KR100339171B1 - Tire vulcanizing system and tire vulcanizing method - Google Patents

Abstract

The tire vulcanization plant of the present invention includes a plurality of rows of tire vulcanization stations for receiving a plurality of sets of movable tire mold assemblies for vulcanizing the tires; A mold opening / closing station which is disposed in a tire vulcanization station that receives the tire mold assembly to open and close the tire mold assembly, thereby removing the vulcanized tire and inserting the green tire; And a first mold conveying device and a second mold conveying device disposed between the mold opening and closing station and the tire vulcanizing station for conveying the tire mold assembly.

Description

Tire Vulcanizing Equipment and Tire Vulcanizing Method {TIRE VULCANIZING SYSTEM AND TIRE VULCANIZING METHOD}

The present invention relates to a tire vulcanization plant and a tire vulcanizing method for performing tire vulcanization, mold replacement, bladder exchange, mold preheating, and the like.

In the conventional fully automatic tire vulcanizing press, the working time for loading, forming and unloading of the green tire is heated / pressurized while the tire mold assembly is closed. It is much shorter than the time to vulcanize by introducing the medium into the tire. Therefore, the tire mold opening and closing device and the tire loading and unloading device for opening / closing the tire mold assembly for loading / unloading the tire have low work efficiency.

In order to solve this problem, the applicant of the present invention has proposed a tire vulcanization facility disclosed in Japanese Patent Laid-Open No. 95-80846.

As shown in Figs. 16 and 17, these tire vulcanization facilities are vulcanization stations 501a and 501b, mold opening and closing stations 502a and 502b, tire mold conveyers 503a and 503b, and tire mold conveyer rails 504. ), Mold beds 505a, 505b ...), unloader 507a, loader 508a, vulcanized tire conveying conveyor 509a, live tire rack 510a and mold changing station 511 It is for replacing a tread mold, a side wall mold, etc. in a tire mold assembly Ma with the specification change of the tire to be vulcanized, and also replacing a bladder which is a consumable.

In such a tire vulcanization facility, the vulcanized tire mold assembly Mc is transferred from the vulcanization station 501a (or 501b) in which the plurality of tire mold assemblies Mc vulcanized are arranged to the tire mold conveyer 503a. It is accommodated and conveyed to the mold opening / closing station 502a (or 502b).

After the tire mold assembly Mc conveyed to the mold opening and closing station 502a is connected to the tire mold opening and closing device 506a (or 506b), the tire mold assembly Mc is opened by the tire mold opening and closing device 506a, The vulcanized tire is unloaded by the unloader 507a attached to the tire mold opening and closing device 506a. The green tire is then loaded using the loader 508a attached to the tire mold opening and closing device 506a. After the loaded tire is shaped during the tire mold closing step and the tire mold assembly Mc is closed, the heating / pressing medium is introduced into the tire and sealed, whereby the tire vulcanizing step is started.

Subsequently, the tire mold assembly Mc having started to be vulcanized is separated from the tire mold opening and closing device 506a, placed on the tire mold conveying machine 503a and conveyed, and returned to the vulcanization stations 501a, 501b ... .

In the above-described conventional tire vulcanization plant, a release device (control valve and conduit) for discharging the heating / pressing medium in the bladder is provided in each vulcanization station in order to shorten the working time at the mold opening and closing station. Therefore, such a facility is undesirable from an economic point of view. In particular, such a facility has disadvantages in terms of economy when the facility, which is provided with control valves and conduits for vulcanization control separately, is used in a facility for mass production of tires having the same vulcanization time.

In addition, when the conventional tire vulcanization equipment is used in production equipment for small tires such as tires for passenger cars whose vulcanization time is very short, such as 8 seconds to 12 seconds, such equipment requires the following matters.

In such a facility, the time for the mold conveying device to accept the tire mold assembly at the vulcanization station, the time for completing the work at the mold opening and closing station, and the time for the closed tire mold assembly to be transported back to the vulcanization station should be as short as possible. . The reason is that since the same mold conveying device is used in both directions, the time interval until the next mold conveying is increased when conveying the mold assembly to the mold conveying device, thereby increasing the number of molds constituting the tire vulcanization plant. This is because there is a problem that the economic efficiency is lowered.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described situation, and an object thereof is to be commonly used for a loaded mold assembly by disposing the discharging device at a position just before the mold loading side of the mold opening / closing station without being disposed at each vulcanization station. To provide a more economical tire device installation and tire vulcanization method that can be.

In addition, another object of the present invention is that the vulcanization control valve or the like is not disposed at each vulcanization station, and the heating / pressing medium supply station is disposed on the mold unloading side of the mold opening and closing station, whereby the heating / pressing medium is removed from the mold opening and closing station. It is to provide a more economical tire vulcanization plant and a tire vulcanization method which are commonly used to feed into the bladder of the unloaded mold assembly and also to feed the heating medium into the heating chamber outside the mold.

In addition, another object of the present invention is that the first conveyer conveys the tire mold assembly from the mold opening and closing apparatus to the vulcanization station, and the second conveyer conveys the tire mold assembly from the vulcanization station to the mold opening and closing apparatus, thereby shortening the conveying time. It is to provide a more economic tire vulcanization equipment in which the number of tire molds constituting the equipment is increased.

For example, if the vulcanization time is 10 minutes, the conveyer reciprocating time is 40 seconds, and the processing time at the mold opening / closing station is 80 seconds, the prior art disclosed in Japanese Patent Laid-Open No. 95-80846. In the case of a system,

The number of molds that can be processed by one mold opening and closing station is N1 = 10x60 / (40 + 80) = 5, i.e., five molds.

On the other hand, in the case of the installation according to the invention, the number of molds that can be processed by one mold opening and closing station is N2 = 10 x 60/80 = 7.5, that is, seven molds, and the first and second molds. The number of molds that can be processed by the conveyer is N3 = 10 x 60/40 = 15, i.e. 15 molds.

For the entire installation, the number of molds that can be processed is up to seven molds. In the system according to the present invention, the number of molds can be increased in comparison with the conventional equipment disclosed in Japanese Patent Laid-Open No. 95-80846.

In order to further increase the number of molds, the processing capacity of the mold opening and closing station should be increased as is apparent from the calculation example. As one solution to this problem, two switching stations need to be arranged. However, this solution is not economically desirable.

Accordingly, the applicant of the present invention proposes a vulcanization facility in which a part of the working process in the mold opening and closing station is performed outside the mold opening and closing station, thereby increasing the processing capacity of the mold opening and closing station.

In particular, the processing time of 80 seconds at the mold opening and closing station is a) time for opening and closing the mold (about 30 seconds), b) working time for the vulcanized tire removing device (about 10 seconds), c) bladder from the vulcanized tire. Bladder working time (approximately 10 seconds) for peeling off, d) operating time (approximately 10 seconds) of the live tire feeder, e) time for inserting the bladder into the live tire and shaping it (approximately 20 seconds) Notice the fact that it is composed.

The processing capacity of the mold opening and closing station is increased because the vulcanized tire is removed from the mold with the bladder assembly and removed about 30 seconds (times c) and e) by being moved out of the mold opening and closing station. Outside the mold opening and closing station, the bladder is peeled off from the vulcanized tire. The bladder is inserted into the raw tire and shaped into other bladder assemblies and tires, which are fed to the mold immediately after the vulcanized tire and bladder assembly are separated from the mold.

According to this method, a trial calculation can be performed as follows by setting the vulcanization time to 10 minutes in the same manner as the above-described calculation example.

The number of molds [N = 10 × 60 / (80-30) = 12] that can be processed by one mold opening and closing station is 12 molds.

The number of molds [N = 10 × 60/40 = 15] that can be processed by the first and second mold conveyers is 15 molds.

In the entire installation, the number of molds that can be processed is up to 12 molds. Thus, a more economic tire vulcanization plant and a tire vulcanization method can be provided.

In order to solve the above-mentioned problems of the prior art, the tire vulcanization facility according to the present invention is provided with a plurality of rows of tire vulcanizing stations for vulcanizing a tire by receiving a plurality of sets of movable tire mold assemblies, and a tire mold assembly disposed at the tire vulcanizing station. A first mold conveying apparatus and a second mold conveying apparatus disposed between the mold opening and closing station and the tire vulcanizing station to convey the tire mold assembly by opening and closing the tire mold to open and close the tire mold to insert the raw tire. It includes a mold conveying device.

In addition, the tire vulcanization plant according to the present invention opens and closes a tire mold because a plurality of rows of tire vulcanization stations receive a plurality of sets of movable tire mold assemblies to vulcanize the tires, and are disposed at the tire vulcanization stations to accommodate the tire mold assemblies. And a mold opening and closing station through which the vulcanized tire is removed and the raw tire is inserted, and a first mold conveying device and a second mold conveying device disposed between the mold opening and closing station and the tire vulcanizing station to convey the tire mold assembly. A discharge station disposed on the mold loading side of the station and discharging the heating / pressing medium in the bladder assembly of the tire mold assembly conveyed from the tire vulcanization station; Tying medium Further it includes a supply station for feeding into the heating chamber and the bladder assembly of the mold assembly.

SUMMARY OF THE INVENTION The present invention provides a tire vulcanization facility in which a movable tire mold assembly is moved onto a mold opening and closing station and the tire mold is opened and closed to remove vulcanized tires and insert live tires for vulcanization of the tires. An outer shaft to which the fixing member for fixing one end of the further is fixed, a fixing member for fixing the other end of the bladder to which the inner shaft is inserted to be axially slid relative to the outer shaft, and a retaining claw A retaining claw is formed at one end of the outer shaft, and a claw flange rotatably coupled to the inner shaft, the claw flange having a claw engaging or passing through the retaining claw of the outer shaft, depending on the rotatable angle. A blade comprising rotation means for rotating from one end of the Has a further assembly, and the retaining claw of the outer shaft being integrated by bonding to the flange of the claws claw, the vulcanized tire or green tire and the bladder assembly is again removed from it for insertion into a tire mold.

The present invention provides a tire vulcanization facility in which a movable tire assembly is moved onto a mold opening and closing station, the tire mold is opened and closed to remove vulcanized tires and insert live tires for vulcanization of the tire. The tire and bladder assembly includes a separation station containing an assembly for integrating and separating the vulcanized tire and bladder assembly from each other, a storage station for storing a plurality of bladder assemblies from which the vulcanized tire is separated, and a bladder delivered from the storage station. And a vulcanized tire removing device and a raw tire supply device, including a shaping station for receiving the assembly, inserting the bladder into the live tire, and integrating the live tire and the bladder assembly from each other.

The present invention also provides a tire vulcanization method in which a movable tire mold assembly is moved onto a mold opening and closing station, and the tire mold is opened and closed to remove vulcanized tires and insert fresh tire for vulcanization of the tires. The heating / pressurizing medium in the tire in the tire mold assembly is discharged at a standby position just before the tire mold assembly is loaded into the mold opening and closing device at the mold opening and closing station, and the tire mold is opened to remove the vulcanized tire and to insert fresh tires. And the heating / pressing medium is fed into the tire in the tire mold assembly, and the heating medium is fed from the mold opening and closing device to the heating chamber of the tire mold assembly at a standby position on the unloading side of the tire mold assembly to vulcanize the tire. It features.

The present invention also relates to a tire vulcanization method in which a movable tire mold assembly is moved onto a mold opening and closing station, and the tire mold is opened and closed to remove vulcanized tires and insert raw tires for vulcanization of the tire, wherein the vulcanized tire is a tire. When removed by opening the mold, the vulcanized tire and bladder assembly is removed into the unit, and the vulcanized tire peels off the bladder assembly, which is subsequently inserted into the tire mold with the integrated tire and bladder assembly integrated into the tire. It is characterized by vulcanizing.

As described above, the tire vulcanization plant according to the present invention includes a plurality of rows of tire vulcanization stations for vulcanizing tires by accommodating a plurality of sets of movable tire mold assemblies, and a tire vulcanization station disposed in the tire vulcanization station to accommodate tire mold assemblies. And a mold opening and closing station for opening and closing, and a first mold conveying device and a second mold conveying device arranged between the mold opening and closing station and the tire vulcanization station to convey the tire mold assembly. Therefore, the conveying operation of the tire mold assembly between the vulcanizing station and the mold opening / closing station is simultaneously performed separately, so that the productivity of the entire installation can be improved by reducing the conveying time and by increasing the number of tire molds constituting the vulcanizing installation.

In addition, the tire vulcanization plant according to the present invention opens and closes a tire mold because a plurality of rows of tire vulcanization stations receive a plurality of sets of movable tire mold assemblies to vulcanize the tires, and are disposed at the tire vulcanization stations to accommodate the tire mold assemblies. And a mold opening and closing station through which the vulcanized tire is removed and the raw tire is inserted, and a first mold conveying device and a second mold conveying device disposed between the mold opening and closing station and the tire vulcanizing station to convey the tire mold assembly. A discharge station disposed on the mold loading side of the station for discharging the heating / pressing medium into the bladder assembly of the tire mold assembly conveyed from the tire vulcanization station, and on the mold unloading side of the mold opening / closing station Heating medium And a supply station for feeding into the bladder assembly of the chamber and the tire mold assembly. Thus, the same effect as the above-described invention can be achieved, and the heating / pressing medium discharge and supply station can be commonly used for the loaded tire mold assembly.

SUMMARY OF THE INVENTION The present invention provides a tire vulcanization facility in which a movable tire mold assembly is moved onto a mold opening and closing station and the tire mold is opened and closed to remove vulcanized tires and insert live tires for vulcanization of the tires. The bladder assembly includes an outer shaft to which the fixing member for fixing one end of the further is fixed, and the fixing member for fixing the other end of the bladder is fixed, which is inserted to be axially slidable with respect to the outer shaft. A claw flange is rotatably coupled to the inner shaft, the claw flange having an inner shaft and a retaining claw formed at one end of the outer shaft and having a claw engaged with or through the retaining claw of the outer shaft according to the rotatable angle. Rotate from one end of the inner shaft, It characterized in that the holding vulcanized tire or green tire and the bladder assembly by the engagement of the claw of the outer shaft is integrated in order to remove from it again in order to insert into the tire mold with the claw fingers. Therefore, the removal of the vulcanized tire and the insertion of the raw tire can be performed quickly and reliably.

The present invention provides a tire vulcanization facility in which a movable tire assembly is moved onto a mold opening and closing station, and the tire mold is opened and closed to remove vulcanized tires and insert fresh tires for vulcanization of the tires. The tire and bladder assembly includes a separation station containing an assembly for integrating and separating the vulcanized tire and bladder assembly from each other, a storage station for storing a plurality of bladder assemblies from which the vulcanized tire is separated, and a bladder delivered from the storage station. And a vulcanized tire removal and live tire supply device including an orthopedic station for receiving the assembly, inserting the bladder into the live tire, and integrating the live tire and the bladder assembly from each other. Therefore, the vulcanized tire removing operation and the raw tire supply operation can be effectively performed.

The present invention also provides a tire vulcanization method in which a movable tire mold assembly is moved onto a mold opening and closing station, and the tire mold is opened and closed to remove the vulcanized tire and to insert fresh tire for vulcanization of the tire. The heating / pressurizing medium in the tire in the tire mold assembly is discharged at a standby position just before the tire mold assembly is loaded into the mold opening and closing device at the mold opening and closing station, and the tire mold is opened to remove the vulcanized tire and to insert fresh tires. And the heating / pressing medium is fed into the tire in the tire mold assembly, and the heating medium is fed from the mold opening and closing device to the heating chamber of the tire mold assembly at a standby position on the unloading side of the tire mold assembly to vulcanize the tire. It features. Thus, the vulcanized tire can be implemented more quickly and economically.

The present invention also relates to a tire vulcanization method in which a movable tire mold assembly is moved onto a mold opening and closing station, and the tire mold is opened and closed to remove vulcanized tires and insert raw tires for vulcanization of the tire, wherein the vulcanized tire is a tire. When removed by opening the mold, the vulcanized tire and bladder assembly is removed into the unit, and the vulcanized tire peels off the bladder assembly, which is subsequently inserted into the tire mold with the integrated tire and bladder assembly integrated into the tire. It is characterized by vulcanizing. Thus, tire vulcanization can be carried out more quickly and economically.

1 is a plan view of a tire vulcanization plant according to a first embodiment of the present invention,

2 is a view in the direction of the arrow along the line I-I of FIG.

3 is a view in the direction of the arrow along the line II-II of FIG.

4 is a plan view showing a tire vulcanization method according to a first embodiment of the present invention, and a tire vulcanization plant according to a second embodiment of the present invention for performing the same method;

5 is a view in the direction of the arrow along the line III-III of FIG.

6 is a view in the direction of the arrow along the IV-IV line of FIG.

7 is a plan view showing a tire vulcanization method according to another embodiment of the present invention, and a part of the tire vulcanization plant according to the third embodiment of the present invention for performing the same method;

8 is a front view showing a part of the tire vulcanizing equipment shown in FIG.

9 is a cross-sectional view showing an example of a bladder assembly used when performing the tire vulcanization method according to another embodiment of the present invention, the bladder assembly is a view showing a state embedded in the mold assembly,

10 is a cross-sectional view showing in detail the structure of the bladder assembly shown in FIG. 9, the bladder is in an expanded state,

11 is a view showing the structure of the bladder assembly, Figure 11a is an enlarged cross-sectional view taken along the line I-I of Figure 10, Figure 11b is a partial cross-sectional view of FIG.

12 is a cross-sectional view taken along line II-II of FIG. 11A;

13 is a cross-sectional view taken along the line III-III of FIG. 10 in the direction of the arrow;

14 is a cross-sectional view taken along line IV-IV of FIG. 10;

15 is a cross-sectional view showing a separation station and a storage station;

16 is a plan view of a conventional tire vulcanization plant,

17 is a front view of a conventional tire vulcanization plant.

Explanation of symbols for main parts of the drawings

1 bladder assembly 2 outer shaft

3: ring 5: flange

6: press plate 9: inner shaft

T: Vulcanized Tire GT: Raw Tire

Embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a plan view of a tire vulcanization plant according to a first embodiment of the present invention, Figure 2 is a view in the direction of the arrow along the line I-I of Figure 1, Figure 3 is along the line II-II of FIG. The figure seen in the direction of the arrow.

As shown in Fig. 1, the tire vulcanization plant according to the first embodiment accommodates a plurality of sets of movable tire mold assemblies M (M11 to M23) to vulcanize tires in a plurality of rows of tire vulcanizing stations C11 to C23. ), A mold opening / closing station (OP1) arranged in the vulcanizing stations (C11 to C23) to receive the tire mold assembly (M), remove the vulcanized tire by inserting and closing the tire mold, and insert a raw tire; 1st tire mold conveying apparatus T1 and 2nd tire mold conveying apparatus T2 arrange | positioned between OP1) and vulcanization stations C11-C23, and convey tire mold assembly M are included.

The vulcanization stations C11, C12, C13 in the first row are arranged so that their centers are in a straight line, and the vulcanization stations C21, C22, C23 in the second row are arranged in parallel with the first row. In the embodiment shown in FIG. 1 a total of six vulcanization stations are arranged, but the number of vulcanization stations may be increased, for example by adding a third row.

Each vulcanization station C11 to C23 has a plurality of sets of movement guide rollers Cf provided on the base (not shown) of the vulcanization station. The tire mold assemblies M11, M12, M13, M21, M22, M23 are arranged to be moved in the movement direction (for example, the direction to the vulcanization stations C11 to C21) by this movement guide roller Cf. do.

Also, on the base of each vulcanization station C11 to C23, a positioning device (not shown) for positioning the moved mold assembly M is provided. By using this positioning device, the tire mold assembly M is fixed at or released from the predetermined position. In addition, on the bases of the respective vulcanization stations C11 to C23, an internal pressure supply device and an external pressure supply device (if necessary, filed by the inventor of the present invention, if necessary). -80846 is provided.

On one end side of the row of vulcanization stations C11 to C23, a mold opening and closing device OP is provided.

As shown in FIGS. 1 and 3, the mold opening and closing apparatus OP is vertically moved on the side of the frame OPa and the frame OPa assembled on the base OPj and the mold opening and closing apparatus (mold opening and closing station). Known loader (OPg) for loading live tires that can swing between the center position and the standby position of OP1, and similar to the loader (OPg) and on the opposite side of the loader (OPg) Known unloader OPh for unloading the vulcanized tire disposed on the side of the frame OPa, and a frame OPa different from the side on which the loader OPg and the unloader OPh are mounted. The elevating guide rail OPe provided on the side of the elbow, the guide bracket OPd slidable on the elevating guide rail OPe, the upper movable plate OPd fixed to the guide bracket OPd, and the upward movement. The known split mold opening and closing actuating device and one end provided in the center of the possible plate OPc It includes a plurality of sets of lifting cylinders OPb fixed to the frame OPa and fixed to the upper movable plate OPc at the other end thereof.

On the upper side of the base OPj, a guide roller OPf and a positioning device (not shown) for positioning the moved tire mold assembly M are provided, and the guide roller and the positioning device include a vulcanization station ( Similar to those in C11 to C23).

In addition, at the center of the base OPj, that is, at the mold opening and closing station OP1, an operating device (not shown) and a heating / pressing medium for a bladder assembly (not shown) coupled in the tire mold assembly M are shown. An internal pressure supply device (not shown) for supplying the to the bladder assembly is provided.

For the bladder assembly, the operating device for the bladder assembly, and the internal pressure supply device (not shown in the drawing), which are not shown in the drawings, see Japanese Patent Laid-Open No. 95-80846 filed by the inventor of the present invention. .

On the other end side (opposite side of the mold opening and closing apparatus OP) of the vulcanization stations C11 to C23, the mold exchange device MC and the preheating device PH are provided.

The mold changing device MC has a structure similar to the mold opening and closing device OP, but it has a loader OPg for loading live tires, an unloader OPh for unloading vulcanized tires, and a mold opening and closing device OPi. ) Is different from the mold opening and closing apparatus OP in that it is not provided. That is, as shown in Figure 2, the mold exchange device is the frame (MCa), the lifting cylinder (MCb), the upper movable plate (MCc), the guide bracket (MCd), the lifting guide rail (MCe), the moving guide roller ( MCf) and the like.

The mold preheating device PH, like the vulcanization stations C11 to C23, comprises a base, a movement guide roller, an external pressure supply device and a positioning device.

On each side surface of the vulcanization stations C11 to C23, the mold opening and closing apparatus OP, the mold exchange apparatus MC, the mold preheating apparatus PH, the first tire mold conveying apparatus T1 and the second tire mold conveying Device T2 is provided.

The 1st tire metal mold | die conveying apparatus T1 (T1a, T1b, etc.) is the stopping position T10 in the front of each mold opening and closing apparatus OP, and the stopping position (in front of the vulcanization stations C11, C12, C13) ( It can move between T11, T12, T13 and the stop position T14 at the front of the mold exchange apparatus MC, and can stop if necessary.

In addition, the 2nd tire metal mold | die conveying apparatus T2 (T2a, T2b, etc.) stops at the front position of the stop position T20 and the vulcanization stations C21, C22, C23 in the front of each metal mold | die opening and closing apparatus OP. It can be moved between the positions T21, T22, T23 and the stop position T24 at the front of the mold preheater PH and can be stopped if necessary.

The 1st tire metal mold | die conveyance apparatus T1 and the 2nd tire metal mold | die conveyance apparatus T2 have the same structure. Therefore, only the first tire mold conveying apparatus T1 will be described.

The 1st tire metal mold | die conveyance apparatus T1 is equipped with the base T1d along the vulcanization stations C11, C12, and C13, and several sets of guide rollers Cf are provided on the base T1d. A first tire mold conveyer T1c is provided on this guide roller Cf, and the first tire conveyer can be moved along the vulcanization stations C11, C12, C13 by a known drive unit T1a. . A plurality of sets of guide rollers T1b are provided on the upper surface of the first tire mold conveyer T1c.

The upper level of the guide roller T1b is the same height as the upper level of the mold opening / closing device OP, the guide roller Cf of the vulcanization stations C11, C12, and C13, and the guide roller MCf of the mold changing device MC. It is set to have.

In addition, the 1st tire metal mold | die conveyer T1c is between the 1st tire metal mold | die conveyer T1c and the mold opening-and-closing device OP, or the 1st tire metal mold | die conveyer T1c and the vulcanization stations C11, C12, and C13. A mold conveying apparatus (not shown) used for conveying the mold assembly between them is provided. For a mold conveying device not shown, refer to Japanese Patent Laid-Open No. 96-192429 filed by the inventor of the present invention. Further, for details of the tire assembly, see Japanese Patent Laid-Open Nos. 96-47928 and 97-29746 filed by the inventor of the present invention.

Although the vulcanization stations C11 to C23 of the first embodiment shown in Fig. 1 are arranged in two rows, the present invention is not limited to this configuration, and the vulcanization stations C11 to C23 are divided into three rows, four rows, and the like. It may be arranged as. Further, the mold opening and closing apparatus OP may be disposed in the middle portion of the vulcanization station.

The operation of the tire vulcanization plant according to the first embodiment of the present invention will then be described.

1) When the completion of tire vulcanization in the tire mold assembly in the vulcanization station C21 is imminent, the second tire mold conveyer T2c moves to the stop position T21 in front of the vulcanization station C21 Stop there.

2) The internal pressure supply device and the external pressure supply device (both not shown) are separated at the vulcanization station C21. On the other hand, a mold receiving arm (not shown) on the table of the second tire mold conveying machine T2c extends toward the vulcanization station C21 and is connected to the lower portion of the tire mold assembly M21.

3) The mold receiving arm is pulled so that the tire mold assembly M21 slides on the guide roller Cf of the vulcanization station C21, and then on the guide roller T2b on the second tire mold conveyer T2c. It is conveyed to and slides on a guide roller. When the tire mold assembly M21 reaches a predetermined position, the assembly stops there.

4) When the tire mold assembly M21 is stopped, the lower portion of the tire mold assembly M21 is fixed to the second tire mold conveyer T2c. On the other hand, the 2nd tire metal mold | die conveyer T2c moves to the stopping position T20 in the front of the metal mold | die opening and closing apparatus OP, and stops there.

5) After the second tire mold conveyer T2c stops, the mold receiving arm of the second tire mold conveyer T2c extends toward the center of the mold opening and closing apparatus OP. The mold receiving arm is then separated from the lower portion of the tire mold assembly M21 and pulled toward the second tire mold conveying machine T2c.

Thereafter, the second tire mold conveying machine T2c then moves to the stop position T21, T22 or T23 at the front of the vulcanization station where the vulcanization is finished, and waits there.

6) The upper movable plate of the mold opening / closing device OP (OPa, OPb, etc.) is more than the tire mold assembly M21 so as not to prevent the tire mold assembly M21 from moving below the upper movable plate OPc. Wait at a rather high position.

7) When the tire mold assembly M21 is stopped, the lower portion of the tire mold assembly M21 is fixed. On the other hand, the upper movable plate OPc is lowered and connected to the upper portion of the tire mold assembly M21.

8) Then, the upper movable plate OPc starts to rise, and at the same time, a split mold apparatus (not shown) operates in the center of the upper movable plate OPc so that the upper mold starts to open. When the upper movable plate OPc continues to rise, the upper mold is fully opened and reaches the upper limit position.

The vulcanized tire on the lower mold and the bladder assembly (not shown) provided in the center of the tire mold assembly M21 are operated by the bladder drive device (not shown) provided in the center of the lower part of the mold opening and closing device OP. The bladder is then peeled off from the inside of the tire.

9) At an appropriate time, the unloader OPh moves forward and lowers, and the upper bead portion of the vulcanized tire on the lower mold is gripped to raise and release the vulcanized tire. This discharge vulcanized tire is conveyed to the next process by using a discharge conveyor (not shown).

10) On the other hand, the loader OPg moves forwards and lowers while holding the raw tire at an appropriate time, while placing the raw tire on the lower mold. The bladder drive is then activated to insert the bladder into the live tires.

11) At the appropriate time, the loader OPg releases the live tires and ascends and retracts. Then, the upper movable plate OPc is lowered so that the open upper mold moves to the closed position.

12) After the upper mold is closed, the upper movable plate OPc is separated from the upper mold and rises to a height allowing passage of the tire mold assembly M21. On the other hand, the lower portion of the mold assembly M21 is released.

At the time of the operation | movement of the metal mold | die opener OP, the 1st tire metal mold | die conveyer T1c waits at the stop position T10 of the exit side of the metal mold | die opener OP.

13) The mold receiving arm extends from the first tire mold conveying machine T1c and is connected to the lower portion of the tire mold assembly M21.

Then the arm is pulled. After the tire die assembly M21 is slid on the guide roller OPf of the tire die opening and closing device OP, it is conveyed onto the guide roller T1b on the first tire die transfer machine T1c and slides thereon. When the tire mold assembly M21 reaches a predetermined position, the assembly stops there.

14) The lower portion of the tire mold assembly M21 is fixed to the first tire mold conveyer T1c, and the first tire mold conveyer T1c moves and stops along the vulcanization station.

The stop position is a stop position T11 at the front of the tire mold assembly M11 arranged side by side with the tire mold assembly M21 moved in items 1), 2) and 3) of the operation description.

After the tire mold assembly M21 is received by the second tire mold conveyer T2c, the tire mold assembly M11 to be vulcanized is moved from the adjacent vulcanization station C11 to the vulcanization station C21 having an empty space. do. Therefore, since the vulcanization station C11 on the side of the 1st tire metal mold | die conveyer T1c is empty, it can accommodate the tire metal mold assembly M21 by which the predetermined | prescribed operation | work was completed by the metal mold | die opening and closing apparatus OP.

15) When the first tire mold conveyer T1c has stopped at the stop position T11 at the front of the vulcanization station C11, the tire mold assembly M21 is released. Then, the arm of the first tire mold conveying machine T1c is extended so that the tire mold assembly M21 is slid onto the guide roller T1b on the conveying machine, and then the guide roller Cf of the vulcanization station C11. Conveyed onto the bed, slid over it and stopped.

16) After the tire mold assembly M21 stops, the arm is pulled toward the conveyer and the conveyer stops to move to the position of the mold opening and closing apparatus and to wait.

On the other hand, the tire mold assembly M21 stopped at the vulcanization station is connected with the internal pressure supply device and the external pressure supply device, and a heating / pressing medium is supplied to continue vulcanization of the tire.

When the tire is manufactured, as shown in the description of the above operation, the vulcanized tire mold assembly M uses the second tire mold conveying machine T2c, and thus from the outlet side of the vulcanizing stations C11 to C23. It is conveyed to a mold opening and closing apparatus. After the predetermined work is finished, the tire mold assembly M is returned to the inlet side of the vulcanization station by using the first tire mold conveying apparatus, so that vulcanization is continued.

When the tire mold apparatus integrated in the tire mold assembly is exchanged during production, the replacement operation is performed in the following order.

1) For the tire mold assembly M in which the final vulcanization is completed, after the vulcanized tire is removed by the order in the items 1) to 9) of the above operation description, the mold is closed without the raw tire being inserted. .

2) Subsequently, after the operation in items 12) and 13) is finished, the first tire mold conveyer T1c moves along the vulcanization station, and the stop position T14 at the front of the mold exchange device MC. Stop at)

3) When the first tire mold conveyer T1c is stopped, the tire mold assembly M is released. Then, by extending the arm of the first tire mold conveying machine T1c, the tire mold assembly M is slid onto the guide roller T1b on the conveying machine, and the guide roller MCf of the mold exchange device MC is provided. It is conveyed to and slid above it, and stops at the center position MC1 of the metal mold | die exchanger MC.

4) After the tire mold assembly M stops, the arm is separated at the lower portion of the tire mold assembly M and pulled towards the conveyer. Then, the tire mold conveyer T1c moves and stops at the stop position T10 at the front of the mold opening and closing apparatus OP for waiting.

5) When the tire mold assembly M is stopped, the lower portion of the tire mold assembly M is fixed.

6) The worker engaged in the mold changing operation removes the connecting bolt to connect the tire mold apparatus to the upper and lower plates of the tire mold assembly M as in the conventional vulcanizer operation.

7) Thereafter, the upper plate of the mold exchange device MC is lowered and connected to the upper plate of the tire mold assembly M. FIG. When the upper plate is raised, the tire mold apparatus is lifted by the lower side.

8) The operator takes out the tire mold apparatus by using a device such as a forklift, and loads and sets a new mold apparatus prepared in advance.

9) The upper movable plate MCc is lowered and the upper plate of the mold assembly M is placed on the new tire mold apparatus. After the upper movable plate MCc is raised, the worker installs the bolt removed in item 6).

10) The tire mold assembly M then moves to the position of the adjacent mold preheater PH and stops. After stopping, the tire mold assembly M is connected with an external pressure supply device to supply a heating medium, whereby heating of the tire mold starts.

11) The mold assembly M heated to predetermined temperature is conveyed to the mold opening-and-closing apparatus OP using the 2nd tire mold conveying machine T2c at an appropriate time, and a metal mold | die is opened. Then, the tires are supplied and tire production begins.

If the number of tire mold assemblies is set so that an extra one station for heating is added to the number of vulcanization stations (six in the example shown in the figure), the tire mold assembly to be replaced can be prepared during tire production, and the used mold After the assembly has been transported out, tire production can begin immediately with a new mold.

4 to 6 show a tire vulcanization method according to a first embodiment of the present invention and a tire vulcanization facility according to a second embodiment for implementing the method. 4 is a plan view thereof, FIG. 5 is a view seen along the line III-III of FIG. 4 in the direction of an arrow, and FIG. 6 is a view seen along the line IV-IV of FIG. 4 in the direction of an arrow.

As shown in FIG. 4, the tire vulcanization plant according to the second embodiment accommodates a plurality of sets of movable tire mold assemblies M (M11 to M33) and vulcanizes a plurality of rows of tire vulcanizing stations C11 to C34. And a mold opening / closing station arranged at the vulcanization stations C11 to C34 to receive the tire mold assembly M and to open / close the tire mold to remove the vulcanized tire T and insert the green tire GT. The first tire mold conveying apparatus T1 and the second tire mold conveying apparatus T2 disposed between OP1, the mold opening and closing station OP1 and the vulcanization stations C11 to C34 to convey the tire mold assembly M. It includes. The vulcanization plant is disposed on the mold loading side of the mold opening / closing station OP1 to release the heating and pressurizing medium in the bladder assembly of the tire mold assembly M conveyed from the tire vulcanization stations C11 to C34. And a feed station OP3 for supplying heating and pressurizing medium to the heating chamber of the tire mold assembly M and also into the bladder assembly.

The first row of vulcanization stations C11, C12, C13, C14 are arranged so that their centers are in a straight line, and the second row of vulcanization stations C21, C22, C23, C24 are arranged parallel to the first row, and the other Three rows of vulcanization stations C31, C32, C33, C34 are arranged. Although in this embodiment shown in FIG. 4 a total of 12 vulcanization stations are arranged, the number of vulcanization stations may be increased, for example, by adding C15, C25 and C35.

The vulcanization stations C11 to C34 each have a plurality of sets of movement guide rollers Cf provided on the base Co of the vulcanization station. The tire mold assemblies M11 to M33 are arranged to be moved by this movement guide roller Cf in the movement direction (for example, the direction from the vulcanization station C11 to C21 or the direction from the vulcanization station C21 to C31).

Since the tire mold assembly moves during operation, this cannot be specified in FIG. 4 in which the mold assembly is indicated by M11. Accordingly, reference numeral M11 is typically shown as mold assembly M at the vulcanization station C11 of FIG. 4.

In addition, on each base of the vulcanization stations C11 to C34, a positioning device (not shown) for positioning the moved mold assembly M is provided. By using such a positioning device, the tire mold assembly M is fixed at or released from the predetermined position.

On one end side of the row of vulcanization stations C11 to C34, a mold opening and closing device OP is provided.

As shown in FIGS. 4 and 6, the mold opening and closing apparatus OP is vertically moved on the side of the frame OPa and the frame OPa assembled on the base OPj and the mold opening and closing apparatus (mold opening and closing). Known loader OPg for loading the live tire GT that can swing between the center position and the standby position of the station OP1, and a frame similar to the loader OPg and on the opposite side of the loader OPg Known unloader OPh for unloading the vulcanized tire T disposed on the side of OPa, and the side of the frame OPa other than the side on which the loader OPa and the unloader OPh are mounted. Lift guide rail OPe provided on the upper surface, guide bracket OPd slidable on the lift guide rail OPe, upper movable plate OPd fixed to the guide bracket OPd, and upper movable plate A known split mold opening and closing operation device provided at the center of the OPc and one end thereof are secured to the frame OPa. And to the other end it comprises a lifting cylinder (OPb) of the plurality of sets that are fixed to the upper movable plate (OPc).

On the upper movable plate OPc, a mold connecting device OPk is provided to connect the upper movable plate OPc to the upper plate Ma of the tire mold assembly M and to disconnect therefrom.

A guide roller OPf and a positioning device (not shown) for positioning the moved tire mold assembly M are provided on the upper side of the base OPj, and the guide roller and the positioning device are vulcanized station ( Similar to those in C11 to C23).

Further, an operating device (not shown) and a vacuum pressure for the bladder assembly (not shown) coupled to the center of the base OPj, that is, to the mold opening / closing station OP1 in the tire mold assembly M, are shown. A conduit connection device (not shown) is provided for supplying pressure and preshaping medium to the bladder assembly.

In the bladder assembly of the mold assembly M to which the heating / pressing medium is moved at an intermediate position between the mold opening / closing station OP1 on the base OPj and the stop position T20 of the second tire mold conveying apparatus T2. A heating / pressurizing medium discharge station OP2 is provided having an internal pressure conduit connection device (not shown) for discharge into the furnace.

The mold assembly which transfers a heating / pressing medium from the mold opening / closing station OP1 to an intermediate position between the mold opening / closing station OP1 on the base OPj and the stop position T10 of the first tire mold conveying apparatus T1 ( With an internal pressure conduit connection device (not shown) for supplying into the bladder assembly of M) and an external pressure conduit connection device (not shown) for supplying heating medium into an external heating chamber of the mold assembly M Heating / pressurizing medium supply station OP3 is provided.

Such internal pressure conduit connection devices and external pressure conduit connection devices are disclosed in Japanese Patent Laid-Open No. 95-80846 filed by the inventor of the present invention.

On the other end side of the vulcanization station (the opposite side of the mold opening and closing apparatus OP), a mold exchange device MC and a preheating device PH are provided.

The mold exchange device MC has a structure similar to the mold opening and closing device OP, but it has a loader OPg for loading the raw tire GT, an unloader OPh for unloading the vulcanized tire T, and The mold opening and closing apparatus OPi is different from the mold opening and closing apparatus OP in that no mold opening and closing operation apparatus OPi is provided. That is, as shown in Figures 4 and 5, the mold exchange device is the frame (MCa), the lifting cylinder (MCb), the upper movable plate (MCc), the guide bracket (MCd), the lifting guide rail (MCe), the movement And a guide roller MCf, a base MCj and a mold connecting device MCk.

The mold preheating apparatus PH is provided at an intermediate position (preheating station) PH1 between the mold exchange station MC1 and the stop position T25 of the second tire mold conveying apparatus T2. In addition, the mold waiting station MC2 is provided at an intermediate position between the mold changing station MC1 and the stop position T15 of the first tire mold changing apparatus T1.

On the base MCj, a movement guide roller MCf and a positioning device (not shown) are provided at the station positions MC1, MC2, and PH1.

On each side surface of the vulcanization stations C11 to C14, C21 to C24, the mold opening and closing apparatus OP, the mold changing apparatus MC, the mold preheating apparatus PH, the first tire mold conveying apparatus T1 and the first 2 tire mold conveying apparatus T2 is provided.

The 1st tire metal mold | die conveying apparatus T1 is the stop position T10 in the front of each heating / pressing medium supply station OP3, and the stop position T11 in the front of the vulcanization stations C11, C12, C13, and C14. , T12, T13, T14 and the stop position T15 at the front of the mold waiting station MC2 can be moved and stopped if necessary.

Moreover, the 2nd tire metal mold | die conveying apparatus T2 is the stop position T20 in the front of each heating / pressing medium discharge station OP2, and the stop position in the front of the vulcanization stations C31, C32, C33, C34. It can be moved between (T21, T22, T23, T24) and the stop position T15 at the front of the mold preheating apparatus PH1 and can be stopped if necessary.

The 1st tire metal mold | die conveyance apparatus T1 and the 2nd tire metal mold | die conveyance apparatus T2 have the same structure. Therefore, only the first tire mold conveying apparatus T1 will be described.

The 1st tire metal mold | die conveyance apparatus T1 is equipped with the base T1d along the vulcanization stations C11, C12, C13, and C14, and a plurality of sets of guide rollers T1f are provided on the base T1d. A first tire mold conveyer T1c is provided on this guide roller T1f, and the first tire conveyer can be moved along the vulcanization stations C11, C12, C13, C14 by a known drive unit T1a. have.

A plurality of sets of guide rollers T1b are provided on the upper side surface of the first tire mold conveying machine T1c. The upper level of the guide roller T1b is the guide roller OPf on the base OPj, the guide roller Cf of the vulcanization stations C11, C12, C13 and C14 and the upper side of the guide roller MCf on the base MCj. It is set to have the same height as the level.

In addition, the 1st tire metal mold | die conveyer T1c is between the 1st tire metal mold | die conveyer T1c and the heating / pressure medium supply station OP3, or the 1st tire metal mold | die conveyer T1c and the vulcanization stations C11 and C12. And a mold conveying device (not shown) used to convey the mold assembly between the C13 and the C14. For a mold conveying device not shown, refer to Japanese Patent Laid-Open No. 96-192429 filed by the inventor of the present invention. Further, for details of the tire assembly, see Japanese Patent Laid-Open Nos. 96-47928 and 97-29746 filed by the inventor of the present invention.

Next, the operation of the tire vulcanization plant according to the second embodiment, which is carried out in the same manner as the tire vulcanization method according to the first embodiment of the present invention, will be described.

1) When the completion of tire vulcanization in the tire mold assembly M32 in the vulcanization station C21 is imminent, the second tire mold carrier T2c moves to the stop position T22 in front of the vulcanization station C32. Move and stop there.

2) The mold receiving arm on the table of the second tire mold conveying machine T2c extends toward the vulcanization station C32 and is connected to the lower portion of the tire mold assembly M32.

3) As the mold receiving arm is pulled, the tire mold assembly M32 is slid onto the guide roller Cf of the vulcanization station C32, and then on the guide roller T2b on the second tire mold conveyer T2c. It is conveyed to and slides on a guide roller. When the tire mold assembly M32 reaches a predetermined position, the assembly stops there.

4) When the tire mold assembly M32 is stopped, the lower portion of the tire mold assembly M32 is fixed to the second tire mold conveyer T2c. On the other hand, the second tire mold conveying machine T2c moves to the mold opening and closing apparatus OP and stops at the stop position T20.

5) After the second tire mold conveyer T2c stops, the mold receiving arm of the second tire mold conveyer T2c extends toward the center of the discharge station OP2. The mold receiving arm is then separated from the lower portion of the tire mold assembly M32 and pulled toward the second tire mold conveying machine T2c.

Thereafter, the second tire mold conveyer T2c then moves to the stop position T21, T22 or T23 at the front of the vulcanization station where the vulcanization is terminated and waits there.

On the other hand, when the mold assembly M32 stops at the position of the discharge station OP2, the internal pressure release device is connected, and the heating / pressing medium in the bladder assembly of the tire mold assembly M32 is discharged. The tire mold assembly M32 waits until the mold opening and closing device OP can receive the mold assembly.

6) In the mold opening and closing apparatus OP, the tire mold assembly moved to the front of the mold assembly M32 which has been subjected to the predetermined work is discharged to the heating / pressing medium supply station OP3.

In addition, since the upper movable plate OPc of the mold opening and closing apparatus OP stands by at a position slightly higher than the tire mold assembly M32, the movement of the tire mold assembly M32 below the upper movable plate OPc is prevented. Do not disturb

7) When the tire mold assembly M21 stops at the center position (mould opening and closing station) OP1 of the mold opening and closing apparatus OP, the lower portion of the tire mold assembly M32 is fixed. On the other hand, the upper movable plate OPc is lowered and connected to the upper portion of the tire mold assembly M32.

8) Then, the upper movable plate OPc starts to rise, and at the same time, the split mold apparatus (not shown) in the center of the upper movable plate OPc starts to operate and the upper mold starts to open. When the upper movable plate OPc continues to rise, the upper mold is fully opened and reaches the upper limit position.

The vulcanized tire T remains on the lower mold, and a bladder assembly (not shown) provided in the center of the lower mold of the tire mold assembly is provided with a bladder drive device provided in the center of the lower portion of the mold opening and closing device OP. (Not shown) to remove the bladder B from the inside of the tire.

9) At an appropriate time, the unloader OPh advances and descends, grips the upper bead portion of the vulcanized tire T on the lower mold, and raises and releases the vulcanized tire T. This discharge tire is conveyed to the next process using a discharge conveyor (not shown).

10) On the other hand, the loader OPg moves forwards and lowers at an appropriate time while fixing the green tire GT, and places the green tire GT on the lower mold. Then, the bladder drive device is operated to insert the bladder B into the green tire GT. At the appropriate time, the loader OPg releases the live tire GT and ascends and retracts.

11) Then, the upper movable plate OPc is lowered so that the opened upper mold moves to the closed position.

After the upper mold is closed, the upper movable plate OPc is separated from the upper mold and rises to a height that allows the passage of the tire mold assembly M32. On the other hand, the lower portion of the mold assembly M32 is released.

The mold assembly M32 moves and stops at the heating / pressing medium supply station OP3, where the internal pressure supply and the external pressure supply are connected to the tire mold assembly M32, the heating / pressing medium is supplied and the tire Vulcanization begins.

This heating / pressing medium is in a restricted state by a check valve provided on the mold assembly. At the time of the said operation | movement, the 1st tire metal mold | die conveyer T1c waits in the stop position T10.

12) The mold receiving arm extends from the first tire mold conveyer T1c and is connected to the lower portion of the tire mold assembly M32.

Then the arm is pulled. After the tire mold assembly M32 is slid on the guide roller OPf, it is conveyed on the guide roller T1b on the 1st tire mold conveyer T1c, and it slides on it. When the tire mold assembly M32 reaches a predetermined position, the assembly stops there.

13) The lower portion of the tire mold assembly M32 is fixed to the first tire mold conveyer T1c, and the first tire mold conveyer T1c moves and stops along the vulcanization station.

The stop position is the stop position T12 at the front of the tire mold assembly M12 in which the tire mold assemblies M32 moved in items 1), 2) and 3) of the operation description are arranged side by side.

After the tire mold assembly M32 is received by the second tire mold conveyer T2c, the tire mold assembly M22 where vulcanization is performed moves from the adjacent vulcanization station C22 to the vulcanization station C32 having an empty space. do. Then, the tire mold assembly M12 to be vulcanized is moved from the vulcanization station C12 to the vulcanization station C22.

Thus, since the vulcanization station C12 on the side of the first tire mold conveying machine T1c is empty, it can accommodate the tire mold assembly M32 in which a predetermined work is completed by the mold opening and closing apparatus OP. .

14) The tire mold assembly M32 is released when the first tire mold conveyer T1c stops at the stop position T12 at the front of the vulcanization station C12. Then, the arm of the first tire mold conveying machine T1c is extended so that the tire mold assembly M32 is slid on the guide roller T1b on the conveying machine and then on the guide roller Cf of the vulcanization station C12. Bounced and stopped.

15) After the tire mold assembly M21 stops, the arm is pulled towards the conveyer, and the conveyer moves to position T10 on the side of the mold opening and closing device and stops to wait until it receives the next mold assembly.

For the tire vulcanization plant according to the second embodiment of the present invention, the operation for producing the tire and the procedure for replacing the tire mold apparatus at the time of operation are the same as in the first embodiment.

7 and 8 illustrate a tire vulcanization method according to another embodiment of the present invention and a tire vulcanization facility according to the third embodiment implemented by the same method. Fig. 7 is a plan view of the present invention, and Fig. 8 is a front view showing a part of the tire vulcanization plant shown in Fig. 7. 9 to 15 show an example of a bladder assembly used when the tire vulcanization method according to the present embodiment is performed. 9 is a cross-sectional view showing a state in which the bladder assembly is integrated into the mold assembly, FIG. 10 is a cross-sectional view showing the inflated state, FIG. 11 is a cross-sectional view taken along the line I-I of FIG. FIG. 12 is a cross-sectional view taken along the line II-II of FIG. 11A, FIG. 13 is a view taken along the line III-III of FIG. 10, and FIG. 14 is a cross-sectional view taken along the line IV-IV of FIG. 10. .

The tire vulcanization plant according to the third embodiment is different from the plant according to the second embodiment in the following points. For the tire vulcanization plant according to the second embodiment, the bladder assembly according to the present embodiment is fixed to the tire mold assembly M, and no means for connecting the upper portion of the bladder assembly to the lower portion thereof is provided. In addition, the loader OPg provided on the mold opening and closing device OP only loads the green tire Gt, and the unloader OPh unloads only the vulcanized tire T.

On the other hand, for the tire vulcanization plant according to the third embodiment, the bladder assembly 1 used in this embodiment can be detached from the mold assembly M, and the upper portion of the bladder assembly 1 is removed. Means are provided for connecting and disconnecting the lower part and from the lower part, and the loader OP-Ag provided on the mold opening and closing device OP-A in its integrated state is a tire and bladder assembly. (1) is loaded, and the unloader OP-Ah unloads the vulcanized tire T and bladder assembly 1 in an integrated state.

Further, the tire vulcanization equipment according to the third embodiment includes a separation station UL for separating the bladder assembly 1 from the vulcanized tire T in the vicinity of the mold opening and closing apparatus OP-A, and the bladder assembly. The second in that a shaping station SH for assembling (1) into a green tire GT for performing formation and a storage station ST for storing the separation bladder assembly 1 are provided. It differs from an Example.

Thus, the vulcanization stations C11 to C34, the mold opening and closing station OP1, the heating / pressing medium discharge station OP2, the heating / pressing medium supply station OP3, the first and second tire mold delivery devices T1 and T2. ), Mold exchange station MC1, mold standby station MC2, mold preheating station PH1 and mold assembly M according to the second embodiment (the bladder assembly 1 is different from the second embodiment). Is the same as in the third embodiment. Therefore, description of these elements is omitted.

In addition, the mold opening and closing apparatus OP-1 of the third embodiment includes the base OPj, the frame OPa, the lifting guide rail OPe, the guide bracket OPd, the upper movable plate OPc, and the slit mold opening and closing operation. An element OPi and a plurality of sets of lifting cylinders OPb are included, the lifting cylinders having the mold opening and closing device OP of the second embodiment.

FIG. 9 shows a state in which the raw tire GT and the bladder assembly 1 are loaded while the mold assembly M is opened, the mold assembly M is closed, and vulcanization is started. In this configuration, the portion having the mold assembly M and the base OPj is shown in dashed line.

In this embodiment, the mold remains closed by operation of the mold itself against the force for opening the mold, which is caused by the operation of the heating / pressing medium introduced into the bladder B upon vulcanization of the tire. A mold assembly M of the type which can be used is used.

The detailed description of such a mold assembly is omitted in Japanese Patent Laid-Open No. 96-47928, so the mold assembly M is distributed along the base plate Mo for the mold assembly, the lower sidewall mold M1, and the circumferential direction. And a plurality of tread molds M2, upper sidewall molds M3, and upper bead rings M4 bolted to the upper sidewall molds M3. The lower bead ring 5a having a portion of the mold at the time of vulcanization is integrated with the flange 5 of the fixing member G1 for fixing the lower end of the bladder B of the bladder assembly 1.

In addition, the mold assembly M includes a base OPj for the mold opening and closing apparatus OP-A shown in FIGS. 7 and 8, a guide roller OPf assembled on the upper surface of the base OPj, There is a lifting device 203 integrated into the base OPj which can move the bladder assembly 1 vertically. The peripheral portion at the upper end of the elevating device 203 is formed with a conical surface which engages with the conical surface 2C of the outer peripheral portion at the lower end of the outer shaft 2 of the bladder assembly 1.

The elevating device 203 receives the bladder assembly 1 in its raised position when the bladder assembly 1 is inserted into and removed from the mold. Further, the lifting operation upon removal separates the vulcanized tire from the lower sidewall mold M1.

At the outer periphery of the lower end of the outer shaft 2, a lock claw 204 is provided to lock the outer shaft 2 to the elevating device 203. The tip end of the lock claw 204 engages with a peripheral groove 2b formed on the outer circumferential surface of the outer shaft 2. In addition, the inner shaft 9 is attached to and detached from the piston rod tip end of the post cylinder (not shown) via the connecting device 205. In addition, the conduit 206 of the internal pressure conduit device can be moved vertically by incorporation into the table 201 and a known sealing member is provided on the contact surface in contact with the valve 23. The heating / pressing medium in the bladder assembly at the heating / pressing medium discharge station OP2 is discharged through the conduit 206 and the heating / pressing medium is supplied at the heating / pressing medium supply station OP3.

Identical elements such as elevating device 203, lock claw 204, connecting device 205, conduit 206 are provided at the location of the separating station UL below.

The right half of FIG. 10 shows a state where the vulcanized tire T and the bladder assembly 1 are disposed in the separation station UL, and the left half of FIG. 10 shows the green tire GT and the bladder assembly 1. ) Is shown in the forming station (SH), where the forming station performs pre-assembly and forming. The bladder assembly 1 with the bladder B is shown in solid lines, and the part to which the separation station UL and the shaping station SH belong is shown by a dashed line. The dotted line shows the expanded state of the bladder B of the bladder assembly 1.

As shown in FIGS. 10 and 11, the base flange 4 is bolted to a two-piece ring 3 inserted into a surface groove 2a formed on the outer circumferential surface of the outer shaft 2 so that the outer shaft 2 Is fixed to.

The fixing member G1 for fixing the lower end of the bladder B fixes the lower end of the bladder B between the flange 5 and the press plate 6 so that the press plate 6 is connected to the flange 5. ), The lower end of the bladder B is held and fixed. The flange 5 has a configuration in which the flange 5 is fixed to the outer shaft 2 via the base flange 4 by being screwed and fixed to the base flange 4.

Further, the extended outer shaft 8 is formed to have a plurality of retaining claws 8a arranged at equal intervals on the outer side of the upper end, and bolted to the upper end of the outer shaft 2. The inner shaft 9 is inserted into the outer shaft 2 to be axially slidable, and the known sealing member 11 and guide bush 12 have an outer shaft 2 and an inner shaft 9. ) Is placed between. The connecting flange 10 described below is fixed to the lower end of the inner shaft 9, and the upper end of the outer cylinder 13 is coupled to the upper end of the inner shaft 9. The outer cylinder 13 fastens the nut 14 and thus is fixed to the inner shaft 9.

On the other hand, in the fixing member G2 for fixing the upper end of the bladder B, the press plate 16 is flanged by fixing the upper end of the bladder B between the flange 15 and the press plate 16. Bolted to (15), the upper end of the bladder (B) is held and fixed. Since the flange 15 is bolted to the lower end flange of the outer cylinder 13, it is configured to be fixed to the inner shaft 9 via the outer cylinder 13.

When the bladder assembly 1 and the vulcanized tire T are unloaded at the outer circumference of the outer cylinder 13 or the bladder assembly 1 and the green tire GT are loaded, the unloader OP-Ah or the loader ( A projection 13a is formed which engages with the extendable fixing claw of OP-Ag).

As shown in FIG. 11A, the claw flange 17 is rotatably assembled at the upper end of the inner shaft 9, and the plurality of claws 17a are circumferentially inward at the lower end of the claw flange 17. It is formed at equal intervals. When the outer shaft 2 and the inner shaft 9 slide relatively axially, the retaining claw 8a and the claw 17a are locked to each other or pass through each other according to the rotatable angle of the claw flange 17.

As shown in FIG. 12, the rotating means for the claw flange 17 is inserted into a square claw 9b formed in a direction perpendicular to the axis of the inner shaft 9, and both ends thereof are in the inner shaft 9. The upper side of the inner shaft such that the key 18, which is engaged with the key groove 17b formed in the rotatable slide hole of the claw flange 17, with respect to the lower end side square cross-sectional portion 19b is formed in the center of the key 18. It consists of a shaft 19 rotatably coupled concentrically to the end, a known sealing member 21, a guide bush 22 and a capping nut 19 for preventing fall out.

The upper end 19a of the shaft 19 has a square cross section for connection with rotational drive means provided on the unloader OP-Ah and loader OP-Ag described below, and the lower end circular cross section 19c is inserted into the round hole 9a formed in the inner shaft 9.

As shown in FIGS. 10 and 13, at the bottom of the base flange 4, a valve 12 (a ball valve is used in this example shown in the figure) is blamed when the bladder assembly 1 is conveyed. It is fixed to limit the pressurized medium sealed in the further B. This valve 23 is connected to the fluid chamber 25 via the passage 4b in the base flange 4.

The fluid chamber 25 is formed by the base flange 4, the flange bolted to the base flange 4, and the outer shaft 2, and communicates with the inside of the bladder via the plurality of nozzles 4a.

9 and 10, reference numeral 201 denotes a table of a separating station UL or a forming station SH therein, and a conical surface 2c formed outside at the lower ends of the outer shafts 2,204. The conical surface engaging) represents the lock claw that locks the outer shaft 2 to the table 201 by engaging the tip end with the peripheral groove 2b formed on the outer circumferential surface of the outer shaft 2, and the reference numeral 205 A connecting device for attaching and detaching the inner shaft 9 to the inner shaft lift drive is shown. The right half of FIG. 14 shows the connected state, and the left half thereof shows the disconnected state.

As shown in FIG. 14, the connecting flange 10 is bolted to the lower end of the inner shaft 9, the guide bush 10a is fixed on the outer circumferential surface of the connecting flange 10, and the ring-shaped protrusion 10b. Is formed inside the lower end.

An upper end of the plurality of levers 205c having projections 205b for fixing the projections 10b from the top, respectively, is disposed in the connecting flange 10, which levers 205c are connected via a pin 205d to the connecting device ( 205a main body 205a.

A pressure spring 205e is inserted between the upper ends of the levers 205c. The pressing force of the spring 205c is applied in the direction in which the upper end of the lever 205c is opened.

The upper end of the output shaft 207 of the elevating drive device is screwed into and fixed to the main body 205a of the connecting device 205. The inner shaft 9 is pushed up by the main body 205a through the connecting flange 10 with the raising of the output shaft 207, and the protrusions of the main body 205a, the pin 205d and the lever 205c ( It lowers by lowering the output shaft 207 through 205b and the projection 10b of the connecting flange 10.

The roller 204g is rotatably coupled to the lower end of the lever 205c through the pin 205f. Accordingly, the lever 205c is deflected by the cam 208 which pushes the roller 205g on the conical surface 208a formed on the upper side of the cam 208, and the cam 208 is accompanied by the output shaft 207 to be guided. It moves vertically by the operation of a cylinder (not shown). As a result, the upper end of the lever 205c decreases in diameter, and the inner shaft 9 is separated from the inner shaft lifting drive.

Conduit 206 for the pressurized medium is integrated into the table 201 to move vertically. A known sealing member 112 is provided on the upper side of the conduit 206 such that airtightness is maintained on the contact surface when the upper side of the conduit 206 contacts the lower flange 23a of the valve 23.

The valve 23 has opening and closing levers 113 and 114 shown in FIG. These opening and closing levers 113 and 114 are configured such that one is raised by the driving means (not shown) while the other is lowered. At both ends of the actuating lever 24 of the valve 23, the loaders 24a and 24b are provided rotatably through the pins, thereby opening and closing the valve 23 by pressing any one of the loaders 24a and 24b. Is performed.

The unloader OP-Ag for unloading the vulcanized tire T and the bladder assembly 1 is a known unloader [unloader for unloading only the vulcanized tire T from the following point of view. (OPh)].

The known unloader OPh has an extendable claw which secures the upper bead portion of the tire T from the inside, and the extendable fixing claw 300 of the unloader OP-Ah is as shown in FIG. 11B. By providing the tire fixing outer protrusion 300a and the outer bladder assembly fixing protrusion 300b, the fixing claw 300 can fix the bead portion of the tire T by the diameter increasing action or, if necessary, the diameter reducing action. The outer cylinder 13 of the bladder assembly 1 can be fixed by this.

The loader OP-Ag for loading the green tire GT and the bladder assembly 1 is the same as the unloader OP-Ah. Therefore, description thereof is omitted.

15 shows the inlet side of the separation station UL and the storage station ST for the bladder assembly 1. The left half of the bladder assembly 1 of FIG. 15 shows a state in which the vulcanized tire T and the bladder assembly 1 are conveyed and arranged in the separation station UL, and the bladder assembly 1 of FIG. The right half of the figure shows a state in which the vulcanized tire T is removed, and the bladder assembly 1 comes close to the storage station ST.

Before the bladder assembly 1 is placed in the separation station UL, the loading table 405 on the inlet side of the storage station ST is located in the lower position as shown by the solid line in FIG. 15 and the bladder assembly 1 Does not interfere with the placement.

The bladder assembly 1 has a known arm 307 that can move and swing vertically, and the disk 302 is fixed to one end of the arm 307. The disk 302 has a guide 301 in the radial direction so that the fixing claw 300 guided by the guide 301 is extended and retracted by a drive unit (not shown). The tire fixing protrusion 300a is provided at the lower end of the fixing claw 300, and the protrusion 300b that engages with the protrusion 13a of the bladder assembly 1 when the diameter of the fixing claw 300 is reduced is a protrusion ( 300a).

At the center of the disk 302 is a drive shaft 304 rotatable in the hole 302a. The drive shaft 304 is formed with a square hole 304a that is coupled to the square shaft 19a at the upper end of the shaft 19 of the bladder assembly 1. The upper portion of the drive shaft 304 is provided with a gear 304b and a gear 305 which mesh with the gear 304b and are driven by the rotation drive device 306.

The drive shaft 304 is rotated by the rotation drive device 306, and the retaining claw 8a and the retaining claw 17a of the bladder assembly 1 are brought into a connected state and a disconnected state.

In the separation station UL configured in this manner, the vulcanized tire T and the bladder assembly 1 are accommodated, the upper part and the lower part of the bladder assembly 1 are separated from each other, and the vulcanized tire T is Separated from the bladder assembly 1, the vulcanized tire T is unloaded, and the expanded bladder B of the bladder assembly 1 is retracted for convenient storage as shown in the right half of FIG. do.

At this time, a suitable pressurized medium of very low pressure can be sealed in the bladder (B).

In FIG. 15, reference numeral ST denotes an entire storage station for a plurality of sets of bladder assemblies 1. This storage station is located on the side of the post 400, the transverse beam 401 having a plurality of sets of rollers 402 on which the bottom surface of the base flange 4 of the bladder assembly 1 slides. A table which is guided by a fixed lifting guide 403, a bearing 404 sliding onto the guide 403, and a lifting guide 403 on the column 400 and moved vertically by a drive unit (not shown) ( 405 and roller 406 for sliding.

Thus, the table 405 rises and places the bladder assembly 1 on the roller 406 after the roll claw 204 is released, and stops at the position of the shelf where the bladder assembly 1 is stored, The bladder assembly 1 is then configured to be conveyed into the storage shelf since the rollers 406 and 402 are driven by a drive unit not shown. The interior of the storage shelf may be kept warm or heated to prevent the stored bladder assembly 1 from cooling.

The shaping station SH is arranged on the outlet side of the storage station ST. It has a table moving vertically on the exit side, a drive unit below the table and a loader (OP-Ag) which holds the green tire (GT) and loads the bladder assembly 1 into the mold opening and closing station (OP). . This configuration is the same as the separation station UL on the inlet side of the storage station ST. Therefore, details of this are omitted.

Next, the tire vulcanization plant according to the third embodiment, which is implemented in the same manner as the tire vulcanization method according to another embodiment of the present invention, will be described.

For the operation of the third embodiment, items 1) to 15) are the same as the items in the description of the operation of the second embodiment.

16) Then, the tire mold assembly stopped at the vulcanization station C12 is connected with the internal pressure supply device and the external pressure supply device, the heating / pressure medium is supplied, and the vulcanization of the tire is continued.

Further, the operation of the bladder assembly 1 of the third embodiment is as follows.

Items 1) to 8) of the third embodiment are the same as those of the second embodiment.

9) At the appropriate time, the unloader OP-Ah is advanced and lowered to secure the upper portion of the bladder assembly on the lower mold, and raised to unload the assembly of the vulcanized tire T and the bladder assembly 1. And the swing conveys the mold opening and closing apparatus OP to the outside of the table.

Operation in the table position will be described below as item 16 of the operation description.

10) Then, after the unloader OP-Ah retracts, the loader OP-Ag advances and descends while holding the assembly of the vulcanized tire T and the bladder assembly 1 to lower the assembly into the lower mold shape. And the assembly is released to raise and retract to the original position.

The operation to join the green tire GT and the bladder assembly 1 will be described in operation 17 below.

Items 11) to 15) are the same as the operational description of the second embodiment.

16) The operation in the table position after the unloader OP-Ah unloads the vulcanized tire T and the bladder assembly 1 is as follows.

a) The unloader OP-Ah integrally unloads the vulcanized tire T and the bladder assembly 1, and unloads the bladder assembly 1 into the storage station ST for the bladder assembly 1. The vulcanized tire T and bladder assembly 1 are placed on a table 201 that moves vertically from the side.

b) Then, the lower part of the bladder assembly 1 is fixed to the table 201. The unloader OP-Ah separates the upper portion and the lower portion of the bladder assembly 1 from each other, releases the bladder assembly 1, and rises to atmosphere.

c) Raise the bladder operating device under the table 201 and extend the rod of the bladder assembly 1 to peel off the bladder B from the vulcanized tire T.

d) Then, the unloader OP-Ah waiting at the upper side descends, the upper bead portion of the vulcanized tire T is gripped, and is raised to separate the vulcanized tire T from the bladder assembly 1. .

e) Unloader OP-Ah raises and retracts and conveys the gripped vulcanized tire T to a discharge conveyor. This discharge conveyor conveys the vulcanized tire T to the next process.

f) After the unloader OP-Ah retracts, the extended rod of the bladder assembly 1 is retracted and set to a convenient height for storage in the storage shelf. At this time, the pressure medium having an atmospheric pressure or a pressure slightly higher than the atmospheric pressure is sealed in the bladder (B).

g) The table 201 then raises and stops by selecting the position of the shelf on which the bladder assembly 1 is to be stored.

h) The bladder assembly 1 on the table 201 is released from the table 201 and stored in a storage shelf.

i) Thus, the vulcanized tire T and bladder assembly 1 which are unloaded by the unloader OP-Ah are separated from each other in the table position. The bladder assembly 1 is stored in the selected storage shelf and then conveyed to the outlet side of the storage shelf at the appropriate time and waits in the storage shelf until it engages with the green tire GT.

17) The operation for combining the green tire (GT) and the bladder assembly (1) is as follows.

a) At a suitable time, the selected bladder assembly 1 is conveyed onto the table 201 from the storage shelf for the bladder assembly, and the table moves vertically at the outlet side of the storage shelf.

Here, a suitable time is a time when the tire mold assembly M reaches the position of the discharge station OP2 for the heating / pressurizing medium. | In fact, following the mold assembly M from which the vulcanized tire T was removed, It means when the preformed assembly with the raw tire GT and bladder assembly 1 can be supplied without problems.

b) The conveying bladder assembly 1 is fixed to the table 201.

c) The bladder operating device under the table 201 extends the rod of the bladder assembly 1. During this operation, the green tire loader OP-Ag provided near the table 21 fixes the selected green tire GT and stands on the upper side of the extended rod.

d) After the extension of the rod is completed, the green tire GT lowers and stops at a predetermined position. Then, the rod is lowered, whereby the bladder B is inserted into the green tire GT while expanding, and shaping of the green tire GT is performed.

e) After the predetermined shaping operation is completed, the loader OP-Ag connects the upper portion and the lower portion of the bladder assembly 1 to each other, releases the green tire GT, and moves up and down.

f) After retracting, the loading device advances, descends and stops at a predetermined position and then waits until the time of operation description of item 10) while gripping the upper portion of bladder assembly 1.

As mentioned above, although embodiment of this invention was described, this invention is not limited to the said embodiment, A various deformation | transformation and a change can be made according to the technical concept of this invention.

The present invention is more economical and the transportation time can be shortened and the number of tire molds can be increased by using the common mold for the loaded mold assembly disposed at the position just before the mold loading side of the mold opening and closing station.

Claims (9)

In the tire vulcanization plant, A plurality of rows of tire vulcanization stations for receiving a plurality of sets of movable tire mold assemblies for vulcanizing a tire, and a mold opening / closing station disposed in a tire vulcanization station for receiving the tire mold assemblies to open and close the tire mold. And a first mold conveying device and a second mold conveying device, which are disposed between the mold opening and closing station, the mold opening and closing station and the tire vulcanization station, and conveying the tire mold assembly, wherein the tire vulcanized is removed and the raw tire is inserted. And the first mold conveying apparatus and the second mold conveying apparatus are provided on both outer sides of the tire vulcanization station. Tire vulcanizing equipment. In the tire vulcanization plant, A plurality of rows of tire vulcanization stations for receiving a plurality of sets of movable tire mold assemblies for vulcanizing a tire, and a mold opening / closing station disposed in a tire vulcanization station for receiving the tire mold assemblies to open and close the tire mold. A mold opening / closing station in which the vulcanized tire is removed and a raw tire is inserted, and a first mold conveying device and a second mold conveying device arranged between the mold opening and closing station and the tire vulcanizing station to convey the tire mold assembly; A discharge station disposed on the mold loading side of the mold opening / closing station and discharging a heating / pressing medium in the bladder assembly of the tire mold assembly conveyed from the tire vulcanization station, and on the mold unloading side of the mold opening / closing station. Placed on the heating / A supply station for supplying pressurized media into the heating chamber and bladder assembly of the tire mold assembly. Tire vulcanizing equipment. The method of claim 1, The first mold conveying apparatus is disposed on one side of the tire vulcanization station in the plurality of rows, the second mold conveying apparatus is disposed on the other side of the tire vulcanizing station, and the tire mold assembly is disposed from one side of the tire vulcanizing station. 1 is carried on a mold conveying apparatus, and the tire mold assembly is conveyed to the mold opening and closing station using the first mold conveying apparatus, and the tire mold assembly is conveyed from the mold opening and closing station onto the second mold conveying apparatus, The tire mold assembly is conveyed to the other side of the tire vulcanization station by using the second mold conveying device and mounted on the tire vulcanization station. Tire vulcanizing equipment. The method of claim 2, The first mold conveying apparatus is disposed on one side of the tire vulcanization station in the plurality of rows, the second mold conveying apparatus is disposed on the other side of the tire vulcanizing station, and the tire mold assembly is disposed from one side of the tire vulcanizing station. 1 is carried on a mold conveying apparatus, and the tire mold assembly is conveyed to the mold opening and closing station using the first mold conveying apparatus, and the tire mold assembly is conveyed from the mold opening and closing station onto the second mold conveying apparatus, The tire mold assembly is conveyed to the other side of the tire vulcanization station by using the second mold conveying device and mounted on the tire vulcanization station. Tire vulcanizing equipment. The method according to any one of claims 1 to 4, The mold opening / closing station is arranged at one end side of the tire vulcanization station row of the plurality of rows, and the mold exchange device and the mold preheating device are arranged at the other end side of the tire vulcanization station row. Tire vulcanizing equipment. In a tire vulcanization facility, a movable tire mold assembly is mounted on a mold opening and closing station, and the tire mold is opened and closed at the mold opening and closing station to remove vulcanized tires and insert fresh tires to vulcanize the tires. The installation includes an outer shaft to which a fixing member for fixing one end of the bladder is fixed; An inner shaft to which a fixing member for fixing the other end of the bladder is fixed and slidably inserted in the axial direction with respect to the outer shaft; A retaining claw is formed at one end of the outer shaft, and a claw flange rotatably assembled to the inner shaft, the claw flange having a claw engaging or passing through the retaining claw of the outer shaft, depending on the angle of rotation. And a bladder assembly including rotation means for rotating from one end of the inner shaft, and by coupling the retaining claw of the outer shaft with the claw of the claw flange, the vulcanized tire or the live tire and the bladder assembly Integrated for insertion into and removal from the mold of the tire Tire vulcanizing equipment. In a tire vulcanization facility, a movable tire mold assembly is loaded on a mold opening and closing station, and the tire mold is opened and closed at the mold opening and closing station to remove vulcanized tires and insert fresh tires to vulcanize the tires. A separation station for receiving an assembly in which the vulcanized tire and the bladder assembly are integrated to separate the vulcanized tire and the bladder assembly from each other; A storage station for storing a plurality of bladder assemblies from which the vulcanized tires are separated; A vulcanized tire removing device and raw tire supply having a shaping station for receiving the bladder assembly conveyed from the storage station and inserting the bladder into the green tire to perform shaping to integrate the green tire and the bladder assembly together. Characterized in that it comprises a device Tire vulcanizing equipment. A tire vulcanizing method in which a movable tire mold assembly is loaded on a mold opening and closing station, and the tire mold is opened and closed at the tire mold opening and closing station to remove the vulcanized tire and insert a fresh tire to vulcanize the tire. Discharging the heating / pressing medium of the tire in the tire mold assembly in a standby position just before the tire mold assembly is loaded from the mold opening and closing station into the mold opening and closing device, and then the tire mold is opened and closed to Removing the vulcanized tire and inserting the raw tire, the heating / pressing medium is supplied into the tire of the tire mold assembly, and the heating medium is released from the mold opening and closing apparatus at the standby position of the unloading side of the tire mold assembly. Supplying a heating chamber of a tire mold assembly to vulcanize the tire; Tire vulcanization method. A tire vulcanizing method in which a movable tire mold assembly is loaded on a mold opening and closing station, in which the tire mold is opened and closed to remove the vulcanized tire and insert a raw tire to vulcanize the tire. When the vulcanized tire is removed by opening the tire mold, the vulcanized tire and the bladder assembly are integrally removed, and then the vulcanized tire is peeled off the bladder assembly, and then the raw tire And vulcanizing the tire by inserting the bladder assembly into the tire mold in an integrated state. Tire vulcanization method.