JP2001009848A - Postcure inflator and method for cooling tire after vulcanization - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a postcure inflator which can cool a tire just after vulcanization while its specified shape and dimension are surely ensured. SOLUTION: First molds 13 and 14 are fixed on one side face on first and second mold supporting plates 9a and 11a sides being brought into contact with each other and separable from each other. The first and second molds 13 and 14 are formed into annular shapes, and first and second storing recessed parts 13a and 14a provided with the shape of the outer side face of a tire T are formed on their insides. In addition, first and second bead holding mechanisms 18 and 22 are fixed on first and second large diameter parts 16b and 17b formed on first and second slide bases 16 and 17. In addition, a water supply mechanism 20 is arranged in the first slide base 16 and a water drainage mechanism 24 is arranged in the second slide base 17.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a post-cure inflator, and more particularly to cooling a pneumatic tire immediately after vulcanization.

[0002]

2. Description of the Related Art Heat-shrinkable materials such as nylon and polyester are used as reinforcing cords for tires. When these reinforcing cords are used, if the vulcanized tire is left to cool in a natural state, the reinforcing cord shrinks and cannot maintain a predetermined shape and dimensions. Therefore, the pneumatic tire immediately after vulcanization is post-cured inflator ( (Cooling and heat setting of the physical properties), and cooled with a predetermined internal pressure filled.

In this method of cooling a tire immediately after vulcanization, for example, a bead portion of a vulcanized tire is supported on a pair of support rims, filled with compressed air, and rotated at a constant speed to expand and cool the tire. Method (Japanese Patent Publication No. 49-17425)
), A method in which a bead portion of a vulcanized tire is supported by a pair of support rims and rotated at a high speed with cooling water filled therein (Japanese Patent Application Laid-Open No. 50-39778). (Japanese Patent Laid-Open No. 2-2)
2016), a method of supporting a bead portion of a vulcanized tire on a pair of supporting rims, supplying air to a predetermined pressure, and forcibly circulating the air in the tire (Japanese Patent Laid-Open No. 4-131210). Is disclosed.

[0004]

Recently, demands for tire quality and cost have been increasing, and it has become particularly important to increase the uniformity of the tire and to reduce the manufacturing cost. For example, there is also a need to remove uniformity defects caused by the overlap generated at the winding start end and winding end of the reinforcing cord. Accordingly, it has become necessary to cool the vulcanized tire so that its shape hardly changes.

[0005] However, in each of the above-described methods of cooling a tire immediately after vulcanization, there is nothing from the bead portion of the tire to the sidewall portion, the shoulder portion, and the tread portion, which regulate the deformation of the tire during cooling. There is a risk of deformation at the part.

The present invention has been made to solve the above problems, and provides a post cure inflator capable of cooling a tire immediately after vulcanization while ensuring a predetermined shape and size. It is in.

[0007]

In order to solve the above-mentioned problems, a first aspect of the present invention relates to a post cure inflator for cooling a tire after vulcanization, a bead portion for gripping a bead portion of the tire. A first mold and a second mold which are provided with a gripping mechanism, first and second storage recesses which cooperate with each other to receive the outer surface of the tire, and which can be separated from and separated from each other; The gist includes a water distribution mechanism for discharging cooling water to the inner surface of the tire held by the mold and the second mold, and a drainage mechanism for discharging cooling water accumulated in the tire.

According to a second aspect of the present invention, in the post cure inflator according to the first aspect, the water distribution mechanism includes a bead gripping mechanism, a tire held by a first mold and a second mold. The gist of the invention is to provide a water distribution pipe that discharges cooling water while rotating toward the side surface.

According to a third aspect of the present invention, in the post cure inflator according to the first aspect, the bead portion gripping mechanism, the first mold and the second mold rotate while holding the tire. Make a summary.

[0010] According to the fourth aspect of the present invention, the first aspect is provided.
4. The post cure inflator according to claim 1, wherein the first
On the inner peripheral surfaces of the first and second housing recesses of the mold and the second mold,
First and second contact preventing grooves are provided to prevent the right and left shoulder portions of the tire from contacting each other.

According to a fifth aspect of the present invention, there is provided a method for cooling a tire after vulcanization, wherein the first mold and the second mold which are capable of gripping a bead portion of the tire by a bead portion gripping mechanism and being capable of coming and coming from each other. While the outer surface of the tire is housed and held in the housing recess formed in the mold, the inner surface of the tire is cooled by a water distribution mechanism, and the cooling water accumulated in the tire is removed from the outside of the tire by a drainage mechanism. And to cool the tire after vulcanization.

According to the first and fifth aspects of the invention, the bead gripping mechanism holds the bead portion of the tire, and the outer surface of the tire is housed in the housing recesses of the first and second molds. The tire after vulcanization is cooled while receiving cooling water on its inner peripheral surface from a water distribution mechanism. Further, the cooling water accumulated in the tire is sucked from a suction hose and drained out of the tire.

Therefore, the inner peripheral surface of the tire is cooled, the shape of the bead portion of the tire is restricted by the bead gripping mechanism, and the outer surface of the tire is controlled by the pressure of the cooling water discharged from the water distribution mechanism. While being pressed outward in the radial direction of the tire, the outer surface of the tire is the first,
The change in the shape is regulated by the housing recess of the second mold.

According to the second aspect of the present invention, the cooling water is discharged from the rotating water pipe toward the inner surface of the tire. Further, since the cooling water accumulated in the tire is drained out of the tire by the drainage mechanism, the inner surface of the tire is uniformly cooled and can receive a uniform water pressure.

According to the third aspect of the present invention, since the first and second dies rotate, the tires mounted in the receiving recesses have the diameters of the first and second dies due to centrifugal force. Receive force in the direction. Furthermore, water pressure is uniformly applied to the inner surface of the rotating tire by the cooling water discharged from the non-rotating water distribution pipe.

Accordingly, the outer surface and the inner surface of the tire are cooled while being uniformly pressed by the centrifugal force and the water pressure toward the first and second housing recesses, so that the outer surface of the tire is the first and second housing recesses. Due to the shape of the concave portion, no distortion occurs on the inner surface of the tire.

According to the fourth aspect of the present invention, the right and left shoulder portions of the tire can be slightly expanded, that is, the tread width of the tire can be increased.

[0018]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of a post cure inflator embodying the present invention will be described below with reference to FIGS.

As shown in FIG. 1, a post cure inflator 1 has first and second housing bases 2, 3 on both sides thereof.
It has. The first and second housing bases 2 and 3
It is formed in a pillar shape, and its bottom is placed on the floor. The first and second housing bases 2 and 3 have first and second housing bases on top thereof.
Slide base support portions 4 and 5 are formed. First,
The second slide base support portions 4 and 5 are formed in a cylindrical shape,
Both ends are open. First and second frame supporting portions 6 and 7 are provided between the first and second housing bases 2 and 3, respectively.
The second housing bases 2 and 3 are disposed equidistant from the center between the second housing bases 2 and 3. First and second frame supporting portions 6,
7 is formed in a plate shape, and a caster 8 is fixed to the lower surface thereof. Then, the first and second frame support portions 6, 7
Are movable between the first and second housing bases 2 and 3.

A first frame 9 is disposed on the first frame support 6. The first frame 9 includes a first mold supporting plate 9a and a first reinforcing plate 9b. The first mold support plate 9a is a rectangular plate made of metal, for example, iron, and has a slide base through hole 9c formed at the center thereof. The lower end surface of the first mold supporting plate 9a is fixed to the upper surface of the first frame supporting portion 6. The first reinforcing plate 9b is a plate made of metal, for example, iron, and has a substantially trapezoidal shape. The lower end surface of the first reinforcing plate 9b is fixed to the upper surface of the first frame supporting portion 6, and one side surface supports the side surface of the first mold supporting plate 9a on the first housing base 2 side. . A first frame cylinder 10 is fixed to a lower portion of the first reinforcing plate 9b.

Therefore, the first frame 9 can be moved toward the first housing base 2 by operating the first frame cylinder 10 to move the first frame support 6 on the floor via the casters 8. it can.

A second frame 11 is provided on the second frame support 7. The second frame 11 includes a second mold supporting plate 11a and a second reinforcing plate 11b. The second mold support plate 11a is a plate made of metal, for example, iron, and has a slide base through hole 11c formed in the center thereof. The lower end surface of the second mold support plate 11 a is fixed to the upper surface of the second frame support 7. The second reinforcing plate 11b is a plate made of metal, for example, iron, and has a substantially trapezoidal shape. The lower end surface of the second reinforcing plate 11b is fixed to the upper surface of the second frame support portion 7, and
One side surface supports the side surface of the second mold support plate 11a on the second housing base 3 side. Also, the second reinforcing plate 11b
The second frame cylinder 12 is fixed to a lower portion of the second frame cylinder.

Accordingly, the second frame 11 can be moved toward the second housing base 3 by operating the second frame cylinder 12 and moving the second frame support 7 on the floor via the casters 8. .

A first mold 13 is fixed to one side of the first mold support plate 9a on the side of the second mold support plate 11a.
The first mold 13 is formed in an annular shape, and a first mold 13 is provided inside thereof.
An accommodation recess 13a is formed. First accommodation recess 13a
Is formed in a shape obtained by cutting the shape of the outer surface of the predetermined tire T into a circle at the center thereof, the inner side surface 13b on the center side of the first accommodation recess 13a is formed in the shape of the sidewall portion Sw of the tire T, The central inner surface 13c of the first recess 13a is formed in the shape of the shoulder S of the tire T, and the outer peripheral inner surface 13d of the first recess 13a.
Is formed in the shape of one half of the tread portion Td of the tire T.

Inside the first mold 13, a first water jacket 13e is formed along the first housing recess 13a. The first water jacket 13e is formed with an inflow port and an outflow port (not shown) of the cooling water so that the cooling water can circulate. Further, a first slide base insertion hole 13f is formed at the center side of the first housing recess 13a. The first slide base insertion hole 13f communicates with the slide base through hole 9c. Further, a first joint 13g is formed on the first mold 13 on the side of the second mold support plate 11a. The second mold support plate 11a side of the first joint 13g is a flat surface, and the tip of the first joint 13g is the first mold 1
3 protrudes from the outer peripheral surface.

The first mold 13 of the second mold support plate 11a
A second mold 14 is fixedly provided on one side surface of the side opposite to the first mold 13. The second mold 14 has the same shape as the first mold 13, and has a second housing recess 14a formed inside. The shape of the second housing recess 14a is formed by cutting the shape of the outer surface of the predetermined tire T into a circle at the center thereof, and the inner side surface 14b on the center side of the second housing recess 14a has the shape of the sidewall portion Sw of the tire T. Formed in the second
The central side inner side surface 14c of the housing recess 14a is formed in the shape of the shoulder S, and the outer peripheral side inner surface 14d of the second housing recess 14a is formed in a half of one side of the tread portion Td of the tire T. .

A second water jacket 14e is formed inside the second mold 14 along the second housing recess 14a. The second water jacket 14e is formed with an inflow port and an outflow port (not shown) of the cooling water so that the cooling water circulates. A second slide base insertion hole 14f is formed at the center of the second housing recess 14a. The second slide base insertion hole 14f communicates with the slide base through hole 11c. Further, the second mold 1
The second bonding portion 14g is formed on the first mold 13 side of No.4. The first mold 13 side of the second joint 14g is a flat surface, and the tip of the second mold 14 protrudes from the outer peripheral surface of the second mold 14.

When the first mold 13 and the second mold 14 are opposed to each other, a lock fitting 15 is detachably attached to the tip of the first joint 13g and the second joint 14g. It has become. The lock fitting 15 is formed in an annular shape, and a recess is formed in the center of the inner peripheral surface. The distal end portions of the first joint portion 13g and the second joint portion 14g are fitted into the concave portions. And the lock fitting 15 is the first
The mold 13 and the second mold 14 are fixed so as not to be divided.

Also, while removing the lock fitting 15,
First frame cylinder 10 and second frame cylinder 1
2 to operate the first frame 9 and the second frame 11
Are moved to the first housing base 2 side and the second housing base 3 side to move the first mold 13 and the second mold 14 as shown in FIG.
And can be divided as shown in FIG.

A first slide base 16 is movably disposed in the first slide base support 4. The first slide base 16 is formed in a cylindrical shape, and the inside thereof is a through hole. The first slide base 16 has a first small diameter portion 16a and a first large diameter portion 16b.
The first small diameter portion 16 a is supported in the first slide base support 4 so as to be movable in the axial direction of the first slide base support 4. A first large-diameter portion 16b is formed to extend from the first small-diameter portion 16a on the first mold 13 side. First large diameter portion 16
The diameter of b is larger than the diameter of the first small diameter portion 16a, and is sufficiently smaller than the diameter of the slide base through hole 9c.

A first bead gripping mechanism 18 is fixed to the outer peripheral surface of the first large diameter portion 16b. First bead gripping mechanism 1
As shown in FIG. 4, 8 is provided with a grip fixing unit 18a and a grip drive unit 18b. The grip fixing portion 18a is formed in an annular shape, and is fixed to the outer peripheral surface of the first large diameter portion 16b on the side of the second mold 14 as shown in FIG. Grip fixing part 18
As shown in FIG. 4, a bead receiving surface 18c is formed at an end of the outer side surface of "a". The bead receiving surface 18c is formed in an outer shape of the bead portion B of the tire T. A plurality of guide recesses 18d are formed on the first slide base 16 side of the holding and fixing portion 18a, and guide grooves 18f are formed on both inner side surfaces 18e in the guide recesses 18d.
The guide groove 18f is bent at the center thereof, one of which extends in the direction of the bead receiving surface 18c, and the other of which extends parallel to the axis of the first large diameter portion 16b.

The sliding portion 18k of the grip driving portion 18b is fitted in the guide recess 18d. The grip drive unit 18b includes a drive cylinder 18h. The bottom surface of the sliding portion 18k is in contact with the outer peripheral surface of the first large diameter portion 16b.
6b slides in the axial direction. At the distal end of the sliding portion 18k, the base end of the rotating plate 18l is connected to the rotating shaft 18l with respect to the sliding portion 18k.
It is supported rotatably about o. This rotating shaft 18
o is formed to extend into the guide groove 18f. The rotating plate 181 is bent at the center portion thereof into a dogleg shape on the bead receiving surface 18c side, and a bead gripping surface 18m is formed on a side surface on the bead receiving surface 18c side. This bead gripping surface 18m is the bead portion B of the tire T.
It is formed in the shape inside. The bead gripping surface 18m grips one bead portion B of the tire T placed on the bead receiving surface 18c in cooperation with the bead receiving surface 18c. A guide projection 18g is formed at the center of the rotating plate 181 to protrude. Both ends of the guide projection 18g are fitted into the guide groove 18f.

A base end of the sliding portion 18k is connected to a cylinder rod 18j of a drive cylinder 18h fixed to the first large diameter portion 16b via a cylinder support 18i. Then, when the drive cylinder 18h is driven, the sliding portion 18k moves between two positions, a holding position shown in FIG. 1 (FIG. 4) and a standby position shown in FIG. That is, when the sliding portion 18k is guided to the grip position, the rotating plate 18
The guide projection 18g is guided in the guide groove 18f and protrudes from the guide recess 18d.
The bead portion B of the tire T is gripped by rotating to the c side. Conversely, when the sliding portion 18k is guided to the standby position, the rotating plate 181 is accommodated in the guide recess 18d.

As shown in FIG. 1, a first slide base cylinder 19 is connected to the first housing base 2 below the first large diameter portion 16b. When the base cylinder 19 is driven, the first slide base 16 is movably supported by the first slide base support portion 4, so that the work position shown in FIG. 1 and the standby position shown in FIG. It moves between two positions.

Further, a water distribution mechanism 20 is provided inside the first slide base 16. The water distribution mechanism 20 includes a water distribution pipe support member 20a, a water distribution pipe sliding member 20b, and a water distribution pipe 20c.
And a motor 20d. Water pipe support member 20a
Is formed in a cylindrical shape, and both ends thereof are open. One end of the water distribution pipe support member 20 a is enlarged in diameter and fixed to the inner peripheral surface of the first slide base 16. A water pipe sliding member 20b is supported inside the water pipe support member 20a so as to be slidable in the axial direction of the water pipe support member 20a. The water pipe sliding member 20b is formed in a cylindrical shape with both ends open, the end on the second slide base 17 side is enlarged in diameter, and the outer peripheral surface is formed on the inner peripheral surface of the first slide base 16 in the axial direction. Slidably in contact with This water pipe sliding member 20b
A cylindrical lock housing 21 is fixed to the outer peripheral surface whose diameter has been increased, and is in sliding contact with the first slide base 16 in the axial direction. Further, a plurality of water discharge holes 21a are formed on the outer peripheral surface at the center of the lock housing 21 in the circumferential direction.

A water pipe 20c is provided at the center of the water pipe sliding member 20b. The water pipe 20c is supported in the water pipe sliding member 20b via a bearing 20e. An output shaft of a motor 20d is fixed to one end of the water distribution pipe 20c via a joint 20f. Further, the other end of the water distribution pipe 20c is a nozzle and is bent toward the water discharge hole 21a, and its tip is the first housing recess 13a and the second housing recess 14a of the first mold 13 and the second mold 14. In the direction of. Further, cooling water W is supplied to the water distribution pipe 20c from a water supply port (not shown).

Therefore, when the motor 20d is rotated, the water distribution pipe 20c is rotated. Then, while rotating the water distribution pipe 20c, the cooling water W can be discharged from the distal end of the water distribution pipe 20c toward the water discharge hole 21a through the water discharge hole 21a.

The water distribution mechanism 20 and the lock housing 2
2 is slidable in the axial direction of the first slide base 16 as shown in FIG. 2 and can move to the first housing base 2 side. Further, the water distribution mechanism 20 and the lock housing 21 are disposed so as to be movable in the axial direction in the first slide base 16, and are moved in the first slide base 16 by a water distribution means moving mechanism (not shown). Then, the water distribution mechanism 20 and the lock housing 21 are moved to the water distribution position shown in FIG.
Is moved between the two standby positions shown in FIG.

A second slide base 17 is movably disposed in the second slide base support 5. The second slide base 17 is formed in a cylindrical shape, and the inside thereof is a through hole. The second slide base 17 has a second small diameter portion 17a and a second large diameter portion 17b.
The second small diameter portion 17 a is supported in the second slide base support 5 so as to be movable in the axial direction of the second slide base support 5. A second large-diameter portion 17b is formed to extend from the second small-diameter portion 17a on the second mold 14 side. Second large diameter portion 17
The diameter of b is sufficiently smaller than the inner diameter of the slide base through hole 11c.

A second bead gripping mechanism 22 is fixed to the outer peripheral surface of the second large diameter portion 17b. Second bead gripping mechanism 2
2 has the same configuration as the first bead gripping mechanism 18 described above, and a detailed description thereof will be omitted. Hereinafter, the names and reference numerals of the members forming the second bead gripping mechanism 22 will be described using the reference numerals of the member names of the first bead gripping mechanism 18.

A second slide base cylinder 23 is fixed to the second housing base 3 below the second large diameter portion 17b. When the base cylinder 23 is driven, the second slide base 17 is movably supported by the second slide base support portion 5, so that the work position shown in FIG. 1 and the standby position shown in FIG. It moves between two positions.

A drainage mechanism 24 is provided in the second slide base 17. The drainage mechanism 24 includes a drainage pipe support member 24a, a drainage pipe storage member 24b, a drainage pipe 24c, a suction hose 24d, and a piston 24e.

The drain pipe support member 24 a is formed in a cylindrical shape and is fixed to the inner peripheral surface of the second slide base 17. A drain pipe storage member 24b is supported inside the drain pipe support member 24a. The drain pipe storage member 24b is
The first slide base 16 is formed in a cylindrical shape, and the end on the first slide base 16 side is enlarged in diameter. Also, the drain pipe storage member 24b
The piston housing hole 24f is formed in the second housing base 3 side.
Are formed. Further, a drain pipe 24c is provided at the center of the drain pipe housing member 24b. This drain pipe 2
4c is supported on the inner peripheral surface of the drain pipe housing member 24b so as to be slidable in the axial direction of the drain pipe housing member 24b. A bendable suction hose 24d is fixed to one end of the drain pipe 24c. The suction hose 24d is connected to the first and second hoses.
The molds 13, 14 are bent downward toward the accommodating recesses 13 a, 14 a, and a suction port 24 g for sucking the accumulated cooling water W is formed at the tip thereof. Drain pipe 24
A piston 24e is fixed to the other end of c. The piston 24e is slidably supported in the piston housing hole 24f of the drain pipe housing member 24b.

When the piston 24e is driven, the suction port 24g of the suction hose 24d is located at two positions, a suction position shown in FIG. 1 and a standby position shown in FIG. Further, the cooling water W is sucked from the suction port 24g and passes through the suction hose 24d and the drain pipe 24c to form the tire T.
It is designed to be discharged outside.

Now, as shown in FIG. 2, the first and second frame cylinders 10 and 12 are operated to separate the first and second frames 9 and 11 and the first and second slide bases 16 and
17 is set to the standby position, and the drive cylinders 18h of the first and second bead gripping mechanisms 18 and 22 are operated to guide the respective sliding portions 18k to the standby position. The water distribution mechanism 20
And the lock housing 21 to the standby position,
Move the suction hose 24d to the standby position. At this time, a tire T of a predetermined size is held between the first and second molds 13 and 14 by, for example, a loader L. Then, as shown in FIG. 3, the first and second slide base cylinders 19 and 23 are operated to move the first and second slide bases 16 and 17 to the working position. Then, the drive cylinder 18h is operated to move the sliding portion 18k to the grip position. At this time, the bead gripping surface 18m of the rotary plate 18l grips the bead portion B of the tire T in cooperation with the bead receiving surface 18c.
After the bead portion B is gripped, the water distribution mechanism 20 is set to the water distribution position, and the suction hose 24d is set to the suction position. Subsequently, the first and second frame cylinders 10 and 12 are operated to
As shown in (1), the first and second molds 13, 14 are brought closer to each other to join the first and second joints 13g, 14g. At this time, the accommodation recesses 13a of the first and second molds 13 and 14
Both sidewall portions Sw of the tire T are provided on the center inner side surfaces 13b and 14b of the tire 14a, and both shoulder portions S and the outer circumferential inner surface 13d are provided on the center side inner side surfaces 13c and 14c.
The tread portion Td of the tire T contacts 14d.

After the lock fitting 15 is fitted to the first and second joints 13g and 14g, the cooling water W is discharged from the water distribution pipe 20c while the motor 20d is driven to rotate the water distribution pipe 20c. Then, the cooling water W accumulated inside the tire T is discharged out of the tire T by the suction hose 24d. Furthermore, the first and second water jackets 13
Cooling water is circulated through e and 14e to cool the sidewall portion Sw, the shoulder portion S, and the tread portion Td of the tire T.

According to the post cure inflator 1 of the first embodiment, the following features can be obtained. (1) In the first embodiment, the bead portion B of the tire T
First and second bead gripping mechanisms 18 and 22 each having a bead gripping surface 18m and a bead receiving surface 18c formed in the shape of FIG.
The bead portion B of the tire T is gripped by the
Both sidewall portions Sw and both shoulder portions S of the tire T
In a state where both tread portions Td are in contact with the first and second receiving recesses 13a and 14a of the first and second molds 13 and 14, the vulcanized tire T is supplied with cooling water W from the rotating water pipe 20c. On its inner surface. The cooling water W accumulated in the tire T is sucked from the suction hose 24d and
Drained outside.

Therefore, the inner peripheral surface of the tire T is cooled, and the change in the shape of the bead portion B of the tire T is regulated by the bead gripping surface 18m and the bead receiving surface 18c. The shoulder portion S and the tread portion Td are provided with the cooling water W discharged from the water distribution pipe 20c.
, The outer surface of the tire T is restricted from changing its shape by the first and second recessed portions 13a, 14a of the first and second molds 13, 14. . As a result, the bead portion B of the tire T is formed in a shape formed by the bead gripping surface 18m and the bead receiving surface 18c, and both the sidewall portions Sw, both the shoulder portions S, and the tread portion Td are the first and second tread portions. 2 mold 1
3 and 14 are formed in the shape of the first and second housing recesses 13a and 14a.

(2) In the first embodiment, the first and second molds 13 and 14 can be brought into contact with and separated from each other.
The tire T can be easily mounted between the first and second molds 13 and 14.

(3) In the first embodiment, the water pipe 2
The cooling water W is discharged toward the inner peripheral surface of the tire T while rotating 0c. Further, since the cooling water W accumulated on the lower inner peripheral surface of the tire T is drained to the outside of the tire T via the suction hose 24d, the inner peripheral surface of the tire T is uniformly cooled, and the water pressure is uniformly increased. As a result, the inner peripheral surface of the cooled tire T is formed uniformly without distortion.

(4) In the first embodiment, the first and second molds 13 and 14 are provided with the first and second water jackets 1 and 2, respectively.
3e and 14e are formed and are cooled by the cooling water circulating therein, so that both the sidewall portions Sw, both the shoulder portions S and the tread portion Td are cooled uniformly and efficiently.

(Second Embodiment) FIG. 5 shows a second embodiment in which the present invention is embodied in a post-cure inflator.
It will be described according to. Note that the post cure inflator of the second embodiment is the same as the first and second molds 1 of the first embodiment.
3 and 14 are made rotatable, and the water pipe 20c is made unrotatable accordingly. Therefore, detailed description of the same parts will be omitted.

As shown in FIG. 5, a first slide base 16 is provided in the first slide base support 4. The first slide base 16 is formed in a substantially cylindrical shape,
The inside is a through hole. 1st slide base 1
A water distribution mechanism 20 is provided in 6. Water distribution mechanism 20
Has a water pipe sliding member 20b and a water pipe 20c. The water pipe sliding member 20b is formed in a cylindrical shape, the diameter of the end on the second slide base 17 side is enlarged, and the outer peripheral surface thereof is supported so as to be slidable in the axial direction of the first slide base 16. . A lock housing 21 is fixed to the outer peripheral surface of the enlarged diameter portion of the water pipe sliding member 20b.
A water pipe 20c is embedded in the center of the water pipe sliding member 20b. The water pipe 20c protrudes axially from the water pipe sliding member 20b, and has one end bent toward a water discharge hole 21a formed in the lock housing 21. Further, cooling water W is supplied to the water distribution pipe 20c from a water supply port (not shown). Furthermore,
The water pipe sliding member 20b slides inside the first slide base 16, and the water pipe 20c and the lock housing 21 can be accommodated in the first slide base 16.

The first slide base 16 has a first small diameter portion 16a and a first large diameter portion 16b. The first small diameter portion 16 a is supported in the first slide base support 4 so as to be movable in the axial direction of the first slide base support 4. A first large diameter portion 16b is formed to extend at a central portion in the axial direction of the first small diameter portion 16a. The first large diameter portion 16b has a larger diameter than the first small diameter portion 16a. A first slide base cylinder 19 is fixed to a lower portion of the first large diameter portion 16b.

A first rotary base 28 formed in an annular shape on the second housing base 3 side of the first large-diameter portion 16b is immovable in the axial direction with respect to the first slide base 16 and is rotatable. Are supported by a first radial bearing 27 and a second thrust bearing 29.

The first bead gripping mechanism 18 is fixed to the outer peripheral surface of the first rotation base 28. The first bead holding mechanism 18 includes a holding unit 18a and a holding driving unit 18b. The holding and fixing portion 18a is formed in an annular shape,
The gripping and fixing portion 18a is fixed to the outer peripheral surface of the rotation base 28,
A plurality of engagement projections 18n are formed on the outer peripheral surface of the first rotation base 28 so as to extend along the axial direction of the first rotation base 28, respectively.

The first die 13 is joined onto the first bead gripping mechanism 18. The first mold 13 has a first slide base insertion hole 13f formed at the center thereof. A plurality of first engagement grooves 13 are provided on the inner peripheral surface of the first slide base insertion hole 13f at positions opposed to the plurality of engagement protrusions 18n.
j is formed. Then, the first mold 13 fits the engaging projections 18n into the plurality of first engaging grooves 13j, and attaches the outer peripheral surface of the holding and fixing portion 18a to the inner peripheral surface of the first mold 13. They are joined and supported by the first bead gripping mechanism 18. Therefore, the first mold 13 is
Along with the bead gripping mechanism 18 and the first rotation base 28,
The first slide base 16 is rotatable.

On the side of the first mold 13 opposite to the first joint 13g, a first engagement portion 13h is formed so as to project concentrically with the center of the first mold 13. First engagement portion 13
The tip of h is bent toward the center of the first mold 13 to form a first annular groove 13i. The outer peripheral edge of the first mold support plate 9a is fitted into the first annular groove 13i with a gap. The first mold support plate 9a is a circular plate, and is supported by the first frame support 6 via the first reinforcing plate 9b. And the first frame cylinder 1
When 0 is operated, the first frame 9 moves to the first housing base 2 side. At this time, since the first mold supporting plate 9a is fitted in the first annular groove 13i of the first mold 13, the outer peripheral edge of the first mold supporting plate 9a is
The first mold 13 is moved toward the first housing base 2 by engaging with the end of the engaging portion 13h.

Further, a drive gear 25 is fixed to the outer peripheral surface of the first mold 13. The drive gear 25 is meshed with a gear fixed to an output shaft of a drive motor 26. In the present embodiment, the drive motor 26 is fixedly provided below the first reinforcing plate 9b. Therefore, the first mold 13 can rotate about the first slide base 16 as a rotation axis via the drive gear 25 as the drive motor 26 rotates.

On the other hand, a second slide base 17 is provided in the second slide base support 5. The second slide base 17 is formed in a substantially cylindrical shape, and the inside thereof is a through hole. The second slide base 17 has a second small diameter portion 17a and a second large diameter portion 17b. The second small diameter portion 17 a is supported in the second slide base support 5 so as to be movable in the axial direction of the second slide base support 5. A second large-diameter portion 17b is formed to extend in the axial center of the second small-diameter portion 17a. The second large diameter portion 17b has a larger diameter than the second small diameter portion 17a. A second slide base cylinder 23 is fixed to a lower portion of the second large diameter portion 17b.

An annular second rotating base 31 is provided on the outer peripheral surface of the second small diameter portion 17a on the first mold 13 side of the second large diameter portion 17b with a third radial bearing 30 and a fourth thrust bearing 32.
Rotatable with respect to the second slide base 17 via
And it is supported so that it cannot move in the axial direction.

The second bead gripping mechanism 22 is fixed to the outer peripheral surface of the second rotation base 31. The second bead gripping mechanism 22 includes a gripping fixing unit 18a and a gripping drive unit 18b. The gripping and fixing portion 18a is formed in an annular shape and is fixed to the outer peripheral surface of the second rotating base 31. A plurality of engaging projections 18n are formed on the outer peripheral surface of the gripping and fixing portion 18a in the axial direction of the second rotating base 31, respectively. It is formed extending along.

The second bead gripping mechanism 22 has a second
The mold 14 is joined. A second slide base insertion hole 14 f is formed in the center of the second mold 14. A plurality of second engagement grooves 14 are provided on the inner peripheral surface of the second slide base insertion hole 14f at positions opposed to the plurality of engagement protrusions 18n.
j is formed. The second mold 14 fits the engaging protrusions 18n into the plurality of second engaging grooves 14j, and the outer peripheral surface of the holding / fixing portion 18a is fitted to the inner peripheral surface of the second mold 14. They are joined and supported by the second bead gripping mechanism 22. Therefore, the second mold 14 is
Along with the bead gripping mechanism 22 and the second rotation base 31,
The second slide base 17 is rotatable.

On the side of the second mold 14 opposite to the second joint 14g, a second engaging portion 14h is formed so as to project concentrically with the center of the second mold 14. Second engagement portion 14h
Is bent toward the center of the second mold 14 to form a second annular groove 14i. The outer peripheral edge of the second mold support plate 11a is fitted into the second annular groove 14i with a gap. The second mold support plate 11a is a disc, and is supported by the second frame support 7 via the second reinforcing plate 11b. And
When the second frame cylinder 12 is operated, the second frame 11 moves to the second housing base 3 side. At this time, since the second mold support plate 11a is fitted into the second annular groove 14i of the second mold 14, the second mold support plate 11a
Is engaged with the end of the second engaging portion 14h of the second mold 14 to move the second mold 14 to the second housing base 3 side.

The first mold 13 and the second mold 14 are the first mold 13 and the second mold 14.
The second joints 13g and 14g are fixed by fitting with the lock fittings 15. Therefore, the second mold 14 is
When the first mold 13 rotates about the first slide base 16 as a rotation axis with the rotation of the drive motor 26, the first mold 13 rotates in synchronization with the rotation.

Now, the first and second joints 13g and 14g are brought into contact with each other, and the inner side surfaces 13b and 14b of the first and second housing recesses 13a and 14a on the central side 13b and 14b are provided on both sidewalls S of the tire T.
w, both shoulder portions S of the tire T and outer peripheral inner side surfaces 13 of the first and second receiving concave portions 13a and 14a are provided on the inner side surfaces 13c and 14c of the first and second receiving concave portions 13a and 14a.
The tread portion Td of the tire T is brought into contact with d and 14d.
Further, the bead gripping surfaces 18m of the first and second bead gripping mechanisms 18, 22 and the bead receiving surface 18c cooperate to grip each bead portion B of the tire T. And lock fitting 1
5 is fitted to the first joint 13g and the second joint 14g, and when the drive motor 26 rotates, the first and second molds 1 are rotated.
The first and second slide bases 3 and 14 rotate via the drive gear 25 with the first and second slide bases 16 and 17 as rotation axes. At this time, the cooling water W is discharged from the water distribution pipe 20c toward the inner peripheral surface of the tire T, and the cooling water W accumulated inside the tire T is discharged out of the tire T by the suction hose 24d. Further, the cooling water is circulated through the first and second water jackets 13e and 14e, so that the sidewall portions Sw and
The shoulder portion S and the tread portion Td are cooled.

Therefore, according to the second embodiment, the following features can be obtained in addition to the features described in (1), (2), and (4) in the first embodiment. .
(1) In the first embodiment, the first and second molds 13 and 14
Rotates, the tire T mounted in the accommodation recesses 13a, 14a of the first and second molds 13, 14 is directed radially outward of the first and second molds 13, 14 by centrifugal force. Receive power. Further, the water pressure is uniformly applied to the inner peripheral surface of the rotating tire T by the cooling water W discharged from the water distribution pipe 20c.

Therefore, both sidewall portions S of the tire T
w, both shoulders S and tread Td are first and second
Since the cooling is performed while being uniformly pressed by the centrifugal force and the water pressure toward the housing recesses 13a and 14a, the first and second housing recesses 13a and 14a allow the both sidewall portions Sw and both shoulder portions S and T of the tire T to be cooled. The shape of the tread portion Td is regulated. As a result, both sidewall portions Sw, both shoulder portions S, and tread portion Td of the tire T are
The first and second housing recesses 13a and 14a are formed without distortion.

(Third Embodiment) Next, a third embodiment of the present invention will be described with reference to FIGS.

The right and left shoulders Te, Te of the tire T are prevented from contacting the inner peripheral surfaces of the first and second housing recesses 13a, 14a of the first and second molds 13, 14. Annular first and second contact blocking grooves 13k, 1
4k are formed.

Accordingly, the first and second receiving recesses 13a, 14
a, right and left shoulder portions Te, T of the tire T accommodated in a
Since e corresponds to the first and second contact blocking grooves 13k and 14k, the standard dimensions of the first and second housing recesses 13a and 14a and the shapes and intervals of the right and left shoulder portions Te and Te of the tire T are slightly different. The tire T can be properly housed in the first and second housing recesses 13a and 14a. As a result, the tire T is not cooled while being deformed,
The shape of the tire can slightly increase both shoulder portions, that is, increase the tread width to increase the contact area.

The above embodiments may be modified as follows. In the second embodiment, the drive motor 26 is connected to the first reinforcing plate 9b
However, this may be fixed anywhere, for example, the first frame support portion 6 as long as it does not rotate.

In the second embodiment, the driving gear 25 is
Although fixed on the outer peripheral surface of the mold 13, it may be fixed on the outer peripheral surface of the second mold 14. In such a configuration, the drive motor 26 is fixed to the lower portion of the second reinforcing plate 11b, and the gear of the output shaft meshes with the drive gear 25.

In each of the above embodiments, the first and second molds are formed with the first and second water jackets 13e and 14e. However, these may not be formed. Also in this case, the same features as those described in the above embodiments can be obtained.

Next, technical ideas other than those described in the claims which can be understood from the above embodiment and other examples will be described below together with their effects. (1) The post cure inflator according to claim 1, wherein first and second water jackets are formed in the first and second molds along the first and second housing recesses. And post cure inflator.

Therefore, according to the post-cure inflator described in (1), the outer surface of the tire can be cooled uniformly and efficiently.

[0077]

As described in detail above, according to the first and fifth aspects of the present invention, the bead portion of the tire is formed uniformly by the bead gripping mechanism, and the outer surface of the tire is formed of the first and second tires. (2) The shape of the recess is uniformly formed without distortion.

According to the second aspect of the present invention, the tire can be easily mounted in the first and second molds. According to the third aspect of the present invention, the inner peripheral surface of the tire is cooled uniformly, and the cooled inner peripheral surface is formed uniformly without distortion.

According to the fourth aspect of the present invention, since the left and right shoulder portions of the tire accommodated in the first and second accommodation recesses correspond to the first and second contact preventing grooves, both right and left shoulders of the tire are provided. The tire can be properly housed in the first and second housing recesses even if the shapes and intervals of the portions are slightly different. As a result, the tire T is not cooled while being deformed, and the shape of the tire is such that both shoulder portions are slightly swollen, that is, the tread width is increased, and the contact area can be increased.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view of a post cure inflator according to a first embodiment.

FIG. 2 is a longitudinal sectional view of the post-cure inflator in a state where the first and second molds are similarly divided before gripping a tire.

FIG. 3 is a longitudinal sectional view of the post-cure inflator in a state where the first and second molds are divided when the tire is similarly gripped.

FIG. 4 is a longitudinal sectional view of the bead gripping mechanism.

FIG. 5 is a longitudinal sectional view of a post cure inflator according to a second embodiment.

FIG. 6 is a longitudinal sectional view of a post cure inflator according to a third embodiment.

FIG. 7 is an enlarged sectional view of a main part of a third embodiment.

[Explanation of symbols]

B: bead portion, T: tire, W: cooling water, 1: post cure inflator, 13: first mold, 13a: first housing recess, 13k: first contact blocking groove, 14: second mold, 14
a: second accommodation recess, 14k: second contact blocking groove, 20: water distribution mechanism, 20c: water distribution pipe, 23: drainage mechanism.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (Reference) B29L 30:00

Claims (5)

[Claims] 1. A post cure inflator for cooling a tire after vulcanization, wherein a bead gripping mechanism for gripping a bead of the tire, and first and second storages for cooperating with each other to store an outer surface of the tire. A first mold and a second mold which are provided with concave portions and can be separated from each other; and a cooling water is discharged to an inner surface of the tire held by the bead gripping mechanism, the first mold and the second mold. A post cure inflator comprising: a water distribution mechanism; and a drainage mechanism for discharging cooling water accumulated in the tire. 2. The post cure inflator according to claim 1, wherein the water distribution mechanism rotates toward an inner surface of the tire held by the bead portion gripping mechanism, a first mold and a second mold. A post-cure inflator comprising a water pipe for discharging cooling water while cooling. 3. The post cure inflator according to claim 1, wherein the bead portion gripping mechanism, the first mold and the second mold rotate while holding the tire. 4. The post cure inflator according to claim 1, wherein left and right shoulder portions of the tire contact inner peripheral surfaces of the first and second receiving recesses of the first mold and the second mold. A post-cure inflator, comprising first and second contact-blocking grooves for preventing the occurrence of such a situation. 5. A method for cooling a tire after vulcanization, wherein a bead portion of the tire is gripped by a bead portion gripping mechanism, and a housing recess formed in a first mold and a second mold which can be separated from and separated from each other. With the outer surface of the tire housed and held therein, the inner surface of the tire is cooled by a water distribution mechanism, and the cooling water accumulated in the tire is discharged out of the tire using a drainage mechanism and vulcanized. How to cool tires.