JP7506297B2 - Method and apparatus for manufacturing pneumatic tires - Google Patents

Description

The present invention relates to a method and device for manufacturing pneumatic tires, and more specifically, to a method and device for manufacturing pneumatic tires that can more stably and quickly form a sealant layer of desired specifications in a specified area on the inner surface of the tire.

To prevent punctures in pneumatic tires, some tires are equipped with a sealant layer on the inside surface of the tire. The sealant material that forms the sealant layer automatically seals any punctures that occur, preventing air from leaking out of the tire.

Various methods have been proposed for manufacturing pneumatic tires with such puncture prevention capabilities. Conventionally, when forming a sealant layer, sealant material is ejected from a nozzle while the tire is rotating, and string-like sealant material is continuously applied in a spiral shape to the inner surface of the tire (see, for example, Patent Document 1).

Therefore, in order to form a sealant layer in a specified area on the inner surface of the tire, it is necessary to wrap the string-shaped sealant material around the inner surface of the tire in a number of times in the circumferential direction of the tire (paragraph 0079 of Patent Document 1). As a result, it takes a considerable amount of time to form the sealant layer. In addition, since the formed sealant layer is in a state where the string-shaped sealant material is arranged in parallel in the width direction, the thickness of the sealant layer in the width direction is likely to vary. Therefore, there is room for improvement in more stably and quickly forming a sealant layer of desired specifications in a specified area on the inner surface of the tire.

JP 2017-74780 A

The object of the present invention is to provide a method and apparatus for manufacturing a pneumatic tire that can more stably and quickly form a sealant layer of the desired specifications on a specified area of the inner surface of the tire.

In order to achieve the above object, the method for manufacturing a pneumatic tire of the present invention has a sealant layer made of a sealant material and continuing around the entire circumferential direction of the tire in a predetermined range on the vulcanized inner surface of the tire, with the inner surface of the sealant layer being exposed inside the tire, and is characterized in that a head having a recess of a predetermined shape and width in a cross-sectional view is arranged so that the recess covers the inner surface of the tire in the predetermined range, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, and the head is arranged cylindrically so that the recess covers the entire inner surface of the tire in the predetermined range that extends continuously around the entire circumferential direction of the tire .
Another manufacturing method of a pneumatic tire of the present invention is a manufacturing method of a pneumatic tire having a sealant layer of a predetermined width made of sealant material in a predetermined range of a vulcanized inner surface of the tire, the inner surface of the sealant layer being exposed inside the tire, the method being characterized in that a head having a recess of a predetermined shape and of the predetermined width in a cross section is arranged so that the recess covers the inner surface of the tire in the predetermined range, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, the head is arranged so that the recess covers the inner surface of the tire in a partial circumferential section of the predetermined range that extends continuously around the entire circumference of the tire, and a filling step of filling the cavity with the sealant material is performed by sequentially shifting the arrangement of the heads in the tire circumferential direction.
Yet another manufacturing method for a pneumatic tire of the present invention is a manufacturing method for a pneumatic tire having a sealant layer of a predetermined width made of sealant material in a predetermined area of the vulcanized inner surface of the tire, the sealant layer being continuous around the entire circumferential direction of the tire, with the inner surface of the sealant layer being exposed inside the tire, the manufacturing method being characterized in that a head having a recess of a predetermined shape and of the predetermined width in cross section is positioned so that the recess covers the inner surface of the tire in the predetermined area, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, wherein the sealant material is supplied to the cavity by a plunger-type injection molding machine.

The present invention provides a pneumatic tire manufacturing apparatus having a sealant supplying means, in which a sealant layer of a predetermined width is formed continuously around the entire circumferential direction of the tire in a predetermined range on the vulcanized inner surface of the tire by the sealant material supplied from the sealant supplying means, and the inner peripheral surface of the sealant layer is exposed inside the tire. The pneumatic tire manufacturing apparatus is characterized in that the pneumatic tire manufacturing apparatus comprises a head having a recess of a predetermined shape and of the predetermined width in cross section, a supply pipe connecting the sealant supplying means and the head, and a setting mechanism for positioning the head such that the inner surface of the tire in the predetermined range is covered by the recess, and the head is positioned cylindrically by the setting mechanism such that the entire inner surface of the tire in the predetermined range that extends continuously around the entire circumferential direction of the tire is covered by the recess, a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, and the sealant layer is formed by filling the cavity with the sealant material.
Another pneumatic tire manufacturing apparatus of the present invention has a sealant supplying means, and a sealant layer is formed in a predetermined range on the vulcanized inner surface of the tire by the sealant material supplied from the sealant supplying means, the sealant layer being continuous over the entire circumference of the tire with a predetermined width, and the inner peripheral surface of the sealant layer is exposed inside the tire. The pneumatic tire manufacturing apparatus further comprises a head having a recess of a predetermined shape and the predetermined width in a cross-sectional view, a supply pipe that communicates between the sealant supplying means and the head, and a setting mechanism that positions the head so that the inner surface of the tire in the predetermined range is covered by the recess. the head is positioned by the setting mechanism so that the inner surface of the tire in a portion of the circumferential direction of the predetermined range extending continuously around the entire tire circumferential direction is covered by the recess, a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, the sealant material is filled into the cavity to form the sealant layer, and a filling process of filling the cavity with the sealant material is performed by sequentially shifting the position of the head in the tire circumferential direction.
Still another pneumatic tire manufacturing apparatus of the present invention has a sealant supplying means, in which a sealant layer of a predetermined width is formed continuously around the entire circumferential direction of the tire in a predetermined range on the vulcanized inner surface of the tire by the sealant material supplied from the sealant supplying means, and the inner peripheral surface of the sealant layer is exposed inside the tire, the pneumatic tire manufacturing apparatus is characterized in that it comprises a head having a recess of a predetermined shape and of the predetermined width in cross section, a supply pipe that connects the sealant supplying means and the head, a setting mechanism that positions the head so that the inner surface of the tire in the predetermined range is covered by the recess, and a plunger-type injection molding machine, wherein a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, and the sealant material is supplied by the plunger-type injection molding machine to fill the cavity, thereby forming the sealant layer.

According to the present invention, the cavity is constructed by positioning the head so that the tire inner surface in the specified range is covered by the recess of the specified width, and the sealant layer of the specified width is formed by filling the cavity with the sealant material. Therefore, the sealant layer of the specified width is formed all at once in the width direction. Therefore, it is not necessary to form the sealant layer by wrapping and extending the string-shaped sealant material multiple times in the tire circumferential direction along the tire inner surface, and the sealant layer of the specified width can be formed quickly. In addition, the thickness variation in the width direction of the formed sealant layer is suppressed, which is advantageous for stably forming a sealant layer of the desired specifications.

1 is an explanatory diagram illustrating an outline of a manufacturing apparatus for a pneumatic tire according to the present invention; 2 is a cross-sectional view illustrating the periphery of the head in FIG. 1 as viewed from the front. 3 is an explanatory diagram illustrating the head periphery in FIG. 2 as viewed from the side; FIG. 4 is a cross-sectional view illustrating a state in which a head is inserted into a tire as viewed from the side. FIG. FIG. 5 is an explanatory diagram illustrating the inside of the tire of FIG. 4 in cross section. 5 is a cross-sectional view illustrating a state in which the head of FIG. 4 is set in contact with the inner surface of a tire, as viewed from the side. FIG. FIG. 7 is an explanatory diagram illustrating the inside of the tire of FIG. 6 in cross section. 8 is an explanatory diagram illustrating a state in which the cavity in FIG. 7 is filled with a sealant material. FIG. 1 is a cross-sectional view illustrating a tire on which a sealant layer is formed, as viewed from the side. 13 is a cross-sectional view illustrating the periphery of a head of another embodiment of a manufacturing apparatus as viewed from the side. 11 is a cross-sectional view illustrating a state in which the head of FIG. 10 is set in contact with the inner surface of the tire, as viewed from the side. FIG. FIG. 11 is an explanatory diagram illustrating the inside of the tire of FIG. 10 in cross section. 13 is an explanatory diagram illustrating a state in which the cavity in FIG. 12 is filled with a sealant material. FIG. 12 is a cross-sectional view illustrating a state in which the head of FIG. 11 is set in contact with the inner surface of the tire at a position shifted in the tire circumferential direction, as viewed from the side. FIG.

The method and device for manufacturing a pneumatic tire of the present invention will be described below based on the embodiment shown in the figures.

By using the pneumatic tire manufacturing apparatus 1 of the present invention illustrated in Figures 1 to 3, a sealant layer SL of a predetermined width W is formed in a predetermined area on the tire inner surface Ta of the vulcanized pneumatic tire T1. In other words, by using the manufacturing apparatus 1, a pneumatic tire T2 having a sealant layer SL and a puncture prevention function is manufactured.

This manufacturing device 1 includes a sealant supply means 2, a head 5, a supply pipe 6 that connects the sealant supply means 2 and the head 5, a setting mechanism 6b that sets the head 6 at a desired position on the tire inner surface Ta, a holding mechanism 7, and a control unit 8. The control unit 8 controls the operation of each component of the manufacturing device 1.

The sealant supply means 2 supplies the sealant material S to the head 5 through the supply pipe 6. The sealant material S has a high viscosity at room temperature and does not flow easily. Various known sealant materials S (e.g., butyl rubber-based sealant material S) used to prevent tire punctures can be used.

In this embodiment, a plunger-type injection molding machine in which an extruder 3 and a plunger 4 are connected in series is used as the sealant supplying means 2. A screw 3b is provided inside the cylinder 3a that constitutes the extruder 3. A piston portion 4b that moves back and forth is provided inside the cylinder 4a that constitutes the plunger 4. A supply pipe 6 is connected to the discharge port of the plunger 4.

The head 5 is formed, for example, from metal, and has a recess 5a of a predetermined shape and a predetermined width W in cross-sectional view, as shown in FIG. 2. This predetermined width W is substantially the same as the width of the sealant layer SL to be formed. In this embodiment, multiple heads 5 are provided, and as shown in FIG. 3, each head 5 has an arc shape in side view. When adjacent heads 5 are connected in the circumferential direction and each head 5 is arranged in a cylindrical shape, the recesses 5a of all heads 5 are connected in the circumferential direction.

The supply pipe 6 has one axial tube 6a extending from the plunger 4, and multiple radial tubes 6b branching out and extending radially from the axial tube 6a. A head 5 is connected to the tip of each radial tube 6b. Each radial tube 6b has a telescopic structure and can be extended and retracted. These telescopic radial tubes 6b function as a setting mechanism. The dashed line CL in the figure indicates the axis of the axial tube 6a.

The configuration of the holding mechanism 7 is not limited as long as it can hold the tire T1 in a predetermined state. In this embodiment, the holding mechanism 7 has a rotating roller 7a, a base 7b, and a support part 7c erected on the base 7b. Four rotating rollers 7a are rotatably supported on the support part 7c. The holding mechanism 7 can slide in the direction of the axis CL.

Next, an example of the procedure for manufacturing a pneumatic tire T2 according to the present invention will be described.

First, a green tire is vulcanized by a known method to manufacture tire T1. If necessary, a treatment is performed to remove any adhering release agent, etc., from a predetermined area of the tire inner surface Ta of tire T1. Tire T1 is held by rotating rollers 7a of a holding mechanism 7. Next, as shown in Figures 4 and 5, with each radial tube 6b in a contracted state, the holding mechanism 7 is slid in the direction of the axis CL so as to be close to the plunger 4, and each head 5 is positioned inside tire T1.

As shown in Figs. 6 and 7, each radial tube 6b is then extended to bring each head 5 into contact with the tire inner surface Ta, connecting adjacent heads 5 in the circumferential direction and positioning the heads 5 in a cylindrical shape. This positions the heads 5 so that the recesses 5a cover a predetermined range of the tire inner surface Ta. In this embodiment, the heads 5 are positioned in a cylindrical shape so that the recesses 5a cover the entire tire inner surface Ta in a predetermined range that extends continuously around the entire tire circumferential direction.

When the head 5 is set on the tire T1 in this manner, as shown in FIG. 6, multiple radial tubes 6b radiate outward from the axial center tube 6a at the axial center of the cylindrically arranged head 5 toward each head 5. In a predetermined range of the tire inner surface Ta, a space C is formed that is surrounded by the recess 5a of the head 5 abutting against the tire inner surface Ta and the tire inner surface Ta facing the recess 5a. The present invention uses this space C as a cavity C.

In the sealant supply means 2, the screw 3b of the extruder 3 is rotated to appropriately heat the sealant S contained inside the cylinder 3a while appropriately reducing its viscosity, and the sealant S is extruded from the extrusion port at the tip of the cylinder and fed into the plunger 4. In the plunger 4, the piston part 4b is advanced to supply the desired amount of the fed sealant S to the head 5 (cavity C) through the supply pipe 6.

That is, as shown in FIG. 8, the sealant material S is filled into the cavity C through the axial tube 6a and each radial tube 6b. The amount of sealant material S supplied can be precisely adjusted by using the plunger 4. The sealant material S filled into the cavity C is shaped by the head 5 for a predetermined time (e.g., several tens of seconds to about 2 minutes), forming a sealant layer SL of a predetermined width W in a predetermined area of the tire inner surface Ta.

After the sealant layer SL is formed, each radial tube 6b is shrunk to separate each head 5 from the manufactured tire T2 (tire inner surface Ta and sealant layer SL), and the tire T2 is removed from the manufacturing device 1. In this way, a tire T2 is manufactured having a sealant layer SL of a predetermined width W in a predetermined area of the tire inner surface Ta, as illustrated in FIG. 9.

As described above, by filling the cavity C with the sealant material S, the sealant layer SL of the specified width W is formed in the entire width direction at once. Therefore, the sealant layer SL of the specified width W can be quickly formed without the need for the complicated operation of wrapping and extending the string-like sealant material multiple times in the circumferential direction along the inner surface Ta of the tire. Moreover, in this embodiment, the cylindrical sealant layer SL that is continuous in the circumferential direction of the tire is formed at once, which is extremely advantageous in shortening the time required to form the sealant layer SL.

A predetermined amount of sealant material S filled in cavity C is pressed against the tire inner surface Ta by head 5 and shaped. As a result, the variation in thickness of sealant layer SL in the width direction is suppressed. This is advantageous for stably forming a sealant layer SL of the desired specifications. The variation in thickness of sealant layer SL in the tire circumferential direction is also suppressed. By making the cross-sectional shape of recess 5a the same shape as the cross-sectional shape (profile) of the sealant layer SL to be formed, even a sealant layer SL with a complex profile can be easily formed.

Figures 10 to 14 show another embodiment of the manufacturing device 1. This embodiment differs from the previous embodiment in the specifications of the head 5, but the other configurations are substantially the same as the previous embodiment.

In this embodiment, only one head 5 is provided, and the tire T1 is rotated in the tire circumferential direction relative to the head 5 by the holding mechanism 7. This holding mechanism 7 is structured to rotate the tire T1, but instead of this holding mechanism 7, a mechanism for rotating the head 5 around the axle tube 6a can also be used. Alternatively, a mechanism for rotating the tire T1 and the head 5 can also be used.

To form the sealing layer SL, the tire T1 is held in an upright position using the rotating rollers 7a of the holding mechanism 7. Next, the head 5 is placed inside the tire T1 with the radial tubes 6b contracted. Thereafter, as illustrated in Figs. 11 and 12, the radial tubes 6b are extended to bring the head 5 into contact with the tire inner surface Ta, and the head 5 is positioned so that the recesses 5a cover the tire inner surface Ta in a predetermined range. In this embodiment, as illustrated in Fig. 11, the head 5 is positioned so that the recesses 5a cover a portion of the tire inner surface Ta in a predetermined range that extends continuously around the entire tire circumferential direction.

Next, as shown in FIG. 13, a filling process is performed in which the sealant material S is filled into the cavity C through the supply pipe 6 to form a sealant layer SL in a circumferential section. Thereafter, as shown in FIG. 14, a filling process is performed in which the sealant material S is filled into the cavity C at positions where the head 5 is sequentially shifted in the tire circumferential direction. That is, after the filling process is performed at one position to form a sealant layer SL in a circumferential section, the holding mechanism 7 is immediately operated to position the head 5 in a position shifted in the tire circumferential direction by a portion of the circumferential direction, and the filling process is repeated at the shifted position. As a result, a cylindrical sealant layer SL is formed in a predetermined range of the tire inner surface Ta and in the tire circumferential direction with a predetermined width W.

In this embodiment, one radial tube 6b is provided at the tip with one head 5, but multiple radial tubes 6b can also be provided with a head 5 at each tip. That is, the heads 5 are arranged at intervals in the circumferential direction on the tire inner surface Ta to form a sealant layer SL that is intermittent in the circumferential direction, and then the filling process is performed with the heads 5 sequentially shifted in the circumferential direction. In this way, a cylindrical sealant layer SL that is continuous in the tire circumferential direction with a predetermined width W can be formed in a predetermined area of the tire inner surface Ta.

1 Manufacturing device 2 Sealant supply means 3 Extruder 3a Cylinder 3b Screw 4 Plunger 4a Cylinder 4b Piston portion 5 Head 5a Recess 6 Supply pipe 6a Axial pipe 6b Radial pipe (setting mechanism)
7 Holding mechanism 7a Rotating roller 7b Base 7c Support part 8 Control part S Sealant material SL Sealant layer T1, T2 Tire Ta Tire inner surface

Claims (7)

A method for manufacturing a pneumatic tire, comprising: a sealant layer made of a sealant material and continuous over the entire circumference of the tire in a predetermined range on an inner surface of the vulcanized tire; and an inner peripheral surface of the sealant layer being exposed inside the tire, the method comprising the steps of:
A method for manufacturing a pneumatic tire, characterized in that a head having a recess of a predetermined shape and width in cross section is positioned so that the recess covers the inner surface of the tire in the predetermined range, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, wherein the head is positioned cylindrically so that the recess covers the entire inner surface of the tire in the predetermined range that extends continuously around the entire circumferential direction of the tire . 2. The method for manufacturing a pneumatic tire according to claim 1, wherein a supply pipe is radially branched into a plurality of pipes extending from a cylindrical axial center portion of the head toward the cavity, and the sealant material is filled into the cavity through each of the branched supply pipes. A method for manufacturing a pneumatic tire, comprising: a sealant layer made of a sealant material and continuous over the entire circumference of the tire in a predetermined range on an inner surface of the vulcanized tire; and an inner peripheral surface of the sealant layer being exposed inside the tire, the method comprising the steps of:
a head having a recess of a predetermined shape and a predetermined width in a cross-sectional view is positioned so that the recess covers the inner surface of the tire in the predetermined range, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, the head is positioned so that the recess covers the inner surface of the tire in a portion of the circumferential direction of the predetermined range that extends continuously around the entire circumference of the tire, and a filling process of filling the cavity with the sealant material is performed by sequentially shifting the position of the head in the circumferential direction of the tire . A method for manufacturing a pneumatic tire, comprising: a sealant layer made of a sealant material and continuous over the entire circumference of the tire in a predetermined range on an inner surface of the vulcanized tire; and an inner peripheral surface of the sealant layer being exposed inside the tire, the method comprising the steps of:
a head having a recess of a predetermined shape and width in cross section, positioned so that the recess covers the inner surface of the tire in the predetermined range, a space surrounded by the recess and the inner surface of the tire facing the recess is used as a cavity, and the sealant material is filled into the cavity to form the sealant layer, the sealant material being supplied to the cavity by a plunger-type injection molding machine . A pneumatic tire manufacturing apparatus includes a sealant supplying means, and a sealant layer is formed on a predetermined area of a vulcanized inner surface of the tire by a sealant material supplied from the sealant supplying means, the sealant layer being continuous over a predetermined width all around the tire in the circumferential direction, and an inner peripheral surface of the sealant layer is exposed inside the tire,
a head having a recess of a predetermined shape and the predetermined width in a cross-sectional view, a supply pipe that connects the sealant supply means and the head, and a setting mechanism that positions the head so that the recess covers the inner surface of the tire in the predetermined range,
The head is arranged in a cylindrical shape by the setting mechanism so that the entire tire inner surface of the predetermined range extending continuously around the entire tire circumferential direction is covered by the recess,
a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, and the sealant layer is formed by filling the cavity with the sealant material. A pneumatic tire manufacturing apparatus includes a sealant supplying means, and a sealant layer is formed on a predetermined area of a vulcanized inner surface of the tire by a sealant material supplied from the sealant supplying means, the sealant layer being continuous over a predetermined width all around the tire in the circumferential direction, and an inner peripheral surface of the sealant layer is exposed inside the tire,
a head having a recess of a predetermined shape and the predetermined width in a cross-sectional view, a supply pipe that connects the sealant supply means and the head, and a setting mechanism that positions the head so that the recess covers the inner surface of the tire in the predetermined range,
The head is positioned by the setting mechanism so that the tire inner surface in a partial section in the circumferential direction of the predetermined range that extends continuously around the entire tire circumferential direction is covered by the recess,
a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, the sealant layer is formed by filling the cavity with the sealant material, and a filling process of filling the cavity with the sealant material is performed by sequentially shifting the position of the head in the circumferential direction of the tire . A pneumatic tire manufacturing apparatus includes a sealant supplying means, and a sealant layer is formed on a predetermined area of a vulcanized inner surface of the tire by a sealant material supplied from the sealant supplying means, the sealant layer being continuous over a predetermined width all around the tire in the circumferential direction, and an inner peripheral surface of the sealant layer is exposed inside the tire,
a head having a recess of a predetermined shape and the predetermined width in a cross-sectional view, a supply pipe that connects the sealant supply means and the head, a setting mechanism that positions the head so that the recess covers the inner surface of the tire in the predetermined range , and a plunger-type injection molding machine ,
a space surrounded by the recess of the head positioned by the setting mechanism and the inner surface of the tire facing the recess becomes a cavity, and the sealant material is supplied by the plunger-type injection molding machine to fill the cavity, thereby forming the sealant layer.

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