JP6220247B2 - Inner liner strip wind molding apparatus and molding method and pneumatic tire - Google Patents

Description

  The present invention is obtained by vulcanizing a raw cover molded by using the inner liner strip wind molding apparatus and molding method in the molding of a raw cover (unvulcanized tire), and the inner liner strip wind molding method. Related to pneumatic tires.

  In the manufacture of pneumatic tires, various rubber members such as tread rubber, sidewall rubber, inner liner rubber and the like are used because required characteristics in each part are different. In recent years, these rubber members have been manufactured using strip wind molding in which a belt-like rubber strip is continuously attached in a spiral shape and wound around a sticking drum (for example, Patent Documents 1 and 2).

  Of these various rubber members described above, butyl rubber is used as a main component of the rubber material for the inner liner in order to ensure sufficient air permeation resistance.

  In the strip wind forming of the inner liner, the strip extruded from the hot-press extruder is transported to the winding drum on the transport belt via the calendar roll, and then spirally formed on the winding drum. This is done by winding.

  However, a strip extruded from a hot-press extruder has a characteristic that shrink (shrinkage) occurs when it is exposed to room temperature, and butyl rubber has low mechanical strength. Depending on the shrink condition, strip breakage may occur.

  Further, since the inner liner is stretched at the time of shaping in the raw cover molding process, shrinkage is still generated when trying to return to the original state at the time of storage until the subsequent vulcanization process. May cause perforation of the strip as shown in FIG.

  When a raw cover with such a strip break or strip perforation on the inner liner is vulcanized, a pneumatic tire with a hole in the inner liner layer that retains air will be produced. Will be scrapped as scrap, leading to a decrease in productivity.

JP 2005-305792 A JP 2009-184152 A

  For this reason, when manufacturing a raw cover in which an inner liner is formed using strip wind forming, an inner liner that sufficiently suppresses occurrence of strip breakage or strip perforation and does not cause a decrease in productivity. The strip wind molding technology was required.

  As a result of intensive studies to solve the above problems, the present inventor has found that the above problems can be solved by the invention described below, and has completed the present invention.

The invention described in claim 1
A hot-water extruder that heats and extrudes a butyl rubber composition of a predetermined composition into a ribbon;
A calender roll for processing the butyl rubber composition that has been heated and extruded into a ribbon shape into a rubber strip having a predetermined shape;
A transport belt for transporting the rubber strip processed into a predetermined shape;
A winding drum that spirally winds the rubber strip that has been conveyed by strip wind forming,
Control means for controlling the conveyor belt speed to be slower than the calendar roll speed is provided,
Control means is provided for controlling the extrusion speed in the hot-water extruder to be 19 to 30 when the calender roll speed is 100,
The control by the two control means is configured to be performed simultaneously,
Further, the inner liner strip wind forming apparatus is an apparatus for performing strip wind forming of an inner liner using a butyl rubber composition having a butyl rubber content of 80% or more as the butyl rubber composition.

The invention described in claim 2
2. The inner liner according to claim 1, wherein the control unit is a control unit that controls the calender roll speed to be greater than 100 and equal to or less than 150 when the transport belt speed is 100. 3. It is a strip wind forming device.

The invention according to claim 3
2. The strip of the inner liner according to claim 1, wherein the control unit is a control unit that controls the conveyance belt speed to be 70 or more and less than 100 when the calendar roll speed is 100. 3. Wind forming apparatus.

The invention according to claim 4
An extrusion process in which a butyl rubber composition having a predetermined composition is hot-extruded into a ribbon using a hot-extrusion extruder;
A rubber strip processing step of processing the butyl rubber composition that has been heated and extruded into a ribbon shape into a rubber strip having a predetermined shape using a calendar roll;
A rubber strip conveyance step of conveying the rubber strip processed into a predetermined shape to a take-up drum using a conveyance belt;
A winding step of winding the rubber strip that has been conveyed on a winding drum in a spiral manner by strip winding molding,
And having a control process for controlling the conveyor belt speed to be slower than the calendar roll speed,
Furthermore, it has a control step of controlling the extrusion speed in the hot-water extruder to be 19 to 30 when the calender roll speed is 100,
Control by the two control steps is performed simultaneously,
The butyl rubber composition is a butyl rubber composition having a butyl rubber content of 80% or more.

The invention described in claim 5
5. The inner liner according to claim 4, wherein the control step is a control step of controlling the calender roll speed to be greater than 100 and equal to or less than 150 when the transport belt speed is 100. 6. This is a strip wind forming method.

The invention described in claim 6
5. The strip of the inner liner according to claim 4, wherein the control step is a control step of controlling the conveying belt speed to be 70 or more and less than 100 when the calender roll speed is 100. 6. Wind forming method.

  According to the present invention, when producing a raw cover formed with an inner liner using strip wind molding, it is possible to sufficiently suppress the occurrence of strip breakage or strip perforation, resulting in a decrease in productivity. No inner liner strip wind forming technology can be provided.

It is a figure which shows typically the strip wind forming apparatus of an inner liner. It is a photograph explaining the perforation which generate | occur | produced in the inner liner shape | molded by strip wind.

  Hereinafter, the present invention will be described with reference to the drawings based on embodiments.

  FIG. 1 is a diagram schematically showing a strip wind forming apparatus (hereinafter also simply referred to as “strip wind forming apparatus”) for an inner liner of a rubber strip according to the present embodiment. It is the same.

  That is, a hot-roll extruder 1 that heats and extrudes a butyl rubber composition of a predetermined composition into a ribbon shape, and a calendar roll 2 that processes the butyl rubber composition hot-extruded and extruded into a ribbon shape into a rubber strip 4 having a predetermined shape; A conveyor belt 3 that conveys the rubber strip 4 processed into a predetermined shape to the take-up drum 5 and a take-up drum 5 that winds the conveyed rubber strip 4 in a spiral manner by strip winding molding are provided. This is the same as the conventional strip wind forming apparatus.

  However, in the strip wind forming apparatus according to the present embodiment, the conveying belt speed at which the conveying belt 3 conveys the rubber strip 4 and the calendar roll speed at which the calendar roll 2 pushes the rubber strip 4 are mutually set. A conventional strip winder in which the conveyor belt speed and the calendar roll speed are set to the same speed in that control means is provided to control the conveyor belt speed to be slower than the calendar roll speed. It is different from the molding equipment.

  In this way, the control means controls the conveyor belt speed to be slower than the calender roll speed, so that the rubber strip 4 that has been heated and extruded into a ribbon shape and then processed into a predetermined shape by the calender roll 2 is Then, it is conveyed to the take-up drum 5 on the conveying belt 3 having a conveying belt speed slower than the calendar roll speed. As a result, it is sufficiently cooled until it reaches the take-up drum 5 and shrinks, and the subsequent shrinkage is alleviated. For this reason, even if it is the rubber strip 4 produced from the butyl rubber composition with low mechanical strength, generation | occurrence | production of the strip breakage and the punching of a strip like the past is suppressed.

  Thus, since it is a raw cover in which the occurrence of strip breakage or perforation is suppressed in the inner liner, the pneumatic tire after vulcanization is sufficiently prevented from being lost as scrap.

  In the present embodiment, the relationship between the transport belt speed and the calender roll speed is such that when the transport belt speed of the transport belt 3 is 100, the calender roll speed of the calender roll 2 exceeds 100 and is 150 or less. It is preferable to be controlled.

  Further, when the calender roll speed of the calender roll 2 is 100, it is preferable that the transport belt speed of the transport belt 3 is controlled to be 70 or more and less than 100.

  When such a strip wind molding apparatus is used, the inner liner is obtained even when a butyl rubber composition having a butyl rubber content of 80% or more is used. Therefore, it is possible to provide an inner liner in which more sufficient air permeation resistance is ensured.

  In addition, as an extrusion speed which is the speed at which the hot-press extruder 1 is hot-extruded into a ribbon shape, about 30 is preferable with respect to the calender roll speed 100 from the viewpoint of hot-extrusion into an appropriate predetermined shape.

(Test example)
(1) Manufacture of test tires [315 / 80R22.5] size, which is a truck bus tire, was prepared using a strip wind forming apparatus for inner liners shown in FIG. The butyl rubber content of the inner liner was 100%.

(A) Experiment 1 with fixed conveyor belt speed
The first experiment is an experiment in which the conveyance belt speed is fixed.

  Specifically, as shown in the upper part of Table 1, while the conveyance belt speed ratio is fixed to 100%, the calender roll speed ratio is changed to 110 to 160% (the extrusion speed ratio is relative to the conveyance belt speed). The inner liner was formed by strip wind forming, and the raw covers of Test Examples 2 to 6 were produced.

(B) Experiment 2 with fixed calendar roll speed
The second experiment is an experiment in which the calendar roll speed is fixed.

  Specifically, as shown in the lower part of Table 1, the calender roll speed ratio is fixed to 100%, while the conveying belt speed ratio is changed to 90 to 60% (the extrusion speed ratio is relative to the calender roll speed). The inner liner was formed by strip wind forming, and the raw covers of Test Examples 7 to 10 were produced.

(C) Conventional Example For comparison, an inner liner was formed by strip winding molding (extrusion ratio was 30%) at a calender roll speed ratio of 100% with respect to the same conveyance belt speed ratio of 100% as in the conventional case. A cover was made.

(2) Evaluation (a) Evaluation Method For each test example, three raw covers were prepared, and the inside appearance of each prepared raw cover was evaluated.

  Specifically, when the inside appearance of the raw cover was inspected, it was evaluated by a 5-point method, with 5 points being completely free of perforations and rubber strips, and 1 point being most likely to be perforated and stripped. did.

(B) Evaluation results Table 1 shows the evaluation results.

  From Table 1, when the conveyance belt speed ratio is 100%, the calender roll speed ratio exceeds 100%, that is, the conveyance belt speed is slower than the calender roll speed (Test Examples 1 to 6). It can be seen that the occurrence of perforations and strip breaks is suppressed, and if it is 130 to 150% (Test Examples 3 to 5), the occurrence of perforations and strip breaks can be completely prevented.

  Further, when the calender roll speed ratio is set to 100%, when the conveyance belt speed ratio falls below 100% (Test Examples 7 to 10), the occurrence of perforation or strip breakage is suppressed, and 80 to 70% (Test Example). 8 and 9), it can be seen that it is possible to completely prevent perforation and strip breakage.

  Even when the butyl rubber content of the inner liner was 80%, the same result as above was obtained.

  While the present invention has been described based on the embodiments, the present invention is not limited to the above embodiments. Various modifications can be made to the above-described embodiments within the same and equivalent scope as the present invention.

1 Heating Extruder 2 Calendar Roll 3 Conveying Belt 4 Rubber Strip 5 Winding Drum

Claims (6)

A hot-water extruder that heats and extrudes a butyl rubber composition of a predetermined composition into a ribbon;
A calender roll for processing the butyl rubber composition that has been heated and extruded into a ribbon shape into a rubber strip having a predetermined shape;
A transport belt for transporting the rubber strip processed into a predetermined shape;
A winding drum that spirally winds the rubber strip that has been conveyed by strip wind forming,
Control means for controlling the conveyor belt speed to be slower than the calendar roll speed is provided,
Control means is provided for controlling the extrusion speed in the hot-water extruder to be 19 to 30 when the calender roll speed is 100,
The control by the two control means is configured to be performed simultaneously,
Furthermore, the inner liner strip wind forming apparatus is an apparatus for performing strip wind forming of an inner liner using a butyl rubber composition having a butyl rubber content of 80% or more as the butyl rubber composition.   2. The inner liner according to claim 1, wherein the control unit is a control unit that controls the calender roll speed to be greater than 100 and equal to or less than 150 when the transport belt speed is 100. 3. Strip wind forming device.   2. The strip of the inner liner according to claim 1, wherein the control unit is a control unit that controls the conveyance belt speed to be 70 or more and less than 100 when the calendar roll speed is 100. 3. Wind forming equipment. An extrusion process in which a butyl rubber composition having a predetermined composition is hot-extruded into a ribbon using a hot-extrusion extruder;
A rubber strip processing step of processing the butyl rubber composition that has been heated and extruded into a ribbon shape into a rubber strip having a predetermined shape using a calendar roll;
A rubber strip conveyance step of conveying the rubber strip processed into a predetermined shape to a take-up drum using a conveyance belt;
A winding step of winding the rubber strip that has been conveyed on a winding drum in a spiral manner by strip winding molding,
And having a control process for controlling the conveyor belt speed to be slower than the calendar roll speed,
Furthermore, it has a control step of controlling the extrusion speed in the hot-water extruder to be 19 to 30 when the calender roll speed is 100,
Control by the two control steps is performed simultaneously,
An inner liner strip wind molding method, wherein the butyl rubber composition is a butyl rubber composition having a butyl rubber content of 80% or more.   5. The inner liner according to claim 4, wherein the control step is a control step of controlling the calender roll speed to be greater than 100 and equal to or less than 150 when the transport belt speed is 100. 6. Strip wind forming method.   5. The strip of the inner liner according to claim 4, wherein the control step is a control step of controlling the conveying belt speed to be 70 or more and less than 100 when the calender roll speed is 100. 6. Wind molding method.