comprising a linear magnet capable of contacting an edge, and a driving means for driving the magnet.