JP2002346978A - Strip rubber member cutting method and cutting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a strip rubber member cutting method and a strip rubber member cutting device capable of shortening the cutting cycle time, and having an excellent cut section. SOLUTION: In this method, a cutter 3 cuts a strip rubber member 2 in the width direction while the cutter advances at the same speed as the feeding speed of the strip rubber member 2 which is continuously fed from stand-by position 7 while traversing in the width direction of the strip rubber member 2. After the cutter 3 cuts the strip rubber member 2, the cutter 3 is moved to the upper position away from the strip rubber member 2 before the cutter stops the traversing, and the cutter is moved to the lower position capable of cutting the strip rubber member 2 before the cutter 3 returns to and stops at the stand-by position 7.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method and an apparatus for cutting a rubber band.

[0002]

2. Description of the Related Art Conventionally, as shown in FIG. 7, in a continuous belt-shaped rubber member 42 sent on a belt conveyor 43, the belt-shaped rubber member 42 is fed by a set length, and the conveyor is conveyed.
43 is temporarily stopped, and the belt-shaped rubber member 42 is moved on the conveyor 43.
A method / apparatus for cutting the band-shaped rubber member 42 in the width direction by using a rotary cutter 44 that moves in the width direction of the belt. Alternatively, while the conveyor is in operation, that is, in the case of the belt-shaped rubber member continuously fed on the belt conveyor, after the belt-shaped rubber member is fed by a set length, the bogie provided with the cutter is moved to the conveyor. 2. Description of the Related Art A method and apparatus for cutting a band-shaped rubber member in a width direction by a rotary cutter that travels at the same speed in a traveling direction and moves in a width direction of the band-shaped rubber member on a running conveyor is used.

FIG. 8 shows a method and an apparatus for cutting the intermittently fed belt-like rubber member 42 shown in FIG. 7 or a method and apparatus for cutting the belt-like rubber member while continuously feeding the same. It is controlled as shown in the explanatory diagram of the movement of the cutter. After cutting the belt-like rubber member with a cutter (cutting process C
After completion) the cutter traverse speed (upper graph in FIG. 8) is V
8 (point x), the vertical position of the cutter (FIG. 8)
Lower graph), the cutter is raised from the lower position L of the cuttable height to the upper position U of the return movable height to the standby position (point y), and then the cutter is moved by the traversing speed V to the standby position 45 ( 7 (see FIG. 7) (return step B). Then, after the cutter reaches the standby position 45 (point z), the cutter is lowered from the upper position U to the lower position L and stopped (one cycle above). Then, the band-shaped rubber member 2 is fed by a required length, the cutter is moved in the width direction of the band-shaped rubber member, and cutting is performed again (cutting step C).

[0004]

As shown in FIG. 8, a series of operations of a cutting process C, a cutter raising, a returning process B, and a cutter lowering are performed after confirming completion of each operation (process). Since the control method and device is such that the operation time of moving is a stacking type, it takes time from the start of the cutting operation to the return of the cutter to the standby position, so the conveyor feed time is limited and the cutting work per unit time There is a problem that efficiency is not favorable.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a method and an apparatus for cutting a belt-shaped rubber member which can shorten the cutting cycle time and have a good cutting surface.

[0006]

In order to achieve the above-mentioned object, a method for cutting a band-shaped rubber member according to the present invention comprises the steps of: moving a cutter from a standby position in a width direction of the band-shaped rubber member; Cutting in the width direction,
The cutter moves to an upper position separated from the band-shaped rubber member before the cutter stops the traverse movement after cutting the band-shaped rubber member, and the cutter moves to the standby position before the cutter returns to the standby position and stops. It moves to a lower position where the belt-shaped rubber member can be cut.

Further, the cutter moves forward from the standby position at the same speed as the feed speed of the belt-like rubber member continuously fed, and moves in the width direction of the belt-like rubber member while moving the cutter laterally. In the method of cutting in the width direction, the cutter moves to an upper position away from the band-shaped rubber member before the cutter stops cutting in the transverse direction after cutting the band-shaped rubber member, and the cutter moves to the standby position. Before returning and stopping, the cutter moves to a lower position where the belt-like rubber member can be cut.

Further, the cutter cuts the band-shaped rubber member in the width direction while changing the moving speed in the width direction of the band-shaped rubber member and moving transversely. Further, when the cutter cuts the band-shaped rubber member in the width direction, at the start of cutting, the band-shaped rubber member is driven at a low speed so as not to be accompanied by displacement or deformation, and then at a high speed enough to have a good cut surface. The cutting of the belt-shaped rubber member is performed while the cutter moves in a transverse direction while changing the moving speed.

In order to achieve the above object, a band-shaped rubber member cutting device according to the present invention comprises a cutter for cutting the band-shaped rubber member in the width direction while moving the band-shaped rubber member in the width direction from a predetermined standby position. A traversing mechanism for moving the cutter in the traversing direction, an elevating drive mechanism for raising and lowering the cutter, and raising the cutter before the cutter stops after cutting the belt-shaped rubber member and returning to the predetermined standby position and stopping. Control means for lowering the cutter before performing the cutting operation.

A cutter for cutting the band-shaped rubber member in a width direction from a predetermined standby position; a cutter carriage having the cutter; a traversing mechanism for moving the cutter and the cutter carriage in a width direction of the band-shaped rubber member; An elevating drive mechanism for raising and lowering the cutter, a cutter truck having the cutter carriage, the traversing mechanism, and the elevating drive mechanism, a synchronous feed mechanism for moving the cutter truck in the feed direction of the belt-shaped rubber member, and the cutter described above. Control means for raising the cutter before stopping after cutting the belt-shaped rubber member and lowering the cutter before returning to the predetermined standby position and stopping.

The traversing mechanism changes the traversing speed of the cutter in the width direction of the band-shaped rubber member,
The band-shaped rubber member is cut in the width direction.

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail based on the illustrated embodiments.

The belt-shaped rubber member cutting apparatus according to the present invention is extruded (continuously or intermittently) from an extruder (not shown) by a conveyor 10 such as a belt conveyor and fed.
This is an apparatus for sequentially cutting a belt-like rubber member 2 such as a tread constituting a rubber tire into a predetermined length dimension corresponding to one tire.

FIGS. 1 and 2 are a plan view and a side view, respectively, showing an embodiment of a band-shaped rubber member cutting apparatus. In the plan view of FIG. 1, a rotary disk-shaped cutter 3 is used. The cutter 3 is a cutting blade that cuts the member 2 in the width direction. The cutter 3 moves forward from the standby position 7 (in a state indicated by a two-dot chain line) at the same speed as the speed of the belt-shaped rubber member 2 continuously fed. While the relative speed is set to 0, the belt-shaped rubber member 2 is cut in the width direction while moving transversely (moving in the left-right direction) in the width direction of the belt-shaped rubber member 2 (cutting step C).
Alternatively, the transfer device 10 (the band-shaped rubber member 2) may be temporarily stopped and cut without moving the cutter 3 forward. After the cutting is completed, the cutter 3 returns to the standby position 7 and enters a standby state (return process B) (one cycle above), and the cutter 3 starts cutting from the standby position 7 continuously from the standby state. Is what you do.

While moving forward at the same speed as the feeding speed of the belt-shaped rubber member 2 continuously fed, the belt-shaped rubber member 2 is moved forward.
The movement of the cutter 3, which cuts the belt-shaped rubber member 2 in the width direction while traversing in the width direction, is as shown by the arrow shown in FIG.
The oblique movement is performed on the belt-shaped rubber member 2.

At the time of cutting the band-shaped rubber member 2, as shown in FIG.
The cutter 3 is arranged at a position L below the cutting height at which cutting can be performed, and performs cutting. Then, after the cutting is completed, the cutter 3 rises from the lower position L to an upper position U of a movable height to the standby position 7 in order to pass over the belt-shaped rubber member 2 and return to the standby position 7. (See FIG. 3).

As shown in FIG. 2, since the disk-shaped cutter 3 is disposed at the lower right (forwardly inclined in the traveling direction) in a side view as shown in FIG. A cut surface having a downwardly inclined front surface (inclined with respect to the longitudinal surface of the belt-shaped rubber member 2) corresponding to the arrangement angle of the cutter 3 is obtained. Thereby, the adhesion of the cut surfaces at both ends performed in the next process of the processing of the belt-shaped rubber member 2 can be made favorable by the action of enlargement of the adhesion surface, etc., and the performance as a tire is such that the joined portion is formed with the non-joined portion. It can be similar. The cutting position of the cutter 3 is configured to cut only the belt-shaped rubber member 2 while keeping the conveying belt material and the like of the conveying device 10 downward.

Next, the raising and lowering operation of the cutter 3 will be described in more detail. The cutter 3 is positioned at an upper position where the cutter 3 is separated from the belt-shaped rubber member 2 after the cutting of the belt-shaped rubber member 2 and before the above-mentioned traverse movement is stopped. Move to U and cutter 3
Is moved to the lower position L where the cutter 3 can cut the band-shaped rubber member 2 before returning to the standby position 7 and stopping. That is, the raising and lowering operation of the cutter 3 is a simultaneous operation included in the cutting step C and the return step B, and the movement of the cutter 3 is not only an operation of only one axis (lateral movement) but also an operation of two axes. (A traversing motion and a lifting motion) are controlled to perform a three-dimensional motion at the same time.

More specifically, the band-shaped rubber member cutting device will be described. The rotary cutter 3 that cuts the band-shaped rubber member 2 in the width direction from a predetermined standby position 7 (FIG. 1), as shown in FIG. The cutter carriage 8 is attached to the cutter carriage 8, and as shown in FIG. 1, the cutter carriage 8 is movably supported by a traversing mechanism 5 that traverses the band-shaped rubber member 2 in the width direction.

The traversing mechanism 5 rotates two guide rails 11 provided in the width direction of the belt-shaped rubber member 2, a male screw rod 12 parallel to the guide rail 11 and located therebetween, and the male screw rod 12. And a traversing servomotor 13. The cutter carriage 8 has a roller (not shown) fitted to the guide rail 11, has a socket 14 having a female screw screwed into the male screw rod 12, and the male screw rod 12 rotates. As a result, the socket 14 moves along the male screw rod 12, and the cutter carriage 8 travels along the guide rail 11. Also, this male screw rod 12 and socket
The fourteen female screws are formed as ball screws to increase the power transmission efficiency, so that the cutter 3 can be traversed smoothly and at high speed. Alternatively, the position displacement mechanism of the cutter carriage 8 included in the traversing mechanism 5 may be a timing belt type.

Next, the lifting drive mechanism 6 for raising and lowering the cutter 3 moves the cutter 3 up and down (swing) to the upper position U and the lower position L, as described above, and is shown in FIGS. In this way, the cutter carriage 8 (or the cutter carriage 8 and the traversing mechanism 5) is moved up and down (oscillating). Alternatively, although not shown, only the cutter 3 may be moved up and down or rocked.

Next, the traveling means for moving the cutter 3 in the feed direction of the belt-shaped rubber member 2 (advancing / retreating operation) includes the cutter carriage 1 on which the cutter carriage 8, the traversing mechanism 5, and the lifting drive mechanism 6 are mounted. And As shown in FIG. 2, the cutter carriage 1 can be moved in the front-rear direction in the feed direction of the band-shaped rubber member 2 by the synchronous feed mechanism 4, and the synchronous feed mechanism 4 is provided in the longitudinal direction of the band-shaped rubber member 2. It includes a male screw rod 15, a feed-moving servomotor 16 for rotating the male screw rod 15, and a guide rail (not shown). The cutter truck 1 has a female screw portion 17 screwed to the male screw rod 15, and the male screw rod 15 rotates,
The female screw portion 17 moves along the male screw rod 15, and the cutter truck 1 travels in the front-rear direction along the guide rail. Further, the male screw rod 15 and the female screw part 17 can be smoothly and quickly moved by using a ball screw similarly to the traversing mechanism 5. Alternatively, the position displacement mechanism of the cutter truck 1 included in the lifting drive mechanism 6 may be a timing belt type.

The raising / lowering drive mechanism 6, the traversing mechanism 5, and the synchronous feed mechanism 4 raise the cutter 3 by the control means 9 before the cutter 3 stops after the cutting of the belt-shaped rubber member 2, and wait for a predetermined time. Control is performed so that the cutter 3 is lowered before returning to the position 7 and stopping (sequence is set).

The operation control of the cutter 3 by the control means 9 will be further described as follows. The cutting step C includes a first margin zone until the cutter 3 at the standby position 7 starts the cutting operation (after the start of the movement in the width direction) and the cutter 3 comes into contact with the belt-shaped rubber member 2, and a cutting zone where the actual cutting is performed. , (The cutter 3 separates from the belt-shaped rubber member 2)
There is a second margin zone until the cutter 3 stops traversing after the cutting is completed. After the cutting of the belt-shaped rubber member 2, the control means 9 moves the cutter 3 from the lower position L to the upper position U.
Is set to be included in the second margin zone or coincide with the second margin zone. Further, the cutter descending movement in which the cutter 3 moves from the upper position U to the lower position L before the cutter 3 returns to the standby position 7 and stops is set so as to coincide with the latter half of the return process B or the return process B. It is. Also, cutter 3
After cutting and after arriving at the standby position 7, the moving direction may be continuously changed and moved to the next step without stopping.

FIG. 5 shows the movement of the cutter controlled by the control means 9. The upper graph in FIG. 5 shows the cutter traversing speed, and the lower graph shows the vertical position of the cutter. After the start command a of the cutter 3 (the cutter 3 is at the lower position L), the traversing speed of the cutter 3 reaches V and cutting is performed. Then, simultaneously with the deceleration command b, cutter 3
The cutter 3 is raised from the lower position L to the upper position U by the rising command m, stops, and the cutting step C ends. Subsequently, in the return step B, the cutter 3 starts moving to the standby position 7 at the traversing speed V (or any speed) according to the start command d while the cutter 3 remains at the upper position U. Then, the cutter 3 returning at the traversing speed V starts decelerating according to the deceleration command e, and the cutter 3 descends from the upper position U to the lower position L according to the descending command n of the cutter 3, stops, and ends the return step B. It is assumed that cutting is performed continuously as one cycle.

The moving distance of the cutter 3 (cutter carriage 8) and the elevating (swinging) distance of the cutter 3 are set by the control means 9 so as to output the command signal. Alternatively, the position of the cutter 3 may be confirmed by a position detecting sensor or the like at the start and end of each operation.

Next, it is assumed that the cutter 3 cuts the band-shaped rubber member 2 in the width direction while moving transversely while changing the moving speed in the width direction of the band-shaped rubber member 2. this is,
The traversing mechanism 5 controls the cutter 3 to change the traversing (moving) speed V in the width direction of the band-shaped rubber member 2 so as to cut the band-shaped rubber member 2 in the width direction.

Conventionally, when cutting is performed while keeping the traversing (moving) speed V constant (at a high speed), the thickness of the belt-like rubber member 2 (tread) constituting the tire is thin or (thickness). When the band-shaped rubber member 2 (tread) with a thin side wall is cut by rotating the cutter 3, the thin portions at both edges of the cut surface of the band-shaped rubber member 2 have low rigidity, and the cutter 3 The cutting is not performed properly during the cutting movement, and the thin portion is pushed in the traversing direction (left-right direction), and cutting is performed in a state where the cut surface is rough. As a result, when the belt-shaped rubber member 2 is rolled into a cylindrical shape by a tire building machine in the next step and the end surfaces are bonded, the both end surfaces are not aligned, and uniform bonding cannot be obtained. In addition, problems such as separation (separation) at the joint and imbalance in tire rotational force are caused.

However, as described above, the traversing (moving) speed V
This problem can be ameliorated by changing and cutting.
More specifically, as shown in FIGS. 4A and 4B, when the cutter 3 cuts the band-shaped rubber member 2 in the width direction, at the start of cutting (at the time of cutting), the band-shaped rubber member 2 is cut. by transverse movement at a low speed V _S as the thin portion or sharp edge portion without displacement or deformation perform reliable cutting (cut approximately 100 mm to 200 mm from the start), then an intermediate portion after the band-shaped rubber member 2, as causes survive at high speed V _H enough to have a good cut surface, and performs cutting of the belt-shaped rubber member 2 while the moving speed of the cutter 3 by transverse movement to change quickly. The degree to which a good cut surface can be obtained refers to a state in which, when the cut end surfaces are bonded, the bonding performance does not occur, or a defect caused by the bonded surface does not occur when the tire is configured.

Next, FIG. 6 shows the movement of the cutter controlled by the control means 9 in which the traverse transmission function is added to the control means 9 of the cutter 3 shown in FIG. Start command a subsequent cutter 3 (cutter 3 in the lower position L), transverse moving speed of the cutter 3 once to cut the thin portion of the belt-shaped rubber member 2 reaches the low-speed V _S. Then, the cutter 3 is in place to reach the vicinity of the thick portion of the belt-shaped rubber member 2, to accelerate the traversing speed of the cutter 3 to V _H continues cutting at a constant speed V _H by acceleration command f. At the same time as the post-cutting deceleration command b, the cutter 3 rises from the lower position L to the upper position U, stops, and the cutting process C ends. Subsequently, the return step B includes
The cutter 3 starts moving to the standby position 7 at the traversing speed V _H (or an arbitrary speed V) according to the start command d while the cutter 3 remains at the upper position U. Then, the cutter 3 returns to the standby position 7 at the traversing speed V and starts to decelerate in accordance with the deceleration command e.
Descends from the upper position U to the lower position L, stops, and ends the return step B. The above-described cycle is defined as one cycle, and the band-shaped rubber member 2 is continuously cut.

A good cut surface can be obtained by the traverse shifting function of the cutter 3, and the feed speed of the belt-shaped rubber member 2 (the transport device 10
Feed speed) can be increased. The speed adjustment and the moving distance of the traverse transmission mechanism can be freely changed and can be set in advance.

[0032]

According to the present invention, the following effects can be obtained by the above configuration.

According to the first and fifth aspects, the cutter 3 can be operated smoothly and efficiently. That is,
It is possible to shorten the widthwise cutting cycle of the band-shaped rubber member 2, prevent the feed speed of the band-shaped rubber member 2 (the transport device 10) from decreasing or stopping, and improve the productivity.

According to the second and sixth aspects, the same effect as the first and fifth aspects can be obtained. Further, by cutting the band-shaped rubber member 2 in the width direction while feeding it in the longitudinal direction, the loss can be further reduced. The time can be shortened, and the cutting cycle of the band-shaped rubber member 2 can be shortened.
It is possible to prevent the feed speed from decreasing or stopping in 0) and improve the productivity.

(According to the third aspect) Cutting can be performed under conditions adapted to the cross-sectional shape of the belt-shaped rubber member 2, a good cut surface can be obtained, and the performance as a tire constituent member can be sufficiently brought out. It is possible.

According to the fourth aspect of the present invention, it is possible to cut the cross section of the band-shaped rubber member 2 without depending on the thickness of the cut surface of the band-shaped rubber member 2 and to cut a good cut surface even in a thin portion. Obtainable. Therefore, when the band-shaped rubber member 2 after cutting is formed into a cylindrical shape of the tire constituent member in the next step, adhesion of the cut surface is ensured, and problems such as separation of the bonded portion and unbalance of tire rotational force are not caused. can do. (According to claim 7) the belt-shaped rubber member 2
Even if the traversing speed V of the cutter 3 at the time of cutting is reduced, the traversing mechanism 5 changes the traversing speed so that the overall production speed does not decrease and a good cut surface can be obtained. .

[Brief description of the drawings]

FIG. 1 is an overall plan view showing an embodiment of a band-shaped rubber member cutting device according to the present invention.

FIG. 2 is a side view showing one embodiment of the belt-shaped rubber member cutting device of the present invention.

FIG. 3 is a side view showing an example of the cutter swing means of the present invention.

FIG. 4 is a cross-sectional view of a belt-shaped rubber member for explaining cutting of the cutter of the present invention.

FIG. 5 is an explanatory view of an example of the movement of a cutter in the belt-shaped rubber member cutting method of the present invention.

FIG. 6 is an explanatory view of another example of the movement of the cutter in the band-shaped rubber member cutting method of the present invention.

FIG. 7 is an overall plan view showing a conventional belt-shaped rubber member cutting device.

FIG. 8 is an explanatory view of the movement of a cutter in a conventional belt-shaped rubber member cutting method.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Cutter cart 2 Band-shaped rubber member 3 Cutter 4 Synchronous feed mechanism 5 Traversing mechanism 6 Elevating drive mechanism 7 Standby position 8 Cutter carriage 9 Control means

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) B26D 5/06 B26D 5/06 A

Claims (7)

[Claims] 1. A method for cutting a band-shaped rubber member 2 in a width direction while a cutter 3 moves from a standby position 7 in a width direction of the band-shaped rubber member 2, wherein the cutter 3 is configured to cut the band-shaped rubber member 2 The cutter 3 moves to an upper position away from the band-shaped rubber member 2 before stopping the traversing movement after cutting, and before the cutter 3 returns to the standby position 7 and stops, the cutter 3 A method for cutting a band-shaped rubber member, wherein the member is moved to a lower position where the member 2 can be cut. 2. The cutter 3 moves forward from the standby position 7 at the same speed as the feeding speed of the belt-shaped rubber member 2 continuously fed, while moving transversely in the width direction of the band-shaped rubber member 2. A method of cutting the band-shaped rubber member 2 in the width direction, wherein the cutter 3 is connected to the band-shaped rubber member 2 before the cutter 3 stops cutting in the transverse direction after cutting the band-shaped rubber member 2.
The cutter 3 moves to a lower position where the cutter 3 can cut the belt-shaped rubber member 2 before the cutter 3 returns to the standby position 7 and stops there. Method. 3. A band rubber member cutting method, wherein the cutter 3 cuts the band rubber member 2 in the width direction while changing the moving speed in the width direction of the band rubber member 2 and moving in a transverse direction. 4. When the cutter 3 cuts the band-shaped rubber member 2 in the width direction, at the start of cutting, the band-shaped rubber member 2 has a good cutting surface at a low speed so as not to be displaced or deformed. Cutter 3
Cutting the band-shaped rubber member 2 while changing the moving speed and moving in a transverse direction. 5. A cutter 3 for cutting the band-shaped rubber member 2 in the width direction while moving the band-shaped rubber member 2 in the width direction from a predetermined standby position 7, a traversing mechanism 5 for moving the cutter 3 in the traverse direction, An elevating drive mechanism 6 for raising and lowering the cutter 3; and raising the cutter 3 before the cutter 3 stops after cutting the band-shaped rubber member 2 and returning the cutter 3 to the predetermined standby position 7 before stopping. And a control means 9 for lowering the rubber member. 6. A cutter 3 for cutting from the predetermined standby position 7 in the width direction of the band-shaped rubber member 2, a cutter carriage 8 having the cutter 3, and the cutter 3 and the cutter carriage 8 in the width direction of the band-shaped rubber member 2. A traversing mechanism 5 for traversing and a lifting drive mechanism 6 for raising and lowering the cutter 3
A cutter carriage 1 having the cutter carriage 8, the traversing mechanism 5, and the elevation drive mechanism 6, a synchronous feed mechanism 4 for moving the cutter carriage 1 in the feed direction of the band-shaped rubber member 2, and the cutter 3. Control means 9 for raising the cutter 3 before stopping after cutting the belt-shaped rubber member 2 and lowering the cutter 3 before returning to the predetermined standby position 7 and stopping. Member cutting device. 7. The traversing mechanism 5 changes the traversing speed of the cutter 3 in the width direction of the band-shaped rubber member 2 to cut the band-shaped rubber member 2 in the width direction. The belt-shaped rubber member cutting device according to any one of the preceding claims.