DE102015221369A1 - Cutting device for cutting at least one edge of a conveyor belt - Google Patents

Abstract

The present invention relates to a cutting device (2) for the cutting machining of at least one edge (12, 13, 14) of a conveyor belt (1) with at least one first cutting edge (21). The cutting device (2) is characterized in that the first cutting edge (21) is designed to be automatically guided relative to the edge (12, 13, 14) of the conveyor belt (1) to be processed.

Description

The invention relates to a cutting device for the cutting machining of at least one edge of a conveyor belt according to the preamble of claim 1 and to a conveyor belt production line with such a cutting device according to claim 10.

In the production of conveyor belts and the like from elastomeric material, during vulcanization at the lateral edges of the product, a portion of the elastomeric material may be expelled therefrom through the scratches of the vulcanization mold. This so-called shoot-out must be removed before the next manufacturing step, because otherwise this laterally overhanging vulcanized material could become trapped between the edges of the vulcanization press, which can lead to damage to the product. Also, this expulsion is undesirable for optical reasons and therefore to remove, because this can disturb the customer.

Removal of the shoot has heretofore usually been done manually by having a person with a cutting edge such as a knife. a blade moves laterally along the edge of the belt and thereby cuts off the shoot. This process can take place between the two aforementioned manufacturing steps within the vulcanization press while the vulcanized conveyor belt section is there. The disadvantage here is that this manual cutting of the shoot can be very stressful for the person, especially for longer conveyor belts, in which for a cut stretching of e.g. must be traveled up to 15 m.

Alternatively, the person may also hold a cutting edge laterally against the belt edge while the conveyor belt is being pulled forward from the curing press to the take-up block or within the curing press to prepare for the next conveyor belt section vulcanization process. The disadvantage here is that in this case the passage speed of the product usually has to be reduced in order to reduce the risk of falling for the person holding the cutting edge. This can lead to increased production times and thus increased production costs.

The disadvantage is overall that it can come by manually guiding the cutting edge by a person to a different quality of cutting the budding. This can result from the qualification of the person, but also from the diminishing attention of the person with increasing fatigue. This can result in both too little budding and too much belt material can be cut off. Furthermore, there is always a certain risk of accidents for the person leading the cutting edge.

From the DE 1 946 549 A1 For example, a method and apparatus is known for trimming the side edges of an unvulcanized rubber body to reduce the width of the rubber body to a uniform degree before it is vulcanized. For this purpose, the two side edges are cut off over the entire thickness, which in addition to the dimensional accuracy of the rubber body can also lead to smooth rectilinear side surfaces with rectangular edges as possible. The cut edge strips are pulled off the rubber body and wound up.

An object of the present invention is to provide a cutting device of the type described above, so that the expulsion of a vulcanized conveyor belt or the like easier, faster and / or safer can be removed than previously known. At least an alternative to known devices should be provided.

The object is achieved by a cutting device with the features of claim 1 and a conveyor belt manufacturing plant with the features of claim 10. Advantageous developments are described in the subclaims.

The present invention thus relates to a cutting device for the cutting machining of at least one edge of a conveyor belt with at least one first cutting edge. Under an edge is the angular and generally rectangular transition between two surfaces of a conveyor belt such. a side surface and a top or bottom to understand. A conveyor belt can also be understood to mean a drive belt, running belt or similar endlessly closable flexible elastomer article. Such cutting devices are known, for example, as hand-to-use and leading metallic blades, which must be guided by a person along the edge to be machined or held by a person to the edge to be machined while the conveyor belt to be machined Edge moved along the cutting edge. In this case, the disadvantages described above may occur.

To overcome, for example, these disadvantages, the first cutting edge of the cutting device according to the invention is designed to be automatically guided relative to the edge of the conveyor belt to be processed. An automated guidance means a mechanical arrangement which, instead of a manual handling of the first Cutting edge can handle and execute the handling of the first cutting edge. As a result, a manual cutting processing of the edge can be avoided, whereby the resulting risk of injury to the person can be avoided. Furthermore, the person can perform other tasks during this time. The resulting waste can fall in the area below the first cutting edge in a collecting container and thereby collected, so that the person can be relieved from collecting the crop.

It is also advantageous in this case that, in the case of this automated cutting operation, a faster pulling through of the conveyor belt from the vulcanization press to the take-up block or within the vulcanization press can take place. As a result, shorter production times and thus lower manufacturing costs can be achieved. It is also advantageous that a constant and therefore generally higher quality of the finished conveyor belt can be achieved by the defined cut on the edge. Furthermore, this can automatically be the optical defect that can constitute the shoot, be avoided.

The first cutting edge can be a metallic blade. Alternatively, the cutting edge can also be removed by methods such as e.g. Laser cutting, water steel cutting or sandblasting are realized.

According to another aspect of the present invention, the first cutting edge is configured to be disposed at a fixed position, wherein the conveying belt can be moved past the first cutting edge in a direction of movement such that the edge of the conveying belt to be processed is machined by the first cutting edge can. The direction of movement or cutting direction runs in the longitudinal direction of the conveyor belt.

This aspect of the present invention is based on the finding that during production the conveyor belt usually has to be moved from a vulcanization device to a take-up device or within the vulcanization device anyway. Accordingly, it can be very simple, e.g. in the direction of movement of the conveyor belt to be produced at the end of the vulcanization press or shortly after the vulcanization press a first cutting edge at a fixed position, which must pass through the conveyor belt, to arrange so that the cutting processing of the edge can be automated in this way. The positioning and / or orientation of the first cutting edge relative to the edge of the conveyor belt to be processed in the longitudinal direction, in the transverse direction and / or in the height can be manually set, e.g. by detecting by means of mechanical fastening means such as e.g. Screw connections can be made or be adjustable via drives, in particular be variable adjustable during a cutting operation. The settings via drives can be controlled or regulated.

According to a further aspect of the present invention, the first cutting edge is designed to be rotatable in a direction of rotation in such a way that the edge of the conveying belt to be processed can be processed in a rotationally cutting manner. By a rotating first cutting edge, the cutting performance of the cutting machining can be increased. In particular, the rotating first cutting edge enables a cutting treatment of harder materials than elastomeric materials.

According to a further aspect of the present invention, the first cutting edge is adjustable in a position transverse to the edge of the conveyor belt to be processed. Thereby, a contact between the first cutting edge and the edge to be processed can be ensured, i. a distance can be avoided. Also, this can be used to set the extent to which cutting should occur, i. the depth of the cut into the material of the conveyor belt. In this way, different width conveyor belts can be edited. This setting can be done manually or by drives.

According to a further aspect of the present invention, the first cutting edge in the transverse direction with respect to the edge of the conveyor belt to be processed in the pressing force is adjustable. By adjusting the force or pressure with which the first cutting edge acts on the edge to be processed, the extent of the cutting off can be influenced. In particular, this makes it possible to control the desired cutting depth of the first cutting edge in the material of the conveyor belt. In this case, this force or pressure setting, e.g. mechanically e.g. take place via at least one spring or hydraulically or pneumatically. In this case, provide a hydraulic or pneumatic force or pressure setting active adjustment options during the process, which can be complicated and expensive. The settings can be controlled or regulated. The mechanical adjustment can provide the advantage of a simpler and cheaper implementation here, but in which only a constant force or a constant pressure for the entire cut can be specified.

According to a further aspect of the present invention, the first cutting edge is adjustable in height relative to the edge of the conveyor belt to be processed in a position. By adjusting the height of the first cutting edge can Cutting device can be adjusted to different thicknesses of conveyor belts. This setting can be made via drives or manually. The settings via drives can be controlled or regulated.

According to a further aspect of the present invention, the first cutting edge is adjustable relative to the edge of the conveyor belt to be processed at an angle about the longitudinal direction. Here, the longitudinal axis forms the axis of rotation, around which the angle adjustment is possible. In this way, an adjustment of the cutting edge machining can also be effected by the cutting angle relative to a surface which forms the edge. Preferably, a setting of 45 ° is selected so that an oblique cutting processing takes place and the cut surface produced thereby has an identical angle with respect to both surfaces between which the edge is formed. This setting can be made via drives or manually.

According to a further aspect of the present invention, the cutting device further comprises at least one second cutting edge, preferably further at least one third cutting edge, which is identical or different from the first cutting edge, wherein the first cutting edge and the second cutting edge, and preferably the third cutting edge, are arranged to edit different edges or the same edge of the conveyor belt. Using multiple identical blades can have the advantage of reducing costs. Using several different cutting edges can have the advantage of being able to increase the influence on the cutting process.

The plurality of blades may be applied such that e.g. by the first cutting edge, the upper edge of the conveyor belt formed by the upper side (supporting side) and a side surface of the conveyor belt, and processed by the second cutting edge, the lower edge of the conveyor belt, which is formed by the bottom (running side) and the same side surface of the conveyor belt can be. If a third cutting edge is used, it may be replaced by this e.g. the side surface itself can be edited.

According to another aspect of the present invention, at least the first cutting edge is a metallic blade, preferably all cutting edges are metallic blades. Metallic blades are usually suitable and sufficient to provide a soft material, such as e.g. to edit an elastomeric material cutting. Metallic blades can be simple, robust and cheap.

The present invention also relates to a conveyor belt production line having a conveyor belt to be manufactured, which can be moved within the conveyor belt production line in a direction of movement, and a cutting device as described above, which is arranged inside the production line for cutting at least one edge of the conveyor belt. In this way, the above-described characteristics and advantages can be applied to a conveyor belt production.

An embodiment and further advantages of the invention are explained below in connection with the following figure. It shows:

1 a perspective schematic representation of a conveyor belt production plant with a cutting device according to the invention.

A conveyor belt manufacturing plant 3 such as a vulcanization press 3 has a conveyor belt 1 on which within the vulcanization press 3 is manufactured or processed. The conveyor belt 1 extends substantially in a longitudinal direction X, which may also be referred to as length X. At right angles to the longitudinal direction X extends on the one hand a transverse direction Y, which may also be referred to as width Y, and on the other hand a vertical direction Z, which may also be referred to as height Z. In the 1 is a section of the conveyor belt 1 shown, so that the conveyor belt 1 extends significantly further than shown in the longitudinal direction X.

At height Z, the conveyor belt points 1 a top 10 on which the carrying side 10 of the conveyor belt 1 represents. The top 10 at the height Z directly opposite the conveyor belt 1 a bottom 11 on, which also as a running page 11 of the conveyor belt 1 can be designated. In the transverse direction Y is on each side in each case a side surface 12 formed, which with the respective limiting upper side 10 or bottom 11 each a right-angle transition 13 . 14 forms. These right-angle transitions 13 . 14 between the side surfaces 12 and the top 10 or bottom 11 be as top edges 13 or lower edges 14 designated.

The conveyor belt 1 is in a manufacturing step in a vulcanization press 3 (not shown in detail) vulcanized and then in a direction of movement A, which extends in the longitudinal direction X, led to further processing or so that the next section of the conveyor belt 1 can be vulcanized. At the end of the vulcanization in the direction of movement A is a cutting device according to the invention 2 arranged.

The cutting device 2 has a first cutting edge 21 in the form of a metallic blade 21 on. The first cutting edge 21 can in the transverse direction Y by means of a lateral guide 22 be set in a lateral position B such that the first cutting edge 21 the upper edge facing her 13 of the conveyor belt 1 cutting can work to the top edge 13 To free from budding of the previous vulcanization process. The adjustment of the lateral position B can be done by means of a mechanical clamping mechanism, for example by means of a screw connection. The cut off shoot can be in the area below the first cutting edge 21 be collected by a container such as a container (not shown).

The cutting device 2 also has a guide 23 for positioning the first cutting edge 21 opposite the top edge 13 of the conveyor belt 1 in the height Z in a position C on. This position C can be made by means of a mechanical clamping mechanism, for example by means of a screw connection. Furthermore, the first cutting edge 21 opposite the lateral guide 22 about the longitudinal axis X as an axis of rotation at an angle α relative to the side surface facing it 12 or the top 10 be adjusted so that the cut surface produced thereby compared to the side surface 12 and the surface 10 preferably has the same angle. Furthermore, the first cutting edge 21 around the axis of the lateral guide 22 in a rotational direction D to perform a rotary cutting motion at a fixed position, which is the conveyor belt to be processed 1 during movement within the vulcanization press 3 or when moving out of the vulcanization press 3 has to happen out.

The cutting device 2 also has a second cutting edge 24 and a third cutting edge 27 on, which in the direction of movement A of the conveyor belt 1 successively behind the first cutting edge 21 arranged and identical to the first cutting edge 21 are formed. Accordingly, the second cutting edge 24 a lateral guide 25 and a guide 26 at height Z on. The second cutting edge 24 is about the lateral guidance 25 rotatable in a direction of rotation E. The second cutting edge 24 can about the longitudinal axis X as a rotation axis at an angle β relative to the side surface facing it 12 be adjusted so that the second cutting edge 24 this side surface 12 can edit flat.

Accordingly, the third cutting edge 27 a lateral guide 28 and a guide 29 at height Z on. The third cutting edge 27 is about the lateral guidance 28 rotatable in a direction of rotation F. The third cutting edge 27 can about the longitudinal axis X as a rotation axis at an angle γ relative to the side surface facing it 12 or the bottom 11 be adjusted so that the third cutting edge 27 the lower edge facing her 13 can edit.

Are two cutting devices according to the invention 2 (not shown) on both sides of the conveyor belt 1 in the transverse direction Y in the vulcanization press 3 arranged, so according to the invention an automated cutting processing of the conveyor belt 1 at its two upper edges 13 , both side surfaces 12 and both lower edges 14 respectively. As a result, people can be relieved of this task, the quality of the cutting processing increased, eliminates the optical lack of sprouting and reduce the production times.

LIST OF REFERENCE NUMBERS

A

Direction of movement of the conveyor belt 1

B

lateral position

C

Position in height Z

D

Direction of rotation of the first cutting edge 21

e

Rotation direction of the second cutting edge 24

F

Rotation direction of the third cutting edge 27

α

Angle of the first cutting edge 21

β

Angle of the second cutting edge 24

γ

Angle of the third cutting edge 27

X

Longitudinal direction, length

Y

Transverse direction, width

Z

vertical direction, height

1

conveyor belt

10

Top side, carrying side

11

Bottom, running side

12

side surface

13

Upper edge, upper conveyor belt edge, upper right-angle transition

14

Lower edge, lower conveyor belt edge, lower right angle transition

2

cutter

21

first cutting edge, first blade

22

lateral guidance of the first cutting edge 21

23

Guide at height Z of the first cutting edge 21

24

second cutting edge, second blade

25

lateral guidance of the second cutting edge 24

26

Guide at height Z of the second cutting edge 24

27

third cutting edge, third blade

28

lateral guidance of the third cutting edge 27

29

Guide at height Z of the third cutting edge 27

3

Conveyor belt production line, vulcanization press

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 1946549 A1 [0006]

Claims (10)

Cutting device ( 2 ) for cutting at least one edge ( 12 . 13 . 14 ) of a conveyor belt ( 1 ), with at least one first cutting edge ( 21 ), characterized in that the first cutting edge ( 21 ) is formed, opposite the edge to be machined ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) to be automated. Cutting device ( 2 ) according to claim 1, wherein the first cutting edge ( 21 ) is arranged to be arranged at a fixed position, wherein the conveyor belt ( 1 ) in a direction of movement (A) at the first cutting edge ( 21 ) can be passed so that the edge to be processed ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) from the first cutting edge ( 21 ) can be edited by cutting. Cutting device ( 2 ) according to claim 1 or 2, wherein the first cutting edge ( 21 ) is rotatable in such a rotational direction (D) that the edge to be machined ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) can be processed rotatingly cutting. Cutting device ( 2 ) according to one of the preceding claims, wherein the first cutting edge ( 21 ) in the transverse direction (Y) with respect to the edge to be machined (Y) 12 . 13 . 14 ) of the conveyor belt ( 1 ) is adjustable in a position (B). Cutting device ( 2 ) according to one of the preceding claims, wherein the first cutting edge ( 21 ) in the transverse direction (Y) with respect to the edge to be machined (Y) 12 . 13 . 14 ) of the conveyor belt ( 1 ) is adjustable in the pressing force. Cutting device ( 2 ) according to one of the preceding claims, wherein the first cutting edge ( 21 ) in height (Z) with respect to the edge to be machined ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) is adjustable in a position (C). Cutting device ( 2 ) according to one of the preceding claims, wherein the first cutting edge ( 21 ) relative to the edge to be processed ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) is adjustable at an angle (α) about the longitudinal direction (X). Cutting device ( 2 ) according to one of the preceding claims, further comprising at least one second cutting edge ( 24 ), preferably also with at least one third cutting edge ( 27 ) which are identical or different from the first cutting edge ( 21 ) is formed, wherein the first cutting edge ( 21 ) and the second cutting edge ( 24 ), and preferably the third cutting edge ( 27 ), different edges ( 12 . 13 . 14 ) or the same edge ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) to edit. Cutting device ( 2 ) according to one of the preceding claims, wherein at least the first cutting edge ( 21 ) a metallic blade ( 21 ), preferably all cutting edges ( 21 . 24 . 27 ) metallic blades ( 21 . 24 . 27 ) are. Conveyor belt production line ( 3 ), with a conveyor belt ( 1 ), which within the conveyor belt manufacturing plant ( 3 ) in a direction of movement (A), and a cutting device ( 2 ) according to one of the preceding claims, which within the production plant ( 3 ) is arranged to at least one edge ( 12 . 13 . 14 ) of the conveyor belt ( 1 ) to edit.

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